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J. Biol. Chem., Vol. 275, Issue 27, 20368-20373, July 7, 2000
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From the
Received for publication, January 31, 2000, and in revised form, March 27, 2000
Both in vitro and in vivo
studies of scavenger receptor class B type I (SR-BI) have implicated it
as a likely participant in the metabolism of HDL cholesterol. To
investigate the effect of SR-BI on atherogenesis, we examined two lines
of SR-BI transgenic mice with high (10-fold increases) and low (2-fold
increases) SR-BI expression in an inbred mouse background hemizygous
for a human apolipoprotein (apo) B transgene. Unlike non-HDL
cholesterol levels that minimally differed in the various groups of
animals, HDL cholesterol levels were inversely related to SR-BI
expression. Mice with the low expression SR-BI transgene had a 50%
reduction in HDL cholesterol, whereas the high expression SR-BI
transgene was associated with 2-fold decreases in HDL cholesterol as
well as dramatic alterations in HDL composition and size including the
near absence of Among the oldest and most consistently replicated finding
concerning the relationship between lipoproteins and risk for
atherosclerotic heart disease is the inverse association of
HDL1 and coronary artery
disease (1, 2). Numerous studies have attempted to explain the
properties of HDL that result in this relationship. A major postulated
anti-atherogenic property of HDL involves the HDL particle
participating in the metabolism of cholesterol through its transport of
this lipid from the periphery to the liver, a process termed reverse
cholesterol transport (3). In addition, it has been proposed that the
particle itself participates in inhibiting pro-atherogenic processes in
the plasma and/or at the vessel wall via a variety of mechanisms
including the inhibition of lipid peroxidation, cytokine-induced
expression of adhesion molecules, and procoagulation processes
(4-7).
A significant advance in the understanding of how HDL may participate
in cholesterol transport has been the identification and functional
analyses of the scavenger receptor class B type I (SR-BI). This is the
first HDL receptor to be well defined at the molecular level, and
in vivo and in vitro studies have supported its
participation in the selective uptake of HDL cholesterol (8-16). Many
of the insights concerning the properties of this receptor in HDL
metabolism have come from studies where SR-BI expression in mice has
been altered by either somatic cell gene transfer or germ line
manipulations. Transgene-mediated overexpression of SR-BI in mice
resulted in dramatic reductions in plasma HDL (15, 16), whereas
adenovirus-mediated overexpression of SR-BI was associated with both a
decrease in plasma HDL as well as a substantial increase in biliary
cholesterol (9). These SR-BI overexpression results are consistent with
studies of mice with decreases in SR-BI expression caused by gene
targeting (12, 14) where a marked increase in plasma HDL was noted in
animals both heterozygous and homozygous for the targeted allele. Taken together, the in vivo and in vitro studies of
SR-BI have consistently supported the suggested role of this molecule
in reverse cholesterol transport.
Although the mouse is relatively resistant to diet-induced
atherogenesis, a variety of transgenic and gene knockout mice have been
created over the last several years with increased atherogenic susceptibility. Mice overexpressing human apo B transgenes with prominent diet-induced hypercholesterolemia have been a useful background to assess the impact on atherogenesis of other
putative pro- or anti-atherogenic genetic manipulations (17, 18). The prominent diet-induced hypercholesterolemia and ensuing
heightened atherosclerosis susceptibility of the apo B transgenics is
the consequence of increased synthesis and decreased clearance of human
apo B containing lipoproteins. FVB mice, the background strain of mice
in this study, do not develop atherogenesis even when fed the
atherogenic diet, whereas C57/BL6 mice do develop lesions on this diet.
This difference allows us to study the well investigated mechanism of
apo B-containing lipoprotein atherogenesis in the absence of an unknown
mechanism that may be involved in the atherogenesis of C57/BL6 mice.
In the present study investigating the effect of SR-BI overexpression
on diet-induced atherogenesis, aortic fatty streak lesions were
quantitatively assessed in animals hemizygous for a human apo B
transgene compared with animals that, in addition to the human apo B
transgene, contain SR-BI transgenes expressing at two different levels.
