Ty insertions at two loci account for most of the spontaneous antimycin A resistance mutations during growth at 15 degrees C of Saccharomyces cerevisiae strains lacking ADH1.

The mutation rate to antimycin A resistance was determined for strains of Sacchromyces cerevisiae lacking a functional copy of the structural gene for alcohol dehydrogenase I (ADH1). One type of mutation that can cause antimycin A resistance in these strains is insertion of the transposable element Ty 5' to ADH2, the structural gene for the glucose-repressed isozyme of alcohol dehydrogenase, resulting in expression of this gene during growth on glucose. Here we show that after growth at 15 or 20 degrees C on glucose, 30% of the antimycin A resistance mutations are Ty insertions at ADH2 and another 65% of the mutations are Ty insertions at ADH4, a new locus identified and cloned as described in this paper. At 30 degrees C only 6% of the mutations are Ty insertions at either of these two loci. In addition, we show that the transposition rate is lower in mating-incompetent (a/alpha) cells than in either haploid or diploid mating-competent cells. Our results suggest that under certain conditions Ty transposition may be a major cause of spontaneous mutations in S. cerevisiae.     

Ty1 sequence with enhancer and mating-type-dependent regulatory activities.

Some insertion mutations in Saccharomyces cerevisiae activate the expression of adjacent structural genes. The CYC7-H2 mutation is a Ty1 insertion 5' to the iso-2-cytochrome c coding region of CYC7. The Ty1 insertion causes a 20-fold increase in CYC7 expression in a and alpha haploid cell types of S. cerevisiae. This activation is repressed in the a/alpha diploid cell type. Previous computer analysis of the CYC7-H2 Ty1 activator region identified two related sequences with homology both to mammalian enhancers and to a yeast a/alpha control site. A 112-base-pair (bp) DNA fragment encompassing one of these blocks of homology functioned as one component of the Ty1 activator. A 28-bp synthetic oligonucleotide with the wild-type homology block sequence was also functional. A single base pair mutation within the enhancer core of the synthetic 28-bp regulatory element reduced its activation ability to near background amounts. In addition, the 112-bp Ty1 fragment by itself functioned as a target for repression of adjacent gene expression in a/alpha diploid cells.     

Transposable elements associated with constitutive expression of yeast alcohol dehydrogenase II

The yeast structural gene ADR2, coding for the glucose-repressible alcohol dehydrogenase (ADHII), has been isolated by complementation of function in transformed yeast. The chromosomal DNA from nine yeast strains with cis-dominant constitutive mutations (ADR3^c) has been investigated by restriction enzyme analysis, using the cloned ADR2 DNA as a hybridization probe. Seven mutants appear to have insertions of approximately 5.6 kb near the 5′ end of the ADR2-coding region. Four of these insertions have the same restriction pattern as the yeast transposable element Tyl. Two differ from Tyl by the presence of an additional Hind III site, and a seventh insertion differs from Tyl at a number of restriction sites. All are inserted in the same orientation with respect to the structural gene. A DNA fragment containing the ADR2 gene and adjacent sequences from a constitutive mutant has been cloned and shown by heteroduplex analysis to contain an insertion near the 5′ end of the structural gene. The cloned insertion sequence hybridizes to multiple genomic DNA fragments, indicating that it contains a moderately repetitive sequence. Thus it appears that insertion of a transposable element near the 5′ terminus of the structural gene can produce constitutive expression of a normally glucose-repressed enzyme. Such insertions seem to be the most common way of generating cis-dominant constitutive mutations of ADHII.     

Disruption of a Silencer Domain by a Retrotransposon

A galactose-inducible Ty element carrying the HIS3 gene has been used as an insertional mutagen to generate alpha-factor resistant mutants. This collection of Ty-induced mutations includes insertions into the gene for the alpha-factor receptor (STE2), several nonspecific STE genes, and mutations that lead to the expression of the normally silent HML alpha locus. The hml alpha "on" mutations fall into two classes, those that disrupt trans-acting regulators involved in silencing HML alpha and a novel class of mutations that activate HML alpha by insertion at that locus. The hml alpha::Ty "on" mutations illustrate the unusual ability of these retrotransposons to activate genes by overcoming gene silencing mechanisms. The hml alpha::Ty "on" mutations include examples of multimeric Ty arrays. Single Ty and solo delta insertion derivatives of these Ty multimers restore the ability of the silencing mechanism to repress HML alpha.     

