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Spread monolayers of proteins
Advances in Colloid and Interface Science, 25 (1986) 341-385
341
Elsevier Science Publishers B.V., Amsterdam - Printed in The Netherlands
SPREAD MONOLAYERS
OF PROTEINS
F. MacRITCHIE
CSIRO Wheat Research Unit, P. 0. Box 7, North Ryde, N.S.W. 2113, AUSTRALIA
CONTENTS I.
ABSTRACT
.......................................................
II.
INTRODUCTION
III.
METHODS
...................................................
FOR SPREADING
A. Aqueous
solution
B. Spreading
for quantitative AND INTERPRETATION
0. Surface
potentials
B. Surface
rheology
346
....................
347
films
.................
MONOLAYERS
...............
349 350 352 355
..........................................
355 356
of film ............................................
358
methods
......................................
362
.....................................
363
........................................
363
FROM MONOLAYERS
A. Kinetic measurements B. Radiolabelled C. Desorption
proteins
......................................
from mixed monolayers
0. Effect of molecular
weight
............................
..................................
367 369 370
E. Theory of desorption
........................................
371
IN MONOLAYERS
........................................
372
.............................................
373
REACTIONS
A. Instrumentation B. Enzyme reactions C. Other reactions
VIII.
346
...................
......................................... PROTEIN
345
............................................
0. Direct optical
VII.
weight
in compressed
FOR STUDYING
A. Surface
DESORPTION
OF n-A CURVES
..........................................
changes
coagulation
.........................
spreading
region and molecular
of state
OTHER TECHNIQUES
C. Transfer
VI.
345
0. Criteria
C. Configurational
344 344
MEASUREMENT
B. Equations
342
..........................................
....................................................
A. Low pressure
V.
...............................
............................................
solvents
C. Crystals
IV.
MONOLAYERS
342
APPLICATIONS A. Biological
and biological
activity
....................
.............................................
...................................................
376 378
........................................
378
B. Foams and emulsions
.........................................
379
C. Biomedical
.........................................
380
0001-8686/86/$15.75
membranes
374
problems
0 1986 Elsevier Science Publishers B.V.
342 IX.
CONCLUOING
REMARKS
X.
REFERENCES
.....................................................
I.
.............................................
383
ABSTRACT The study of spread monolayers
the fundamental
behavior
from their ubiquitous proteins
of proteins
presence
liposomes
arrangement and packing
trolled.
Methods
potential
of monolayers
spectroscopy,
changes,
ellipsometry).
molecular
surface
theoretical reviewed.
relevance
of multicompartment
to biological
occurring
where
the enzyme
of monolayer
membranes,
region
interface
and is
has proved valu-
This instrumentation
at the surface,
is imnobilized
for
reflectance
Experimental
film balances
in monolayers.
foams and emulsions
diffrac-
methods
configurational
from the air/water
studies are briefly
removal
in the low pressure
are all observed.
of proteins
to the study of enzyme reactions
to reactions
Some applications
(e.g., multiple
and desorption
able for the study of reactions has been applied
electron
At higher pressures,
work on the desorption The introduction
(such as surface
Direct optical
The use of measurements
that
and con-
including
is discussed.
weights
coagulation
methods
techniques,
in situ are also available --
In
chemistry.
used for their manipu-
innovations,
are discussed.
of
to other branches
may be measured
and techniques
more recent
spectroscopy,
mimetic
the unique advantage
in monolayers
proteins
for study by radiotracer
(IR)
the study of monolayers
to measure
of molecules
despite
resulting
Spread monolayers
in comparison
As well as the more traditional
on slides
tion and infrared
in nature.
field of membrane
neglected
and viscosity),
for understanding
as well as the many phenomena
and vesicles),
for spreading
lation are outlined. pressure,
is of interest
at interfaces
it has been somewhat
(such as bilayers, the
of proteins
is a branch of the developing
recent times,
II.
381
of direct
in the cell membrane.
illustrated
and biomedical
with reference
problems.
INTRODUCTION A striking
solution,
property
of proteins
is that, although
they may be spread quantitatively
to give highly stable monomolecular pounds, which
require
at these interfaces. results mainly large size. attached
from two properties:
A protein
molecule
and glutamic
a configuration
or oil/water
This is in contrast
solubility
1) their polar/non-polar
consists
ofa polypeptide degrees
and leucine)
acids).
to most com-
at interfaces
nature;
backbone
of polarity,
and 2) their
to which are
ranging
from
to polar ones (such as the
In the dissolved
that minimizes
in aqueous interfaces
in order to spread as monolayers
of protein molecules
of varying
(such as phenylalanine
aspartic
cules assume
films.
The great stability
amino acid side-chains
very non-polar ionizable
very low water
many are soluble
at air/water
state,
protein mole-
the free energy of the system.
Thus,
343 they fold up in such a manner groups at the periphery side, protected
that the number of polar
are maximized
from energetically of non-polar
unfavorable
Complete
shielding
however,
because
residues
sequence
and the steric constraints
of their possible
When a molecule
reaches
proximity
order
for this to occur,
conformation
in which
the non-polar
is replaced
to polar residues
has a certain of the molecule
segments.
Although
each segment
adsorption
(AG), the total free energy
if the number of segments
stability quires
The drastic
unfolding
molecules
the effects
has only a moderately
to an insoluble
priate.
interaction
on proteins,
large free energy of
However,
systems,
in response
to changes
interfaces.
to many biological
phenomena
produce
coagulation
in their energy
that,
of proteins that occur
appears
are continually
inappro-
altering
environment,
their
including
with interfaces
(such as cell membrane
to
irrever-
processes
denaturation"
It is this interaction
of
being applied
by the observation
when the different
re-
from the interface.
loss of solubility
are shaken,
protein molecules
very high
for the great
of a whole molecule
that surfaces
the term "surface
toward
This ex-
so that for many pur-
This accounts
by an apparent
implying
phase.
(nAG) may attain
the desorption
solutions
form results.
with
per molecule
This view is supported
protein
are understood,
In biological
conformations
accompanied
In chain
in terms of a series of
of a large number of segments
in proteins.
cases where
at interfaces
relevant
may be described
has led to the term "surface denaturation"
of surfaces
sible changes in certain
removai
directed
to the aqueous
(n) is large.
interface
side-chains.
into a two-dimensional
degree of flexibility
of protein monolayers,since
simultaneous
protein
unfold
protein
side chains are predominantly
poses, the behavior
is encountered.
if an area of high energy
by non-polar
phase and the polar side chains
tended configuration
values
medium.
achieved,
in the chain
a new energy environment
protein molecules
non-polar
not be closely
in-
imposed on chain folding.
an interface,
by water molecules
ionizable)
groups are mainly
contact with the aqueous
can usually
The free energy of the system may be reduced occupied
(especially
and the non-polar
that is
structure
and
created
model
function). A growing systems
field of research
is concerned
of cells and cell membranes.
This has become
chemistry
(ref. 1,2) and includes monolayers,
liposomes
and vesicles.
of the film balance, attention
with artificially
Despite attracting
(such as bilayers,
times.
This does not mean that there
Present
techniques
are not capable
3.4) has drawn attention
is no
multilayers,
much interest
the study of protein monolayers
as other areas
known as membrane
bilayers,
micelles
following
develapment
has not received and liposomes)
mimetic
micelles,
as much
in recent
scope for further work or that
of yielding
to the use of designed
new information. monolayer
tibius
assemblies
(ref.
to create
344 processes
analogous
cules
in biological
which
light energy
cific proteins
to those performed systems.
is converted
assemblies
of biological
monolayer
research
advantage
over some of the complementary may be manipulated
a function
determined
METHODS Although
FOR SPREADING
the technique
tional
monolayers.
are adsorbed. proportion
These conditions
in incomplete
proteins.
A. Aqueous
solution
Purely aqueous
solution
precautions
in which
A method
is allowed
satisfactory
of all protein molecules
Rigorous
theory was applied
variables
fully by a number of workers spreading
solvent
theory,
to adsorption
difficult solution
to derive appropriate
into the system. technique
This may be explained
to the surface
ionic strength, satisfactorily.
the electrical
energy
conditions
thickness
in
in terms
of flowing
aque-
has been used successthat no non-aqueous to be occas-
of energy barriers
Proteins
of mole-
are particularly
charge and the spreading
spreading
solution
and sub-
point of the protein and at a moderate
barrier
In fact, some proteins
glass
the elapsed
is to prevent a fraction
By having
strate at a pH close to the isoelectric
(ref. 5)
does not work as well as predicted
from adsorbing.
electrolyte.
for
unless
wetted
There do appear
to spread when they carry a net electrical does not contain
by Trurnit
by the presence
(ref. 6,7), the effect of which
cules which diffuse
are available
to the surface during
This method of spreading
is introduced
so that if a
then becomes a problem
and has the great advantage
ions, however, when this spreading by diffusion
spreading
(such as protein concentration,
ous film and length of rod).
of
or be convected
to flow down a perfectly
ensuring time.
spreading
for spreading
has been devised
surface.
of relevant
Quantitative
it will diffuse Several methods
is not usually
solution
quantitative
in which all the protein molecules
rod onto the water diffusion
as
is not as simple as that of conven-
are not always easy to achieve
spreading.
are taken.
an aqueous
chem-
measured
concentrations.
The secret for obtaining
is to create conditions
spreading
mimetic
properties
stable once they become attached
for spreading
of the protein does not adsorb,
away, resulting
special
two-dimensional
for furin protein
have an important
of membrane
and various
are extremely
to an interface, insoluble
promise
MONOLAYERS
protein molecules
protein monolayers
Monolayers
in
The use of spe-
that a resurgence
techniques
istry in that molecules
III.
holds sufficient
mole-
membrane
stored energy.
processes
seems likely to eventuate.
of precisely
arrays of cooperating
is the photosynthetic
into chemically
in such organized
thering our understanding
by complex
One example
is reduced and many proteins
may be spread quantitatively
spread
under these
conditions
simply by using a microsyringe
example,
bovine
solution
of pH 7.3 containing
composition
serum albumin
spread quantitatively
useful
B. Spreading
efficiency
Welcome) tative
solvent with
remain which
of isopropanol-water by Stallberg
is usually
monolayers
stable
and Teorell
is present
dissolve
the protein
are also soluble, may be spread.
in this solvent initially
vent at low temperature, become turbid,
Another
or are slowly in aqueous
ensuring
this may be avoided
solutions.
rapid mixing.
However,
clear,
ing ionic strength
concluded strength
and alcohol
of spreading
0.01, containing
Some proteins
concentration
solution
0.5% amyl alcohol
do not
It is preferable
the resulting
solution
solution
furof
as "denaturing the solutions is identical,
solution.
Small quanti-
in spreading
of different
of the spreading
to
sol-
are skeptical
that, providing
the effects
of human serum albumin
that the ideal spreading
contamination
of spread monolayers
have also been used to assist
lipids
protein-
is that the solutions
Some workers
or purely aqueous
et al. (ref. 12) have studied
quanti-
and then add the mixed
Should
experience
the behavior
spread from isopropanol/water
ties of isoamyl alcohol
mixed
because of their reputation
it is the author's
perfectly
(Burroughs
that certain
the pH of the aqueous
solvents
as protein
advantage
solution
by moving
purpose
With this solvent,
precipitated.
point of the protein.
efficiency
could
0.5 M sodium
the danger of bacterial
using alcohols
Minones
proteins
so that homogeneous
ther from the isoelectric
whether
do not
a more detailed
(ref. 9) as a general
is used.
in the case of purely aqueous
easily
are prepared
of the same
or "Agla" microsyringe
It has the advantage
achieved.
for long periods without
dissolve
agents".
for different
(60:40) containing
A micropipette
for proteins.
phospholipids)
phospholipid
This suggests'that
of spreading
its glass tip at the surface
spreading
(including
on a substrate
(e.g., bovine v-globulin)
solvents
was introduced
spreading
proteins
spread from a buffer
information.
A solvent consisting acetate
other
under these conditions.
study of the comparative yield
0.15 M sodium chloride
However,
(ref. 8).
For
with the tip in the surface.
(BSA) has been quantitatively
(ref. 10,ll).
variables solvent)
(HSA) monolayers.
(includ-
on the
These authors
is a buffer of pH 5.1 and ionic (v/v).
C. Crystals Many proteins convenient spreading constant
method
spread
rapidly
is not required surface
cult spreading
from crystals
to use for certain
purposes,
(such as where
pressure),
from solution
the method
placed at a surface. For example,
kinetic measurements
is rapid, avoiding
and the use of spreading
This is a
if quantitative are to be made at
the problem of diffi-
solvents.
In theory,
it
346 can also be adapted capable
for quantitative
of measuring
of protein
microgram
has a surface
spreading
quantities
Losses of protein
ever, the surface of dissolution,
concentration
D. Criteria
by dissolution
spreading
with a balance
A close-packed monolayer -2 in the order of 1 mg m . Therefore, to
spread a film of half this concentration Pg.
in conjunction
(ref. 13).
on an area of 400 cm2 would
require
into the bulk phase can also occur.
rate for many proteins
is much greater
20
How-
than the rate
so that losses are often minimal.
for quantitative
spreading
Since a large number of proteins which extrapolate rough indicator
give surface pressure (rr)-area (A) curves -1 to an area close.to 1.0 m'mg , this value can be used as a
of quantitative
than this almost certainly curred.
spreading.
A calculated
means that a loss of protein
If there is doubt about the efficiency
between
replicate
is to use several
spreadings spreading
Losses will usually concentration
of spreading,
is not a useful criterion. solutions
increase with
of different
increasing
of about 0.03% is recommended
protein
that the film is not under any appreciable completion
is a barrier
to the adsorption
the surface
against a surface where rier.
of spreading.
the monolayer However,
When protein
a different
n-A curve
MEASUREMENT
caused
AND INTERPRETATION
When a monolayer of the clean is defined
Vaiues of II are usualiy change
in interfacial
measurement
expressed
for monolayers.
and for many purposes
(or interfacial)
free energy
during and
pressure,
there
of the molecules
is spread in this way from the one
by compressions
with a bar-
a surface
pressure.
OF n-A CURVES
(y,) may be reduced
as the surface
It is
by the failure to take into account
is spread at an interface,
interface
pressure
a surface
is obtained
is spread at high area followed
this is an artifact
A protein
solution.
step (ref. 6), so that a fraction
the losses of protein when spread against
IV.
concentrations.
surface
When spread against
is not adsorbed.
pressure,
close agreement
for the spreading
important
smaller
has oc-
The best way to check
protein concentration.
following
reaching
area appreciably by dissolution
the initial
to a new value pressure
interfacial (y).
tension
The difference
(II); i.e.:
in mNm-' and are numerically equal to the -2 . II is thus the most fundamental
in mJm
Its units are those of a two-dimensional
it is analogous
to the more comn
pressure
three-dimensional
pres-
sure. Protein monolayers which the monolayer
may be easily manipulated is compressed
or expanded
by means of a film balance between
movable
barriers
or a
ln
341 flexible
ribbon and relations Interfacial
(n-A curves).
plate or a Cangmuir
between
pressure
interfacial
pressure
may be measured
float connected
to a torsion
and area established
by either a Wilhelmy
wire or force transducer.
main problem with the Wilhelmy
plate method
is the maintenance
angle.
angle caused
by spreading
Changes
in the contact
by the use of isolation appeared
(ref. 14).
clean glass,
holding always
mica or platinum)
it over a smoky Bunsen keep the plate wetted
elasticity. on either
Therefore,
particularly automatic
flame is convenient
A. Low pressure
to calculate
weights
remains
ecular weights
of small
Early workers
in composition
is more susceptible
Many film balances
leading
available
film balance
that employs
to leakage,
are arranged
for
(MCN Lauda, Germany
the iangmuir
float principle.
weights at very low values of n (below 0.1 mNm-' caused many workers More recently,
one for determination
to moderately
sized proteins.
phase transitions
analogous
in the field to
interest
has dwindled
of number-average
mol-
with other
In comn
in protein monolayers.
to the gaseous-type
monolayers
is not observed.
Nevertheless,
at sufficiently
act independently
and therefore
n-A relations
a colligative
high visco-
by dual barriers
to keep the film uniform
(ref. 15).
a legitimate
a region completely
molecules
compression
of proteins
there are no well defined
protein molecules reflect
instrument
on this region
but the method
(such as
be taken to
exhibit
of the plate from the vertical,
but this method
A commercially
molecular
but care should
Protein monolayers
pressures.
use of n-A measurements
focus attention
simpler
angles
regilon and molecular
The possible
Therefore,
tilting
at high interfacial
automated
has dis-
In the case of the Langmuir float, there are no prob-
contact
operations.
plate
Where the lower phase is an
a film balance which allows
measurements.
is a reliable,
polymers,
is used.
side of the plate is advisable
lems with changing
can be avoided
A mica plate coated with lamp black by
by the oil.
over the surface and to prevent to incorrect
solvents
which can be removed after the solvent
plate may be used.
The
of a zero contact
With water as the lower phase, a hydrophilic
roughened
oil. a hydrophobic
barriers
hanging
of
high areas, in this region
property.
(ref. 16) applied
an Amagat-type
equation
for imperfect
gases;
i.e.: n(A- Ao) = nRT
,
(2
where A is the area available Universal
gas constant
that the surface
aratingthe
and T the absolute
pressure
to a two-dimensional
temperature..
Bull
in this region was thermodynamically
osmotic
film-covered
to n moles of film, A, is a constant,
pressure
surface
than to a gas pressure.
R is the
(ref. 17) argued more equivalent The barrier
from the clean surface may be considered
sep-
as a
1
348 semi-permeablemembrane. A similar equation to Eq. 2 is obtained from which a plot of flA vs. i'l (extrapolatedto zero n) may be used to evaluate the molecular weight (M) from the relation:
(n A),,0 = ; RT
3
2 -1 where w is the weight of monolayer substance. If II is in mNm-l, A in cm g , then w is unity (1 g), R has the value 8.3x lo7 ergs per mole per degree and -2 T is the absolute temperature. Since A is normally expressed in mgm , this value must be converted to cm 2g-' by multiplying by 107. Molecular weights of many proteins (ovalbumin, gliadin, hemoglobin, f+lactoglobulin)calculated by the film balance method agree well with values obtained by other methods (ref. 15). One of the most thorough studies was carried out by Harrap (ref. 11) on the molecular weight of insulin over a wide range of pH and ionic strength. Some of the results are illustrated in Fig. 1 for a
subsolution of pH 2.05 and
differing ionic strengths.
Fig. 1. n-A and nA-n for insulin films spread on subsolutions of pH 2.05 and differing ionic strength. Curve a: r/ = 0.01; b: r/2= 0.1; c: r/ = 0.2; d: r/2= 0.5. Some values of Fredericq (ref. 1i ) (0) are also shown for t e range in which the two sets of data overlap (ref. 11).
2
At the lowest ionic strength (f= O,Ol), the nA-n plot is linear at all values, leading to an extrapolated value of 6,000 for the molecular weight of insulin.
349
At higher ionic strengths, the curves are convex to the IIaxis.
This behavior
may be compared to PV-P curves of real gases and similarly indicates aggregation due to the tendency of attractive forces to predominate over the electrical repulsion. Extrapolationof the linear portions in these cases thus gives false values for the molecular weight, although at sufficiently low pressures, the limiting value. Effects of aggregation
curves are seen to approach a comn
at a given ionic strength were greatest at pHs
near the isoelectric point (pH
5.6) and were absent only when the molecule carried a high net charge as for the example in Fig. 1 (pH 2.05, f 0.01). This work emphasizes the advantage of measuring molecular weights under conditions where the protein carries a high net electrical charge,
If this is not possible, measurements must be made
at very low surface pressures (e.g., below 0.02 mNm-' for the results in Fig. 1). Under these conditions, a very sensitive and stable instrument is required. Extremely clean water, free of surface active impurities, is essential for this work.
Providing these considerations are observed, the method is a rapid and
reliable one for estimating molecular weights of proteins. B. Equations of state An equation such as Eq. 3 is strictly valid only for molecules which behave as rigid disks. However, protein molecules in monolayers are unfolded and the extended chains have a degree of flexibility, A number of equations have been developed to describe linear polymers at interfaces by application of statistical thermodynamics. One of the best known,is the equation of Singer (ref. 19) based on the high polymer theories of Huggins (ref. 20) and Flory (ref. 21).
Singer's equation for a completely unfolded monolayer is:
rl=J$lnII-$\+$Q-$
(,I - 2A 1
iln-+
,
where t is the total number of segments per molecule, A is the area per segment available, A, is the limiting area per segment and z is the surface coordination number in the two-dimensionalquasi-lattice in the interface. For a completely rigid chain, z= 2 and for a completely random chain z= 4. Singer's equation predictsthat if z is appreciably greater than 2, curvature in the plot of IIA vs. IIoccurs due to entropic effects arising from the random arrangements and flexibility of the long chains, For very dilute monolayers, the equation has been found to show good agreement (ref. 22). Other contributions to equations of state which take into account surface activity coefficients (ref. 23), partial solution of polymer chains in the substrate (ref. 24) intermolecularcohesion (ref. 25) and electrical 'intermolecularrepulsion (ref. 26) are relevant to protein monolayers.
350 An equation of state of the virial type (ref. 27) has been applied to x-A measurements of several proteins (ref. 28). The data were interpreted to mean that the proteins BSA, hemoglobin and ovalbumin were more unfolded than transferrin and myoglobin. By measuring changes in n-A curves as a function of temperature and applying a suitably modified Singer equation, Llopis and Albert (ref. 29,30) have derived thermodynamic spreading terms for protein monolayers. Spreading entropy (S,) and enthalpy (H,) were plotted as a function of the area and were shown to depend markedly on the pH of the substrate. The spreading terms were in accord with the notion that cohesive forces play a more important role in y-globulin than in BSA monolayers. C. Configurationalchanges in compressed films When protein monolayers are compressed to higher pressures than those considered in the previous section, relaxation processes occur which are manifested by losses in surface area (if n is kept constant) or losses in surface pressure (A constant). Providing there is no desorption'(Part VI) or surface coagulation (Part IV-D), these losses are recoverable on expansion. The very large reversible reductions in area that are observed at high pressures (II>20 mNm_') can only be rationalized if it is assumed that parts of the molecules are forced out of the surface. It has been well established that adsorbed linear polymer molecules may exist as trains (segments attached to the surface), loops (segments extending into the adjacent phase) and tails (segments at the ends of molecules) which are also preferentiallydisplaced from the surface (ref. 31, 32). Monolayers allow the opportunity to study the distribution of attached and displaced molecular segments. In the case of proteins, the relaxation processes are often sufficiently slow to enable them to be easily followed experimentally. If A, is the initial area of a protein monolayer before any relaxation has occurred and A is the area after equilibrium has been established between adsorbed and displaced segments at a constant pressure II,then the ratio of adsorbed to displaced segments (r) is given by:
If the work required for a displaced segment to enter the surface is IIAA, (ref. 33), where AA, is the area per segment, then the variation of r with IIwill be given by:
(AG, - rrAA,) r = exp kT
,
(6)
351 where AGO is the difference ments at n=O.
in free energy between adsorbed and displaced seg-
Plots of log r vs. n for monolayers of catalase at several values
of pH are shown in Fig. 2.