These studies revealed that moderate increases in SR-BI expression,
accompanied by moderate decreases in HDL concentration in the SR-BI/apo
B transgenics, were associated with a significant reduction in
atherogenesis. In contrast, significant increases in SR-BI expression
accompanied by dramatic changes in HDL concentration, size, and
composition were associated with an atherogenic susceptibility similar
to animals exclusively expressing the human apo B transgene.
Transgenic Mice--
The two lines of SR-BI transgenic mice used
in this study were created in an FVB background and expressed the
transgene specifically in the liver at levels approximately 2-fold (low
SR-BI) and 10-fold (high SR-BI) higher than those of control FVB mice
(16). The transgene in these mice was a construct where the human apo
A-I promoter had been fused to an SR-BI genomic fragment at its
initiation codon.
The human apo B transgenic line (apo B) created and maintained in an
inbred FVB background has previously been described (18). Hemizygous
high or low SR-BI transgenic mice were bred with hemizygous apo B mice
to produce mice that either were nontransgenic, hemizygous for one
transgene (high or low SR-BI or apo B), or doubly hemizygous for both
transgenes (high SR-BI/apo B and low SR-BI/apo B). All mice used in
this study were female.
Total RNA Isolation and RNase Protection Assays--
Total RNA
(10 µg) isolated from livers using RNA Stat 60 (Teltest Inc.,
Friendswood, TX) were subjected to RNase protection assays. The
expression of the endogenous SR-BI, the SR-BI transgene, and the LDL
receptor (LDLr) gene was determined as described previously (16).
Diets and Apolipoprotein and Lipoprotein Analyses--
Mice were
fed Purina mouse chow (number 5001) until 6 weeks of age and then fed
an atherogenic diet consisting of 1.25% cholesterol, 0.5% cholic
acid, and 15% fat for 18 weeks (19). Blood samples from the tail vein
after an overnight fast were collected at 6 weeks of age and 4 weeks
after initiation of the atherogenic diet.
Plasma levels of lipids, lipoproteins, and apolipoproteins were
determined as described previously (16). Briefly, total cholesterol was
determined by an enzymatic colorimetric assay using a kit (number
112756B Roche Molecular Biochemicals). Free cholesterol was determined
using a commercially available kit (Wako, Osaka, Japan). Triglyceride
and phospholipid concentrations were measured with Triglyceride/GB kit
number 450032 (Roche Molecular Biochemicals) and Phospholipid B reagent
(Wako), respectively. HDL cholesterol was measured after selective
precipitation of non-HDL lipoproteins by dextran sulfate and magnesium
chloride. Plasma levels of mouse apo A-I, apo B, and human apo B were
determined by enzyme-linked immunosorbent assays as described
previously (16, 20).
Two-dimensional nondenaturing electrophoresis and antibody blotting was
carried out as described previously (21). Briefly, the first
dimensional gel electrophoresis was run on a 0.75% agarose gel in 50 mM barbital buffer on Gelbond (FMC, Rockland, ME) and then
placed on a 3-16% polyacrylamide gradient gel (Integrated Separation
Systems, Natick, MA) in 25 mM Tris-glycine buffer (pH 8.3).
Electrophoresis was carried out for 4.5 h. After transfer to Nitro
Plus transfer membranes (Micron Separation Incorporated, Westboro, MA),
the samples were treated with a biotinylated rabbit polyclonal antibody
to murine apo AI (Biodesign, Kennebunk, ME) in 10 mM
phosphate buffer, pH 7.0 containing 2% milk. Apo AI-containing HDL
species were visualized with 125I-labeled streptavidin
(Amersham Pharmacia Biotech), and the nitrocellulose membranes were
exposed to Fuji XLS film at
Pooled plasma samples of animals of each genotype were combined and
fractionated using two tandem Superose 6 columns (Amersham Pharmacia
Biotech) as described previously (22). Fractions containing either
non-HDL or HDL were pooled and concentrated with Centricon concentrators (Amicon Inc., Beverly, MA) for further lipid composition and apolipoprotein analyses.
