雷帕霉素对小鼠原代肝细胞脂滴形态和脂滴表面蛋白表达的影响

目的:探讨雷帕霉素(Rapamycin)对小鼠原代肝细胞脂滴形态和脂滴表面蛋白表达的影响。方法:采用胶原酶灌注方法分离和培养小鼠原代肝细胞,采用100μM油酸诱导肝细胞内脂肪的合成。采用0、10、20、50μM的雷帕霉素处理肝细胞12 hr后,利用中性脂肪染料Bodipy493/503对肝细胞内的脂滴进行染色,荧光显微镜下观察细胞脂滴形态和数量。定量试剂盒检测细胞内甘油三酯(TG)的含量利用Western blot检测不同浓度雷帕霉素处理的小鼠原代肝细胞脂滴表面蛋白ADRP的表达水平。结果:成功分离和培养了小鼠原代肝细胞,使用油酸处理能够明显增加原代肝细胞内脂滴的数量。随着体外雷帕霉素处理浓度的增加,荧光显微镜下观察发现原代肝细胞内脂滴的数量呈现明显的下降趋势,甘油三酯的含量也呈见明确的下降趋势,在20μM浓度下就表现出显著性差异。Western blot结果显示雷帕霉素能够在抑制肝细胞内脂肪储积的同时降低脂滴表面蛋白ADRP的表达水平,并且随着雷帕霉素处理浓度的增加,其对ADRP表达的抑制越明显。结论:雷帕霉素能够抑制肝细胞内中性脂肪的储积,同时降低脂滴表面蛋白ADRP的表达水平。也间接说明了mTOR信号通路能够影响肝细胞内脂肪的储积,也为脂肪肝的防治提供了一个新的实验基础。     

Nrf2/ARE通路相关因子在脂肪变性HepG2细胞中的表达及其意义

目的:探讨建立一种新型的脂肪变性人肝癌细胞(Hep G2)模型,观察核因子E2相关因子2(Nrf2)/抗氧化反应元件(ARE)通路相关因子在脂肪变性Hep G2细胞中的表达及其意义。方法:Hep G2细胞给予含25%的胎牛血清、0.1%医用脂肪乳和0.1 mmol/L游离脂肪酸(FFA)的DMEM培养基分阶段诱导后,建立脂肪变性Hep G2细胞模型,并设置对照组。模型成功后,以油红O染色观察细胞内脂滴形成状况,并用全自动生化仪检测细胞内甘油三酯(TG)含量;采用流式细胞仪测定细胞内活性氧(ROS)的含量,采用生物试剂盒检测细胞内一氧化氮(NO)、超氧化物歧化酶(SOD)、丙二醛(MDA)、谷胱甘肽过氧化物酶(GSH-Px)含量及活性的变化;运用Western blot法检测各组细胞Nrf2、血红素氧化酶-1(HO-1)和醌氧化还原酶1(NQO1)蛋白的表达。结果:与对照组比较,模型组油红O染色可见细胞内橘红色脂滴大量形成,TG、ROS、NO、MDA含量水平明显增高(P0.05,P0.01),SOD、GSHPx活性明显下降(P0.01),Nrf2、HO-1和NQO1蛋白表达均显著增高(P0.05,P0.01)。结论:本模型可以成功诱导Hep G2细胞发生脂肪变性和氧化应激损伤状态;Nrf2/ARE通路下游相关因子发生激活可能与脂肪变性Hep G2细胞氧化应激的过度反应有关。     

