Saccharomyces cerevisiae translational activator Cbs2p is associated with mitochondrial ribosomes

A characteristic feature of the mitochondrial expression system in Saccharomyces cerevisiae is the requirement for gene-specific translational activator proteins. Translation of mitochondrial apocytochrome b mRNA requires the nucleus-encoded proteins Cbs1p and Cbs2p. These proteins are thought to tether cytochrome b mRNA to the mitochondrial inner membrane via binding to the 5 untranslated mRNA leader. Here, we demonstrate by the use of affinity chromatography and coimmunoprecipitation that Cbs2p interacts with the mitoribosomes. We further provide evidence that the C-terminus of Cbs2p is important for ribosome association, while the N-terminal portion is essential for the formation of homomeric structures.     

Control of the G1-G0 transition and G0 protein synthesis by cyclic AMP in Saccharomyces cerevisiae

Summary When the cyr1-1 cells of Saccharomyces cerevisiae, which require cyclic AMP (cAMP) for growth, were starved for cAMP, cell division was arrested at the G1 state of the mitotic cell cycle and the cells entered the resting state (G0) also observed in wild-type cells transferred to sulfur-free medium. The level of cAMP in wild-type cells decreased rapidly when the cells were starved for sulfur and subsequently increased following its addition. The cyr1-1 cells starved for cAMP preferentially synthesized nine G0 proteins. The synthesis of these G0 proteins in the sulfur-starved cells was repressed by the addition of cAMP. The RAS2 ^val19 or bcy1 cells, which produced an elevated level of cAMP or cAMP-independent protein kinase, did not synthesize the G0 proteins under the sulfur-starved condition. The results suggest that cAMP plays a role in the transition between the proliferating state and G0 state.     

Organization of assembly factors Cbp3p and Cbp4p and their effect on bc 1 complex assembly in Saccharomyces cerevisiae

The bc₁ complex (complex III) of Saccharomyces cerevisae is composed of ten subunits that are assembled in the inner mitochondrial membrane. Cbp3p and Cbp4p are two mitochondrial proteins which are postulated to act as chaperones in bc₁ complex formation. Here, we show by blue native PAGE that cbp3 and cbp4 mutants are disturbed in complex III assembly and accumulate intermediate-sized forms of the complex. Moreover, deletion of CBP3 interferes with the formation of complex III/IV supracomplexes. Our studies show that Cbp3p and Cbp4p interact and are present in high-molecular-weight complexes, some of which might represent intermediates of complex III assembly. Overexpression of Cbp4p cannot substitute for the function of Cbp3p, but high-level expression of Cbp3p can partially compensate for the lack of Cbp4p. The finding that mitochondria of cbp3 and cbp4 mutants exhibit a wild-type lipid composition favors the idea that Cbp3p and Cbp4p are specific assembly factors for complex III rather than components of the mitochondrial lipid metabolism.     

The STA2 and MEL1 genes of Saccharomyces cerevisiae are idiomorphic

Summary The STA2 (glucoamylase) gene of Saccharomyces cerevisiae has been mapped close to the end of the left arm of chromosome II. Meiotic analysis of a cross between a haploid strain containing STA2, and another strain carrying the melibiase gene MEL1 (which is known to be at the end of the left arm of chromosome II) produced parental ditype tetrads only. Since there is no significant DNA sequence similarity between the STA2 and MEL1 genes, or their respective flanking regions, we conclude that these two genes are carried by separate non-hybridizing sequences of chromosomal DNA, either of which can reside at the end of the left arm of chromosome II. By analogy with the mating-type locus of Neurospora crassa, we suggest that the STA2 and MEL1 genes are idiomorphs with respect to one another.     

Palindrome content of the yeast Saccharomyces cerevisiae genome

Palindromic sequences are important DNA motifs involved in the regulation of different cellular processes, but are also a potential source of genetic instability. In order to initiate a systematic study of palindromes at the whole genome level, we developed a computer program that can identify, locate and count palindromes in a given sequence in a strictly defined way. All palindromes, defined as identical inverted repeats without spacer DNA, can be analyzed and sorted according to their size, frequency, GC content or alphabetically. This program was then used to prepare a catalog of all palindromes present in the chromosomal DNA of the yeast Saccharomyces cerevisiae. For each palindrome size, the observed palindrome counts were significantly different from those in the randomly generated equivalents of the yeast genome. However, while the short palindromes (2–12 bp) were under-represented, the palindromes longer than 12 bp were over-represented, AT-rich and preferentially located in the intergenic regions. The 44-bp palindrome found between the genes CDC53 and LYS21 on chromosome IV was the longest palindrome identified and contained only two C-G base pairs. Avoidance of coding regions was also observed for palindromes of 4–12 bp, but was less pronounced. Dinucleotide analysis indicated a strong bias against palindromic dinucleotides that could explain the observed short palindrome avoidance. We discuss some possible mechanisms that may influence the evolutionary dynamics of palindromic sequences in the yeast genome.     