Atherosclerosis Lesion Area--
After 18 weeks of feeding the
atherogenic diet, female mice of the various genotypes were sacrificed,
and their hearts were collected. Aortic sectioning, lipid staining, and
lesion scoring were performed as described previously with some
modification (18). Briefly, the heart and attached aorta were first
perfused with phosphate-buffered saline and then perfused with diluted tissue embedding medium (Tissue-Tek O.C.T. (Miles Inc., Elkhart, IN):H2O, 1:1) and quickly frozen in O.C.T. 10-µm-thick
sections were collected starting with the first and most proximal
section of the aorta where the aorta becomes round and the aortic
valves distinct. Sections were stained with oil-red O and hematoxylin; the lesion area was determined by measuring the oil-red O stained lesions using a calibrated eyepiece at 200× magnification. The mean
lesion area/section/animal was determined for each individual animal.
Statistical Analysis--
Significant differences between means
were determined using the Mann-Whitney U test for nonparametric analysis.
Gene Expression--
To quantitatively assess SR-BI expression and
to distinguish expression of the SR-BI transgene from that of the
endogenous SR-BI gene, we performed RNase protection assays of SR-BI in
differing genetic and dietary environments. Results were normalized
densitometrically against the
The RNase protection assays for mouse LDLr analyzed the response of
this gene to diet as well as SR-BI genotype. The presence of an SR-BI
transgene did not alter the LDLr expression levels, and LDLr expression
was down-regulated after the atherogenic diet treatment in every
genotype. This suggests that the atherogenic diet treatment results in
increases in hepatocellular cholesterol concentrations of sufficient
magnitude to down-regulate LDLr expression. Human apo B transgene
induces up-regulation of LDLr with chow diet and higher response to the
atherogenic diet compared with wild type mice. Human apo B-containing
LDL may block the interaction between mouse apo B and LDLr while not
being internalized, resulting in up-regulation of LDLr.
Plasma Lipid and Apolipoprotein Analyses and FPLC
Profiles--
When fed mouse chow, the SR-BI expression level was
inversely associated with total, HDL, and non-HDL cholesterol
concentrations in apo B transgenic mice (Fig.
2, a-c). Relationship of
plasma human apo B levels to genotype was similar to that of
cholesterol, whereas plasma mouse apo B levels did not show this trend
(Fig. 2, a-e). The atherogenic diet treatment, however, led
to dramatic increases in total cholesterol levels in all the transgenic
lines studied (Fig. 2f). Notably, non-HDL cholesterol
concentrations in each of the three genotypes studied was no longer
inversely related to SR-BI expression levels when the animals were fed
the atherogenic diet (Fig. 2h). Non-HDL cholesterol levels
were similar in low SR-BI/apo B and apo B transgenic mice, whereas high
SR-BI/apo B transgenic mice had significant increases in non-HDL
cholesterol concentrations compared with the low SR-BI/apo B mice.
There no longer exists any significant difference in human apo B levels among the three genotypes of animals after the atherogenic diet treatment (Fig. 2j). Unlike the changes in non-HDL
cholesterol in response to the atherogenic diet, HDL cholesterol levels
remained inversely related to SR-BI expression levels in these animals (Fig. 2, b and g). These results were identical
in animals after either 4 or 18 weeks on the atherogenic diet. Male
mice of each genotype show characteristics in lipid and apolipoprotein
analyses comparable with those in female mice (data not shown).
To examine apolipoprotein distribution among lipoprotein fractions,
mouse and human apo B and mouse apo A-I concentrations in FPLC
fractions were measured in the different groups of animals fed the
atherogenic diet (Fig. 3). Apo A-I
concentrations in the HDL fractions decreased inversely with SR-BI
expression level (Fig. 3b). HDL lipid composition shows no
significant differences between low SR-BI/apo B and apo B transgenics
(Table I). In contrast, high level
expression of SR-BI was associated with the generation of
triglyceride-rich, phospholipid depleted HDL. Although there is no
significant difference in human apo B concentrations in LDL/IDL
fractions between low SR-BI/apo B and apo B transgenics, high SR-BI/apo
B mice have higher concentrations of human apo B in these fractions
(Fig. 3c). Comparing lipid composition and apo B
concentrations of LDL/IDL fractions (Table
II) between the different groups of mice
revealed no consistent pattern of differences in cholesterol,
triglyceride, phospholipid, and apo B content in these particles with
SR-BI expression level. These results suggest that these three lines of
mice can serve as reagents for exploring the effect of SR-BI expression
levels on atherogenesis in a large part, but not entirely, independent
of its effect on non-HDL cholesterol.
