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J Biol Chem, Vol. 274, Issue 44, 31613-31618, October 29, 1999
From the Membrane Biophysics Laboratory, Cardiovascular and
Pulmonary Research Institute, Neuroscience Graduate Program, MCP
Hahnemann University School of Medicine, Allegheny Campus, Pittsburgh,
Pennysylvania 15212 and the The molecular structure of human ocular lens
fiber cell plasma membranes was examined directly using small angle
x-ray diffraction approaches. A distinct biochemical feature of these
membranes is their high relative levels of free cholesterol; the mole
ratio of cholesterol to phospholipid (C/P) measured in these membranes ranges from 1 to 4. The organization of cholesterol in this membrane system is not well understood, however. In this study, the structure of
plasma membrane samples isolated from nuclear (3.3 C/P) and cortical
(2.4 C/P) regions of human lenses was evaluated with x-ray diffraction
approaches. Meridional diffraction patterns obtained from the oriented
membrane samples demonstrated the presence of an immiscible cholesterol
domain with a unit cell periodicity of 34.0 Å, consistent with a
cholesterol monohydrate bilayer. The dimensions of the sterol-rich
domains remained constant over a broad range of temperatures
(5-20 °C) and relative humidity levels (31-97%). In contrast,
dimensions of the surrounding sterol-poor phase were significantly
affected by experimental conditions. Similar structural features were
observed in membranes reconstituted from fiber cell plasma membrane
lipid extracts. The results of this study indicate that the lens fiber
cell plasma membrane is a complex structure consisting of separate
sterol-rich and -poor domains. Maintenance of these separate domains
may be required for the normal function of lens fiber cell plasma
membrane and may interfere with the cataractogenic aggregation of
soluble lens proteins at the membrane surface.
The ocular crystalline lens is a transparent tissue that by means
of altering its shape provides the ability for visible light to be
transmitted unimpeded into the eye and focused onto the retina for
proper visual sensation. The lens is an encapsulated structure
consisting almost entirely of a large number of rigid, elongated cells
known as lens fibers or fiber cells. These cells are produced via the
terminal differentiation of a monolayer of epithelial cells located
just beneath the anterior lens capsule (1). This process begins early
in embryogenesis and continues throughout life, resulting in the
deposition of one layer of fiber cells upon another. As new layers of
fiber cells are produced, existing layers are displaced toward the
center of the lens. Fiber cell layers that are compacted into the
center of the lens during embryonic development and through adulthood
comprise a region known as the lens nucleus; fiber cells
peripheral to the nucleus, including the newly formed and metabolically
active fiber cells, define the lens cortex.
During their progressive displacement toward the lens nucleus, fiber
cells lose all subcellular organelles that would scatter light and thus
impair vision (2). Consequently, plasma membrane becomes essentially
the only organelle of the lens (1). The fiber cell plasma membrane is
unique in that it contains only trace amounts of polyunsaturated fatty
acid (3), very high concentrations of a 26-kDa water channel protein
known as main intrinsic protein (MIP or MP26) (4), and, in the human
lens, a phospholipid composition of over 50% sphingomyelin and
sphingomyelin derivatives (5, 6). In addition, human lens fiber cell
plasma membrane contains a relative concentration of cholesterol that is the highest found in nature (7). The cholesterol to phospholipid (C/P)1 mole ratio ranges from
1 to 2 in the cortex to 3 to 4 in the nucleus (8, 9). In contrast,
plasma membranes of typical eukaryotic cells have C/P mole ratios
between 0.5 and 1.0 (10).
