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【摘要】
Objective- Low-density lipoprotein (LDL) receptor-related protein (LRP1) mediates the internalization of aggregated LDL (agLDL)-LDL trapped in the arterial intima bound to proteoglycans-into human vascular smooth muscle cells (VSMC). LRP1-mediated agLDL uptake induces high-intracellular cholesteryl ester (CE) accumulation. The aim of this study was to characterize the mechanism of agLDL internalization in human VSMC.
Methods and Results- The lipidic component of LDL was labeled with [ 3 H] and the apolipoprotein component with [ 125 I]. 90% of intracellular CE derived from agLDL uptake was not associated with apoB100 degradation but was selectively taken up from agLDL. The inhibition of LRP1 expression by small interfering RNA treatment led to a decrease of 80±0.05% in agLDL-CE selective uptake. AgLDL induced intracellular CE accumulation without a concomitant CE synthesis. Cytosolic and cytoskeletal proteins were not required for CE transport. Electron and confocal microscopy experiments indicate that CE derived from agLDL accumulated in adipophilin-stained lipid droplets that were not removable by high-density lipoprotein.
Conclusions- Taken together, these results demonstrate that LRP1 mediates the selective uptake of CE from agLDL and that CE derived from agLDL is not intracellularly processed but stored in lipid droplets in human VSMC.
LRP1-mediated aggregated low-density lipoprotein (agLDL) uptake induces intracellular cholesteryl ester (CE) accumulation. Our aim was to characterize the mechanism of agLDL internalization in human vascular smooth muscle cells (VSMCs). Results demonstrate that LRP1 mediates the selective uptake of CE from agLDL and that CE derived from agLDL is not intracellularly processed but stored in lipid droplets in human VSMCs.
【关键词】 LRP selective uptake cholesteryl ester adipophilin aggregated LDL
Introduction
One of the main events in the atherogenic process is the accumulation of lipids, mainly cholesteryl esters (CEs), in the subendothelial space of the arterial wall. 1-3 Macrophages become foam cells through uptake of diversely modified low-density lipoprotein (LDL), whereas aggregation of LDL (agLDL) seems to be a key condition for lipid accumulation in vascular smooth muscle cells (VSMCs). 4,5 We have demonstrated previously that the pattern of agLDL internalization differs from that of native LDL (nLDL) in human VSMC. Endocytosed nLDL were found in bright vesicles that were homogenously distributed in the perinuclear space, leading to an unstained cytoplasm surrounding the fluorescent vesicles. In contrast, agLDLs were found in bigger and more diffuse structures distributed throughout the cytoplasm. 5 Contrarily to nLDL, agLDL was shown to be a strong inducer of intracellular CE accumulation in human VSMC. 5-8 These findings are related to differences in the internalization mechanisms; whereas nLDL is taken up by the endocytic LDL receptor (LDLr), which is downregulated by intracellular cholesterol, agLDL is taken up through LDLr-related protein (LRP1). 6,7 Uptake of agLDL through LRP1 allows high-intracellular CE accumulation not only because of its high capacity to bind and internalize agLDL but also because of its transcriptional upregulation by intracellular cholesterol. 8 LRP1 collaborates with heparan sulfate proteoglycans (HS-PGs) to mediate the internalization of certain ligands. 9,10 However, in human VSMC, we have demonstrated previously that HS-PGs have a minimal contribution to agLDL uptake and that, in the absence of LRP1, VSMCs do not internalize agLDL. 11 Although the endocytic mechanism involved in LDLr-mediated nLDL catabolism is well characterized, 12 the process involved in LRP1-mediated agLDL internalization is less known. LRP1 has been involved in endocytosis, 13 phagocytosis, 14 and selective uptake 15,16 pathways in different cell types and with different ligands. Besides LRP1, other receptors and molecules, such as scavenger receptor class B, type I (SR-BI), 17 lipoprotein lipase, 18 hepatic lipase, 19 and apolipoprotein E (apoE) 16 have been involved in selective uptake. Although it has been studied predominantly with high-density lipoprotein (HDL), selective uptake with LDL-CE has been shown in steroidogenic cells, liver, fibroblasts, and murine macrophage cells. 20 The objective of this work was to characterize the mechanism of agLDL internalization in human VSMC. We analyzed: (1) the role of LRP1 and HS-PGs in the process; (2) whether the capacity of agLDL to induce CE accumulation is because of the induction of ACAT esterification; (3) the involvement of lysosomal, cytoskeleton, and kinase proteins on agLDL-derived CE accumulation; and (4) whether the intracellularly accumulated CE is removable by HDL.
