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Surface diffusion in human serum lipoproteins
BIOCHEMICAL
Vol. 746, No. 3, 1987 August 14, 1987
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 1139-1145
SURFACEDIFFDSION IN HDMANSERUMLIPOPROTEINS Robert J. Cushley*, W. Dale Treleaven, Yashpal I. and David B. Fenske
Parmar, Ravinder S. Chana,
Department of Chemistry, Simon Fraser University, Burnaby, British Columbia, Canada V5A 156 Received June 16, 1987
SUMMARY.From the viscosity dependence of the 31P RMR signals, the diffusion coefficients DT of phospholipid molecules in the surface monolayer of HDL, LDL and VLDL have been determined. DT for HDL, and HDL, are found to be 2.3~10-~ cm>/5 and 1.8~10-~ cm’/s, respectively. These values are similar to values reported for diffusion of phosphoiipid molecules in phospholipid bilayers above the gel to liquid crystalline phase transition temperature. Viscosity dependence of [16,16,16-ZH,]phosphatidylcholine incorporated into HDL, yielded a value similar to that determined by 31P (D = 1.9x1O-8 cm2/s). Slower diffusion coefficients were measured for LDL, an3 VLDL. VLDL had a value DT = 9.1x10-' cm2/s. The diffusion coefficient for LDL, was 1.4~10-~ cml/s. Thus, diffusion of phospholipids in LDL, is a full order of magnitude slower at 25OC than diffusion of phospholipids in the HDLs. B’ 1987 Acadcmlc Press, Inc. The human serum lipoproteins spherical
particles
phospholipids specific
of an apolar core consisting
composed
esters and triglycerides
enveloped by an amphiphillic
and cholesterol.
into
of cholesterol
monolayer of
Embeddedin the monolayer are proteins
to the various particles.
incorporated
HDL, LDL and VLDL are essentially
the core - this
Some cholesterol
is believed
should indeed. be the case
to be
for particles
the size of VLDL where the volume of the core components would be sufficient al.(l)
to solubilize
significant
have suggested that
the phospholipid partitioned the ratio
- protein
approximately
Eisenberg et
82% of VLDL cholesterol
is within
monolayer while the remaining cholesterol
in the triglyceride-rich of protein
amounts of cholesterol.
to lipid
core. As particle
density
is
increases,
increases at the expense of neutral
lipid.
LDL, low density lipoprotein; Abbreviations: HDL, high density lipoprotein; VLDL, very low density lipoprotein; PC, phosphatidylcholine; SPM, sphingomyelin. *Author to whomcorrespondence should be addressed. 0006-291X/87$1.50 1139
AN
Copyright 0 1987 rights qf reproducfion
by Academic Press, Inc. in any form reserved.
Vol.
146,
BIOCHEMICAL
No. 3, 1987
The major
role
AND
of the serum lipoproteins
from various
tissues.
accomplished
via
between
membrane and lipoprotein
cell
different
high affinity
is
delivery
Thus,
recognize
the
the recognition
is
While myriads of studies on the lipoproteins
measurement of composition and interactions
components, no previous
is interaction
The receptors
surface.
to or
dependent upon the primary amino acid
i.e.
sequence of the apoproteins.
lipids
or lipid-lipid
monolayer.
on the lipoprotein
COMMUNICATIONS
to transport
membrane receptors
to be structure-based
have involved
RESEARCH
In the case of LDL and HDL lipid
apoproteins
believed
BIOPHYSICAL
study of phospholipid
of the surface
surface dynamics has been
reported.
In the present communication, we present evidence, s1P NMR spectroscopy, different
that
surface phospholipid
based on 'H and
diffusion
is significantly
in HDL, LDL and VLDL.
The NMRtechnique we have used is based upon the behavior of the NMR linewidth
as a function
be related
of solvent viscosity.
Av1,2 can
to the second moment M, by (2) rAv1,2
= M,T, + C
where re is the effective
(1)
correlation
the nucleus and C is a constant. the difference axially
The NMRlinewidth
1
symmetric shielding
e'qQ/h is the static bond. The correlation
tensor.
chemical shift For 'H,
quadrupolar interaction time r,
for isotropic
reorientation
For 31P, M, = (4/45)7fH$(o
a - u is the residual II
time
M,
II
- uI)'
anisotropy
term
~~
is the tumbling
= (9/20)(xezqQ/h)l
constant for a carbon-deuterium
(2) time
for the isotropic
rotation
for diffusion
of the particle (3)
R is the particle
radius,
Roltzmann's constant and T is the absolute temperature. time
where
is
?t = (4nqRJ)/(3kT) where 17is the solvent viscosity,
correlation
where
for an
7-l = r-1 + r-1 e t d The
of
k is
The term 7d is the
in the surface plane
Td = R=/6DT
(4) 1140
Vol. 146, No. 3, 1987
BIOCHEMICAL
and DT is the translational obtained from the ratio (Av1,2 - C)-l
AND BIOPHYSICAL
diffusion
coefficient.