The effects of SR-BI on HDL subclass distribution was studied by
two-dimensional nondenaturing gradient gel electrophoresis (Fig.
4). The size and distribution of pre
The HDL particle size distribution in mice fed the atherogenic diet, as
determined by gradient gel electrophoresis of HDL isolated by
ultracentrifugation, is in agreement with a previous study (16) and
consisted of a monodisperse population of particles. When SR-BI was
overexpressed, there was a slight decrease in particle size in low
expressors (9.39 ± 0.09 nm (n = 4)
versus 9.51 ± 0.03 (n = 4) for low
SR-BI/apo B and apo B mice, respectively) and the complete absence of
large HDL particles with the appearance of a minor population of
particles with peak diameter of 7.74 ± 0.15 nm (n = 6) in high expressors.
Lesion Development--
To evaluate the effect of SR-BI
overexpression and associated changes in lipoprotein metabolism on
atherogenesis, the various lines of transgenic mice were fed the
atherogenic diet for 18 weeks. Consistent with previous studies (17,
18), the 18-week atherogenic diet treatment resulted in large fatty
streak lesions in the apo B mice (10133 ± 4035 µm2/aorta) (Fig.
5a). The apo B transgenics
also containing the low expression SR-BI transgene had significantly
smaller lesions (4448 ± 1908 µm2/aorta) than the
mice expressing exclusively the human apo B transgene (p < 0.001). This difference in atherogenesis
susceptibility between apo B and low SR-BI/apo B mice occurred in the
setting of similar non-HDL cholesterol levels, despite the significant
decreases in plasma HDL and apo A-I levels in the low SR-BI/apo B
transgenics. The individual animal plots of the lesion area and HDL
cholesterol levels (Fig. 5b) indicate that low
SR-BI/apo B mice develop smaller fatty streak lesions than apo B mice
with similar plasma HDLc levels. This observation also is apparent when
mice were subgrouped according to their non-HDLc levels (Fig.
5c).
The effect on diet-induced atherogenesis of the high expression SR-BI
transgene differed significantly from that of the low expression SR-BI
transgene. The lesion area of high SR-BI/apo B transgenics was three
times greater than that observed in low SR-BI/apo B animals
(p < 0.001). High SR-BI/apo B transgenics also
developed larger lesions (14692 ± 7238 µm2/aorta)
than those expressing the apo B transgene alone, although this
difference did not quite achieve statistical significance (p = 0.06) (Fig. 5a). The effect of the
differences in non-HDL cholesterol levels in the high SR-BI/apo B
transgenics compared with the low SR-BI/apo B and apo B transgenics on
atherogenesis was minimized when lesion area was compared in animals
grouped according to similar non-HDL cholesterol concentrations. The
lesion area of the high SR-BI/apo B transgenics with lower HDL
cholesterol levels was larger than that of low SR-BI/apo B and the apo
B transgenics, when comparing animals grouped at three similar levels
of non-HDL cholesterol (Fig. 5c).
Analysis of SR-BI in several in vivo and in
vitro studies has provided convincing evidence that SR-BI mediates
the selective transport of cholesteryl ester into cells, a process
intimately linked to how HDL is believed to participate in reverse
cholesterol transport (8, 12-16, 24). In the present study we have
investigated the relationship between murine atherogenesis and
differing HDL cholesterol and hepatic SR-BI expression levels. The
demonstration that the low SR-BI/apo B transgenic mice, despite low HDL
cholesterol concentrations, are protected against diet-induced
atherogenesis provides in vivo (25-27) support for the
hypothesis that HDL-mediated reverse cholesterol transport is likely
one mechanism by which HDL participates in inhibiting atherogenesis.
