Abstract
Although understudied relative to many phospholipids, accumulating evidence suggests that bis(monoacylglycero)phosphate (BMP) is an important class of regulatory lipid that plays key roles in lysosomal integrity and function. BMPs are rare in most mammalian tissues, comprising only a few percent of total cellular lipid content, but are elevated in cell types such as macrophages that rely heavily on lysosomal function. BMPs are markedly enriched in endosomal and lysosomal vesicles compared to other organelles and membranous structures, and their unique sn-1:sn-1′ stereoconfiguration may confer stability within the hydrolytic lysosomal environment. BMP-enriched vesicles serve in endosomal-lysosomal trafficking and function as docking structures for the activation of lysosomal hydrolytic enzymes, notably those involved in the catabolic breakdown of sphingolipids. BMP levels are dysregulated in lysosomal storage disorders, phospholipidosis, metabolic diseases, liver and kidney diseases and neurodegenerative disorders. However, whether BMP alteration is a mediator or simply a marker of pathological states is unclear. Likewise, although BMP acyl chain composition may be altered with disease states, the functional significance of specific BMP species remains to be resolved. Newly developed tools for untargeted lipidomic analysis, together with a deeper understanding of enzymes mediating BMP synthesis and degradation, will help shed further light on the functional significance of BMPs in cellular physiology and pathology.
Highlights
Recent analytical, cheminformatic, and biological breakthroughs are revealing the diverse roles of lipids in physiology and disease
At lysosomal pH, acid sphingomyelinase (ASM) activity is highly stimulated by anionic lipids such as Bis(acylglycero)phosphates may contain multiple acyl chains: two (BMPs) [54], and ASM has been found to contribute to lysosomal membrane stability through interactions with heat shock protein 70 (Hsp70) [47]
BMP binding to Niemann-Pick Disease Type C2 Protein (NPC-2) is important for cholesterol transport within the lysosome, emphasizing how it is clear that BMP binding to Niemann-Pick Disease Type C (NPC)-2 is important for cholesterol transport within the lysosome, alterations to BMP’s binding andenzyme cofactorbinding functionand cancofactor affect lysosome andlysosome produce a emphasizing how enzyme alterations to BMP’s function biology can affect range of phenotypic changes depending upon local protein and lipid levels
Summary
Cheminformatic, and biological breakthroughs are revealing the diverse roles of lipids in physiology and disease. BMP comprises up to 4% of total lipids in bacteria [6]. While the cellular abundance and acyl-chain diversity of BMPs is supported by a. 2020, 21, 8067 growing body of literature, BMP metabolism remains largely uncharacterized. (b) Known BMP species variants, shown with fatty acyl side chains composed of oleic acid (FA C18:1) as an example. Variants, shown with fatty acyl side chains composed of oleic acid (FA C18:1) as an example. In most cells and tissues, BMP is found to comprise less than 1% of total phospholipids [6,7,8,9]. While the cellular abundance and acyl-chain diversity of BMPs is supported by a growing body of literature, BMP metabolism remains largely uncharacterized
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