点击显示 收起
【摘要】
Objective- The activity of the antitumoral agent bexarotene (Targretin, Bexarotene) depends on its binding to the nuclear retinoid-X receptor (RXR) and subsequent transcriptional regulation of target genes. Through RXR activation, bexarotene may modulate numerous metabolic pathways involved in atherosclerosis. Here, we investigated the effect of bexarotene on atherosclerosis progression in a dyslipidemic murine model, the human apolipoprotein E2 knockin mouse, that develops essentially macrophage-laden lesions.
Methods and Results- Atherosclerotic lesions together with different metabolic pathways involved in atherosclerosis were investigated in mice treated or not with bexarotene. Bexarotene protects from atherosclerosis development in mice, at least in part by improving the circulating cholesterol distribution profile likely via a marked decrease of dietary cholesterol absorption caused by modulation of intestinal expression of genes recently identified as major players in this process, Niemann-Pick-C1-Like1 (NPC1L1) and CD13. This atheroprotection appears despite a strong hypertriglyceridemia. Moreover, bexarotene treatment only modestly modulates inflammatory gene expression in the vascular wall, but markedly enhanced the capacity of macrophages to efflux cellular lipids.
Conclusion- These data provide evidence of a favorable pharmacological effect of bexarotene on atherosclerosis despite the induction of hypertriglyceridemia, likely via a beneficial action on intestinal absorption and macrophage efflux.
In human apolipoprotein E2-knockin mice, the rexinoid bexarotene inhibits atherosclerotic lesion development in association with decreased intestinal cholesterol absorption, resulting in lower circulating atherogenic lipoprotein concentrations. Bexarotene enhances the capacity of macrophages to efflux cellular lipids, whereas it has only modest effects on inflammation in the vascular wall.
【关键词】 atherosclerosis cholesterol homeostasis intestinal cholesterol absorption rexinoid triglycerides
Introduction
Bexarotene [Targretin, 4-[1-(5,6,7,8-tetrahydro-3,5,5,8,8-pentamethyl-2-naphtalenyl) ethenyl] benzoic acid] is an antitumoral agent used as chemotherapy in the treatment of cutaneous T-cell lymphoma. 1 Bexarotene is currently being evaluated for the treatment of other cancers 1 and psoriasis. 2 Thus, bexarotene is both an element of the current antitumoral therapeutic arsenal and a molecule with emerging and promising effects in various pathologies.
Atherosclerosis is a complex inflammatory pathology of the vascular wall, precipitated by systemic factors, such as qualitative or quantitative abnormalities of circulating lipids and lipoproteins. Blood lipid concentrations reflect an equilibrium between absorption of dietary lipids in the small intestine, production after endogenous synthesis in the liver, and removal by different peripheral tissues and the liver. In pathological conditions, circulating atherogenic lipoproteins can be taken up by macrophages in the vascular wall, thus initiating an inflammatory process leading to a progressive evolution of atherosclerosis. Through the action of locally produced cytokines and other inflammatory proteins leading to cell migration and proliferation, the vascular wall is continuously remodeled. Atherosclerosis progressively evolves from the simple fatty streak to advanced atherosclerotic plaques, which may ultimately lead to plaque rupture and thrombus formation.
The pharmacological responses to bexarotene originate from the transcriptional control of gene programs via activation of a member of the nuclear receptor superfamily, the retinoid-X receptor (RXR). As other nuclear receptors, RXR acts as a transcription factor that, on activation by binding of a specific ligand, binds to gene regulatory DNA sequences and subsequently modulates the transcription of target genes. A growing number of studies have reported effects of RXR ligands on plasma lipid and apolipoprotein concentrations, cell migration, proliferation, apoptosis, matrix remodeling, and inflammation, all of which impinge on atherogenesis. 3-5 A beneficial effect on atherogenesis in vivo has been reported only once, with the rexinoid LG100364, a molecule that was never further developed, and thus has no clinical applications, in the apolipoprotein E (apoE) knockout (apoE-KO) mouse. 6 In the present report, we studied the apoE2-KI mouse model, which differs from the apoE-KO mouse model, because it rather develops a mixed dyslipidemia combining hypertriglyceridemia and hypercholesterolemia as frequently found in humans, whereas apoE-KO mice are characterized by an isolated hypercholesterolemia. Furthermore, apoE2-KI mice appear a better pharmacological model to test agonists of nuclear receptors than apoE2-KO mice. 7 Because the concept of selective nuclear receptor modulator (SNRM) agonists, which postulates that different agonists of a nuclear receptor lead to overlapping but also distinct biological effects, also pertains to RXR modulators and because apoE2-KI mice display hypertriglyceridemia that is exacerbated by rexinoid treatment as observed in humans treated with rexinoids, we decided to study the effects of bexarotene, a rexinoid used in humans, on atherosclerosis and related metabolic pathways in the apoE2-KI model.
