The biosynthesis of most amino acids in Saccharomyces cerevisiae is coregulated. Starvation for a single amino acid results in the derepression of amino acid biosynthetic enzymes in many unrelated pathways. This phenomenon, known as general control, is mediated by both positive (GCN) and negative (GCD) regulatory genes. In this paper we describe the identification and characterization of several new regulatory genes for this system, GCN6, GCN7, GCN8, GCN9, and GCDS. A mutation in the negative regulator GCDS was isolated on the basis of its suppression of a gcn2 mutation. The effect of gedS is a posttranscriptional increase in histidine biosynthetic enzyme activity. Suppressors of ged5 which are deficient in derepression were in turn isolated. Eight such mutations, defining four new positive regulatory genes (GCN6 through GCN9), were obtained. These mutations are recessive, confer sensitivity to multiple amino acid analogs, and result in decreased mRNA levels for genes under general control. The GCN6 and GCN7 gene products were shown to be positive regulators for transcription of the GCN4 gene, the most direct-acting positive regulator thus far identified. The interaction of GCN6 and GCN7 with GCN4 is fundamentally different from that of previously isolated GCN genes. It should also be noted that these gen selections gave a completely different nonoverlapping set of mutations from earlier selections which relied on analog sensitivity. Thus, we may have identified a new class of GCN genes which are functionally distinct from GCNI through GCNS.
In Saccharomyces cerevisiae, many amino acid biosynthetic pathways are coregulated by a complex general control system: starvation for a single amino acid results in the derepression of amino acid biosynthetic genes in multiple pathways. Derepression of these genes is mediated by positive (GCN) and negative (GCD) regulatory genes. In this paper we describe the isolation and characterization of a previously unreported negative regulatory gene, GCD3. A gcd3 mutation is recessive to wild type, confers resistance to multiple amino acid analogs, and results in overproduction and partially constitutive elevation of mRNA levels for amino acid biosynthetic genes. Furthermore, a gcd3 mutation can overcome the derepression-deficient phenotype of mutations in the positive regulatory GCN1, GCN2, and GCN3 genes. However, the gcd3 mutation cannot overcome the derepression-deficient phenotype of a gcn4 mutation, suggesting that GCD3 acts as a negative regulator of the important GCN4 gene. Northern blot analysis confirmed this conclusion, in that the steady-state levels of GCN4 mRNA are greatly increased in a gcd3 mutant. Thus, the negative regulatory gene GCD3 plays a central role in derepression of amino acid biosynthetic genes.
Enzyme levels in multiple amino acid biosynthetic pathways in yeast are coregulated. This control is effected largely at the transcriptional level by a number of regulatory genes. We report the isolation and characterization of a new negative regulatory gene, GCD4, for this general control system. GCD4 mutations are recessive and define a single Medelian gene on chromosome III. A gcd4 mutation results in resistance to different amino acid analogs and elevated, but fully inducible, mRNA levels of genes under general control. Epistasis analysis indicates that GCD4 acts more directly than the positive regulators GCN1, GCN2, GCN3 and GCN5, but less directly than GCN4, on the transcription of the amino acid biosynthetic genes. These data imply that GCD4 is a negative regulator of the positive effector, GCN4. Although GCD4 occupies the same position relative to the GCN genes as other GCD genes, it produces a unique phenotype. These results illustrate the diversity of function of negative regulators in general control.
The biosynthesis of most amino acids in Saccharomyces cerevisiae is coregulated. Starvation for a single amino acid results in the derepression of amino acid biosynthetic enzymes in many unrelated pathways. This phenomenon, known as general control, is mediated by both positive (GCN) and negative (GCD) regulatory genes. In this paper we describe the identification and characterization of several new regulatory genes for this system, GCN6, GCN7, GCN8, GCN9, and GCD5. A mutation in the negative regulator GCD5 was isolated on the basis of its suppression of a gcn2 mutation. The effect of gcd5 is a posttranscriptional increase in histidine biosynthetic enzyme activity. Suppressors of gcd5 which are deficient in derepression were in turn isolated. Eight such mutations, defining four new positive regulatory genes (GCN6 through GCN9), were obtained. These mutations are recessive, confer sensitivity to multiple amino acid analogs, and result in decreased mRNA levels for genes under general control. The GCN6 and GCN7 gene products were shown to be positive regulators for transcription of the GCN4 gene, the most direct-acting positive regulator thus far identified. The interaction of GCN6 and GCN7 with GCN4 is fundamentally different from that of previously isolated GCN genes. It should also be noted that these gcn selections gave a completely different nonoverlapping set of mutations from earlier selections which relied on analog sensitivity. Thus, we may have identified a new class of GCN genes which are functionally distinct from GCN1 through GCN5.
In Saccharomyces cerevisiae, many amino acid biosynthetic pathways are coregulated by a complex general control system: starvation for a single amino acid results in the derepression of amino acid biosynthetic genes in multiple pathways. Derepression of these genes is mediated by positive (GCN) and negative (GCD) regulatory genes. In this paper we describe the isolation and characterization of a previously unreported negative regulatory gene, GCD3. A gcd3 mutation is recessive to wild type, confers resistance to multiple amino acid analogs, and results in overproduction and partially constitutive elevation of mRNA levels for amino acid biosynthetic genes. Furthermore, a gcd3 mutation can overcome the derepression-deficient phenotype of mutations in the positive regulatory GCN1, GCN2, and GCN3 genes. However, the gcd3 mutation cannot overcome the derepression-deficient phenotype of a gcn4 mutation, suggesting that GCD3 acts as a negative regulator of the important GCN4 gene. Northern blot analysis confirmed this conclusion, in that the steady-state levels of GCN4 mRNA are greatly increased in a gcd3 mutant. Thus, the negative regulatory gene GCD3 plays a central role in derepression of amino acid biosynthetic genes.
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