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Conformational changes and complement activation induced upon antigen binding to antibodies
Vol. 74, No. 4, 1977
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
CONFORMATIONAL CHANGES AND COMPLEMENT ACTIVATION
INDUCED
UPON ANTIGEN BINDING TO ANTIBODIES
I. Departments
Pecht,
of Chemical
B. Ehrenberg,
Immunology of Science,
Received
September
E. Calef
and Chemical
and R. Arnon
Physics,
The Weizmann
Institute
Rehovot , Israel
30,1976
SUMMARY: The interaction between antibodies specific for the loop region of lysozyme and this monovalent antigenic determinant was compared to their interaction with either the dimeric derivative of the loop (bis-loop) or the polyvalent antigen loop-A--L. This comparison was based on complement fixation capacity, and on spectroscopic changes in the circular polarized fluorescence (CPL) of the antibodies. The binding of the loop to its antibodies causes spectroscopic changes, assigned to conformational changes in the Fc region, which are not accompanied by complement activation. However, the binding of the bisloop led to distinctly different CPL changes and concomitantly to complement fixation comparable to that induced upon binding of the loop-A--L. Complement fixation and the CPL changes can be induced in the intact antibodies only; reduction of the interchain disulfide bridges, or cleavage by papain or pepsin digestion abolishes both activities. Three ing
different
antibody
effector
According
(1Jl. thermodynamics body
conformational mission,
changes
in turn,
physicochemical the
circular
such changes It
(4-6).
These
interaction probably
was previously
between
were
observed the
from those a change
Indeed,
in the
with
the whole
conformation
Copyright 0 I977 by Academic Press, Inc. All rights of reproduction in any form reserved.
of Fc. 1302
antirequires mechanism),
and their
(an by trans-
using
several
and measurement
report
antibodies
and their
their
respective
antigens
antigens
Fab fragments
antibody of the
of
on the existence
intact
multivalent
in CPL of the
with
Fab,
investigations
(3))
with
Fc and Fab fragments
mechanism
of detection
in both
(5) that
changes
observed the
recent
interaction
antigen
favorable
The third, CH2 domains. functions are initiated to the
(CPL)
detected
the
of initiat-
to antigen-mediated
The second
the method
of the
with , the
Fab and Fc (“distortive”
at the effector
of luminescence
as a result
leads
by antigen-binding
including
the mechanism
of antibody
phenomena. between
to the Fc region.
for
activation)
which
hinderence that the
induced
methods,
and poly-D&alanine, different
these
steric infers
polarization
Fab fragments
for
relationship
so as to possibly remove “allosteric” mechanism),
interaction
(“associative” attachment,
accounts angular
upon
first,
of multipoint
in the
have been proposed
function
to the
aggregation,
a change
alternatives
were
molecules, specific
With monovalent
of (5,6).
such as RNase markedly indicating
antibody, haptens,
and a rough ISSN
0006291
X
Vol. 74, No. 4, 1977
correlation
between
phosphorylcholine saccharides changes
the
transitions
which
attributed
to the
it
b) It ing
about
dimers
of lysozyme for
neither
but
is
nor
antigen,
reasons:
still
monovalent
and high
affinity
(K = 3 x lo6
The above mentioned changes
with
antigen
complex,
induction
complement.
We wish
body
with
complex
whereas
the
distinctly antibody
in terms M-l)
to report formed This
different
the
for
or of the
which
of changes
prepar-
of a larger
specificity.
d) It heterogeneity
in the CPL which
effector
functions to other
or with
dimeric
lysozyme,
or polyvalent
correlated formed
with with
the
of these
of the anti-loop
in analogy
the complex
MATERIALS
a part
range.
for
and functional
the correlation
loop,
loop-antibody
wavelength
is a significantly loop
this
(9).
that with
for
of aromatic
can be used
constitutes
of the
capacity
activity
It
devoid
relevant but
structural
of one of the with
the monovalent
complexes
complement-fixing.
c)
of restricted observations
namely
in the
lysozyme,
led us to investigate
the
can be
and useful
a) Being
determinant, (8).
namely
antibodies
antibodies
which
convenient
fluoresces
derivatives
specific
its
antibody.
in the conformational
changes
is particularly
the following
absorbs
or polyvalent occurring
molecule,
anti-loop
induced
Fc region.
provokes
free
in the antibody,
antibodies.
lysozyme)
of intact
haptens
and oligo-
respective
of hen egg-white
small
the small
(5)
in their
Fab and the Fc regions
has been shown to be a monovalent
naturally
in
64-80
from
whereas
tetra-i-alanine changes
(residues
brings
peptide
(7) it
spectral
differs
RESEARCH COMMUNICATIONS
in CPL was observed;
any change,
loop
of investigation,
residues
cause limited
to both
that
The loop
not fragment
assignable
AND BIOPHYSICAL
and changes
produced
“loop”
implies
type
size did
(6)
The lysozyme This
BIOCHEMICAL
induces
of the
antibody-
antibody
to fix
systems
(2,11),
did not loop
CPL spectra, the bis-loop
loop
spectroscopic
fix
the anticomplement,
derivatives which
were were
and those
of the
complex.