We demonstrated for the first time that: (1) intracellular CE accumulation in agLDL-exposed VSMC derives from LRP1-mediated agLDL-CE selective uptake; (2) this mechanism, as opposed to endocytic processes, does not involve the proteolytic lysosomal degradation of apoB100 and upregulation of cholesterol esterification rate; (3) different lysosomal, cytosolic, or cytoskeleton proteins fail to induce alterations in agLDL-CE intracellular accumulation, suggesting that these proteins are not strictly required for the intracellular transport of agLDL-CE; and (4) agLDL-CE accumulates in adipophilin-stained, CE-enriched lipid droplets that are not removable by HDL.
Methods
Materials and Laboratory Methods
Methods, LDL, agLDL, and HDL preparation, 5-8 Real-time PCR, 8 Western blot analysis, 7,8 and free and esterified cholesterol content determination, 5-8 were performed as described previously, and details are provided in the online supplement (which can be accessed at http://atvb.ahajournals.org).
AgLDL Subfractionation
AgLDL was subfractionated using a Cell Sorter (EPICS ALTRA). Two different fractions were collected according to their forward scatter (FS) signal. FS signal is related to particle size. The ratio of cholesterol:protein in total, small, and large aggregates was determined by spectrophotometric methods.
VSMC Culture
Primary cultures of human VSMC were from human coronary arteries of explanted hearts at transplant operations performed at the Hospital de la Santa Creu i Sant Pau. VSMC were obtained by a modification of the explant technique as we described previously. 5-8 VSMCs were used between passages 2 and 6.
To obtain LRP1-deficient cells [small interfering RNA (siRNA)-LRP1-VSMC], human VSMCs were transiently transfected with annealed siRNA (50 nmol/L). LRP1-specific sense and antisense oligodeoxynucleotides were synthesized by Ambion according to our previously published LRP1 target sequences. 6 Fasta analysis (in the Genetic Computer Group Package) indicated that these sequences would not hybridize to other receptor sequences (including LDLrs) in the GenBank database. Cell transfection was performed with siPORT Amine in serum-free DMEM (1% glutamine) according to the kit instructions (SilencerTM siRNA Transfection kit; Ambion no. 1630). The cells did not take up trypan blue, and their morphology was not altered by the procedure. Extra wells were used in the experiments to test the inhibition of LRP1 mRNA and protein expression by real-time PCR and Western blot analysis, respectively. HS-PG-depleted VSMCs were obtained by treating cells with heparinase I and heparinase III (HSI&III; 4 U/mL) 2 hours before and during LDL incubation (18 hours). HSI&III treatment was highly effective to degrade HS-PG in human VSMC, as demonstrated previously. 11 LRP1-siRNA-VSMC and HS-PG-depleted VSMCs were incubated with lipoproteins following the specific conditions of the experimental procedure.
To obtain VSMC-overexpressing LRP1, VSMCs were preincubated with insulin (Ins; 10 nmol/L, 1 hour) 21 or with dexamethasone (Dx; 2 µmol/L, 2 hours). 22 Then VSMCs were washed and incubated with agLDL (100 µg/mL) for 18 hours.
