Localization of a cruciform cutting endonuclease to yeast mitochondria

We have found a cruciform cutting endonuclease in the yeast, Saccharomyces cerevisiae, which localizes to the mitochondria. This activity apparently is associated with the mitochondrial inner membrane since the activity is not released into solution by osmolysis, in contrast to the matrix enzyme, isocitrate dehydrogenase. The cruciform cutting activity appears to be encoded by CCE1. This gene has been shown to encode one of the major cruciform cutting endonucleases present in a yeast cell. In ccel strains, which lack CCE1 endonuclease activity, the mitochondrial cruciform cutting endonucleolytic activity is also absent. Since CCE1 is allelic to MGT1, a gene required for the highly biased transmission of petite mitochondrial DNA in crosses between ⁺ and hypersuppressive ^– cells, it seems likely that the CCE1 endonuclease functions within mitochondria.     

Identification and characterization of genes and mutants for an N-terminal acetyltransferase from yeast.

A gene from Saccharomyces cerevisiae has been mapped, cloned, sequenced and shown to encode a catalytic subunit of an N-terminal acetyltransferase. Regions of this gene, NAT1, and the chloramphenicol acetyltransferase genes of bacteria have limited but significant homology. A nat1 null mutant is viable but exhibits a variety of phenotypes, including reduced acetyltransferase activity, derepression of a silent mating type locus (HML) and failure to enter G0. All these phenotypes are identical to those of a previously characterized mutant, ard1. NAT1 and ARD1 are distinct genes that encode proteins with no obvious similarity. Concomitant overexpression of both NAT1 and ARD1 in yeast causes a 20-fold increase in acetyltransferase activity in vitro, whereas overexpression of either NAT1 or ARD1 alone does not raise activity over basal levels. A functional iso-1-cytochrome c protein, which is N-terminally acetylated in a NAT1 strain, is not acetylated in an isogenic nat1 mutant. At least 20 other yeast proteins, including histone H2B, are not N-terminally acetylated in either nat1 or ard1 mutants. These results suggest that NAT1 and ARD1 proteins function together to catalyze the N-terminal acetylation of a subset of yeast proteins.     

Identification and characterization of a gene and protein required for glycosylation in the yeast Golgi

The MNN2 gene of Saccharomyces cerevisiae has been cloned by complementation of the mnn2 mutant phenotype scored by a change in cell surface carbohydrate structure resulting from a lack of alpha 1----2-mannose branching in the outer chain. The gene was subcloned as a 3 kb DNA fragment that integrated at the MNN2 locus, and a gene disruption yielded the mnn2 phenotype. A lacZ-MNN2 gene fusion protein, produced in Escherichia coli, was used to raise a specific antiserum that recognized a 65 kD wild-type yeast protein. This MNN2 gene product lacks N-linked carbohydrate but appears to be an integral membrane protein. Overproduction of MNN2p does not enhance the alpha 1----2-mannosyltransferase activity of yeast cells. The results suggest that MNN2p is a Golgi-associated protein that is involved in mannoprotein sorting rather than glycosylation.     

Proteinase yscD mutants of yeast. Isolation and characterization

Mutants of the yeast Saccharomyces cerevisiae, devoid of proteinase yscD activity, were isolated by screening for the inability of mutagenized cells to hydrolyze Ac-Ala-Ala-Pro-Ala-beta-naphthylamide in situ. One of the selected mutants bears a thermolabile activity pointing to the gene called PRD1 as being the structural gene for proteinase yscD. All mutants isolated fell into one complementation group. The defect segregates 2:2 in meiotic tetrads indicating a single gene mutation, which was shown to be recessive. Diploids heterozygous for PRD1 display gene dosage. The absence of proteinase yscD did not affect mitotic growth under rich or poor growth conditions, neither mating nor ascopore formation. Also growth of mutant cells after a nutritional shift-down was not altered. Inactivation of enzymes tested which are subject to carbon-catabolite inactivation, a process proposed to be of proteolytic nature, is not affected by the absence of proteinase yscD. Protein degradation rates in growing cells, in cells under conditions of differentiation or heat shock, showed no obvious alteration in the absence of proteinase yscD activity. Also inactivation of alpha-factor pheromone was not affected by proteinase yscD absence. Normal growth of mutant cells on glycerol indicates that the enzyme is not involved in any vital event in mitochondrial biogenesis.     

Mak mutants of yeast: mapping and characterization.