RESEARCH COMMUNICATIONS
The value of DT is
of the slope to the intercept = (3kT)/4M,xqR3 + (6D)/M,RZ
from the relationship (5)
MATERIALS AND METHODS Egg lyso-PC and deuterium depleted water were purchased from Sigma Chemical Co. Aquacide (Molecular Weight 70,000) was purchased from Calbiochem. [16,16,16-aH,]Palmitic acid was purchased from Serdary Research Laboratories. [16,16,16-~H,]PC was synthesized by condensation of egg lyso-PC and [16,16,16-2H,]palmitic acid using l,l'-carbonyldiimidazole by a method described in Thewalt et al. (3). The lipoproteins were isolated from fresh (<3 days old) plasma supplied by the Canadian Red Cross. Isolation was by means of sequential ultracentrifugal floatation: VLDL, dc1.006 g/ml; LDL,, d=1.025-1.063 g/ml; HDL,r d=1.063-1.125 g/ml; HDL,, d=1.125-1.210 g/ml. VLDL fractions from several fresh plasma units were pooled and spun twice more (42,000 rpm; 5OC) for 30, then 20, min and the top one-quarter fraction discarded both times. [16,16,16-ZH,IPC was incorporated into HDL, by addition of solid (5 mol % with respect to lipoprotein phospholipid) to the HDL, solution followed by three one-minute sonications at 42OC using a Biosonic III probe-type sonicator . The HDL, purity was checked by immunoelectrophoresis (4). Protein was determined by the method of Lowry (5) as modified by Kashyap et al. (6). Phospholipid was determined as described by Ames (7). Cholesteryl ester and total cholesterol were enzymatically determined using Boehringer Mannheim clinical test kits. Prior to NMRexperiments all lipoproteins except HDL, were dialysed into 0.15M NaCl, 2mtj EDTA, pH 1.5. HDL, was dialysed into deuterium depleted water. The lipoproteins were concentrated by ultracentrifugal floatation (VLDL), treatment with Aquacide (LDL,), or Millipore CX30 submersible ultrafiltration units (LDL,,HDL,). The 31P NMRexperiments were performed at 102.2 MHz, without proton decoupling, using a 5.9 Tesla Nalorac superconducting magnet and a home-built spectrometer. Collection and Fourier transformation of the free induction decays was performed using a Nicolet BNC-12 computer. Spectra were obtained using a one-pulse sequence with phase alternation in order to minimize baseline distortion. Except for HDL,, temperature was controlled at 25f0.5Y by a home-built solid state controller/home-built variable temperature probe. 2H NMRspectra were determined as above at 38.8 MHz. The spectra for VLDL, LDL, and HDL, were analyzed using an iterative least squares fitting routine to Lorentzian lineshape functions. The plots in Fig. 1 were analyzed using a weighted least squares routine courtesy of Dr. Ian Gay, Simon Fraser University. Mean sizes of VLDL and LDL, were determined using a model 270 Nicomp Submicron Particle Sizer. Electron micrographs of HDL, were obtained using a Philips EM300 Electron Microscope at 80 kV. Electron microscopy samples were stained with 2% ammoniummolybdate at pH 8.0 and applied to 200 mesh Formvar carbon coated grids, then air dried. Solvent viscosities were measured using an Ostwald viscometer. RESULTSAND DISCUSSION ,lP NMRspectra were obtained for function
of solvent viscosity.
HDL,, HDL,, LDL, and VLDL as a
Computer generated spectra composedof the 1141
Vol. 146, No. 3, 1987
BIOCHEMICAL
AND BIOPHYSICAL
25
LDL
(3’P
RESEARCH COMMUNICATIONS
NMR)
20. 15.
0
20
601HDL,
9 x -i 0
40
(3’P
NMR)
5
10
60
80
0’0
100 -1
20 ‘LDL
(“P
40
60
80
100
1
60
80
100
12
NMR)
30.
