Isolation and characterization of SUA5, a novel gene required for normal growth in Saccharomyces cerevisiae.

We have identified the sua5 locus as a suppressor of an aberrant ATG codon located in the leader region of the cyc1 gene. The sua5-1 allele enhances the iso-1-cytochrome c steady state level in the cyc1-1019 mutant from 2% to approximately 60% of normal (Cyc+) and also confers a marked slow growth (Slg-) phenotype. Suppression is not a consequence of altered transcription initiation at the cyc1 locus. The SUA5 wild-type gene was isolated and sequenced, revealing an open reading frame (ORF) encoding a potential protein of 46,537 Da. SUA5 transcript analyses were consistent with expression of the predicted ORF and Sua5 antisera detected a protein with an apparent molecular mass of 44 kDa. SUA5 was mapped to chromosome VII, immediately adjacent to the PMR1 gene. Hybridization analysis revealed the presence of a related gene on chromosome XII. Neither the SUA5 DNA sequence nor deduced amino acid sequence showed homology to any sequences in the data banks. Disruption of SUA5 conferred the same Cyc+ and Slg- phenotypes as the sua5-1 suppressor, which is the result of a missense mutation, encoding a Ser107----Phe replacement. In addition, sua5 null mutants lack cytochrome a.a3 and fail to grow on lactate or glycerol medium. These results define SUA5 as a new gene encoding a novel protein that is necessary for normal cell growth.

cis- and trans-acting suppressors of a translation initiation defect at the cyc1 locus of Saccharomyces cerevisiae.

The cyc1-362 mutant of Saccharomyces cerevisiae is deficient in iso-1-cytochrome c as a consequence of an aberrant ATG codon that initiates a short open reading frame (uORF) in the cyc1 transcribed leader region. We have isolated and characterized functional revertants of cyc1-362 in an effort to define cis- and trans-acting factors that can suppress the effect of the uORF. Genetic and DNA sequence analyses have defined three classes of revertants: (i) those that acquired point mutations in the upstream ATG (uATG), restoring iso-1-cytochrome c to its normal level; (ii) substitution of the normal A residue at position -1 relative to the uATG by either C or T, enhancing iso-1-cytochrome c production from approximately 2% to 6% (C) or 10% (T) of normal, indicating that the nucleotide immediately preceding the initiator codon can affect the efficiency of AUG start codon recognition and that purines are preferred over pyrimidines at this site; and (iii) extragenic suppressors that enhance iso-1-cytochrome c expression to 10-40% of normal while retaining the uATG. These suppressors are represented by five different genes, designated sua1-sua4 and sua6. In contrast to the previously described sua7 and sua8 suppressors, they do not compensate for the uATG by affecting cyc1 transcription start site selection. Potential suppressor mechanisms are discussed.

Extragenic suppressors of a translation initiation defect in the cyc1 gene of Saccharomyces cerevisiae.

The cycl-362 allele contains a point mutation that generates an aberrant AUG codon upstream of the normal CYC1 translation initiation codon. Mutants containing this allele express only about 2% of normal iso-1-cytochrome c, presumably due to translation initiation at the upstream AUG, termination at a UAA sequence six codons downstream, and failure to reinitiate at the normal AUG codon two nucleotides later. Both intragenic and extragenic revertants of cycl-362, expressing elevated levels of iso-1-cytochrome c, have been isolated simply by selecting for growth on lactate medium. Here we describe an improved method for isolating and readily distinguishing cis- from trans-acting suppressors of the upstream AUG. Eight different genes, designated sua1-sua8, are represented in our current collection of extragenic suppressors; all are recessive and enhance iso-1-cytochrome c levels to 10-60% of normal. None of the sua genes is allelic to SUI2 or sui3, which encode eIF-2 alpha and eIF-2 beta, respectively, or to SUI1. Many of the suppressors exhibit pleiotropic phenotypes, including slow growth, cold (16 degrees C) and heat (37 degrees C) sensitivity. These phenotypes have been exploited to clone the SUA5, SUA7 and SUA8 genes, which are presently being characterized. The structure of cyc1-362 and the number of sua genes already uncovered suggest that the SUA genes are likely to encode factors affecting several different cellular processes, including translation initiation, mRNA stability and possibly transcription start site selection.

The Kluyveromyces gene encoding the general transcription factor IIB: structural analysis and expression in Saccharomyces cerevisiae.