不同来源肝细胞在体外降脂药物评价中药效反应的对比

目的:通过对比不同来源的人肝癌细胞系HepG2和原代大鼠肝细胞在体外降脂药物评价中药效反应,指导两种肝细胞在体外降脂药物评价中的实际应用。方法:用游离脂肪酸(油酸/棕榈酸,2:1)诱导HepG2细胞、原代大鼠肝细胞脂肪变性,并用100μmol·L-1苯扎贝特干预,检测细胞内甘油三酯(TG)、总胆固醇(TC)、活性氧(ROS)含量,细胞内脂滴数目、并检测细胞上清液中丙二醛(MDA)含量和超氧化物歧化酶(SOD)活性。结果:FFA刺激使HepG2细胞和原代大鼠肝细胞脂质沉积(TG、脂滴)和氧化应激(ROS、MDA、SOD)水平上升。苯扎贝特对HepG2细胞1 mmol·L-1FFA造模组和原代大鼠肝细胞0.5 mmol·L-1FFA造模组脂质沉积和氧化应激水平改善显著;而HepG2细胞0.5 mmol·L-1FFA造模组和原代大鼠肝细胞1 mmol·L-1FFA造模组脂质沉积和氧化应激水平在苯扎贝特干预后变化不明显。结论:在相同FFA造模浓度,原代大鼠肝细胞病理特征变化更为明显;苯扎贝特对两种肝细胞在脂质沉积和氧化应激水平的作用也不完全相同。因而HepG2细胞和原代大鼠肝细胞在体外降脂药物评价中药效反应是不完全相同的。     

胰岛素对小鼠原代肝细胞甘油三酯合成分解代谢的影响

目的：建立小鼠肝细胞体外培养的方法,研究不同浓度胰岛素对肝细胞甘油三酯合成代谢、分解代谢及甘油三酯含量的影响。方法：通过肝脏灌注和胶原酶消化分离小鼠肝细胞,密度梯度离心纯化后,进行体外培养。在0 nmol/L,50 nmol/L,100 nmol/L,200 nmol/L胰岛素存在的情况下培养,通过3H标记的甘油测定细胞内甘油三酯合成速率,使用3H标记的油酸预孵育,加入triacsin C抑制脂肪酸重酯化,追踪掺入3H的甘油三酯分解的速率。采用甘油三酯检测试剂盒,测定不同浓度胰岛素对细胞内甘油三酯含量的影响。结果：成功分离了小鼠原代肝细胞,存活率达90%。50 nmol/L胰岛素对细胞甘油三酯含量及甘油三酯合成分解速率影响较小。100 nmol/L胰岛素可显著增加甘油三酯合成速率,减低分解速率,使细胞内甘油三酯含量增加。200 nmo/L胰岛素反而降低甘油三酯合成速率,细胞内甘油三酯含量少于对照组（0 nmol/L）。结论：本研究成功建立了小鼠原代肝细胞分离培养的方法,使用3H标记物敏感的检测肝细胞内甘油三酯合成分解速率。研究发现,过高浓度的胰岛素反而抑制肝细胞甘油三酯的储积。     

下调Fsp27基因表达联合杨梅素干预对3T3-L1细胞脂解的影响

目的:下调脂肪特异性蛋白27(Fsp27)基因表达联合杨梅素干预,观察对3T3-L1细胞中脂质代谢的影响,并探究脂滴发生、发展变化的调控机制。方法:常规培养3T3-L1前脂肪细胞,采用"鸡尾酒"法诱导其分化为成熟脂肪细胞。脂质体法转染sh-Fsp27干扰载体,以杨梅素浓度为100μmol/L的完全培养基干预成熟脂肪细胞72h。油红O染色,观察脂滴形态及大小的变化;酶法测定细胞内甘油及甘油三酯的含量,观察细胞脂质代谢的变化。Western blot检测Fsp27、激素敏感性甘油三酯脂肪酶(HSL)、甘油三酯脂肪酶(ATGL)以及丝裂原活化蛋白激酶(MAPK)信号通路蛋白的表达。结果:1. 3T3-L1细胞诱导分化后,形态由纤维样变成圆形,并伴随有细胞体积的增大。2.与对照组相比,杨梅素组和转染组细胞中甘油三酯含量下降,甘油含量升高(P 0. 05)。与其他三组相比,联合干预组细胞中甘油三酯含量减少,甘油含量增加(P 0. 05)。3.与对照组相比,其余三组细胞内Fsp27蛋白的表达量均降低,ATGL和PPARγ的表达量升高(P 0. 05)。另外,联合干预组和杨梅素组细胞内HSL的表达量和p-p38MAPK/p38MAPK的比值均大于sh-Fsp27组和对照组(P 0. 05)。结论:1. Fsp27基因沉默与杨梅素联合干预可以更大程度地促进脂肪分解代谢。2.杨梅素可通过激活MAPK信号通路,上调HSL和ATGL的蛋白表达来发挥其促脂解的作用; sh-Fsp27干扰载体通过调节PPARγ和Fsp27蛋白的表达,增加ATGL含量来加速脂肪分解。     