Despite an advanced understanding of the lipid composition of the human
ocular lens, there is little information about the structural
organization of the lens plasma membrane. How does a membrane
accommodate 3 to 4 cholesterol molecules per one phospholipid? The
presence of cholesterol at such extremely high relative concentrations in lens membrane has led to the proposal that the fiber cell plasma membrane is "a mosaic of phospholipid bilayer and cholesterol patches" (8). A number of independent studies employing other biological membrane systems give credence to this possibility. Using
model membrane systems, it has been determined that cholesterol tends
to aggregate into clusters at C/P mole ratios in excess of 0.3 (11),
and C/P mole ratios greater than 1.0 (i.e. 50 mole % sterol) can yield pure cholesterol phases (12). In well defined lipid
monolayer systems, the addition of cholesterol produces lateral sterol
domains, as characterized by microscopy approaches (13-15). The
formation of distinct cholesterol domains has also been observed in
various membrane bilayer systems. Using small angle x-ray diffraction,
it has been shown that increasing the relative cholesterol content to
50% of total phospholipid in model membrane bilayers produces an
immiscible cholesterol monohydrate phase with a unit cell periodicity
or d-space of 34.0 Å existing within the liquid crystalline
lipid bilayer (16). The periodicity of 34.0 Å corresponds to a
tail-to-tail cholesterol bilayer, as the long axis of cholesterol
monohydrate is 17 Å in the crystalline state (17). Recent studies in
our laboratories have also provided evidence for the existence of
separate cholesterol domains in vascular smooth muscle cell plasma
membranes under diseased, atherosclerotic conditions, a process
characterized by an excessive accumulation of cholesterol in the
vascular wall (18). In these diseased membranes, the C/P mole ratio
approached 1.0, a level that is 3-fold higher than in normal membranes.
Small angle x-ray diffraction analysis of these membranes provided
evidence for the formation of membrane-restricted cholesterol domains
in vivo under pathologic conditions.
In the present study, small angle x-ray diffraction approaches were
used to characterize the structural organization of cholesterol within
fiber cell plasma membranes isolated from human ocular lenses.
Immiscible cholesterol monohydrate domains were present in lens
cortical and nuclear membrane samples, and these domains remained
stable over a broad range of temperatures and relative humidity levels.
Additionally, membrane protein content did not affect the presence or
molecular dimensions of the observed cholesterol domains. The
structurally distinct cholesterol phase was found to be restricted
within the surrounding sterol-poor membrane bilayer phase with
dimensions that were highly affected by temperature, humidity, and
protein content. These results provide direct evidence for the
existence of immiscible cholesterol monohydrate domains in human ocular
lens fiber cell plasma membranes under physiologic-like conditions. The
structural stability of these domains suggests a well ordered membrane
system that must be conserved to maintain lens transparency to visible light.
Isolation of Human Lens Plasma Membrane and Lipid--
Six
normal human lenses were obtained from the National Disease Research
Interchange (Philadelphia). The ages of the lens sample donors ranged
from 65 to 77 years. Lenses were decapsulated with the concomitant
removal of lens epithelial cells that adhere to the capsule. The
decapsulated lenses were placed in a 20-cm2 culture dish
containing 8 ml of 5 mM Tris-HCl (pH 7.4), 5 mM EDTA, 10 mM
Cortical and nuclear lens regions were separately homogenized in 8 ml
of buffer A using a glass Dounce homogenizer. Plasma membranes were
isolated using the methods described by Russell, et al.
(19). Briefly, the homogenates were centrifuged at 10,000 × g for 20 min. The pellets were washed twice with buffer A,
extracted twice with 7 M urea in 50 mM Tris-HCl
(pH 7.4), and extracted twice with 0.1 mM NaOH. The pellets
were then washed once with 5 mM Tris-HCl (pH 8.0), 1 mM EDTA, 150 mM NaCl, 0.02% NaN3
(buffer B) and were resuspended in 1.2-1.4 ml of buffer B. Small
aliquots were taken for quantitation of protein using a modified Lowry assay (20). Main intrinsic protein of 26 kDa and its 22-kDa degradation
product were overwhelmingly the principal proteins shown present by
SDS-polyacrylamide gel electrophoresis in the cortical and nuclear
membrane preparations (data not shown). Total lipids from one-half of
each membrane suspension were Folch-extracted as described previously
(21) and dissolved in chloroform. Aliquots of these membrane lipid
extracts were taken for gas-chromatograph quantitation of cholesterol
(22) and colorimetric assay of phospholipid (23). The compositions of
the intact membrane suspensions and reconstituted membrane lipid
samples are shown in Table I.
Preparation of Oriented Intact Lens Plasma Membrane Samples for
X-ray Diffraction--
Intact lens plasma membrane samples were
oriented for x-ray diffraction analysis as described previously (24).
Briefly, 200 µg (phospholipid) of plasma membrane samples (in buffer
B) were loaded into Lucite sedimentation cells. Each sedimentation cell
contained an aluminum foil substrate upon which the membrane pellets
were collected. The membrane samples were centrifuged in a Sorvall
AH-629 swinging bucket ultracentrifuge rotor (DuPont) at 35,000 × g for 50 min at 5 °C. Samples were washed three times with diffraction buffer (0.5 mM HEPES, 150 mM
NaCl, pH 7.3). After the final washing cycle, the supernatants were
removed, and the aluminum foil substrates, containing the membrane
pellets, were removed from the sedimentation cells and mounted on
curved glass supports. The samples were then placed in hermetically
sealed brass canisters in which temperature and relative humidity were controlled during x-ray diffraction experiments.