We show here that bexarotene protects apoE2-KI mice from atherosclerotic lesion development, despite a marked increase in triglycerides, at least in part, by decreasing the atherogenic cholesterol-containing lipoprotein fraction likely due to a marked decrease of dietary cholesterol absorption in relation to decreased intestinal expression of Niemann-Pick C1-Like1 (NPC1L1) 8 and CD13. 9 Bexarotene treatment only modestly modulates the expression of inflammatory genes in the vascular wall, but enhanced the capacity of macrophages to efflux cellular lipids. Thus pharmacological atheroprotection can be obtained despite triglyceride elevation when atherogenic lipoprotein concentrations decrease.
Materials and Methods
Animals and Treatment
Homozygous female human apoE2-KI mice on a C57BL6 genetic background were used. 10 The animal experiments were performed according to the institutional guidelines. Mice were euthanized by cervical dislocation.
Bexarotene was synthesized in the Laboratoire de Chimie Pharmaceutique (Faculté des Sciences Pharmaceutiques, Université de Lille 2, France).
In three different experiments, 2 separate groups of apoE2-KI mice were matched for age. Doses of bexarotene, within the range of doses previously used in rodents, 11 efficient on lipid parameters and nontoxic during the treatment duration were used.
Twenty-four mice (n=12/group) aged 7 to 10 weeks were fed a Western-style diet containing 0.2% cholesterol and 21% fat (SAFE, Augy, France) supplemented or not with bexarotene (0.018% wt/wt) for 11 weeks. Based on food consumption, this dose corresponds to 35 mg per kg. At the end of the treatment, blood was collected by retro-orbital venipuncture under isoflurane anesthesia after 4 hours of fasting (9:00 AM to 1:00 PM ) and plasma was separated. Livers and intestines were removed, duodenum and jejunum separated, longitudinally opened, and enterocytes were scrapped. Hearts were removed and treated as further described.
Sixteen chow fed mice (n=8/group) aged 6 months were dosed for 14 days with bexarotene (300 mpk) or with vehicle alone (carboxymethylcellulose 1%/polyethylene glycol 400/Tween, 90/9.95/0.05, by volume). Hearts were removed and the upper half containing the aortic sinus was sectioned at a plane parallel to a line drawn between the tips of the atria. The intestine was removed and enterocytes obtained as noted.
For these experiments, tissues and cells were frozen in liquid nitrogen (LN 2 ) and stored at -80°C until mRNA analysis.
Sixteen chow diet fed mice (n=8/group) aged 6 months were dosed once daily first with bexarotene (300 mpk) or vehicle (carboxymethylcellulose 1%/PEG 400/Tween, 90/9.95/0.05, by volume) for 5 days, and then with a single dose of [ 14 C]cholesterol (1 µCi) and [ 3 H]sitostanol (2 µCi) in 150 µL of olive oil. The mice were subsequently dosed once daily with bexarotene or vehicle for 4 additional days, totaling 9 consecutive treatment days. Feces were collected during the 4 last days to calculate intestinal cholesterol absorption (see http://atvb.ahajournals.org).
For expanded Materials and Methods used in this article, please see http://atvb.ahajournals.org.
Results
Bexarotene Decreases Atherosclerosis Development in ApoE2-KI Mice
The apoE2-KI mice were fed a Western diet with or without bexarotene for 11 weeks. The treated group gained weight to a comparable extent as the control group, indicating absence of toxicity (data not shown).
Bexarotene-treated mice displayed a marked decrease in atherosclerotic lesion areas as compared with control mice (median 0.028 versus 0.129 mm 2, P <0.001) ( Figure 1 A). Microphotographs representative of treated and control mice ( Figure 1 B) show the decrease of lipid-stained surfaces induced by treatment. Moreover, as revealed by MOMA-2-specific staining of the lesions, macrophage content was reduced on bexarotene treatment and colocalized with Oil-Red-O-stained areas (data not shown).
Figure 1. Bexarotene decreases atherosclerosis development in apoE2-KI mice. Female apoE2-KI mice were fed a Western-style diet supplemented (BEXA) or not (CONT) with 0.018% bexarotene (n=12/group) for 11 weeks. A, Oil-Red-O staining of atherosclerotic lesions in aortas of control ( ) and treated () mice. Graphs represent mean lesion area of the analyzed portion. Each point corresponds to one mouse. Horizontal bars indicate the median of the mean lesion area. *** P <0.01 vs controls. B, Representative micrographs showing atherosclerotic lesions in the aortic sinus of control (CONT) or treated (BEXA) mice. Bar=0.5 mm. Arrows indicate traces of remaining Oil-Red-O staining parts.