血管活性肠肽对肺表面活性物质结合蛋白A表达的影响

目的:研究血管活性肠肽(VIP)对肺表面活性物质结合蛋白A(SP-A)表达的影响以及VIP调控SP-A表达的细胞内信号转导途径.方法:运用免疫组织化学和RT-PCR技术研究VIP对SP-A表达的影响;并进一步运用受体拮抗、蛋白激酶抑制、反义寡核苷酸阻断等手段探讨VIP促进SP-A表达的信号转导途径.结果:①VIP(10-8mol/L)促进肺泡Ⅱ型细胞(ATⅡ)细胞中的SP-A蛋白表达和提高肺组织SP-AmRNA含量:②VIP受体拮抗剂(10-6mol/L)可取消VIP(10-8mol/L)促进SP-A表达的效应;③蛋白激酶C抑制剂H7(10-5mol/L)和c-fos基因的反义寡核苷酸(9×10 6mol/L)均可阻断VIP促进SP-A表达的作用.结论:VIP通过其受体促进SP-A的表达,PKC及c-fos蛋白在介导VIP促进SP-A表达的细胞内信号转导过程中起重要作用.     

肿瘤坏死因子-α诱导心肌肥大中CaN信号通路的作用

目的:研究钙调神经磷酸酶(CaN)信号通路在肿瘤坏死因子-α(TNF-α)诱导心肌细胞肥大中的作用。方法:Lowry法测心肌细胞蛋白含量;计算机图象分析系统测心肌细胞体积;[3H]-亮氨酸掺入法测心肌细胞蛋白合成;Till阳离子测定系统观察胞内[Ca2+]i瞬变;Western blot法测定CaN的表达。结果:①CaN特异性抑制剂CsA(0.2μmol/L)明显抑制TNF-α(100μg/L)诱导的心肌细胞蛋白含量、蛋白合成和细胞体积增大,但对正常心肌细胞生长无影响。②CaN特异性抑制剂CsA(0.2μmol/L)明显降低TNF-α诱导的心肌细胞内钙离子浓度([Ca2+]i)瞬变幅度增高。③TNF-α明显增强心肌细胞内CaN的表达。结论:TNF-α可能通过引起心肌细胞[Ca2+]i升高,促进CaN表达诱导心肌细胞肥大。     

小鼠肝纤维化中内质网应激分子的表达与作用

[目的]利用高脂饲料和异种血清诱导建立肝纤维化模型,检测内质网应激分子在该纤维化模型中的作用及机制。[方法]收集各组小鼠血清进行ALT检测,对小鼠肝组织进行HE和Masson染色观察肝组织的结构变化以及胶原纤维状况,并分别用Western和RT-PCR检测组织内CRT、GRP78、TLR2等基因的表达。[结果]与正常对照组(48.8±6.1 U/L)相比高脂饲料饮食组(139.7±13.4 U/L)、腹腔注射异种血清组(72.8±7.2U/L)以及高脂饲料联合腹腔异种血清注射组(193.0±14.1 U/L)血清ALT显著升高(p0.05);镜下也观察到肝细胞脂肪变性,大量的胶原纤维产生;肝组织内GRP78和TLR2基因mRNA水平、CRT蛋白水平均升高(p0.05)。[结论]高脂饲料和异种血清诱导建立的肝纤维化模型显示内质网应激与肝纤维化的发生发展密切相关。     