Fi 2. Log r vs..n for monolayers of catalase on buffer solutions at 23'C: CopI pH 7.3; (0) pH 4.4; (Cl) pH 3.5 (ref. 33). The linearity of these plots are in agreement with the premises of Eq. 6. From the slopes and intercepts, hGs and &A, values may be calculated. A summary of these values for several proteins under different conditions of temperature and substrate pH is given in Table 1. Values of CAM fall In the range 0.9-1.5 nm2, correspondi~ngto an average size of 6-10 amino acid residues per segment, hGS values fall in the range 4,6-8,8 kT per segment for the proteins studied. In general, AG, decreases with IncreasIng electrical charge as the substrate pH moves away from the isoelectrjc point of the protein (i,e., the equilibrium distribution shifts in favor of the di,splacedsegments). This reflects a contribution to aG, of an electrical term of the form q,$, where q, is th, electrical charge per segment and J, Is the electrical potential in the plane of the charged groups. On the other hand, increasing temperature increases AG, in the range studied, favoring the adsorbed segments, Thls result indicates that adsorption of segments is accompanied by an @crease of entropy, Disordering processes that may be involved are the elPminatlon of ordered water around non-polar side chains and loss of secondary structure (e.g., o-helix) by the protein.
352 TABLE 1 Values of AG, (II= 0) and AA, for protein monolayers (ref. 33). Protein
Subphase
T-Globulin
buffer, buffer, buffer;
T-Globulin
distilled
Catalase
Ferritin
Because
Temp. (OC)
pH 7.3 pH 4.4 pH 3.5 water,
distilled
pH 5.4
protein monolayers,
water,
configurational
the most meaningful
the equilibrium equilibrium, quires
distribution
although
long periods
fore, when-film recording
equilibrium
n-A curve
construct
constant
represent
curve
the n-A relations
D. Surface
;55 25
7.7 8.8 8.2 7.5
kT kT kT kT
1.5 1.5 1.6 1.5
25
7.8 kT
1.2
occur relatively
is probably
and displaced
segments
is shown
(above 20 mNm-l).
rapid stepwise
of the essentially
There-
with automatic
An example
of an
Here it is compared
compressions
unrelaxed
re-
that these measured
parameters.
in Fig. 3.
from a two-dimensional
of monolayers
some study (ref. 35).
is an interesting
are made to
monolayer.
Theoretically,
to a three-dimensional phenomenon
a monolayer
to its bulk state) on reaching
pressure
(E.S.P.).
In certain
state when the E.S.P. energy barrier
cases, monolayers
is exceeded.
associated
This
with creation
occurs
because
spreading
in a supersaturated
of the need to overcome an
energy
in crystal
nuclei
(ref. 36). proteins
spread
from their crystals
true E.S.P.s are obtained
(Part
and none appear
to
should begin to
its equilibrium
may remain
of surface
state on com-
which has been subjected
substance
(transform
Although
of
This
pressures,
rates of compression
collapse
whether
in
the equilibrium
at lower surface
fundamental
in which
slowly
coagulation
The transition pression
employing
1.4
25
at higher pressures
for a protein
with an instantaneous
4.6 kT 5.1 kT 5.8 kT
of n-A curves are used, it needs to be realized
curves do not necessarily
1.3 1.3
point corresponds to the attainment
fairly rapidly
(many minutes)
balances
7.3 kT 6.4 kT 5.5 kT
255 45
changes
between attached
reached
s2 (nm 1
0.9 1.0 1.1
II-A curve
one (i.e., the one in which each measured
AA
(n=O)
pH 5.4
pH 5.4
conditions
AGS
25 25 25
distilled water, buffer, pH 7.3 buffer, pH 4.4 buffer, pH 3.5
these reversible
under different
III-C),
it is doubtful
to have been reported
for
363
I
I
100
50
equilibrium curve; Fig. 3. n-A curves of BSA on distilled water at 2o"c; -: ----: curve which would be obtained if no expulsion of segments from interface (ref. 34).
pure proteins. by surfaces,
Because
proteins
ties to the crystals solutions
of the drastic
form a coagulum
protein.
extent of coagulation strength.
conditions,
structure
induced
and proper-
This is seen when protein
often resulting in turbidity
in the formation
of solutions
of a
on shaking was made by Henson et al. (ref. 37).
during a one-hour
Of the thirteen
coagulation
molecules.
A study of the increase
large range of proteins
of protein molecules
with very different
formed by globular
are shaken under certain
of insoluble
unfolding
proteins
and a-lactalbumin
shaking
examined,
period varied with pH and ionic
ovalbumin
was least susceptible.
globin and pepsin are other proteins
The
was most susceptible
s-lactoglobulin,
that are relatively
to
hemo-
easily surface
coag-
ulated. A simple theory protein
a substance surface
has been proposed
monolayers
will remain stable as a monolayer
free energy,
the surface by splitting Ya=Yb+Yab
ya, and will continue
free energy
in the presence
it into three terms, + nc
provided
stability
films (ref. 38). it lowers
of
Briefly,
the initial
to spread until ya= ye, where ye is
of the monolayer.
ye may be interpreted
such that at equilibrium:
(6) free energy
and the non-aqueous
pressure.
between
the non-polar
phase, Tab is the interfacial
the polar groups and the aqueous sure or coagulation
governing
to duplex
,
where yb is the interfacial monolayer
for the conditions
based on their resemblance
groups of the
free energy
phase and II~ is the equilibrium
between
spreading
pres-
354 This equation predicts that once this critical surface pressure (II~)is reached, whether by compression of a monolayer in a film balance or by adsorption from solution (as occurs during shaking), transformationof the protein to an insoluble coagulated form will occur. The results of Henson et al. (ref. 37) confirm that spontaneous surface coagulation is frequently observed when protein solutions are shaken, this process creating large extensions of interface. Certain results agree with Eq. 6, at least semi-quantitatively. This is illustrated by some experimental measurements of flc(for ovalbumiln)as summarized in Table 2. TABLE 2 Measured coagulation pressures and separated free energy terms for ovalbumin at different interfaces (20°C) (ref. 38). Interface
ya (mNm-l)
%
(mNm-I)
'b (mNm-I)
Yab (mNm-I)
Air/water
72
27
35
10
Air/5M NH4Ac
67.5
17
35
15.5
Heptane/water
50
16
24
10
Benzene/water
35
12
13
10
For example, II~is lowered as y, decreases, so that coagulation occurs more readily at O/W than at A/W interfaces. Values of yb and Tab were calculated from contact angle measurements on Langmuir-Blodgettfilms removed from a closepacked ovalbumin monolayer, The differences in surface coagulation behavior between proteins (ref. 37) must reflect variations in composition or structure which can be interpreted in terms of the yb and yab terms. These rather large differences are observed despite the great similarity in n-A curves between proteins, Sensitivity to surface coagulation may be an important property in biological processes and, for this reason, a closer study of the phenomenon by the monolayer technique seems warranted, One interesting observation which illustrates this is that, in solution, fully oxygenated sickle-cell hemoglobin (HbS) is much more susceptible to precipitation by shaking than normal hemoglobin (HbA), despite the otherwise great similarity in structure and properties (ref. 39,40). Other studies have focussed on the surface deactivation of cellulase by shaking and its prevention by surfactants (ref. 41) and the denaturation of e-lactoglobulinand its subsequent renaturation by dissolution in dilute acid (ref. 42).
355 OTHER TECHNIQUES FOR STUDYING PROTEIN MONOLAYERS
V.
A. Surface potentials The change in electrical potential between two electrodes (one in the aqueous subsolution and the other in the air above the surface) when a monolayer is spread is called the surface potential (AV) of the film. Two methods of measurement are in common use: 1) the ionizing electrode; and 2) the vibrating plate (ref. 43). Surface potential measurements on protein monolayers can give information on the homogeneity of the film and the orientation of dipoles in the film.
In principle,
they can also be used in conjunction with surface pressures to follow the kinetics of reactions occurring in the film.
The influence
of pH on the AV-A curves of proteins is very marked. Near the
isoelectric point and at high areas, the surface potential fluctuates wildly as the electrode is moved across the surface (ref. 44,45), showing the film to be heterogeneous. Because of the low net charge on molecules, intermolecularattractive forces (van der Waals forces, hydrogen bonding) operate to cause the formation of discrete clusters or "islands", separated by regions of very dilute gaseous film. On compression to lower areas, the surface potential becomes uniform over the whole surface, showing the film to be homogeneous (ref. 45).
Sim-
ilarly, as the pH is moved away from the isoelectric point, the region of instability of AV disappears even at the highest areas. An equation that has been used to assist in the interpretationof surface potentials is:
AV
q
4Tnu
(7)
,
where n is the number of dipoles (usually molecules) per unit area and u is the effective surface dipole moment in the perpendicular direction. The term p may in turn be interpreted by: r!=:cose
,
(8)
where E is an intrinsic moment making an angle e with the vertical. Eq. 7 has been derived by analogy with an equation attributed to Helmholtz for the potential difference between the plates of a parallel-plate condenser, assuming a surface film to consist of a planar array of dipoles. The limitations of this analogy have been stressed (ref. 46); for example, it is assumed that the dielectric constant is unity and the contribution to AV of reorientation of subphase molecules is ignored. However, the equation has been found to be useful. Frequently, the term AAV (which is proportional to p) is plotted as a function of A. By studying the variation of AV with pH for protein monolayers, it has been established that it is the contribution of the ionogenic side chains which is pH dependent (ref. 47).
Fig. 4 shows a comparison between the AV-pH curve at
356
2
6
4
a
PH Fig. 4. II-pH and AV-pH curves for insulin films on subsolutions of ionic strength; r/2= 0.01, together with the electrometric titration curve (ref. 45).
an area of 2 m2mgs1
for an insulin monolayer
0.01 and the electrometric*curve Epstein
(ref. 48).
on a substrate
for this protein
The similarity
for different
groups
is apparent
face pressure
at the isoelectric
is striking
in the AV-pH
measured
of ionic strength by Tanford
and
and the pH range of ionization curve. The minimum
point of the protein
in the sur-
is also illustrated
in
Fig. 4.
In general, AV and AAV increase with decrease of area as a protein monolayer is compressed. being oriented
Increase of AAV suggests more vertically
becomes close-packed tends to plateau pression
and segments
More detailed
compressed
films.
B. Surface
rheology
the manner
Two types of surface
studies
shear and dilational.
whereas
bulk or expansion
viscosity
high surface
dilational
by the flow through
are
AV com-
potential
changes
should prove help-
changes
occur
in these
for protein monolayers,
shear viscosity interfacial
of three-dimensional
(ns) has been measured
pressures
have been measured
Two-dimensional
three dimensions,
on further
of how the surface
in which configurational
viscosity
side-chains)
once the monolayer
begin to be pushed out of the surface,
films are held at constant
ful in interpreting
cosity
(ionized
However,
(ref. 45,49) and AAV falls off dramatically
(ref. 50).
as protein
that dipoles
on compression.
is analogous
viscosity fluids.
to that for
corresponds
to the
Shear surface
a canal under a surface
ViS-
357 pressure
qradient
(ref. 51) or by the torque on a ring or cylinder
(ref. 52) or oscillating
(ref. 53) in the surface.
fined in terms of the differences similarly
it is not strictly
cules from that of substrate protein which
studied,
viscosity
rate).
viscosity
is treated
energy
barrier.
where
The expression
to another
obtained
of the non-
Joly applied
of flow units
the theory
In this theory,
(normally
over an intermediate
for the coefficient
above
on shear
mole-
activation
of surface
viscosity
is:
k exp
(AG+ WA) kT
h = Planck's
is associated
(91
' constant
with:
and AG is
molecule
the activation
1) the work required
ently large for the molecule
done against
to form a hole in the surface
Joly concluded pearance
pressure
their size practically calculation
behavior
independent
of the activation
the area of the elementary based on the Moore-Eyring
of ns for all proteins
are summarized
Joly determined
flow units.
calculated dently,
independently
the molecules
in which
As a result,
(ref. 53) that keto imido hydrogen Thus, polyproline
gave no measureable
appear
ns, while
bonding
for other
contributed
These
and the value
in solutions
of molecular Evidence
largely
Evi-
so that segments
This is similar
no keto imido hydrogen polyaminoacids
acid
good agreement.
to diffuse
independent
65 and 69 kJ mole-‘.
in which
120 i2)
flexible
move as units.
AG and ns are approximately
Values of AG (Table 3) fell between
viscosity,
for AA (loo-
are sufficiently
long chain hydrocarbons
but still values of AA,
of plots of log ns vs. n,
The values
(on the average)
approach
and one polyamino
by Joly (90 fi2) are in remarkably
of 6-8 amino acid residues the manner
respectively,
in the monolayer
From a direct
(ref. 53) calculated proteins
and
a value of about 90 i2 for
Using a different
theory, MacRitchie
in Table 3.
at the point of ap-
of the nature of the protein.
the area of the flow unit and AG for several
results
to break all bonds
work that has to be
that all the flow units were submolecular
energy,
from the slopes and intercepts,
suffici-
to move the
to create a hole.
from the constancy
of non-Newtonian
the work required
naA is the additional
molecules.
the surface
free energy at zero II. AG
to move into; and 2) the work required
into the hole, this term including
formed with neighboring
56).
pressure,
(ref. 55) to the data.
as a movement
position
surface and
of film mole-
depended
ns at the point of appearance
of Moore and Eyring
from one equilibrium
=
surface
viscosity
was of the same order of magnitude.
the flow of a monolayer
%
and different
(i.e., calculated
for all proteins,
cules)
(II,)
the contribution
de-
(ref. 54) showed that for each
Joly
there was a well defined
viscosity
for surface
the clean and film-covered
to separate
molecules.
was non-Newtonian
However,
Newtonian
between
possible
rotating
As with IIand AV, qs is
to (ref.
weight.
was obtained
to the surface bonding
and proteins
is present
ns decreased
358 TABLE 3 Calculated values of AA and AG for proteins and one polyamino acid (ref. 53) Protein
AA
(nm*)
(kJ’Zole-1)
Polyalanine y-Globulin Pepsin
1.5 160 34
1.05 1.10 1.20
8; 67
BSA Lysozyme
70 15
1.00 1.15
:;
dramatically with increasing electrical charge. Assuming a flow unit of seven amino acid residues, the maximum number of hydrogen bonds which could contribute to AG would be seven, remembering that each residue forms two bonds but that each bond is shared by two units. A hydrogen bond energy of just over 9 kJ mole-' would then account for most of the measured surface viscosity. Measurements of nd are normally obtained from methods based on either continuous (ref. 57) or periodical (ref. 58) compression or expansion of the monolayer covered surface. In recent times, more attention has been given to dilational than to shear surface viscosity of protein monolayers. This is justified because interfaces are more often subjected to dilational rather than shear stresses. Interfacial dilational measurements would thus be expected to be relevant to emulsion and foam stability and to biological membrane systems. Pertinent studies are those of the apoprotein of the Folch-Lees proteolipid (FPi) from myelin (ref. 59) and of mixed tubulin&lipid monolayers (ref. 60).
Protein monolayers exhibit
viscoelastic rather than pure viscous behavior. For FPi monolayers, nd increased with IIin the range 37- 50 surface poise. The results indicated that,if during compression of a mixed monolayer of FPi with dipalmitoyl lecithin, energy dilssipationoccurs, it may be assigned to the protein constituent. This may be the situation in biological membranes and the alveolar lung surfacant. It was suggested that the energy dissipation results from changes in conformation of the FPi molecules (such as formation of loops and tails). In view of the previous discussion (Part IV-C),
this appears to be a realistic conclusion.
For the peripheral membrane protein, tubulin (the subunit protein of cytoplasmic microtubules), the relaxation time calculated from dynamic measurements was about five times lower than that of other protein films. The suggestion was made that this may be related to the role of microtubules in conferring mechanical stability to membranes and other cellular structures. C. Transfer of film In certain cases, it is advantageous to remove protein films after compression for more convenient examination elsewhere, For example, this method has been
359
used to study the concentration of radioiodinated BSA at the surface (ref. 61) after removal on glass slides. If a clean glass slide is lowered through a surface containing a compressed protein monolayer, no change of surface pressure is observed. On raising the wetted slide, a decrease of IIoccurs as monolayer is transferred to the slide. If the pressure is maintained constant, comparison of the decrease in area of the monolayer with the surface area of the slide shows that the film is transferred quantitatively (i.e., a transfer ratio of unity). For radiolabelled proteins, concentrations can then be determined by direct measurements in a scintillation counter. One precaution to be observed is to allow for any decrease in radioactivity,greater than the normal decay, caused by the surface (see Part VI-B). A number of different techniques have been used to study the conformation of protein and polypeptide monolayers after removal from the surface, either as collapsed or uncollapsed films. Loeb and Baier (ref. 62) deposited polymethyl glutamate (PMG) monolayers at constant pressure directly onto germanium prisms suitable for multiple internal reflection spectroscopy in the infrared. Spectra characteristicof both the a-helical and B conformdrtions were found; they were independent of the degree of composition but depended on the spreading solvent. Films spread from chloroform-pyridinesolutions containing at least 60% chloroform and collapsed onto AgCl plates for study by direct transmission IR spec-1 amide 1 and 11 absorption peaks at 1654 cm-l and 1550 cm ,
troscopy showed the
respectively,which is characteristic of both the a-helical and random coil conformations. As the pyridine concentration in the spreading solvent was increased,the monolayer spectrum showed increases in intensity of bands at 1625 -1 -1 -1 cm and 1520 cm at the expense of the 1654 cm and 1550 cm-l bands, respectively. Amide 1 and 11 absorptions at 1625 cm-' and 1520 cm'l bands are associated with the extended chain 6 configuration of polypeptides. The behavior is illustrated in Fig. 5
for films that had been removed after compression beyond
the monolayer collapse point. Similar results were obtained for this polypeptide by Goupil and Goodrich (ref. 63) who also used a suitable choice of spreading solvent to vary the conformation and infrared spectra of films transferred OntO
germanium prisms by the Langmuir-Blodgettmethod, They also showed how sur-
face viscosity measurements could be used to differentiate between the a and 8 conformations. It was postulated that a surface film of folded, independent rods (a-helix structure) should be less viscous than a coherent interlocked
chains
(B-structure).
set of unfolded,
This appeared to be the case,
The tempera-
ture dependence of the surface viscosity was different for the two conformations. The B conformation was characterized by a high surface viscosity which fell with increasing temperature, possibly due to weakening of the intermolecularhydrogen bonding. On the other hand, the surface viscosity of the polypeptide in the u
360
Wavenumber
cd
Fig. 5. Infrared spectra of collapsed films of PMG spread from _. spreading solutions of varying chloroform/pyridine content. Numbers on the figure refer to percent chloroform in the spreading solution (ref. 62).
form showed a relatively
low surface
increasing
This was thought
temperature.
viscosity
which
increased
irreversibly
to be due to conversion
of the
with
CL to
the B structure. An extensive
study of the conformation
moval of compressed
surface
By means of infrared
of synthetic
films has been carried
spectroscopy,
polypeptides
out by Malcolm
it was shown that material
face films of a range of polypeptides
was in the a-helical
addition
introduced
method
to infrared
spectra,
for monitoring
of requiring information. men is low.
Malcolm
the conformation.
very small amounts Infrared
spectra
Electron
of material
electron
after re(ref. 64,65).
removed
diffraction
diffraction
The study of transferred
In
as another
has the advantage
yet giving detailed
conformational
are more useful when the crystallinity
bility exists that conformational
from sur-
conformation.
of a speci-
films is an indirect method and the possi-
changes
may occur on removing
the film from the
surface,
In order to check this point, Malcolm developed a method for studying
deuterium
exchange
in polypeptide
monolayers
peptides were spread at the surface sion, dried and the infrared mined
from the relative
spectra measured.
strengths
(ref. 65).
for measured
times,
The N-deuterated
poly-
removed after compres-
The extent of exchange was deter-1 of the NH and ND stretching bands at 3300 cm
361 and 2400 cm where
-1
confirmatory
Rates of exchange
, respectively.
hydrogen
bonding
evidence
for the a-helix where
bonded and would not be expected Most of the conformational
form, proteins
only partially
studies
red spectra of paramyosin
polypeptide
amounts
of the molecule
technique
known, whereas
as a rough
index of conformation.
found for transferred compared
after spreading
proporthe infra-
contains
and
is one of
appreciable
The ratio of absorb-
to that at 1655 m-l (a and random) was taken Values
for this index of 0.6 and 0.9 were
monolayer-s of paramyosin
and s-lactoglobulin, solution
results were taken to mean that the B structure proteins
in
as monolayers
Paramyosin
at 10 mNm-'.
s-lactoglobulin
to 1.1 for residue from the spreading
by spreading
pro-
have their chains
larger or smaller
in the B and random chain forms.
ance at 1635 cm -' (B configuration)
on model
Loeb (ref. 67) has measured
and B-lactoglobulin
proteins
intramolecularly
chains may exist exclusively state generally
form, with relatively
by the Langmuir-Blodgett
the most helical
groups are
with water molecules.
in their solution
in the a-helix
this was taken as
to date have concentrated
tions in the 6 form or random structure.
transfer
peptide
to exchange
Whereas
teins, the polypeptides. the a-helix
were much slower than in polymers
to water can take place; therefore,
respectively, The
of s-lactoglobulin.
does not appear
at the surface and that the a-helical
to be induced
structure
is main-
tained as found for the polypeptides. Optical
rotary dispersion
(ORD) and circular
to study the confortmttion of polypeptides CD has been applied
to the study of corresponding
plates by the Langmuir-Blodgett aligned
identically
L-alanine
the film balance.
the orientation
True OD spectra, at numerous
The results were consistent in the a-helical of the incident
light.
copy after transfer
monolayers
(ref. 68,69).
exhibited
deposited
and unlabelled
expected
has been examined to quartz
plates
and B-sheet
molar absorptivity
protein.
a planar sample
explained
or changes
effects
light beam.
of polypeptides to the direction
by UV and CD spectros(ref. 69).
CD spectra
in the film oompared
of 11,950
It was proposed
of
were obtained
1 mole cm"
to values of 9,100 and 9,600 for isotropic
from the effect of orienting by solvent
properties
with the helix axis perpendicular
amount of a-helix
194 nm was found compared
which could
chains on the surface
about the axis of the incident
B-lactoglobulin
on quartz
films of poly-
free of the linear component,
with the optical
An enhanced
Recently,
When all plates were
linear dichroism
of the polymer
from a film balance
an increased
of labelled
angles
conformation
that in solution,
(CD) have been used
in solution.
in the light beam of the spectropolarimeter,
be used to determine
suggested
method
and poly-y-methyl-l-glutamate
on films oriented
dichroism
and proteins
to
at 193-
solutions
that this results
mainly
in the light beam and could not be
in conformation
of the protein.
Measurement of contact angles after transfer of protein monolayers to Langmuir-Blodgettslides is another technique which yields useful information on the orientation of polar and non-polar groups (see Part IV-D). D. Direct optical methods Spectroscopy has been a powerful tool for studying molecular structure in bulk solution. Because of the small amount of material present in a monolayer, some method must be used to amplify the spectral signal. One approach is to use parallel mirrors to pass light through the film many times. An example of this technique applied to protein monolayers is the interesting study of films of oxyhemoglobinsA and S at the air/water interface (ref. 70). As mentioned (Part IV-D), these hemoglobin variants display different surface behavior as evidenced by their tendencies for mechanical precipitation. Absorption maxima were shifted from the solution value of 415 nm to 419 nm for both HbA and Hbs, consistent with a conformationalchange in the direction of greater unfolding, although shifts were the same for each. These Soret band maxima did not shift on compression of the films. It was noted, however, that surface isotherms were more expanded for HbS than HbA, indicating a greater unfolding. Ellipsometry is a sensitive method for measuring the thickness and refractive index of thin films at surfaces. The technique has been mainly used for studies of films adsorbed from solution (ref. 71,72) but can be applied equally well to monolayers. De Feijter et al. (ref. 73) compared measurements of surface concentrationsof protein monolayers by ellipsometry with results for two other independent techniques: 1) a spreading technique by which known amounts of protein are spread on a known area of surface; and 2) a radiotracer method using radioactively labelled protein. For B-lactoglobulin,two different spread-2 calculated from the amount ing experiments gave values of 0.98 and 1.09 mgm -2 spread and 1.00 and 1.05 mgm calculated from ellipsometer measurements. For -2 -2 by the radiotracer a-casein, ellipsometry gave 2.5 mgm compared to 2.7 mgm method. From these figures, the reliability of ellipsometry is evident.