Bexarotene Increases Plasma Triglyceride Concentrations in ApoE2-KI Mice
Compared with controls, bexarotene-treated mice showed a marked increase in plasma triglyceride concentrations (+50%, P <0.001) ( Figure 2 A). The triglyceride distribution profile showed that triglycerides were associated with very-low-density lipoprotein (VLDL) (data not shown). To analyze the mechanisms involved in this increase, the hepatic expression of proteins controlling triglyceride metabolism were measured. Stearyl-coenzyme A (CoA) desaturase 1 (SCD1) and fatty acid synthase (FAS) are lipogenic enzymes, whereas angiopoietin-like 3 (Angptl3) is implicated in triglyceride catabolism. The expression of genes encoding SCD1 and FAS was strongly increased in livers of treated mice as compared with controls ( P <0.001), whereas Angptl3 mRNA was only slightly increased ( P <0.05) ( Figure 2 B).
Figure 2. Bexarotene increases plasma triglycerides in apoE2-KI mice. Female apoE2-KI mice were fed a Western-style diet supplemented (BEXA) or not (CONT) with 0.018% bexarotene (n=12/group) for 11 weeks. Mean±SD. * P <0.05, *** P <0.001 vs controls. A, Plasma triglyceride concentrations in control (white bars) and treated (black bars) mice. B, Hepatic SCD1, FAS and Angptl3 mRNA levels. Data are expressed as percentages, arbitrary values of 100% being attributed to the control group.
Because the activity of SCD1 can be evaluated by determining the ratio of oleic acid to stearic acid (desaturation index; C18:1/C18:0), 12 the fatty acid composition of cholesteryl esters in plasma was measured (see http://atvb.ahajournals.org, Table II). Expressed as percentage of total fatty acid mass in cholesteryl esters, saturated fatty acids with 16 and 18 carbon atoms were significantly decreased ( P <0.001) in treated mice, whereas monounsaturated fatty acids with the same number of carbons were unchanged, leading to a significant increase of the ratios C18:1/C18:0 and C16:1/C16:0, indicative of an enhanced SCD1 activity.
Bexarotene Decreases Atherogenic Cholesterol-Containing Lipoproteins in ApoE2-KI Mice
Bexarotene-treated mice exhibited a reduction in total cholesterol levels ( P <0.05), which was entirely caused by reduced non-high-density lipoprotein (HDL) cholesterol concentrations ( P <0.01), whereas HDL cholesterol levels were comparable in treated and control mice ( Figure 3 A). Cholesterol distribution profile analysis in control mice ( Figure 3 B) clearly showed that in the apoE2-KI mouse model, cholesterol is mainly transported by VLDL, intermediary-density lipoprotein (IDL), and low-density lipoprotein (LDL), whereas the HDL fraction represents only 20% of total cholesterol as previously observed. 13 Treatment with bexarotene led to a decrease in non-HDL cholesterol exclusively by decreasing the IDL-LDL fraction without any change in the HDL fraction ( Figure 3 B). The reduction of the atherogenic cholesterol-rich remnant particles in treated mice was associated with reduced plasma concentrations of its main protein component, apoB ( P <0.01) ( Figure 3 C), but hepatic apoB mRNA levels were unchanged ( Figure 3 D). Because marked changes were observed in the cholesterol distribution profile in treated mice, the mechanisms that could explain these modifications were further analyzed by measuring the hepatic expression of genes controlling cholesterol homeostasis. While LDL receptor mRNA levels were markedly enhanced ( P <0.001) in treated mice as compared with controls ( Figure 3 E), 3-hydroxy-3-methylglutaryl (HMG)-CoA-synthase (HMG-CoA-S) gene expression was not altered ( Figure 3 F), suggesting that hepatic removal of LDL from circulation could be enhanced by treatment without concomitant changes in cholesterol synthesis.
Figure 3. Bexarotene decreases concentrations of non-HDL cholesterol-containing lipoproteins in apoE2-KI mice. Female apoE2-KI mice were fed a Western-style diet supplemented (BEXA) or not (CONT) with 0.018% bexarotene (n=12/group) for 11 weeks. * P <0.05, ** P <0.01, *** P <0.001 vs controls. A, Plasma cholesterol concentrations in control (white bars) and treated (black bars) mice. Mean±SD. B, Representative cholesterol profile obtained after size exclusion chromatography of lipoproteins from control ( ) and treated () mice. C, Plasma apoB concentrations. D, Hepatic apoB mRNA levels. Data are expressed as percentages, arbitrary values of 100% being attributed to the control group. Mean±SD. E and F, Hepatic LDL-R and HMG-CoA synthase mRNA levels. Data are expressed as percentages, arbitrary values of 100% being attributed to the control group. Mean±SD.