To analyze the role of phagocytosis on agLDL uptake, VSMC were treated with cytochalasin B (1 µg/mL) for 2 hours. Then, VSMCs were washed and incubated with agLDL (100 µg/mL) for 18 hours.
Cholesterol Esterification Assay
This procedure is discussed in the online supplement.
Determination of Selective CE Uptake from Aggregated LDL
This procedure is discussed in the online supplement.
Immunocytochemistry and Electron Microscopy
These procedures were performed following previously described techniques 5 and discussed in the online supplement.
Statistical Analysis
Data were expressed as mean±SEM. Multiple groups were compared by 1 factor ANOVA. Statistical significance was considered when P <0.05.
Results
Selective Uptake Is Involved in CE-agLDL Internalization and Is Dependent on LRP1 Expression
Two agLDL subpopulations, large and small agLDL, were collected according to their FS signal. The ratio cholesterol:protein was similar in total, small, and large agLDL fractions ( Figure 1 A). By incubating VSMC with [ 3 H]- [ 125 I]-agLDL, we observed 90% at any agLDL concentration) was not associated with [ 125 I]-apoB100 internalization. Indeed, <10% of the intracellular CE would derive from apoB100-agLDL degradation ( Figure 1 B). Thus, VSMC seems to acquire most of the CE from agLDL by selective uptake of CE without apoB100 degradation.
Figure 1. A, Aggregated LDL subfractionation. LDL aggregates were separated using a cell sorter into small and large aggregates. The table shows the cholesterol:protein ratio determined by spectrofotometric methods. Results are shown as the mean of 3 different experiments. B, Dose response to agLDL CE selective uptake. VSMCs were incubated with increasing concentrations (25, 50, and 100 µg/mL) of [ 3 H]-[ 125 I]-agLDL for 18 hours. At the end of this period, degraded [ 125 I]-apoB100, cell-associated [ 125 I]-apoB100, and cell-associated [ 3 H]-CE were analyzed as described in Methods. The sum of degraded [ 125 I]-apoB100 and cell-associated [ 125 I]-apoB100 was expressed as CE equivalents using the ratio cholesterol:apoprotein of the LDL. Selective uptake (triangles) is shown as the difference between cell-associated [ 3 H]-CE (CE total; squares) and CE equivalents (rhomboids). CE total, CE equivalents, and CE-selective uptake were expressed as micrograms of CE per milligram of cell protein and are shown as the mean of 3 experiments performed in duplicate (deviations <5% of the mean do not appear in the computer-originated graphs).
The involvement of LRP1 in agLDL-CE selective uptake has been demonstrated by inhibiting and overexpressing LRP1 expression in VSMC. As shown in Figure 2 A, siRNA-LRP1-VSMC showed a significant decrease ( P <0.05) in LRP1 mRNA expression (78.57±0.73%), but they did not show any significant change in LDLr mRNA expression. In agreement with the effects on LRP1 mRNA expression, siRNA-LRP1 almost completely abrogated LRP1 protein expression ( Figure 2 B). Both Ins and Dx significantly increased LRP1 protein expression from 2.01±0.25 AU to 3.39±0.3 AU and 2.98±0.4 AU, respectively ( P <0.05; Figure 2 B). No effect of LRP1 siRNA, Ins, or Dx treatment was observed on -actinin. siRNA LRP1 inhibition led to agLDL-CE selective uptake decrease from 47.7±2 µg/mg protein to 9.54±0.38 µg/mg protein. On the contrary, Ins and Dx-LRP1 upregulation led to agLDL-CE selective uptake increase from 47.7±2 µg/mg protein to 53±1.22 µg/mg protein and 55±1.11 µg/mg protein, respectively ( P <0.05; Figure 2 C). In agreement, agLDL-derived CE accumulation was inhibited from 138±2.98 µg/mg protein to 27.08±1.75 µg/mg protein by siRNA-LRP1 and increased to 151±0.77 µg/mg protein and 197±1.90 µg/mg protein, respectively, by Dx and Ins treatment ( Figure 2 D). No significant alterations on FC content were observed by any treatment.