Killer strains of Saccharomyces cerevisiae are those carrying a 1.5 x 10(6)-dalton double-stranded (ds) ribonucleic acid (RNA) (M) in virus-like particles and secreting a protein toxin. Most yeast (koller or not) also carry a 3 x 10(6)-dalton dsRNA (L). We have mapped mutations in eight of the chromosomal genes needed for maintaining M (mak genes). The mak genes are widely distributed on the yeast map, with no multigene complexes. We show that mutants defective in these and other mak genes lose M dsRNA, but not L dsRNA. The mak3-1 mutation results in markedly decreased cellular levels of L dsRNA, but mak3-1 stains do not lose L dsRNA completely. Mutation of mak16 results in temperature-sensitive growth, whereas mutations in mak13, mak15, mak17, mak20, mak22, and mak27 result in slow growth at any temperature. No effect of mak mutations on mating, meiosis, sporulation, germination, homothallism, or ultraviolet sensitivity has been found. The specificity of mak mutations is discussed.     

Isolation and characterization of new fission yeast cytokinesis mutants.

Schizosaccharomyces pombe is an excellent organism in which to study cytokinesis as it divides by medial fission using an F-actin contractile ring. To enhance our understanding of the cell division process, a large genetic screen was carried out in which 17 genetic loci essential for cytokinesis were identified, 5 of which are novel. Mutants identifying three genes, rng3(+), rng4(+), and rng5(+), were defective in organizing an actin contractile ring. Four mutants defective in septum deposition, septum initiation defective (sid)1, sid2, sid3, and sid4, were also identified and characterized. Genetic analyses revealed that the sid mutants display strong negative interactions with the previously described septation mutants cdc7-24, cdc11-123, and cdc14-118. The rng5(+), sid2(+), and sid3(+) genes were cloned and shown to encode Myo2p (a myosin heavy chain), a protein kinase related to budding yeast Dbf2p, and Spg1p, a GTP binding protein that is a member of the ras superfamily of GTPases, respectively. The ability of Spg1p to promote septum formation from any point in the cell cycle depends on the activity of Sid4p. In addition, we have characterized a phenotype that has not been described previously in cytokinesis mutants, namely the failure to reorganize actin patches to the medial region of the cell in preparation for septum formation.     

A genetic system for isolation and characterization of TaqI restriction endonuclease mutants

The gene encoding TaqI restriction endonuclease has been subcloned downstream from an inducible phoA promoter. Certain strains of Escherichia coli remain viable when endonuclease is expressed, even in the absence of (protective) methylation. Infecting lambda phage DNA is not restricted in vivo. One E. coli strain, MM294, exhibited a temperature-sensitive phenotype when TaqI endonuclease was induced. This allowed for design of an in vivo plate assay for identification of specially constructed two-codon insertion mutants in the endonuclease gene. These mutants exhibited a wide range of in vitro activities, including wild-type activity, greater activity in low-salt buffer, and sequence-specific nicking activity.     

Expression of a prokaryotic gene in yeast: isolation and characterization of mutants with increased expression

Summary The Escherichia coli Tn9 derived chloramphenicol resistance gene (cam ^r) is functionally expressed in the yeast Saccharomyces cerevisiae. This gene was introduced into yeast cells as part of a hybrid yeast/E. coli shuttle plasmid. A number of plasmid associated yeast mutants overproducing the cam ^r gene product, chloramphenicol acetyltransferase (acetyl-CoA: chloramphenicol 3-0-acetyltransferase, E.C. 2.3.1.28) were isolated. One of the plasmid mutants was analyzed in some detail. Even though this mutant showed a 1,000 fold overproduction of chloramphenicol acetyltransferase in the yeast host the level of RNA complementary to the cam ^r gene was not increased. A deletion of 127 base pairs in the region immediately upstream from the 5 end of the cam ^r gene appeared to be responsible for the up phenotype of this mutant. This mutation affected the expression of the cam ^r gene in E. coli in a down fashion, in contrast to its effect in yeast.     

Isolation and characterization of yeast mutants auxotrophic for 2''-deoxythymidine 5''-monophosphate.

Summary Mutant strains of Saccharomyces cerevisiae auxotrophic for deoxythymidine monophosphate (dTMP) were isolated and characterized. Two distinct classes of auxotrophs were obtained. One class had a simple requirement for dTMP and was analogous to thymine-requiring bacteria. The second class required dTMP, adenine, histidine and methionine and this complex nutritional phenotype was due to defects in folate metabolism. The dTMP-dependent growth of respiratory-competent grande auxotrophs was found to be markedly affected by media composition and carbon source. In the absence of dTMP thymineless death occurred in both mutant classes.     