Analysis of mutations affecting Ty-mediated gene expression in Saccharomyces cerevisiae

Summary Yeast translocatable, Ty, elements can cause constitutive synthesis of the glucose-repressible alcohol dehydrogenase (ADHII) when inserted upstream from the 5 end of the structural gene, ADR2. These insertion mutations, ADR3 ^c, are unstable and give rise to secondary ADHII^– mutations. The majority of such mutants, adr3, can be attributed to excision of the insertion sequence, leaving behind a single copy of the -sequence which occurs as a direct repeat at the ends of the Ty elements. A few adr3 mutants appear to be generated by DNA-rearrangements in the vicinity of the Ty insertion. The occurrence of recessive mutants, tye, which are unlinked to ADR2 indicates that the constitutive expression of ADR2 caused by the Ty insertions requires the function of trans-acting genes. These results support the idea that regulation of Ty-linked ADR2 is actively mediated by the insertion sequence and is probably not due to a mere disruption of the wild-type controlling site.     

Ethanol formation in adh0 mutants reveals the existence of a novel acetaldehyde-reducing activity in Saccharomyces cerevisiae.

A strain of Saccharomyces cerevisiae has been constructed which is deficient in the four alcohol dehydrogenase (ADH) isozymes known at present. This strain (adh0), being irreversibly mutated in the genes ADH1, ADH3, and ADH4 and carrying a point mutation in the gene ADH2 coding for the glucose-repressible isozyme ADHII, still produces up to one third of the theoretical maximum yield of ethanol in a homofermentative conversion of glucose to ethanol. Analysis of the glucose metabolism of adh0 cells shows that the lack of all known ADH isozymes results in the formation of glycerol as a major fermentation product, accompanied by a significant production of acetaldehyde and acetate. Treatment of glucose-growing adh0 cells with the respiratory-chain inhibitor antimycin A leads to an immediate cessation of ethanol production, demonstrating that ethanol production in adh0 cells is dependent on mitochondrial electron transport. Reduction of acetaldehyde to ethanol in isolated mitochondria could also be demonstrated. This reduction is apparently linked to the oxidation of acetaldehyde to acetate. Preliminary data suggest that this novel type of ethanol formation in S. cerevisiae is associated with the inner mitochondrial membrane.     

Identification of New Genes Involved in the Regulation of Yeast Alcohol Dehydrogenase II

Recessive mutations in two negative control elements, CRE1 and CRE2, have been obtained that allow the glucose-repressible alcohol dehydrogenase (ADHII) of yeast to escape repression by glucose. Both the cre1 and cre2 alleles affected ADHII synthesis irrespective of the allele of the positive effector, ADR1. However, for complete derepression of ADHII synthesis, a wild-type ADR1 gene was required. Neither the cre1 nor cre2 alleles affected the expression of several other glucose-repressible enzymes. A third locus, CCR4, was identified by recessive mutations that suppressed the cre1 and cre2 phenotypes. The ccr4 allele blocked the derepression of ADHII and several other glucose-repressible enzymes, indicating that the CCR4 gene is a positive control element. The ccr4 allele had no effect on the repression of ADHII when it was combined with the ADR1-5c allele, whereas the phenotypically similar ccr1 allele, which partially suppresses ADR1-5c, did not suppress the cre1 or cre2 phenotype. Complementation studies also indicated that ccr1 and snf1 are allelic. A model of ADHII regulation is proposed in which both ADR1 and CCR4 are required for ADHII expression. CRE1 and CRE2 negatively control CCR4, whereas CCR1 is required for ADR1 function.     

Expression of the ROAM mutations in Saccharomyces cerevisiae: involvement of trans-acting regulatory elements and relation with the Ty1 transcription

