Abstract
Intracellular triglyceride (TG) hydrolysis or lipolysis is catalyzed by the key intracellular triglyceride hydrolase, adipose triglyceride lipase (ATGL). The G0/G1 Switch Gene 2 (G0S2) was recently identified as the major selective inhibitor of ATGL and its hydrolase function. Since G0S2 levels are dynamically linked and rapidly responsive to nutrient status or metabolic requirements, the identification of its regulation at the protein level is of significant value. Earlier evidence from our laboratory demonstrated that G0S2 is a short-lived protein degraded through the proteasomal pathway. However, little is currently known regarding the underlying mechanisms. In the current study we find that 1) protein degradation is initiated by K48-linked polyubiquitination of the lysine- 25 in G0S2; and 2) G0S2 protein is stabilized in response to ATGL expression and TG accumulation. Mutation of lysine-25 of G0S2 abolished ubiquitination and increased protein stability. More importantly, G0S2 was stabilized via different mechanisms in the presence of ATGL vs. in response to fatty acid (FA)-induced TG accumulation. Furthermore, G0S2 protein but not mRNA levels were reduced in the adipose tissue of ATGL-deficient mice, corroborating the involvement of ATGL in the stabilization of G0S2. Taken together our data illustrate for the first time a crucial multifaceted mechanism for the stabilization of G0S2 at the protein level.
Highlights
The process of lipid catabolism, known as lipolysis in adipose tissue, is a mechanism that plays a central role in governing global lipid and energy homeostasis
Since adipose triglyceride lipase (ATGL) is coactivated by Comparative gene identification-58 (CGI-58), we examined the effects of CGI-58 on G0S2 protein stability
G0S2 has been established as a key regulator of lipid metabolism by virtue of its ability to bind to and inhibit the hydrolase activity of ATGL
Summary
The process of lipid catabolism, known as lipolysis in adipose tissue, is a mechanism that plays a central role in governing global lipid and energy homeostasis. This catabolic pathway in which fatty acids (FA) and glycerol are liberated from neutral triglyceride (TG) stores is essential for adaptive energy response [1]. FAs released into circulation from adipose lipolysis are used for a variety of cellular processes including as energy substrates in the liver [2]. Lipolysis in adipose tissue has been shown to be rapidly responsive to nutrient status [1,3]. Fasting and PLOS ONE | DOI:10.1371/journal.pone.0156742 June 1, 2016
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