| Abstract: | Lipolysis is the catabolic pathway by which triglycerides are hydrolyzed into fatty acids. Adipose triglyceride lipase (ATGL) and hormone-sensitive lipase (HSL) have the capacity to hydrolyze in vitro the first ester bond of triglycerides, but their respective contributions to whole cell lipolysis in human adipocytes is unclear. Here, we have investigated the roles of HSL, ATGL, and its coactivator CGI-58 in basal and forskolin-stimulated lipolysis in a human white adipocyte model, the hMADS cells. The hMADS adipocytes express the various components of fatty acid metabolism and show lipolytic capacity similar to primary cultured adipocytes. We show that lipolysis and fatty acid esterification are tightly coupled except in conditions of stimulated lipolysis. Immunocytochemistry experiments revealed that acute forskolin treatment promotes HSL translocation from the cytosol to small lipid droplets and redistribution of ATGL from the cytosol and large lipid droplets to small lipid droplets, resulting in enriched colocalization of the two lipases. HSL or ATGL overexpression resulted in increased triglyceride-specific hydrolase capacity, but only ATGL overexpression increased whole cell lipolysis. HSL silencing had no effect on basal lipolysis and only partially reduced forskolin-stimulated lipolysis. Conversely, silencing of ATGL or CGI-58 significantly reduced basal lipolysis and essentially abolished forskolin-stimulated lipolysis. Altogether, these results suggest that ATGL/CGI-58 acts independently of HSL and precedes its action in the sequential hydrolysis of triglycerides in human hMADS adipocytes.Adipose tissue fat stores in humans are mainly dependent upon fatty acid (FA)2 supply, FA esterification to triglycerides (TG), and TG breakdown, or lipolysis. Adipose tissue lipolysis is governed by three lipases. Adipose triglyceride lipase (ATGL) and hormone-sensitive lipase (HSL) both have the capacity to initiate TG degradation by cleaving the first ester bond, but HSL is unique in its capacity to break down the second ester bond, converting diglycerides (DG) to monoglycerides (1–3). The non-rate-limiting monoglyceride lipase completes lipolysis by cleaving the last ester bond from a monoglyceride molecule, leading to glycerol release (4). Adipose tissue lipolysis has received much attention over the past 10 years because of its altered regulation in obesity (5).HSL resides freely in the cytosol and can associate with lipid droplets (LD). It is regulated by hormones such as catecholamines, insulin, and natriuretic peptides. Catecholamines bind to β-adrenoceptors on adipocyte cell membranes and activate cyclic AMP-dependent protein kinase. Similarly, natriuretic peptides bind to type A receptors and activate cyclic GMP-dependent protein kinase (6). The protein kinase action in stimulated lipolysis is 2-fold: 1) phosphorylation of HSL, leading to its translocation from the cytosol to LD (7, 8), and 2) phosphorylation of perilipin A (6, 9, 10), the predominant perilipin isoform in adipocytes, enhancing interaction between HSL and LD. The importance of HSL activity in stimulating complete lipolysis is indisputable, particularly given its unique capacity to hydrolyze DG. However, lipolysis is not exclusively dependent upon HSL because HSL null mice revealed residual TG lipase activity in adipose tissue (2, 11). Another adipose tissue lipase was identified (3, 12, 13). ATGL, also known as desnutrin or patatin-like phospholipase domain-containing protein 2, shows affinity toward TG only (3, 14). ATGL is activated by CGI-58, an esterase/thioesterase/lipase subfamily protein devoid of TG hydrolase enzymatic activity (15, 16). The role of HSL and ATGL has been investigated in murine fat cell lipolysis, but the relative importance of these lipases in basal and protein kinase A-stimulated human fat cell lipolysis has remained elusive.Increased fat mass is associated with defects in adipose tissue metabolism. In obesity, resistance to catecholamine-induced lipolysis is observed (17–19). This inhibition of lipolysis may be naturally occurring as an adaptive protective mechanism to minimize FA release and its deleterious consequences on metabolism. Indeed, decreased expression of HSL and ATGL has been observed in isolated adipocytes and differentiated preadipocytes of obese subjects and adipose tissue of insulin-resistant subjects, respectively (20–23). However, by virtue of its mass, adipose tissue basal lipolysis elevates circulating levels of FAs in obese subjects, thereby increasing the risk of insulin resistance. Therefore, the use of pharmacological lipid-lowering agents that act through inhibition of lipolysis has been a promising research avenue leading to the development of several series of HSL inhibitors (24).Herein, we sought to examine the respective contributions of HSL and ATGL to lipolysis and re-esterification in fat cells derived from human adipose tissue derived-multipotent stem cells (termed hMADS cells). These cells, which exhibit at a clonal level normal karyotype, self-renewal ability, and no tumorigenicity, are able to differentiate into functional adipocytes (25, 26). We investigated the localization of HSL and ATGL in basal and stimulated lipolytic conditions and studied lipase activities and whole cell lipolysis in adipocytes with altered expression levels of HSL, ATGL, and its coactivator CGI-58. Our results provide novel insights into ATGL localization and its critical role with coactivator CGI-58 in DG provision to HSL during basal and stimulated lipolysis. |