Isolation and characterization of yeast monomorphic mutants of Candida albicans.

A method was devised for the isolation of yeast monomorphic (LEV) mutants of Candida albicans. By this procedure, about 20 stable yeast-like mutants were isolated after mutagenesis with ethyl methane sulfonate. The growth rate of the mutants in different carbon sources, both fermentable and not, was indistinguishable from that of the parental strain, but they were unable to grow as mycelial forms after application of any of the common effective inducers, i.e., heat shock, pH alterations, proline addition, or use of GlcNAc as the carbon source. Studies performed with one selected strain demonstrated that it had severe alterations in the chemical composition of the cell wall, mainly in the levels of chitin and glucans, and in specific mannoproteins, some of them recognizable by specific polyclonal and monoclonal antibodies. It is suggested that these structural alterations hinder the construction of a normal hyphal wall.     

Characterization of a UV endonuclease gene from the fission yeast Schizosaccharomyces pombe and its bacterial homolog.

From the fission yeast Schizosaccharomyces pombe, a cDNA fragment was isolated, which confers UV resistance on repair deficient Escherichia coli host cells. The cloned cDNA encodes a protein of 68,815 Da, which has a 36.6% identity of amino acid sequence with the previously identified 74 kDa UV endonuclease of the filamentous fungus Neurospora crassa. Analysis of several truncated gene constructs shows that only the C-terminal two thirds region, which has 54% identity of amino acid sequence with the C-terminal region of the Neurospora homolog, is necessary for complementing activity of UV-sensitivity in the E. coli host cells. Purified recombinant protein from E. coli host cells incises both UV-induced cyclobutane pyrimidine dimers and (6-4) photoproducts at the sites immediately 5' to the DNA damage in the same fashion as the Neurospora protein. Furthermore, a bacterial homologous sequence was isolated from Bacillus subtilis and shows a similar complementing activity of UV sensitivity in E. coli host cells, indicating a wide distribution of this alternative excision repair mechanism in life.     

Cloning and characterization of the gene for the yeast cytoplasmic threonyl-tRNA synthetase.

A fragment of DNA from the yeast nuclear gene MST1 that codes for the mitochondrial tRNAThr1 synthetase was used as a probe to screen for other yeast threonyl-tRNA synthetase genes. At low stringency, the MST1 probe hybridizes strongly to a 6.6 kb EcoRI fragment of yeast genomic DNA with the homologous gene and in addition hybridizes more weakly to a smaller 3.6 kb EcoRI fragment with a second threonyl-tRNA synthetase gene (THS1). To clone THS1, a library was constructed by ligation to pUC18 of size selected (3-4.5 kb) EcoRI fragments of genomic DNA. Several clones containing the 3.6 kb EcoRI fragment were isolated. A 2,202 nucleotide long open reading frame corresponding to THS1 has been identified in the cloned fragment of DNA. The predicted protein encoded by THS1 is 38% identical to the E. coli threonyl-tRNA synthetase over the latter's length (642 amino acids) and is 42% identical to the predicted MST1 product over its 462 residues. In situ disruption of the chromosomal copy of THS1 is lethal to the cell, indicating that this gene codes for the cytoplasmic threonyl-tRNA synthetase.     

Identification and isolation of the yeast cytochrome c gene.

The iso-1-cytochrome c gene of yeast has been identified and cloned using a synthetic oligodeoxynucleotide as a hybridization probe. The oligomer d[pT-T-A-G-C-A-G-A-A--C-C-G-G] is complementary to a region near the N terminal coding region of the yeast cyc 1 gene. Of several yeast Eco RI fragments which hybridize to this probe, one is changed in size by a G leads to T mutation which eliminates an Eco RI site within the cyc 1 gene. Both the wild-type and the RI- mutant forms were cloned in lambda gt vectors. Maxam-Gilbert sequencing for 91 nucleotides into the coding region for iso-1-cytochrome c yielded a DNA sequence in perfect correspondence with the known protein sequence.     