Bexarotene Decreases Intestinal Cholesterol Absorption and Modulates Expression of Intestinal Genes in ApoE2-KI Mice
To gain insight in the mechanisms underlying the reduced LDL/IDL levels in treated mice, intestinal cholesterol absorption was determined. Bexarotene treatment led to a 64% reduction of cholesterol absorption efficiency ( P <0.001) ( Figure 4 ). Since NPC1L1 and CD13 have recently been identified as critical components of the intestinal cholesterol absorption machinery, intestinal mRNA levels of these genes were measured. NPC1L1 and CD13 mRNA levels were significantly decreased in both duodenum and jejunum of bexarotene-treated mice as compared with controls ( Figure 5 ). In addition, as ABCA1 has been shown to be implicated in intestinal cholesterol metabolism, its expression was also measured. ABCA1 mRNA levels were significantly lower in treated mice than in controls ( Figure 5 ). Comparable decreases both in cholesterol absorption and expression of these genes were observed in mice fed a Western diet for 11 weeks (data not shown).
Figure 4. Bexarotene decreases intestinal cholesterol absorption. Cholesterol absorption in control and treated mice was measured using the fecal dual-isotope method (n=8/group). After a 5-day treatment, mice received an intragastric single dose of [ 14 C]cholesterol and [ 3 H]sitostanol and were subsequently treated for 4 additional days. Feces from the 4 last days of treatment were pooled, lipids were extracted, and radiolabeled isotopes were measured. Mean±SD, *** P <0.001 vs controls.
Figure 5. Bexarotene decreases expression of cholesterol-handling genes in the intestine. Female apoE2-KI mice fed a chow diet were treated with bexarotene (300 mpk) (BEXA) or vehicle (CONT) for 14 days (n=8/group). Data are expressed as percentages, arbitrary values of 100% being attributed to the control group. Mean±SD. * P <0.05, ** P <0.01 vs controls.
Bexarotene Improves Macrophage Lipid Homeostasis In Vivo and In Vitro, and Induces ABCA1 and ABCG1 Expression
The efficiency of plasma from treated and control mice to promote cholesterol efflux ex vivo in Fu5AH hepatoma cells was comparable (30.5±4.7% versus 27.1±6.2%, treated versus controls, P =0.118).
Interestingly, mice fed a Western diet displayed an increased number of Oil-Red-O-stained peritoneal macrophages (73% of total cells) compared with mice fed a chow diet (14% of total cells), and bexarotene-treatment strongly reduced (33% of total cells) the Western diet-induced lipid-loading of these peritoneal macrophages ( Figure 6 A). To further analyze the mechanism, cholesterol-loaded peritoneal macrophages isolated from apoE2-KI mice and in vitro treated with bexarotene were incubated with either apoA-I or HDL as cholesterol acceptors, and cellular cholesterol efflux was measured. The cholesterol efflux was significantly higher in bexarotene-treated macrophages than in controls whatever the acceptor ( P <0.05) ( Figure 6 B). Because ABCA1 and ABCG1 are the main cholesterol transporters mediating apoA-I-dependent and HDL-dependent cholesterol efflux pathways, respectively, the expression of these transporters was compared in the aortic sinus of bexarotene-treated and control mice. The mRNA levels of both proteins were significantly induced by bexarotene treatment ( P <0.01) ( Figure 6 C).
Figure 6. Bexarotene increases macrophage lipid efflux. A, Representative micrographs of in vivo lipid-loaded peritoneal macrophages. Female apoE2-KI mice were fed a chow diet (left), a Western diet (middle), or a Western diet supplemented with bexarotene for 12 days (right). Peritoneal macrophages were recruited using thioglycollate and stained ex vivo by Oil-Red-O. Bar=50 µm. B, Apo A-I and HDL mediated-cholesterol efflux in peritoneal macrophages obtained from apoE2-KI mice. Macrophages were in vitro treated with bexarotene (1 µmol/L) for 24 hours and cholesterol efflux measured. Results are expressed as fold induction as compared with controls. Mean±SD. * P <0.05 vs controls. C, ABCA1 and ABCG1 gene expression in the aortic sinus. Female ApoE2-KI mice fed a chow diet were treated with bexarotene (300 mpk) or vehicle for 12 days (n=8/group). Aortic sinuses were removed from individual mice, RNA extracted, and gene expression analyzed. Data are expressed as percentages, arbitrary values of 100% being attributed to the control group. Mean±SD. ** P <0.01 vs controls.
