Purification and characterization of the Pac1 ribonuclease of Schizosaccharomyces pombe.

The pac1+ gene of the fission yeast Schizosaccharomyces pombe is essential for viability and its overexpression induces sterility and suppresses mutations in the pat1+ and snm1+ genes. The pac1+ gene encodes a protein that is structurally similar to RNase III from Escherichia coli, but its normal function is unknown. We report here the purification and characterization of the Pac1 protein after overexpression in E. coli. The purified protein is a highly active, double-strand-specific endoribonuclease that converts long double-stranded RNAs into short oligonucleotides and also cleaves a small hairpin RNA substrate. The Pac1 RNase is inhibited by a variety of double- and single-stranded polynucleotides, but polycytidylic acid greatly enhances activity and also promotes cleavage specificity. The Pac1 RNase produces 5'-phosphate termini and requires Mg2+; Mn2+ supports activity but causes a loss of cleavage specificity. Optimal activity was obtained at pH 8.5, at low ionic strength, in the presence of a reducing agent. The enzyme is relatively insensitive to N-ethylmaleimide but is strongly inhibited by ethidium bromide and vanadyl ribonucleoside complexes. The properties of the Pac1 RNase support the hypothesis that it is a eukaryotic homolog of RNase III.     

Characterization of the Schizosaccharomyces pombe ral2 gene implicated in activation of the ras1 gene product.

Mutations in the Schizosaccharomyces pombe ral2 gene cause a phenotype indistinguishable from that of the ras1-defective mutant. Using cloned ral2 DNA, we disrupted the chromosomal gene. The disruptants showed the same phenotype as the original ral2 isolates, i.e., they had spherical cells, had no detectable mating activity, and exhibited no response to the mating pheromone, but their vegetative growth was apparently normal. Sequence analysis of the ral2 gene suggests that it encodes a polypeptide of 611 amino acid residues whose predicted amino acid sequence shows no strong homology to any known protein. Either multiple copies or even a single copy of the ras1Val-17 allele, which is an activated form of ras1, restored rodlike cell morphology and ability to respond to the mating factor to ral2 mutants. These results suggest that the ral2 and ras1 gene products interact intimately and that the ral2 gene product is involved in activation of the ras1 protein in S. pombe.     

Rapamycin specifically interferes with the developmental response of fission yeast to starvation.

Rapamycin is a microbial macrolide which belongs to a family of immunosuppressive drugs that suppress the immune system by blocking stages of signal transduction in T lymphocytes. In Saccharomyces cerevisiae cells, as in T lymphocytes, rapamycin inhibits growth and cells become arrested at the G1 stage of the cell cycle. Rapamycin is also an effective antifungal agent, affecting the growth of yeast and filamentous fungi. Unexpectedly, we observed that rapamycin has no apparent effect on the vegetative growth of Schizosaccharomyces pombe. Instead, the drug becomes effective only when cells experience starvation. Under such conditions, homothallic wild-type cells will normally mate and undergo sporulation. In the presence of rapamycin, this sexual development process is strongly inhibited and cells adopt an alternative physiological option and enter stationary phase. Rapamycin strongly inhibits sexual development of haploid cells prior to the stage of sexual conjugation. In contrast, the drug has only a slight inhibitory effect on the sporulation of diploid cells. A genetic approach was applied to identify the signal transduction pathway that is inhibited by rapamycin. The results indicate that either rapamycin did not suppress the derepression of sexual development of strains in which adenylate cyclase was deleted or the cyclic AMP-dependent protein kinase encoded by pka1 was mutated. Nor did rapamycin inhibit the unscheduled meiosis observed in pat1-114 mutants. Overexpression of ras1+, an essential gene for sexual development, did not rescue the sterility of rapamycin-treated cells. However, expression of the activated allele, ras1Val17, antagonized the effect of rapamycin and restored the ability of the cells to respond to mating signals in the presence of the drug. We discuss possible mechanisms for the inhibitory effect of rapamycin on sexual development in S. pombe.     

Schizosaccharomyces pombe sxa1+ and sxa2+ encode putative proteases involved in the mating response.

The Schizosaccharomyces pombe sxa1 and sxa2 mutants showed an exaggerated response to mating pheromones, producing excessively long conjugation tubes and exhibiting mating deficiency. This phenotype was similar to phenotypes of cells bearing an activated allele of ras1, such as ras1Val-17 or ras1Leu-66, and phenotypes of cells defective in gap1. However, genetic evidence suggested that the sxa1 and sxa2 gene products are not directly involved in the Ras1 pathway. The gene products of sxa1 and sxa2, as deduced from their nucleotide sequences, were homologous to aspartyl proteases and serine carboxypeptidases, respectively. The sxa1 gene function was required for efficient mating only in h+ cells, although even disruption of sxa1 did not completely abolish the mating ability. Conversely, the sxa2 gene function was required only in h- cells. Wild-type cells produced a diffusible substance, which may be the sxa2 gene product itself, that could confer fertility to sxa2 mutant cells placed at a distance. These observations are consistent with the possibility that the sxa gene products are involved in degradation or processing of the mating pheromones and that their loss cause a persistent response to the pheromones.     

Sexual reproduction as a response to H2O2 damage in Schizosaccharomyces pombe.

