We identified the phhl ÷ gene that encodes a MAP kinase as the effector of Wisl MAP kinase kinase in fission yeast, which is highly homologous with HOG1 of S. cerevisiae. Heterothalic phhl dsiruptant is phenotypically indistinguishable from wisl deletion mutant, both displaying the same extent of partial sterility and enhanced sensitivity to a variety of stress. In phhl disruptant, nitrogen starvation-induced expression of stell +, a key controller of sexual differentiation, is markedly diminished. Ectopic expression of stell ÷ effectively restores fertility, but not stress resistance, to the phhl disruptant. These data show that stress signal, mediated by a MAP kinase, is required for efficient start of sexual differentiation.
The C31 subunit belongs to a complex of three subunits (C31, C34 and C82) specific to RNA polymerase (pol) III that have no counterparts in other RNA polymerases. This complex is thought to play a role in transcription initiation since it interacts with the general initiation factor TFIIIB via subunit C34. We have obtained a conditional mutation of pol III by partially deleting the acidic C‐terminus of the C31 subunit. A Saccharomyces cerevisiae strain carrying this truncated C31 subunit is impaired in in vivo transcription of tRNAs and failed to grow at 37 degrees C. This conditional growth phenotype was suppressed by overexpression of the gene coding for the largest subunit of pol III (C160), suggesting an interaction between C160 and C31. The mutant pol III enzyme transcribed non‐specific templates at wild‐type rates in vitro, but was impaired in its capacity to transcribe tRNA genes in the presence of general initiation factors. Transcription initiation, but not termination or recycling of the enzyme, was affected in the mutant, suggesting that it could be altered on interaction with initiation factors or on the formation of the open complex. Interestingly, the C‐terminal deletion was also suppressed by a high gene dosage of the DED1 gene encoding a putative helicase.
A 15.1 kb fragment of the yeast genome was allocated to the centromeric region of chromosome XIV by genetic mapping. It contained six bona fide genes, RPC34, FUN34, CIT1 (Suissa et al., 1984), RLP7, PET8 and MRP7 (Fearon and Mason, 1988) and two large open reading frames, DOM34 and TOM34. RPC34 and RLP7 define strictly essential functions, whereas CIT1, PET8 and MRP7 encode mitochondrial proteins. The PET8 product belongs to a family of mitochondrial carrier proteins. FUN34 encodes a putative transmembraneous protein that is non-essential as judged from the normal growth of the fun34-::LUK18(URA3) allele even on respirable substrates. TOM34 codes for a putative RNA binding protein, and DOM34 defines a hypothetical polypeptide of 35 kDa, with no significant homology to known proteins. The region under study also contains two divergently transcribed tDNAs, separated only by a chimeric transposable element. This tight tDNA linkage pattern is commonly encountered in yeast, and a general hypothesis is proposed for its emergence on the Saccharomyces cerevisiae genome. RPC34, RLP7, PET8 and MRP7 are unique on the yeast genome, but the remaining genes belong to an extant centromeric duplication between chromosome III and XIV.
The wis1 protein kinase of Schizosaccharomyces pombe is a member of the MAP kinase kinase family. Loss of wis1 function has previously been reported to lead to a delay in the G2-mitosis transition, loss of viability in stationary phase, and hypersensitivity to osmotic shock. It acts at least in part by activating the MAP kinase homologue sty1; loss-of-function sty1 mutants share many phenotypes with wis1 deletion mutants. We show here that, in addition, loss of wis1 function leads to defective conjugation, and to suppression of the hyperconjugation phenotype of the pat1-114 mutation. Consistent with this, the induction of the mei2 gene, which is normally induced by nitrogen starvation, is defective in wis1 mutants. In wild-type cells, nitrogen starvation leads to mei2 induction through a fall in intracellular cyclic AMP (cAMP) level and activity of the cAMP-dependent protein kinase. We show here that wis1 function is required for mei2 induction following nitrogen starvation. Expression of the fbp1 gene is negatively regulated by cAMP in response to glucose limitation: induction of fbp1 also requires wis1 and sty1 function. Loss of wis1 is epistatic over increased fbp1 expression brought about by loss of adenylate cyclase (git2/cyr1) or cAMP-dependent protein kinase (pka1) function. These observations can be explained by a model in which the pka1 pathway negatively regulates the wis1 pathway, or the two pathways might act independently on downstream targets. The latter explanation is supported, at least as regards regulation of cell division, by the observation that loss of function of the regulatory subunit of the cAMP-dependent protein kinase (cgs1) brings about a modest increase in cell length at division in both wis1+ and wis1 delta genetic backgrounds.
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