The effects of SR-BI on HDL speciation, size, and composition
previously have been reported (12, 24). In our studies, significant
differences with regard to HDL lipid composition and particle
distribution where noted in the high SR-BI/apo B transgenics compared
with the low SR-BI/apo B transgenics and apo B transgenic control
animals. The near complete absence of The finding that the SR-BI/apo B mice have lower non-HDL as well as HDL
cholesterol levels compared with apo B transgenics when fed the chow
diet agrees with previous SR-BI transgenic studies, suggesting that the
selective uptake of cholesteryl esters via SR-BI is not restricted to
HDL but also includes non-HDL lipoproteins (15, 16, 29-32). Recently,
SR-BI transgenics containing an inactive LDLr allele were shown to
experience decreases in both HDL as well as non-HDL cholesterol when
fed an atherogenic diet (25). This is in contrast to the results of the
present study where the non-HDL cholesterol levels in both the low and
high SR-BI/apo B transgenics, when fed a similar atherogenic diet, underwent marked increases which eliminated any significant difference between these mice and the apo B animals. FPLC analyses shown in Fig. 3
indicate increases of non-HDLc and human apo B levels in high SR-BI/apo
B mice, which are not significant in the plasma lipid analyses shown in
Fig. 2. These findings suggest that the high influx of non-HDLc via
overexpressed SR-BI may stimulate the secretion of lipoproteins, as
well as down-regulate LDLr expression. To what extent this increase of
non-HDL lipoproteins contributes to the atherogenic susceptibility in
high SR-BI/apo B mice is to be investigated in a future study. A
possible explanation for the increase of non-HDLc in SR-BI transgenic
animals is that non-HDL lipoproteins may be a poor substrate for SR-BI.
Because non-HDLc is not taken up as efficiently as HDLc via SR-BI,
non-HDL lipoproteins saturate their binding sites in SR-BI when fed the
atherogenic diet. This renders the levels of non-HDLc and apo B
independent of SR-BI expression. The majority of non-HDL lipoproteins
in these animals contain human apo B, which raises the possibility that human apo B containing lipoproteins may be poorer ligands for mouse
SR-BI than mouse apo B containing lipoproteins.
The effect of SR-BI on atherogenesis has recently been assessed in two
groups of animals: mice containing an SR-BI transgene expressing at
more than 10-fold endogenous levels in combination with LDLr knockout
alleles (25) and homozygous knockouts for both SR-BI and apo E (24). In
these studies dramatic increases and decreases in SR-BI expression
resulted in decreases and increases in atherogenesis, respectively. In
both studies significant alterations in non-HDL cholesterol as well as
HDL cholesterol levels prevented an assessment of the impact of SR-BI
on atherogenesis via its ability to participate in the metabolism of
HDL. The results from our study of low SR-BI/apo B mice sheds light on
the antiatherogenic property of HDL as a key of the reverse cholesterol
transport system. Moreover, studying animals with two different
overexpression levels of SR-BI reveals the complexity of the protective
mechanism of HDL against atherogenesis.
A general observation in studies exploring the effect of transgenes on
organismal phenotypes is that there invariably exists a direct
relationship between the expression level of the transgene and the
magnitude of the transgene effect. Thus, it is surprising that the high
SR-BI/apo B transgenics fail to be protected from atherogenesis at a
level greater or even equal to that of the low SR-BI/apo B transgenics.
The molecular mechanisms contributing to the atherogenic protective
properties of HDL have long been thought to be multifactorial (4-7).
Studies of the high SR-BI expressor based on the absence of
By examining a large number of inbred mice differing in SR-BI
expression levels, we have derived a perspective on the effect of this
molecule on atherogenesis that would have been missed had we examined a
smaller number of mice expressing the SR-BI transgene at a single
level. Although directly supporting the anti-atherogenic properties of
HDL via participation in SR-BI-mediated reverse cholesterol transport,
our results suggest that marked overexpression of SR-BI and its impact
on HDL and possibly non-HDL lipoproteins may lessen the
anti-atherogenic properties normally associated with elevated reverse
cholesterol transport. Taken together, these findings suggest that,
although activating the reverse cholesterol transport system through
increased SR-BI expression is a potential way to reduce atherogenesis,
the level of activity may need to be monitored to maximize
anti-atherogenic benefits.
*
This work was supported by National Institutes of Health
Program Project Grant HL-18574 from the NHLBI and by National
Institutes of Health Grant HL-50590 and Cooperative Research and
Development Agreement Grant BG97×131(00). The E. O. Lawrence
Berkeley National Laboratory was supported by Department of Energy
Contract DE-AC0376SF00098.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.
¶
To whom correspondence should be addressed: Genome Sciences
Dept., Lawrence Berkeley National Lab., One Cyclotron Rd., MS-84-171 Berkeley, CA 94720. Tel.: 510-486-5072; Fax: 510-486-4229; E-mail: Emrubin@lbl.gov.