Preparation of Oriented Lens Membrane Lipid Samples for X-ray
Diffraction--
Aliquots of lens plasma membrane total lipid,
initially solubilized in chloroform (see above), were added directly to
13 × 100 mm glass test tubes to yield 230 µg of phospholipid.
The samples were then dried down under a steady stream of nitrogen gas
to the sides and bottom of the test tubes while vortex mixing. Residual solvent was removed under vacuum. A volume of diffraction buffer was
added to each test tube to yield a final phospholipid concentration of
0.38 mg/ml. Multilamellar vesicles were formed by vortex mixing the
buffer and lens membrane lipids for 3 min at ambient temperature. Volumes yielding the equivalent of 200 µg of phospholipid for each
sample were loaded into sedimentation cells. Oriented membrane multibilayers were prepared by centrifugation, as described above for
the intact membrane samples.
Small Angle X-ray Diffraction Analysis--
The oriented lens
plasma membrane samples were aligned at grazing incidence with respect
to a collimated, monochromatic x-ray beam (CuK
The unit cell periodicity, or d-space, of the membrane lipid
bilayer is the measured distance from the center of one lipid bilayer
to the next, including surface hydration. The d-spaces for
the membrane multibilayer samples were calculated using Bragg's Law,
Saturated salt solutions were used to define the relative humidity (RH)
levels employed in these x-ray diffraction analyses. The following salt
solutions (with associated RH in parentheses) were used in these
experiments: MgCl2·6H2O (33%),
Mg(NO3)2·6H2O (52%),
K2C4H4O6·1/2H2O
(74%), (NH4)2SO4 (79%),
NaKC4H4O6·4H2O
(87%), Na2C4H4O6·2H2O
(92%), NH4H2PO4 (93%),
K2SO4 (97%).
Analysis of Human Lens Fiber Cell Plasma Membrane
Structure--
Small angle x-ray diffraction approaches were used to
characterize directly the structural organization of plasma membranes isolated from human ocular lens fiber cells in the presence and absence
of membrane protein. Representative x-ray diffraction profiles
generated from oriented fiber cell plasma membranes at 20 °C, 92%
RH are shown in Fig. 1. All samples
yielded meridional diffraction patterns consistent with two
structurally distinct membrane domains or phases: a sterol-poor liquid
crystalline membrane bilayer phase, corresponding to diffraction orders
1 and 2, and an immiscible cholesterol monohydrate domain, defined by
diffraction orders 1' and 2'. Calculation of d-space values
corresponding to these diffraction orders revealed distinct structural
features of these separate lipid domains. The width of the sterol-poor membrane bilayer region varied with each sample, with intact plasma membranes from the cortex and nucleus (Fig. 1, A and
C, respectively) yielding d-space values of 80.6 and 88.8 Å, respectively. In the absence of membrane protein
(reconstituted membrane samples), the cortical and nuclear membrane
lipid bilayer d-space was 79.1 Å (Fig. 1, B and
D, respectively). In contrast, the d-space for the cholesterol domain remained unchanged at 34.0 Å. Two-dimensional representations of the x-ray diffraction data are shown in Fig. 2.
Effects of Temperature on Membrane Structure--
Intact and
reconstituted cortical and nuclear plasma membranes were examined over
a temperature range of 5 to 40 °C (Fig. 3). Diffraction peaks corresponding to an
immiscible cholesterol domain were observed at every temperature level.
The calculated width of the cholesterol domains was unaffected by
temperature changes, with a reproducible d-space of 34.0 Å.
In contrast, the surrounding lipid membrane bilayer phase was
significantly affected by sample temperature. Consistent with a
disordering effect with increasing temperature, elevating the
temperature from 5 °C to 40 °C caused an overall decrease in
membrane unit cell periodicity. Intact cortical and nuclear plasma
membrane bilayer d-spaces decreased by 5.2 Å (7%) and 3.3 Å (5%), respectively.