氧化损伤与内质网应激在四氯化碳致大鼠肝脂肪变性中的作用机制

肝脂肪变性是长期饮酒、肥胖、药物中毒等致脂肪肝形成过程中重要的中间阶段,严 重的脂肪堆积会导致肝细胞坏死或肝硬化,但是有关肝脂肪变性的分子机理目前仍不十分清 楚.本实验利用四氯化碳建立大鼠肝脂肪变性模型,四氯化碳处理组较对照组肝脏丙二醛含 量增加68%,内质网应激标志蛋白GRP78 mRNA水平和蛋白质水平表达均明显增加;人肝癌细胞株HepG2体外培养中,加入四氯化碳处理后内质网发生应激,并导致SREBP-1表达增加且活化.结果表明,四氯化碳导致的肝脂肪变性与肝细胞的氧化损伤和内质网应激有关,其分子机理可能为内质网应激发生后促进SREBP-1转录因子的表达与活化,SREBP-1在细胞核内参与生脂相关酶如HMG CoA 还原酶等基因的诱导表达,生脂相关酶含量的增加进一步使肝细胞甘油三酯、胆固醇合成增加,脂质的异常堆积导致了肝脂肪变性的发生.     

干扰miR-135a减轻非酒精性脂肪肝的细胞变性和肝功能损害

目的评估干扰miR-135a是否对非酒精性脂肪肝(nonalcoholic fatty liver disease, NAFLD)具有治疗作用。方法采集NAFLD患者以及健康志愿者的血清样本,用qRT-PCR检测miR-135a表达水平;用25、100和400μmol/L棕榈酸(palmitic acid, PA)处理人源原代肝细胞48h,RT-qPCR检测细胞中miR-135a表达水平;将miR-135a inhibitor转入人源原代肝细胞后再给予400μmol/L PA处理48h,尼罗红染色法检测细胞中脂质蓄积情况。通过高脂饮食(high fatty diet, HFD)诱导法制作NAFLD小鼠模型,并在HFD喂养的第7周通过尾静脉注射LV-anti-miR-135a;在第10周末,处死小鼠并收集肝组织和血液样本;肝组织病理学染色用于分析脂质含量及脂肪变性程度,血液生化检测用于分析肝功能和脂质代谢。结果在NAFLD患者血清、PA处理的肝细胞、HFD喂养的小鼠血清和肝组织中miR-135a的表达明显升高;干扰miR-135a能抑制PA诱导的肝细胞中脂质累积;肝组织病理学检测显示,干扰miR-135a能减轻HFD诱导的肝组织脂肪变性;血液生化检测结果显示,干扰miR-135a能降低HFD喂养的小鼠血清中甘油三酯、胆固醇、谷草转氨酶(glutamic-oxaloacetic transaminase,AST)、谷丙转氨酶(alanine transaminase, ALT)、碱性磷酸酶(alkaline phosphatase, ALP)以及总胆红素(total bilirubin,TBIL)的水平。结论干扰miR-135a能够减轻NAFLD引起的肝脂肪变性,并恢复肝功能和改善脂质代谢,因此,抑制体内miR-135a表达水平可能是潜在的NAFLD治疗的新途径之一。     

Effects of dietary retinoid and triglyceride on the lipid composition of rat liver stellate cells and stellate cell lipid droplets

Hepatic stellate cells store the majority of the liver's retinoid (vitamin A) reserves as retinyl esters in stellate cell lipid droplets. A study was conducted to explore the effects of differences in dietary retinoid and triglyceride intake on the composition of the stellate cell lipid droplets. Weanling rats were placed on one of five diets that differed in retinoid or triglyceride contents. The dietary groups were: 1) control (2.4 mg retinol (as retinyl acetate)/kg diet and 20.5% of the calories supplied by triglyceride (as peanut oil]; 2) low retinol (0.6 mg retinol/kg diet and control triglyceride levels); 3) high retinol (24 mg retinol/kg diet and control triglyceride levels); 4) low triglyceride (2.4 mg retinol/kg diet and 5% of the calories supplied by triglyceride); and 5) high triglyceride (2.4 mg retinol/kg diet and 45% of the calories supplied by triglyceride). Stellate cells were isolated using the pronase-collagenase method and stellate cell lipid droplets were isolated by differential centrifugation. The levels of retinoids and other lipids were measured by high performance liquid chromatography. The stellate cells from control rats contained 113 micrograms total lipid/10(6) cells. Control stellate cell lipid droplets had the following mean percent lipid composition: 39.5% retinyl ester; 31.7% triglyceride; 15.4% cholesteryl ester; 4.7% cholesterol; 6.3% phospholipids; and 2.4% free fatty acids. Both the concentration of stellate cell lipids and the composition of stellate cell lipid droplets were markedly altered by changes in dietary retinoid. The low and high retinol groups contained, respectively, 82 and 566 micrograms total lipid/10(6) cells, with retinyl ester representing, respectively, 13.6% and 65.4% of the lipid present in the stellate cell lipid droplets. Low and high triglyceride groups were similar to controls in both stellate cell lipid content and the composition of the stellate cell lipid droplets. These findings indicate that the composition of stellate cell lipid droplets is strongly regulated by dietary retinoid status but not by dietary triglyceride intake.     

