Regulation of lipid metabolism

Lipids including cholesterol, phospholipids, fatty acids and triacylglycerols are important cellular constituents involved in membrane structure, energy homeostasis and many biological processes such as signal transduction, organelle development and cell differentiation.Recently, the area of lipid metabolism has drawn a great deal of attention due to its emerging role in the development of metabolic disorders such as obesity, diabetes, atherosclerosis and liver steatosis.We decided to organize a special issue of Frontiers in Biology focusing on our current understanding of lipid metabolism.     

LXRs在脂质代谢中的作用

LXRs ,为liverX activatedreceptors的简称 ,是核受体超家族的成员 ,包括两种同源亚型LXRα(NR1H3)和LXRβ(NR1H2 )。LXRs被内源性配体氧化甾醇或人工合成配体激活后 ,先与RXRα(retinoidXreceptorα ,亦称NR2B1)形成异二聚体 ,再与其靶基因的LXR调控元件结合 ,通过转录调节调控胆固醇的代谢、储存、吸收和转运 ,从而维持甾醇和脂肪酸代谢平衡。此外 ,LXRs也参与糖代谢调节 ,活化的LXRs可通过抑制肝脏糖异生而改变II型糖尿病动物的血糖水平。因此 ,LXRs有望成为治疗动脉粥样硬化和II型糖尿病的新靶点     

miR-122 regulation of lipid metabolism revealed by in vivo antisense targeting

Current understanding of microRNA (miRNA) biology is limited, and antisense oligonucleotide (ASO) inhibition of miRNAs is a powerful technique for their functionalization. To uncover the role of the liver-specific miR-122 in the adult liver, we inhibited it in mice with a 2'-O-methoxyethyl phosphorothioate ASO. miR-122 inhibition in normal mice resulted in reduced plasma cholesterol levels, increased hepatic fatty-acid oxidation, and a decrease in hepatic fatty-acid and cholesterol synthesis rates. Activation of the central metabolic sensor AMPK was also increased. miR-122 inhibition in a diet-induced obesity mouse model resulted in decreased plasma cholesterol levels and a significant improvement in liver steatosis, accompanied by reductions in several lipogenic genes. These results implicate miR-122 as a key regulator of cholesterol and fatty-acid metabolism in the adult liver and suggest that miR-122 may be an attractive therapeutic target for metabolic disease.     

Apelin对改善小鼠低氧性肺动脉高压的作用及与调节脂质代谢的关系

目的：探讨外源性apelin对小鼠慢性低氧性肺动脉高压的作用及其机制。方法：SPF级雄性apoE基因敲除（apoE-KO）小鼠30只,随机均分为3组（n=10）,即常氧组、低氧组和低氧+apelin组,apelin组小鼠每天于低氧前经腹腔注射apelin-13（10 nmol/（kg·d））,其他组腹腔注射相同体积的生理盐水。采用常压连续低氧方法（9%~11% O₂,23 h/d）复制慢性低氧性肺动脉高压模型。低氧3周后,采用右心导管法测定小鼠右心室压（RVSP）和右心室与左心室加室间隔重量比,Elisa法检测血浆中高密度脂蛋白（HDL）、低密度脂蛋白（LDL）和总胆固醇（TC）的含量;real-time PCR法检测肝组织中三磷酸腺苷结合盒转运体A1（ABCA1）、清道夫受体B1（SR-B1）、低密度脂蛋白受体（LDLR）和3-羟基-3-甲基戊二酸单酰辅酶A还原酶（HMGCR）等基因的表达。Western blot法检测小鼠肺组织中过氧化物酶体增殖物激活受体γ（PPARγ）蛋白的表达。结果：①低氧组小鼠RVSP、RV/（LV+S）较常氧组分别高87%、85%（P均<0.05）,apelin组小鼠RVSP、RV/（LV+S）较低氧组分别低39%、33%（P均<0.05）。②apelin组小鼠血浆中HDL-C含量、HDL/LDL比值分别较hypoxia组高21%、20%（P均<0.05）,而血浆中TC、LDL-C含量两组间无显著差异（P均>0.05）。③apelin组小鼠肝组织中LDLR、SR-B1、ABCA1基因表达分别较低氧组上调241%、112%、69%（P均<0.05）,而HMGCR基因表达下调45%（P<0.05）。④apelin组小鼠肺组织中PPARγ蛋白表达较低氧组上调47%。结论：Apelin可降低小鼠低氧性肺动脉高压,其机制与调节脂质代谢有关。     

Regulation of lipid metabolism by palmitoleate and eicosapentaenoic acid (EPA) in mice fed a high-fat diet

We investigated whether oral administration of palmitoleate ameliorates disorders of lipid metabolism to clarify the effects of one of the components of fish oil. Lipid levels in the liver and plasma were significantly decreased by palmitoleate and by EPA administration. These results suggest that palmitoleate, in addition to EPA, plays a role in the regulation of lipid metabolism by fish oil.     