Effects of Relative Humidity on Membrane Structure--
As
observed for temperature, changes in relative humidity did not affect
the presence of cholesterol monohydrate phases in each of the samples
tested (Fig. 4). Over a range of 33 to
97% RH, the cholesterol domains remained highly organized and stable with a consistent d-space value of 34.0 Å. However, the
surrounding membrane bilayer phase for each sample was significantly
altered as a function of relative humidity. With increasing relative
humidity, d-space values increased by 28.2 Å (54%) and
30.9 Å (60%) for intact and reconstituted lens cortical plasma
membrane bilayer phases, respectively. Over the same relative humidity
range, nuclear sample d-space values increased by 40.1 Å (79%) and 24.0 Å (44%) for intact and reconstituted samples,
respectively.
Cholesterol is asymmetrically distributed within typical
eukaryotic cells, and it is estimated that more than 90% of cellular cholesterol associates with the plasma membrane (25). This estimate is
probably low for lens fiber cell plasma membranes, however, because
mature fiber cells lack internal organelles, particularly in the lens
nucleus (8). Plasma membrane accounts for only ~1% of total lens
volume (26, 27), and surface area calculations have indicated that
phospholipid accounts for only ~1/3 of the lens plasma membrane (8).
Because essentially all lens cholesterol is confined to this small
portion of the total lens volume, the C/P mole ratios for native lens
membranes are extremely high. In these studies, the C/P mole ratios
ranged from 2.42 to 3.27 (Table I),
consistent with previous reports (8, 9). These ratios are significantly
greater than the C/P values of 0.5-1.0 reported for the typical cell
membrane (10).
It is well established that C/P mole ratios in excess of 1 (i.e. 50 mole % sterol) can promote the formation of
separate cholesterol domains in the cell membrane (12). Numerous
theoretical and model monolayer and bilayer studies have demonstrated
that the systematic addition of cholesterol to biological membranes can eventually induce lateral phase separation, forming membrane-restricted immiscible sterol domains (11-16, 18, 28). Additionally, recent small
angle x-ray diffraction studies in our laboratory have provided direct
evidence for the formation of separate, membrane-restricted cholesterol
domains in vascular smooth muscle cell plasma membranes isolated from
animals modeling atherosclerosis, a process characterized by an
excessive accumulation of cholesterol in the vascular wall (18). In
these diseased membranes, the C/P mole ratio approached 1.0, a level
3-fold higher than in normal membranes (18). These studies confirm the
physicochemical propensity of cholesterol to form separate membrane
phases at high relative concentrations. Because the C/P mole ratios of
ocular lens fiber cell plasma membranes are extremely high, it has been
proposed that these membrane bilayers are a mosaic of cholesterol-rich
and cholesterol-poor regions (8); however, direct evidence for the
existence of separate cholesterol domains in lens fiber cell plasma
membrane has not been previously provided.
Immediately evident from the results of this study is the presence of
two structurally distinct membrane domains within the lens fiber cell
plasma membrane: a sterol-poor liquid crystalline membrane bilayer
phase and an immiscible sterol-rich monohydrate bilayer phase. A
striking feature of the cholesterol monohydrate phase is its stability
over a broad range of temperatures and relative humidity levels. In
contrast, the sterol-poor liquid crystalline membrane bilayer phase was
significantly influenced by temperature and humidity. The biochemical
basis for these changes in membrane width may be attributed to the
complex head group and acyl chain composition of the lens fiber cell
plasma membrane. This question is being systematically evaluated in a
separate study.
The high levels of cholesterol present in these membrane samples may
contribute to the stability of the lateral cholesterol phases.
Cholesterol is present at levels 2.5-3.5-fold higher than required to
produce sterol domains in previous studies (18). In addition, the
phospholipid constitution of the surrounding membrane bilayer may
promote cholesterol domain stability. Sphingomyelin and its derivative,
4,5-dihydrosphingomyelin, are the most abundant phospholipids in human
ocular lens, accounting for more than 50% of total phospholipid (5).