Hepatic stellate cell lipid droplets: A specialized lipid droplet for retinoid storage

The majority of retinoid (vitamin A and its metabolites) present in the body of a healthy vertebrate is contained within lipid droplets present in the cytoplasm of hepatic stellate cells (HSCs). Two types of lipid droplets have been identified through histological analysis of HSCs within the liver: smaller droplets bounded by a unit membrane and larger membrane-free droplets. Dietary retinoid intake but not triglyceride intake markedly influences the number and size of HSC lipid droplets. The lipids present in rat HSC lipid droplets include retinyl ester, triglyceride, cholesteryl ester, cholesterol, phospholipids and free fatty acids. Retinyl ester and triglyceride are present at similar concentrations, and together these two classes of lipid account for approximately three-quarters of the total lipid in HSC lipid droplets. Both adipocyte-differentiation related protein and TIP47 have been identified by immunohistochemical analysis to be present in HSC lipid droplets. Lecithin:retinol acyltransferase (LRAT), an enzyme responsible for all retinyl ester synthesis within the liver, is required for HSC lipid droplet formation, since Lrat-deficient mice completely lack HSC lipid droplets. When HSCs become activated in response to hepatic injury, the lipid droplets and their retinoid contents are rapidly lost. Although loss of HSC lipid droplets is a hallmark of developing liver disease, it is not known whether this contributes to disease development or occurs simply as a consequence of disease progression. Collectively, the available information suggests that HSC lipid droplets are specialized organelles for hepatic retinoid storage and that loss of HSC lipid droplets may contribute to the development of hepatic disease.     

Microsomal triglyceride transfer protein expression in adipocytes: a new component in fat metabolism

Microsomal triglyceride transfer protein (MTP) is a carrier of triglyceride essential for the assembly of apolipoprotein (apo)B-containing lipoproteins by the liver and the small intestine. Its role in triglyceride transfer in tissues that do not secrete lipoproteins has not been explored. In particular, MTP would seem to be a candidate for a role in triglyceride metabolism within the adipocyte. To test this hypothesis, we probed adipocytes for the presence of MTP. Immunohistochemical and biochemical studies demonstrate MTP in adipocytes from brown and white fat depots of mice and human, as well as in 3T3-L1 cells. Confocal microscopy revealed MTP throughout 3T3 cells; however, MTP fluorescence was prominent in juxtanuclear areas. In differentiated 3T3 cells MTP fluorescence was very striking around lipid droplets. In vitro lipid transfer assays demonstrated the presence of triglyceride transfer activity within microsomal fractions isolated from rat adipose tissue. In addition, quantitative rtPCR studies showed that MTP expression in mouse white fat depots was approximately 1% of MTP expression in mouse liver. MTP mRNA in differentiated 3T3 cells was approximately 13% of liver expression. Our results provide unequivocal evidence for the presence of MTP in adipocytes and present new possibilities for defining the mechanisms by which triglyceride is stored and/or hydrolyzed and mobilized.     