The Kluyveromyces lactis gene encoding the general transcription factor IIB (TFIIB) was isolated from a genomic library by complementation of the cold-sensitive phenotype conferred by a mutation in the SUA7 gene, which encodes TFIIB in Saccharomyces cerevisiae. DNA sequence analysis of the KI-SUA7 gene revealed a 357 amino acid open reading frame that is 67% identical (81% overall similarity) to S. cerevisiae TFIIB. Comparison with other eukaryotic TFIIBs indicated that the most highly conserved sequence is located adjacent to the Zn-finger motif near the N-terminus. A plasmid shuffle system was used to replace the essential Sc-SUA7 gene with KI-SUA7 in S.cerevisiae. The resulting strain was viable and phenotypically indistinguishable from the normal strain. However, transcription start site selection at the ADH1 locus, shown previously to be affected by mutations in Sc-SUA7, was affected by K.lactis TFIIB. This result provides further evidence that TFIIB is a principal determinant of start site selection in yeast.

The Dr1/DRAP1 heterodimer is a global repressor of transcription in vivo.

A general repressor extensively studied in vitro is the human Dr1/DRAP1 heterodimeric complex. To elucidate the function of Dr1 and DRAP1 in vivo, the yeast Saccharomyces cerevisiae Dr1/DRAP1 repressor complex was identified. The repressor complex is encoded by two essential genes, designated YDR1 and BUR6. The inviability associated with deletion of the yeast genes can be overcome by expressing the human genes. However, the human corepressor DRAP1 functions in yeast only when human Dr1 is coexpressed. The yDr1/Bur6 complex represses transcription in vitro in a reconstituted RNA polymerase II transcription system. Repression of transcription could be overcome by increasing the concentration of TATA-element binding protein (TBP). Consistent with the in vitro results, overexpression of YDR1 in vivo resulted in decreased mRNA accumulation. Furthermore, YDR1 overexpression impaired cell growth, an effect that could be rescued by overexpression of TBP. In agreement with our previous studies in vitro, we found that overexpression of Dr1 in vivo also affected the accumulation of RNA polymerase III transcripts, but not of RNA polymerase I transcripts. Our results demonstrate that Dr1 functions as a repressor of transcription in vivo and, moreover, directly targets TBP, a global regulator of transcription.

Characterization of sua7 mutations defines a domain of TFIIB involved in transcription start site selection in yeast.

The SUA7 gene of Saccharomyces cerevisiae encodes the general transcription factor TFIIB. SUA7 was identified based on the ability of mutations at this locus to shift transcription start site selection at the cyc1 gene downstream of normal. Here, we report the nature of these mutations; the sua7-1 and sua7-2 alleles encode identical E62K replacements, and sua7-3 encodes an R78C replacement. Both Glu-62 and Arg-78 are phylogenetically invariant and occur within the most highly conserved region of TFIIB, immediately distal to a zinc finger motif. A double E62K,R78C mutant was constructed and exhibited the same phenotypes associated with the single mutants, including cold sensitivity and altered start site selection, suggesting that Glu-62 and Arg-78 are functionally related. This observation, and the opposite charge of the 2 residues, suggested that Glu-62 and Arg-78 might interact to form a salt bridge. This was tested by constructing reciprocal E62R and R78E replacements. The E62R mutant is phenotypically identical to the E62K mutant, whereas the R78E mutant is inviable. However, an E62R,R78E double mutant was not only viable but is phenotypically similar to the single mutants. These results define the highly conserved sequence adjacent to the zinc finger of TFIIB as a critical determinant of start site selection and suggest that an Glu-62-Arg-78 salt bridge is an important structural element of that domain.

Mutation in PMR1, a Ca(2+)-ATPase in Golgi, confers salt tolerance in Saccharomyces cerevisiae by inducing expression of PMR2, an Na(+)-ATPase in plasma membrane.

Sodium tolerance in yeast is enhanced by continuous activation of calcineurin, a Ca(2+)/calmodulin-dependent protein phosphatase that is required for modulation of the Na(+) efflux mechanism. We isolated several salt-tolerant mutations with the treatment of ethylmethane sulfonate under high salt stress. One of the mutations was mapped in the PMR1 gene. Pmr1p, the P-type Ca(2+)-ATPase in the Golgi apparatus, regulates a cytosolic Ca(2+) level in various responses. Cytosolic Ca(2+) concentration in the pmr1 mutant is highly maintained, and thus calcineurin is activated continuously. The treatment of FK506, a specific inhibitor of calcineurin, abolishes the salt-tolerant phenotype of the pmr1 mutant. Activated calcineurin induces the expression of PMR2, encoding the P-type Na(+)-ATPase, through the specific transcription factor, Tcn1p/Crz1p. Also, expression of the PMR2::lacZ reporter gene in the pmr1 mutant was higher than that in wild type. We propose that the pmr1 mutation confers salt tolerance through continuous activation of calcineurin and that Pmr1p might act as a major Ca(2+)-ATPase under high salt stress.