Cholesterol is known to have favorable molecular interactions with
sphingomyelin (29-31), exhibiting greater affinity for
sphingomyelin-enriched plasma membranes than for other cellular
membranes (32, 33). Although the mechanisms responsible for the
preferential interaction of cholesterol with sphingomyelin are not
fully understood, it is believed that an increased probability of van
der Waal's forces may contribute to the strength of their interaction
(14, 30, 34). It should be pointed out that sphingomyelin is not
required for the formation of cholesterol domains since domains have
been observed in systems composed exclusively of other lipids (28),
including dimyristoylphosphatidylcholine (35),
dipalmitoylphosphatidylcholine (13),
N-palmitoylgalactosylsphingosine (16), and
dimyristoylphosphatidylserine (28). However, recent experiments
conducted in our laboratory suggest that cholesterol domains form more readily in cholesterol/sphingomyelin binary mixtures
and exhibit stability characteristics similar to that of cholesterol
domains formed in the lens fiber cell plasma membrane (unpublished
data). Slotte (14) has published data suggesting that the high-affinity
interactions of cholesterol with sphingomyelin may reduce the free
energy needed to form the critical nuclei for the growth of cholesterol
domains in cholesterol/sphingomyelin monolayers. In addition, the
lateral surface pressure required to abolish lateral phase boundaries
of cholesterol-rich domains appears to be significantly lower for
cholesterol/dipalmitoylphosphatidylcholine monolayers than for mixtures
of cholesterol/sphingomyelin (14). These data suggest that the
sphingomyelin-rich lens fiber cell membrane provides the ideal lipid
milieu for forming very stable cholesterol domains. It is also
interesting to note that nuclear lens membranes contain greater amounts
of sphingomyelin (36) and saturated fatty acids (9) than do cortical
membranes. This observation would suggest that cholesterol domains
occur more readily in the lens nucleus, possibly explaining the fact
that the diffraction peaks corresponding to the cholesterol domains in
the intact nuclear samples were more well defined than in the intact
cortical samples (compare Fig. 1, A and C).
Protein content did not affect the presence of immiscible cholesterol
domains within the lens fiber cell plasma membrane. However, the
intensity of the cholesterol diffraction peaks was greater in the
absence of membrane protein (reconstituted samples), which may be due
to partial protein interference with diffraction of the cholesterol
domains. It is also clear that the formation of cholesterol domains
does not require lens membrane protein because cholesterol domains were
present in reconstituted samples. Thus, lateral cholesterol domains
occur within the phospholipid bilayer regions of the lens fiber cell
plasma membrane.
These data support a model that is consistent with the existence of
separate cholesterol monohydrate bilayers within the plane of the cell
membrane (Fig. 5). Individual cholesterol
molecules appear to align in a tail-to-tail fashion, as described
previously in model bilayers and atherosclerotic vascular smooth muscle
cell membranes (18, 37). X-ray crystallography approaches have determined that the long-axis dimension of an individual cholesterol monohydrate molecule is 17 Å (17); thus, a tail-to-tail orientation in
the cholesterol bilayer yields a periodicity of 34.0 Å. The formation
of cholesterol domains appears to be supported by direct interaction of
cholesterol with the acyl chains of surrounding membrane phospholipids,
independent of molecular interaction with membrane protein. This
conclusion is supported by the observation of distinct cholesterol
phases in bilayers reconstituted solely from lens fiber cell plasma
membrane lipid.
Direct Evidence for Immiscible Cholesterol Domains in Human
Ocular Lens Fiber Cell Plasma Membranes*
§, and Department of
Biochemistry, Kirksville College of Osteopathic Medicine, Kirksville,
Missouri 63501
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-mercaptoethanol (buffer A) and stirred on a
rotatory mixer at 100 rpm for 2 h. Under these gentle stirring
conditions, the lens cortex separated from the nucleus as clumps of
fiber cells. Based on lens weight before and after fractionation, the removed cortex accounted for 48% of total lens volume.
, 
= 1.54 Å) produced by a Rigaku Rotaflex RU-200, a high brilliance
rotating anode microfocus generator (Rigaku USA, Danvers, MA). The
fixed geometry beamline utilized a single Franks mirror providing
nickel-filtered radiation (K1 and K2 unresolved) at the detection plane.
Diffraction data were collected on a one-dimensional,
position-sensitive electronic detector (Innovative Technologies,
Newburyport, MA), the calibration of which was verified using
cholesterol monohydrate crystals. The sample-to-detector distance used
in these experiments was 150 mm. Representative two-dimensional
diffraction patterns for each sample were also collected on a
two-dimensional PhosphorImager system (Molecular Dynamics, Sunnyvale,
CA) at a sample-to-detector distance of 70 mm.
in which h is the diffraction order number,
(Eq. 1)
is the wavelength of the x-ray radiation (1.54 Å),
d is the membrane lipid bilayer unit cell periodicity, and
is the Bragg angle equal to one-half the angle between
the incident beam and scattered beam.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (27K):
[in a new window]
Fig. 1.
