糖基化磷脂酰肌醇锚定高密度脂蛋白结合蛋白1——影响血浆甘油三酯代谢的新基因

近年研究发现,脂蛋白脂酶(lipoprotein lipase,LPL)水解血浆富含甘油三酯的脂蛋白这一脂解过程中,糖基化磷脂酰肌醇锚定高密度脂蛋白结合蛋白1(glycosylphosphatidylinositol-anchoredhigh density lipoprotein-binding protein 1,GPIHBP1)起到了非常重要的作用。它能够结合LPL和乳糜微粒,发挥脂解平台的作用;同时它也参与LPL向毛细血管内皮细胞的转运。GPIHBP1基因敲除小鼠和GPIHBP1基因突变的病人发生严重高乳糜微粒血症。GPIHBP1的发现丰富了人们对于血浆脂蛋白代谢的认识,并为治疗高乳糜微粒血症提供了新的途径。     

脂蛋白脂酶基因的研究进展

脂蛋白脂酶(lipoprotein lipase, LPL)是脂质代谢的关键酶, 主要催化乳糜微粒和极低密度脂蛋白中的甘油三酯水解, 产生供组织利用的脂肪酸和单酰甘油。LPL基因突变影响LPL活性, 导致脂质代谢紊乱, 与2型糖尿病、高血压、动脉硬化、肥胖、冠心病的发病风险相关联。文章综述了LPL基因的结构、功能、表达调控以及与复杂疾病的关联研究进展。     

脂蛋白脂酶的调控及在动脉粥样硬化中的作用

脂蛋白脂酶(lipoprotein lipase,LPL,EC 3.1.1.34)是降解甘油三酯(triglyceride,TG)的限速酶,其活性降低是引起高甘油三酯血症的主要原因。LPL受到众多因素调控,包括血管生成素样蛋白、载脂蛋白、miRNAs和lncRNAs等。LPL是影响动脉粥样硬化(atherosclerosis,AS)发生发展的重要因素,其分布位置不同决定了LPL具有促AS或抗AS作用。该文重点阐述了LPL调控机制对AS的影响,有助于进一步揭示LPL在脂质代谢及AS发生发展中的作用。     

运动和饮食对脂蛋白酯酶的影响及机制研究进展

脂蛋白酯酶(lipoprotein lipase,LPL)主要由脂肪细胞、心肌细胞、骨骼肌细胞等实质细胞合成和分泌,可以水解乳糜微粒和极低密度脂蛋白中的甘油三酯(triglyceride,TG),对清除体内过多的TG至关重要。激素、营养、运动、过氧化物增殖因子活化受体γ(peroxisome proliferative activated receptorsγ,PPARγ)、载脂蛋白、糖基化磷脂酰肌醇锱定高密度脂蛋白结合蛋白1(glycosylphosphatidylinositol-anchored high-density lipoprotein-binding protein 1,GPIHBP1)、血管生成素样蛋白3和4(angiopoietin-like protein 3 and 4,ANGPTL3和ANGPTL4)等都可调控LPL的表达和活性。本文在介绍LPL结构、功能和调控的基础上,综述运动和饮食干预对LPL表达和活性的影响及其可能机制。     

畜禽PPARα基因研究进展

过氧化物酶体增殖物激活受体(Peroxisome proliferator-activated receptors,PPARs)是核激素受体家族中的配体激活受体,控制许多细胞内的代谢过程,PPARα作为过氧化物酶体增殖物激活受体家族重要成员之一,是调控机体脂质代谢的重要枢纽,在调控畜禽机体肝脏脂质代谢方面有重要作用。PPARα基因由四个结构域组成,多在机体肝脏和脂肪组织中表达,可作为细胞核受体被外源和内源的特异性配体结合并激活,进而结合靶基因发挥对肝脏脂质代谢的调控作用。就PPARα基因的结构特点及表达模式、PPARα基因对肝脏脂代谢的调控机制,以及现阶段PPARα在畜禽方面的研究进展进行阐述,旨在引起人们对PPARα基因调控脂质代谢的关注,并为畜禽肝脏脂质代谢过程的机理研究和相关疾病的治疗提供一些理论支持。     

