Inhibitors of the sphingomyelin cycle: Sphingomyelin synthases and sphingomyelinases.

Sphingolipids are a class of bioactive lipids, which are key modulators of an increasing number of physiologic and pathophysiologic processes that include cell cycle, apoptosis, angiogenesis, stress and inflammatory responses. Sphingomyelin is an important structural component of biological membranes, and one of the end-points in the synthesis of sphingolipids. Mainly synthetized in the Golgi apparatus, sphingomyelin is transported to all other biological membranes. Upon stimulation, sphingomyelin can be hydrolyzed to ceramide by 5 different sphingomyelinases. The diversity and cellular topology of ceramide allow it to exert multiple biologies. Furthermore, ceramide can be metabolized to many other bioactive sphingolipids. Ceramide, coming from sphingomyelin or other complex sphingolipids, can be hydrolyzed to sphingosine, which can easily change cellular localization. In turn, sphingosine can be recycled to ceramide and to sphingomyelin in the endoplasmic reticulum, completing the sphingomyelin cycle. Our understanding of the roles of various sphingolipids in the regulation of different cellular processes has come from studying the enzymes that regulate these sphingolipids, and their manipulation. The use of pharmacologic inhibitors has been critical for their study, as well as being promising bullets for disease treatment. Some of these diseases involving the sphingomyelin cycle include cancer, inflammation, atherosclerosis, diabetes and some rare diseases such as Niemann-Pick disease. This review will focus on the enzymes involved in the sphingomyelin cycle, their history, and their involvement in pathophysiological processes. Finally, it will describe in details all the small molecules that are being used to inhibit these enzymes and their use in therapeutics.