Disrupted sphingolipid metabolism following acute clozapine and olanzapine administration

Obesity predisposes individuals to the development of insulin resistance in skeletal muscle and the liver, and researchers have recently proposed two mechanisms by which excess adiposity antagonizes insulin action in peripheral tissues. First, when adipocytes exceed their storage capacity, fat begins to accumulate in tissues not suited for lipid storage, leading to the formation of specific metabolites that inhibit insulin signal transduction. Second, obesity triggers a chronic inflammatory state, and cytokines released from either adipocytes or from macrophages infiltrating adipose tissue antagonize insulin action. The sphingolipid ceramide is a putative intermediate linking both excess nutrients (i.e. saturated fatty acids) and inflammatory cytokines (e.g. tumor necrosis factor-alpha, TNFalpha) to the induction of insulin resistance. Moreover, ceramide has been shown to be toxic in a variety of different cell types (e.g. pancreatic beta-cells, cardiomyocytes, etc.), and review of the literature reveals putative roles for the sphingolipid in the damage of cells and tissues which accompany diabetes, hypertension, cardiac failure, atherosclerosis, etc. In this review, I will evaluate the contribution of ceramides in the development of insulin resistance and the complications associated with metabolic diseases.

Very long-chain fatty acids (VLCFAs) exert a variety of cellular functions and are associated with numerous diseases. However, the precise pathway behind their elongation has remained elusive. Moreover, few regulatory mechanisms for VLCFAs synthesis have been identified. Elongases catalyze the first of four steps in the VLCFA elongation cycle; mammals have seven elongases (ELOVL1-7). In the present study, we determined the precise substrate specificities of all the ELOVLs by in vitro analyses. Particularly notable was the high activity exhibited by ELOVL1 toward saturated and monounsaturated C20- and C22-CoAs, and that it was essential for the production of C24 sphingolipids, which are unique in their capacity to interdigitate within the membrane as a result of their long chain length. We further established that ELOVL1 activity is regulated with the ceramide synthase CERS2, an enzyme essential for C24 sphingolipid synthesis. This regulation may ensure that the production of C24-CoA by elongation is coordinated with its utilization. Finally, knockdown of ELOVL1 caused a reduction in the activity of the Src kinase LYN, confirming that C24-sphingolipids are particularly important in membrane microdomain function.