DHA缓解肝X受体激活所致HepG2细胞的甘油三酯积聚

目的探讨DHA对肝X受体激动剂T0901317诱导的HepG2细胞甘油三酯积聚的影响。方法体外培养HepG2细胞,以50μmol／LDHA、10μmol／LT0901317分别处理细胞以及50μmloL／LDHA和10μmol／LT0901317共同处理细胞48h。油红0染色观察细胞内脂质沉积;氯仿-甲醇抽提细胞总脂质,酶法定量检测细胞甘油三酯含量;实时定量PCR检测与脂肪酸代谢相关基因如SREBP-1c、FAS、SCD-1、PPARa和CD36的mRNA水平。结果与对照组相比,10μmol／LT0901317处理48h后,HepG2细胞内的油红O染色脂滴增多,甘油二酯浓度升高了50％;脂肪酸合成基因：SREBP-1c、FAS和SCD-1及脂肪酸吸收基因CD36的mRNA水平分别升高了9．9、5．2、2．2和1．5倍,而脂肪酸降解基因PPARoz的mRNA无变化。DHA与T0901317共同处理的HepG2细胞内脂滴明显减少;甘油三酯含量比70901317处理组降低了15％：SREBP—1c、FAS、SCD-1和CD36的mRNA水平比T0901317处理组分别降低了92％、31％、46％和60％,而PPARa的mRNA水平比T0901317处理组升高了30％。结论DHA通过降低脂肪酸合成和吸收基因的表达并升高脂肪酸降解基因的表达缓解肝x受体激活所致HepG2细胞内甘油三酯积聚。     

Microsomal Triglyceride Transfer Protein (MTP) Associates with Cytosolic Lipid Droplets in 3T3-L1 Adipocytes

Lipid droplets are intracellular energy storage organelles composed of a hydrophobic core of neutral lipid, surrounded by a monolayer of phospholipid and a diverse array of proteins. The function of the vast majority of these proteins with regard to the formation and/or turnover of lipid droplets is unknown. Our laboratory was the first to report that microsomal triglyceride transfer protein (MTP), a lipid transfer protein essential for the assembly of triglyceride-rich lipoproteins, was expressed in adipose tissue of humans and mice. In addition, our studies suggested that MTP was associated with lipid droplets in both brown and white fat. Our observations led us to hypothesize that MTP plays a key role in lipid droplet formation and/or turnover. The objective of these studies was to gain insight into the function of MTP in adipocytes. Using molecular, biochemical, and morphologic approaches we have shown: 1) MTP protein levels increase nearly five-fold as 3T3-L1 cells differentiate into adipocytes. 2) As 3T3-L1 cells undergo differentiation, MTP moves from the juxtanuclear region of the cell to the surface of lipid droplets. MTP and perilipin 2, a major lipid droplet surface protein, are found on the same droplets; however, MTP does not co-localize with perilipin 2. 3) Inhibition of MTP activity has no effect on the movement of triglyceride out of the cell either as a lipid complex or via lipolysis. 4) MTP is found associated with lipid droplets within hepatocytes from human fatty livers, suggesting that association of MTP with lipid droplets is not restricted to adipocytes. In summary, our data demonstrate that MTP is a lipid droplet-associated protein. Its location on the surface of the droplet in adipocytes and hepatocytes, coupled with its known function as a lipid transfer protein and its increased expression during adipocyte differentiation suggest a role in lipid droplet biology.     

Distinct populations of hepatic stellate cells in the mouse liver have different capacities for retinoid and lipid storage

Hepatic stellate cell (HSC) lipid droplets are specialized organelles for the storage of retinoid, accounting for 50-60% of all retinoid present in the body. When HSCs activate, retinyl ester levels progressively decrease and the lipid droplets are lost. The objective of this study was to determine if the HSC population in a healthy, uninjured liver demonstrates heterogeneity in its capacity for retinoid and lipid storage in lipid droplets. To this end, we utilized two methods of HSC isolation, which leverage distinct properties of these cells, including their vitamin A content and collagen expression. HSCs were isolated either from wild type (WT) mice in the C57BL/6 genetic background by flotation in a Nycodenz density gradient, followed by fluorescence activated cell sorting (FACS) based on vitamin A autofluorescence, or from collagen-green fluorescent protein (GFP) mice by FACS based on GFP expression from a GFP transgene driven by the collagen I promoter. We show that GFP-HSCs have: (i) increased expression of typical markers of HSC activation; (ii) decreased retinyl ester levels, accompanied by reduced expression of the enzyme needed for hepatic retinyl ester synthesis (LRAT); (iii) decreased triglyceride levels; (iv) increased expression of genes associated with lipid catabolism; and (v) an increase in expression of the retinoid-catabolizing cytochrome, CYP2S1. CONCLUSION: Our observations suggest that the HSC population in a healthy, uninjured liver is heterogeneous. One subset of the total HSC population, which expresses early markers of HSC activation, may be "primed" and ready for rapid response to acute liver injury.     