Representative x-ray diffraction patterns
obtained from oriented human ocular lens fiber cell plasma membrane
samples. Data were collected on a one-dimensional,
position-sensitive electronic detector at 20 °C and 92% RH. Typical
diffraction profiles were generated from intact plasma membrane samples
(A) and reconstituted lipid membrane samples (B)
isolated from the lens cortex and from intact plasma membrane samples
(C) and reconstituted lipid membrane samples (D)
isolated from the lens nucleus. In each panel, diffraction
peaks labeled as 1' and 2' correspond to
immiscible cholesterol domains (periodicity of 34.0 Å); peaks labeled
as 1 and 2 correspond to the surrounding membrane
lipid bilayer phase.
View larger version (33K):
[in a new window]
Fig. 2.
Two-dimensional diffraction patterns obtained
from oriented human ocular lens fiber cell plasma membrane
samples. Data were collected at 40 °C, 74% RH. Meridional
diffraction patterns were generated from intact plasma membrane samples
(A) and reconstituted lipid membrane samples (B)
isolated from the lens cortex. Diffraction bands are labeled as for
Fig. 1.
View larger version (59K):
[in a new window]
Fig. 3.
Effects of temperature on lens fiber cell
plasma membrane structure. X-ray diffraction patterns were
collected on a one-dimensional, position-sensitive electronic detector
at low water levels (74% RH) and over a broad range of temperatures
(5-40 °C). Diffraction profiles were generated from intact plasma
membrane samples (A) and reconstituted lipid membrane
samples (B) isolated from the lens cortex and from intact
plasma membrane samples (C) and reconstituted lipid membrane
samples (D) isolated from the lens nucleus. Cholesterol
domains were present at every temperature level and are marked by
arrows on each panel.
View larger version (57K):
[in a new window]
Fig. 4.
Effects of relative humidity on lens fiber
cell plasma membrane structure. X-ray diffraction patterns were
collected on a one-dimensional, position-sensitive electronic detector
at 20 °C and over a broad range of relative humidity levels
(33-97%). Diffraction profiles were generated from intact plasma
membrane samples (A) and reconstituted lipid membrane
samples (B) isolated from the lens cortex and from intact
plasma membrane samples (C) and reconstituted lipid membrane
samples (D) isolated from the lens nucleus. Cholesterol
domains were present at every relative humidity level and are marked by
arrows on each panel.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
Composition of lens membrane samples
View larger version (48K):
[in a new window]
Fig. 5.
Schematic model of the proposed lipid
organization of the human ocular lens fiber cell plasma membrane.
The lens fiber cell plasma membrane is characterized by separate
cholesterol domains with a width of 34.0 Å surrounded by a sterol-poor
liquid crystalline lipid membrane bilayer.
The functional significance of cholesterol domains within the ocular
lens fiber cell plasma membrane is not completely understood. However,
the essential function of the lens fiber cell plasma membrane is to
maintain lens transparency to visible light throughout life, and the
unusually high membrane concentrations of cholesterol appear to be
critical for supporting this function. Using infrared spectroscopy
approaches, it has been determined that the progressive increase in
membrane cholesterol concentration moving from the lens cortex toward
the lens nucleus is necessary to buffer the structural order of these
two regions to similar fluidity levels (38). This membrane ordering
effect of cholesterol may be essential to maintaining lens transparency
and is achieved only by significantly higher concentrations of
cholesterol in nuclear versus cortical membranes. In
addition to containing the highest relative levels of membrane
cholesterol, the lens also contains high concentrations of soluble
protein, known as lens cyrstallins. Association of crystallin,
primarily 
-crystallin, with the lens membrane has been shown to
accompany the development of human and experimental animal cataracts
(39-41). This association may be promoted by reductions in membrane
cholesterol as the inhibition of cholesterol biosynthesis in the lens
has been shown to induce the development of cataracts in rats (42),
dogs (43), and humans (44, 45). Maintenance of high membrane
concentrations of cholesterol may attenuate the interaction of
-crystallin with the lens fiber cell membrane (46), but the
mechanism is not understood. Based on the findings from this study, it
is proposed that the formation of separate sterol-rich and -poor
domains may interfere with the ability of extrinsic proteins to
aggregate at the membrane surface. This hypothesis is currently being
investigated in our laboratory and may lead to new insights into the
effects of fiber cell plasma membrane lipid organization on cataract formation.
| |
FOOTNOTES |
|---|
* The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
§ Supported by National Institutes of Health Grant EY02568.