20. 4
lo-
&
07 0 14’
HDL,
(2H
15
20
25
20
:
40
NMR)
120. 1 oo80. 60~ 40. 0
5
10
15
20
q-1 (Pa.&) FIGURE1. Plots of reciprocal NMRlinewidths versus reciprocal of solvent viscosity at 25OCfor, clockwise from bottom left, 'H NMR linewidth of [16,16,16-zH,]phosphatidylcholine in HDL,; SIP NMR linewidths of phospholipids in HDL,; HDL,; LDL,; VLDL. The solid lines in the plots for HDL,, LDL, and VLDLare weighted least squares fits to the data points. The constant C was taken as 15 Hz for 3lP and 2.5 Hz for =H.
superposition
of two Lorentzian
were used to fit
the experimental
contained approximately noise-decoupled
functions,
a signal
spectra in most cases. HDL, and HDL,
20% and 15% SPM respectively,
31P NMRspectroscopy,
proton noise-decoupled 31P NMRof extracted
linewidths
as shown by proton
and the linewidths
equal. LDL, and VLDL contained approximately
Necessary conditions
each for SPM and PC,
of the signals are
40% and 14% SPM as shown by lipids
in CHCl,/MeOH (2:l
for convergence of the computer routine
of the SPM and PC signals be made equal and that
chemical shift
remain unchanged at 0.6 ppm. 1142
were that
v/v). the
the SPM-PC
BIOCHEMICAL
Vol. 146, No. 3, 1987
Fig. viscosity
AND BIOPHYSICAL
1 is a double reciprocal (see eqn. 5). The plots
mL3, HDL, containing respectively.
-5
A plot
mol%
plot
RESEARCH COMMUNICATIONS
of NMRlinewidth
verSuS solvent
are determined based on the 31P NMRof
[16,16,16-~H,]PC,
LDL,, and VLDL,
was also determined from the 2H NMRlinewidth
dependence of the labelled
HDL, sample upon solvent
viscosity
(Fig.
1,
lower left). The sizes of the LDL, and VLDL particles determined by light the Tablel.The light
scattering
used in the NMRstudies were
and the mean particle
HDLs are too small to give reliable
scattering
and since HDL, is reported
radii
E are given in
size measurements by
to have a diameter of 8.5-11 nm
(81, a mean radius of E = 5.0 run was assumed. The size of HDL, was determined by electron From the plots
microscopy. in Fig.
1, diffusion
coefficients
DT for phospholipid
molecules in the surface monolayer of the lipoproteins
were calculated
at
25OC and are presented in the Table. From 31P NMRDT for HDL, and HDL, were calculated
to be 1.8x10-*
approximately
and 2.3x10-*
the sameas that
where values for DT range
from
reported 1x10-*
respectively.
cm*/s,
These values are
for PC in phospholipid to
7~10-~
cm2/s
The fact
(9).
= 1.8x10-8 cm2/s for HDL, when determined by 2H NMRindicates
TABLE
1
DIFFUSION COEFFICIENTS OF PHOSPHOLIPIDS IN THE OUTER MONOLAYER OF HUMAN SERUM LIPOPROTEINS Lipoprotein
HDL2
c Nucleus
D (cm2
R (nm)
. s“)
3’P
4.0a
2.3
2 0.8
x 10-8
3’P
5.ob
1.8
20.3
x 10-8
2H
5.0b
1.9 to.3
x10-8
LDL2
3’P
12.oc
1.4 kO.5
x 10-9
VLDL
3’P
18.4c
9.1 + 1.0
x 10-g
a. Measured by electron microscopy b. Sizes reported with R=4.3 - 5.5 nm (P.J. and Cell Biol. 6_3, 850 (1985) c. Measured by quasielastic light scattering
1143
Dolphin,
Can.
bilayers
J. Bich.
that
that the
DT
BIOCHEMICAL
Vol. 146, No. 3, 1987
phospholipid envisige
AND BIOPHYSICAL
molecules undergo diffusion
each phospholipid
as rigid
(7<5xlO-*s)
entities.
molecule moving as a cylinder
across the surface of the lipoprotein. is rapidly
RESEARCH COMMUNICATIONS
reorienting
The phospholipid
Thus, we randomly walking
molecule, of course,
about the long axis of the cylindrically
symmetric molecule. The larger diffusion.
particles,
LDL, and VLDL, have distinctly
The value of DT = 9.1x10-'
cm*/s for phospholipid
the surface monolayer of VLDL is at least corresponding diffusion
diffusion
is the fact
slower diffusion
compared to HDL can be attributed (10). The ratio
of cholesterol
in the two HDLs it
at 25OC, phospholipid
found in VLDL, it
of phospholipid
to phospholipid
to phospholipid
can explain,
only in part,
acyl chain heterogeneity, the gel to liquid
transition
display
significantly
rate
phospholipids
greater
(see
occuring SPMs, as a result
of
complicated thermal behaviour and,
crystalline
phase transition
temperature is
occuring PCs (11). Howwer, we are
monolayer for LDL, at 25Y,
as it
from LDL, do not display
has been shown
a thermal
over the range 20-45OC (12,13).