AND METHODS
AnAn. The loop fragment and its conjugate, loop-A--L, were prepared as described previously (8,9). The synthetic loop, prepared by the solid phase synthesis (12), was described in detail in an earlier publication (13). This peptide comprised residues 64 to 80 in the amino acid sequence of lysozyme and did not contain any fluorescent residues. The loop dimer was prepared by coupling the synthetic loop to each of the using water soluble 1-ethyl-3-(3-diethyltwo amino groups of 1,9-diamino-nonane, aminopropyl) carbodiimide (EDCI) (Ott Chem. Co., Muskagon, Michigan, USA): Fifty mg of loop were reacted with equivalent amount of EDCI (4 mg) for 30 min at room temperature and the slight precipitate formed was centrifuged off. Two mg (half equivalent) of 1,9-diaminononane was added and the reaction mixture was maintained Separation of the dimer from lower molecular at room temperature overnight. weight components was carried out on a Sephadex G-10 column (7.4 x 0.8 cm) in 0.05 molar acetic acid. The fractions under the main peak (monitored at 230 nm) The purity of this were pooled and lyophilized to yield 30 mg of bis-loop. product was assayed by high voltage (3000 volts) electrophoresis on Whatman 3 MM paper at pH 1.9. Only a single spot, corresponding to the bis-loop, was observed.
Vol. 74, No. 4, 1977
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Antibodies. Antibodies specific to the loop region of hen egg-white lysozyme were prepared as described elsewhere by immunizing New Zealand rabbits with the loop-A--L conjugate (8). The antibodies were subsequently purified on a lysozyme-Sepharose immunoadsorbent (8,9) . The cleavage of the antibodies was carried out by papain digestion according to Porter (14). (Fab’) dimer fragments of the anti-loop IgG were prepared by pepsin digestion (15). Reduction of the inter-heavy chains disulphide bridge was carried out in a 5 mg/ml solution in PBS with 2.5 mM dithiothreitol (16,17). CPL measurements. The measurements of circular polarization of the emission of the immunoglobulins were carried out with an instrument constructed in the Department of Chemical Physics of this Institute, and described elsewhere (18,19). Sample cells of 1.0 or 2.0 mm light path were used. The circular polarization of luminescence is expressed by the emission anisotropy factor defined as gem = 2 * Af/f, where Af is the intensity of the circularly polarized component of the fluorescence (defined positive for left-handed circular polarization), and f is the total intensity of the fluorescence (3). The exciting light, set at 275 nm (band pass 30 nm), was passed through a chlorine filter (Ophthos Instruments) to remove stray light. The fluorescence was monochromated by a Jarrell-Ash double monochromator (model 82-410). The experimental error part of the emission in the measurement of gem was + 5 x 10V5 in the central band and increased to about f 1 x 10s4 at the red edge of it. Micro-complement fixation assay. Sheep red blood cells were freshly prepared, hemolysin was purchased from Difco Laboratories, Detroit, Mich. and Titration of whole guinea pig serum was used as the source of complement. complement and complement fixation assay were performed according to Wasserman and Levine (20), in a total volume of 1.4 ml, using 0.02 M tris-HCl buffer, pH 7.4, containing 0.14 M NaCl, 0.5 mM Mg2+, 0.15 mM Ca2+ and 1% bovine serum albumin. For measurement of complement fixing activity a series of the antigen dilutions was made in 0.2 ml buffer. A premixed solution (1 ml) of the antibodies in suitable dilution, and complement in an amount that would give 90% lysis, were added to each tube as its contents were rapidly stirred. After equilibration overnight at 4’C, 0.2 ml of a 0.25% suspension of hemolysinsensitized sheep red blood cells was added at O’C and the tubes were incubated at 37°C until the complement controls showed approximately 90% lysis. The tubes were then transferred to O’C, centrifuged and the supernatants were monitored at 410 nm. Appropriate controls of the complement at several dilutions, of the antigen or antibody separately, and of sheep red blood cells without complement were set with each experiment. Ultracentrifugal analysis. Sedimentation velocity measurements were carried out at 25°C and 56,000 rpm with an electronic speed control in a Beckman Spinco Model E analytical ultracentrifuge equipped either with Schlieren optics, or with optical scanner. RESULTS Circular bodies
are shown
throughout of the
polarization the
different
previously antigen
binding
in Figure
emission
1.
band
the binding
of the protein to other
The variation is
tryptophans
(51,
CPL spectrum
of fluorescence. a result
(Fig. rabbit
of anti-loop
in the
anisotropy
of the
contributing of the
The CPL spectra
to this
loop
leads
1).
1304
spectrum.
to a very
In analogy
antibodies
emission
heterogeneity
(5,6),
of the
a marked
factor chirality
As observed
pronounced
to the
anti-
effect shift
change observed towards
in the upon positive
Vol. 74, No. 4, 1977
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
I
I
: : 1’
t5 -
d t 0 x O-
-5 -
I
30( 3
I
350
400 X (nm)
Fig. 1. Circular polarized fluorescence spectra of anti-loop ml) 0 -0, and it complexes with 1.5 equivalents of loop, loop xx, respectively.
antibodies (6.5 mg/ e-e, and bis-
Q
Fig. 2. The CPL spectra of papain-cleaved anti-loop antibody o-o, and its complexes with 1.5 equivalents of loop o-m, respectively. values
of gem is observed The binding
namely, negative
the than
in the
of the bis-loop
gem values that
of this
of the free
longer leads
complex antibody.