Hepatocellular triglyceride synthesis and transfer to lipid droplets and nascent very low density lipoproteins

The transfer of triglyceride from sites of synthesis in the endoplasmic reticulum to cytoplasmic lipid droplets and nascent VLDL (very low density lipoproteins) in rat liver in vivo has been examined with [3H]glycerol, cell fractionation, and electron microscopy. Rates of mass transfer of newly synthesized triglyceride were estimated from the specific radioactivity of triglyceride present in microsomal membranes and the radioactivity observed in recipient triglyceride pools. Fasting decreased the transfer of triglyceride to nascent VLDL without affecting transfer to lipid droplets. Stimulation of triglyceride synthesis with 2-tetradecylglycidic acid (TDGA) increased transfer of triglyceride to nascent VLDL 5-fold, and to lipid droplets 14-fold, 1 hr after TDGA administration. Triglyceride transfer to nascent VLDL was increased 6-fold, and to lipid droplets 37-fold, above control rates 6 hr following TDGA treatment, indicative of saturation of triglyceride assembly into nascent VLDL and storage of excess triglyceride in lipid droplet reservoirs. These liver triglyceride pools were concurrently expanded and electron microscopy demonstrated more abundant VLDL particles in the endoplasmic reticulum together with a proliferation of lipid droplets in hepatocytes. TDGA progressively decreased hepatic sn-glycerol-3-phosphate in fasting rats while triglyceride synthesis increased, indicating that sn-glycerol-3-phosphate does not limit the rate of triglyceride synthesis in this metabolic state. Results implicate triglyceride transfer from endoplasmic reticulum membranes to nascent VLDL as a regulated determinant of hepatic VLDL assembly and VLDL triglyceride secretion in vivo.     

Expression of carboxylesterase and lipase genes in rat liver cell-types

Approximately 80% of the body vitamin A is stored in liver stellate cells with in the lipid droplets as retinyl esters. In low vitamin A status or after liver injury, stellate cells are depleted of the stored retinyl esters by their hydrolysis to retinol. However, the identity of retinyl ester hydrolase(s) expressed in stellate cells is unknown. The expression of carboxylesterase and lipase genes in purified liver cell-types was investigated by real-time PCR. We found that six carboxylesterase and hepatic lipase genes were expressed in hepatocytes. Adipose triglyceride lipase was expressed in Kupffer cells, stellate cells and endothelial cells. Lipoprotein lipase expression was detected in Kupffer cells and stellate cells. As a function of stellate cell activation, expression of adipose triglyceride lipase decreased by twofold and lipoprotein lipase increased by 32-fold suggesting that it may play a role in retinol ester hydrolysis during stellate cell activation.     

Clinical and genetic characterization of Chanarin-Dorfman syndrome

We describe the clinical features, muscle pathology features, and molecular studies of seven patients with Chanarin-Dorfman syndrome (CDS) or neutral lipid storage disease and ichthyosis (NLSDI), a multisystem triglyceride storage disease with massive accumulation of lipid droplets in muscle fibers.All patients presented with congenital ichthyosiform erythroderma, cytoplasmic lipid droplets in blood cells, mild to severe hepatomegaly, and increased serum CK levels and liver enzymes. Three patients showed muscle symptoms and three had steathorrea. Molecular analysis identified five mutations, three of which are novel.These findings expand the clinical and mutational spectrum and underline the genetic heterogeneity of this disease.