2. Core-Monolayer Interactions. cholesteryl
the slower diffusion
in LDL, is so slow:
higher than for naturally
the isolated
in LDL, is the same as
molecules in the LDL, monolayer. We can suggest three
not proposing a gel-like that
content
in our VLDL is 0.27 whereas
ratio
above) than does VLDL or the HDLs. Naturally
significantly
molecules in VLDL
to the much higher cholesterol
reasons why the diffusion
in general,
is in the HDLs.
of phospholipid
1. Monolayer Composition. LDL, has a SPM content
fatty
cm2/s) is
is X0.15.
Since the cholesterol
possible
that,
one order of magnitude slower than it
The slightly
that
in the surface monolayer of the
in the surface monolayer of LDL, (DT = l.l~lO-~
approximately
molecules in
two times slower than the
rate of phospholipid
HDLs. Even more significant,
slower surface
The LDL, core is composedpredominantly
esters while the VLDL core is mostly triglycerides. 1144
It
is
of
Vol.
146,
No. 3, 1987
possible
that
phospholipid just
into
their
AND
BIOPHYSICAL
interactions
is
slowed.
RESEARCH
COMMUNICATIONS
in LDL, are of a nature
At 25OC the core
phase transition
diffusion
that
CT,-20-40°C)
components
(13)
by means of interdigitation
that
of LDL, are
and the solid-like of phospholipid
core
acyl
chains
core.
3. Protein Weight
core-monolayer diffusion
may impair into
BIOCHEMICAL
LDL, contains
Composition.
512,000).
phospholipid
Perhaps
there
and apoB which
a single
strong
is a unique,
causes
protein
apoB (Molecular
interaction
the phospholipid
diffusion
between rate
to slow
significantly. Clearly,
more work
component diffusion however,
any explanation
communication must also
in
(14,15),
must be done to explain lipoproteins. of surface
possibly
accommodate the surface
In light
the differences
of our diffusion
in surface measurements
phenomena such as protein-protein
necessary dynamics
for
efficient
presented
receptor
binding,
here.
REFERENCES L Eisenberg, S., Bilheimer, D. W., Levy, R. I. and Lindgren, F. T. (1973) Biochim. Biophys. Acta 326, 361-377 2, Abragam, A. (1961) Principals of Nuclear Magnetism, pp 424-427, Clarendon Press, Oxford & Thewalt, J. L., Wassall, S. R., Gorrissen and Cushley, R. J. (1985) Biochim. Biophys. Acta 817, 355-365 4. Hatch, 5. T. and Lees, R. S. (1968) Adv. Lipid Res. 6, l-35 5, Lowry, O.H., Rosebrough, N. J., Parr, A. L. and Randall, R. J. (1951) J. %ol. Chem. 193, 265-275 & Kashyap, M. L., Hynd, B. A. and Robinson, K. (1980) J. Lipid Res. 21, 491-495 7. Ames, B. N. (1966) Methods Enzymol. 8, 115-118 z Pownall, H. J. and Gotto, A. M. (1983) Phospholipids and Atherosclerosis (Avogaro, P., Mancini, M., Ricci, G. and Pavletti, R, eds) pp 99-114, Raven Press, New York k Mackay, A. L., Burnell, E. E., Nichol, C. P., Weeks, G., Bloom, M. and Valic, M. I. (1978) FEBS Lett. 88, 97-100 & Cullis, P. R. (1976) FEBS Lett. 70, 223-228 11. Barenholz, Y., Suurkuusk, J., Mountcastle, D., Thompson, T. E. and ztonen, R. L. (1976) Biochemistry 15, 2441-2447 12. Small, D. M. (1977) J. Colloid Interface Sci. 58,581-602 13. Deckelbaum, R. J., Shipley, G. G. and Small, D. S. (1977) J. Biol. Chem. 252, 744-754 14. Devaux, P. and McConnell, H. M. (1972) J. Am. Chem. Sot. 94 ,4475-4481 15. Schlessinger, J. and Elson, E. L. (1981) Membrane Receptors; Receptors xd Recognition (Jacobs, S. and Cautrecasas, P. eds) Series B, Vol. 11, pp 159-170, Chapmanand Hall, New York
1145
Vol. 746, No. 3, 1987 August 14, 1987
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 1139-1145
SURFACEDIFFDSION IN HDMANSERUMLIPOPROTEINS Robert J. Cushley*, W. Dale Treleaven, Yashpal I. and David B. Fenske
Parmar, Ravinder S. Chana,
Department of Chemistry, Simon Fraser University, Burnaby, British Columbia, Canada V5A 156 Received June 16, 1987