wavelength
half
to an inversion in the range That this 1305
of the of this
(7.0 mg/ml) bis-loop x-x,
emission
band.
spectral
pattern,
340-380 nm is even more effect is due to the rever-
Vol. 74, No. 4, 1977
BIOCHEMICAL
300
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
350
400
A (nm) Fig. 3. Effect of the reduction of the interchain disulphide bridges of antiloop antibodies on the circular polarized fluorescence spectra of the free antibody o-o, complex with the 1.5 equivalents of loop o-o, and bis-loop x-x, respectively.
sible binding of loop or bis-loop was confirmed by addition of an excess loop which resulted in reversal of the CPL pattern to that obtained with the loop. Variation of the equivalent ratio of loop or bis-loop to antibody from 1:l up to 6:l did not cause significant changes in the CPL spectra. Cleavage of the antibodies by papain to Fab and Fc,or mild reduction of their
interchain
disulfide
bond, resulted in a product with CPL spectrum similar
to that of the intact free protein (Fig. 2 and Fig. 3). The binding of either loop or bis-loop to the cleaved or reduced antibody did not cause significant gem changes in the longer wavelength half of the emission band; yet, somediffer ence is found in the blue half of the emission band below 350 nm. A similar behaviour is observed in the CPL spectra of (Fab')2 and of its complexes with the loop and bis-loop, as shown in Fig. 4. Complementfixation. The results of the complement fixation assay are presented in Figure 5 and expressed in terms of the percentage of fixed complement as a function of loop concentration. The homologousmultivalent antigen, loop-A--L, fixed complementreadily. On the other hand, no significant fixation was observed upon interaction of the anti-loop with either the loop or lysozyme, even when added in higher concentration than the antigen (in terms of equivalent weight). The bis-loop led to a level of complement fixation almost as high as the homologous antigen at the sameantibody concentrations.
1306
Vol. 74, No. 4, 1977
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
nm Fig. 4. The CPL spectra of complex with 1.5 equivalents respectively.
Sedimentation anti-loop
velocity
antibodies Both
examined
as references. fold
followed
excess
by the
of oligomeric
measurements.
and the bis-loop
centrifuge. to six
(Fab’)z of anti-loop of loop l -•,or
free
antibodies
over
the
Schlieren
species
The complexes
were and the
The bis-loop
studied
sites. system,
formed
formed
with
were
In the
of its
between loop
sedimentation were
were
equivalence pattern,
amounts
complexes
the
ultra-
the
from half
no significant
of the antibody-bis-loop
o-o,and x-x,
in the analytical
complex
concentrations
antibody
optical
antibodies with bis-loop
(less
than
5%)
observed.
DISCUSSION The assumption the effector spectral
functions
changes
biological
that
antibodies
mechanism
upon antigen-antibody
observed
activities
to its
an allosteric
does not
complex lead
the one operative
binding,
in the Fc region
of the
is
should
would
be manifested
as well.
However,
to complement
activation,
but
still
those
a monovalent
conformational
sufficient
antigen
complement in the
for
fixation.
changes functional
the
anti-loop
This
monitored sense
by CPL, though
(1,Z).
1307
On the other
of the it
perhaps hand,
is
in the Fc even a larger
also
in this
incapable system,
necessary, the
loop
does cause
residues comprising
at least
the
in the various
though
antibodies,
means that,
that
the binding
spectroscopic changes which probably stem from tryptophan part of the molecule (5). Furthermore, intact lysozyme, of eliciting
imply
in inducing
polyvalent
are not
BIOCHEMICAL
Vol. 74, No. 4, 1977
I 0.4 Concentral~on
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
I 0.6 of loop
I 12 tn the ontgen
I 1.6 sdution
I 2.0 (yglmll
Fig. 5. Complement fixation of anti-loop IgG antibodies bis-loop 0 lysozyme AA, and loop-A--L fJ concentration is 4 ngjml.
antigen
loop-A--L,
complement for
to induce
In this
we have fixation
from
that
interaction also
complement
that
binding
production and his
loop
it
only
in a change
dominated
by both of divalent
haptens
colleagues a spacer
at equilibrium seems that
(23,24), of ca.
This (with
it
was a dimer a different
(23).
situation
However,
1308
differing
of the
complex
that
the
of the
it
complex,
unexpected leads
in the
studies
in as
in view of
microscopy
showing to preferential of Schumaker
of a soluble
species
was
efficient
spacing)
with
immuno-
domains,
Moreover, being
upon binding
is prevailing.
of along
the antibody
species
the main
capable
indicates
was somewhat
that
and antibodies
distinctly
though
For example,
i! length,
in
body of
antibodies,
within
appropriate
was found
large
likewise
and electron
dimers. 15-16
the
relationships.
by monomeric
analysis.
effective
behavior loop
complexes,
ultracentrifugation
of antibody-hapten with
obtained
results
by sedimentation studies
hapten
spectroscopic monomeric
are
is
anti-loop
CPL spectra,
antibody
(8),
21,22). is
to the
on the inter-domain
loop o-o, The antibody
of antigens
the bis-loop
This
not
with
(l-3,
with
the bis-loop
fixation,
evidenced several
that
line
the complex
dependent
demonstrated
loop.
