Dominant suppressor mutation bypasses the sphingolipid requirement for growth of Saccharomyces cells at low pH: role of the CWP2 gene.

Strains of Saccharomyces cerevisiae termed sphingolipid compensatory (SLC) do not grow at low pH when the cells lack sphingolipids. To begin to understand why sphingolipids are required for growth at low pH, we isolated derivatives of SLC strains, termed low pH resistant (LprR), carrying the LPR suppressor gene that allows growth at pH 4.1 when cells lack sphingolipids. Suppression is due to mutation of a single nuclear gene. The LPR suppressor gene functions, at least in part, by enhancing the ability of cells lacking sphingolipids to generate a net efflux of protons in suspension fluid with a pH range of 4.0-6.0. The LPR suppressor gene also enables cells lacking sphingolipids to maintain their intracellular pH near neutrality when the pH of the suspension fluid is low, unlike cells lacking the suppressor gene, which cannot maintain their intracellular pH in the face of a low external pH. These results demonstrate that some functions(s) of sphingolipids necessary for growth at low pH can be bypassed by a suppressor mutation. Attempts to clone the LPR suppressor gene were not successful, but they led to the isolation of the CWP2 gene, which encodes a major mannoprotein component of the outer cell wall. It was isolated because an increased copy number has the unusual property of increasing the frequency at which LprR strains arise. As we show here, part of the reason for this effect is that the CWP2 gene is essential for generating a net efflux of protons and for controlling intracellular pH in LprR strains that lack sphingolipids. These results suggest new cellular functions for the Cwp2 protein.

Mannosylphosphoryldolichol-mediated reactions in oligosaccharide-P-P-dolichol biosynthesis. Recognition of the saturated alpha-isoprene unit of the mannosyl donor by pig brain mannosyltransferases.

The specificity of Man-P-Dol:Man5-8GlcNAc2-P-P-Dol (Oligo-P-P-Dol) mannosyltransferase activity in pig brain was investigated by comparing a variety of mannosylphosphorylisoprenols as mannosyl donors. For this comparison the beta-Man-P-isoprenols were synthesized using a partially purified preparation of mannosylphosphorylundecaprenol (Man-P-Undec) synthase from Micrococcus luteus. The bacterial mannosyltransferase efficiently catalyzed the transfer of mannose from GDP-[3H]Man to a series of defined isoprenyl monophosphate substrates. Two alpha-Man-P-dolichols were synthesized chemically and also examined as substrates. When exogenous beta-[3H]Man-P-Dol95 was tested as a substrate for Man-P-Dol:Oligo-P-P-Dol mannosyltransferase activity in pig brain microsomes, [3H]mannose was actively transferred to endogenous Oligo-P-P-Dol acceptors. The major enzymatically labeled product was Man9GlcNAc2-P-P-Dol. Under identical conditions beta-[3H]mannosylphosphorylpolyprenol (Man-P-Poly95) was an extremely poor substrate, indicating that the saturated alpha-isoprene unit of the dolichyl moiety is critical for recognition of the lipophilic mannosyl donor by the endoplasmic reticulum-associated mannosyltransferase(s). When Man-P-dolichols containing 2, 11, or 19 isoprene units were compared, the initial rates for the mannosyl transfer reactions and the affinity of the enzyme(s) for the mannophospholipid substrate increased with the length and hydrophobicity of the polyisoprenol chain. The anomeric configuration of the mannosyl moiety is apparently essential because the brain mannosyltransferases exhibited a strong preference for beta-Man-P-dolichols over the corresponding chemically synthesized alpha-stereoisomers. These results: 1) describe a simple two-step procedure for obtaining a partially purified preparation of Man-P-Undec synthase that efficiently synthesizes a variety of beta-Man-P-isoprenols; 2) indicate that pig brain Man-P-Dol:Oligo-P-P-Dol mannosyltransferase activity is relatively specific for lipophilic mannosyl donors containing 19 isoprene units with a beta-Man 1-P group attached to the saturated alpha-isoprene unit of dolichol; and 3) emphasize the importance of the reduction of the alpha-isoprene unit in the biosynthesis and function of Dol-P in mammalian cells.