SUMMARY.From the viscosity dependence of the 31P RMR signals, the diffusion coefficients DT of phospholipid molecules in the surface monolayer of HDL, LDL and VLDL have been determined. DT for HDL, and HDL, are found to be 2.3~10-~ cm>/5 and 1.8~10-~ cm’/s, respectively. These values are similar to values reported for diffusion of phosphoiipid molecules in phospholipid bilayers above the gel to liquid crystalline phase transition temperature. Viscosity dependence of [16,16,16-ZH,]phosphatidylcholine incorporated into HDL, yielded a value similar to that determined by 31P (D = 1.9x1O-8 cm2/s). Slower diffusion coefficients were measured for LDL, an3 VLDL. VLDL had a value DT = 9.1x10-' cm2/s. The diffusion coefficient for LDL, was 1.4~10-~ cml/s. Thus, diffusion of phospholipids in LDL, is a full order of magnitude slower at 25OC than diffusion of phospholipids in the HDLs. B’ 1987 Acadcmlc Press, Inc. The human serum lipoproteins spherical
particles
phospholipids specific
of an apolar core consisting
composed
esters and triglycerides
enveloped by an amphiphillic
and cholesterol.
into
of cholesterol
monolayer of
Embeddedin the monolayer are proteins
to the various particles.
incorporated
HDL, LDL and VLDL are essentially
the core - this
Some cholesterol
is believed
should indeed. be the case
to be
for particles
the size of VLDL where the volume of the core components would be sufficient al.(l)
to solubilize
significant
have suggested that
the phospholipid partitioned the ratio
- protein
approximately
Eisenberg et
82% of VLDL cholesterol
is within
monolayer while the remaining cholesterol
in the triglyceride-rich of protein
amounts of cholesterol.
to lipid
core. As particle
density
is
increases,
increases at the expense of neutral
lipid.
LDL, low density lipoprotein; Abbreviations: HDL, high density lipoprotein; VLDL, very low density lipoprotein; PC, phosphatidylcholine; SPM, sphingomyelin. *Author to whomcorrespondence should be addressed. 0006-291X/87$1.50 1139
AN
Copyright 0 1987 rights qf reproducfion
by Academic Press, Inc. in any form reserved.
Vol.
146,
BIOCHEMICAL
No. 3, 1987
The major
role
AND
of the serum lipoproteins
from various
tissues.
accomplished
via
between
membrane and lipoprotein
cell
different
high affinity
is
delivery
Thus,
recognize
the
the recognition
is
While myriads of studies on the lipoproteins
measurement of composition and interactions
components, no previous
is interaction
The receptors
surface.
to or
dependent upon the primary amino acid
i.e.
sequence of the apoproteins.
lipids
or lipid-lipid
monolayer.
on the lipoprotein
COMMUNICATIONS
to transport
membrane receptors
to be structure-based
have involved
RESEARCH
In the case of LDL and HDL lipid
apoproteins
believed
BIOPHYSICAL
study of phospholipid
of the surface
surface dynamics has been
reported.
In the present communication, we present evidence, s1P NMR spectroscopy, different
that
surface phospholipid
based on 'H and
diffusion
is significantly
in HDL, LDL and VLDL.
The NMRtechnique we have used is based upon the behavior of the NMR linewidth
as a function
be related
of solvent viscosity.
Av1,2 can
to the second moment M, by (2) rAv1,2
= M,T, + C
where re is the effective
(1)
correlation
the nucleus and C is a constant. the difference axially
The NMRlinewidth
1
symmetric shielding
e'qQ/h is the static bond. The correlation
tensor.
chemical shift For 'H,
quadrupolar interaction time r,
for isotropic
reorientation
For 31P, M, = (4/45)7fH$(o
a - u is the residual II
time
M,
II
- uI)'
anisotropy
term
~~
is the tumbling
= (9/20)(xezqQ/h)l
constant for a carbon-deuterium
(2) time
for the isotropic
rotation
for diffusion
of the particle (3)
R is the particle
radius,
Roltzmann's constant and T is the absolute temperature. time
where
is
?t = (4nqRJ)/(3kT) where 17is the solvent viscosity,
correlation
where
for an
7-l = r-1 + r-1 e t d The
of
k is
The term 7d is the
in the surface plane
Td = R=/6DT
(4) 1140
Vol. 146, No. 3, 1987
BIOCHEMICAL
and DT is the translational obtained from the ratio (Av1,2 - C)-l
AND BIOPHYSICAL
diffusion
coefficient.