microRNAs——脂质代谢调控新机制

综述了近年来microRNAs,尤其是miR-33在脂质代谢调控方面的功能研究进展.脂质代谢在细胞水平进行有规律的调控,主要参与者有肝X受体(LXRs)和固醇调节元件结合蛋白(SREBPs)等.最近研究发现,非编码RNAs家族成员microRNAs在转录后水平调节脂质代谢相关基因表达,参与胆固醇、甘油三酯和脂肪酸代谢.其中miR-33可靶向沉默三磷酸脂苷结合盒(ABC)转运体家族成员ABCA1和ABCG1,抑制胆固醇流出和高密度脂蛋白(HDL)合成;通过靶向沉默脂肪酸β-氧化相关基因,如CPT1A、CROT和HADHB表达,抑制脂肪酸氧化;还可沉默AMPK和RIP140的表达,影响甘油三酯代谢.其他microRNAs如miR-122、miR-370、miR-125a-5p、miR-27、miR-320等,也参与调控胆固醇、甘油三脂、脂肪酸代谢及脂肪细胞分化.     

miRNAs与脂蛋白酯酶

miRNAs是一类具有调控基因功能的非编码RNAs,它在细胞核中合成,可转运至细胞质,调控脂质代谢相关性疾病的发生发展。脂蛋白酯酶(lipoprotein lipase,LPL)作为甘油三酯水解的限速酶,由心肌、脂肪、骨骼肌、乳腺及巨噬细胞等实质细胞合成和分泌,在脂蛋白转运和脂质代谢过程中发挥重要作用。近期研究证实多种miRNAs,包括miR-29、miR-467b、miR-590、miR-27、miR-134和miR-186,可通过调控脂蛋白酯酶LPL的表达,进而影响脂质代谢。为了深入探讨miRNAs对LPL的影响,本文以miRNAs对LPL的调控作用进行综述,期望以miRNAs为靶点,为脂质代谢相关性疾病的防治提供治疗方案。     

低氧对脂肪细胞发育及脂质代谢调控研究进展

脂肪细胞的生长、分化与增殖贯穿整个生命过程,脂肪细胞中脂质代谢紊乱影响脂肪组织免疫和全身能量代谢。脂质代谢参与调控机体多种疾病的发生与发展,如高脂血症、非酒精性脂肪肝病、糖尿病和癌症等,对人和动物健康具有重大威胁。低氧诱导因子（hypoxia inducible factor,HIF）是介导机体组织器官中氧感受器的主要转录因子,HIF可调控脂质合成、脂肪酸代谢和脂滴形成并诱导疾病发生。但由于低氧程度、时间和作用方式的不同,对机体脂肪细胞发育和脂质代谢产生有害或有益的影响还无从定论。本文总结了低氧介导转录因子的调控作用以及对脂肪细胞发育和脂质代谢调控的研究进展,旨在揭示低氧诱导脂肪细胞代谢途径变化的潜在机制。     

脂蛋白酯酶研究进展及对动脉粥样硬化的影响北大核心CSCD

脂蛋白脂酶(lipoprotein lipase,LPL)主要在脏器实质细胞合成和分泌,可以水解乳糜微粒(chylomicron,CM)、低密度脂蛋白(low-density lipoproteins,LDL)及极低密度脂蛋白(very low-den-sity lipoproteins,VLDL)中的甘油三酯(triglyceride,TG),对清除体内过多的TG至关重要。新近研究发现LPL的基因结构、合成、分泌及降解具有复杂性,生物功能的发挥和基因的表达也受到多种转录因子、微小RNA(microRNA,miRNA)、相关蛋白及营养激素的调控,其在动脉硬化性疾病中的作用也存在较大的争议。因此,本文主要针对LPL基因的结构、合成与降解、生物功能、表达调控及与动脉硬化性心血管疾病关系的研究进展做一综述,以期进一步明确LPL在心血管疾病中的作用和意义。     

转录因子ChREBP在葡萄糖诱导生脂中的作用

葡萄糖既是动物主要的能量来源和脂肪合成的底物,也可通过转录因子碳水化合物反应元件结合蛋白（ChREBP）调控脂肪生成。ChREBP是具有碱性螺旋-环-螺旋亮氨酸拉链（bHLH/ZIP）结构的转录因子,可激活糖酵解和脂肪生成相关基因的转录表达,在机体脂质代谢和葡萄糖稳态的调控中起重要作用。对ChREBP调控机制的认识,可为肥胖及相关代谢综合征的治疗和肉用动物体脂沉积的营养调控提供基础。本文就有关ChREBP表达、反式激活活性的调控,以及与其他调控因子的相互作用等方面的研究新进展作一综述。     