Bexarotene Only Modestly Modulates Gene Expression of Cytokines in the Aortic Sinus of ApoE2-KI Mice
The expression of genes encoding several molecules implicated in the inflammatory process was measured in the aortic sinus of 6-month-old chow fed female mice after a 14-day treatment with bexarotene. At this age, female apoE2-KI mice display large macrophage-laden lesions in the aortic sinus (personal unpublished results), which allows to study gene expression in the context of inflammatory protein producing cells. Monocyte chemoattractant protein-1 (MCP-1) and macrophage colony-stimulating factor (M-CSF) mRNA levels were minimally altered in bexarotene-treated mice (MCP-1 161±75 versus 100±28, treated versus controls, P <0.05; macrophage colony-stimulating factor 72±18 versus 100±17, treated versus controls, P <0.05). Expression of other genes studied, IL-6, IL-12, tumor necrosis factor-, cyclo-oxygenase 2, tissue factor, and vascular cellular adhesion molecule-1, was not significantly changed by treatment (supplemental Figure I, available online at http://atvb.ahajournals.org).
Discussion
In the present report, we show that bexarotene, a rexinoid used in humans, inhibits atherogenesis in the apoE2-KI mouse. Bexarotene treatment induces effects both on systemic plasma lipid parameters and on macrophage lipid homeostasis. Bexarotene likely exerts atheroprotection in apoE2-KI mice by lowering circulating atherogenic cholesterol-containing lipoproteins. Interestingly, the pronounced effect of bexarotene treatment on plasma cholesterol concentrations coincides with a decrease in intestinal cholesterol absorption, which is associated with a reduced intestinal gene expression of NPC1L1 and CD13. Indeed, NPCL1 has been recently identified as a target of the hypocholesterolemic drug ezetimibe through regulating intestinal cholesterol absorption. 14-18 Thus, inhibiting NPC1L1 activity by ezetimibe in apoE-KO mice 14 or gene expression by bexarotene in apoE2-KI mice leads to a decreased susceptibility to atherosclerosis. CD13 has been identified as a molecule potentially implicated in cholesterol absorption 19 and could also be a molecular target of ezetimibe. 9 Interestingly, bexarotene decreased the expression of ABCA1 in the intestine. This result differs from observation with an other rexinoid, LG268, showing an increased ABCA1 expression in the intestine associated with a decreased intestinal cholesterol absorption. 20 However, the potential effect of ABCA1 in cholesterol absorption has been highly debated 21-23 and a recent study 24 showed its implication in intestinal HDL biogenesis.
One level of complexity of RXR biology relates to its ability to activate transcription as an obligate partner of heterodimerization with many nuclear receptors. Thus, bexarotene activation of RXR could elicit responses of the permissive heterodimers and thus modulate cholesterol absorption. The question addressing which partner(s) of heterodimerization modulate the bexarotene responses in intestinal cholesterol absorption is still open. Despite being expressed in the intestine, Peroxisome proliferator-activated receptor (PPAR) is unlikely to be involved, because a previous study showed no effect of its activation on NPC1L1 gene expression. 25 Conversely, PPAR could be implicated because NPC1L1 is known to be reduced in the intestine on PPAR activation. 16 However, PPAR mRNA levels are decreased in bexarotene-treated mice as compared with controls (data not shown), suggesting the existence of an alternative partner. Finally, the most attractive partner of RXR heterodimerization in the intestine is the liver-X receptor (LXR). Indeed, NPC1L1 is reduced after LXR activation. 25 Surprisingly, expression of the ABCA1 gene, a positive LXR target gene, is decreased in the intestine of bexarotene-treated mice. In addition, expression of ABCG5 and ABCG8, other well-characterized LXR target genes, 26 are also decreased in the intestine of bexarotene-treated mice (data not shown). Interestingly, treatment with bexarotene did increase aortic ABCA1 expression, but only modestly altered expression of genes implicated in the parietal inflammatory process, whereas LXR activation has been shown to exert anti-inflammatory effects. 27 Thus it is unclear to what extent the LXR/RXR pathway mediates the effects of bexarotene and bexarotene certainly acts as a selective, tissue-specific, and gene-specific modulator of the LXR/RXR pathway.
Cholesterol efflux, the obligatory first step of reverse cholesterol transport, is a "bi-partner process." On the one side are the acceptors of cholesterol, namely lipoproteins present in plasma and intercellular fluids, and on the other side the cells and their cholesterol transporters. Among them, ABCA1 and ABCG1 have been shown to specifically mediate cholesterol efflux from cells to lipid-poor apoA-I and to HDL, respectively. 28,29 Treating mice with bexarotene did not significantly modify the capacity of plasma to accept cholesterol from cells ex vivo. By contrast, in vitro incubation of murine cholesterol-laden peritoneal macrophages with bexarotene resulted in a significant increase of lipid-free apoA-I-mediated cholesterol efflux. Moreover, bexarotene enhanced cholesterol efflux mediated by HDL, suggesting that both ABCA1 and ABCG1-mediated cholesterol efflux are facilitated on treatment of macrophages in vitro. Finally, the expression of these cholesterol transporters was enhanced in the aortic sinus, ie, the area enriched in macrophages, on in vivo treatment. Moreover, in vivo treatment decreased the number of lipid-loaded peritoneal macrophages, which correlates with less lipid-loading of the cell population present in the atherosclerotic lesions. Taken together, our present results suggest that macrophages in the aortic sinus of treated mice display enhanced capacity to efflux cholesterol, thus preventing foam cell formation and subsequent lesion development.