RESEARCH COMMUNICATIONS
The value of DT is
of the slope to the intercept = (3kT)/4M,xqR3 + (6D)/M,RZ
from the relationship (5)
MATERIALS AND METHODS Egg lyso-PC and deuterium depleted water were purchased from Sigma Chemical Co. Aquacide (Molecular Weight 70,000) was purchased from Calbiochem. [16,16,16-aH,]Palmitic acid was purchased from Serdary Research Laboratories. [16,16,16-~H,]PC was synthesized by condensation of egg lyso-PC and [16,16,16-2H,]palmitic acid using l,l'-carbonyldiimidazole by a method described in Thewalt et al. (3). The lipoproteins were isolated from fresh (<3 days old) plasma supplied by the Canadian Red Cross. Isolation was by means of sequential ultracentrifugal floatation: VLDL, dc1.006 g/ml; LDL,, d=1.025-1.063 g/ml; HDL,r d=1.063-1.125 g/ml; HDL,, d=1.125-1.210 g/ml. VLDL fractions from several fresh plasma units were pooled and spun twice more (42,000 rpm; 5OC) for 30, then 20, min and the top one-quarter fraction discarded both times. [16,16,16-ZH,IPC was incorporated into HDL, by addition of solid (5 mol % with respect to lipoprotein phospholipid) to the HDL, solution followed by three one-minute sonications at 42OC using a Biosonic III probe-type sonicator . The HDL, purity was checked by immunoelectrophoresis (4). Protein was determined by the method of Lowry (5) as modified by Kashyap et al. (6). Phospholipid was determined as described by Ames (7). Cholesteryl ester and total cholesterol were enzymatically determined using Boehringer Mannheim clinical test kits. Prior to NMRexperiments all lipoproteins except HDL, were dialysed into 0.15M NaCl, 2mtj EDTA, pH 1.5. HDL, was dialysed into deuterium depleted water. The lipoproteins were concentrated by ultracentrifugal floatation (VLDL), treatment with Aquacide (LDL,), or Millipore CX30 submersible ultrafiltration units (LDL,,HDL,). The 31P NMRexperiments were performed at 102.2 MHz, without proton decoupling, using a 5.9 Tesla Nalorac superconducting magnet and a home-built spectrometer. Collection and Fourier transformation of the free induction decays was performed using a Nicolet BNC-12 computer. Spectra were obtained using a one-pulse sequence with phase alternation in order to minimize baseline distortion. Except for HDL,, temperature was controlled at 25f0.5Y by a home-built solid state controller/home-built variable temperature probe. 2H NMRspectra were determined as above at 38.8 MHz. The spectra for VLDL, LDL, and HDL, were analyzed using an iterative least squares fitting routine to Lorentzian lineshape functions. The plots in Fig. 1 were analyzed using a weighted least squares routine courtesy of Dr. Ian Gay, Simon Fraser University. Mean sizes of VLDL and LDL, were determined using a model 270 Nicomp Submicron Particle Sizer. Electron micrographs of HDL, were obtained using a Philips EM300 Electron Microscope at 80 kV. Electron microscopy samples were stained with 2% ammoniummolybdate at pH 8.0 and applied to 200 mesh Formvar carbon coated grids, then air dried. Solvent viscosities were measured using an Ostwald viscometer. RESULTSAND DISCUSSION ,lP NMRspectra were obtained for function
of solvent viscosity.
HDL,, HDL,, LDL, and VLDL as a
Computer generated spectra composedof the 1141
Vol. 146, No. 3, 1987
BIOCHEMICAL
AND BIOPHYSICAL
25
LDL
(3’P
RESEARCH COMMUNICATIONS
NMR)
20. 15.
0
20
601HDL,
9 x -i 0
40
(3’P
NMR)
5
10
60
80
0’0
100 -1
20 ‘LDL
(“P
40
60
80
100
1
60
80
100
12
NMR)
30.