In view of the inherent uncertainty in drawing conclusions from measurements on films transferred from monolayers (particularlyin relation to conformation determinations),there is a need to develop further the direct methods for examining protein films _in situ. These methods have the great advantage that the films can be manipulated and measurements made as a function of different variables such as surface pressure and time. Techniques such as those developed by M6bius and co-workers, including enhanced light reflection (ref. 74) for direct measurements as well as quenching of fluorescence (ref. 75) for transferred monolayers may prove valuable for studying mixed monolayers and two-dimensionalreactions of proteins.
363 VI.
DESORPTION The question
FROM MONOLAYERS
of whether
a controversial
adsorption
that it is an irreversible monolayers,
despite
and Schaeffer
process
of a monolayer The equation
= akT
increase
per cm* at the surface
with the film. 2 -1 on the surface 1 m mg
and c is the concen-
According
There-
10s8.
to this, an increase of film pressure
between
of compressed
and has a molecular
o would have a value of 2.85x
of the film by a factor of 10 g5. The
the solubility
lack of correspondence
the great stability an argument
to the
in equilibrium
fore, at 20°C, dln c= 220 dn. of 15 mNm -' should
pressure
(11)
(e.g., ovalbumin),
of 35,000
from
Langmuir
solution.
theory of the effect of surface
,
in solution
apparent
held belief proteins
(ref. 77) (based on the Gibbs equation)
For a protein which occupies weight
of desorbing
used was:
where u is the number of molecules tration
or not has been
a widely
of many in aqueous
a general
case of proteins.
is reversible
that has prompted
is the difficulty
the high solubility
(ref. 76) applied
on the solubility
dn/dlnc
of proteins
One observation
topic.
the predicted
solubility
protein monolayers
in support of the irreversible
increase
has been considered
nature of protein
and to be
adsorption.
A. Kinetic measurements Langmuir of proteins
and Waugh
and their enzyme
sure displacement
pressure
expulsion solubility
effects of increasing
of portions involves
displacement
of molecules
desorption
on monolayers
They distinguished
between
pres-
is equivalent
in Part IV-C,
discussed
of complete
times in solution
of monolayers
of compression
Pressure
solubility.
digestion
sures on the solubility
the effects
(pepsin) digests.
and pressure
to the reversible whereas
(ref. 78) studied
molecules.
and increasing
of insulin and its digests
The
surface
pres-
are summarized
in Table 4. With increasing
digestion
These are the figures reference
pressure
time, losses of material
in the first row at n=mNm-',
for measuring
refer to the loss of monolayer originally
For ovalbumin,
relatively
initial molecular A preliminary
as a percentage
lower proportions
conditions
Other figures
of the total material
to compression
for 10 min. periods.
of pressure-soluble
than for insulin,
theory
consistent
material
were
with its higher
to explain
This theory
pressure predicted
solubility
was proposed
that polypeptides
If pressure solubility
is observed
between
by Langmuir
should show pres-
in the range II= 5 to 10 mNm-' when the molecular
1200.
increased.
weight.
(ref. 78).
sure solubility proximately
expressed
spreading
losses of monolayer.
spread when films were subjected
found under comparable
and Waugh
permanent
during
which was taken as the
weight
is ap-
II= 20 and 25 mNm-',
364 TABLE 4 Losses of monolayer for insulin and its peptic digests during spreading and 10 min. compressions at different surface pressures. The first row (1 mNm-I) gives the amount of protein (as a percentage of total spread) lost during spreading. The last row (residue)gives the amount of monolayer (as a percentage of total spread) remaining after spreading and compression at each of the six pressures (ref. 78). --."-1 (mNm )
Time of digestion 21
0
: 10 15
!*': 5:2 3.0 87.0 --
a molecular
weight of ca. 1700 is indicated.
tion products
of insulin
had molecular
The first quantitative
measurements
tein monolayers
were reported
Because of the superimposed pressure sured
displacement
a given pressure. face pressure
relaxation
by Langmuir
higher surface 79) therefore of area. constant
However,
process described
and Waugh),
desorption
(15 mNm-' and above). pressure
for a measured
The permanent
(called
be simply mea-
of surface
recoverable
area at
at low sur-
losses are only observed Gonzalez
(A,),
and MacRitchie
at
(ref.
permanent
losses
After maintaining
time, the surface was completely
(area A).
in Part IV-C cannot
of 5 mNm-I to monitor
at 5 mNm-I
from pro-
(ref. 79) for BSA.
by the decrease
losses of area are totally
The area was first measured
that the degrada-
in the range l,OOO- 2,000.
and MacRitchie
substances)
chose a reference
pressed to 5 mNm-'
::: 4.5 3.0 1.7
of the kinetics of desorption
(10 mNm-I and below) and permanent pressures
70 4.5
It was concluded
weights
by Gonzalez
(as with other monolayer
52
46 1.4 4.0 10.9 7.6 4.3 25.8
i.7
22: residue
in hours
expanded
n
and recom-
loss of area was then given by
A,-A. Two checks were used to determine due to desorption.
tion of time at a fixed pressure BSA in the subphase.
whether
the permanent
concentration
the rate (in the presence system continued
the idea that desorption
Initially,
gentle
of
the kinetics of
stirring
the rateand with
the rates were the same but after a time,
of stirring) to decrease
increased,
The second check was to compare
time curves at this same value of IIwith and without no BSA in the subphase.
as a func-
of 25.6 mNm-' with varying concentrations
As the subphase
area loss slowed as shown in Fig. 6.
stirred
area losses were
In the first, rates of area loss were measured
became constant
while that in the un-
with time (Fig. 6).
was the cause of the permanent
The results area losses.
support
365
P
I
1
40
80 (min)
Time Fi
. 6. Rate of desorption-time curves for BSA monolayers at 25.6 mNm-I pressure. 3 : no protein in subphase no stirring; (o ): stirring; (A): 0.008% BSA in
!.:bphase; (A):
In desorption
0.05% BSA in'subphase;
from monolayers,
between the monolayer
an equilibrium
and an adjacent
In the absence of convection layer
(0): 0.10% BSA in subphase
(which is maintained
is usually
thin subsurface
and back-diffusion,
at constant
t, is then given by the corresponding
established
diffuse
from this
to the bulk phase,
n, of molecules
equation
rapidly
layer of bulk solution.
molecules
concentration)
The number,
ially at zero concentration,
(ref. 79).
that desorb
from classical
init-
in a time,
diffusion
theory
(ref. 80):
n = 2c,
IT I i DJ
l/2
iw
,
where co is the subsurface is 3.14.
concentration,
The rate of desorption
D is the diffusion
at any time, t, follows
coefficient
and
II
of
by differentiation
Eq. 12:
t-1/2 Gonzalez several
(13)
and MacRitchie surface
did not extrapolate diffusion
(ref. 79) plotted 2
pressures. to zero.
This is consistent
but with an energy barrier
the slopes,
vs. t-1'2 for BSA monolayers
The plots were linear although
with a process
to the desorption
values of co (the steady state sublayer
lated and are shown in Table 5, together
at
lines of best fit controlled
step (ref. 81).
concentration)
by
From
were calcu-
with values of co, at corresponding
366 TABLE 5 Calculated
subsurface
concentrations
n
of BSA (ref. 79) C
cO
(from &d;;ption
(mNm-l)
(from adiorption isotherm)
(g cms3)
(gem -3 1
28.8
1.28 x 1O-6
5.5 x 10-2
27.2
1.94 x 1o-6
2.2 x lo-2
25.6
4.86 x lO-7
9.1 x 10-3
24.0
2.62 x lO-7
3.8 x lO-3
22.4
5.7 x 10-8
1.6 x lO-3
pressures,
from the equilibrium
ancy between
adsorption
isotherm of BSA.
the two sets of values for co is confirmation
The large discrepfor the existence
of an energy barrier at the surface. Returning protein
to the results
in the subphase,
and the desorption interface, diffusion
shown in Fig. 6, it can be appreciated
the concentration
rate would be expected
there is a stationary only.
tionary
to decrease,
conditions.
layer, where material
we can calculate
in thickness.depending
Near every occurs
by
on the type of inter-
For the results of Fig. 6, the introduction
gradient
is carried
the thickness
is lowered
as observed.
causes the rate of area loss to become constant
At this point, the concentration
that with
near the surface
layer through which mass transport
This layer varies
face and the stirring of stirring
gradient
has extended
after about 30 min.
to the edge of the sta-
away by convection.
of the diffusion
layer
For this example,
(6) from the equation:
(14) Using values of 6.0 x 10e7 cm2 set -' for D, the diffusion coefficient of BSA -7 -3 (ref. 82), 4.86 x 10 for co (from Table 5) and zero for c, the effective g cm concentration
at the edge of the diffusion
lated for 6.
Values for the width of the stationary
have been found to vary between about 0.03
mm where
stirred
vigorous
subphase
We may utilize -1 to estimate mNm the equation:
stirring
thus appears the results
layer, a value of 0.08 mm
1.0 mm for unstirred
is used (ref. 84).
is calcu-
layer in aqueous systems
solutions
(ref. 83) and
The value of 0.08 mm for a
to be of the right order. for the steady state desorption
the magnitude
of the energy barrier
of BSA at 25.6
to desorption
by applying
367 dn _ 'o --R1+R2 dt where
(15)
’
RI is the diffusional
resistance
and R2 is the interfacial
is equal to i and thus has a value of 1.3x lo4 set cm for g
and co gives a value for R2 of 2.4x lo* set cm
the kinetics
of desorption
in controlled probable
mainly
to a cooperative
must leave the interface
B. Radiolabelled
protein
bility of monolayers
as it provides
losses of compressed
monolayers
the absolute
rate
It appears
resistance.
step in which all segments
of a
a reliable
method
for studying
way of determining
configurational and labelled
changes
the sta-
if permanent from the surface
or coagulation.
with 1251 was carried
A out by
(ref. 8). Permanent losses of area were -1 of 18 mNn and above. Monolayers were compressed
and maintained
then expanded
and recompressed
the permanent
loss of area before
samples
compression
was measured
at constant
to a reference
of the monolayer
and radioactivity
repeating
pressure pressure
in r~ corresponding
together with the measured remained
successive
For example,
for 20 min. periods, -1 to determine
of 10 mNm
the cycle.
For the radiolabelled
were removed on glass slides
in a scintillatian
counter.
cycles are shown in Fig. 7 for radiolabelled
Radioactivity following
although
simultaneously.
is a valuable
of BSA unlabelled
at pressures
to a given pressure
decreases
Therefore,
RI
of values
and Ter-Minassian-Saraga
only observed
protein,
.
are due to removal of molecules
such as molecular
study of monolayers MacRitchie
Substitution
proteins
The use of radiolabelled
or to processes
-1
resistance.
.
of diffusion,
by the much larger interfacial
that R2 is related
given molecule
show the influence
-1
(see Part V-C)
Examples of the
BSA at 21 mNm-'.
The
to the removal of slides at 10 mNm-' are shown -1 -2 counts in min cm for the transferred films.
constant
compression
within
experimental
cycles,
error at all pressures
as also did film compressibility,
after
losing 68.6% of the film at 27 mNm-I, the specific activity -1 -2 counts min cm compared to an average value of 3620 counts
was 3720+400 -1 $2 min for measurements gimes) at 10 mNm-'.
on 18 slides of BSA films
This is consistent
the remaining
monolayer
from analyses
of radioactivity
being unchanged.
(removed after varying
re-
with an area loss due to desorption, Confirmation
in the subsolution
of desorption
was obtained
after a known loss of material
from the surface. From results
such as those in Fig. 7, it is possible
to separate
sible and irreversible
area losses at a given pressure.
tracting
loss (from the area change at 10 mNm-')
the permanent
loss (measured at the high pressure over the 20 min. period). shown in Table 6.
the rever-
This is done by subfrom the total Some values are
368
125 Fig. 7. Compression-expansion (not shown) cycles for I-labelled BSA monolayer held for 20 min. periods at 21 mNm-I. A is in arbitrary units. Surface area may be calculated from the fo mula: area= 8.33At10.7 cm2. Amount of protein spread= 80 1 of a 0.62 mgml -1 solution. The numbers correspond to the measured counts min- y cm-2 for the films transferred onto the glass slides (ref. 8).
TABLE 6 Reversible changes tervals at various
and irreversible losses of BSA monolayers surface pressures (ref. 8) Decrease
II
(mNm
-1
of film area
Decrease (total)
during
20 min. in-
(% of total) Change++ (reversible)
Loss+
:Y
22 51.5
:
44.5 21
z': 30
80.4 71.5 82.2
9 15 18
62.5 65 65
'Determined
tt
Difference
One
at n= 10 mNm-' between
total decrease
and loss (columns 2 and 3)
factor that needs to be allowed
proteins
is the possible
relatively
for in surface
rapid decrease
natural decay rate) when they remain at the surface of about 2% per hour was reported face catalyses
a reaction
stancy of specific losses
implied
in which
activity
in this work. iodine
using
in radioactivity
It was suggested
BSA film following
(calculated
I-labelled (above the
for long periods.
A decrease
that the sur-
is lost from the surface.
in the labelled
that the tagged molecules
studies
The con-
irreversible
to be only one in 90 of
area
369 the total) desorbed
at the same rate as the untagged
found that the sample of labelled above pressures altered
of 20 mNm
the protein
C. Desorption
in biological
monolayer.
sample had
y-globulin
and catalase
A striking
the mixed
films are initially
The area coverage
of insulin
The rate then deviates
and catalase.
is one
identical
from the surface,
(T-globulin
studied
is that the rates from
was
to 25- 30%.
film, the area approaching
value, the desorbable
(min
after spreading
is reduced
or catalase).
leaving a monolayer
Time
of 17.5 mNm-I,
to those from a pure insulin monolayer.
until the coverage
at this moderate
and
is il-
loss of area over long
behavior
in the mixed films immediately
protein
for from
B-lactoglobulin The behavior
At the pressures
show no permanent
from that of the pure insulin
that of the non-desorbable
tively removed
(ref. 85).
of insulin at a pressure
feature of the desorption
50% and the rate is constant
ing the film pressure
of two proteins,
has been studied
with y-globulin
periods.
processes
(lipids and other proteins)
useful to know how a pure protein desorbs
in Fig. 8 for the desorption
alone and in admixture
about
treatment
systems and industrial
The desorption
from mixed monolayers
(~20 mNm-I),
faster than the unlabelled
that the labelling
compete with other compounds
It is therefore
a multicomponent
lustrated
BSA desorbed
This suggests
it was
in some way.
situation
proteins
the interface.
insulin,
.
However,
from mixed monolayers
The practical in which
-1
ones.
Thus, by maintaininsulin
is effec-
of the pure component
that
1
Fig. 8. Log A-time plots for desorption of insulin from its pure monolayer (0); from a mixed monolayer with T-globulin (0); and from a mixed monolayer with catalase (0) at 17.5 mNm-I on pH 7.3 buffer. Dashed line corresponds to area of pure v-globulin and catalase monolayers (ref. 85).
370 is non-desorbable
at that pressure.
for mixed monolayers 86).
It evidently
the sublayer systems
arises
This behavior
desorbable
because
to date,is
layer providing
the concentration
practically
its surface coverage
low this coverage,
is greater
to maintain
at different
surface
for mixed
films are relevant
occurring
in blood clotting.
cesses across
interfaces
in
and, for the
from the monolayer concentration.
are summarized
to competitive
protein
pressure
alone and in admixture
pressures
(ref.
of the mono-
than 25- 30% of the total.
the sublayer
adsorption
Some results
in systems
The results
such as those
for transport
where multicomponent
Be-
to the
with non-desorbable
in Table 7.
They also have implications
or membranes
compounds
of the composition
the rate of supply of molecules
is insufficient
to be quite general
of desorbable
by the surface
independent
for films of insulin and B-lactoglobulin components
appears
and non-desorbable
(co in Eq. 12) is determined
studied
sublayer
containing
pro-
films are present.
TABLE 7 Rates of desorption of insulin and B-lactoglobulin surface pressures on pH 7.3 buffer (ref. 85). Monolayer
from monolayers
Rate of desorption 15+
Pure insulin Insulin - DPPC Insulin - y-globulin Insulin - catalase
17.5+
zo+
pressure
The displacement
and catalase
trolling
desorption;
Whereas
(Fig. 8), provides namely,
insulin
Z
at surface
size.
The same is suggested
of several
desorption
products.
proteins
by the MacRitchie
spanning
a range
where the rates could be conveniently
in Table 8.
it can be seen that as the molecular
the rate of desorption
y-
to one of the factors con-
and their degradation
pressures
Results are summarized
by the large proteins,
a pointer
the molecular
the rates of desorption
weights
In general, creases,
14 15
weight
and Waugh on proteins
(ref. 85) studied
measured.
11 12
30+
:; 60 61
22: 26
of the small protein
globulin
of molecular
27.5+
(mNm-')
D. Effect of molecular
work of Langmuir
(min-l x 103) 25+
24 ; 6 6
Pure 6-lactoglobulin s-lactoglobulin - DPPC +Surface
at different
at a given surface
weight of the protein pressure
decreases
in-
markedly.
(molecular weight 6,000) is large enough to be -1 measured at a pressure of 15 mNm , the larger-sized proteins such as y-globulin -1 and catalase are stable at this pressure and require pressures above 30 mNm for comparable
of insulin
desorption
rates.
In most studies of protein monolayers,
it is
373 TABLE 8 Rates of desorption
of five proteins
Mol. wt (x 10-3) Insulin B-Lactoglobulin Myoglobin y-Globulin Catalase
unusual belief
6 17.5
15+
ZO+
56
530 20
25+
30+
50 34
90 67 9
:;0 230
pressure
pressures
(ref. 85).
35+
40+
45'
144 20 30
40 70
110
(mNm-')
for this higher range of pressure that protein
stability
surface
Rate of desorption -1 (min x lo4
Protein
'Surface
at different
adsorption
at lower pressures)
to be investigated.
is irreversible is therefore
The widely
(based on observations
understandable,
although
held
of their unjustifiable.
E. Theory of desorption In any explanation
for the observed
desorption
behavior
of proteins,
the
following results need to be considered, Most proteins are stable up to 15 -1 mNm and desorption is not usually detectable below that surface pressure; this despite ficient tion.
the fact that equilibrium
equilibrium Above
concentrations
15 mNm_l,
than would be expected trations,
indicating
stantial magnitude. as molecular
weight
adsorption
desorption
can be measured
from calculations
the existence
would
predict
to cause measurable
suf-
desorp-
but rates are appreciably
using the equilibrium
of an energy
From a comparison increases,
isotherms
in the sublayer
sublayer
less
concen-
barrier at the surface of sub-
of different
proteins,
the rate of desorption
it appears
that,
at a given surface
pres-
sure decreases. An attempt
to quantify
been made by MacRitchie
the free energy barrier
(ref. 34).
step is taken to be a molecule of ca. 1 nm2.
process,
The transition
whose trains
This is the calculated
for a protein molecule
to adsorb.
when a protein molecule
equilibrium
and there may attain
It is therefore is compressed
trains,
is a finite probability the transition
configuration fluctuation
between
energy
required
assumed
occupy an area to be cleared
that in the reverse
to this area,
it is no longer
pressure,
state.
fluctuations,
At low pressures,
there is a (see Part IV-C)
individual because
molecules
the average'
in the form of trains,
be prohibitively
has
in the desorption
segments)
At any surface
that through
for this would
of proteins
loops and tails of a molecule
is one with nearly all segments required
complex
(adsorbed
area of surface
stable at the surface and will desorb. dynamic
to desorption
the energy
high and the probability
372 almost zero.
However,
the form of trains A quantitative
estimate
given surface
pressure
tein (see Fig. 3). required
to compress
(nc) at which
I
pressures
Adn
of the free energy barrier
to desorption
the molecule
required
(aGdes) at a
II-A curve of the pro-
to remove a molecule
from the given pressure
it occupies
in
increases.
an area of ca. 1 nm*.
will be that
(II,) to the critical This is given by:
.
(16)
e
The integral appropriate
can be evaluated
from the area under the n-A curve,
limits of Il. Because
of the sigmoidal
this area (and thus the free energy) rapidly
as Re increases
different
surface
constants
for desorption,
are compared desorption decreases
of such a fluctuation
C
AGdes = n
creases
where the proportion of segments
may be made from the equilibrium
The free energy
pressure
II
at surface
is much lower, the probability
pressures
15 mNm
-1 .
for BSA together
Some calculations
with corresponding
rapidly and attains
to the range of surface values relative
of AGdes at
measured
and MacRitchie
It can be seen that the appearance
rates corresponds
the
is very large at low values of ne but de-
above
from results of Gonzalez
in Table 9.
between
nature of the n-A curve,
rate
(ref. 79),
of measurable
pressures
at which ~~~~~
to kT where rate processes
become
significant. This simple theory appears tion.
to explain
significant compressed
desorption.
The rapidly changing
at higher surface
fewer trains molecules
per molecule)
of different
same distribution
pressures
causes
molecular
of segments
trains and hence the correspondingly consistent
with observations
REACTIONS
Many biological
trains,
reactions
proteins
ever
If we compare two
(at a given pressure)
the
loops and tails, the large mole-
of the greater
number of segments
larger area occupied
occur at interfaces.
participate
reactions,
trough or Wilhelmy-type
and control
by them.
Proteins,
as
This is
new instruments
phenomena.
reactions
Spread monolayers
In order to study
based on modifications
have been introduced.
with lipids,
of living cells.
of interfacial
and many enzyme reactions.
for these complex
film balance
together
the functioning
in a wide variety
respiration
simple model systems
interfacial
leaving
any when
(see Table 9).
which surround
such as blood clotting, provide
of segments
and assume
preclude
of molecules
IN MONOLAYERS
form the membranes
In addition,
pressures
~~~~~ to fall rapidly.
between
of protein desorp-
configuration
(expulsion
weights
cule will have a higher ~~~~~ because
VII.
the main features
The very large values of ~~~~~ at lower surface
of the Langmuir
TABLE 9 Calculated free energies of activation for desorption for desorption of BSA monolayers at different surface
n
Rate constant for desorption
AGdes/kT
AGdes (uJ molecule-')
(mNm-I)
(Atides) and rate constants pressures (ref. 34).
(gcm-2sec-1'2x 0 20 22.4 24.0 25.6 27.2 28.8
2.6 4.3 2.6 1.7 1.0 5.8 3.6
x x x x x x x
10 10 10 10 10 10 10
660 106 t:
lOI*)
0.42 1.83 3.50 7.50 9.17
24 14 9
A. Instrumentation Troughs
composed
one subphase
to another
the instrument ments
of several
have proved
of Fromherz
Each of the axles
be coupled
assembly
is connected
composed
thus compressing
monolayer
to be transported are separated
the trough.
This arrangement
and transferred
to another
may be quenched
by moving
occurring
where
reaction
over one or more compartments
tion of the monolayer by depositing Another
by walls which are slightly allows monolayers
important
development
monolayers. subphase, action
When lipid monolayers the reaction
is followed
area decreases compartment
products
at constant
according
The slope of the plot is directly expressed
no reactants.
by standard
become soluble
if enzyme
The
surface
trough
of enzyme
by lipases
techniques
introduced
present
away.
or
analysis.
reactions
in a conventional
curve of Fig. 9.
is
The composi-
chemical
and diffuse
pressure
a reaction
where reaction
for subsequent
by a small canal
it is
pressure.
