Abstract
Long-chain bases (LCBs) are both intermediates in sphingolipid metabolism and potent signaling molecules that control cellular processes. To understand how regulation of sphingolipid metabolism and levels of individual LCB species impinge upon physiological and pathophysiological processes requires sensitive and specific assays for monitoring these molecules. Here we describe a shotgun lipidomics method for quantitative profiling of LCB molecules. The method employs a “mass-tag” strategy where LCBs are chemically derivatized with deuterated methyliodide (CD3I) to produce trimethylated derivatives having a positively charged quaternary amine group. This chemical derivatization minimizes unwanted in-source fragmentation of LCB analytes and prompts a characteristic trimethylaminium fragment ion that enables sensitive and quantitative profiling of LCB molecules by parallel reaction monitoring on a hybrid quadrupole time-of-flight mass spectrometer. Notably, the strategy provides, for the first time, a routine for monitoring endogenous 3-ketosphinganine molecules and distinguishing them from more abundant isomeric sphingosine molecules. To demonstrate the efficacy of the methodology we report an in-depth characterization of the LCB composition of yeast mutants with defective sphingolipid metabolism and the absolute levels of LCBs in mammalian cells. The strategy is generic, applicable to other types of mass spectrometers and can readily be applied as an additional routine in workflows for global lipidome quantification and for functional studies of sphingolipid metabolism.
Highlights
Long-chain bases (LCBs) are low abundant biosynthetic intermediates in sphingolipid metabolism and signaling molecules that impinge on a wide range of physiological processes [1,2]
To evaluate if this mass-tag strategy is applicable for profiling LCB species, which contain an amine group (Fig 1), we tested whether LCBs could be converted to trimethylated derivatives (denoted (CD3)3-LCB))
We evaluated whether the CD3I derivatization would improve the ionization efficiency of LCB analytes
Summary
Long-chain bases (LCBs) are low abundant biosynthetic intermediates in sphingolipid metabolism and signaling molecules that impinge on a wide range of physiological processes [1,2]. The first step in de novo sphingolipid metabolism is the condensation of serine and fatty acyl-CoAs to produce the 3-ketosphinganines. This reaction is catalyzed by serine palmitoyltransferase, which in yeast and mammalian cells primarily uses palmitoyl-CoA to produce C183-ketosphingosine. Shotgun Lipidomic Analysis of Long-Chain Bases produce LCBs with different hydrocarbon chain lengths and numbers of double bonds. 3-ketosphinganines can be reduced to sphinganines which can be further converted 4-hydroxysphinganines (phytosphingosines) These LCB molecules can be N-acylated to generate ceramides. To understand how LCB metabolism and level of individual LCB species impinge upon physiological and pathophysiological processes warrants sensitive and specific assays for monitoring these molecules
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