GPIHBP1, an endothelial cell transporter for lipoprotein lipase

Interest in lipolysis and the metabolism of triglyceride-rich lipoproteins was recently reignited by the discovery of severe hypertriglyceridemia (chylomicronemia) in glycosylphosphatidylinositol-anchored high density lipoprotein-binding protein 1 (GPIHBP1)-deficient mice. GPIHBP1 is expressed exclusively in capillary endothelial cells and binds lipoprotein lipase (LPL) avidly. These findings prompted speculation that GPIHBP1 serves as a binding site for LPL in the capillary lumen, creating "a platform for lipolysis." More recent studies have identified a second and more intriguing role for GPIHBP1-picking up LPL in the subendothelial spaces and transporting it across endothelial cells to the capillary lumen. Here, we review the studies that revealed that GPIHBP1 is the LPL transporter and discuss which amino acid sequences are required for GPIHBP1-LPL interactions. We also discuss the human genetics of LPL transport, focusing on cases of chylomicronemia caused by GPIHBP1 mutations that abolish GPIHBP1's ability to bind LPL, and LPL mutations that prevent LPL binding to GPIHBP1.     

Assessing the role of the glycosylphosphatidylinositol-anchored high density lipoprotein-binding protein 1 (GPIHBP1) three-finger domain in binding lipoprotein lipase

Glycosylphosphatidylinositol-anchored high density lipoprotein-binding protein 1 (GPIHBP1) is an endothelial cell protein that transports lipoprotein lipase (LPL) from the subendothelial spaces to the capillary lumen. GPIHBP1 contains two main structural motifs, an amino-terminal acidic domain enriched in aspartates and glutamates and a lymphocyte antigen 6 (Ly6) motif containing 10 cysteines. All of the cysteines in the Ly6 domain are disulfide-bonded, causing the protein to assume a three-fingered structure. The acidic domain of GPIHBP1 is known to be important for LPL binding, but the involvement of the Ly6 domain in LPL binding requires further study. To assess the importance of the Ly6 domain, we created a series of GPIHBP1 mutants in which each residue of the Ly6 domain was changed to alanine. The mutant proteins were expressed in Chinese hamster ovary (CHO) cells, and their expression level on the cell surface and their ability to bind LPL were assessed with an immunofluorescence microscopy assay and a Western blot assay. We identified 12 amino acids within GPIHBP1, aside from the conserved cysteines, that are important for LPL binding; nine of those were clustered in finger 2 of the GPIHBP1 three-fingered motif. The defective GPIHBP1 proteins also lacked the ability to transport LPL from the basolateral to the apical surface of endothelial cells. Our studies demonstrate that the Ly6 domain of GPIHBP1 is important for the ability of GPIHBP1 to bind and transport LPL.     

The acidic domain of GPIHBP1 is important for the binding of lipoprotein lipase and chylomicrons

GPIHBP1, a glycosylphosphatidylinositol-anchored endothelial cell protein of the lymphocyte antigen 6 (Ly6) family, plays a key role in the lipolysis of triglyceride-rich lipoproteins (e.g. chylomicrons). GPIHBP1 is expressed along the luminal surface of endothelial cells of heart, skeletal muscle, and adipose tissue, and GPIHBP1-expressing cells bind lipoprotein lipase (LPL) and chylomicrons avidly. GPIHBP1 contains an amino-terminal acidic domain (amino acids 24-48) that is enriched in aspartate and glutamate residues, and we previously speculated that this domain might be important in binding ligands. To explore the functional importance of the acidic domain, we tested the ability of polyaspartate or polyglutamate peptides to block the binding of ligands to pgsA-745 Chinese hamster ovary cells that overexpress GPIHBP1. Both polyaspartate and polyglutamate blocked LPL and chylomicron binding to GPIHBP1. Also, a rabbit antiserum against the acidic domain of GPIHBP1 blocked LPL and chylomicron binding to GPIHBP1-expressing cells. Replacing the acidic amino acids within GPIHBP1 residues 38-48 with alanine eliminated the ability of GPIHBP1 to bind LPL and chylomicrons. Finally, mutation of the positively charged heparin-binding domains within LPL and apolipoprotein AV abolished the ability of these proteins to bind to GPIHBP1. These studies indicate that the acidic domain of GPIHBP1 is important and that electrostatic interactions play a key role in ligand binding.     