Published, JBC Papers in Press, April 4, 2000, DOI 10.1074/jbc.M000730200
The abbreviations used are:
HDL, high density
lipoprotein;
SR-BI, scavenger receptor class B type I;
LDL, low density
lipoprotein;
LDLr, LDL receptor;
apo, apolipoprotein;
FPLC, fast
protein liquid chromatography;
HDLc, HDL cholesterol.
Relationship between Expression Levels and Atherogenesis in
Scavenger Receptor Class B, Type I Transgenics*
,,,¶
Lawrence Berkeley National Laboratory,
Berkeley, California 94720 and § Pfizer Inc., Department of
Cardiovascular & Metabolic Diseases, Groton, Connecticut 06340
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
-migrating particles as determined by
two-dimensional electrophoresis. The low expression SR-BI/apo B
transgenics had more than a 2-fold decrease in the development of
diet-induced fatty streak lesions compared with the apo B transgenics
(4448 ± 1908 µm2/aorta to 10133 ± 4035 µm2/aorta; p < 0.001), whereas the high
expression SR-BI/apo B transgenics had an atherogenic response similar
to that of the apo B transgenics (14692 ± 7238 µm2/aorta) but 3-fold greater than the low SR-BI/apo B
mice (p < 0.001). The prominent anti-atherogenic
effect of moderate SR-BI expression provides in vivo
support for the hypothesis that HDL functions to inhibit atherogenesis
through its interactions with SR-BI in facilitating reverse cholesterol
transport. The failure of the high SR-BI/apo B transgenics to have
similar or even greater reductions in atherogenesis suggests that the
changes resulting from extremely high SR-BI expression including
dramatic changes in lipoproteins may have both pro- and
anti-atherogenic consequences, illustrating the complexity of the
relationship between SR-BI and atherogenesis.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
MATERIALS AND METHODS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
70 °C. Gradient gel electrophoresis
and particle size distribution was determined by computer-assisted
scanning densitometry as described (16).
RESULTS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
-actin signal. Neither the SR-BI nor
the human apo B transgenes altered the expression of the endogenous
SR-BI gene (Fig. 1). The endogenous SR-BI
expression levels also were not affected by diet-induced
hypercholesterolemia. These results are inconsistent with the previous
report (23). A possible explanation is that RNase protection assays,
which we performed with total liver RNA, may mask the reciprocal
effects on parenchymal and nonparenchymal cells as previously reported.
The SR-BI transgenes in this study, consistent with their previous
analysis (16), expressed at levels more than 10-fold (high SR-BI
transgenics) and 2-fold (low SR-BI transgenics) higher than that of the
endogenous SR-BI genes on both the chow and the atherogenic diet.
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Fig. 1.
RNase protection assay of SR-BI and LDLr gene
expression and the dietary effect on their expression in the
liver. Total RNA was isolated from the livers of mice from each
genotype with or without the atherogenic diet treatment. 10 µg of
total liver RNA from each animal were hybridized with SR-BI 5', mouse
LDLr, or mouse -actin ribo probes and digested with RNase A/T1 mix.
The protected fragments were separated on 5% polyacrylamide/8
M urea gels and were detected by autoradiography. The
expression of endogenous and transgenic SR-BI was identified as 248 and
176 base-sized protected bands, respectively.
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Fig. 2.
Lipid and apolipoprotein analysis of plasma
from high SR-BI/apo B (solid columns), low SR-BI/apo B
(shaded columns), and apo B (open
columns) mice. Total cholesterol (a and
f), HDL cholesterol (b and g), non-HDL
cholesterol (c and h), mouse apo B (d
and i), and human apo B (e and j)
levels in plasma of the animals were determined before (upper
panels) and after (lower panels) the atherogenic diet
treatment. Each bar graph represents the mean ± standard
deviation from 10-15 female animals from each group.
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Fig. 3.
FPLC profile of plasma cholesterol
(a) and apolipoproteins (b-d), in
high SR-BI/apo B (closed circles), low SR-BI
(closed triangles), and apo B (open
circles) mice. Plasma samples from 10-15 mice of each
group fed with the atherogenic diet were combined and subjected to FPLC
fractionation analysis as described under "Materials and Methods."