Regulation of cardiac inwardly rectifying potassium channels by membrane lipid metabolism

Types and distributions of inwardly rectifying potassium (Kir) channels are one of the major determinants of the electrophysiological properties of cardiac myocytes. Kir2.1 (classical inward rectifier K(+) channel), Kir6.2/SUR2A (ATP-sensitive K(+) channel) and Kir3.1/3.4 (muscarinic K(+) channels) in cardiac myocytes are commonly upregulated by a membrane lipid, phosphatidylinositol 4,5-bisphosphates (PIP(2)). PIP(2) interaction sites appear to be conserved by positively charged amino acid residues and the putative alpha-helix in the C-terminals of Kir channels. PIP(2) level in the plasma membrane is regulated by the agonist stimulation. Kir channels in the cardiac myocytes seem to be actively regulated by means of the change in PIP(2) level rather than by downstream signal transduction pathways.     

Regulation of inflammatory and lipid metabolism genes by eicosapentaenoic acid-rich oil

Omega-3-PUFAs, eicosapentaenoic acid (EPA), and docosahexaenoic acid (DHA), are associated with prevention of various aspects of metabolic syndrome. In the present studies, the effects of oil rich in EPA on gene expression and activation of nuclear receptors was examined and compared with other ω3-PUFAs. The EPA-rich oil (EO) altered the expression of FA metabolism genes in THP-1 cells, including stearoyl CoA desaturase (SCD) and FA desaturase-1 and -2 (FASDS1 and -2). Other ω3-PUFAs resulted in a similar gene expression response for a subset of genes involved in lipid metabolism and inflammation. In reporter assays, EO activated human peroxisome proliferator-activated receptor α (PPARα) and PPARβ/γ with minimal effects on PPARγ, liver X receptor, retinoid X receptor, farnesoid X receptor, and retinoid acid receptor γ (RARγ); these effects were similar to that observed for purified EPA. When serum from a 6 week clinical intervention with dietary supplements containing olive oil (control), DHA, or two levels of EPA were applied to THP-1 cells, the expression of SCD and FADS2 decreased in the cells treated with serum from the ω3-PUFA-supplemented individuals. Taken together, these studies indicate regulation of gene expression by EO that is consistent with treating aspects of dyslipidemia and inflammation.     

Insulin-dependent interactions of proteins with GLUT4 revealed through stable isotope labeling by amino acids in cell culture (SILAC)

The insulin-regulated glucose transporter (GLUT4) translocates to the plasma membrane in response to insulin in order to facilitate the postprandial uptake of glucose into fat and muscle cells. While early insulin receptor signaling steps leading to this translocation are well defined, the integration of signaling and regulation of GLUT4 traffic remains elusive. Several lines of evidence suggest an important role for the actin cytoskeleton and for protein-protein interactions in regulating GLUT4 localization by insulin. Here, we applied stable isotope labeling by amino acids in cell culture (SILAC) to identify proteins that interact with GLUT4 in an insulin-regulated manner. Myc-tagged GLUT4 (GLUT4myc) stably expressed in L6 myotubes was immunoprecipitated via the myc epitope from total membranes isolated from basal and insulin-stimulated cells grown in medium containing normal isotopic abundance leucine or deuterated leucine, respectively. Proteins coprecipitating with GLUT4myc were analyzed by liquid chromatography/ tandem mass spectrometry. Of 603 proteins quantified, 36 displayed an insulin-dependent change of their interaction with GLUT4myc of more than 1.5-fold in either direction. Several cytoskeleton-related proteins were elevated in immunoprecipates from insulin-treated cells, whereas components of the ubiquitin-proteasome degradation system were generally reduced. Proteins participating in vesicle traffic also displayed insulin-regulated association. Of cytoskeleton-related proteins, alpha-actinin-4 recovery in GLUT4 immunoprecipitates rose in response to insulin 2.1 +/- 0.5-fold by SILAC and 2.9 +/- 0.8-fold by immunoblotting. Insulin caused GLUT4 and alpha-actinin-4 co-localization as revealed by confocal immunofluorescence microscopy. We conclude that insulin elicits changes in interactions between diverse proteins and GLUT4, and that cytoskeletal proteins, notably alpha-actinin-4, associate with the transporter, potentially to facilitate its routing to the plasma membrane.     