in
attachment
on their
the
antibodies
functions
shown that effect
by the
versus
are
upon binding
marked
induced
the bis-loop is
findings
immunoglobulin
study
a concomitant
anti-loop
of multipoint
complement
with
but
These
the requirement
the effector
inducing
precipitates
activation,
evidence
logical
which
with o-o.
of the
in the case of the The bis-loop
bivalent
complex bisprepared
Vol. 74, No. 4, 1977
and used in this nonane
BIOCHEMICAL
investigation
and further and the
terminus
of the synthetic
extended
form
two extra
would,
for
closed with
loop,
antibody It
the
not
with
of the free
that
intactness
of the
the Fab fragment,
can they
be demonstrated
fixing
mechanism
should
are
essential
binding for
which
and that
in the ratio
the observed antibody
changes
of a is
of its
complex
of bis-loop
to
(Fab’)2
or inmildlyreduced
bridges,
mixture
as well
in CPL above
molecule,
its
with
As is
namely
they
Fc fragment;
known
as fragmentation,
340 nm
are not neither
antibodies,
where
(16,17),the
mild
also
abolish
the
of the antibodies. here,
support,
be conceived
for
therefore,
activating
and by cross the transformation
linking
the notion
the
of the IgG class. To a certain extent this allosteric and distortive mechanisms; these by antigen
be the
The formation
CPL spectrum,
antibody
in its
to be
plausibly
(25).
carboxy
spacer
expected
could
observed
bond was disrupted.
activity
described
of this is
or with
in the
of the disulphide
due to the
point.
with
The data
the
by an increase
significance
disulphide
which
line
altered
This
form of complex
that
observed
complement
complex
1, 9 diamino-
at each of the
The length
in
on the
reduction
(13).
of the bonds
present
both
are dependent
the inter-heavy
peptide
equivalence
is of great
consists
amont to Q 36 ii.
is
from
and is
beyond
residues
and dominant
complex
which
and carbon-carbon acid
of an intermal
different
the
loop
favored
monomeric
amino
therefore,
closure
thermodynamically distinctly
has a spacer
16 carbon-nitrogen
cysteine
sufficient
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
effector
the
functions
a unique of antibodies
combines elements of the “simple” conformation changes induced both
the two sites into
that
active
of an IgG molecules state.
REFERENCES 1.
2. 3. 4. 5. 6. 7. 8. 9. 10. 11.
Metzger, H. (1974) Adv. Immunol. 18, 169-207. Hyslop, N.E. Jr., Dourmashkin, R.R., Green, N.M. and Porter, R.R. (1970) J. Exp. Med. 131, 783-802. Steinberg, I.r(l975) In: Concepts in Biochemical Fluorescence, (Chen, R. and Edelhoch, H. eds.) Marcel Dekker, New York. Pilz, I., Kratky, O., Licht, A. and Sela, M. (1973) Biochemistry 12, 49985005. Schlessinger, J., Steinberg, I.Z., Givol, D., Hochman, J. and Pecht, I. (1975) Proc. Natl. Acad. Sci. USA 72, 2775-2779. Jaton, J.-C., Huser, H., Braun, D., Givol, D., Pecht, I. and Schlessinger, J (1975) Biochemistry 2, 5308-5312. Canfield, R.E. (1963) J. Biol. Chem. 238, 2698-2707. Arnon, R. and Sela, M. (1969) Proc. Natl. Acad. Sci. USA 62, 163-170. Maron, E., Shiozawa, C., Arnon, R. and Sela, M. (1971) Biochemistry lo, 763-771. Pecht, I., Maron, E., Arnon, R. and Sela, M. (1971) Eur. J. Biochem. 19, 368-371. V.N., Glovsky, M.M., Rebek, J. and MUllerGoers, J.W., Schumaker, Eberhard, H.J. (1975) J. Biol. Chem. 250, 4918-4925.
Vol. 74, No. 4, 1977
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
12. Merrifield, R.B. (1965) Science 150, 178-185. 13. Arnon, R., Maron, E., Sela, M. and Anfinsen, C.B. (1971) Proc. Natl. Acad. Sci. USA 68, 1450-1455. 14. Porter, R.R. (1959) Biochem. J. 73, 119-126. 15. Nissonof, A., Wissler, F.C., Lippman, L.N. and Woernley, D.L. (1960) Arch. Biochem. Biophys. 89, 230. 16. Press, E.M. (1975)Tiochem. J. 149, 285-288. 17. Isenman, D.E., Dorrington, K.J. and Painter, R.H. (1975) J. Immunol. 114, 1726-1729. 18. Steinberg, I.Z. and Gafni, A. (1972) Rev. Sci. Instrum. 43, 409-413. 19. Schlessinger, J. (1974) Ph.D. Dissertation, The Weizmann Institute of Science, Rehovot, Israel. 20. Wasserman,E. and Levine, L. (1960) J. Immunol. 87, 290-295. 21. Landsteiner, K. (1945) The Specificity of Serological Reactions. Harvard University Press. 22. Siraganian, R.P., Hook, W.A. and Levine, B.B. (1975) Immunochemistry 12, 149-157. 23. Wilder, R.L., Green, G. and Schumaker, V.N. (1975) Immunochemistry 12, 39-47. 24. Wilder, R.L., Green, G. and Schtimaker, V.N. (1975) Immunochemistry 12, 49-54. 25. Schumaker, V.N., Green, G. and Wilder, R.L. (1973) Immunochemistry 10, 521528.