As the role of inflammation in atherosclerosis has been increasingly recognized at all stages of its pathogenesis, we measured the expression of genes encoding different cytokines and proteins implicated in the inflammatory process and previously shown to be regulated in vitro by retinoids (natural RXR ligands) or rexinoids (synthetic RXR ligands). 30-34 Bexarotene treatment induced only modest variations in the genes encoding MCP-1 and macrophage colony-stimulating factor, two strong modulators of foam cell formation. In addition, in the subcutaneous dorsal pouch acute inflammatory model, 35 bexarotene treatment did not exert any anti-inflammatory activity (data not shown) indicating that bexarotene has no marked effect in the inflammatory process in the vascular wall in vivo.
In our model, bexarotene-treatment induced a marked increase in triglyceridemia as it does in humans. 1 Our results demonstrate that the biosynthesis of triglycerides could be affected by bexarotene treatment, because hepatic expression of SCD1 and FAS was increased. Interestingly, these genes are targets of the LXR/RXR heterodimer and LXR agonists also increase hepatic lipogenesis and plasma triglycerides. 36 SCD1 protein activity appeared also increased by bexarotene treatment, as assessed by the higher desaturation index (C18:1/C18:0) of plasma cholesteryl esters in treated mice as compared with controls. In addition, the slight increase of hepatic expression of Angptl3, a protein identified as an inhibitor of lipoprotein-lipase, 37 the enzyme responsible for catabolism of triglycerides in the vascular compartment, could also enhance the triglyceridemia. Although epidemiological and clinical studies demonstrated the association of elevated plasma triglyceride levels with increased risk of cardiovascular disease, 38 it is interesting to note that increasing plasma triglyceride levels, as observed not only after bexarotene but also LXR agonist treatment, is not sufficient to aggravate atherosclerosis progression when associated with a decrease in non-HDL cholesterol and an improvement of lipid homeostasis in macrophages.
Acknowledgments
We thank Dr Hafid Mezdour for providing the mouse strain, Pr Jean-Paul Bonte and Brigitte Lacroix for fatty acid composition analyses, and Emmanuelle Vallez, Bruno Derudas, and Jonathan Vanhoutte for excellent technical assistance.
Sources of Funding
This work was supported by grants of the Leducq Foundation, ACI 02 20475 (French Research Ministry and Servier laboratory) and the European project X-TRA-NET (018882).
Disclosures
None.
【参考文献】
Farol LT, Hymes KB. Bexarotene: a clinical review. Expert Rev Anticancer Ther. 2004; 4: 180-188.
Smit JV, Franssen ME, de Jong EM, Lambert J, Roseeuw DI, De Weert J, Yocum RC, Stevens VJ, van de Kerkhof PC. A phase II multicenter clinical trial of systemic bexarotene in psoriasis. J Am Acad Dermatol. 2004; 51: 249-256.
Staels B. Regulation of lipid and lipoprotein metabolism by retinoids. J Am Acad Dermatol. 2001; 45: S158-S167.
Streb JW, Miano JM. Retinoids: pleiotropic agents of therapy for vascular diseases? Curr Drug Targets Cardiovasc Haematol Disord. 2003; 3: 31-57.
Szanto A, Narkar V, Shen Q, Uray IP, Davies PJ, Nagy L Retinoid X receptors: X-ploring their (patho)physiological functions. Cell Death Differ. 2004; 11 (Suppl 2): S126-S143.
Claudel T, Leibowitz MD, Fievet C, Tailleux A, Wagner B, Repa JJ, Torpier G, Lobaccaro JM, Paterniti JR, Mangelsdorf DJ, Heyman RA, Auwerx J. Reduction of atherosclerosis in apolipoprotein E knockout mice by activation of the retinoid X receptor. Proc Natl Acad Sci U S A. 2001; 98: 2610-2615.
Tailleux A, Torpier G, Mezdour H, Fruchart JC, Staels B, Fievet C. Murine models to investigate pharmacological compounds acting as ligands of PPARs in dyslipidemia and atherosclerosis. Trends Pharmacol Sci. 2003; 24: 530-534.
Altmann SW, Davis HR, Jr., Zhu LJ, Yao X, Hoos LM, Tetzloff G, Iyer SP, Maguire M, Golovko A, Zeng M, Wang L, Murgolo N, Graziano MP. Niemann-Pick C1 Like 1 protein is critical for intestinal cholesterol absorption. Science. 2004;%20; 303: 1201-1204.
