Metabolism of GPIs in mammalian cells

In Trypanosoma brucei, glycosylphosphatidylinositol (GPI) anchors of proteins and free GPIs with identical structures have been characterized. This identity provides strong presumptive evidence that the free GPIs are in fact precursors of the GPI anchors on proteins. In mammalian tissues, however, rather consistent differences in the structures of free GPIs and GPI anchors are observed. The terminal GPIs produced by the mammalian biosynthetic pathway differ from GPI anchors in being almost exclusively fatty acid acylated on the inositol residue, having a greater number of phosphoethanolamine residues, and perhaps in containing a greater percentage of diacylglycerol components. While in principle these differences could be reconciled by remodeling reactions before or after attachment of GPI anchors, it is possible that some of the mammalian free GPIs play cellular roles other than as anchor precursors. We have approached this question by studying the lifetimes of the last three GPIs on the biosynthetic pathway, denoted H6, H7 and H8, in K562 cells and in K562 mutant designated class K that is devoid of GPI-anchored proteins. Pulse-chase metabolic labeling with [3H]-mannose indicated that H6 was a precursor of H7 and H8 and that the H8 lifetime was more than one hour in the parental cells and even longer in the mutant. Preliminary data indicated that the majority of each of the three GPIs was localized in the plasma membrane fraction rather than the endoplasmic reticulum. These observations argue that mammalian GPIs are not utilized exclusively as GPI anchor precursors

Characterization of alternatively spliced PIG-A transcripts in normal and paroxysmal nocturnal hemoglobinuria cells

The genetic lesion in paroxysmal nocturnal hemoglobinuria (PNH) cells resides in a DNA element that 1) encodes a product required for assembly of GlcNAc-inositol phospholipid and 2) is commonly affected in different patients. In this study, three alternative mRNA transcripts (1600, 1200 and 950 bp) that derive from this genetic element in normal cells were characterized. The 1200-bp transcript was found to arise from splicing out of 374 bp of exonic sequence extending from positions 407-780. The 950-bp transcript was found to arise from removal of this and 284 bp of additional exonic sequence beginning further upstream at position 123. Analyses of transcripts expressed in Epstein-Barr virus (EBV)-transformed B lymphocytes prepared from two PNH patients showed that both failed to express normal 1600-bp transcripts. One expressed truncated transcripts of 1000 and 800 bp generated by an alternate splice which utilized a downstream signal in place of the normal intronic splice signal. The other expressed a 1600 bp-transcript with multiple nucleotide changes but normal 1200- and 950- bp "spliced" transcripts