Two different Swi5-containing protein complexes are involved in mating-type switching and recombination repair in fission yeast

Homologous recombination is an important biological process that occurs in all organisms and facilitates genome rearrangements and repair of DNA double-strand breaks. Eukaryotic Rad51 proteins (Rad51sp or Rhp51 in fission yeast) are functional and structural homologs of bacterial RecA protein, an evolutionarily conserved protein that plays a key role in homologous pairing and strand exchange between homologous DNA molecules in vitro. Here we show that the fission yeast swi5+ gene, which was originally identified as a gene required for normal mating-type switching, encodes a protein conserved among eukaryotes and is involved in a previously uncharacterized Rhp51 (Rad51sp)-dependent recombination repair pathway that does not require the Rhp55/57 (Rad55/57sp) function. Protein interactions with both Swi5 and Rhp51 were found to be mediated by a domain common to Swi2 and Sfr1 (Swi five-dependent recombination repair protein 1, a previously uncharacterized protein with sequence similarity to the C-terminal part of Swi2). Genetic epistasis analyses suggest that the Swi5-Sfr1-Rhp51 interactions function specifically in DNA recombination repair, whereas the Swi5-Swi2-Rhp51 interactions may function, together with chromodomain protein Swi6 (HP1 homolog), in mating-type switching.     

Expression of a cDNA derived from the yeast killer preprotoxin gene: implications for processing and immunity.

The type I killer strains of Saccharomyces cerevisiae secrete a dimeric 19-kDa protein that kills sensitive cells by disrupting cytoplasmic membrane function. This toxin is encoded by the double-stranded RNA plasmid M1-dsRNA, which also determines specific immunity to toxin. A preprotoxin, the 35-kDA in vitro translation product of denatured M1-dsRNA, is presumed to be the primary in vivo gene product. To facilitate studies on preprotoxin structure and maturation, we have inserted a partial cDNA copy of M1-dsRNA into the yeast vector p1A1, bringing it under control of the phosphate-repressible PHO5 promoter. This in-frame gene fusion encodes all of the preprotoxin sequence except for its N-terminal secretion leader, which is replaced by the leader sequence of PHO5. Transformation of sensitive yeast strains lacking M1-dsRNA with such fusion plasmids converts them to phosphate-repressible, immune killers, demonstrating that both toxin and immunity determinants are contained within the preprotoxin molecule. L-1-Tosylamido-2-phenylethyl chloromethyl ketone retards glycosylation of preprotoxin to toxin, facilitating size comparisons and indicating that processing of the normal precursor involves three glycosylation events but does not involve cotranslational leader peptidase action. In contrast, the PHO5 leader is apparently removed from the fusion preprotoxin.     

GCR1 of Saccharomyces cerevisiae encodes a DNA binding protein whose binding is abolished by mutations in the CTTCC sequence motif.

In Saccharomyces cerevisiae, glycolysis enzymes constitute 30-60% of the soluble protein. GCR1 gene function is required for high-level glycolytic gene expression. In gcr1 mutant strains the levels of most glycolytic enzymes are between 2% and 10% of wild type. Binding sites for the global regulatory protein known as repressor activator protein 1 (RAP1)/general regulatory factor 1 (GRF1)/translation upstream factor (TUF) are found in close proximity to one or more CTTCC sequence motifs in the controlling region of GCR1-dependent genes. RAP1/GRF1/TUF-binding sites are known to be essential elements of upstream activating sequences that control expression of many glycolytic genes. In this report, I demonstrate that GCR1 encodes a DNA binding protein whose ability to bind DNA is dependent on the CTTCC sequence motif. This finding, in addition to the work of others, suggests that the GCR1 gene product and the RAP1/GRF1/TUF gene product act in concert to mediate high-level glycolytic gene expression.     

Isolation of an activator-dependent, promoter-specific chromatin remodeling factor

Repressed PHO5 gene chromatin, isolated from yeast in the native state, was remodeled by yeast extract in a gene activator-dependent, ATP-dependent manner. The product of the reaction bore the hallmark of the process in vivo, the selective removal of promoter nucleosomes, without effect on open reading frame nucleosomes. Fractionation of the extract identified a single protein, chromodomain helicase DNA binding protein 1 (Chd1), capable of the remodeling activity. Deletion of the CHD1 gene in an isw1Δ pho80Δ strain abolished PHO5 gene expression, demonstrating the relevance of the remodeling reaction in vitro to the process in vivo.     

Translation in Saccharomyces cerevisiae: initiation factor 4A-dependent cell-free system.

Yeast Saccharomyces cerevisiae genes TIF1 and TIF2 (translation initiation factor) encode a protein tentatively called translation initiation factor (Tif) due to the similarity of its amino acid sequence and its molecular weight to mammalian eukaryotic initiation factor 4A. To clarify whether Tif is involved in translation, we produced an affinity-purified anti-Tif antibody by using Tif isolated from a Tif-overproducing yeast strain as immunogen and an Escherichia coli strain expressing Tif from an expression vector to provide the extract for affinity purification of the antibody. By using chromatographic procedures and the affinity-purified anti-Tif antibody as probe to identify Tif-containing fractions, we purified Tif from wild-type yeast cells. When yeast cells containing the only TIF1 gene on a plasmid under the control of the galactose-inducible CYC1-GAL10 promoter were grown in medium containing glucose as the carbon source, the production of Tif was shut off and growth was arrested. Lysates made from these cells were inactive in in vitro translation. Addition of Tif to these lysates restored in vitro protein synthesis. These results show that Tif is a translation factor, the yeast homologue of mammalian translation initiation factor 4A.     

In vitro regulation of a SIN3-dependent DNA-binding activity by stimulatory and inhibitory factors.

The yeast SIN3 gene (also known as SDII, is a known negative regulator of the yeast HO gene. A DNA-binding activity, called SDP1, which binds to the HO promoter, is absent in extracts prepared from sin3 mutants and has been proposed to function as a repressor. We show that SIN3 does not encode SDP1 and that SDP1 DNA-binding activity is modulated in vitro by two factors, an inhibitory factor, I-SDP1, and a stimulatory factor, S-SDP1. I-SDP1 acts as an in vitro inhibitor of the SDP1 DNA-binding activity. Restoration of the DNA-binding activity is achieved by inclusion of a stimulatory factor, S-SDP1, which copurifies with the SIN3 protein. SDP1 DNA-binding activity was restored by treating a protein fraction containing SDP1 and I-SDP1 with the dissociating agent formamide.