20. 4
lo-
&
07 0 14’
HDL,
(2H
15
20
25
20
:
40
NMR)
120. 1 oo80. 60~ 40. 0
5
10
15
20
q-1 (Pa.&) FIGURE1. Plots of reciprocal NMRlinewidths versus reciprocal of solvent viscosity at 25OCfor, clockwise from bottom left, 'H NMR linewidth of [16,16,16-zH,]phosphatidylcholine in HDL,; SIP NMR linewidths of phospholipids in HDL,; HDL,; LDL,; VLDL. The solid lines in the plots for HDL,, LDL, and VLDLare weighted least squares fits to the data points. The constant C was taken as 15 Hz for 3lP and 2.5 Hz for =H.
superposition
of two Lorentzian
were used to fit
the experimental
contained approximately noise-decoupled
functions,
a signal
spectra in most cases. HDL, and HDL,
20% and 15% SPM respectively,
31P NMRspectroscopy,
proton noise-decoupled 31P NMRof extracted
linewidths
as shown by proton
and the linewidths
equal. LDL, and VLDL contained approximately
Necessary conditions
each for SPM and PC,
of the signals are
40% and 14% SPM as shown by lipids
in CHCl,/MeOH (2:l
for convergence of the computer routine
of the SPM and PC signals be made equal and that
chemical shift
remain unchanged at 0.6 ppm. 1142
were that
v/v). the
the SPM-PC
BIOCHEMICAL
Vol. 146, No. 3, 1987
Fig. viscosity
AND BIOPHYSICAL
1 is a double reciprocal (see eqn. 5). The plots
mL3, HDL, containing respectively.
-5
A plot
mol%
plot
RESEARCH COMMUNICATIONS
of NMRlinewidth
verSuS solvent
are determined based on the 31P NMRof
[16,16,16-~H,]PC,
LDL,, and VLDL,
was also determined from the 2H NMRlinewidth
dependence of the labelled
HDL, sample upon solvent
viscosity
(Fig.
1,
lower left). The sizes of the LDL, and VLDL particles determined by light the Tablel.The light
scattering
used in the NMRstudies were
and the mean particle
HDLs are too small to give reliable
scattering
and since HDL, is reported
radii
E are given in
size measurements by
to have a diameter of 8.5-11 nm
(81, a mean radius of E = 5.0 run was assumed. The size of HDL, was determined by electron From the plots
microscopy. in Fig.
1, diffusion
coefficients
DT for phospholipid
molecules in the surface monolayer of the lipoproteins
were calculated
at
25OC and are presented in the Table. From 31P NMRDT for HDL, and HDL, were calculated
to be 1.8x10-*
approximately
and 2.3x10-*
the sameas that
where values for DT range
from
reported 1x10-*
respectively.
cm*/s,
These values are
for PC in phospholipid to
7~10-~
cm2/s
The fact
(9).
= 1.8x10-8 cm2/s for HDL, when determined by 2H NMRindicates
TABLE
1
DIFFUSION COEFFICIENTS OF PHOSPHOLIPIDS IN THE OUTER MONOLAYER OF HUMAN SERUM LIPOPROTEINS Lipoprotein
HDL2
c Nucleus
D (cm2
R (nm)
. s“)
3’P
4.0a
2.3
2 0.8
x 10-8
3’P
5.ob
1.8
20.3
x 10-8
2H
5.0b
1.9 to.3
x10-8
LDL2
3’P
12.oc
1.4 kO.5
x 10-9
VLDL
3’P
18.4c
9.1 + 1.0
x 10-g
a. Measured by electron microscopy b. Sizes reported with R=4.3 - 5.5 nm (P.J. and Cell Biol. 6_3, 850 (1985) c. Measured by quasielastic light scattering
1143
Dolphin,
Can.
bilayers
J. Bich.
that
that the
DT
BIOCHEMICAL
Vol. 146, No. 3, 1987
phospholipid envisige
AND BIOPHYSICAL
molecules undergo diffusion
each phospholipid
as rigid
(7<5xlO-*s)
entities.
molecule moving as a cylinder
across the surface of the lipoprotein. is rapidly
RESEARCH COMMUNICATIONS
reorienting
The phospholipid
Thus, we randomly walking
molecule, of course,
about the long axis of the cylindrically
symmetric molecule. The larger diffusion.
particles,
LDL, and VLDL, have distinctly
The value of DT = 9.1x10-'
cm*/s for phospholipid
the surface monolayer of VLDL is at least corresponding diffusion
diffusion
is the fact
slower diffusion
compared to HDL can be attributed (10). The ratio
of cholesterol
in the two HDLs it
at 25OC, phospholipid
found in VLDL, it
of phospholipid
to phospholipid
to phospholipid
can explain,
only in part,
acyl chain heterogeneity, the gel to liquid
transition
display
significantly
rate
phospholipids
greater
(see
occuring SPMs, as a result
of
complicated thermal behaviour and,
crystalline
phase transition
temperature is
occuring PCs (11). Howwer, we are
monolayer for LDL, at 25Y,
as it
from LDL, do not display
has been shown
a thermal
over the range 20-45OC (12,13).