1310
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
CONFORMATIONAL CHANGES AND COMPLEMENT ACTIVATION
INDUCED
UPON ANTIGEN BINDING TO ANTIBODIES
I. Departments
Pecht,
of Chemical
B. Ehrenberg,
Immunology of Science,
Received
September
E. Calef
and Chemical
and R. Arnon
Physics,
The Weizmann
Institute
Rehovot , Israel
30,1976
SUMMARY: The interaction between antibodies specific for the loop region of lysozyme and this monovalent antigenic determinant was compared to their interaction with either the dimeric derivative of the loop (bis-loop) or the polyvalent antigen loop-A--L. This comparison was based on complement fixation capacity, and on spectroscopic changes in the circular polarized fluorescence (CPL) of the antibodies. The binding of the loop to its antibodies causes spectroscopic changes, assigned to conformational changes in the Fc region, which are not accompanied by complement activation. However, the binding of the bisloop led to distinctly different CPL changes and concomitantly to complement fixation comparable to that induced upon binding of the loop-A--L. Complement fixation and the CPL changes can be induced in the intact antibodies only; reduction of the interchain disulfide bridges, or cleavage by papain or pepsin digestion abolishes both activities. Three ing
different
antibody
effector
According
(1Jl. thermodynamics body
conformational mission,
changes
in turn,
physicochemical the
circular
such changes It
(4-6).
These
interaction probably
was previously
between
were
observed the
from those a change
Indeed,
in the
with
the whole
conformation
Copyright 0 I977 by Academic Press, Inc. All rights of reproduction in any form reserved.
of Fc. 1302
antirequires mechanism),
and their
(an by trans-
using
several
and measurement
report
antibodies
and their
their
respective
antigens
antigens
Fab fragments
antibody of the
of
on the existence
intact
multivalent
in CPL of the
with
Fab,
investigations
(3))
with
Fc and Fab fragments
mechanism
of detection
in both
(5) that
changes
observed the
recent
interaction
antigen
favorable
The third, CH2 domains. functions are initiated to the
(CPL)
detected
the
of initiat-
to antigen-mediated
The second
the method
of the
with , the
Fab and Fc (“distortive”
at the effector
of luminescence
as a result
leads
by antigen-binding
including
the mechanism
of antibody
phenomena. between
to the Fc region.
for
activation)
which
hinderence that the
induced
methods,
and poly-D&alanine, different
these
steric infers
polarization
Fab fragments
for
relationship
so as to possibly remove “allosteric” mechanism),
interaction
(“associative” attachment,
accounts angular
upon
first,
of multipoint
in the
have been proposed
function
to the
aggregation,
a change
alternatives
were
molecules, specific
With monovalent
of (5,6).
such as RNase markedly indicating
antibody, haptens,
and a rough ISSN
0006291
X
Vol. 74, No. 4, 1977
correlation
between
phosphorylcholine saccharides changes
the
transitions
which
attributed
to the
it
b) It ing
about
dimers
of lysozyme for
neither
but
is
nor
antigen,
reasons:
still
monovalent
and high
affinity
(K = 3 x lo6
The above mentioned changes
with
antigen
complex,
induction
complement.
We wish
body
with
complex
whereas
the
distinctly antibody
in terms M-l)
to report formed This
different
the
for
or of the
which
of changes
prepar-
of a larger
specificity.
d) It heterogeneity
in the CPL which
effector
functions to other
or with
dimeric
lysozyme,
or polyvalent
correlated formed
with with
the
of these
of the anti-loop
in analogy
the complex
MATERIALS
a part
range.
for
and functional
the correlation
loop,
loop-antibody
wavelength
is a significantly loop
this
(9).
that with
for
of aromatic
can be used
constitutes
of the
capacity
activity
It
devoid
relevant but
structural
of one of the with
the monovalent
complexes
complement-fixing.
c)
of restricted observations
namely
in the
lysozyme,
led us to investigate
the
can be
and useful
a) Being
determinant, (8).
namely
antibodies
antibodies
which
convenient
fluoresces
derivatives
specific
its
antibody.
in the conformational
changes
is particularly
the following
absorbs
or polyvalent occurring
molecule,
anti-loop
induced
Fc region.
provokes
free
in the antibody,
antibodies.
lysozyme)
of intact
haptens
and oligo-
respective
of hen egg-white
small
the small
(5)
in their
Fab and the Fc regions
has been shown to be a monovalent
naturally
in
64-80
from
whereas
tetra-i-alanine changes
(residues
brings
peptide
(7) it
spectral
differs
RESEARCH COMMUNICATIONS
in CPL was observed;
any change,
loop
of investigation,
residues
cause limited
to both
that
The loop
not fragment
assignable
AND BIOPHYSICAL
and changes
produced
“loop”
implies
type
size did
(6)
The lysozyme This
BIOCHEMICAL
induces
of the
antibody-
antibody
to fix
systems
(2,11),
did not loop
CPL spectra, the bis-loop
loop
spectroscopic
fix
the anticomplement,
derivatives which
were were
and those
of the
complex.