Angiopoietin-like 4 Modifies the Interactions between Lipoprotein Lipase and Its Endothelial Cell Transporter GPIHBP1

The release of fatty acids from plasma triglycerides for tissue uptake is critically dependent on the enzyme lipoprotein lipase (LPL). Hydrolysis of plasma triglycerides by LPL can be disrupted by the protein angiopoietin-like 4 (ANGPTL4), and ANGPTL4 has been shown to inactivate LPL in vitro. However, in vivo LPL is often complexed to glycosylphosphatidylinositol-anchored high density lipoprotein-binding protein 1 (GPIHBP1) on the surface of capillary endothelial cells. GPIHBP1 is responsible for trafficking LPL across capillary endothelial cells and anchors LPL to the capillary wall during lipolysis. How ANGPTL4 interacts with LPL in this context is not known. In this study, we investigated the interactions of ANGPTL4 with LPL-GPIHBP1 complexes on the surface of endothelial cells. We show that ANGPTL4 was capable of binding and inactivating LPL complexed to GPIHBP1 on the surface of endothelial cells. Once inactivated, LPL dissociated from GPIHBP1. We also show that ANGPTL4-inactivated LPL was incapable of binding GPIHBP1. ANGPTL4 was capable of binding, but not inactivating, LPL at 4 °C, suggesting that binding alone was not sufficient for ANGPTL4''s inhibitory activity. We observed that although the N-terminal coiled-coil domain of ANGPTL4 by itself and full-length ANGPTL4 both bound with similar affinities to LPL, the N-terminal fragment was more potent in inactivating both free and GPIHBP1-bound LPL. These results led us to conclude that ANGPTL4 can both bind and inactivate LPL complexed to GPIHBP1 and that inactivation of LPL by ANGPTL4 greatly reduces the affinity of LPL for GPIHBP1.     

Multimerization of Glycosylphosphatidylinositol-anchored High Density Lipoprotein-binding Protein 1 (GPIHBP1) and Familial Chylomicronemia from a Serine-to-Cysteine Substitution in GPIHBP1 Ly6 Domain

GPIHBP1, a glycosylphosphatidylinositol-anchored glycoprotein of microvascular endothelial cells, binds lipoprotein lipase (LPL) within the interstitial spaces and transports it across endothelial cells to the capillary lumen. The ability of GPIHBP1 to bind LPL depends on the Ly6 domain, a three-fingered structure containing 10 cysteines and a conserved pattern of disulfide bond formation. Here, we report a patient with severe hypertriglyceridemia who was homozygous for a GPIHBP1 point mutation that converted a serine in the GPIHBP1 Ly6 domain (Ser-107) to a cysteine. Two hypertriglyceridemic siblings were homozygous for the same mutation. All three homozygotes had very low levels of LPL in the preheparin plasma. We suspected that the extra cysteine in GPIHBP1-S107C might prevent the trafficking of the protein to the cell surface, but this was not the case. However, nearly all of the GPIHBP1-S107C on the cell surface was in the form of disulfide-linked dimers and multimers, whereas wild-type GPIHBP1 was predominantly monomeric. An insect cell GPIHBP1 expression system confirmed the propensity of GPIHBP1-S107C to form disulfide-linked dimers and to form multimers. Functional studies showed that only GPIHBP1 monomers bind LPL. In keeping with that finding, there was no binding of LPL to GPIHBP1-S107C in either cell-based or cell-free binding assays. We conclude that an extra cysteine in the GPIHBP1 Ly6 motif results in multimerization of GPIHBP1, defective LPL binding, and severe hypertriglyceridemia.     

Assessing mechanisms of GPIHBP1 and lipoprotein lipase movement across endothelial cells

Lipoprotein lipase (LPL) is secreted into the interstitial spaces by adipocytes and myocytes but then must be transported to the capillary lumen by GPIHBP1, a glycosylphosphatidylinositol-anchored protein of capillary endothelial cells. The mechanism by which GPIHBP1 and LPL move across endothelial cells remains unclear. We asked whether the transport of GPIHBP1 and LPL across endothelial cells was uni- or bidirectional. We also asked whether GPIHBP1 and LPL are transported across cells in vesicles and whether this transport process requires caveolin-1. The movement of GPIHBP1 and LPL across cultured endothelial cells was bidirectional. Also, GPIHBP1 moved bidirectionally across capillary endothelial cells in live mice. The transport of LPL across endothelial cells was inhibited by dynasore and genistein, consistent with a vesicular transport process. Also, transmission electron microscopy (EM) and dual-axis EM tomography revealed GPIHBP1 and LPL in invaginations of the plasma membrane and in vesicles. The movement of GPIHBP1 across capillary endothelial cells was efficient in the absence of caveolin-1, and there was no defect in the internalization of LPL by caveolin-1-deficient endothelial cells in culture. Our studies show that GPIHBP1 and LPL move bidirectionally across endothelial cells in vesicles and that transport is efficient even when caveolin-1 is absent.     