Figure 2. Role of LRP1 and HSPG on agLDL CE selective uptake by human VSMCs. VSMCs were treated with siRNA anti-LRP1 (50 nmol/L, 24 hours; siRNA-LRP1-VSMC), with Ins (10 nmol/L, 1 hours), or with a mixture of HSI&III (4 U/mL, 2 hours; HS-PG-depleted VSMC) as described in Methods. A, Real-time PCR quantification of LRP1 and LDLr mRNA expression levels in control VSMC ( ) and siRNA-LRP1-VSMC ( ). B, Western blot showing LRP1 (ß-chain) and -actinin protein levels in control, siRNA-LRP1-VSMC (LRP1), Dx-treated, and Ins-treated VSMCs. C, VSMCs were incubated with 100 µg/mL of [ 3 H]-[ 125 I]-agLDL for 18 hours. At the end of this period, degraded [ 125 I]-apoB100, cell-associated [ 125 I]-apoB100, and cell-associated [ 3 H]-CE (CEt) were analyzed as described in Methods. Bar graph showing CEt, the sum of [ 125 I]-degraded and [ 125 I]-cell-associated expressed as CE equivalents using the ratio cholesterol:apoprotein of the LDL, and CE-selective uptake (the difference between CEt and CE equivalents) in control VSMC ( ), siRNA-LRP1-VSMC ( ), HSPG-depleted VSMC (scratched bars), and Ins-VSMC (pointed bars). CEt, CE equivalents, and CE-selective uptake were expressed as micrograms of CE per miligram cell protein and are shown as the mean of 3 experiments performed in duplicate (deviations <5% of the mean do not appear in the computer-originated graphs). D, TLC showing the FC and CE bands corresponding to control, siRNA-LRP1-VSMC, Dx-, and Ins-VSMC incubated with agLDL (100 µg/mL, 18 hours) and bar graphs showing the quantification of FC ( ) and CE ( ) of agLDL-exposed VSMC. CE accumulation was expressed as micrograms of cholesterol per milligrams of protein and shown as mean±SEM of 3 independent experiments. P <0.05, vs control VSMC.
Cytochalasin B, a phagocytosis inhibitor, increased agLDL-CE selective uptake by 1.47-fold (Figure I, available online at http://atvb.ahajournals.org) and HS-PG depletion did not lead to significant alterations of CE selective uptake in VSMC ( Figure 2 C). These results demonstrate a major role for LRP1 but not for HS-PG on agLDL-CE selective uptake in human VSMCs.
Effect of nLDL and agLDL on CE Synthesis and CE Accumulation in VSMCs
VSMCs were incubated overnight with 0.2 mmol/L [ 14 C]-oleate-albumin complex and simultaneously with increasing concentrations of nLDL and agLDL (50, 100, and 200 µg/mL). nLDL induced a moderate CE synthesis, from 0.61±0.11 at 50 µg/mL to 2.18±0.27 nmol/mg protein at 200 µg/mL (Figure II, available online at http://atvb.ahajournals.org). nLDL slightly increased the CE content of VSMCs (from 2.5±0.05 at 50 µg/mL to 10.47±0.04 µg CE/mg protein at 200 µg/mL; Figure II, available online at http://atvb.ahajournals.org). In contrast, agLDL induced a strong intracellular CE accumulation (from 41±0.25 at 50 µg/mL to 100±0.36 µg CE/mg protein at 200 µg/mL; Figure II) concomitantly with a moderate CE synthesis, from 0.27±0.01 at 50 µg/mL to 1.50±0.02 nmol/mg protein at 200 µg/mL (Figure II). Intracellular FC remained unaltered in the presence of nLDL or agLDL in agreement with previous results. 5-8
Effect of Lysosomal, Cytoskeleton, and Protein Kinase Inhibitors on agLDL-Derived CE Content of VSMCs