AND METHODS
AnAn. The loop fragment and its conjugate, loop-A--L, were prepared as described previously (8,9). The synthetic loop, prepared by the solid phase synthesis (12), was described in detail in an earlier publication (13). This peptide comprised residues 64 to 80 in the amino acid sequence of lysozyme and did not contain any fluorescent residues. The loop dimer was prepared by coupling the synthetic loop to each of the using water soluble 1-ethyl-3-(3-diethyltwo amino groups of 1,9-diamino-nonane, aminopropyl) carbodiimide (EDCI) (Ott Chem. Co., Muskagon, Michigan, USA): Fifty mg of loop were reacted with equivalent amount of EDCI (4 mg) for 30 min at room temperature and the slight precipitate formed was centrifuged off. Two mg (half equivalent) of 1,9-diaminononane was added and the reaction mixture was maintained Separation of the dimer from lower molecular at room temperature overnight. weight components was carried out on a Sephadex G-10 column (7.4 x 0.8 cm) in 0.05 molar acetic acid. The fractions under the main peak (monitored at 230 nm) The purity of this were pooled and lyophilized to yield 30 mg of bis-loop. product was assayed by high voltage (3000 volts) electrophoresis on Whatman 3 MM paper at pH 1.9. Only a single spot, corresponding to the bis-loop, was observed.
Vol. 74, No. 4, 1977
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Antibodies. Antibodies specific to the loop region of hen egg-white lysozyme were prepared as described elsewhere by immunizing New Zealand rabbits with the loop-A--L conjugate (8). The antibodies were subsequently purified on a lysozyme-Sepharose immunoadsorbent (8,9) . The cleavage of the antibodies was carried out by papain digestion according to Porter (14). (Fab’) dimer fragments of the anti-loop IgG were prepared by pepsin digestion (15). Reduction of the inter-heavy chains disulphide bridge was carried out in a 5 mg/ml solution in PBS with 2.5 mM dithiothreitol (16,17). CPL measurements. The measurements of circular polarization of the emission of the immunoglobulins were carried out with an instrument constructed in the Department of Chemical Physics of this Institute, and described elsewhere (18,19). Sample cells of 1.0 or 2.0 mm light path were used. The circular polarization of luminescence is expressed by the emission anisotropy factor defined as gem = 2 * Af/f, where Af is the intensity of the circularly polarized component of the fluorescence (defined positive for left-handed circular polarization), and f is the total intensity of the fluorescence (3). The exciting light, set at 275 nm (band pass 30 nm), was passed through a chlorine filter (Ophthos Instruments) to remove stray light. The fluorescence was monochromated by a Jarrell-Ash double monochromator (model 82-410). The experimental error part of the emission in the measurement of gem was + 5 x 10V5 in the central band and increased to about f 1 x 10s4 at the red edge of it. Micro-complement fixation assay. Sheep red blood cells were freshly prepared, hemolysin was purchased from Difco Laboratories, Detroit, Mich. and Titration of whole guinea pig serum was used as the source of complement. complement and complement fixation assay were performed according to Wasserman and Levine (20), in a total volume of 1.4 ml, using 0.02 M tris-HCl buffer, pH 7.4, containing 0.14 M NaCl, 0.5 mM Mg2+, 0.15 mM Ca2+ and 1% bovine serum albumin. For measurement of complement fixing activity a series of the antigen dilutions was made in 0.2 ml buffer. A premixed solution (1 ml) of the antibodies in suitable dilution, and complement in an amount that would give 90% lysis, were added to each tube as its contents were rapidly stirred. After equilibration overnight at 4’C, 0.2 ml of a 0.25% suspension of hemolysinsensitized sheep red blood cells was added at O’C and the tubes were incubated at 37°C until the complement controls showed approximately 90% lysis. The tubes were then transferred to O’C, centrifuged and the supernatants were monitored at 410 nm. Appropriate controls of the complement at several dilutions, of the antigen or antibody separately, and of sheep red blood cells without complement were set with each experiment. Ultracentrifugal analysis. Sedimentation velocity measurements were carried out at 25°C and 56,000 rpm with an electronic speed control in a Beckman Spinco Model E analytical ultracentrifuge equipped either with Schlieren optics, or with optical scanner. RESULTS Circular bodies
are shown
throughout of the
polarization the
different
previously antigen
binding
in Figure
emission
1.
band
the binding
of the protein to other
The variation is
tryptophans
(51,
CPL spectrum
of fluorescence. a result
(Fig. rabbit
of anti-loop
in the
anisotropy
of the
contributing of the
The CPL spectra
to this
loop
leads
1).
1304
spectrum.
to a very
In analogy
antibodies
emission
heterogeneity
(5,6),
of the
a marked
factor chirality
As observed
pronounced
to the
anti-
effect shift
change observed towards
in the upon positive
Vol. 74, No. 4, 1977
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
I
I
: : 1’
t5 -
d t 0 x O-
-5 -
I
30( 3
I
350
400 X (nm)
Fig. 1. Circular polarized fluorescence spectra of anti-loop ml) 0 -0, and it complexes with 1.5 equivalents of loop, loop xx, respectively.
antibodies (6.5 mg/ e-e, and bis-
Q
Fig. 2. The CPL spectra of papain-cleaved anti-loop antibody o-o, and its complexes with 1.5 equivalents of loop o-m, respectively. values
of gem is observed The binding
namely, negative
the than
in the
of the bis-loop
gem values that
of this
of the free
longer leads
complex antibody.