The regulatory mutations in Saccharomyces cerevisiae designated cargA + Oh, cargB + Oh, and durOh are alterations in the control regions of the respective structural genes. The alteration causing the cargA + Oh mutation has been shown to be an insertion of a Ty1 element in the 5' noncoding region of the CAR1 ( cargA ) locus. All three mutations cause overproduction of their corresponding gene products and belong to the ROAM family of mutations (Regulated Overproducing Allele responding to Mating signals) in yeast. The amount of overproduction in ROAM mutants is determined, at least in part, by signals that control mating functions in yeast. We report the identification of two genetic loci that regulate Oh mutant gene expression but that do not affect mating ability. These loci are defined by the recessive roc mutations ( ROAM mutation control) that reduce the amount of overproduction caused by the cargA + Oh, cargB + Oh, and durOh mutations. RNAs homologous to CAR1 ( cargA ), DUR1 ,2 and Ty1 DNA probes were analyzed by the Northern hybridization technique. In comparison with wild-type strains, cargA + Oh and durOh mutant strains grown on ammonia medium contain increased amounts of CAR1 and DUR1 ,2 RNA. This RNA overproduction is diminished in MATa/MAT alpha diploid strains as well as in haploid strains that also carry the ste7 mutation which prevents mating or that carry either of the roc1 or roc2 mutant alleles. The amount of RNA homologous to Ty1 DNA is also reduced in ste7 , roc1 , and roc2 mutant strains. This reduction is not observed in a strain with the ste5 mutation, which prevents mating but has no effect on overproduction of ROAM mutant gene products.(ABSTRACT TRUNCATED AT 250 WORDS)     

Isolation and characterization of the positive regulatory gene ADR1 from Saccharomyces cerevisiae.

The DNA segments containing the ADR1 gene and a mutant allele, ADR1-5c, have been isolated by complementation of function in Saccharomyces cerevisiae. The ADR1 gene is required for synthesis of the glucose-repressible alcohol dehydrogenase (ADHII) when S. cerevisiae cells are grown on a nonfermentable carbon source, whereas the ADR1-5c allele allows ADHII synthesis even during glucose repression. A plasmid pool consisting of yeast DNA fragments isolated from a strain carrying the ADR1-5c allele was used to transform a strain containing the adr1-1 allele, which prevents ADHII depression. Transformants were isolated which expressed ADHII during glucose repression. A plasmid isolated from one of these transformants was shown to carry the ADR1-5c allele by its ability to integrate at the chromosomal adr1-1 locus. The wild-type ADR1 gene was isolated by colony hybridization, using the cloned ADR1-5c gene as a probe. The ADR1-5c and ADR1 DNA segments were indistinguishable by restriction site mapping. A partial ADR1 phenotype could be conferred by a 1.9-kilobase region, but DNA outside of this region appeared to be necessary for normal activation of ADHII by the ADR1 gene.     

Identification of regulatory regions within the Ty1 transposable element that regulate iso-2-cytochrome c production in the CYC7-H2 yeast mutant.

The CYC7-H2 mutation in the yeast Saccharomyces cerevisiae was caused by insertion of a Ty1 transposable element in front of the iso-2-cytochrome c structural gene, CYC7. The Ty1 insertion places iso-2-cytochrome c production under control of regulatory signals that are normally required for mating functions in yeast cells. We have investigated the regions of the Ty1 insertion that are responsible for the aberrant production of iso-2-cytochrome c in the CYC7-H2 mutant. Five alterations of the CYC7-H2 gene were obtained by specific restriction endonuclease cleavage of the cloned DNA and ligation of appropriate fragments. The CYC7+, CYC7-H2, and modified CYC7-H2 genes were each inserted into the yeast vector YIp5 and used to transform a cytochrome c-deficient yeast strain. Expression and regulation of each allele integrated at the CYC7 locus have been compared in vivo by determination of the amount of iso-2-cytochrome c produced. These results show that distal regions of the Ty1 element are not essential for the CYC7-H2 overproducing phenotype. In contrast, alterations in the vicinity of the proximal Ty1 junction abolish the CYC7-H2 expression and give rise to different phenotypes.     

Mutations Affecting Ty-Mediated Expression of the HIS4 Gene of SACCHAROMYCES CEREVISIAE

We have identified mutations in seven unlinked genes (SPT genes) that affect the phenotypes of Ty and δ insertion mutations in the 5' noncoding region of the HIS4 gene of S. cerevisiae. Spt mutants were selected for suppression of his4-912δ, a solo δ derivative of Ty912. Other Ty and δ insertions at HIS4 are suppressed by mutations in some but not all of the SPT genes. Only spt4 suppresses a non-Ty insertion at HIS4. In addition to their effects on Ty and δ insertions, mutations in several SPT genes show defects in general cellular functions—mating. DNA repair and growth.