The interactome of a PTB domain-containing adapter protein, Odin, revealed by SILAC

Signal transduction pathways are tightly controlled by positive and negative regulators. We have previously identified Odin (also known as ankyrin repeat and sterile alpha motif domain-containing 1A; gene symbol ANKS1A) as a negative regulator of growth factor signaling; however, the mechanisms through which Odin regulates these pathways remain to be elucidated. To determine how Odin negatively regulates growth factor signaling, we undertook a proteomic approach to systematically identify proteins that interact with Odin using the SILAC strategy. In this study, we identified 18 molecules that were specifically associated in a protein complex with Odin. Our study established that the complete family of 14-3-3 proteins occur in a protein complex with Odin, which is also supported by earlier reports that identified a few members of the 14-3-3 family as Odin interactors. Among the novel protein interactors of Odin were CD2-associated protein, SH3 domain kinase binding protein 1 and DAB2 interacting protein. We confirmed 8 of the eighteen interactions identified in the Odin protein complex by co-immunoprecipitation experiments. Finally, a literature-based network analysis revealed that Odin interacting partners are involved in various cellular processes, some of which are key molecules in regulating receptor endocytosis.     

Regulation of lipid metabolism by dipyridamole and adenosine antagonists in rat adipocytes

1. Acute effects of dipyridamole, an inhibitor of adenosine transport, direct activators of adenylate cyclase and thirteen adenosine antagonist analogs on fatty acid synthesis have been examined in terms of the control of [1-14C]acetate incorporation into labeled fatty acids in the presence of glucose. 2. This monosaccharide acts as a stimulator of lipogenesis by generating NADPH for the lipid synthesis. 3. The relationship between lipogenesis and lipolysis was compared with a variety of adenylate cyclase stimulators. 4. The data obtained reveals that dipyridamole potentiated the inhibitory or stimulatory effects of isoproterenol and forskolin on lipogenesis and on lipolysis, respectively. 5. In these cases the data show that it exists an inverse relationship between lipogenesis and lipolysis. 6. Dipyridamole and methylxanthine analogs only moderately affect the rate of lipolysis whereas its effects are more potent on lipogenesis and lend further support to the hypothesis that dipyridamole antagonize adenosine actions as well as methyl xanthines. 7. These results suggest that dipyridamole and adenosine antagonists alter lipogenesis independently of the lipolytic process and that it exists an inverse relationship between lipogenesis and lipolysis under some conditions whereas there are not under others.     

Regulation of peroxisomal lipid metabolism by catalytic activity of tumor suppressor H-rev107

H-rev107 is a mammalian protein belonging to the HRAS-like suppressor family. Although the protein was originally found as a tumor suppressor, currently it is receiving considerable attention as a regulator of adipocyte lipolysis. We recently revealed that purified recombinant H-rev107 has phospholipase A(1/2) activity, releasing free fatty acids from glycerophospholipids with a preference for esterolysis at the sn-1 position. In the present study, we constitutively expressed H-rev107 in cloned HEK293 cells to examine its biological function in living cells. Initially, the cells accumulated free fatty acids. We also found a remarkable decrease in the levels of ether-type lipids, including plasmalogen and ether-type triglyceride, with a concomitant increase in fatty alcohols, substrates for the biosynthesis of ether-type lipids. Considering that peroxisomes are involved in the ether-type lipid biosynthesis, we next focused on peroxisomes and found that the peroxisomal markers 70-kDa peroxisomal membrane protein and catalase were abnormally distributed in the transfected cells. These biochemical and morphological abnormalities were not seen in HEK293 cells stably expressing a catalytically inactive mutant of H-rev107. When H-rev107 or its fusion protein with enhanced green fluorescence protein was transiently expressed in mammalian cells, both proteins were associated with peroxisomes in some of the observed cells. These results suggest that H-rev107 interferes with the biosynthesis of ether-type lipids and is responsible for the dysfunction of peroxisomes in H-rev107-expressing cells.