Alternatively,
the kinetics
to the left-hand
trough connected
a linear plot is obtained
reaction,
containing
are hydrolyzed
surface
surface
when
an enclosed
lower than the edges of
has been the zero-order
Verger and de Haas (ref. 89) to measure
whereas
the
to be spread on one subphase
proceeds.
may then be determined
concentric-
to the frame,
enabling
from the subphase
one or more layers on slides
In
The inner axle may
the surface,
move together,
the monolayer
pivoted
barrier.
along the trough at constant
compartments
from
(ref. 87,88,89,90).
it is coupled
If
of monolayers
trough with eight compart-
of two axles
to a movable
to the outer axle, both barriers
transfer
useful
a circular
to the outer axle or the frame.
motor moves only one barrier, coupled
to allow
particularly
(ref. 87,88),
is used with a driving
ally.
compartments
by
in
in the
If the retrough,
the
By using a two-
(as shown on the right in Fig. 9),
is present only in the left compartment.
proportional to the velocity of the enzyme -2 -1 cm min since, in this case, the
in units of molecules
total number of substrate
molecules
accessible
to the enzyme
remains
constant.
37'4
First
order
,‘I
trough
1. 4
*
I
8 Time
Zero order
a.
12 min
I,
1 .
16
I 4
trough
I
I
I
8 Time
1
I
.
12 min
I
(
16
Fig. 9. Comparison between the recorded kinetic plots obtained with a standard trough (left) and with a "zero order trough" (right) (from ref. 90).
Most of the studies by having
on enzyme
the substrate
the subphase.
reactions
at interfaces
spread as a monolayer
Nevertheless,
some experiments
have been carried out
with the enzyme
in solution
using spread monolayers
in
of enzymes
have been reported.
B. Enzyme reactions
and retention
The usual procedure enzymes
for investigating
by transfer
to solution
vantage of this approach measured
It would therefore activity devised
of enzymes a method
and assay of the activity.
configuration.
in cell membranes be valuable
for measuring
to be studied.
or attached
in situ. --
the activity
spreading
The obvious
disadbeing
are known to function
to intracellular
interfaces.
these systems by studying
For this purpose,
the effects of surface
pressure
the
Skou (ref. 91)
of acetylcholinesterase
To avoid interference
on
film on a slide,
is not necessarily
Many enzymes
to try to emulate
as monolayers
layer state, which permitted unfolding
or collapsed
is that the enzyme activity
in its interfacial
incorporated
activity
the effect of surface
has been to remove the enzyme monolayer
followed
while
of biological
in the mono-
and the degree of
caused by dissolution
of enzyme
into the subphase
during
the monolayer
spreading,
ing) to a new compartment
of a multicompartment
new compartment
the acetylcholine
and samples reaction
contained
removed
occurring
The measured
preted
higher
pressure
was a maximum
times.
favorable
pressure
conditions
the measured of enzyme
and also with the surface
before compression
on further
enzymes
for maximum
was calculated
of the protein.
the orientation
was 10 mNm-I.
was inter-
off at lower and of side-
Under the most
time before compression
to be 51% of the activity
that this approach
in the monolayer
and 10 mNm'I),
of the same amount
frequency
after removal
does not give direct
protein molecules
after unfolding
in the two cases.
Skou
of enzyme
of enzyme with
There
is thus a
of the retention
of biological
films.
this type of experiment
Although
about activity spreading
revert
at the surface.
Although
ref. 92).
for each case to allow a more valid comparison.
from surface
of whether
up with studies
that the rate of collisions
factors
information
to the question
and whether
(see, however,
may be quite different
There have been a number of studies of proteins
has not been followed
state with those for equal amounts
it should be remembered
molecules
need to calculate
relate
to reflect
activity
spread as monolayers
activities
in solution, substrate
was assumed
The time
pressure.
in solution.
It seems surprising
compared
in this was stirred
of the enzyme
of the monolayer
of the degree of unfolding
(i.e., 30 sec. elapsed
activity
the kinetics
when this time was 30 sec., falling
The pressure
Optimum
chains.
The subphase This subphase
of the enzyme was found to vary with the time allowed
by the author to be a measure
The activity
(after spread-
to be measured.
before compression
at zero surface
trough.
substrate.
for assay, allowing
at the surface
activity
after spreading allowed
at intervals
was transferred
in the surface
of proteins
to their original
activity
state, it does
is a reversible solution
process
configuration
In some of the studies, a total loss of activity
has been found following
compl.ete spreading
are removed
films or fibers, care needs to be taken in interpreting
as collapsed
results as surface Part IV-D). activity antigenic
Other studies
may be retained activity
after spreading suction proteins
coagulation
Relatively
after taking
freeze drying.
after surface
of the soluble
spreading.
surface
and removal
most of the was recovered
by compression
(lo- 29%) were reported
losses caused
(see
and serological)
of paramecium
from the surface
When enzymes
in proteins
(enzymatic
For example,
proteins
small losses
into account
(ref. 93).
large changes
have shown that biological
as monolayers
(ref. 94).
itself causes
of enzymes
by the spreading
and
for three
solvent
and
376 C. Other reactions The unfolding molecular
of protein molecules
secondary
valence
molecularly,
this being favored
Furthermore,
reactive
ientation
groups,
of molecules,
layers, provide
previously
suitable
tively few studies of reactions been to measure of dissolved
changes
substances
with those on polyamino identify
at an interface
shielded,
attained
for high reactivity.
in mono-
There have been rela-
protein monolayers.
One approach
induced
in the subphase.
the effects
By comparing
The or-
possible
in II-A or n,-A characteristics
acids with various
inter-
in monolayers.
may become exposed.
to the high concentrations
in spread
causes intra-
These bonds may re-form
by the high concentrations
in addition
conditions
on spreading
bonds to be broken:
side-chains,
has
by the presence
it becomes
of proteins possible
to
the site of reaction.
Low concentrations (gelatin,
collagen
to show considerable interaction
of silicic acid in the subphase
and human serum albumin) hysteresis
served for a poly-DL-alanine tion of hydrogen
monolayer
bonds between
acid and the carboxyl,
viscosity,
protein monolayers
Because
the vicinity
of their isoelectric This is illustrated
(ref. 95).
(SiOH) groups of polymerized
technique
Proteins
either side.
curves
The
the same effect was ob-
groups of the protein.
of the silicosis
ns, is a useful
(ref. 53).
compression
and
, interaction was interpreted as the forma-
the silanol
amino and ketoimino
of this study to an explanation Surface
in successive
took place in the pH range 2-8.
caused protein monolayers
to become much less compressible
process was discussed. for detecting
show a maximum
points,
silicic
The relevance
decreasing
interactions
in ns at pH values
in in
as the pH is moved away on
in Fig. 10 for monolayers
I
of pepsin
(I.P.-2)
I
PH (A): BSA; (A): Fig. 10. Log no vs. pH for monolayers: glutamic acid; (o ): poly-L-lysine (from ref. 53).
pepsin;
(0): poly-L-
311 and BSA (I.P.
Poly-L-lysine
-4.5).
arly show a drastic
in ns as the electrical
decrease
This effect was thought
is increased. ular keto-imido
hydrogen
set up in the surface presence
and poly-L-glutamic
bonds as a result of the electrical
chloride
Protein monolayers
of metal
solution,
simil-
charge on the molecules
to be due to the breaking
(see Part V-B).
of low concentrations
0.001 M mercuric
acid monolayers
ions in solution.
a BSA monolayer
of intermolec-
repulsive
forces
are sensitive
to the
On a subphase
showed an increase
of
in no
(the value of ns when the log ns-R is extrapolated
to II= 0) of about 60 surface
poise (typical
Polyalanine
for a number of proteins
by this subphase similar
manner
whereas
to the proteins.
with the ionizable side-chains,
carboxyl
possibly
If lipid molecules is observed, is compressed, and decreases reversible.
polylysine
Polyalanine
that the structure
that the mercuric
some type ofcross-link
by Schulman
the viscosity with further
increases
increase
behaves
of polyalanine
in a
ion interacts
and Rideal normally
of surface
(ref. 97).
an unusual
effect
As the mixed
film
but then goes through presssure,
to the proteins
and lecithin.
acid
(cf. ref. 96).
into protein monolayers,
similarly
of the monolayer
was unaffected
acid were affected
groups on the protein or polyamino
are incorporated
first reported
for mixed monolayers
This suggested
and amino
forming
studied).
and polyglutamic
being
as shown in Fig. 11
The unusual
must be changing
a maximum
the behavior
behavior
shows
as it is compressed.
It
Fig. 11. Log ns vs. II for mixed monolayers of poly-DL-alanine and lecithin at pH 5.5; (0): polyalaning; (0): polyalanine-lecithin 4:l by weight; (A)polyalanine-lecithin 2:l by weight (from ref. 53).
378 was postulated between
that lipid molecules
the polypeptide
chains,
cause breaking
either
the net surface charge or by formation At low pressures comparatively however,
the effect
influence
VIII.
(high areas
becomes
the effect
bonds
increase of
bonds with the chains. is small because of the As the film is compressed,
of lipid molecules.
greater owing to the relatively
increasing
field of
of lipid molecules.
APPLICATIONS
In many natural
systems
(e.g., cell membranes,
the packing and conformation Monolayers
rect study. area occupied more,
hydrogen
steric effect,
of new hydrogen
per molecule),
low surface density
of keto-imido
by a simple
serve as excellent
per molecule
it can be varied
face pressure,
molecular
in a controlled
membranes
Membranes
have been studied. compartment
of protein monolayer
the
Further-
changes
may be followed.
in surA few ex-
studies
to practi-
here.
has been used by Verger and co-workers as surface
on the packing of membrane enzymes.
because
measured.
and the resulting
to di-
membranes
A direct approach spreadino
for these systems
and reactivity
applications
will be discussed
A. Biological
models
manner
conformation
dispersions),
is not easily amenable
at the surface can be precisely
amples of the many possible cal problems
protein-stabilized
of protein molecules
components
of intestinal
and catalytic
activity
trough by the Trurnit method
(ref. 5).
variables
of membrane-bound
brush border, human erythrocytes
They were spread from suspensions
cles, the amount of membrane
(ref. 98,99) by
films to study the effects of different
and -E. coli
of vesicles
on a multi-
Using 1251-labelled
vesi-
present at the surface was evaluated.
For intes-
tinal brush border membranes,
this was 25- 30% of the total amount
spread when
spreading
pressure
spread,
was at zero surface
the films were very stable.
proteins
spread from aqueous
and two brush border marker were assayed
was injected
and assayed.
tion of the experiment.
The specific
hydrolytic
the enzyme.
to that of pure
isotherms were measured and alkaline
phosphatase)
film by suction. out.
Films were com-
to a new compartment,
subphase,
Aliquots
No detectable
(i.e., no desorption)
the intact vesicles,indicating
is similar
were also carried
into the stirred
into the subphase
did not damage
activity
rinsed and transferred
were taken at intervals activity
Compression
(aminopeptidase
after removal of the surface
to 15 mNm_l,
substrate
This behavior
solution. enzymes
Kinetics of aminopeptidase pressed
and only 11% at 21 mNm -' (ref. 98). Once
activity
that spreading
of the subphase
release of aminopeptidase
was observed
during
the dura-
was in the same range as that of and subsequent
film manipulations
These results agree with the hypothesis
unit of the aminopeptidase
where the
is on the outer
that the
layer of the brush border
379 membrane border
When papain or trypsin was injected
(ref. 100).
film, a rapid release
occurred
with no change
Higher spreading cytoplasmic
portions
in surface
yields
of the two radioactive indicated
labels were recovered
the A/W interface
by the authors
In addition
functions
to this direct
coefficients
a dispersion
and cholesterol,
are important
of membranes
mixed
for membranes,
for synthetic
film
support
of cells at
the influence
of mem-
of the membrane.
the magnitude
on a solution
in the resistance
and
Fleming -.--* et al of interfacial
These were formed by spreading
membranes,
Diffusion
films of proteins
For example,
theory to calculate
of phosphatidylcholine
tion of calcium barriers
diffusion
This im-
in this work strongly
for studying
type of approach,
have been studied as models applied
reported
from the film.
there is no preferential
that the spreading
could prove a simple method
brane packing on biological
transfer
the hypothesis.
(33- 37%) and -E. coli
ratio in the surface
and therefore
Results
of either component.
the view expressed
(ref. 101)
with erythrocytes
that the protein/lipid
is the same as in the native membrane
lipids
brush phase
phospholipids
portant observation
spreadinq
under a spread
into the aqueous
further confirming
pressure,
were obtained
activity
When E. Coli cytoplasmic membranes containing (55- 60%). 14 -C-labelled proteins were spread, similar proand
membranes
32P-labelled
of aminopeptidase
of BSA followed
analysis
to passive
indicated transport
by the addi-
that interfacial across
these mem-
branes.
B. Foams and emulsions A dispersion
of a gas or liquid
stance
is present which adsorbs
persed
phase against
their capacity
Proteins
(ref. 102,103).
is unstable
unless a sub-
and thereby
stabilizes
compounds
vary greatly
Surface active
izers of foams and O/W emulsions. reviews
liquid
at the interface
coalescence.
as stabilizers.
in another
are particularly
effective
the disin
as stabil-
This has been the subject of some recent
The present
of how studies of protein monolayers
discussion
will be limited
may give information
to considerations
relevant
to these dis-
persed systems, When two emulsion
droplets
This means that during stabilizing
the coalescence
there is a reduction process
film and this could conceivably
at least in the initial film to compression
stage
would
(of the form rAdn).The
devised
(ref. 106) to measure and this parameter
ties of different
the work opposing
has been correlated
surfactants,
including
The response
the magnitude
tensiolaminometer
in interfacial
there is a compression
create a barrier
(ref. 104,105).
then determine
barrier
lamellae
coalesce,
of the interfacial
of the activation
reduction
energy
that has been of liquid
with foam stabilizing
proteins.
of the
to coalescence.
is an instrument surface
area.
proper-
A low compressibility
and
380 a low tendency teins,
to desorb
short-circuiting
to a great extent pressibility
both favor a high energy of the compression
(Part VI) although
of the monolayer.
case for colliding
droplets),
This is because
the relatively
displacement
measurements
relaxation
long times involved
The pushing out of segments
droplets
from the free energy
protein
segments
108).
protein,
tial at the surfaces effective
of droplets. agents
net charge,
(see
completion
barrier
during
of loops and
between
segments
produce a steric barrier a rise in concentration
flocculation
from the isoelectric
however,
(to coalescence)
proteins
(ref.
point of poten-
seem to be most
under conditions
that factors other
reof
of loops and tails can
thus promoting
is set up by the electrical
Generally,
showing
(formation
The presence
by molecules,
a repulsive
as stabilizing
carry a minimum
towards
The interaction
If the pH of the aqueous phase is displaced
the stabilizinq
be the
is quite
a high compressibility
phase
will usually
(ref. 107).
of droplets
the com-
(as would
in these measurements.
increase accompanying
in this region
also lead to bridging
increases
however
proceed
into the aqueous
as they approach
sulting
does not occur
of protein monolayers
indicate
processes
tails) by the protein could have two effects. on adjacent
of segments
the compressibility
case of pro-
In the
by desorption
For rapid compressions,
low, even though film balance Fiq. 3).
barrier.
barrier
where
than electrical
they repulsion
are predominant. The tendency
for proteins
to form thick films by surface coagulation
needs to be taken into account. surface
coagulation
This is particularly
for coalescence
be promoted
because
coagulation
in emulsion
stability
the well known phenomenon
of these films.
has not been studied
of phase inversion
a W/O one by shaking as in butter-making)
droplets
(Part IV-D).
may
The role of surface systematically
(conversion
is usually
as
from approach-
On the other hand, flocculation
to occur.
of the "stickiness"
preventing
also
to emulsions
occurs more readily at O/W than A/W interfaces
Thick films can form a simple steric barrier, ing close enough
relevant
although
of an O/W emulsion
attributed
to
to surface coag-
ulation of the protein at the A/W interface.
C.
Biomedical
problems
It is generally
accepted
ing recognition
and adhesion
role of surface
chemistry
part played by proteins and Freeman
(ref. 109).
drugs and hormones high molecular
weight
reactions
surface
functions)
in the biology
attached
is mediated
at the cell surface
Phagocytosis
glycoprotein,
of the living cell
by the cell surface.
of pinocytosis
has been discussed
is relevant.
the
for
such as the
(ref. 112) and surface
(ref. 113) are some of the many areas where
behavior
The
by Brandt
receptors
and the role of agents
fibronectin
(includ-
and, in particular,
(ref. 110), cell surface
(ref. ill), cell adhesion
blood-clotting of protein
that much of the behavior
induced
knowledge
381 An example of a natural appears
surfactant-covered
preventing
reduces
their collapse
been challenged liquid
in which monolayer
by Hills
surface
to cover the alveolar
tension,
at decreased
interface.
The major component
dipalmitoyl
lecithin,
adsorption
but other components
proteins
for the alveolar
preted the reproducible processes
dimensional in yield
hysteresis
at a molecular
level.
including
behavior
viscosity
The
as well as
studies
have
of the lung surfactant (ref. 117) have inter-
in terms of collapse
Blank and Britten
especially
proteins.
proteins
chemical
hysteresis
flow of films of lung surfactant
stress and surface
is phospholipid,
Mehta and Nagarajan
system.
for a discon-
at the solid tissue/air
serum-type
Surface
(ref. 115,116).
tended to focus on the expansion-compression as a model
the air spaces by
occurring
are present,
and comprises
A
of the lung.
The model has, however,
of the lung surfactant
is heterogeneous
surfactant-specific
cavities
thus stabilizing
lung volumes.
at an interface apparatus.
(ref. 114) who has put forward arguments
lining with surfactant
protein component
behavior
role is that of the respiratory
film is believed
This considerably
tinuous
system
to play an important
and reentry
(ref. 118) have measured
two-
and shown that there is a decrease. The results were interpreted
with age.
to indicate
that a two-dimensional network is formed rapidly having a yield -1 stress of about 3 mNm . The different processes of loop formation, desorption
and surface
coaqulation
are now better tribution
IX.
understood
of proteins
CONCLUDING Progress
during compression and should
for spreading
our knowledge.
valid method
At higher
urational
changes,
processes
relate
in conformation
desorption
to problems
under compression
may serve as a model
behavior
of the con-
films has been improved shows promise
in the very low pressure weights
providing
the different
posed in natural of molecules
(ultimately
membrane
parts of these molecules ing a configuration
of surface
appropriate
processes
leading
precautions
of molecular
For example,
to desorption
solution
that certain
These
the changes from the
the removal
conformation.
of The
has.not yet
segments
could form loops in the non-aqueous
that would make the probability
config-
of whole molecules)
biosynthesis:
under high compression
It seems possible
for fur-
provide a
have ben delineated.
systems.
to take up its unique proteins
region
(tails and loops) are expelled
for the final step in protein
in detail.
facets of protein monolayers.
and surface coagulation
from the ribosome
of integral
been studied
understanding films.
such as spectroscopy
molecular
pressures,
as portions
certain
and manipulation
Measurements
for determining
are observed.
(see Fig. 7)
REMARKS
of newer techniques
the molecule
in lipid-protein
has been made in understanding
The methodology
surface
lead to a better
to hysteresis
and application thering
of protein monolayers
in the apolar
phase, thus creat-
of desorption
extremely
low.
382 Direct studies of the desorption esting
results.
surface
of other proteins
One is that smaller
proteins
by those of higher molecular
ations where
there is competition
such as in blood clotting. protein
Another
reached.
between
is that desorption
different
to situ-
species,
of a slightly
soluble
at the same rate as from the pure monolayer
until low surface coverages
This is pertinent
from the
a result that is relevant
for the surface
from a mixed film proceeds
at a given pressure
weight,
have led us to some inter-
tend to be displaced
to considerations
of the desorbing
of mass transport
protein are across
biological
membranes. The structure
of protein monolayers
the newer spectroscopic
techniques
should help to clarify
the details.
compressibilities plained.
of different
functions
is warranted.
are studied;
photosynthetic
proteins which
in Photosystem
Processes
such as surface
size but dependent
to reflect
flow and loop formation
the surface
for proteins,
from the surface
projects
mainly apolar
secondary
structure
Because
strongly
ular to its axis. of proteins,
in the protein)
can act as
side-chains
to be
favor a random
from protein and polypeptide
the presence
of the a-helix
there is a tendency
in
for one surface
The mean helical
of polar and apolar
the retention hydrophobic
surfaces,
that the helix is highly amphiphilic
Krebs and Phillips
(ref. 121,122)
between
the product
in the molecule
of
moment,
a large perpendic-
have found, for a number ;hF (u,, being the average
and F being the fraction at the A/W surface
of a-helix
for a given amount
into the subphase.
The design of multicompartment of reactions
appear
concept
and the value of II exerted
injected
of
on the
This has led to the interesting
of the separation
value of p,, for all helixes
of protein
an A/W interface
(ref. 120j which justifies
monolayers.
a good correlation
consisting,
surface
moment
meaning
to be independent
phase, conditions
support
accessory
polar side chains while the opposite
side chains.
in protein
value for the parameter
ex-
(ref. 119).
flow and loop formation
polar and apolar
In some proteins,
hydrophobic
Ph, gives a measure
reactions
Surface
allowing
of each helix to project mainly
of the helical
appear
On the other hand, evidence
conformation.
an essentiaT and red algae
on a segment of the molecule
towards and away from the aqueous
films removed
in situ -in the
to amino acid composition
is phycocyanin,
a random chain conformation.
chain configuration.
variations
have never been satisfactorily
are related
2 of blue-green
of 6- 10 amino acid residues.
a "good" solvent
although
of monolayers
There are some marked
a recent example
pigment
examination
resolved
This becomes more so as new proteins with specific
molecular
directed
for direct
A study of how these variations
and structure
average,
is still not entirely
in protein
troughs
monolayers.
to date but other
processes
has provided
a stimulus
They have been used mainly are amenable
to study,
to the study
to follow enzyme
including
many in
383 the biological approach. in membrane
X.
area, which would benefit
This includes mimetic
from a collaborative
the further development
of protein
multidisciplinary monolayers
as a tool
chemistry.
