Phosphosphingolipids (PSL) are essential components of eukaryotic membranes. The major PSL in fungi and protists is inositol phosphorylceramide (IPC), while sphingomyelin (SM), and to a lesser extent ethanolamine phosphorylceramide (EPC) predominate in mammals. Most kinetoplastid protozoa have a syntenic locus that encodes a single sphingolipid synthase (SLS) gene. Uniquely, among the kinetoplastids, the salivarian (African) trypanosomes have expanded this locus from a single gene in Trypanosoma vivax (TvSLS) to four genes in T. brucei (TbSLS1-4). We have previously shown that one of these is an IPC synthase, while the others are SM/EPC synthases, and that specificity is controlled by a single signature residue (IPC, serine; SM/EPC, phenylalanine). This residue is serine in T. cruzi and Leishmania major SLSs, both of which are demonstrated IPC synthases. However, T. vivax has a tyrosine at this residue raising the issue of specificity. Using a liposome-supplemented in vitro translation system we now show that T. vivax SLS is an SM/EPC synthase, and that the basal kinetoplastid Bodo saltans SLS is an IPC synthase (serine). We use these data, and a multiple alignment of available sequences, to discuss the evolution of kinetoplastid SLSs and their unique expansion in T. brucei and related salivarian trypanosomes.
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