Although sexual reproduction is widespread, its adaptive advantage over asexual reproduction is unclear. One major advantage of sex may be its promotion of recombinational repair of DNA damage during meiosis. This idea predicts that treatment of the asexual form of a facultatively sexual-asexual eucaryote with a DNA-damaging agent may cause it to enter the sexual cycle more frequently. Endogenous hydrogen peroxide is a major natural source of DNA damage. Thus, we treated vegetative cells of Schizosaccharomyces pombe with hydrogen peroxide to test if sexual reproduction increases. Among untreated stationary-phase S. pombe populations the sexual spores produced by meiosis represented about 1% of the total cells. However, treatment of late-exponential-phase vegetative cells with hydrogen peroxide increased the percentage of meiotic spores in the stationary phase by 4- to 18-fold. Oxidative damage therefore induces sexual reproduction in a facultatively sexual organism, a result expected by the hypothesis that sex promotes DNA repair.     

Rescue of the fission yeast snRNA synthesis mutant snm1 by overexpression of the double-strand-specific Pac1 ribonuclease

The Schizosaccharomyces pombe temperature-sensitive mutant snm1 maintains reduced steady-state quantities of the spliceosomal small nuclear RNAs (snRNAs) and the RNA subunit of the tRNA processing enzyme RNase P. We report here the isolation of the pac1 ⁺ gene as a multi-copy suppressor of snm1. The pac1 ⁺ gene was previously identified as a suppressor of the ran1 mutant and by its ability to cause sterility when overexpressed. The pac1 ⁺ gene encodes a double-strand-specific ribonuclease that is similar to RNase III, an RNA processing and turnover enzyme in Escherichia coli. To investigate the essential structural features of the Pac1 RNase, we altered the pac1 ⁺ gene by deletion and point mutation and tested the mutant constructs for their ability to complement the snm1 and ran1 mutants and to cause sterility. These experiments identified four essential amino acids in the Pac1 sequence: glycine 178, glutamic acid 251, and valines 346 and 347. These amino acids are conserved in all RNase III-like proteins. The glycine and glutamic acid residues were previously identified as essential for E. coli RNase III activity. The valines are conserved in an element found in a family of double-stranded RNA binding proteins. Our results support the hypothesis that the Pac1 RNase is an RNase III homolog and suggest a role for the Pac1 RNase in snRNA metabolism.     

Rescue of the fission yeast snRNA synthesis mutant snm1 by overexpression of the double-strand-specific Pac1 ribonuclease

The Schizosaccharomyces pombe temperature-sensitive mutant snm1 maintains reduced steady-state quantities of the spliceosomal small nuclear RNAs (snRNAs) and the RNA subunit of the tRNA processing enzyme RNase P. We report here the isolation of the pac1 ⁺ gene as a multi-copy suppressor of snm1. The pac1 ⁺ gene was previously identified as a suppressor of the ran1 mutant and by its ability to cause sterility when overexpressed. The pac1 ⁺ gene encodes a double-strand-specific ribonuclease that is similar to RNase III, an RNA processing and turnover enzyme in Escherichia coli. To investigate the essential structural features of the Pac1 RNase, we altered the pac1 ⁺ gene by deletion and point mutation and tested the mutant constructs for their ability to complement the snm1 and ran1 mutants and to cause sterility. These experiments identified four essential amino acids in the Pac1 sequence: glycine 178, glutamic acid 251, and valines 346 and 347. These amino acids are conserved in all RNase III-like proteins. The glycine and glutamic acid residues were previously identified as essential for E. coli RNase III activity. The valines are conserved in an element found in a family of double-stranded RNA binding proteins. Our results support the hypothesis that the Pac1 RNase is an RNase III homolog and suggest a role for the Pac1 RNase in snRNA metabolism.     

Meiotically Induced Rec7 and Rec8 Genes of Schizosaccharomyces Pombe

The Schizosaccharomyces pombe rec7 and rec8 genes, which are required for meiotic intragenic recombination but not for mitotic recombination, have been cloned and their DNA sequences determined. Genetic and physical analyses demonstrated that the cloned fragments contained the rec genes rather than rec mutation suppressors. A 1.6-kb DNA fragment contained a functional rec7 gene, and a 2.1-kb fragment contained a functional rec8 gene. The nucleotide sequences of these fragments revealed open reading frames predicting 249 amino acids for the rec7 gene product and 393 amino acids for the rec8 gene product. Northern hybridization analysis showed that both rec gene mRNAs were detectable only at 2-3 hr after induction of meiosis. The absence of these mRNAs in mitosis and their disappearance at 4 hr and later in meiosis suggest that the rec7 and rec8 gene products may be involved primarily in the early steps of meiotic recombination in S. pombe.     

Genes encoding farnesyl cysteine carboxyl methyltransferase in Schizosaccharomyces pombe and Xenopus laevis.

The mam4 mutation of Schizosaccharomyces pombe causes mating deficiency in h- cells but not in h+ cells. h- cells defective in mam4 do not secrete active mating pheromone M-factor. We cloned mam4 by complementation. The mam4 gene encodes a protein of 236 amino acids, with several potential membrane-spanning domains, which is 44% identical with farnesyl cysteine carboxyl methyltransferase encoded by STE14 and required for the modification of a-factor in Saccharomyces cerevisiae. Analysis of membrane fractions revealed that mam4 is responsible for the methyltransferase activity in S. pombe. Cells defective in mam4 produced farnesylated but unmethylated cysteine and small peptides but no intact M-factor. These observations strongly suggest that the mam4 gene product is farnesyl cysteine carboxyl methyltransferase that modifies M-factor. Furthermore, transcomplementation of S. pombe mam4 allowed us to isolate an apparent homolog of mam4 from Xenopus laevis (Xmam4). In addition to its sequence similarity to S. pombe mam4, the product of Xmam4 was shown to have a farnesyl cysteine carboxyl methyltransferase activity in S. pombe cells. The isolation of a vertebrate gene encoding farnesyl cysteine carboxyl methyltransferase opens the way to in-depth studies of the role of methylation in a large body of proteins, including Ras superfamily proteins.