REFERENCES
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D.W. Gouoil and F.C. Goodrich. J. Colloid Interface Sci., 62(1977)142. B.R. Malcolm, Progr. Surface i Membrane Sci., 7(1973)183; B.R. Malcolm, "Applied Chemistry at Protein Interfaces", R.E. Baier, ed., American Chemical Society Advances in Chemistry Series, 145(1975)338. B.R. Malcolm, Proc, Roy. Sot., A305(1968)363. G.J. Loeb, J. Colloid Interface Sci., 31(1969)572. D.G. Cornell,J. Colloid Interface Sci., 70(1979)167. D.G. Cornell,J. Colloid Interface Sci., 98(1984)283. R.E. Hirsch. D. Elbaum. S.S. Brady and R.L. Naqel, J. Colloid Interface I Sci., 78(1980)212. . L. Vroman, A.L. Adams, M. Klinge, G.C. Fischer, P.C. Miinoz and R.P. Solensky, Ann. New York Acad. Sci., 283(1977)65. A.L. Adams, G.C. Fischer and L. Vroman, J. Colloid Interface Sci., 65(1978) 468. J.A. De Feijter, J. Benjamins and F.A. Veer, Biopolymers, 17(1978)1759. H. Gruniger, 0. Mb'bius and H. Meyer, 3. Chem. Phys,, 79(1983)3701. T.L. Penner and D.J. Mb'bius, Amer. Chem. Sot., 104(1982)7407. I. Langmuir and V.J. Schaeffer, Chem. Rev., 24(1939)181. I. Langmuir, J. Amer. Chem. Sot., 39(1917)1883. I. Langmuir and D.F. Waugh, J. Amer. Chem. Sot., 62(1940)2771. G. Gonzalez and F. MacRitchie, 3, Colloid Interface Sci., 32(1970)55. J. Crank, "The Mathematics of Diffusion", Oxford University Press, p. 38, 1956. J.T. Davies and J.B. Wiggill, Proc. Roy. Sot. London, A255(1960)277. H. Neurath and K. Bailey, "The Proteins", Academic Press, New York, Vol. 1, Part B, p. 636, 1953. L. Ter-Minassian-Saraga, J. Chim. Phys., 52(1955)181. "The Kinetics of Reactions in Solutions!', Oxford E.A. Moelwyn-Hughes, University Press, London, 2nd ed., 1947. F. MacRitchie, 3. Colloid Interface Sci., 105(1985)119. F. MacRitchie, 3. Colloid Interface Sci., 107(1985)276. P. Fromherz, Biochim. Biophys, Acta, 225(1971)382. P. Fromherz, Rev. Sci. Instrum., 46(1975)1380. R. Verger and G.H. de Haas, Chem. Phys. Lipids, 10(1973)127, J. Rietsch, F. Pattus, P. Desnuelle and R. Verger, J. Biol. Chem., 252(1977) 4313.
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341
Elsevier Science Publishers B.V., Amsterdam - Printed in The Netherlands
SPREAD MONOLAYERS
OF PROTEINS
F. MacRITCHIE
CSIRO Wheat Research Unit, P. 0. Box 7, North Ryde, N.S.W. 2113, AUSTRALIA
CONTENTS I.
ABSTRACT
.......................................................
II.
INTRODUCTION
III.
METHODS
...................................................
FOR SPREADING
A. Aqueous
solution
B. Spreading
for quantitative AND INTERPRETATION
0. Surface
potentials
B. Surface
rheology
346
....................
347
films
.................
MONOLAYERS
...............
349 350 352 355
..........................................
355 356
of film ............................................
358
methods
......................................
362
.....................................
363
........................................
363
FROM MONOLAYERS
A. Kinetic measurements B. Radiolabelled C. Desorption
proteins
......................................
from mixed monolayers
0. Effect of molecular
weight
............................
..................................
367 369 370
E. Theory of desorption
........................................
371
IN MONOLAYERS
........................................
372
.............................................
373
REACTIONS
A. Instrumentation B. Enzyme reactions C. Other reactions
VIII.
346
...................
......................................... PROTEIN
345
............................................
0. Direct optical
VII.
weight
in compressed
FOR STUDYING
A. Surface
DESORPTION
OF n-A CURVES
..........................................
changes
coagulation
.........................
spreading
region and molecular
of state
OTHER TECHNIQUES
C. Transfer
VI.
345
0. Criteria
C. Configurational
344 344
MEASUREMENT
B. Equations
342
..........................................
....................................................
A. Low pressure
V.
...............................
............................................
solvents
C. Crystals
IV.
MONOLAYERS
342
APPLICATIONS A. Biological
and biological
activity
....................
.............................................
...................................................
376 378
........................................
378
B. Foams and emulsions
.........................................
379
C. Biomedical
.........................................
380
0001-8686/86/$15.75
membranes
374
problems
0 1986 Elsevier Science Publishers B.V.
342 IX.
CONCLUOING
REMARKS
X.
REFERENCES
.....................................................
I.
.............................................
383
ABSTRACT The study of spread monolayers
the fundamental
behavior
from their ubiquitous proteins
of proteins
presence
liposomes
arrangement and packing
trolled.
Methods
potential
of monolayers
spectroscopy,
changes,
ellipsometry).
molecular
surface
theoretical reviewed.
relevance
of multicompartment
to biological
occurring
where
the enzyme
of monolayer
membranes,
region
interface
and is
has proved valu-
This instrumentation
at the surface,
is imnobilized
for
reflectance
Experimental
film balances
in monolayers.
foams and emulsions
diffrac-
methods
configurational
from the air/water
studies are briefly
removal
in the low pressure
are all observed.
of proteins
to the study of enzyme reactions
to reactions
Some applications
(e.g., multiple
and desorption
able for the study of reactions has been applied
electron
At higher pressures,
work on the desorption The introduction
(such as surface
Direct optical
The use of measurements
that
and con-
including
is discussed.
weights
coagulation
methods
techniques,
in situ are also available --
In
chemistry.
used for their manipu-
innovations,
are discussed.
of
to other branches
may be measured
and techniques
more recent
spectroscopy,
mimetic
the unique advantage
in monolayers
proteins
for study by radiotracer
(IR)
the study of monolayers
to measure
of molecules
despite
resulting
Spread monolayers
in comparison
As well as the more traditional
on slides
tion and infrared
in nature.
field of membrane
neglected
and viscosity),
for understanding
as well as the many phenomena
and vesicles),
for spreading
lation are outlined. pressure,
is of interest
at interfaces
it has been somewhat
(such as bilayers, the
of proteins
is a branch of the developing
recent times,
II.
381
of direct
in the cell membrane.
illustrated
and biomedical
with reference
problems.
INTRODUCTION A striking
solution,
property
of proteins
is that, although
they may be spread quantitatively
to give highly stable monomolecular pounds, which
require
at these interfaces. results mainly large size. attached
from two properties:
A protein
molecule
and glutamic
a configuration
or oil/water
This is in contrast
solubility
1) their polar/non-polar
consists
ofa polypeptide degrees
and leucine)
acids).
to most com-
at interfaces
nature;
backbone
of polarity,
and 2) their
to which are
ranging
from
to polar ones (such as the
In the dissolved
that minimizes
in aqueous interfaces
in order to spread as monolayers
of protein molecules
of varying
(such as phenylalanine
aspartic
cules assume
films.
The great stability
amino acid side-chains
very non-polar ionizable
very low water
many are soluble
at air/water
state,
protein mole-
the free energy of the system.
Thus,
343 they fold up in such a manner groups at the periphery side, protected
that the number of polar
are maximized
from energetically of non-polar
unfavorable
Complete
shielding
however,
because
residues
sequence
and the steric constraints
of their possible
When a molecule
reaches
proximity
order
for this to occur,
conformation
in which
the non-polar
is replaced
to polar residues
has a certain of the molecule
segments.
Although
each segment
adsorption
(AG), the total free energy
if the number of segments
stability quires
The drastic
unfolding
molecules
the effects
has only a moderately
to an insoluble
priate.
interaction
on proteins,
large free energy of
However,
systems,
in response
to changes
interfaces.
to many biological
phenomena
produce
coagulation
in their energy
that,
of proteins that occur
appears
are continually
inappro-
altering
environment,
their
including
with interfaces
(such as cell membrane
to
irrever-
processes
denaturation"
It is this interaction
of
being applied
by the observation
when the different
re-
from the interface.
loss of solubility
are shaken,
protein molecules
very high
for the great
of a whole molecule
that surfaces
the term "surface
toward
This ex-
so that for many pur-
This accounts
by an apparent
implying
phase.
(nAG) may attain
the desorption
solutions
form results.
with
per molecule
This view is supported
protein
are understood,
In biological
conformations
accompanied
In chain
in terms of a series of
of a large number of segments
in proteins.
cases where
at interfaces
relevant
may be described
has led to the term "surface denaturation"
of surfaces
sible changes in certain
removai
directed
to the aqueous
(n) is large.
interface
side-chains.
into a two-dimensional
degree of flexibility
of protein monolayers,since
simultaneous
protein
unfold
protein
side chains are predominantly
poses, the behavior
is encountered.
if an area of high energy
by non-polar
phase and the polar side chains
tended configuration
values
medium.
achieved,
in the chain
a new energy environment
protein molecules
non-polar
not be closely
in-
imposed on chain folding.
an interface,
by water molecules
ionizable)
groups are mainly
contact with the aqueous
can usually
The free energy of the system may be reduced occupied
(especially
and the non-polar
that is
structure
and
created
model
function). A growing systems
field of research
is concerned
of cells and cell membranes.
This has become
chemistry
(ref. 1,2) and includes monolayers,
liposomes
and vesicles.
of the film balance, attention
with artificially
Despite attracting
(such as bilayers,
times.
This does not mean that there
Present
techniques
are not capable
3.4) has drawn attention
is no
multilayers,
much interest
the study of protein monolayers
as other areas
known as membrane
bilayers,
micelles
following
develapment
has not received and liposomes)
mimetic
micelles,
as much
in recent
scope for further work or that
of yielding
to the use of designed
new information. monolayer
tibius
assemblies
(ref.
to create
344 processes
analogous
cules
in biological
which
light energy
cific proteins
to those performed systems.
is converted
assemblies
of biological
monolayer
research
advantage
over some of the complementary may be manipulated
a function
determined
METHODS Although
FOR SPREADING
the technique
tional
monolayers.
are adsorbed. proportion
These conditions
in incomplete
proteins.
A. Aqueous
solution
Purely aqueous
solution
precautions
in which
A method
is allowed
satisfactory
of all protein molecules
Rigorous
theory was applied
variables
fully by a number of workers spreading
solvent
theory,
to adsorption
difficult solution
to derive appropriate
into the system. technique
This may be explained
to the surface
ionic strength, satisfactorily.
the electrical
energy
conditions
thickness
in
in terms
of flowing
aque-
has been used successthat no non-aqueous to be occas-
of energy barriers
Proteins
of mole-
are particularly
charge and the spreading
spreading
solution
and sub-
point of the protein and at a moderate
barrier
In fact, some proteins
glass
the elapsed
is to prevent a fraction
By having
strate at a pH close to the isoelectric
(ref. 5)
does not work as well as predicted
from adsorbing.
electrolyte.
for
unless
wetted
There do appear
to spread when they carry a net electrical does not contain
by Trurnit
by the presence
(ref. 6,7), the effect of which
cules which diffuse
are available
to the surface during
This method of spreading
is introduced
so that if a
then becomes a problem
and has the great advantage
ions, however, when this spreading by diffusion
spreading
(such as protein concentration,
ous film and length of rod).
of
or be convected
to flow down a perfectly
ensuring time.
spreading
for spreading
has been devised
surface.
of relevant
Quantitative
it will diffuse Several methods
is not usually
solution
quantitative
in which all the protein molecules
rod onto the water diffusion
as
is not as simple as that of conven-
are not always easy to achieve
spreading.
are taken.
an aqueous
chem-
measured
concentrations.
The secret for obtaining
is to create conditions
spreading
mimetic
properties
stable once they become attached
for spreading
of the protein does not adsorb,
away, resulting
special
two-dimensional
for furin protein
have an important
of membrane
and various
are extremely
to an interface, insoluble
promise
MONOLAYERS
protein molecules
protein monolayers
Monolayers
in
The use of spe-
that a resurgence
techniques
istry in that molecules
III.
holds sufficient
mole-
membrane
stored energy.
processes
seems likely to eventuate.
of precisely
arrays of cooperating
is the photosynthetic
into chemically
in such organized
thering our understanding
by complex
One example
is reduced and many proteins
may be spread quantitatively
spread
under these
conditions
simply by using a microsyringe
example,
bovine
solution
of pH 7.3 containing
composition
serum albumin
spread quantitatively
useful
B. Spreading
efficiency
Welcome) tative
solvent with
remain which
of isopropanol-water by Stallberg
is usually
monolayers
stable
and Teorell
is present
dissolve
the protein
are also soluble, may be spread.
in this solvent initially
vent at low temperature, become turbid,
Another
or are slowly in aqueous
ensuring
this may be avoided
solutions.
rapid mixing.
However,
clear,
ing ionic strength
concluded strength
and alcohol
of spreading
0.01, containing
Some proteins
concentration
solution
0.5% amyl alcohol
do not
It is preferable
the resulting
solution
solution
furof
as "denaturing the solutions is identical,
solution.
Small quanti-
in spreading
of different
of the spreading
to
sol-
are skeptical
that, providing
the effects
of human serum albumin
that the ideal spreading
contamination
of spread monolayers
have also been used to assist
lipids
protein-
is that the solutions
Some workers
or purely aqueous
et al. (ref. 12) have studied
quanti-
and then add the mixed
Should
experience
the behavior
spread from isopropanol/water
ties of isoamyl alcohol
mixed
because of their reputation
it is the author's
perfectly
(Burroughs
that certain
the pH of the aqueous
solvents
as protein
advantage
solution
by moving
purpose
With this solvent,
precipitated.
point of the protein.
efficiency
could
0.5 M sodium
the danger of bacterial
using alcohols
Minones
proteins
so that homogeneous
ther from the isoelectric
whether
do not
a more detailed
(ref. 9) as a general
is used.
in the case of purely aqueous
easily
are prepared
of the same
or "Agla" microsyringe
It has the advantage
achieved.
for long periods without
dissolve
agents".
for different
(60:40) containing
A micropipette
for proteins.
phospholipids)
phospholipid
This suggests'that
of spreading
its glass tip at the surface
spreading
(including
on a substrate
(e.g., bovine v-globulin)
solvents
was introduced
spreading
proteins
spread from a buffer
information.
A solvent consisting acetate
other
under these conditions.
study of the comparative yield
0.15 M sodium chloride
However,
(ref. 8).
For
with the tip in the surface.
(BSA) has been quantitatively
(ref. 10,ll).
variables solvent)
(HSA) monolayers.
(includ-
on the
These authors
is a buffer of pH 5.1 and ionic (v/v).
C. Crystals Many proteins convenient spreading constant
method
spread
rapidly
is not required surface
cult spreading
from crystals
to use for certain
purposes,
(such as where
pressure),
from solution
the method
placed at a surface. For example,
kinetic measurements
is rapid, avoiding
and the use of spreading
This is a
if quantitative are to be made at
the problem of diffi-
solvents.
In theory,
it
346 can also be adapted capable
for quantitative
of measuring
of protein
microgram
has a surface
spreading
quantities
Losses of protein
ever, the surface of dissolution,
concentration
D. Criteria
by dissolution
spreading
with a balance
A close-packed monolayer -2 in the order of 1 mg m . Therefore, to
spread a film of half this concentration Pg.
in conjunction
(ref. 13).
on an area of 400 cm2 would
require
into the bulk phase can also occur.
rate for many proteins
is much greater
20
How-
than the rate
so that losses are often minimal.
for quantitative
spreading
Since a large number of proteins which extrapolate rough indicator
give surface pressure (rr)-area (A) curves -1 to an area close.to 1.0 m'mg , this value can be used as a
of quantitative
than this almost certainly curred.
spreading.
A calculated
means that a loss of protein
If there is doubt about the efficiency
between
replicate
is to use several
spreadings spreading
Losses will usually concentration
of spreading,
is not a useful criterion. solutions
increase with
of different
increasing
of about 0.03% is recommended
protein
that the film is not under any appreciable completion
is a barrier
to the adsorption
the surface
against a surface where rier.
of spreading.
the monolayer However,
When protein
a different
n-A curve
MEASUREMENT
caused
AND INTERPRETATION
When a monolayer of the clean is defined
Vaiues of II are usualiy change
in interfacial
measurement
expressed
for monolayers.
and for many purposes
(or interfacial)
free energy
during and
pressure,
there
of the molecules
is spread in this way from the one
by compressions
with a bar-
a surface
pressure.
OF n-A CURVES
(y,) may be reduced
as the surface
It is
by the failure to take into account
is spread at an interface,
interface
pressure
a surface
is obtained
is spread at high area followed
this is an artifact
A protein
solution.
step (ref. 6), so that a fraction
the losses of protein when spread against
IV.
concentrations.
surface
When spread against
is not adsorbed.
pressure,
close agreement
for the spreading
important
smaller
has oc-
The best way to check
protein concentration.
following
reaching
area appreciably by dissolution
the initial
to a new value pressure
interfacial (y).
tension
The difference
(II); i.e.:
in mNm-' and are numerically equal to the -2 . II is thus the most fundamental
in mJm
Its units are those of a two-dimensional
it is analogous
to the more comn
pressure
three-dimensional
pres-
sure. Protein monolayers which the monolayer
may be easily manipulated is compressed
or expanded
by means of a film balance between
movable
barriers
or a
ln
341 flexible
ribbon and relations Interfacial
(n-A curves).
plate or a Cangmuir
between
pressure
interfacial
pressure
may be measured
float connected
to a torsion
and area established
by either a Wilhelmy
wire or force transducer.
main problem with the Wilhelmy
plate method
is the maintenance
angle.
angle caused
by spreading
Changes
in the contact
by the use of isolation appeared
(ref. 14).
clean glass,
holding always
mica or platinum)
it over a smoky Bunsen keep the plate wetted
elasticity. on either
Therefore,
particularly automatic
flame is convenient
A. Low pressure
to calculate
weights
remains
ecular weights
of small
Early workers
in composition
is more susceptible
Many film balances
leading
available
film balance
that employs
to leakage,
are arranged
for
(MCN Lauda, Germany
the iangmuir
float principle.
weights at very low values of n (below 0.1 mNm-' caused many workers More recently,
one for determination
to moderately
sized proteins.
phase transitions
analogous
in the field to
interest
has dwindled
of number-average
mol-
with other
In comn
in protein monolayers.
to the gaseous-type
monolayers
is not observed.
Nevertheless,
at sufficiently
act independently
and therefore
n-A relations
a colligative
high visco-
by dual barriers
to keep the film uniform
(ref. 15).
a legitimate
a region completely
molecules
compression
of proteins
there are no well defined
protein molecules reflect
instrument
on this region
but the method
(such as
be taken to
exhibit
of the plate from the vertical,
but this method
A commercially
molecular
but care should
Protein monolayers
pressures.
use of n-A measurements
focus attention
simpler
angles
regilon and molecular
The possible
Therefore,
tilting
at high interfacial
automated
has dis-
In the case of the Langmuir float, there are no prob-
contact
operations.
plate
Where the lower phase is an
a film balance which allows
measurements.
is a reliable,
polymers,
is used.
side of the plate is advisable
lems with changing
can be avoided
A mica plate coated with lamp black by
by the oil.
over the surface and to prevent to incorrect
solvents
which can be removed after the solvent
plate may be used.
The
of a zero contact
With water as the lower phase, a hydrophilic
roughened
oil. a hydrophobic
barriers
hanging
of
high areas, in this region
property.
(ref. 16) applied
an Amagat-type
equation
for imperfect
gases;
i.e.: n(A- Ao) = nRT
,
(2
where A is the area available Universal
gas constant
that the surface
aratingthe
and T the absolute
pressure
to a two-dimensional
temperature..
Bull
in this region was thermodynamically
osmotic
film-covered
to n moles of film, A, is a constant,
pressure
surface
than to a gas pressure.
R is the
(ref. 17) argued more equivalent The barrier
from the clean surface may be considered
sep-
as a
1
348 semi-permeablemembrane. A similar equation to Eq. 2 is obtained from which a plot of flA vs. i'l (extrapolatedto zero n) may be used to evaluate the molecular weight (M) from the relation:
(n A),,0 = ; RT
3
2 -1 where w is the weight of monolayer substance. If II is in mNm-l, A in cm g , then w is unity (1 g), R has the value 8.3x lo7 ergs per mole per degree and -2 T is the absolute temperature. Since A is normally expressed in mgm , this value must be converted to cm 2g-' by multiplying by 107. Molecular weights of many proteins (ovalbumin, gliadin, hemoglobin, f+lactoglobulin)calculated by the film balance method agree well with values obtained by other methods (ref. 15). One of the most thorough studies was carried out by Harrap (ref. 11) on the molecular weight of insulin over a wide range of pH and ionic strength. Some of the results are illustrated in Fig. 1 for a
subsolution of pH 2.05 and
differing ionic strengths.
Fig. 1. n-A and nA-n for insulin films spread on subsolutions of pH 2.05 and differing ionic strength. Curve a: r/ = 0.01; b: r/2= 0.1; c: r/ = 0.2; d: r/2= 0.5. Some values of Fredericq (ref. 1i ) (0) are also shown for t e range in which the two sets of data overlap (ref. 11).
2
At the lowest ionic strength (f= O,Ol), the nA-n plot is linear at all values, leading to an extrapolated value of 6,000 for the molecular weight of insulin.
349
At higher ionic strengths, the curves are convex to the IIaxis.
This behavior
may be compared to PV-P curves of real gases and similarly indicates aggregation due to the tendency of attractive forces to predominate over the electrical repulsion. Extrapolationof the linear portions in these cases thus gives false values for the molecular weight, although at sufficiently low pressures, the limiting value. Effects of aggregation
curves are seen to approach a comn
at a given ionic strength were greatest at pHs
near the isoelectric point (pH
5.6) and were absent only when the molecule carried a high net charge as for the example in Fig. 1 (pH 2.05, f 0.01). This work emphasizes the advantage of measuring molecular weights under conditions where the protein carries a high net electrical charge,
If this is not possible, measurements must be made
at very low surface pressures (e.g., below 0.02 mNm-' for the results in Fig. 1). Under these conditions, a very sensitive and stable instrument is required. Extremely clean water, free of surface active impurities, is essential for this work.
Providing these considerations are observed, the method is a rapid and
reliable one for estimating molecular weights of proteins. B. Equations of state An equation such as Eq. 3 is strictly valid only for molecules which behave as rigid disks. However, protein molecules in monolayers are unfolded and the extended chains have a degree of flexibility, A number of equations have been developed to describe linear polymers at interfaces by application of statistical thermodynamics. One of the best known,is the equation of Singer (ref. 19) based on the high polymer theories of Huggins (ref. 20) and Flory (ref. 21).
Singer's equation for a completely unfolded monolayer is:
rl=J$lnII-$\+$Q-$
(,I - 2A 1
iln-+
,
where t is the total number of segments per molecule, A is the area per segment available, A, is the limiting area per segment and z is the surface coordination number in the two-dimensionalquasi-lattice in the interface. For a completely rigid chain, z= 2 and for a completely random chain z= 4. Singer's equation predictsthat if z is appreciably greater than 2, curvature in the plot of IIA vs. IIoccurs due to entropic effects arising from the random arrangements and flexibility of the long chains, For very dilute monolayers, the equation has been found to show good agreement (ref. 22). Other contributions to equations of state which take into account surface activity coefficients (ref. 23), partial solution of polymer chains in the substrate (ref. 24) intermolecularcohesion (ref. 25) and electrical 'intermolecularrepulsion (ref. 26) are relevant to protein monolayers.
350 An equation of state of the virial type (ref. 27) has been applied to x-A measurements of several proteins (ref. 28). The data were interpreted to mean that the proteins BSA, hemoglobin and ovalbumin were more unfolded than transferrin and myoglobin. By measuring changes in n-A curves as a function of temperature and applying a suitably modified Singer equation, Llopis and Albert (ref. 29,30) have derived thermodynamic spreading terms for protein monolayers. Spreading entropy (S,) and enthalpy (H,) were plotted as a function of the area and were shown to depend markedly on the pH of the substrate. The spreading terms were in accord with the notion that cohesive forces play a more important role in y-globulin than in BSA monolayers. C. Configurationalchanges in compressed films When protein monolayers are compressed to higher pressures than those considered in the previous section, relaxation processes occur which are manifested by losses in surface area (if n is kept constant) or losses in surface pressure (A constant). Providing there is no desorption'(Part VI) or surface coagulation (Part IV-D), these losses are recoverable on expansion. The very large reversible reductions in area that are observed at high pressures (II>20 mNm_') can only be rationalized if it is assumed that parts of the molecules are forced out of the surface. It has been well established that adsorbed linear polymer molecules may exist as trains (segments attached to the surface), loops (segments extending into the adjacent phase) and tails (segments at the ends of molecules) which are also preferentiallydisplaced from the surface (ref. 31, 32). Monolayers allow the opportunity to study the distribution of attached and displaced molecular segments. In the case of proteins, the relaxation processes are often sufficiently slow to enable them to be easily followed experimentally. If A, is the initial area of a protein monolayer before any relaxation has occurred and A is the area after equilibrium has been established between adsorbed and displaced segments at a constant pressure II,then the ratio of adsorbed to displaced segments (r) is given by:
If the work required for a displaced segment to enter the surface is IIAA, (ref. 33), where AA, is the area per segment, then the variation of r with IIwill be given by:
(AG, - rrAA,) r = exp kT
,
(6)
351 where AGO is the difference ments at n=O.
in free energy between adsorbed and displaced seg-
Plots of log r vs. n for monolayers of catalase at several values
of pH are shown in Fig. 2.