Whereas the lysosomal inhibitor chloroquine induced a 19-fold increase in CE derived from nLDL uptake, it did not significantly increase CE derived from agLDL uptake. A myosin ATPase inhibitor, 2,3-butanedione monoxime, and a phosphatidylinositol 3-kinase inhibitor, wortmannin, increased CE accumulation from nLDL by 1.55-fold and 1.89-fold, respectively. However, these agents did not exert a significant effect on CE accumulation from agLDL uptake. A serine/threonine protein kinase inhibitor (H89) and a specific protein kinase C inhibitor (bisindolylmaleimide) strongly upregulated CE accumulation in nLDL-exposed VSMCs by 4.72-fold and 3.29-fold, respectively. However, they did not significantly alter agLDL-derived CE accumulation. Additionally, 2,3-butanedione monoxime, wortmannin, H-89, and bisindolylmaleimide slightly increased FC in nLDL-exposed VSMCs, whereas they did not exert any effect on FC content of agLDL-exposed VSMCs. A potent tyrosine kinase inhibitor (genistein) did not show any significant effect on nLDL or agLDL-derived CE. Cytochalasin B (a phagocytosis inhibitor) increased CE accumulation from nLDL and agLDL by 2.6-fold and 2.45-fold, respectively ( Table ).
Effect of Several Lysosomal, Cytoskeleton, Protein Kinase, and Phagocytosis Inhibitors on Intracellular Cholesterol Derived from nLDL or agLDL Uptake in Human VSMCs
Fluorescence microscopy experiments were carried out to visualize the pattern of internalization of either 1,1-dioctadecyl-3,3,3',3'-tetramethylindo-carbocyamine (DiI)-nLDL or DiI-agLDL (50 µg/mL) with or without chloroquine (75 µmol/L). After removal of unbound DiI-LDL by extensive washing, the internalized DiI-LDL (during the 4-hour incubation) was observed under fluorescence microscopy. Whereas chloroquine increased DiI-nLDL fluorescence in vesicles, leading to an internalization pattern similar to that observed for agLDL internalization, chloroquine did not apparently change the pattern of agLDL internalization (Figure III, available online at http://atvb.ahajournals.org).
agLDL CE Accumulates in Lipid Droplets That Are Not Removed by HDL
Conventional thin-section electron microscopy showed agLDL entering VSMCs ( Figure 3 A) and forming enormous lipid-filled vacuoles ( Figure 3 B). As observed in Figure 3, these lipidic vacuoles are surrounded by a membrane that seems to be continuous with that of endoplasmic reticulum. Confocal microscopy ( Figure 4 A) shows that adipophilin, considered a marker of lipid droplet formation, 23,24 colocalizes with the lipid. As shown in Figure 4 B, most cytoplasmic lipid vacuoles are positively marked by adipophilin. These results suggest that CE taken through selective uptake from agLDL accumulates in adipophilin-enriched lipid droplets.
Figure 3. Lipid droplets in human VSMCs exposed to agLDL. A, Thin-section electron micrograph of agLDL entering human VSMCs. VSMCs were incubated for 4 hours with agLDL (100 µg/mL). Cells were then fixed in glutaraldehyde followed by OsO 4. AgLDL entering VSMCs can be observed (arrowhead). B, Thin-section electron micrograph of agLDL forming the lipid droplets. VSMCs were incubated for 18 hours with agLDL (100 µg/mL). Completely formed lipid droplets (*) beside others in the process of formation (arrows). Connections between lipid droplet surrounding membrane and endoplasmic reticulum (arrowheads) are also shown.