Kramer W, Girbig F, Corsiero D, Pfenninger A, Frick W, Jahne G, Rhein M, Wendler W, Lottspeich F, Hochleitner EO, Orso E, Schmitz G. Aminopeptidase N (CD13) is a molecular target of the cholesterol absorption inhibitor ezetimibe in the enterocyte brush border membrane. J Biol Chem. 2005; 280: 1306-1320.
Sullivan PM, Mezdour H, Quarfordt SH, Maeda N. Type III hyperlipoproteinemia and spontaneous atherosclerosis in mice resulting from gene replacement of mouse Apoe with human Apoe*2. J Clin Invest. 1998; 102: 130-135.
Lubet RA, Christov K, Nunez NP, Hursting SD, Steele VE, Juliana MM, Eto I, Grubbs CJ. Efficacy of Targretin on methylnitrosourea-induced mammary cancers: prevention and therapy dose-response curves and effects on proliferation and apoptosis. Carcinogenesis. 2005; 26: 441-448.
Attie AD, Krauss RM, Gray-Keller MP, Brownlie A, Miyazaki M, Kastelein JJ, Lusis AJ, Stalenhoef AF, Stoehr JP, Hayden MR, Ntambi JM. Relationship between stearoyl-CoA desaturase activity and plasma triglycerides in human and mouse hypertriglyceridemia. J Lipid Res. 2002; 43: 1899-1907.
Hennuyer N, Tailleux A, Torpier G, Mezdour H, Fruchart JC, Staels B, Fievet C. PPARalpha, but not PPARgamma, activators decrease macrophage-laden atherosclerotic lesions in a nondiabetic mouse model of mixed dyslipidemia. Arterioscler Thromb Vasc Biol. 2005; 25: 1897-1902.
Davis HR, Jr., Compton DS, Hoos L, Tetzloff G. Ezetimibe, a potent cholesterol absorption inhibitor, inhibits the development of atherosclerosis in ApoE knockout mice. Arterioscler Thromb Vasc Biol. 2001; 21: 2032-2038.
Garcia-Calvo M, Lisnock J, Bull HG, Hawes BE, Burnett DA, Braun MP, Crona JH, Davis HR, Jr., Dean DC, Detmers PA, Graziano MP, Hughes M, Macintyre DE, Ogawa A, O?neill KA, Iyer SP, Shevell DE, Smith MM, Tang YS, Makarewicz AM, Ujjainwalla F, Altmann SW, Chapman KT, Thornberry NA. The target of ezetimibe is Niemann-Pick C1-Like 1 (NPC1L1). Proc Natl Acad Sci U S A. 2005; 102: 8132-8137.
van der Veen JN, Kruit JK, Havinga R, Baller JF, Chimini G, Lestavel S, Staels B, Groot PH, Groen AK, Kuipers F. Reduced cholesterol absorption upon PPARdelta activation coincides with decreased intestinal expression of NPC1L1. J Lipid Res. 2005; 46: 526-534.
Murdoch D, Scott LJ. Ezetimibe/Simvastatin: a review of its use in the management of hypercholesterolemia. Am J Cardiovasc Drugs. 2004; 4: 405-422.
Davies JP, Scott C, Oishi K, Liapis A, Ioannou YA. Inactivation of NPC1L1 causes multiple lipid transport defects and protects against diet-induced hypercholesterolemia. J Biol Chem. 2005; 280: 12710-12720.
Kramer W, Glombik H, Petry S, Heuer H, Schafer H, Wendler W, Corsiero D, Girbig F, Weyland C. Identification of binding proteins for cholesterol absorption inhibitors as components of the intestinal cholesterol transporter. FEBS Lett. 2000; 487: 293-297.
Repa JJ, Turley SD, Lobaccaro JA, Medina J, Li L, Lustig K, Shan B, Heyman RA, Dietschy JM, Mangelsdorf DJ. Regulation of absorption and ABC1-mediated efflux of cholesterol by RXR heterodimers. Science. 2000; 289: 1524-1529.
McNeish J, Aiello RJ, Guyot D, Turi T, Gabel C, Aldinger C, Hoppe KL, Roach ML, Royer LJ, de Wet J, Broccardo C, Chimini G, Francone OL. High density lipoprotein deficiency and foam cell accumulation in mice with targeted disruption of ATP-binding cassette transporter-1. Proc Natl Acad Sci U S A. 2000; 97: 4245-4250.
Drobnik W, Lindenthal B, Lieser B, Ritter M, Christiansen WT, Liebisch G, Giesa U, Igel M, Borsukova H, Buchler C, Fung-Leung WP, Von Bergmann K, Schmitz G. ATP-binding cassette transporter A1 (ABCA1) affects total body sterol metabolism. Gastroenterology. 2001; 120: 1203-1211.