Equivalent binding of wild-type lipoprotein lipase (LPL) and S447X-LPL to GPIHBP1, the endothelial cell LPL transporter

The S447X polymorphism in lipoprotein lipase (LPL), which shortens LPL by two amino acids, is associated with low plasma triglyceride levels and reduced risk for coronary heart disease. S447X carriers have higher LPL levels in the pre- and post-heparin plasma, raising the possibility that the S447X polymorphism leads to higher LPL levels within capillaries. One potential explanation for increased amounts of LPL in capillaries would be more avid binding of S447X-LPL to GPIHBP1 (the protein that binds LPL dimers and shuttles them to the capillary lumen). This explanation seems plausible because sequences within the carboxyl terminus of LPL are known to mediate LPL binding to GPIHBP1. To assess the impact of the S447X polymorphism on LPL binding to GPIHBP1, we compared the ability of internally tagged versions of wild-type LPL (WT-LPL) and S447X-LPL to bind to GPIHBP1 in both cell-based and cell-free binding assays. In the cell-based assay, we compared the binding of WT-LPL and S447X-LPL to GPIHBP1 on the surface of cultured cells. This assay revealed no differences in the binding of WT-LPL and S447X-LPL to GPIHBP1. In the cell-free assay, we compared the binding of internally tagged WT-LPL and S447X-LPL to soluble GPIHBP1 immobilized on agarose beads. Again, no differences in the binding of WT-LPL and S447X-LPL to GPIHBP1 were observed. We conclude that increased binding of S447X-LPL to GPIHBP1 is unlikely to be the explanation for more efficient lipolysis and lower plasma triglyceride levels in S447X carriers.     

Glycosylation of Asn-76 in mouse GPIHBP1 is critical for its appearance on the cell surface and the binding of chylomicrons and lipoprotein lipase

GPIHBP1 is a glycosylphosphatidylinositol-anchored protein in the lymphocyte antigen 6 (Ly-6) family that recently was identified as a platform for the lipolytic processing of triglyceride-rich lipoproteins. GPIHBP1 binds both LPL and chylomicrons and is expressed on the luminal face of microvascular endothelial cells. Here, we show that mouse GPIHBP1 is N-glycosylated at Asn-76 within the Ly-6 domain. Human GPIHBP1 is also glycosylated. The N-linked glycan could be released from mouse GPIHBP1 with N-glycosidase F, endoglycosidase H, or endoglycosidase F1. The glycan was marginally sensitive to endoglycosidase F2 digestion but resistant to endoglycosidase F3 digestion, suggesting that the glycan on GPIHBP1 is of the oligomannose type. Mutating the N-glycosylation site in mouse GPIHBP1 results in an accumulation of GPIHBP1 in the endoplasmic reticulum and a markedly reduced amount of the protein on the cell surface. Consistent with this finding, cells expressing a nonglycosylated GPIHBP1 lack the ability to bind LPL or chylomicrons. Eliminating the N-glycosylation site in a truncated soluble version of GPIHBP1 causes a modest reduction in the secretion of the protein. These studies demonstrate that N-glycosylation of GPIHBP1 is important for the trafficking of GPIHBP1 to the cell surface.     

Modulation of plasma TG lipolysis by Angiopoietin-like proteins and GPIHBP1

There is evidence that elevated plasma triglycerides (TG) serve as an independent risk factor for coronary heart disease. Plasma TG levels are determined by the balance between the rate of production of chylomicrons and VLDL in intestine and liver, respectively, and their rate of clearance in peripheral tissues. Lipolytic processing of TG-rich lipoproteins is mediated by the enzyme lipoprotein lipase (LPL), which is tethered to the capillary endothelium via heparin sulphate proteoglycans. In recent years the Angiopoietin-like proteins ANGPTL3 and ANGPTL4 have emerged as novel modulators of LPL activity. Studies in transgenic animals supported by in vitro experiments have demonstrated that ANGPTL3 and ANGPTL4 impair plasma TG clearance by inhibiting LPL activity. In humans, genetic variation within the ANGPTL3 and ANGPTL4 genes contributes to variation in plasma TG and HDL levels, thereby validating the importance of ANGPTLs in the regulation of lipoprotein metabolism in humans. Combined with the discovery of GPIHBP1 as a likely LPL anchor, these findings have led to a readjustment of the mechanism of LPL function. This review provides an overview of our current understanding of the role and regulation of ANGPTL3, ANGPTL4 and GPIHBP1, and places the newly acquired knowledge in the context of the established function and mechanism of LPL-mediated lipolysis.