Figure 4. Colocalization of lipid droplets and adipophilin in human VSMCs. Confocal microscopy of VSMCs incubated with antibodies antiadipophilin (in green) and DiI (in red). VSMC were incubated with agLDL (100 µg/mL) for 18 hours. Cells were then exhaustively washed, fixed, and incubated with antiadipophilin antibody. During the incubation with the secondary antibody, DiI (1 µg/mL) was added to stain lipid droplets. A, Six of 16 consecutive images obtained by optical sectioning of a cell. B, Photo showing the majority of the lipid vacuoles are positive for adiphophilin staining. Photomicrographs are representative of 2 experiments. Colocalization of adipophilin and lipid appears in yellow.
To analyze the effect of HDL on agLDL-derived CE, VSMCs were incubated with nLDL or agLDL (100 µg/mL) for 18 hours. VSMCs were then exhaustively washed and incubated with increasing concentrations of HDL (50 and 100 µg protein/mL) for an additional 48 hours. HDL (100 µg/mL) decreased the CE accumulation derived from nLDL uptake from 7.86±0.78 to 3.42±0.26 µg CE/mg protein at 100 µg/mL of HDL. In contrast, HDL did not exert any effect on CE accumulation derived from agLDL (Table I, available online at http://atvb.ahajournals.org). These results indicate that agLDL CE is not susceptible to removal by HDL.
Discussion
AgLDL, contrarily to nLDL, is internalized through LRP1, leading to a high-intracellular cholesterol accumulation in human VSMCs. 5-8 Fluorescence microscopy revealed that the agLDL internalization pattern differed from the pattern of cytoplasmic DiI-nLDL internalization in human VSMCs. 5 Here, we demonstrated that agLDL, contrarily to nLDL, is not internalized as a whole particle, because agLDL CE is taken up in a dose-dependent manner without the concomitant proteolytic degradation of apoB100. Thus, CEs are selectively taken up from agLDL in human VSMCs. AgLDL CE selective uptake and agLDL-CE accumulation are lower in LRP1-deficient VSMCs and higher in VSMCs overexpressing LRP1. These results clearly demonstrate the pivotal role of LRP1 on VSMC-agLDL-CE selective uptake. On the contrary, HS-PG depletion did not exert any significant effect on agLDL CE selective uptake. These results are in agreement with a previous study performed by our group in which, by means of biosynthetical labeling of proteoglycans with [ 35 S]-Na 2 SO 4 and specific degradation with HSI&III, we demonstrated that heparinase treatment disrupted the pericellular matrix of VSMCs and specifically degraded HS-PG. 11 HS-PG depletion led to a dramatic decrease on agLDL uptake by fibroblasts, but it only slightly decreased agLDL-derived CE accumulation in human VSMCs. Although HS-PGs do not seem to have a significant role on agLDL uptake in VSMCs, Swarnakar et al 16 described a pivotal role of PG on the selective uptake of apoE-enriched lipoproteins by LRP1 in adrenocortical cells, and other researchers 25-27 described the important role of HS-PGs on the uptake of apoE-enriched lipoproteins in hepatocytes. It has been suggested that the selective uptake of certain LRP1 ligands can be favored by the relative inefficiency of LRP1 as an endocytic receptor compared with the LDLr. 28 The pattern of agLDL-CE selective uptake is in agreement with the dose-dependent upregulation of LRP1 expression by agLDL that we have demonstrated previously in human VSMCs. 8 Upregulation of the SR-BI receptor, involved in the selective uptake of HDL, has also been described in different hormone-stimulated models. 29 The implication of LRP1 in the selective uptake of agLDL-CE in human VSMCs could be determined, at least in part, by the agLDL lipidic structure. The high-CE content in agLDL 5,7 could explain why agLDL can induce intracellular CE accumulation without increasing CE synthesis. 