Mulligan JD, Flowers MT, Tebon A, Bitgood JJ, Wellington C, Hayden MR, Attie AD. ABCA1 is essential for efficient basolateral cholesterol efflux during the absorption of dietary cholesterol in chickens. J Biol Chem. 2003; 278: 13356-13366.
Brunham LR, Kruit JK, Iqbal J, Fievet C, Timmins JM, Pape TD, Coburn BA, Bissada N, Staels B, Groen AK, Hussain MM, Parks JS, Kuipers F, Hayden MR. Intestinal ABCA1 directly contributes to HDL biogenesis in vivo. J Clin Invest. 2006; 116: 1052-1062.
Duval C, Touche V, Tailleux A, Fruchart JC, Fievet C, Clavey V, Staels B, Lestavel S. Niemann-Pick C1 like 1 gene expression is down-regulated by LXR activators in the intestine. Biochem Biophys Res Commun. 2006; 340: 1259-1263.
Yu L, York J, Von Bergmann K, Lutjohann D, Cohen JC, Hobbs HH. Stimulation of cholesterol excretion by the liver X receptor agonist requires ATP-binding cassette transporters G5 and G8. J Biol Chem. 2003; 278: 15565-15570.
Joseph SB, Castrillo A, Laffitte BA, Mangelsdorf DJ, Tontonoz P. Reciprocal regulation of inflammation and lipid metabolism by liver X receptors. Nat Med. 2003; 9: 213-219.
Lawn RM, Wade DP, Garvin MR, Wang X, Schwartz K, Porter JG, Seilhamer JJ, Vaughan AM, Oram JF. The Tangier disease gene product ABC1 controls the cellular apolipoprotein-mediated lipid removal pathway. J Clin Invest. 1999; 104: R25-R31.
Wang N, Lan D, Chen W, Matsuura F, Tall AR. ATP-binding cassette transporters G1 and G4 mediate cellular cholesterol efflux to high-density lipoproteins. Proc Natl Acad Sci U S A. 2004; 101: 9774-9779.
Zhu L, Bisgaier CL, Aviram M, Newton RS. 9-cis retinoic acid induces monocyte chemoattractant protein-1 secretion in human monocytic THP-1 cells. Arterioscler Thromb Vasc Biol. 1999; 19: 2105-2111.
Kang BY, Chung SW, Kim SH, Kang SN, Choe YK, Kim TS. Retinoid-mediated inhibition of interleukin-12 production in mouse macrophages suppresses Th1 cytokine profile in CD4(+) T cells. Br J Pharmacol. 2000; 130: 581-586.
Tenno T, Botling J, Oberg F, Jossan S, Nilsson K, Siegbahn A. The role of RAR and RXR activation in retinoid-induced tissue factor suppression. Leukemia. 2000; 14: 1105-1111.
Mou L, Lankford-Turner P, Leander MV, Bissonnette RP, Donahoe RM, Royal W. RXR-induced TNF-alpha suppression is reversed by morphine in activated U937 cells. J Neuroimmunol. 2004; 147: 99-105.
Uchimura K, Nakamuta M, Enjoji M, Irie T, Sugimoto R, Muta T, Iwamoto H, Nawata H. Activation of retinoic X receptor and peroxisome proliferator-activated receptor-gamma inhibits nitric oxide and tumor necrosis factor-alpha production in rat Kupffer cells. Hepatology. 2001; 33: 91-99.
Diomede L, Albani D, Sottocorno M, Donati MB, Bianchi M, Fruscella P, Salmona M. In vivo anti-inflammatory effect of statins is mediated by nonsterol mevalonate products. Arterioscler Thromb Vasc Biol. 2001; 21: 1327-1332.
Schultz JR, Tu H, Luk A, Repa JJ, Medina JC, Li L, Schwendner S, Wang S, Thoolen M, Mangelsdorf DJ, Lustig KD, Shan B. Role of LXRs in control of lipogenesis. Genes Dev. 2000; 14: 2831-2838.
Shimizugawa T, Ono M, Shimamura M, Yoshida K, Ando Y, Koishi R, Ueda K, Inaba T, Minekura H, Kohama T, Furukawa H. ANGPTL3 decreases very low density lipoprotein triglyceride clearance by inhibition of lipoprotein lipase. J Biol Chem. 2002; 277: 33742-33748.
Gotto AM, Jr. Triglyceride as a risk factor for coronary artery disease. Am J Cardiol. 1998; 82: 22Q-25Q.
作者单位:From Institut Pasteur de Lille (F.L., C.F., S.L., G.T., V.T., S.B., R.P., J.-C.F., B.S., A.T.), Département d?Athérosclérose, Lille, France; Inserm (F.L., C.F., S.L., G.T., V.T., S.B., R.P., J.-C.F., B.S., A.T.), U54 Lille, France; Université de Lille 2 (F.L., C.F., S.L.,