2. Core-Monolayer Interactions. cholesteryl
the slower diffusion
in LDL, is so slow:
higher than for naturally
the isolated
in LDL, is the same as
molecules in the LDL, monolayer. We can suggest three
not proposing a gel-like that
content
in our VLDL is 0.27 whereas
ratio
above) than does VLDL or the HDLs. Naturally
significantly
molecules in VLDL
to the much higher cholesterol
reasons why the diffusion
in general,
is in the HDLs.
of phospholipid
1. Monolayer Composition. LDL, has a SPM content
fatty
cm2/s) is
is X0.15.
Since the cholesterol
possible
that,
one order of magnitude slower than it
The slightly
that
in the surface monolayer of the
in the surface monolayer of LDL, (DT = l.l~lO-~
approximately
molecules in
two times slower than the
rate of phospholipid
HDLs. Even more significant,
slower surface
The LDL, core is composedpredominantly
esters while the VLDL core is mostly triglycerides. 1144
It
is
of
Vol.
146,
No. 3, 1987
possible
that
phospholipid just
into
their
AND
BIOPHYSICAL
interactions
is
slowed.
RESEARCH
COMMUNICATIONS
in LDL, are of a nature
At 25OC the core
phase transition
diffusion
that
CT,-20-40°C)
components
(13)
by means of interdigitation
that
of LDL, are
and the solid-like of phospholipid
core
acyl
chains
core.
3. Protein Weight
core-monolayer diffusion
may impair into
BIOCHEMICAL
LDL, contains
Composition.
512,000).
phospholipid
Perhaps
there
and apoB which
a single
strong
is a unique,
causes
protein
apoB (Molecular
interaction
the phospholipid
diffusion
between rate
to slow
significantly. Clearly,
more work
component diffusion however,
any explanation
communication must also
in
(14,15),
must be done to explain lipoproteins. of surface
possibly
accommodate the surface
In light
the differences
of our diffusion
in surface measurements
phenomena such as protein-protein
necessary dynamics
for
efficient
presented
receptor
binding,
here.
REFERENCES L Eisenberg, S., Bilheimer, D. W., Levy, R. I. and Lindgren, F. T. (1973) Biochim. Biophys. Acta 326, 361-377 2, Abragam, A. (1961) Principals of Nuclear Magnetism, pp 424-427, Clarendon Press, Oxford & Thewalt, J. L., Wassall, S. R., Gorrissen and Cushley, R. J. (1985) Biochim. Biophys. Acta 817, 355-365 4. Hatch, 5. T. and Lees, R. S. (1968) Adv. Lipid Res. 6, l-35 5, Lowry, O.H., Rosebrough, N. J., Parr, A. L. and Randall, R. J. (1951) J. %ol. Chem. 193, 265-275 & Kashyap, M. L., Hynd, B. A. and Robinson, K. (1980) J. Lipid Res. 21, 491-495 7. Ames, B. N. (1966) Methods Enzymol. 8, 115-118 z Pownall, H. J. and Gotto, A. M. (1983) Phospholipids and Atherosclerosis (Avogaro, P., Mancini, M., Ricci, G. and Pavletti, R, eds) pp 99-114, Raven Press, New York k Mackay, A. L., Burnell, E. E., Nichol, C. P., Weeks, G., Bloom, M. and Valic, M. I. (1978) FEBS Lett. 88, 97-100 & Cullis, P. R. (1976) FEBS Lett. 70, 223-228 11. Barenholz, Y., Suurkuusk, J., Mountcastle, D., Thompson, T. E. and ztonen, R. L. (1976) Biochemistry 15, 2441-2447 12. Small, D. M. (1977) J. Colloid Interface Sci. 58,581-602 13. Deckelbaum, R. J., Shipley, G. G. and Small, D. S. (1977) J. Biol. Chem. 252, 744-754 14. Devaux, P. and McConnell, H. M. (1972) J. Am. Chem. Sot. 94 ,4475-4481 15. Schlessinger, J. and Elson, E. L. (1981) Membrane Receptors; Receptors xd Recognition (Jacobs, S. and Cautrecasas, P. eds) Series B, Vol. 11, pp 159-170, Chapmanand Hall, New York
1145