5-8 Our results demonstrate that CE accumulation not only occurs without lysosomal proteolytic apoB100 degradation, but also without lysosomal CE hydrolysis, indicating that there is no lysosomal processing. A possible loss or redistribution of apoB100 in LDL aggregates during the incubation time cannot be excluded. This mechanism and the requirement of apoB100 for the interaction of agLDL with LRP1 will be analyzed in the near future. In contrast to the inhibitory effect of cytochalasin on agLDL uptake by macrophages, 14,30 it seems to have a stimulatory effect on agLDL uptake in human VSMCs. The inhibition of the phagocytic capacity does not interfere on LRP1 functionality. The lack of effect of cytochalasin B and of several lysosomal, cytoskeleton, and protein kinase inhibitors on agLDL uptake in human VSMCs indicates that the mechanism for agLDL uptake in VSMCs completely differs from that described in macrophages. 30 Lysosomal and cytoskeleton proteins are not required for the intracellular transport of agLDL-CE. AgLDL, in contrast with nLDL, is not intracellularly processed in VSMCs, and CE is readily directed to their intracellular sites of storage. Our results agree with those from Reaven et al, 31 who demonstrated that, in the selective uptake pathway, lipoprotein-donated CE flow through vesicles or intracellular membrane sheets and their connections. This process takes place without the involvement of cytosolic proteins and is facilitated by the higher capacity of neutral CE to diffuse through membranes compared with highly charged lipids. 32,33 This transference of CE from the plasmatic membranes to intracellular membranes could also be favored by VSMC sphingomyelin enrichment induced by agLDL. 34 Indeed, a dynamic relationship between cellular cholesterol and phospholipid content has been described. It seems that cholesterol and sphingomyelin directly interact and that this could contribute to the plasma membrane-bound flow of lipids. 35,36 In agreement, electronic microscopy images revealed the continuity between the membrane of lipidic vacuoles and the endoplasmic reticulum membrane in agreement with previous results. 37 Electronic and confocal microscopy images show that CE selectively taken up from agLDL accumulates in large lipid vacuoles. Confocal microscopy images show the colocalization of adipophilin, a specific marker of lipid droplet formation 21,22 and the big lipid vacuoles, indicating that these vacuoles are lipid droplet characteristics of foam cell formation. These results emphasize the capacity of agLDL to induce intracellular lipid accumulation and foam cell formation in VSMCs. Although it has been described that cholesterol efflux from VSMCs was poor compared with other cell types, 38 HDL has been able to diminish the increase in intracellular CE content induced by nLDL but not that induced by agLDL. These results confirm the lack of processing of agLDL in VSMCs and are in agreement with previous results in macrophages describing that the stimulation of adipophilin expression by modified LDL promotes cholesterol storage and reduces cholesterol efflux. 39
In summary, CE derived from LRP1-mediated agLDL selective uptake and stored in lipid droplets surrounded by adipophilin contributes to the transformation of human VSMCs into foam cells and may, therefore, contribute to atherosclerosis. Additional studies are needed to gain insight into the functional implications of these lipid-rich VSMCs in atherosclerosis plaque progression and its complications.
Acknowledgments
This work has been possible thanks to funding from Fondo Investigaciones Sanitarias (FIS) C03-01 (FIS Red Centres Cardiovasculares), SAF2003-03187, Merck Sharp Dohme unrestricted grant, and Fundación Investigación Cardiovascular Catalana-Occidente. S.C.L. and P.C. are predoctoral fellows from Fundación Investigación Cardiovascular and Plan Nacional de Salud, respectively. We thank the Heart Transplant Team of the Division of Cardiology and Cardiac Surgery at Hospital Santa Creu i Sant Pau and the Blood Bank at Hospital Vall d?Hebron, Barcelona, for their collaboration. Electron microscopy experiments were performed in Serveis Cientifico-Tecnics of Barcelona. We thank Dr. Esther Peña for the confocal microscopy images and Dr. Berta Raposo for sorting subfractionation of aggregated LDL. We also thank Laura Nasarre and Vanessa Martín for technical support.
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作者单位:Cardiovascular Research Center, CSIC-ICCC, Hospital de la Santa Creu i Sant Pau, Barcelona, Spain.