Abstract
In yeast, mutations in the CDP-choline pathway for phosphatidylcholine biosynthesis permit the cell to grow even when the SEC14 gene is completely deleted (Cleves, A., McGee, T., Whitters, E., Champion, K., Aitken, J., Dowhan, W., Goebl, M., and Bankaitis, V. (1991) Cell 64, 789-800). We report that strains carrying mutations in the CDP-choline pathway, such as cki1, exhibit a choline excretion phenotype due to production of choline during normal turnover of phosphatidylcholine. Cells carrying cki1 in combination with sec14(ts), a temperature-sensitive allele in the gene encoding the phosphatidylinositol/phosphatidylcholine transporter, have a dramatically increased choline excretion phenotype when grown at the sec14(ts)-restrictive temperature. We show that the increased choline excretion in sec14(ts) cki1 cells is due to increased turnover of phosphatidylcholine via a mechanism consistent with phospholipase D-mediated turnover. We propose that the elevated rate of phosphatidylcholine turnover in sec14(ts) cki1 cells provides the metabolic condition that permits the secretory pathway to function when Sec14p is inactivated. As phosphatidylcholine turnover increases in sec14(ts) cki1 cells shifted to the restrictive temperature, the INO1 gene (encoding inositol-1-phosphate synthase) is also derepressed, leading to an inositol excretion phenotype (Opi-). Misregulation of the INO1 gene has been observed in many strains with altered phospholipid metabolism, and the relationship between phosphatidylcholine turnover and regulation of INO1 and other co-regulated genes of phospholipid biosynthesis is discussed.
Highlights
As phosphatidylcholine turnover increases in sec14ts cki1 cells shifted to the restrictive temperature, the INO1 gene is derepressed, leading to an inositol excretion phenotype (Opi2)
Analysis of suppressors that permit the sec14ts mutant to grow at the restrictive temperature led to the discovery that mutations in the CDP-choline pathway for PC biosynthesis (Fig. 1) suppress the sec14 mutant phenotype, allowing wild type growth even in strains carrying a total deletion of the SEC14 gene [1]
We report here a related choline excretion phenotype (Fig. 3), which we are designating as Opc2
Summary
INO1, inositol-1-phosphate synthase; CHO1, PS synthase; PSD1, PS decarboxylase; CHO2 (PEM1), PE N-methyltransferase; OPI3 (PEM2), phospholipid N-methyltransferase; CKI1, choline kinase; CCT1, choline phosphate:CTP cytidylyltransferase; CPT1, sn-1,2-diacylglycerol choline phosphotransferase; SEC14, PI/PC transporter. While the deletion of genes encoding enzymes of the CDP-choline pathway does not affect INO1 regulation in response to inositol [9], such mutants suppress the sec phenotype [1, 14]. The INO1 gene is the most highly regulated of a set of genes encoding enzymes of phospholipid biosynthesis that are subject to complex coordinate control. We document a relationship between PC turnover and regulation of the INO1 gene and, by extension, other co-regulated genes of phospholipid metabolism
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