wavelength
half
to an inversion in the range That this 1305
of the of this
(7.0 mg/ml) bis-loop x-x,
emission
band.
spectral
pattern,
340-380 nm is even more effect is due to the rever-
Vol. 74, No. 4, 1977
BIOCHEMICAL
300
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
350
400
A (nm) Fig. 3. Effect of the reduction of the interchain disulphide bridges of antiloop antibodies on the circular polarized fluorescence spectra of the free antibody o-o, complex with the 1.5 equivalents of loop o-o, and bis-loop x-x, respectively.
sible binding of loop or bis-loop was confirmed by addition of an excess loop which resulted in reversal of the CPL pattern to that obtained with the loop. Variation of the equivalent ratio of loop or bis-loop to antibody from 1:l up to 6:l did not cause significant changes in the CPL spectra. Cleavage of the antibodies by papain to Fab and Fc,or mild reduction of their
interchain
disulfide
bond, resulted in a product with CPL spectrum similar
to that of the intact free protein (Fig. 2 and Fig. 3). The binding of either loop or bis-loop to the cleaved or reduced antibody did not cause significant gem changes in the longer wavelength half of the emission band; yet, somediffer ence is found in the blue half of the emission band below 350 nm. A similar behaviour is observed in the CPL spectra of (Fab')2 and of its complexes with the loop and bis-loop, as shown in Fig. 4. Complementfixation. The results of the complement fixation assay are presented in Figure 5 and expressed in terms of the percentage of fixed complement as a function of loop concentration. The homologousmultivalent antigen, loop-A--L, fixed complementreadily. On the other hand, no significant fixation was observed upon interaction of the anti-loop with either the loop or lysozyme, even when added in higher concentration than the antigen (in terms of equivalent weight). The bis-loop led to a level of complement fixation almost as high as the homologous antigen at the sameantibody concentrations.
1306
Vol. 74, No. 4, 1977
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
nm Fig. 4. The CPL spectra of complex with 1.5 equivalents respectively.
Sedimentation anti-loop
velocity
antibodies Both
examined
as references. fold
followed
excess
by the
of oligomeric
measurements.
and the bis-loop
centrifuge. to six
(Fab’)z of anti-loop of loop l -•,or
free
antibodies
over
the
Schlieren
species
The complexes
were and the
The bis-loop
studied
sites. system,
formed
formed
with
were
In the
of its
between loop
sedimentation were
were
equivalence pattern,
amounts
complexes
the
ultra-
the
from half
no significant
of the antibody-bis-loop
o-o,and x-x,
in the analytical
complex
concentrations
antibody
optical
antibodies with bis-loop
(less
than
5%)
observed.
DISCUSSION The assumption the effector spectral
functions
changes
biological
that
antibodies
mechanism
upon antigen-antibody
observed
activities
to its
an allosteric
does not
complex lead
the one operative
binding,
in the Fc region
of the
is
should
would
be manifested
as well.
However,
to complement
activation,
but
still
those
a monovalent
conformational
sufficient
antigen
complement in the
for
fixation.
changes functional
the
anti-loop
This
monitored sense
by CPL, though
(1,Z).
1307
On the other
of the it
perhaps hand,
is
in the Fc even a larger
also
in this
incapable system,
necessary, the
loop
does cause
residues comprising
at least
the
in the various
though
antibodies,
means that,
that
the binding
spectroscopic changes which probably stem from tryptophan part of the molecule (5). Furthermore, intact lysozyme, of eliciting
imply
in inducing
polyvalent
are not
BIOCHEMICAL
Vol. 74, No. 4, 1977
I 0.4 Concentral~on
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
I 0.6 of loop
I 12 tn the ontgen
I 1.6 sdution
I 2.0 (yglmll
Fig. 5. Complement fixation of anti-loop IgG antibodies bis-loop 0 lysozyme AA, and loop-A--L fJ concentration is 4 ngjml.
antigen
loop-A--L,
complement for
to induce
In this
we have fixation
from
that
interaction also
complement
that
binding
production and his
loop
it
only
in a change
dominated
by both of divalent
haptens
colleagues a spacer
at equilibrium seems that
(23,24), of ca.
This (with
it
was a dimer a different
(23).
situation
However,
1308
differing
of the
complex
that
the
of the
it
complex,
unexpected leads
in the
studies
in as
in view of
microscopy
showing to preferential of Schumaker
of a soluble
species
was
efficient
spacing)
with
immuno-
domains,
Moreover, being
upon binding
is prevailing.
of along
the antibody
species
the main
capable
indicates
was somewhat
that
and antibodies
distinctly
though
For example,
i! length,
in
body of
antibodies,
within
appropriate
was found
large
likewise
and electron
dimers. 15-16
the
relationships.
by monomeric
analysis.
effective
behavior loop
complexes,
ultracentrifugation
of antibody-hapten with
obtained
results
by sedimentation studies
hapten
spectroscopic monomeric
are
is
anti-loop
CPL spectra,
antibody
(8),
21,22). is
to the
on the inter-domain
loop o-o, The antibody
of antigens
the bis-loop
This
not
with
(l-3,
with
the bis-loop
fixation,
evidenced several
that
line
the complex
dependent
demonstrated
loop.
