Analysis of Lipolytic Protein Trafficking and Interactions in Adipocytes

Granneman, James G.; Moore, Hsiao-Ping; Granneman, Rachel L.; Greenberg, Andrew S.; Obin, Martin S.; Zhu, Zhenhong

doi:10.1074/jbc.m610580200

Cited by 265 publications

(307 citation statements)

References 33 publications

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“…The localized metabolic subdomain is consistent with a small cytosolic volume due to large lipid droplet in adipocyte (Moore et al, 2005;Denton et al, 1966). Furthermore, the volume fraction of this metabolic subdomain estimated by the model corresponds to the volume fraction of intracellular water space (1~4% of total tissue volume) measured from in vitro studies of adipose fat pad (Denton et al, 1966;Crofford and Renold, 1965) Recent in vitro studies of adipocyte lipid mobilization showed that major lipolytic enzymes and proteins are co-localized in a subcellular domain during beta-adrenergic stimulation (Granneman et al, 2007;Moore et al, 2005;Clifford et al, 2000). The localization of enzyme complexes reduces the transit time of metabolites which allows faster cellular dynamics (Welch and Easterby, 1994).…”

Section: Intracellular Compartmentationsupporting

confidence: 69%

A computational model of adipose tissue metabolism: Evidence for intracellular compartmentation and differential activation of lipases

Kim

Saidel

Kalhan

2008

Journal of Theoretical Biology

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Regulation of lipolysis in adipose tissue is critical to whole body fuel homeostasis and to the development of insulin resistance. Due to the challenging nature of laboratory investigations of regulatory mechanisms in adipose tissue, mathematical models could provide a valuable adjunct to such experimental work. We have developed a computational model to analyze key components of adipose tissue metabolism in vivo in human in the fasting state. The various key components included triglyceride-fatty acid cycling, regulation of lipolytic reactions, and glyceroneogenesis. The model, consisting of spatially lumped blood and cellular compartments, included essential transport processes and biochemical reactions. Concentration dynamics for major substrates were described by mass balance equations. Model equations were solved numerically to simulate dynamic responses to intravenous epinephrine infusion. Model simulations were compared with the corresponding experimental measurements of the arteriovenous difference across the abdominal subcutaneous fat bed in humans. The model can simulate physiological responses arising from the different expression levels of lipases. Key findings of this study are as follows: (1) Distinguishing the active metabolic subdomain (~3% of total tissue volume) is critical for simulating data. (2) During epinephrine infusion, lipases are differentially activated such that diglyceride breakdown is ~4 times faster than triglyceride breakdown. (3) Glyceroneogenesis contributes more to glycerol-3-phosphate synthesis during epinephrine infusion when pyruvate oxidation is inhibited by a high acetyl-CoA/free-CoA ratio.

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Section: Intracellular Compartmentationsupporting

confidence: 69%

A computational model of adipose tissue metabolism: Evidence for intracellular compartmentation and differential activation of lipases

Kim

Saidel

Kalhan

2008

Journal of Theoretical Biology

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“…A large number of hormonal signaling pathways and lipid droplet-associated protein factors have been demonstrated to regulate substrate access and the activity of lipase, and thereby to govern the lipolysis of white adipose tissue [31,32] . Our data showed that the phosphorylation of HSL and expression of CGI-58 were increased in the tissue of the RRM rats.…”

Section: Discussionmentioning

confidence: 99%

The effect of inhibition of endoplasmic reticulum stress on lipolysis in white adipose tissue in a rat model of chronic kidney disease

et al. 2014

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Aim: Lipolysis in fat tissue plays an important role in the development of metabolic disturbances, a characteristic feature of chronic kidney disease (CKD). In the present study, we tested the hypothesis that the inhibition of endoplasmic reticulum (ER) stress could alleviate lipolysis in white adipose tissue in a rat model of CKD. Methods: A rat model of CKD was established by a method of reduced renal mass (RRM). Lipolysis was measured as the release of glycerol in ex vivo fat pads and cultured primary adipocytes. The activity of lipases and markers of ER stress were measured by Western blotting and immunoprecipitation. Results: Our data showed that lipolysis in visceral white adipose tissue was increased in RRM rats compared with control rats. In addition, increased phosphorylation of hormone-sensitive lipase (HSL) and binding of adipose triglyceride lipase (ATGL) to comparative gene identification-58 (CGI-58) protein were observed in the RRM rats. The phosphorylation of ER stress markers, including IRE1α, PERK, and eukaryotic initiation factor (eIF) 2α, and the expression of ER stress marker 78 kDa glucose-regulated protein (GRP78) were significantly increased in RRM rats. Treatment with an inhibitor of ER stress partially but significantly alleviated lipolysis, and this alleviation was accompanied by reduced binding of ATGL to CGI-58. Conclusion: Our results showed that enhanced lipolysis and ER stress occurred in visceral white adipose tissue in a rat model of CKD. Moreover, inhibition of ER stress significantly alleviated lipolysis. These findings suggest that ER stress is a potential therapeutic target for the metabolic disturbances associated with CKD.

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“…To initiate lipolysis, catecholamines bind to β-adrenergic receptors to activate adenylyl cyclase, which results in increased intracellular concentrations of cyclic AMP and, thus, activated protein kinase A (PKA). PKA phosphorylates HSL and perilipin, with subsequent translocation of HSL from the cytosol to the lipid droplets [13], leading to the hydrolysis of triacylglycerols. Catecholamine release is increased when there is an increased energy demand (e.g.…”

Section: Biological Differences Between Visceral and Subcutaneous Adimentioning

confidence: 99%

Adipose tissue distribution and risk of metabolic disease: does thiazolidinedione-induced adipose tissue redistribution provide a clue to the answer?

2007

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The relative effect of visceral and subcutaneous obesity on the risk of chronic metabolic disease has been a matter of long-term dispute. While ample data support either of the fat depots being causative or associative, valid argument for one depot often automatically belittles the other. Paradigms such as the visceral/portal hypothesis and the acquired lipodystrophy/ectopic fat storage and endocrine hypothesis have been proposed. Nevertheless, neither hypothesis alone explains the entire pathophysiological setting. Treatment of diabetes with thiazolidinediones selectively increases fat partitioning to the subcutaneous adipose depot but does not change visceral fat accumulation. This is in contrast to the preferential visceral fat mobilisation by diet and exercise. Surgical removal of visceral or subcutaneous adipose tissue yields relatively long-lasting metabolic improvement only when combined with procedures that ameliorate adipose tissue cell composition. These studies illustrate that human adipose tissue in different anatomic locations does not work in isolation, and that there is a best-fit relationship in terms of volume and function among different fat depots that needs to be met to maintain the systemic energy balance and to prevent the complications related to obesity.

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Analysis of Lipolytic Protein Trafficking and Interactions in Adipocytes

Cited by 265 publications

References 33 publications

A computational model of adipose tissue metabolism: Evidence for intracellular compartmentation and differential activation of lipases

A computational model of adipose tissue metabolism: Evidence for intracellular compartmentation and differential activation of lipases

The effect of inhibition of endoplasmic reticulum stress on lipolysis in white adipose tissue in a rat model of chronic kidney disease

Adipose tissue distribution and risk of metabolic disease: does thiazolidinedione-induced adipose tissue redistribution provide a clue to the answer?

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