Fi 2. Log r vs..n for monolayers of catalase on buffer solutions at 23'C: CopI pH 7.3; (0) pH 4.4; (Cl) pH 3.5 (ref. 33). The linearity of these plots are in agreement with the premises of Eq. 6. From the slopes and intercepts, hGs and &A, values may be calculated. A summary of these values for several proteins under different conditions of temperature and substrate pH is given in Table 1. Values of CAM fall In the range 0.9-1.5 nm2, correspondi~ngto an average size of 6-10 amino acid residues per segment, hGS values fall in the range 4,6-8,8 kT per segment for the proteins studied. In general, AG, decreases with IncreasIng electrical charge as the substrate pH moves away from the isoelectrjc point of the protein (i,e., the equilibrium distribution shifts in favor of the di,splacedsegments). This reflects a contribution to aG, of an electrical term of the form q,$, where q, is th, electrical charge per segment and J, Is the electrical potential in the plane of the charged groups. On the other hand, increasing temperature increases AG, in the range studied, favoring the adsorbed segments, Thls result indicates that adsorption of segments is accompanied by an @crease of entropy, Disordering processes that may be involved are the elPminatlon of ordered water around non-polar side chains and loss of secondary structure (e.g., o-helix) by the protein.
352 TABLE 1 Values of AG, (II= 0) and AA, for protein monolayers (ref. 33). Protein
Subphase
T-Globulin
buffer, buffer, buffer;
T-Globulin
distilled
Catalase
Ferritin
Because
Temp. (OC)
pH 7.3 pH 4.4 pH 3.5 water,
distilled
pH 5.4
protein monolayers,
water,
configurational
the most meaningful
the equilibrium equilibrium, quires
distribution
although
long periods
fore, when-film recording
equilibrium
n-A curve
construct
constant
represent
curve
the n-A relations
D. Surface
;55 25
7.7 8.8 8.2 7.5
kT kT kT kT
1.5 1.5 1.6 1.5
25
7.8 kT
1.2
occur relatively
is probably
and displaced
segments
is shown
(above 20 mNm-l).
rapid stepwise
of the essentially
There-
with automatic
An example
of an
Here it is compared
compressions
unrelaxed
re-
that these measured
parameters.
in Fig. 3.
from a two-dimensional
of monolayers
some study (ref. 35).
is an interesting
are made to
monolayer.
Theoretically,
to a three-dimensional phenomenon
a monolayer
to its bulk state) on reaching
pressure
(E.S.P.).
In certain
state when the E.S.P. energy barrier
cases, monolayers
is exceeded.
associated
This
with creation
occurs
because
spreading
in a supersaturated
of the need to overcome an
energy
in crystal
nuclei
(ref. 36). proteins
spread
from their crystals
true E.S.P.s are obtained
(Part
and none appear
to
should begin to
its equilibrium
may remain
of surface
state on com-
which has been subjected
substance
(transform
Although
of
This
pressures,
rates of compression
collapse
whether
in
the equilibrium
at lower surface
fundamental
in which
slowly
coagulation
The transition pression
employing
1.4
25
at higher pressures
for a protein
with an instantaneous
4.6 kT 5.1 kT 5.8 kT
of n-A curves are used, it needs to be realized
curves do not necessarily
1.3 1.3
point corresponds to the attainment
fairly rapidly
(many minutes)
balances
7.3 kT 6.4 kT 5.5 kT
255 45
changes
between attached
reached
s2 (nm 1
0.9 1.0 1.1
II-A curve
one (i.e., the one in which each measured
AA
(n=O)
pH 5.4
pH 5.4
conditions
AGS
25 25 25
distilled water, buffer, pH 7.3 buffer, pH 4.4 buffer, pH 3.5
these reversible
under different
III-C),
it is doubtful
to have been reported
for
363
I
I
100
50
equilibrium curve; Fig. 3. n-A curves of BSA on distilled water at 2o"c; -: ----: curve which would be obtained if no expulsion of segments from interface (ref. 34).
pure proteins. by surfaces,
Because
proteins
ties to the crystals solutions
of the drastic
form a coagulum
protein.
extent of coagulation strength.
conditions,
structure
induced
and proper-
This is seen when protein
often resulting in turbidity
in the formation
of solutions
of a
on shaking was made by Henson et al. (ref. 37).
during a one-hour
Of the thirteen
coagulation
molecules.
A study of the increase
large range of proteins
of protein molecules
with very different
formed by globular
are shaken under certain
of insoluble
unfolding
proteins
and a-lactalbumin
shaking
examined,
period varied with pH and ionic
ovalbumin
was least susceptible.
globin and pepsin are other proteins
The
was most susceptible
s-lactoglobulin,
that are relatively
to
hemo-
easily surface
coag-
ulated. A simple theory protein
a substance surface
has been proposed
monolayers
will remain stable as a monolayer
free energy,
the surface by splitting Ya=Yb+Yab
ya, and will continue
free energy
in the presence
it into three terms, + nc
provided
stability
films (ref. 38). it lowers
of
Briefly,
the initial
to spread until ya= ye, where ye is
of the monolayer.
ye may be interpreted
such that at equilibrium:
(6) free energy
and the non-aqueous
pressure.
between
the non-polar
phase, Tab is the interfacial
the polar groups and the aqueous sure or coagulation
governing
to duplex
,
where yb is the interfacial monolayer
for the conditions
based on their resemblance
groups of the
free energy
phase and II~ is the equilibrium
between
spreading
pres-
354 This equation predicts that once this critical surface pressure (II~)is reached, whether by compression of a monolayer in a film balance or by adsorption from solution (as occurs during shaking), transformationof the protein to an insoluble coagulated form will occur. The results of Henson et al. (ref. 37) confirm that spontaneous surface coagulation is frequently observed when protein solutions are shaken, this process creating large extensions of interface. Certain results agree with Eq. 6, at least semi-quantitatively. This is illustrated by some experimental measurements of flc(for ovalbumiln)as summarized in Table 2. TABLE 2 Measured coagulation pressures and separated free energy terms for ovalbumin at different interfaces (20°C) (ref. 38). Interface
ya (mNm-l)
%
(mNm-I)
'b (mNm-I)
Yab (mNm-I)
Air/water
72
27
35
10
Air/5M NH4Ac
67.5
17
35
15.5
Heptane/water
50
16
24
10
Benzene/water
35
12
13
10
For example, II~is lowered as y, decreases, so that coagulation occurs more readily at O/W than at A/W interfaces. Values of yb and Tab were calculated from contact angle measurements on Langmuir-Blodgettfilms removed from a closepacked ovalbumin monolayer, The differences in surface coagulation behavior between proteins (ref. 37) must reflect variations in composition or structure which can be interpreted in terms of the yb and yab terms. These rather large differences are observed despite the great similarity in n-A curves between proteins, Sensitivity to surface coagulation may be an important property in biological processes and, for this reason, a closer study of the phenomenon by the monolayer technique seems warranted, One interesting observation which illustrates this is that, in solution, fully oxygenated sickle-cell hemoglobin (HbS) is much more susceptible to precipitation by shaking than normal hemoglobin (HbA), despite the otherwise great similarity in structure and properties (ref. 39,40). Other studies have focussed on the surface deactivation of cellulase by shaking and its prevention by surfactants (ref. 41) and the denaturation of e-lactoglobulinand its subsequent renaturation by dissolution in dilute acid (ref. 42).
355 OTHER TECHNIQUES FOR STUDYING PROTEIN MONOLAYERS
V.
A. Surface potentials The change in electrical potential between two electrodes (one in the aqueous subsolution and the other in the air above the surface) when a monolayer is spread is called the surface potential (AV) of the film. Two methods of measurement are in common use: 1) the ionizing electrode; and 2) the vibrating plate (ref. 43). Surface potential measurements on protein monolayers can give information on the homogeneity of the film and the orientation of dipoles in the film.
In principle,
they can also be used in conjunction with surface pressures to follow the kinetics of reactions occurring in the film.
The influence
of pH on the AV-A curves of proteins is very marked. Near the
isoelectric point and at high areas, the surface potential fluctuates wildly as the electrode is moved across the surface (ref. 44,45), showing the film to be heterogeneous. Because of the low net charge on molecules, intermolecularattractive forces (van der Waals forces, hydrogen bonding) operate to cause the formation of discrete clusters or "islands", separated by regions of very dilute gaseous film. On compression to lower areas, the surface potential becomes uniform over the whole surface, showing the film to be homogeneous (ref. 45).
Sim-
ilarly, as the pH is moved away from the isoelectric point, the region of instability of AV disappears even at the highest areas. An equation that has been used to assist in the interpretationof surface potentials is:
AV
q
4Tnu
(7)
,
where n is the number of dipoles (usually molecules) per unit area and u is the effective surface dipole moment in the perpendicular direction. The term p may in turn be interpreted by: r!=:cose
,
(8)
where E is an intrinsic moment making an angle e with the vertical. Eq. 7 has been derived by analogy with an equation attributed to Helmholtz for the potential difference between the plates of a parallel-plate condenser, assuming a surface film to consist of a planar array of dipoles. The limitations of this analogy have been stressed (ref. 46); for example, it is assumed that the dielectric constant is unity and the contribution to AV of reorientation of subphase molecules is ignored. However, the equation has been found to be useful. Frequently, the term AAV (which is proportional to p) is plotted as a function of A. By studying the variation of AV with pH for protein monolayers, it has been established that it is the contribution of the ionogenic side chains which is pH dependent (ref. 47).
Fig. 4 shows a comparison between the AV-pH curve at
356
2
6
4
a
PH Fig. 4. II-pH and AV-pH curves for insulin films on subsolutions of ionic strength; r/2= 0.01, together with the electrometric titration curve (ref. 45).
an area of 2 m2mgs1
for an insulin monolayer
0.01 and the electrometric*curve Epstein
(ref. 48).
on a substrate
for this protein
The similarity
for different
groups
is apparent
face pressure
at the isoelectric
is striking
in the AV-pH
measured
of ionic strength by Tanford
and
and the pH range of ionization curve. The minimum
point of the protein
in the sur-
is also illustrated
in
Fig. 4.
In general, AV and AAV increase with decrease of area as a protein monolayer is compressed. being oriented
Increase of AAV suggests more vertically
becomes close-packed tends to plateau pression
and segments
More detailed
compressed
films.
B. Surface
rheology
the manner
Two types of surface
studies
shear and dilational.
whereas
bulk or expansion
viscosity
high surface
dilational
by the flow through
are
AV com-
potential
changes
should prove help-
changes
occur
in these
for protein monolayers,
shear viscosity interfacial
of three-dimensional
(ns) has been measured
pressures
have been measured
Two-dimensional
three dimensions,
on further
of how the surface
in which configurational
viscosity
side-chains)
once the monolayer
begin to be pushed out of the surface,
films are held at constant
ful in interpreting
cosity
(ionized
However,
(ref. 45,49) and AAV falls off dramatically
(ref. 50).
as protein
that dipoles
on compression.
is analogous
viscosity fluids.
to that for
corresponds
to the
Shear surface
a canal under a surface
ViS-
357 pressure
qradient
(ref. 51) or by the torque on a ring or cylinder
(ref. 52) or oscillating
(ref. 53) in the surface.
fined in terms of the differences similarly
it is not strictly
cules from that of substrate protein which
studied,
viscosity
rate).
viscosity
is treated
energy
barrier.
where
The expression
to another
obtained
of the non-
Joly applied
of flow units
the theory
In this theory,
(normally
over an intermediate
for the coefficient
above
on shear
mole-
activation
of surface
viscosity
is:
k exp
(AG+ WA) kT
h = Planck's
is associated
(91
' constant
with:
and AG is
molecule
the activation
1) the work required
ently large for the molecule
done against
to form a hole in the surface
Joly concluded pearance
pressure
their size practically calculation
behavior
independent
of the activation
the area of the elementary based on the Moore-Eyring
of ns for all proteins
are summarized
Joly determined
flow units.
calculated dently,
independently
the molecules
in which
As a result,
(ref. 53) that keto imido hydrogen Thus, polyproline
gave no measureable
appear
ns, while
bonding
for other
contributed
These
and the value
in solutions
of molecular Evidence
largely
Evi-
so that segments
This is similar
no keto imido hydrogen polyaminoacids
acid
good agreement.
to diffuse
independent
65 and 69 kJ mole-‘.
in which
120 i2)
flexible
move as units.
AG and ns are approximately
Values of AG (Table 3) fell between
viscosity,
for AA (loo-
are sufficiently
long chain hydrocarbons
but still values of AA,
of plots of log ns vs. n,
The values
(on the average)
approach
and one polyamino
by Joly (90 fi2) are in remarkably
of 6-8 amino acid residues the manner
respectively,
in the monolayer
From a direct
(ref. 53) calculated proteins
and
a value of about 90 i2 for
Using a different
theory, MacRitchie
in Table 3.
at the point of ap-
of the nature of the protein.
the area of the flow unit and AG for several
results
to break all bonds
work that has to be
that all the flow units were submolecular
energy,
from the slopes and intercepts,
suffici-
to move the
to create a hole.
from the constancy
of non-Newtonian
the work required
naA is the additional
molecules.
the surface
free energy at zero II. AG
to move into; and 2) the work required
into the hole, this term including
formed with neighboring
56).
pressure,
(ref. 55) to the data.
as a movement
position
surface and
of film mole-
depended
ns at the point of appearance
of Moore and Eyring
from one equilibrium
=
surface
viscosity
was of the same order of magnitude.
the flow of a monolayer
%
and different
(i.e., calculated
for all proteins,
cules)
(II,)
the contribution
de-
(ref. 54) showed that for each
Joly
there was a well defined
viscosity
for surface
the clean and film-covered
to separate
molecules.
was non-Newtonian
However,
Newtonian
between
possible
rotating
As with IIand AV, qs is
to (ref.
weight.
was obtained
to the surface bonding
and proteins
is present
ns decreased
358 TABLE 3 Calculated values of AA and AG for proteins and one polyamino acid (ref. 53) Protein
AA
(nm*)
(kJ’Zole-1)
Polyalanine y-Globulin Pepsin
1.5 160 34
1.05 1.10 1.20
8; 67
BSA Lysozyme
70 15
1.00 1.15
:;
dramatically with increasing electrical charge. Assuming a flow unit of seven amino acid residues, the maximum number of hydrogen bonds which could contribute to AG would be seven, remembering that each residue forms two bonds but that each bond is shared by two units. A hydrogen bond energy of just over 9 kJ mole-' would then account for most of the measured surface viscosity. Measurements of nd are normally obtained from methods based on either continuous (ref. 57) or periodical (ref. 58) compression or expansion of the monolayer covered surface. In recent times, more attention has been given to dilational than to shear surface viscosity of protein monolayers. This is justified because interfaces are more often subjected to dilational rather than shear stresses. Interfacial dilational measurements would thus be expected to be relevant to emulsion and foam stability and to biological membrane systems. Pertinent studies are those of the apoprotein of the Folch-Lees proteolipid (FPi) from myelin (ref. 59) and of mixed tubulin&lipid monolayers (ref. 60).
Protein monolayers exhibit
viscoelastic rather than pure viscous behavior. For FPi monolayers, nd increased with IIin the range 37- 50 surface poise. The results indicated that,if during compression of a mixed monolayer of FPi with dipalmitoyl lecithin, energy dilssipationoccurs, it may be assigned to the protein constituent. This may be the situation in biological membranes and the alveolar lung surfacant. It was suggested that the energy dissipation results from changes in conformation of the FPi molecules (such as formation of loops and tails). In view of the previous discussion (Part IV-C),
this appears to be a realistic conclusion.
For the peripheral membrane protein, tubulin (the subunit protein of cytoplasmic microtubules), the relaxation time calculated from dynamic measurements was about five times lower than that of other protein films. The suggestion was made that this may be related to the role of microtubules in conferring mechanical stability to membranes and other cellular structures. C. Transfer of film In certain cases, it is advantageous to remove protein films after compression for more convenient examination elsewhere, For example, this method has been
359
used to study the concentration of radioiodinated BSA at the surface (ref. 61) after removal on glass slides. If a clean glass slide is lowered through a surface containing a compressed protein monolayer, no change of surface pressure is observed. On raising the wetted slide, a decrease of IIoccurs as monolayer is transferred to the slide. If the pressure is maintained constant, comparison of the decrease in area of the monolayer with the surface area of the slide shows that the film is transferred quantitatively (i.e., a transfer ratio of unity). For radiolabelled proteins, concentrations can then be determined by direct measurements in a scintillation counter. One precaution to be observed is to allow for any decrease in radioactivity,greater than the normal decay, caused by the surface (see Part VI-B). A number of different techniques have been used to study the conformation of protein and polypeptide monolayers after removal from the surface, either as collapsed or uncollapsed films. Loeb and Baier (ref. 62) deposited polymethyl glutamate (PMG) monolayers at constant pressure directly onto germanium prisms suitable for multiple internal reflection spectroscopy in the infrared. Spectra characteristicof both the a-helical and B conformdrtions were found; they were independent of the degree of composition but depended on the spreading solvent. Films spread from chloroform-pyridinesolutions containing at least 60% chloroform and collapsed onto AgCl plates for study by direct transmission IR spec-1 amide 1 and 11 absorption peaks at 1654 cm-l and 1550 cm ,
troscopy showed the
respectively,which is characteristic of both the a-helical and random coil conformations. As the pyridine concentration in the spreading solvent was increased,the monolayer spectrum showed increases in intensity of bands at 1625 -1 -1 -1 cm and 1520 cm at the expense of the 1654 cm and 1550 cm-l bands, respectively. Amide 1 and 11 absorptions at 1625 cm-' and 1520 cm'l bands are associated with the extended chain 6 configuration of polypeptides. The behavior is illustrated in Fig. 5
for films that had been removed after compression beyond
the monolayer collapse point. Similar results were obtained for this polypeptide by Goupil and Goodrich (ref. 63) who also used a suitable choice of spreading solvent to vary the conformation and infrared spectra of films transferred OntO
germanium prisms by the Langmuir-Blodgettmethod, They also showed how sur-
face viscosity measurements could be used to differentiate between the a and 8 conformations. It was postulated that a surface film of folded, independent rods (a-helix structure) should be less viscous than a coherent interlocked
chains
(B-structure).
set of unfolded,
This appeared to be the case,
The tempera-
ture dependence of the surface viscosity was different for the two conformations. The B conformation was characterized by a high surface viscosity which fell with increasing temperature, possibly due to weakening of the intermolecularhydrogen bonding. On the other hand, the surface viscosity of the polypeptide in the u
360
Wavenumber
cd
Fig. 5. Infrared spectra of collapsed films of PMG spread from _. spreading solutions of varying chloroform/pyridine content. Numbers on the figure refer to percent chloroform in the spreading solution (ref. 62).
form showed a relatively
low surface
increasing
This was thought
temperature.
viscosity
which
increased
irreversibly
to be due to conversion
of the
with
CL to
the B structure. An extensive
study of the conformation
moval of compressed
surface
By means of infrared
of synthetic
films has been carried
spectroscopy,
polypeptides
out by Malcolm
it was shown that material
face films of a range of polypeptides
was in the a-helical
addition
introduced
method
to infrared
spectra,
for monitoring
of requiring information. men is low.
Malcolm
the conformation.
very small amounts Infrared
spectra
Electron
of material
electron
after re(ref. 64,65).
removed
diffraction
diffraction
The study of transferred
In
as another
has the advantage
yet giving detailed
conformational
are more useful when the crystallinity
bility exists that conformational
from sur-
conformation.
of a speci-
films is an indirect method and the possi-
changes
may occur on removing
the film from the
surface,
In order to check this point, Malcolm developed a method for studying
deuterium
exchange
in polypeptide
monolayers
peptides were spread at the surface sion, dried and the infrared mined
from the relative
spectra measured.
strengths
(ref. 65).
for measured
times,
The N-deuterated
poly-
removed after compres-
The extent of exchange was deter-1 of the NH and ND stretching bands at 3300 cm
361 and 2400 cm where
-1
confirmatory
Rates of exchange
, respectively.
hydrogen
bonding
evidence
for the a-helix where
bonded and would not be expected Most of the conformational
form, proteins
only partially
studies
red spectra of paramyosin
polypeptide
amounts
of the molecule
technique
known, whereas
as a rough
index of conformation.
found for transferred compared
after spreading
proporthe infra-
contains
and
is one of
appreciable
The ratio of absorb-
to that at 1655 m-l (a and random) was taken Values
for this index of 0.6 and 0.9 were
monolayer-s of paramyosin
and s-lactoglobulin, solution
results were taken to mean that the B structure proteins
in
as monolayers
Paramyosin
at 10 mNm-'.
s-lactoglobulin
to 1.1 for residue from the spreading
by spreading
pro-
have their chains
larger or smaller
in the B and random chain forms.
ance at 1635 cm -' (B configuration)
on model
Loeb (ref. 67) has measured
and B-lactoglobulin
proteins
intramolecularly
chains may exist exclusively state generally
form, with relatively
by the Langmuir-Blodgett
the most helical
groups are
with water molecules.
in their solution
in the a-helix
this was taken as
to date have concentrated
tions in the 6 form or random structure.
transfer
peptide
to exchange
Whereas
teins, the polypeptides. the a-helix
were much slower than in polymers
to water can take place; therefore,
respectively, The
of s-lactoglobulin.
does not appear
at the surface and that the a-helical
to be induced
structure
is main-
tained as found for the polypeptides. Optical
rotary dispersion
(ORD) and circular
to study the confortmttion of polypeptides CD has been applied
to the study of corresponding
plates by the Langmuir-Blodgett aligned
identically
L-alanine
the film balance.
the orientation
True OD spectra, at numerous
The results were consistent in the a-helical of the incident
light.
copy after transfer
monolayers
(ref. 68,69).
exhibited
deposited
and unlabelled
expected
has been examined to quartz
plates
and B-sheet
molar absorptivity
protein.
a planar sample
explained
or changes
effects
light beam.
of polypeptides to the direction
by UV and CD spectros(ref. 69).
CD spectra
in the film oompared
of 11,950
It was proposed
of
were obtained
1 mole cm"
to values of 9,100 and 9,600 for isotropic
from the effect of orienting by solvent
properties
with the helix axis perpendicular
amount of a-helix
194 nm was found compared
which could
chains on the surface
about the axis of the incident
B-lactoglobulin
on quartz
films of poly-
free of the linear component,
with the optical
An enhanced
Recently,
When all plates were
linear dichroism
of the polymer
from a film balance
an increased
of labelled
angles
conformation
that in solution,
(CD) have been used
in solution.
in the light beam of the spectropolarimeter,
be used to determine
suggested
method
and poly-y-methyl-l-glutamate
on films oriented
dichroism
and proteins
to
at 193-
solutions
that this results
mainly
in the light beam and could not be
in conformation
of the protein.
