Selection of lys2 Mutants of the Yeast SACCHAROMYCES CEREVISIAE by the Utilization of alpha-AMINOADIPATE.

Normal strains of Saccharomyces cerevisiae do not use alpha-aminoadipate as a principal nitrogen source. However, alpha-aminoadipate is utilized as a nitrogen source by lys2 and lys5 strains having complete or partial deficiencies of alpha-aminoadipate reductase and, to a limited extent, by heterozygous lys2/+ strains. Lys2 mutants were conveniently selected on media containing alpha-aminoadipate as a nitrogen source, lysine, and other supplements to furnish other possible auxotrophic requirements. The lys2 mutations were obtained in a variety of laboratory strains containing other markers, including other lysine mutations. In addition to the predominant class of lys2 mutants, low frequencies of lys5 mutants and mutants not having any obvious lysine requirement were recovered on alpha-aminoadipate medium. The mutants not requiring lysine appeared to have mutations at the lys2 locus that caused partial deficiencies of alpha-aminoadipate reductase. Such partial deficiencies are believed to be sufficiently permissive to allow lysine biosynthesis, but sufficiently restrictive to allow for the utilization of alpha-aminoadipate. Although it is unknown why partial or complete deficiencies of alpha-aminoadipate reductase cause utilization of alpha-aminoadipate as a principal nitrogen source, the use of alpha-aminoadipate medium has considerable utility as a selective medium for lys2 and lys5 mutants.

Genetic and physiological control of serine and glycine biosynthesis in Saccharomyces.

Two of the three known metabolic pathways to serine and glycine have been shown to be present in prototrophic yeast strains, i.e., the phosphorylated pathway from glycolytic intermediates and the glyoxylate pathway from tricarboxylic acid cycle intermediates. Two serine-glycine auxotrophs (ser1 and ser2) were found to be blocked in the phosphoglycerate pathway. The ser1 gene controls l-glutamate:phosphohydroxypyruvate transaminase biosynthesis, and the ser2 gene controls phosphoserine phosphatase biosynthesis. The other pathway to glycine, from isocitrate, is repressed by growth in glucose media, specifically, at isocitrate lyase and at the alanine:glyoxylate transaminase. This pathway is derepressed by growth to stationary phase in glucose media yielding high activity of these enzymes. The phosphorylated pathway appears to be the principal biosynthetic pathway to serine and glycine during growth on sugar media. Strains which are serine-glycine dependent in glucose media became capable of serine-glycine independent growth on acetate media. These results describe a method of physiological control of a secondary metabolic pathway allowing a single lesion in the principal biosynthetic pathway to produce auxotrophy. This may be termed conditional auxotrophy.

Effects of supersuppressor genes on enzymes controlling lysine biosynthesis in Saccharomyces.

Yeast supersuppressor genes capable of masking the effects of several lysine mutant genes (ly(1-1), ly(9-1), ly(2-1)) were studied with respect to their effects on the respective enzymes (saccharopine dehydrogenase, saccharopine reductase, and alpha-amino-adipic acid reductase). In all strains tested, the supersuppressors functioned by allowing enzyme synthesis not found in the unsuppressed mutant. Studies by optical methods of saccharopine dehydrogenase and saccharopine reductase extracted from suppressed ly(1-1) and ly(9-1) cells, respectively, revealed that the K(m) values for these enzymes were significantly greater than those found in wild type. Saccharopine dehydrogenase from suppressed ly(9-1) cells was found to have K(m) values similar to wild type. These findings are consistent with the inference that a supersuppressor may act by enabling nonsense codons to be read, producing altered enzyme protein. Recent findings that lysine degradation in mammals may involve saccharopine and that the human diseases, hyperlysinemia and saccharopinuria, may be due to metabolic blocks in this route of lysine degradation suggest the ly(1-1) and ly(9-1) yeast mutants as models for the human condition and its possible euphenic treatment.

"Active" one-carbon generation in Saccharomyces cerevisiae.

A new mutation introducing a one-carbon requirement (e.g., formate) for the glycine-supplemented growth of a serine-glycine auxotroph (ser1) was correlated with a lack of glycine decarboxylase activity. The presence of oxalate decarboxylase activity or glyoxylate decarboxylase activity did not overcome the one-carbon requirement. Another mutation characterized by the absence of oxalate decarboxylase activity did not introduce a one-carbon requirement. The presence and physiological significance of glycine decarboxylase activity in Saccharomyces are thus inferred.