in
attachment
on their
the
antibodies
functions
shown that effect
by the
versus
are
upon binding
marked
induced
the bis-loop is
findings
immunoglobulin
study
a concomitant
anti-loop
of multipoint
complement
with
but
These
the requirement
the effector
inducing
precipitates
activation,
evidence
logical
which
with o-o.
of the
in the case of the The bis-loop
bivalent
complex bisprepared
Vol. 74, No. 4, 1977
and used in this nonane
BIOCHEMICAL
investigation
and further and the
terminus
of the synthetic
extended
form
two extra
would,
for
closed with
loop,
antibody It
the
not
with
of the free
that
intactness
of the
the Fab fragment,
can they
be demonstrated
fixing
mechanism
should
are
essential
binding for
which
and that
in the ratio
the observed antibody
changes
of a is
of its
complex
of bis-loop
to
(Fab’)2
or inmildlyreduced
bridges,
mixture
as well
in CPL above
molecule,
its
with
As is
namely
they
Fc fragment;
known
as fragmentation,
340 nm
are not neither
antibodies,
where
(16,17),the
mild
also
abolish
the
of the antibodies. here,
support,
be conceived
for
therefore,
activating
and by cross the transformation
linking
the notion
the
of the IgG class. To a certain extent this allosteric and distortive mechanisms; these by antigen
be the
The formation
CPL spectrum,
antibody
in its
to be
plausibly
(25).
carboxy
spacer
expected
could
observed
bond was disrupted.
activity
described
of this is
or with
in the
of the disulphide
due to the
point.
with
The data
the
by an increase
significance
disulphide
which
line
altered
This
form of complex
that
observed
complement
complex
1, 9 diamino-
at each of the
The length
in
on the
reduction
(13).
of the bonds
present
both
are dependent
the inter-heavy
peptide
equivalence
is of great
consists
amont to Q 36 ii.
is
from
and is
beyond
residues
and dominant
complex
which
and carbon-carbon acid
of an intermal
different
the
loop
favored
monomeric
amino
therefore,
closure
thermodynamically distinctly
has a spacer
16 carbon-nitrogen
cysteine
sufficient
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
effector
the
functions
a unique of antibodies
combines elements of the “simple” conformation changes induced both
the two sites into
that
active
of an IgG molecules state.
REFERENCES 1.
2. 3. 4. 5. 6. 7. 8. 9. 10. 11.
Metzger, H. (1974) Adv. Immunol. 18, 169-207. Hyslop, N.E. Jr., Dourmashkin, R.R., Green, N.M. and Porter, R.R. (1970) J. Exp. Med. 131, 783-802. Steinberg, I.r(l975) In: Concepts in Biochemical Fluorescence, (Chen, R. and Edelhoch, H. eds.) Marcel Dekker, New York. Pilz, I., Kratky, O., Licht, A. and Sela, M. (1973) Biochemistry 12, 49985005. Schlessinger, J., Steinberg, I.Z., Givol, D., Hochman, J. and Pecht, I. (1975) Proc. Natl. Acad. Sci. USA 72, 2775-2779. Jaton, J.-C., Huser, H., Braun, D., Givol, D., Pecht, I. and Schlessinger, J (1975) Biochemistry 2, 5308-5312. Canfield, R.E. (1963) J. Biol. Chem. 238, 2698-2707. Arnon, R. and Sela, M. (1969) Proc. Natl. Acad. Sci. USA 62, 163-170. Maron, E., Shiozawa, C., Arnon, R. and Sela, M. (1971) Biochemistry lo, 763-771. Pecht, I., Maron, E., Arnon, R. and Sela, M. (1971) Eur. J. Biochem. 19, 368-371. V.N., Glovsky, M.M., Rebek, J. and MUllerGoers, J.W., Schumaker, Eberhard, H.J. (1975) J. Biol. Chem. 250, 4918-4925.
Vol. 74, No. 4, 1977
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
12. Merrifield, R.B. (1965) Science 150, 178-185. 13. Arnon, R., Maron, E., Sela, M. and Anfinsen, C.B. (1971) Proc. Natl. Acad. Sci. USA 68, 1450-1455. 14. Porter, R.R. (1959) Biochem. J. 73, 119-126. 15. Nissonof, A., Wissler, F.C., Lippman, L.N. and Woernley, D.L. (1960) Arch. Biochem. Biophys. 89, 230. 16. Press, E.M. (1975)Tiochem. J. 149, 285-288. 17. Isenman, D.E., Dorrington, K.J. and Painter, R.H. (1975) J. Immunol. 114, 1726-1729. 18. Steinberg, I.Z. and Gafni, A. (1972) Rev. Sci. Instrum. 43, 409-413. 19. Schlessinger, J. (1974) Ph.D. Dissertation, The Weizmann Institute of Science, Rehovot, Israel. 20. Wasserman,E. and Levine, L. (1960) J. Immunol. 87, 290-295. 21. Landsteiner, K. (1945) The Specificity of Serological Reactions. Harvard University Press. 22. Siraganian, R.P., Hook, W.A. and Levine, B.B. (1975) Immunochemistry 12, 149-157. 23. Wilder, R.L., Green, G. and Schumaker, V.N. (1975) Immunochemistry 12, 39-47. 24. Wilder, R.L., Green, G. and Schtimaker, V.N. (1975) Immunochemistry 12, 49-54. 25. Schumaker, V.N., Green, G. and Wilder, R.L. (1973) Immunochemistry 10, 521528.
1310