Measurement of contact angles after transfer of protein monolayers to Langmuir-Blodgettslides is another technique which yields useful information on the orientation of polar and non-polar groups (see Part IV-D). D. Direct optical methods Spectroscopy has been a powerful tool for studying molecular structure in bulk solution. Because of the small amount of material present in a monolayer, some method must be used to amplify the spectral signal. One approach is to use parallel mirrors to pass light through the film many times. An example of this technique applied to protein monolayers is the interesting study of films of oxyhemoglobinsA and S at the air/water interface (ref. 70). As mentioned (Part IV-D), these hemoglobin variants display different surface behavior as evidenced by their tendencies for mechanical precipitation. Absorption maxima were shifted from the solution value of 415 nm to 419 nm for both HbA and Hbs, consistent with a conformationalchange in the direction of greater unfolding, although shifts were the same for each. These Soret band maxima did not shift on compression of the films. It was noted, however, that surface isotherms were more expanded for HbS than HbA, indicating a greater unfolding. Ellipsometry is a sensitive method for measuring the thickness and refractive index of thin films at surfaces. The technique has been mainly used for studies of films adsorbed from solution (ref. 71,72) but can be applied equally well to monolayers. De Feijter et al. (ref. 73) compared measurements of surface concentrationsof protein monolayers by ellipsometry with results for two other independent techniques: 1) a spreading technique by which known amounts of protein are spread on a known area of surface; and 2) a radiotracer method using radioactively labelled protein. For B-lactoglobulin,two different spread-2 calculated from the amount ing experiments gave values of 0.98 and 1.09 mgm -2 spread and 1.00 and 1.05 mgm calculated from ellipsometer measurements. For -2 -2 by the radiotracer a-casein, ellipsometry gave 2.5 mgm compared to 2.7 mgm method. From these figures, the reliability of ellipsometry is evident.
In view of the inherent uncertainty in drawing conclusions from measurements on films transferred from monolayers (particularlyin relation to conformation determinations),there is a need to develop further the direct methods for examining protein films _in situ. These methods have the great advantage that the films can be manipulated and measurements made as a function of different variables such as surface pressure and time. Techniques such as those developed by M6bius and co-workers, including enhanced light reflection (ref. 74) for direct measurements as well as quenching of fluorescence (ref. 75) for transferred monolayers may prove valuable for studying mixed monolayers and two-dimensionalreactions of proteins.
363 VI.
DESORPTION The question
FROM MONOLAYERS
of whether
a controversial
adsorption
that it is an irreversible monolayers,
despite
and Schaeffer
process
of a monolayer The equation
= akT
increase
per cm* at the surface
with the film. 2 -1 on the surface 1 m mg
and c is the concen-
According
There-
10s8.
to this, an increase of film pressure
between
of compressed
and has a molecular
o would have a value of 2.85x
of the film by a factor of 10 g5. The
the solubility
lack of correspondence
the great stability an argument
to the
in equilibrium
fore, at 20°C, dln c= 220 dn. of 15 mNm -' should
pressure
(11)
(e.g., ovalbumin),
of 35,000
from
Langmuir
solution.
theory of the effect of surface
,
in solution
apparent
held belief proteins
(ref. 77) (based on the Gibbs equation)
For a protein which occupies weight
of desorbing
used was:
where u is the number of molecules tration
or not has been
a widely
of many in aqueous
a general
case of proteins.
is reversible
that has prompted
is the difficulty
the high solubility
(ref. 76) applied
on the solubility
dn/dlnc
of proteins
One observation
topic.
the predicted
solubility
protein monolayers
in support of the irreversible
increase
has been considered
nature of protein
and to be
adsorption.
A. Kinetic measurements Langmuir of proteins
and Waugh
and their enzyme
sure displacement
pressure
expulsion solubility
effects of increasing
of portions involves
displacement
of molecules
desorption
on monolayers
They distinguished
between
pres-
is equivalent
in Part IV-C,
discussed
of complete
times in solution
of monolayers
of compression
Pressure
solubility.
digestion
sures on the solubility
the effects
(pepsin) digests.
and pressure
to the reversible whereas
(ref. 78) studied
molecules.
and increasing
of insulin and its digests
The
surface
pres-
are summarized
in Table 4. With increasing
digestion
These are the figures reference
pressure
time, losses of material
in the first row at n=mNm-',
for measuring
refer to the loss of monolayer originally
For ovalbumin,
relatively
initial molecular A preliminary
as a percentage
lower proportions
conditions
Other figures
of the total material
to compression
for 10 min. periods.
of pressure-soluble
than for insulin,
theory
consistent
material
were
with its higher
to explain
This theory
pressure predicted
solubility
was proposed
that polypeptides
If pressure solubility
is observed
between
by Langmuir
should show pres-
in the range II= 5 to 10 mNm-' when the molecular
1200.
increased.
weight.
(ref. 78).
sure solubility proximately
expressed
spreading
losses of monolayer.
spread when films were subjected
found under comparable
and Waugh
permanent
during
which was taken as the
weight
is ap-
II= 20 and 25 mNm-',
364 TABLE 4 Losses of monolayer for insulin and its peptic digests during spreading and 10 min. compressions at different surface pressures. The first row (1 mNm-I) gives the amount of protein (as a percentage of total spread) lost during spreading. The last row (residue)gives the amount of monolayer (as a percentage of total spread) remaining after spreading and compression at each of the six pressures (ref. 78). --."-1 (mNm )
Time of digestion 21
0
: 10 15
!*': 5:2 3.0 87.0 --
a molecular
weight of ca. 1700 is indicated.
tion products
of insulin
had molecular
The first quantitative
measurements
tein monolayers
were reported
Because of the superimposed pressure sured
displacement
a given pressure. face pressure
relaxation
by Langmuir
higher surface 79) therefore of area. constant
However,
process described
and Waugh),
desorption
(15 mNm-' and above). pressure
for a measured
The permanent
(called
be simply mea-
of surface
recoverable
area at
at low sur-
losses are only observed Gonzalez
(A,),
and MacRitchie
at
(ref.
permanent
losses
After maintaining
time, the surface was completely
(area A).
in Part IV-C cannot
of 5 mNm-I to monitor
at 5 mNm-I
from pro-
(ref. 79) for BSA.
by the decrease
losses of area are totally
The area was first measured
that the degrada-
in the range l,OOO- 2,000.
and MacRitchie
substances)
chose a reference
pressed to 5 mNm-'
::: 4.5 3.0 1.7
of the kinetics of desorption
(10 mNm-I and below) and permanent pressures
70 4.5
It was concluded
weights
by Gonzalez
(as with other monolayer
52
46 1.4 4.0 10.9 7.6 4.3 25.8
i.7
22: residue
in hours
expanded
n
and recom-
loss of area was then given by
A,-A. Two checks were used to determine due to desorption.
tion of time at a fixed pressure BSA in the subphase.
whether
the permanent
concentration
the rate (in the presence system continued
the idea that desorption
Initially,
gentle
of
the kinetics of
stirring
the rateand with
the rates were the same but after a time,
of stirring) to decrease
increased,
The second check was to compare
time curves at this same value of IIwith and without no BSA in the subphase.
as a func-
of 25.6 mNm-' with varying concentrations
As the subphase
area loss slowed as shown in Fig. 6.
stirred
area losses were
In the first, rates of area loss were measured
became constant
while that in the un-
with time (Fig. 6).
was the cause of the permanent
The results area losses.
support
365
P
I
1
40
80 (min)
Time Fi
. 6. Rate of desorption-time curves for BSA monolayers at 25.6 mNm-I pressure. 3 : no protein in subphase no stirring; (o ): stirring; (A): 0.008% BSA in
!.:bphase; (A):
In desorption
0.05% BSA in'subphase;
from monolayers,
between the monolayer
an equilibrium
and an adjacent
In the absence of convection layer
(0): 0.10% BSA in subphase
(which is maintained
is usually
thin subsurface
and back-diffusion,
at constant
t, is then given by the corresponding
established
diffuse
from this
to the bulk phase,
n, of molecules
equation
rapidly
layer of bulk solution.
molecules
concentration)
The number,
ially at zero concentration,
(ref. 79).
that desorb
from classical
init-
in a time,
diffusion
theory
(ref. 80):
n = 2c,
IT I i DJ
l/2
iw
,
where co is the subsurface is 3.14.
concentration,
The rate of desorption
D is the diffusion
at any time, t, follows
coefficient
and
II
of
by differentiation
Eq. 12:
t-1/2 Gonzalez several
(13)
and MacRitchie surface
did not extrapolate diffusion
(ref. 79) plotted 2
pressures. to zero.
This is consistent
but with an energy barrier
the slopes,
vs. t-1'2 for BSA monolayers
The plots were linear although
with a process
to the desorption
values of co (the steady state sublayer
lated and are shown in Table 5, together
at
lines of best fit controlled
step (ref. 81).
concentration)
by
From
were calcu-
with values of co, at corresponding
366 TABLE 5 Calculated
subsurface
concentrations
n
of BSA (ref. 79) C
cO
(from &d;;ption
(mNm-l)
(from adiorption isotherm)
(g cms3)
(gem -3 1
28.8
1.28 x 1O-6
5.5 x 10-2
27.2
1.94 x 1o-6
2.2 x lo-2
25.6
4.86 x lO-7
9.1 x 10-3
24.0
2.62 x lO-7
3.8 x lO-3
22.4
5.7 x 10-8
1.6 x lO-3
pressures,
from the equilibrium
ancy between
adsorption
isotherm of BSA.
the two sets of values for co is confirmation
The large discrepfor the existence
of an energy barrier at the surface. Returning protein
to the results
in the subphase,
and the desorption interface, diffusion
shown in Fig. 6, it can be appreciated
the concentration
rate would be expected
there is a stationary only.
tionary
to decrease,
conditions.
layer, where material
we can calculate
in thickness.depending
Near every occurs
by
on the type of inter-
For the results of Fig. 6, the introduction
gradient
is carried
the thickness
is lowered
as observed.
causes the rate of area loss to become constant
At this point, the concentration
that with
near the surface
layer through which mass transport
This layer varies
face and the stirring of stirring
gradient
has extended
after about 30 min.
to the edge of the sta-
away by convection.
of the diffusion
layer
For this example,
(6) from the equation:
(14) Using values of 6.0 x 10e7 cm2 set -' for D, the diffusion coefficient of BSA -7 -3 (ref. 82), 4.86 x 10 for co (from Table 5) and zero for c, the effective g cm concentration
at the edge of the diffusion
lated for 6.
Values for the width of the stationary
have been found to vary between about 0.03
mm where
stirred
vigorous
subphase
We may utilize -1 to estimate mNm the equation:
stirring
thus appears the results
layer, a value of 0.08 mm
1.0 mm for unstirred
is used (ref. 84).
is calcu-
layer in aqueous systems
solutions
(ref. 83) and
The value of 0.08 mm for a
to be of the right order. for the steady state desorption
the magnitude
of the energy barrier
of BSA at 25.6
to desorption
by applying
367 dn _ 'o --R1+R2 dt where
(15)
’
RI is the diffusional
resistance
and R2 is the interfacial
is equal to i and thus has a value of 1.3x lo4 set cm for g
and co gives a value for R2 of 2.4x lo* set cm
the kinetics
of desorption
in controlled probable
mainly
to a cooperative
must leave the interface
B. Radiolabelled
protein
bility of monolayers
as it provides
losses of compressed
monolayers
the absolute
rate
It appears
resistance.
step in which all segments
of a
a reliable
method
for studying
way of determining
configurational and labelled
changes
the sta-
if permanent from the surface
or coagulation.
with 1251 was carried
A out by
(ref. 8). Permanent losses of area were -1 of 18 mNn and above. Monolayers were compressed
and maintained
then expanded
and recompressed
the permanent
loss of area before
samples
compression
was measured
at constant
to a reference
of the monolayer
and radioactivity
repeating
pressure pressure
in r~ corresponding
together with the measured remained
successive
For example,
for 20 min. periods, -1 to determine
of 10 mNm
the cycle.
For the radiolabelled
were removed on glass slides
in a scintillatian
counter.
cycles are shown in Fig. 7 for radiolabelled
Radioactivity following
although
simultaneously.
is a valuable
of BSA unlabelled
at pressures
to a given pressure
decreases
Therefore,
RI
of values
and Ter-Minassian-Saraga
only observed
protein,
.
are due to removal of molecules
such as molecular
study of monolayers MacRitchie
Substitution
proteins
The use of radiolabelled
or to processes
-1
resistance.
.
of diffusion,
by the much larger interfacial
that R2 is related
given molecule
show the influence
-1
(see Part V-C)
Examples of the
BSA at 21 mNm-'.
The
to the removal of slides at 10 mNm-' are shown -1 -2 counts in min cm for the transferred films.
constant
compression
within
experimental
cycles,
error at all pressures
as also did film compressibility,
after
losing 68.6% of the film at 27 mNm-I, the specific activity -1 -2 counts min cm compared to an average value of 3620 counts
was 3720+400 -1 $2 min for measurements gimes) at 10 mNm-'.
on 18 slides of BSA films
This is consistent
the remaining
monolayer
from analyses
of radioactivity
being unchanged.
(removed after varying
re-
with an area loss due to desorption, Confirmation
in the subsolution
of desorption
was obtained
after a known loss of material
from the surface. From results
such as those in Fig. 7, it is possible
to separate
sible and irreversible
area losses at a given pressure.
tracting
loss (from the area change at 10 mNm-')
the permanent
loss (measured at the high pressure over the 20 min. period). shown in Table 6.
the rever-
This is done by subfrom the total Some values are
368
125 Fig. 7. Compression-expansion (not shown) cycles for I-labelled BSA monolayer held for 20 min. periods at 21 mNm-I. A is in arbitrary units. Surface area may be calculated from the fo mula: area= 8.33At10.7 cm2. Amount of protein spread= 80 1 of a 0.62 mgml -1 solution. The numbers correspond to the measured counts min- y cm-2 for the films transferred onto the glass slides (ref. 8).
TABLE 6 Reversible changes tervals at various
and irreversible losses of BSA monolayers surface pressures (ref. 8) Decrease
II
(mNm
-1
of film area
Decrease (total)
during
20 min. in-
(% of total) Change++ (reversible)
Loss+
:Y
22 51.5
:
44.5 21
z': 30
80.4 71.5 82.2
9 15 18
62.5 65 65
'Determined
tt
Difference
One
at n= 10 mNm-' between
total decrease
and loss (columns 2 and 3)
factor that needs to be allowed
proteins
is the possible
relatively
for in surface
rapid decrease
natural decay rate) when they remain at the surface of about 2% per hour was reported face catalyses
a reaction
stancy of specific losses
implied
in which
activity
in this work. iodine
using
in radioactivity
It was suggested
BSA film following
(calculated
I-labelled (above the
for long periods.
A decrease
that the sur-
is lost from the surface.
in the labelled
that the tagged molecules
studies
The con-
irreversible
to be only one in 90 of
area
369 the total) desorbed
at the same rate as the untagged
found that the sample of labelled above pressures altered
of 20 mNm
the protein
C. Desorption
in biological
monolayer.
sample had
y-globulin
and catalase
A striking
the mixed
films are initially
The area coverage
of insulin
The rate then deviates
and catalase.
is one
identical
from the surface,
(T-globulin
studied
is that the rates from
was
to 25- 30%.
film, the area approaching
value, the desorbable
(min
after spreading
is reduced
or catalase).
leaving a monolayer
Time
of 17.5 mNm-I,
to those from a pure insulin monolayer.
until the coverage
at this moderate
and
is il-
loss of area over long
behavior
in the mixed films immediately
protein
for from
B-lactoglobulin The behavior
At the pressures
show no permanent
from that of the pure insulin
that of the non-desorbable
tively removed
(ref. 85).
of insulin at a pressure
feature of the desorption
50% and the rate is constant
ing the film pressure
of two proteins,
has been studied
with y-globulin
periods.
processes
(lipids and other proteins)
useful to know how a pure protein desorbs
in Fig. 8 for the desorption
alone and in admixture
about
treatment
systems and industrial
The desorption
from mixed monolayers
(~20 mNm-I),
faster than the unlabelled
that the labelling
compete with other compounds
It is therefore
a multicomponent
lustrated
BSA desorbed
This suggests
it was
in some way.
situation
proteins
the interface.
insulin,
.
However,
from mixed monolayers
The practical in which
-1
ones.
Thus, by maintaininsulin
is effec-
of the pure component
that
1
Fig. 8. Log A-time plots for desorption of insulin from its pure monolayer (0); from a mixed monolayer with T-globulin (0); and from a mixed monolayer with catalase (0) at 17.5 mNm-I on pH 7.3 buffer. Dashed line corresponds to area of pure v-globulin and catalase monolayers (ref. 85).
370 is non-desorbable
at that pressure.
for mixed monolayers 86).
It evidently
the sublayer systems
arises
This behavior
desorbable
because
to date,is
layer providing
the concentration
practically
its surface coverage
low this coverage,
is greater
to maintain
at different
surface
for mixed
films are relevant
occurring
in blood clotting.
cesses across
interfaces
in
and, for the
from the monolayer concentration.
are summarized
to competitive
protein
pressure
alone and in admixture
pressures
(ref.
of the mono-
than 25- 30% of the total.
the sublayer
adsorption
Some results
in systems
The results
such as those
for transport
where multicomponent
Be-
to the
with non-desorbable
in Table 7.
They also have implications
or membranes
compounds
of the composition
the rate of supply of molecules
is insufficient
to be quite general
of desorbable
by the surface
independent
for films of insulin and B-lactoglobulin components
appears
and non-desorbable
(co in Eq. 12) is determined
studied
sublayer
containing
pro-
films are present.
TABLE 7 Rates of desorption of insulin and B-lactoglobulin surface pressures on pH 7.3 buffer (ref. 85). Monolayer
from monolayers
Rate of desorption 15+
Pure insulin Insulin - DPPC Insulin - y-globulin Insulin - catalase
17.5+
zo+
pressure
The displacement
and catalase
trolling
desorption;
Whereas
(Fig. 8), provides namely,
insulin
Z
at surface
size.
The same is suggested
of several
desorption
products.
proteins
by the MacRitchie
spanning
a range
where the rates could be conveniently
in Table 8.
it can be seen that as the molecular
the rate of desorption
y-
to one of the factors con-
and their degradation
pressures
Results are summarized
by the large proteins,
a pointer
the molecular
the rates of desorption
weights
In general, creases,
14 15
weight
and Waugh on proteins
(ref. 85) studied
measured.
11 12
30+
:; 60 61
22: 26
of the small protein
globulin
of molecular
27.5+
(mNm-')
D. Effect of molecular
work of Langmuir
(min-l x 103) 25+
24 ; 6 6
Pure 6-lactoglobulin s-lactoglobulin - DPPC +Surface
at different
at a given surface
weight of the protein pressure
decreases
in-
markedly.
(molecular weight 6,000) is large enough to be -1 measured at a pressure of 15 mNm , the larger-sized proteins such as y-globulin -1 and catalase are stable at this pressure and require pressures above 30 mNm for comparable
of insulin
desorption
rates.
In most studies of protein monolayers,
it is
373 TABLE 8 Rates of desorption
of five proteins
Mol. wt (x 10-3) Insulin B-Lactoglobulin Myoglobin y-Globulin Catalase
unusual belief
6 17.5
15+
ZO+
56
530 20
25+
30+
50 34
90 67 9
:;0 230
pressure
pressures
(ref. 85).
35+
40+
45'
144 20 30
40 70
110
(mNm-')
for this higher range of pressure that protein
stability
surface
Rate of desorption -1 (min x lo4
Protein
'Surface
at different
adsorption
at lower pressures)
to be investigated.
is irreversible is therefore
The widely
(based on observations
understandable,
although
held
of their unjustifiable.
E. Theory of desorption In any explanation
for the observed
desorption
behavior
of proteins,
the
following results need to be considered, Most proteins are stable up to 15 -1 mNm and desorption is not usually detectable below that surface pressure; this despite ficient tion.
the fact that equilibrium
equilibrium Above
concentrations
15 mNm_l,
than would be expected trations,
indicating
stantial magnitude. as molecular
weight
adsorption
desorption
can be measured
from calculations
the existence
would
predict
to cause measurable
suf-
desorp-
but rates are appreciably
using the equilibrium
of an energy
From a comparison increases,
isotherms
in the sublayer
sublayer
less
concen-
barrier at the surface of sub-
of different
proteins,
the rate of desorption
it appears
that,
at a given surface
pres-
sure decreases. An attempt
to quantify
been made by MacRitchie
the free energy barrier
(ref. 34).
step is taken to be a molecule of ca. 1 nm2.
process,
The transition
whose trains
This is the calculated
for a protein molecule
to adsorb.
when a protein molecule
equilibrium
and there may attain
It is therefore is compressed
trains,
is a finite probability the transition
configuration fluctuation
between
energy
required
assumed
occupy an area to be cleared
that in the reverse
to this area,
it is no longer
pressure,
state.
fluctuations,
At low pressures,
there is a (see Part IV-C)
individual because
molecules
the average'
in the form of trains,
be prohibitively
has
in the desorption
segments)
At any surface
that through
for this would
of proteins
loops and tails of a molecule
is one with nearly all segments required
complex
(adsorbed
area of surface
stable at the surface and will desorb. dynamic
to desorption
the energy
high and the probability
372 almost zero.
However,
the form of trains A quantitative
estimate
given surface
pressure
tein (see Fig. 3). required
to compress
(nc) at which
I
pressures
Adn
of the free energy barrier
to desorption
the molecule
required
(aGdes) at a
II-A curve of the pro-
to remove a molecule
from the given pressure
it occupies
in
increases.
an area of ca. 1 nm*.
will be that
(II,) to the critical This is given by:
.
(16)
e
The integral appropriate
can be evaluated
from the area under the n-A curve,
limits of Il. Because
of the sigmoidal
this area (and thus the free energy) rapidly
as Re increases
different
surface
constants
for desorption,
are compared desorption decreases
of such a fluctuation
C
AGdes = n
creases
where the proportion of segments
may be made from the equilibrium
The free energy
pressure
II
at surface
is much lower, the probability
pressures
15 mNm
-1 .
for BSA together
Some calculations
with corresponding
rapidly and attains
to the range of surface values relative
of AGdes at
measured
and MacRitchie
It can be seen that the appearance
rates corresponds
the
is very large at low values of ne but de-
above
from results of Gonzalez
in Table 9.
between
nature of the n-A curve,
rate
(ref. 79),
of measurable
pressures
at which ~~~~~
to kT where rate processes
become
significant. This simple theory appears tion.
to explain
significant compressed
desorption.
The rapidly changing
at higher surface
fewer trains molecules
per molecule)
of different
same distribution
pressures
causes
molecular
of segments
trains and hence the correspondingly consistent
with observations
REACTIONS
Many biological
trains,
reactions
proteins
ever
If we compare two
(at a given pressure)
the
loops and tails, the large mole-
of the greater
number of segments
larger area occupied
occur at interfaces.
participate
reactions,
trough or Wilhelmy-type
and control
by them.
Proteins,
as
This is
new instruments
phenomena.
reactions
Spread monolayers
In order to study
based on modifications
have been introduced.
with lipids,
of living cells.
of interfacial
and many enzyme reactions.
for these complex
film balance
together
the functioning
in a wide variety
respiration
simple model systems
interfacial
leaving
any when
(see Table 9).
which surround
such as blood clotting, provide
of segments
and assume
preclude
of molecules
IN MONOLAYERS
form the membranes
In addition,
pressures
~~~~~ to fall rapidly.
between
of protein desorp-
configuration
(expulsion
weights
cule will have a higher ~~~~~ because
VII.
the main features
The very large values of ~~~~~ at lower surface
of the Langmuir
TABLE 9 Calculated free energies of activation for desorption for desorption of BSA monolayers at different surface
n
Rate constant for desorption
AGdes/kT
AGdes (uJ molecule-')
(mNm-I)
(Atides) and rate constants pressures (ref. 34).