Isolation and characterization of salt-sensitive mutants of a salt-tolerant yeast Zygosaccharomyces rouxii

Abstract Twenty salt-sensitive (ss) mutants were isolated from the salt-tolerant yeast Zygosaccharomyces rouxii by treatment with N -methyl- N '-nitro- N -nitrosoguanidine. The mutants were divided into five classes on the basis of their ability to grow in media containing various high concentrations of NaCl. The mutant with the greatest sensitivity to NaCl of all the mutants tested was able to grow very slowly with a longer lag phase in medium containing 2 M NaCl, in contrast to the wild strain which had the capacity to grow in medium containing 3.5 M NaCl. Most of the ss mutants exhibited, to some extent, less tolerance to high concentrations of glucose than the wild strain. It appeared from the characterization of the ss mutants that the following factors are necessary for growth of Z. rouxii in high concentrations of NaCl: (a) the ability to produce glycerol under these conditions; (b) the ability to maintain a defined concentration of glycerol within the cells; (c) the ability to take up glycerol that has leaked into the medium, and to assimilate glycerol; and (d) unknown factor(s).     

An endonuclease with multiple cutting sites, Endo.SceI, initiates genetic recombination at its cutting site in yeast mitochondria.

Endo.SceI is a mitochondrial sequence-specific endonuclease which has multiple cutting sites. In order to examine the possible role of Endo.SceI in homologous recombination, we analyzed the mode of recombination upon mating using antibiotic resistance markers on the mitochondrial genome. The segregation of a marker located very close to one of the Endo.SceI cutting sites showed a disparity (polarized segregation, i.e. gene conversion). This gene conversion depended on the presence of the functional Endo.SceI gene. In vivo cutting of mitochondrial DNA upon mating was detected at the cutting site in the antibiotic marker region, which also depended on the Endo.SceI activity. These results suggest that mitochondrial recombination is induced by cleavage of mitochondrial DNA by this sequence-specific endonuclease. This is the first demonstration that a sequence-specific endonuclease with multiple cutting sites induces genetic recombination.     

Identification and characterization of the gene for neurofibromatosis type 1.

Elucidation of the partial genomic structure and DNA sequence of the gene responsible for neurofibromatosis type 1, and discovery of clues to its function, have led to new opportunities not only for understanding this particular disease process, but also for clarifying signalling pathways involved in cellular growth and differentiation.     

Identification and characterization of the gene for neurofibromatosis type 1.

Elucidation of the partial genomic structure and DNA sequence of the gene that is altered in neurofibromatosis type 1, and the discovery of clues to its function, have opened new opportunities not only for understanding this particular disease process but also for clarifying signal pathways involved in cellular growth and differentiation. (This review is an updated and modified version of a review first published in Current Opinion in Genetics and Development 1991, 1:15-19.)     

Identification and characterization of a Giardia lamblia group-specific gene.

Giardia lamblia consist of heterogeneous isolates that can be divided into at least three groups. Differential screening of a cDNA library with isolate-specific antisera identified a gene which is expressed and found only in Group 3 isolates. This gene, GLORF-C4, is 597 bp in length and predicts a deduced protein of 198 amino acids that is characterized by a polyserine motif. Giardia can also be grouped by their ability to express certain variant-specific surface proteins (VSPs), expression of which is restricted among groups. In Southern blots, probes specific to two VSPs were used to characterize isolates. Failure to detect VSP genes correlated with inability to express the same VSP. Analysis of isolates with these new probes complements and confirms the groupings previously suggested using other criteria. These genetic differences should allow differentiation of isolates and permit the application of basic epidemiological techniques to determine the manner of spread and the presence of animal reservoirs.     

Isolation of cell size mutants of a fission yeast by a new selective method: characterization of mutants and implications for division control mechanisms.

Previously known cell size (wee) mutations of fission yeast suppress the mitotic block caused by a defective cdc25 allele. Some 700 revertants of cdc25-22 were obtained after ultraviolet mutagenesis and selection at the restrictive temperature. Most revertants carried the original cdc25 lesion plus a mutation in or very close to the wee1 gene. Two partial wee1 mutations of a new type were found among the revertants. Two new wee mutations mapping at the cdc2 gene (cdc2-w mutants) were also obtained. The various mutations were examined for their effects on cell division size, their efficiency as cdc25 suppressors, and their dominance relations. Full wee1 mutations were found to suppress cdc25 lesions very efficiently, whereas partial wee1 mutations were poor suppressors. The cdc25 suppression ability of cdc2-w mutations was allele specific for cdc2, suggesting bifunctionality of the gene product. The wee1 mutations were recessive for cdc25 suppression; cdc2-w mutations were dominant. A model is proposed for the genetic control of mitotic timing and cell division size, in which the cdc2+ product is needed and is rate limiting for mitosis. The cdc2+ activity is inhibited by the wee1+ product, whereas the cdc25+ product relieves this inhibition.