Role of ATGL in hepatic energy metabolism

ATGL在肝脏能量代谢中的作用

• 批准号: 8280419
• 负责人: Douglas G Mashek
• 金额: $ 32.39万
• 依托单位: UNIVERSITY OF MINNESOTA
• 依托单位国家: 美国
• 财政年份: 2011
• 资助国家: 美国
• 起止时间: 2011-06-15 至 2016-05-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8280419
• 关键词: Adipose tissue; Affect; Biological Process; Cardiovascular Diseases; Comorbidity; Complex; Data; Development; Diabetes Mellitus; Diet; Disease; Energy Metabolism; Etiology; Event; Fatty Acids; General Population; Glean; Health; Hepatic; Homeostasis; Human; Hydrolysis; Hyperglycemia; Hypertriglyceridemia; In Vitro; Insulin Resistance; Knowledge; Laboratories; Link; Lipase; Lipids; Liver; Liver diseases; Mediating; Metabolic; Metabolic Diseases; Metabolic Pathway; Metabolism; Methodology; Methods; Non-Insulin-Dependent Diabetes Mellitus; Nutritional; Obesity; Outcome; Pathway interactions; Peroxisome Proliferator-Activated Receptors; Pharmacologic Substance; Production; Property; Regulation; Research; Risk; Role; Signal Transduction; Signaling Molecule; Techniques; Testing; Transcriptional Regulation; Triglycerides; Very low density lipoprotein; base; diabetic; experience; fatty acid metabolism; glucose output; glucose tolerance; hepatic lipase; improved; in vivo; innovation; insight; insulin sensitivity; lipid metabolism; loss of function; mouse model; non-alcoholic fatty liver; novel; prevent; stable isotope; trafficking; uptake

DESCRIPTION (provided by applicant): Non-alcoholic fatty liver disease (NAFLD), defined by triacylglycerol (TAG) accumulation, is a prevalent disorder that is involved in the etiology of numerous metabolic diseases including obesity, diabetes and cardiovascular disease. Despite the importance of TAG metabolism and the advancements into our understanding of the TAG synthetic pathway, the mechanisms regulating hepatic TAG hydrolysis and their effects on disease etiology are unknown. The objective of this application is to define the role of adipose TAG lipase (ATGL) in hepatic lipid metabolism and signaling, the etiology of insulin resistance and in mediating diet-specific effects. The hypothesis of the proposed studies is that ATGL is a prominent hepatic lipase that elicits wide-ranging effects on energy metabolism by altering FA channeling and signaling. We base this hypothesis on Preliminary Studies from our laboratory showing that ATGL alters partitioning of hydrolyzed FA between anabolic and catabolic pathways, regulates PPAR-1 activity, uncouples insulin resistance from NAFLD and selectively hydrolyzes TAG. The rationale for the proposed research is that identifying the role of ATGL in mediating hepatic TAG metabolism will provide significant insight into the etiology of NAFLD and related comorbidities, thereby, advancing the possibilities for development of nutritional or pharmaceutical therapies. The hypothesis will be tested using three specific aims: 1) to characterize the ATGL and PPAR-1 signaling axis and its role in hepatic energy metabolism, 2) to define the role of hepatic ATGL in regulating hepatic and whole-body insulin resistance and 3) to characterize the effect of hepatic ATGL on hydrolyzing distinct TAG pools and mediating subsequent FA channeling and signaling. Under the first aim, ATGL gain or loss-of-function studies in mouse models will define the relationship between ATGL and PPAR-a. Additionally, in vitro studies will define the mechanisms through which ATGL regulates PPAR-1 activity. The second aim will employ both in vitro and in vivo methodologies along with stable isotope techniques to characterize how ATGL uncouples hepatic TAG accumulation from insulin resistance and its role in the formation of lipid signaling molecules. The third aim will define how hepatic ATGL regulates the signaling and channeling of TAG-FA derived from different substrates and mediates diet-specific effects on metabolism. These studies are innovative because they approach NAFLD and its comorbidities from the understudied and often ignored pathway of TAG hydrolysis. Understanding how hepatic TAG hydrolysis is regulated is significant because it not only impacts TAG accumulation, but also dictates the metabolic fate and signaling properties of the hydrolyzed FA that can ultimately influence a multitude of biological processes.

描述（由申请方提供）：由三酰甘油（TAG）蓄积定义的非酒精性脂肪性肝病（NAFLD）是一种普遍存在的疾病，与许多代谢疾病（包括肥胖症、糖尿病和心血管疾病）的病因有关。尽管TAG代谢的重要性和我们对TAG合成途径的理解的进步，但调节肝脏TAG水解的机制及其对疾病病因学的影响尚不清楚。本申请的目的是确定脂肪TAG脂肪酶（ATGL）在肝脏脂质代谢和信号传导、胰岛素抵抗的病因学和介导饮食特异性效应中的作用。提出的研究假设是，ATGL是一种重要的肝脂肪酶，通过改变FA通道和信号传导对能量代谢产生广泛影响。我们基于我们实验室的初步研究表明，ATGL改变了水解FA在合成代谢和分解代谢途径之间的分配，调节了PPAR-1活性，解除了NAFLD的胰岛素抵抗，并选择性水解了TAG。拟议研究的基本原理是，确定ATGL在介导肝脏TAG代谢中的作用将为NAFLD和相关合并症的病因学提供重要见解，从而促进营养或药物治疗的发展。将使用三个特定目的对该假设进行检验：1）表征ATGL和PPAR-1信号传导轴及其在肝脏能量代谢中的作用，2）确定肝脏ATGL在调节肝脏和全身胰岛素抵抗中的作用，3）表征肝脏ATGL对水解不同TAG池和介导后续FA通道和信号传导的作用。在第一个目标下，在小鼠模型中的ATGL获得或功能丧失研究将定义ATGL和PPAR-a之间的关系。此外，体外研究将确定ATGL调节PPAR-1活性的机制。第二个目标将采用体外和体内方法沿着稳定同位素技术来表征ATGL如何将肝脏TAG蓄积与胰岛素抵抗解偶联，以及其在脂质信号分子形成中的作用。第三个目标是确定肝脏ATGL如何调节来自不同底物的TAG-FA的信号传导和通道，并介导饮食对代谢的特异性影响。这些研究是创新的，因为它们从研究不足和经常被忽视的TAG水解途径接近NAFLD及其合并症。了解肝脏TAG水解是如何调节的是重要的，因为它不仅影响TAG积累，而且还决定了水解FA的代谢命运和信号传导特性，最终可以影响许多生物过程。