(gcm-2sec-1'2x 0 20 22.4 24.0 25.6 27.2 28.8
2.6 4.3 2.6 1.7 1.0 5.8 3.6
x x x x x x x
10 10 10 10 10 10 10
660 106 t:
lOI*)
0.42 1.83 3.50 7.50 9.17
24 14 9
A. Instrumentation Troughs
composed
one subphase
to another
the instrument ments
of several
have proved
of Fromherz
Each of the axles
be coupled
assembly
is connected
composed
thus compressing
monolayer
to be transported are separated
the trough.
This arrangement
and transferred
to another
may be quenched
by moving
occurring
where
reaction
over one or more compartments
tion of the monolayer by depositing Another
by walls which are slightly allows monolayers
important
development
monolayers. subphase, action
When lipid monolayers the reaction
is followed
area decreases compartment
products
at constant
according
The slope of the plot is directly expressed
no reactants.
by standard
become soluble
if enzyme
The
surface
trough
of enzyme
by lipases
techniques
introduced
present
away.
or
analysis.
reactions
in a conventional
curve of Fig. 9.
is
The composi-
chemical
and diffuse
pressure
a reaction
where reaction
for subsequent
by a small canal
it is
pressure.
Alternatively,
the kinetics
to the left-hand
trough connected
a linear plot is obtained
reaction,
containing
are hydrolyzed
surface
surface
when
an enclosed
lower than the edges of
has been the zero-order
Verger and de Haas (ref. 89) to measure
whereas
the
to be spread on one subphase
proceeds.
may then be determined
concentric-
to the frame,
enabling
from the subphase
one or more layers on slides
In
The inner axle may
the surface,
move together,
the monolayer
pivoted
barrier.
along the trough at constant
compartments
from
(ref. 87,88,89,90).
it is coupled
If
of monolayers
trough with eight compart-
of two axles
to a movable
to the outer axle, both barriers
transfer
useful
a circular
to the outer axle or the frame.
motor moves only one barrier, coupled
to allow
particularly
(ref. 87,88),
is used with a driving
ally.
compartments
by
in
in the
If the retrough,
the
By using a two-
(as shown on the right in Fig. 9),
is present only in the left compartment.
proportional to the velocity of the enzyme -2 -1 cm min since, in this case, the
in units of molecules
total number of substrate
molecules
accessible
to the enzyme
remains
constant.
37'4
First
order
,‘I
trough
1. 4
*
I
8 Time
Zero order
a.
12 min
I,
1 .
16
I 4
trough
I
I
I
8 Time
1
I
.
12 min
I
(
16
Fig. 9. Comparison between the recorded kinetic plots obtained with a standard trough (left) and with a "zero order trough" (right) (from ref. 90).
Most of the studies by having
on enzyme
the substrate
the subphase.
reactions
at interfaces
spread as a monolayer
Nevertheless,
some experiments
have been carried out
with the enzyme
in solution
using spread monolayers
in
of enzymes
have been reported.
B. Enzyme reactions
and retention
The usual procedure enzymes
for investigating
by transfer
to solution
vantage of this approach measured
It would therefore activity devised
of enzymes a method
and assay of the activity.
configuration.
in cell membranes be valuable
for measuring
to be studied.
or attached
in situ. --
the activity
spreading
The obvious
disadbeing
are known to function
to intracellular
interfaces.
these systems by studying
For this purpose,
the effects of surface
pressure
the
Skou (ref. 91)
of acetylcholinesterase
To avoid interference
on
film on a slide,
is not necessarily
Many enzymes
to try to emulate
as monolayers
layer state, which permitted unfolding
or collapsed
is that the enzyme activity
in its interfacial
incorporated
activity
the effect of surface
has been to remove the enzyme monolayer
followed
while
of biological
in the mono-
and the degree of
caused by dissolution
of enzyme
into the subphase
during
the monolayer
spreading,
ing) to a new compartment
of a multicompartment
new compartment
the acetylcholine
and samples reaction
contained
removed
occurring
The measured
preted
higher
pressure
was a maximum
times.
favorable
pressure
conditions
the measured of enzyme
and also with the surface
before compression
on further
enzymes
for maximum
was calculated
of the protein.
the orientation
was 10 mNm-I.
was inter-
off at lower and of side-
Under the most
time before compression
to be 51% of the activity
that this approach
in the monolayer
and 10 mNm'I),
of the same amount
frequency
after removal
does not give direct
protein molecules
after unfolding
in the two cases.
Skou
of enzyme
of enzyme with
There
is thus a
of the retention
of biological
films.
this type of experiment
Although
about activity spreading
revert
at the surface.
Although
ref. 92).
for each case to allow a more valid comparison.
from surface
of whether
up with studies
that the rate of collisions
factors
information
to the question
and whether
(see, however,
may be quite different
There have been a number of studies of proteins
has not been followed
state with those for equal amounts
it should be remembered
molecules
need to calculate
relate
to reflect
activity
spread as monolayers
activities
in solution, substrate
was assumed
The time
pressure.
in solution.
It seems surprising
compared
in this was stirred
of the enzyme
of the monolayer
of the degree of unfolding
(i.e., 30 sec. elapsed
activity
the kinetics
when this time was 30 sec., falling
The pressure
Optimum
chains.
The subphase This subphase
of the enzyme was found to vary with the time allowed
by the author to be a measure
The activity
(after spread-
to be measured.
before compression
at zero surface
trough.
substrate.
for assay, allowing
at the surface
activity
after spreading allowed
at intervals
was transferred
in the surface
of proteins
to their original
activity
state, it does
is a reversible solution
process
configuration
In some of the studies, a total loss of activity
has been found following
compl.ete spreading
are removed
films or fibers, care needs to be taken in interpreting
as collapsed
results as surface Part IV-D). activity antigenic
Other studies
may be retained activity
after spreading suction proteins
coagulation
Relatively
after taking
freeze drying.
after surface
of the soluble
spreading.
surface
and removal
most of the was recovered
by compression
(lo- 29%) were reported
losses caused
(see
and serological)
of paramecium
from the surface
When enzymes
in proteins
(enzymatic
For example,
proteins
small losses
into account
(ref. 93).
large changes
have shown that biological
as monolayers
(ref. 94).
itself causes
of enzymes
by the spreading
and
for three
solvent
and
376 C. Other reactions The unfolding molecular
of protein molecules
secondary
valence
molecularly,
this being favored
Furthermore,
reactive
ientation
groups,
of molecules,
layers, provide
previously
suitable
tively few studies of reactions been to measure of dissolved
changes
substances
with those on polyamino identify
at an interface
shielded,
attained
for high reactivity.
in mono-
There have been rela-
protein monolayers.
One approach
induced
in the subphase.
the effects
By comparing
The or-
possible
in II-A or n,-A characteristics
acids with various
inter-
in monolayers.
may become exposed.
to the high concentrations
in spread
causes intra-
These bonds may re-form
by the high concentrations
in addition
conditions
on spreading
bonds to be broken:
side-chains,
has
by the presence
it becomes
of proteins possible
to
the site of reaction.
Low concentrations (gelatin,
collagen
to show considerable interaction
of silicic acid in the subphase
and human serum albumin) hysteresis
served for a poly-DL-alanine tion of hydrogen
monolayer
bonds between
acid and the carboxyl,
viscosity,
protein monolayers
Because
the vicinity
of their isoelectric This is illustrated
(ref. 95).
(SiOH) groups of polymerized
technique
Proteins
either side.
curves
The
the same effect was ob-
groups of the protein.
of the silicosis
ns, is a useful
(ref. 53).
compression
and
, interaction was interpreted as the forma-
the silanol
amino and ketoimino
of this study to an explanation Surface
in successive
took place in the pH range 2-8.
caused protein monolayers
to become much less compressible
process was discussed. for detecting
show a maximum
points,
silicic
The relevance
decreasing
interactions
in ns at pH values
in in
as the pH is moved away on
in Fig. 10 for monolayers
I
of pepsin
(I.P.-2)
I
PH (A): BSA; (A): Fig. 10. Log no vs. pH for monolayers: glutamic acid; (o ): poly-L-lysine (from ref. 53).
pepsin;
(0): poly-L-
311 and BSA (I.P.
Poly-L-lysine
-4.5).
arly show a drastic
in ns as the electrical
decrease
This effect was thought
is increased. ular keto-imido
hydrogen
set up in the surface presence
and poly-L-glutamic
bonds as a result of the electrical
chloride
Protein monolayers
of metal
solution,
simil-
charge on the molecules
to be due to the breaking
(see Part V-B).
of low concentrations
0.001 M mercuric
acid monolayers
ions in solution.
a BSA monolayer
of intermolec-
repulsive
forces
are sensitive
to the
On a subphase
showed an increase
of
in no
(the value of ns when the log ns-R is extrapolated
to II= 0) of about 60 surface
poise (typical
Polyalanine
for a number of proteins
by this subphase similar
manner
whereas
to the proteins.
with the ionizable side-chains,
carboxyl
possibly
If lipid molecules is observed, is compressed, and decreases reversible.
polylysine
Polyalanine
that the structure
that the mercuric
some type ofcross-link
by Schulman
the viscosity with further
increases
increase
behaves
of polyalanine
in a
ion interacts
and Rideal normally
of surface
(ref. 97).
an unusual
effect
As the mixed
film
but then goes through presssure,
to the proteins
and lecithin.
acid
(cf. ref. 96).
into protein monolayers,
similarly
of the monolayer
was unaffected
acid were affected
groups on the protein or polyamino
are incorporated
first reported
for mixed monolayers
This suggested
and amino
forming
studied).
and polyglutamic
being
as shown in Fig. 11
The unusual
must be changing
a maximum
the behavior
behavior
shows
as it is compressed.
It
Fig. 11. Log ns vs. II for mixed monolayers of poly-DL-alanine and lecithin at pH 5.5; (0): polyalaning; (0): polyalanine-lecithin 4:l by weight; (A)polyalanine-lecithin 2:l by weight (from ref. 53).
378 was postulated between
that lipid molecules
the polypeptide
chains,
cause breaking
either
the net surface charge or by formation At low pressures comparatively however,
the effect
influence
VIII.
(high areas
becomes
the effect
bonds
increase of
bonds with the chains. is small because of the As the film is compressed,
of lipid molecules.
greater owing to the relatively
increasing
field of
of lipid molecules.
APPLICATIONS
In many natural
systems
(e.g., cell membranes,
the packing and conformation Monolayers
rect study. area occupied more,
hydrogen
steric effect,
of new hydrogen
per molecule),
low surface density
of keto-imido
by a simple
serve as excellent
per molecule
it can be varied
face pressure,
molecular
in a controlled
membranes
Membranes
have been studied. compartment
of protein monolayer
the
Further-
changes
may be followed.
in surA few ex-
studies
to practi-
here.
has been used by Verger and co-workers as surface
on the packing of membrane enzymes.
because
measured.
and the resulting
to di-
membranes
A direct approach spreadino
for these systems
and reactivity
applications
will be discussed
A. Biological
models
manner
conformation
dispersions),
is not easily amenable
at the surface can be precisely
amples of the many possible cal problems
protein-stabilized
of protein molecules
components
of intestinal
and catalytic
activity
trough by the Trurnit method
(ref. 5).
variables
of membrane-bound
brush border, human erythrocytes
They were spread from suspensions
cles, the amount of membrane
(ref. 98,99) by
films to study the effects of different
and -E. coli
of vesicles
on a multi-
Using 1251-labelled
vesi-
present at the surface was evaluated.
For intes-
tinal brush border membranes,
this was 25- 30% of the total amount
spread when
spreading
pressure
spread,
was at zero surface
the films were very stable.
proteins
spread from aqueous
and two brush border marker were assayed
was injected
and assayed.
tion of the experiment.
The specific
hydrolytic
the enzyme.
to that of pure
isotherms were measured and alkaline
phosphatase)
film by suction. out.
Films were com-
to a new compartment,
subphase,
Aliquots
No detectable
(i.e., no desorption)
the intact vesicles,indicating
is similar
were also carried
into the stirred
into the subphase
did not damage
activity
rinsed and transferred
were taken at intervals activity
Compression
(aminopeptidase
after removal of the surface
to 15 mNm_l,
substrate
This behavior
solution. enzymes
Kinetics of aminopeptidase pressed
and only 11% at 21 mNm -' (ref. 98). Once
activity
that spreading
of the subphase
release of aminopeptidase
was observed
during
the dura-
was in the same range as that of and subsequent
film manipulations
These results agree with the hypothesis
unit of the aminopeptidase
where the
is on the outer
that the
layer of the brush border
379 membrane border
When papain or trypsin was injected
(ref. 100).
film, a rapid release
occurred
with no change
Higher spreading cytoplasmic
portions
in surface
yields
of the two radioactive indicated
labels were recovered
the A/W interface
by the authors
In addition
functions
to this direct
coefficients
a dispersion
and cholesterol,
are important
of membranes
mixed
for membranes,
for synthetic
film
support
of cells at
the influence
of mem-
of the membrane.
the magnitude
on a solution
in the resistance
and
Fleming -.--* et al of interfacial
These were formed by spreading
membranes,
Diffusion
films of proteins
For example,
theory to calculate
of phosphatidylcholine
tion of calcium barriers
diffusion
This im-
in this work strongly
for studying
type of approach,
have been studied as models applied
reported
from the film.
there is no preferential
that the spreading
could prove a simple method
brane packing on biological
transfer
the hypothesis.
(33- 37%) and -E. coli
ratio in the surface
and therefore
Results
of either component.
the view expressed
(ref. 101)
with erythrocytes
that the protein/lipid
is the same as in the native membrane
lipids
brush phase
phospholipids
portant observation
spreadinq
under a spread
into the aqueous
further confirming
pressure,
were obtained
activity
When E. Coli cytoplasmic membranes containing (55- 60%). 14 -C-labelled proteins were spread, similar proand
membranes
32P-labelled
of aminopeptidase
of BSA followed
analysis
to passive
indicated transport
by the addi-
that interfacial across
these mem-
branes.
B. Foams and emulsions A dispersion
of a gas or liquid
stance
is present which adsorbs
persed
phase against
their capacity
Proteins
(ref. 102,103).
is unstable
unless a sub-
and thereby
stabilizes
compounds
vary greatly
Surface active
izers of foams and O/W emulsions. reviews
liquid
at the interface
coalescence.
as stabilizers.
in another
are particularly
effective
the disin
as stabil-
This has been the subject of some recent
The present
of how studies of protein monolayers
discussion
will be limited
may give information
to considerations
relevant
to these dis-
persed systems, When two emulsion
droplets
This means that during stabilizing
the coalescence
there is a reduction process
film and this could conceivably
at least in the initial film to compression
stage
would
(of the form rAdn).The
devised
(ref. 106) to measure and this parameter
ties of different
the work opposing
has been correlated
surfactants,
including
The response
the magnitude
tensiolaminometer
in interfacial
there is a compression
create a barrier
(ref. 104,105).
then determine
barrier
lamellae
coalesce,
of the interfacial
of the activation
reduction
energy
that has been of liquid
with foam stabilizing
proteins.
of the
to coalescence.
is an instrument surface
area.
proper-
A low compressibility
and
380 a low tendency teins,
to desorb
short-circuiting
to a great extent pressibility
both favor a high energy of the compression
(Part VI) although
of the monolayer.
case for colliding
droplets),
This is because
the relatively
displacement
measurements
relaxation
long times involved
The pushing out of segments
droplets
from the free energy
protein
segments
108).
protein,
tial at the surfaces effective
of droplets. agents
net charge,
(see
completion
barrier
during
of loops and
between
segments
produce a steric barrier a rise in concentration
flocculation
from the isoelectric
however,
(to coalescence)
proteins
(ref.
point of poten-
seem to be most
under conditions
that factors other
reof
of loops and tails can
thus promoting
is set up by the electrical
Generally,
showing
(formation
The presence
by molecules,
a repulsive
as stabilizing
carry a minimum
towards
The interaction
If the pH of the aqueous phase is displaced
the stabilizinq
be the
is quite
a high compressibility
phase
will usually
(ref. 107).
of droplets
the com-
(as would
in these measurements.
increase accompanying
in this region
also lead to bridging
increases
however
proceed
into the aqueous
as they approach
sulting
does not occur
of protein monolayers
indicate
processes
tails) by the protein could have two effects. on adjacent
of segments
the compressibility
case of pro-
In the
by desorption
For rapid compressions,
low, even though film balance Fiq. 3).
barrier.
barrier
where
than electrical
they repulsion
are predominant. The tendency
for proteins
to form thick films by surface coagulation
needs to be taken into account. surface
coagulation
This is particularly
for coalescence
be promoted
because
coagulation
in emulsion
stability
the well known phenomenon
of these films.
has not been studied
of phase inversion
a W/O one by shaking as in butter-making)
droplets
(Part IV-D).
may
The role of surface systematically
(conversion
is usually
as
from approach-
On the other hand, flocculation
to occur.
of the "stickiness"
preventing
also
to emulsions
occurs more readily at O/W than A/W interfaces
Thick films can form a simple steric barrier, ing close enough
relevant
although
of an O/W emulsion
attributed
to
to surface coag-
ulation of the protein at the A/W interface.
C.
Biomedical
problems
It is generally
accepted
ing recognition
and adhesion
role of surface
chemistry
part played by proteins and Freeman
(ref. 109).
drugs and hormones high molecular
weight
reactions
surface
functions)
in the biology
attached
is mediated
at the cell surface
Phagocytosis
glycoprotein,
of the living cell
by the cell surface.
of pinocytosis
has been discussed
is relevant.
the
for
such as the
(ref. 112) and surface
(ref. 113) are some of the many areas where
behavior
The
by Brandt
receptors
and the role of agents
fibronectin
(includ-
and, in particular,
(ref. 110), cell surface
(ref. ill), cell adhesion
blood-clotting of protein
that much of the behavior
induced
knowledge
381 An example of a natural appears
surfactant-covered
preventing
reduces
their collapse
been challenged liquid
in which monolayer
by Hills
surface
to cover the alveolar
tension,
at decreased
interface.
The major component
dipalmitoyl
lecithin,
adsorption
but other components
proteins
for the alveolar
preted the reproducible processes
dimensional in yield
hysteresis
at a molecular
level.
including
behavior
viscosity
The
as well as
studies
have
of the lung surfactant (ref. 117) have inter-
in terms of collapse
Blank and Britten
especially
proteins.
proteins
chemical
hysteresis
flow of films of lung surfactant
stress and surface
is phospholipid,
Mehta and Nagarajan
system.
for a discon-
at the solid tissue/air
serum-type
Surface
(ref. 115,116).
tended to focus on the expansion-compression as a model
the air spaces by
occurring
are present,
and comprises
A
of the lung.
The model has, however,
of the lung surfactant
is heterogeneous
surfactant-specific
cavities
thus stabilizing
lung volumes.
at an interface apparatus.
(ref. 114) who has put forward arguments
lining with surfactant
protein component
behavior
role is that of the respiratory
film is believed
This considerably
tinuous
system
to play an important
and reentry
(ref. 118) have measured
two-
and shown that there is a decrease. The results were interpreted
with age.
to indicate
that a two-dimensional network is formed rapidly having a yield -1 stress of about 3 mNm . The different processes of loop formation, desorption
and surface
coaqulation
are now better tribution
IX.
understood
of proteins
CONCLUDING Progress
during compression and should
for spreading
our knowledge.
valid method
At higher
urational
changes,
processes
relate
in conformation
desorption
to problems
under compression
may serve as a model
behavior
of the con-
films has been improved shows promise
in the very low pressure weights
providing
the different
posed in natural of molecules
(ultimately
membrane
parts of these molecules ing a configuration
of surface
appropriate
processes
leading
precautions
of molecular
For example,
to desorption
solution
that certain
These
the changes from the
the removal
conformation.
of The
has.not yet
segments
could form loops in the non-aqueous
that would make the probability
config-
of whole molecules)
biosynthesis:
under high compression
It seems possible
for fur-
provide a
have ben delineated.
systems.
to take up its unique proteins
region
(tails and loops) are expelled
for the final step in protein
in detail.
facets of protein monolayers.
and surface coagulation
from the ribosome
of integral
been studied
understanding films.
such as spectroscopy
molecular
pressures,
as portions
certain
and manipulation
Measurements
for determining
are observed.
(see Fig. 7)
REMARKS
of newer techniques
the molecule
in lipid-protein
has been made in understanding
The methodology
surface
lead to a better
to hysteresis
and application thering
of protein monolayers
in the apolar
phase, thus creat-
of desorption
extremely
low.
382 Direct studies of the desorption esting
results.
surface
of other proteins
One is that smaller
proteins
by those of higher molecular
ations where
there is competition
such as in blood clotting. protein
Another
reached.
between
is that desorption
different
to situ-
species,
of a slightly
soluble
at the same rate as from the pure monolayer
until low surface coverages
This is pertinent
from the
a result that is relevant
for the surface
from a mixed film proceeds
at a given pressure
weight,
have led us to some inter-
tend to be displaced
to considerations
of the desorbing
of mass transport
protein are across
biological
membranes. The structure
of protein monolayers
the newer spectroscopic
techniques
should help to clarify
the details.
compressibilities plained.
of different
functions
is warranted.
are studied;
photosynthetic
proteins which
in Photosystem
Processes
such as surface
size but dependent
to reflect
flow and loop formation
the surface
for proteins,
from the surface
projects
mainly apolar
secondary
structure
Because
strongly
ular to its axis. of proteins,
in the protein)
can act as
side-chains
to be
favor a random
from protein and polypeptide
the presence
of the a-helix
there is a tendency
in
for one surface
The mean helical
of polar and apolar
the retention hydrophobic
surfaces,
that the helix is highly amphiphilic
Krebs and Phillips
(ref. 121,122)
between
the product
in the molecule
of
moment,
a large perpendic-
have found, for a number ;hF (u,, being the average
and F being the fraction at the A/W surface
of a-helix
for a given amount
into the subphase.
The design of multicompartment of reactions
appear
concept
and the value of II exerted
injected
of
on the
This has led to the interesting
of the separation
value of p,, for all helixes
of protein
an A/W interface
(ref. 120j which justifies
monolayers.
a good correlation
consisting,
surface
moment
meaning
to be independent
phase, conditions
support
accessory
polar side chains while the opposite
side chains.
in protein
value for the parameter
ex-
(ref. 119).
flow and loop formation
polar and apolar
In some proteins,
hydrophobic
Ph, gives a measure
reactions
Surface
allowing
of each helix to project mainly
of the helical
appear
On the other hand, evidence
conformation.
an essentiaT and red algae
on a segment of the molecule
towards and away from the aqueous
films removed
in situ -in the
to amino acid composition
is phycocyanin,
a random chain conformation.
chain configuration.
variations
have never been satisfactorily
are related
2 of blue-green
of 6- 10 amino acid residues.
a "good" solvent
although
of monolayers
There are some marked
a recent example
pigment
examination
resolved
This becomes more so as new proteins with specific
molecular
directed
for direct
A study of how these variations
and structure
average,
is still not entirely
in protein
troughs
monolayers.
to date but other
processes
has provided
a stimulus
They have been used mainly are amenable
to study,
to the study
to follow enzyme
including
many in
383 the biological approach. in membrane
X.
area, which would benefit
This includes mimetic
from a collaborative
the further development
of protein
multidisciplinary monolayers
as a tool
chemistry.
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