¶ Supported by National Institutes of Health Grant PPG HL22633. To whom correspondence should be addressed: Allegheny General Hospital, 320 East North Ave., 2-ST, Pittsburgh, PA 15212-4772; Tel.: 412-359-4815; Fax: 412-359-6390; E-mail: mason@pgh.auhs.edu.
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ABBREVIATIONS |
|---|
The abbreviations used are: C/P, mole ratio of cholesterol to phospholipid; RH, relative humidity.
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REFERENCES |
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TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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|---|
| 1. | Rafferty, N. S. (1985) in The Ocular Lens (Maisel, H., ed) , pp. 1-60, Marcel Dekker, Inc., New York |
| 2. |
Bassnett, S.
(1995)
Invest. Ophthalmol. Vis. Sci.
36,
1793-1803 |
| 3. | Broekhuyse, R. M., and Soeting, W. J. (1976) Exp. Eye Res. 22, 653-657[CrossRef][Medline] [Order article via Infotrieve] |
| 4. |
Mulders, S. M.,
Preston, G. M.,
Deen, P. M.,
Guggino, W. B.,
van Os, C. H.,
and Agre, P.
(1995)
J. Biol. Chem.
270,
9010-9016 |
| 5. | Byrdwell, W. C., Borchman, D., Porter, R. A., Taylor, K. G., and Yappert, M. C. (1994) Invest. Ophthalmol. Vis. Sci. 35, 4333-4343[Abstract] |
| 6. | Byrdwell, W. C., and Borchman, D. (1997) Ophthalmic Res. 29, 191-206[Medline] [Order article via Infotrieve] |
| 7. | Zelenka, P. S. (1984) Curr. Eye Res. 3, 1337-1359[Medline] [Order article via Infotrieve] |
| 8. | Li, L. K., So, L., and Spector, A. (1985) J. Lipid Res. 26, 600-609[Abstract] |
| 9. | Li, L. K., So, L., and Spector, A. (1987) Biochim. Biophys. Acta 917, 112-120[Medline] [Order article via Infotrieve] |
| 10. | Emmelot, P. (1977) in Mammalian Cell Membranes (Jamison, G. A. , and Robinson, D. M., eds), Vol. 2 , pp. 1-54, Butterworths, Inc., Boston |
| 11. |
Engelman, D. M.,
and Rothman, J. E.
(1972)
J. Biol. Chem.
247,
3694-3697 |
| 12. | Houslay, M. D., and Stanley, K. K. (1982) Dynamics of Biological Membranes: Influence on Synthesis, Structure and Function , pp. 71-81, John Wiley & Sons, New York, NY |
| 13. |
Rice, P. A.,
and McConnell, H. M.
(1989)
Proc. Natl. Acad. Sci. U. S. A.
86,
6445-6448 |
| 14. | Slotte, J. P. (1995) Biochim. Biophys. Acta 1235, 419-427[Medline] [Order article via Infotrieve] |
| 15. | Slotte, J. P. (1995) Biochim. Biophys. Acta 1237, 127-134[Medline] [Order article via Infotrieve] |
| 16. |
Ruocco, M. J.,
and Shipley, G. G.
(1984)
Biophys. J.
46,
695-707 |
| 17. | Craven, B. M. (1976) Nature 260, 727-729[CrossRef][Medline] [Order article via Infotrieve] |
| 18. |
Tulenko, T. N.,
Chen, M.,
Mason, P. E.,
and Mason, R. P.
(1998)
J. Lipid Res.
39,
947-956 |
| 19. | Russell, P., Robison, W. G., Jr., and Kinoshita, J. H. (1981) Exp. Eye Res. 32, 511-516[CrossRef][Medline] [Order article via Infotrieve] |
| 20. | Lees, M. B., and Paxman, S. (1972) Anal. Biochem. 47 (1), 184-192[CrossRef][Medline] [Order article via Infotrieve] |
| 21. | Fleschner, C. R., and Cenedella, R. J. (1991) J. Lipid Res. 32, 45-53[Abstract] |
| 22. | Cenedella, R. J. (1982) Lipids 17, 443-447[CrossRef][Medline] [Order article via Infotrieve] |
| 23. | Pollet, S., Ermidou, S., Le Saux, F., Monge, M., and Baumann, N. (1978) J. Lipid Res. 19, 916-921[Abstract] |
| 24. | Mason, R. P., Shoemaker, W. J., Shajenko, L., Chambers, T. E., and Herbette, L. G. (1992) Neurobiol. Aging 13, 413-419[CrossRef][Medline] [Order article via Infotrieve] |
| 25. |
Lange, Y.,
and Ramos, B. V.