Total cholesterol (a), apo A-I (b), human apo B
(c), and mouse apo B (d) concentrations in each
fraction were measured.
Lipid composition in HDL fractions
Lipid and apolipoprotein concentrations in LDL/IDL fractions
-HDL species was not affected by the level of expression of SR-BI,
whereas the HDL fraction, predominantly monodisperse, was
influenced by the expression of SR-BI and is markedly decreased in high
SR-BI/apo B plasma. Interestingly, the amount of a less prominent but
distinct HDL population of smaller particles was induced by SR-BI,
suggesting a dose effect.
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Fig. 4.
Two-dimensional nondenaturing polyacrylamide
gel electrophoresis and antibody blotting of plasma from apo B
(a), low SR-BI/apo B (b), and high
SR-BI/apo B mice (c) fed the atherogenic diet.
Plasma samples of 10-15 mice from each group were combined and
subjected to two-dimensional electrophoresis. 20 µl of plasma were
electrophoresed on a 0.75% agarose gel (first dimension) and then
placed on a 3-16% polyacrylamide gradient gel. Electrophoresis in the
second dimension was carried out for 4.5 h. Plasma proteins were
transferred to nitrocellulose membranes, and the murine apo AI was
visualized with a polyclonal rabbit anti-mouse apo AI antibody.
Arrows indicate electrophoretic mobility of lipoproteins in
each gel.
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Fig. 5.
Lesion area development after the 18-week
atherogenic diet treatment (a), individual plots of
the lesion area and HDL cholesterol levels (b), and
the lesion area of the mice subgrouped according to the ranges of
non-HDL cholesterol levels (c). a,
lesion areas in high SR-BI/apo B (solid column), low
SR-BI/apo B (shaded column), and apo B (open
column) transgenic mice were determined by measuring the oil-red O
stained lesions as described under "Materials and Methods." The bar
graph represents the mean ± standard deviation from 14 high
SR-BI/apo B, 14 apo B, or 15 low SR-BI/apo B female mice. b,
lesion area versus plasma HDLc levels of the individual high
SR-BI/apo B (solid circles), low SR-BI/apo B (solid
triangles), and apo B (open circles) animals after
18-week atherogenic diet treatment. c, animals subgrouped
according to the range of their non-HDL cholesterol levels: 250-499,
500-749, and 750-1000 mg/dl. The mean lesion area is represented by
solid columns (high SR-BI/apo B), shaded columns
(low SR-BI/apo B), or open columns (apo B) with p
values shown at the top. The numbers in
parentheses show the mean plasma HDLc levels (mg/dl) of the
animals. One outlying apo B transgenic mouse whose lesion area (46944 µm2/aorta) was more than 2 standard deviations beyond the
other animals of the group was excluded. The exclusion of this animal
did not affect the results or statistical significance.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
-migrating HDL supports the
hypothesized involvement of these particles in the later steps of
reverse cholesterol transport (28) and is in agreement with the
increased HDL-cholesteryl ester clearance previously observed in the
high SR-BI compared with the low SR-BI expressing transgenics (16).
Taken together, these findings suggest increased reverse cholesterol
transport in the high SR-BI transgenics compared with the two other
groups of animals studied.
-migrating particles and their increased HDL cholesterol clearance
(16) suggest that these animals have increased reverse cholesterol
transport compared with the low SR-BI transgenics, as well as the
control animals. Whether the reverse cholesterol transport system,
including peripheral cholesterol efflux, is activated in SR-BI
overexpressing animals remains to be clarified. The dramatic effects of
high SR-BI expression on HDL and more modest effects on non-HDL
lipoproteins suggest that the atherogenesis findings in these animals
may be mediated via these lipoprotein changes, thus countering any
atheroprotective effect of the increase in reverse cholesterol
transport. It is possible that the profound decrease in HDL
concentration and/or HDL lipid composition in high expressor SR-BI
transgenics may lead to a shortage of specific HDL particles with
atherogenesis inhibiting properties. Alterations of LDL/IDL lipoprotein
particles and their effect on atherogenesis in the high SR-BI/apo B
transgenics may also contribute to the increased diet-induced
atherogenic susceptibility of these animals.
FOOTNOTES
ABBREVIATIONS
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TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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