Michael Hampsey

The yeast SUA7 gene encodes a homolog of human transcription factor TFIIB and is required for normal start site selection in vivo

Mutations in the Saccharomyces cerevisiae SUA7 gene were isolated as suppressors of an aberrant ATG translation initiation codon in the leader region of the cyc1 gene. Molecular and genetic analysis of the cloned SUA7 gene demonstrated that SUA7 is a single copy, essential gene encoding a basic protein (calculated Mr of 38,142) that is homologous to human transcription factor TFIIB. Analysis of cyc1 transcripts from sua7 strains revealed that suppression is a consequence of diminished transcription initiation at the normal start sites in favor of initiation at downstream sites, including a major site between the aberrant and normal ATG start codons. A similar effect was found at the ADH1 locus, establishing that this effect is not cyc1 gene-specific. Thus, SUA7 encodes a yeast TFIIB homolog and functions in transcription start site selection.

Synthetic enhancement of a TFIIB defect by a mutation in SSU72, an essential yeast gene encoding a novel protein that affects transcription start site selection in vivo.

An ssu72 mutant of Saccharomyces cerevisiae was identified as an enhancer of a TFIIB defect (sua7-1) that confers both a cold-sensitive growth defect and a downstream shift in transcription start site selection. The ssu72-1 allele did not affect cold sensitivity but, in combination with sua7-1, created a heat-sensitive phenotype. Moreover, start site selection at the ADH1 gene was dramatically shifted further downstream of the normal sites. Both of these effects could be rescued by either SUA7 or SSU72, thereby defining a functional relationship between the two genes. SSU72 is a single-copy, essential gene encoding a novel protein of 206 amino acids. The ssu72-1 allele is the result of a 30-bp duplication creating a sequence encoding a Cys-X2-Cys-X6-Cys-X2-Cys zinc binding motif near the N terminus of Ssu72p. Mutational analysis demonstrated that the N terminus of Ssu72p is essential for function and that cysteine residues in both the normal and mutant proteins are critical. We discuss the possibility that the potential zinc binding motif of Ssu72 facilitates assembly of the transcription preinitiation complex and that this effect is important for accurate start site selection in vivo.

The sua8 suppressors of Saccharomyces cerevisiae encode replacements of conserved residues within the largest subunit of RNA polymerase II and affect transcription start site selection similarly to sua7 (TFIIB) mutations.

Mutations in the Saccharomyces cerevisiae sua8 gene were found to be suppressors of an aberrant ATG translation initiation codon in the leader region of the cyc1 gene. Analysis of cyc1 transcripts from sua8 mutants revealed that suppression is a consequence of diminished transcription initiation at the normal start sites in favor of initiation at downstream sites, including a site between the aberrant and normal ATG start codons. This effect is not cyc1 gene specific since initiation at other genes, including ADH1, CYC7, and HIS4, was similarly affected, although initiation at HIS3 and SPT15 was unaffected. The SUA8 gene was cloned and partially sequenced, revealing identity to RPB1, which encodes the largest subunit of RNA polymerase II. The sua8 suppressors are the result of single amino acid replacements of highly conserved residues. Three replacements were found either within or immediately preceding homology block D, and a fourth was found adjacent to homology block H, indicating that these regions play a role in defining start sites in vivo. Nearly identical effects on start site selection were observed for sua7 suppressors, which encode altered forms of TFIIB. Synthetic lethality was associated with double sua7 sua8 suppressor mutations, and recessive sua7 mutants failed to fully complement recessive sua8 mutants in heterozygous diploids (nonallelic noncomplementation). These data indicate that the largest subunit of RNA polymerase II and TFIIB are important determinants of transcription start site selection in S. cerevisiae and suggest that this function might be conferred by interaction between these two proteins.

Genetic analysis of yeast iso-1-cytochrome c structural requirements: suppression of Gly6 replacements by an Asn52----Ile replacement.

Gly6 (vertebrate numbering system) is an evolutionarily invariant amino acid located in an electron-dense region of cytochrome c. Serine, cysteine, and aspartic acid replacements of Gly6 abolished yeast iso-1-cytochrome c function, presumably by destabilizing the mature forms of the altered proteins (1). Here we report that genetic reversion analysis of these mutants has uncovered a single base-pair substitution, encoding an Asn52----Ile replacement, that suppresses all three position 6 defects, as well as a Gly6....Gly29----Ser6....Ser29 double replacement. In each case the suppressor restored at least partial function to the altered iso-1-cytochromes c, with the Sera6....Ile52 protein being nearly indistinguishable from the normal protein. The suppressor also affected otherwise normal iso-1-cytochrome c, enhancing the in vivo amount of the protein by about 20%. While this work was in progress, Das et al. (1989, Proc. Natl. Acad. Sci. USA 86, 496-499) uncovered Ile52 as a suppressor of single Gly29 and His33 replacements in iso-1-cytochrome c. The ability of Ile52 to suppress amino acid replacements at three different sites, and its effect in isolation from the primary mutations, defines Ile52 as a global suppressor of specific iso-1-cytochrome c structural defects. These data suggest that position 52 plays a critical role in the folding and/or stability of iso-1-cytochrome c.