(1983)
J. Biol. Chem.
258,
15130-15134 |
| 26. | Bloemendal, H., Zweers, A., Vermorken, F., Dunia, I., and Benedetti, E. L. (1972) Cell Differ. 1, 91-106[CrossRef][Medline] [Order article via Infotrieve] |
| 27. | Broekhuyse, R. M., and Kuhlmann, E. D. (1974) Exp. Eye Res. 19, 297-302[CrossRef][Medline] [Order article via Infotrieve] |
| 28. | Bach, D., Borochov, N., and Wachtel, E. (1998) Chem. Phys. Lipids 92, 71-77[CrossRef] |
| 29. | Calhoun, W. I., and Shipley, G. G. (1979) Biochemistry 18, 1717-1722[CrossRef][Medline] [Order article via Infotrieve] |
| 30. | Lund-Katz, S., Laboda, H. M., McLean, L. R., and Phillips, M. C. (1988) Biochemistry 27, 3416-3423[CrossRef][Medline] [Order article via Infotrieve] |
| 31. | McIntosh, T. J., Simon, S. A., Needham, D., and Huang, C. H. (1992) Biochemistry 31, 2020-2024[CrossRef][Medline] [Order article via Infotrieve] |
| 32. |
Wattenberg, B. W.,
and Silbert, D. F.
(1983)
J. Biol. Chem.
258,
2284-2289 |
| 33. | Demel, R. A., Jansen, J. W., van Dijck, P. W., and van Deenen, L. L. (1977) Biochim. Biophys. Acta 465, 1-10[Medline] [Order article via Infotrieve] |
| 34. | Bittman, R. (1993) in Cholesterol in Model Membranes (Finegold, L. X., ed) , pp. 45-65, CRC Press, Boca Raton, FL |
| 35. | Subramaniam, S., and McConnell, H. M. (1987) J. Phys. Chem. 91, 1715-1718[CrossRef] |
| 36. | Broekhuyse, R. M., and Daemen, F. J. M. (1977) in Lipid Metabolism in Mammals (Snyder, F., ed), Vol. 2 , pp. 145-148, Plenum Press, New York |
| 37. | Harris, J. S., Epps, D. E., Davis, S. R., and Kezdy, F. J. (1996) Biochemistry 34, 3851-3857 |
| 38. | Borchman, D., Cenedella, R. J., and Lamba, O. P. (1996) Exp. Eye Res. 62, 191-197[CrossRef][Medline] [Order article via Infotrieve] |
| 39. |
Spector, A.
(1984)
Invest. Ophthalmol. Vis. Sci.
25,
130-146 |
| 40. | Cenedella, R. J., and Fleschner, C. R. (1992) Curr. Eye Res. 11, 801-815[Medline] [Order article via Infotrieve] |
| 41. | Chandrasekher, G., and Cenedella, R. J. (1995) Exp. Eye Res. 60, 707-717[CrossRef][Medline] [Order article via Infotrieve] |
| 42. | Cenedella, R. J., and Bierkamper, G. G. (1979) Exp. Eye Res. 28, 673-688[CrossRef][Medline] [Order article via Infotrieve] |
| 43. | Gerson, R. J., MacDonald, J. S., Alberts, A. W., Chen, J., Yudkovitz, J. B., Greenspan, M. D., Rubin, L. F., and Bokelman, D. L. (1990) Exp. Eye Res. 50, 65-78[CrossRef][Medline] [Order article via Infotrieve] |
| 44. | Kirby, T. J., Acher, R. W. P., and Perry, H. O. (1962) Arch. Ophthalmol. 68, 486-489 |
| 45. | Laughlin, R. C., and Carey, T. F. (1962) J. Am. Med. Assoc. 182 |
| 46. | Tang, D., Borchman, D., Yappert, M. C., and Cenedella, R. J. (1998) Exp. Eye Res. 66, 559-567[CrossRef][Medline] [Order article via Infotrieve] |
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