A DNA sequence in Saccharomyces exiguus is homologous with the HO gene of Saccharomyces cerevisiae

Summary The DNA of Saccharomyces exiguus was analyzed by Southern hybridization using cloned MATa, MAT, and HO genes of Saccharomyces cerevisiae as probes. It was shown that S. exiguus has a DNA sequence homologous with the HO gene of S. cerevisiae and that this DNA sequence is on a chromosome of about 940 kb of DNA in S. exiguus. However, there is no DNA sequence in S. exiguus that is homologous with the MAT genes of S. cerevisiae.     

Cloning and identification of a DNA fragment coding for the sup1 gene of Saccharomyces cerevisiae

Summary A plasmid, pYsup1-1, containing a DNA fragment able to suppress the recessive mutant phenotype of the suppressor locus sup1 (allele sup1-ts36) of Saccharomyces cerevisiae was isolated from a bank of yeast chromosomal DNA cloned in cosmid p3030. The complementing gene was localized on a 2.6 kb DNA fragment by further subcloning. Evidence is presented that the cloned DNA segment codes for the sup1 structural gene (chromosome IIR).     

Genetic mapping of two pairs of linked ribosomal protein genes in Saccharomyces cerevisiae

Summary We have used the 2 mapping method described by Falco and Botstein (1983) and tetrad analysis to map four ribosomal protein genes (two linked pairs) in S. cerevisiae. One pair (rp28–rp55 copy 1) is on chromosome XV, 14 cM proximal to ARG8. The other pair (rp55–rp28 copy 2) is 19 cM from the centromere on the left arm of chromosome XIV. To map copy 1 we used the E. coli -galactosidase gene rather than a yeast gene to mark the ribosomal protein chromosomal locus. This provided a more sensitive color screening assay for chromosome loss in the 2 method. It also removed the restriction that the mapping tester strains must be mutant for the plasmid marker.     

Isolation and characterization of three mutants with increased sensitivity to photoactivated 3-carbethoxypsoralen in Saccharomyces cerevisiae

The complementation and genetical analysis of yeast mutants sensitive to photoactivated 3-carbethoxy-psoralen define three novel recessive mutant alleles pso-5-1, pso6-1, and pso7-1. Their cross-sensitivity to UV_254nm, radiomimetic mutagens, and to chemicals enhancing oxidative stress suggest that these mutants are either impaired in metabolic steps protecting from oxidative stress or in mechanisms of the repair of oxygen-dependent DNA lesions. None of the three novel mutant alleles block the induction of reverse mutation by photoactivated mono- and bi-functional psoralens, nitrogen mustards, or UV_254nm.     

Hybridization of Saccharomyces cerevisiae with Candida utilis through protoplast fusion

Summary Auxotrophic mutants of Saccharomyces cerevisiae and Candida utilis were hybridized through protoplast fusion. Spontaneous, UV- and FPA-induced mitotic segregation indicated that after cell fusion, exclusion of the S. cerevisiae nucleus or nuclear fusion followed by preferential loss of S. cerevisiae chromosomes can take place. Some of the hybrids were stable. One of them, expressed mating and sporulation functions of the S. cerevisiae parent. Thus, markers from both parents could be recovered as mitotic and meiotic segregants.     

Localization of telomeres and telomere-associated proteins in telomerase-negative Saccharomyces cerevisiae

Cells lacking telomerase cannot maintain their telomeres and undergo a telomere erosion phase leading to senescence and crisis in which most cells become nonviable. On rare occasions survivors emerge from these cultures that maintain their telomeres in alternative ways. The movement of five marked telomeres in Saccharomyces cerevisiae was followed in wild-type cells and through erosion, senescence/crisis and eventual survival in telomerase-negative (est2::HYG) yeast cells. It was found that during erosion, movements of telomeres in est2::HYG cells were indistinguishable from wild-type telomere movements. At senescence/crisis, however, most cells were in G₂ arrest and the nucleus and telomeres traversed back and forth across the bud neck, presumably until cell death. Type I survivors, using subtelomeric Y′ amplification for telomere maintenance, continued to show this aberrant telomere movement. However, Type II survivors, maintaining telomeres by a sudden elongation of the telomere repeats, became indistinguishable from wild-type cells, consistent with growth properties of the two types of survivors. When telomere-associated proteins Sir2p, Sir3p and Rap1p were tagged, the same general trend was seen—Type I survivors retained the senescence/crisis state of protein localization, while Type II survivors were restored to wild type. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Cloning and characterization of the SKI3 gene of Saccharomyces cerevisiae demonstrates allelism to SKI5

Summary We have identified a mutant strain of the yeast Saccharomyces cerevisiae which overproduces killer toxin. This strain contains a single mutation which fails to complement defects in both the SKI3 and SKI5 genes, while a cloned copy of this gene complements both the ski3 and ski5 defects. The level of secreted toxin from a cDNA based plasmid is not increased in a ski3 strain, showing that the overproduction phenotype is dependent upon an increased level of M1 dsRNA.     

Analysis of cell-cycle specific localization of the Rdi1p RhoGDI and the structural determinants required for Cdc42p membrane localization and clustering at sites of polarized growth

The Cdc42p GTPase regulates multiple signal transduction pathways through its interactions with downstream effectors. Specific functional domains within Cdc42p are required for guanine-nucleotide binding, interactions with downstream effectors, and membrane localization. However, little is known about how Cdc42p is clustered at polarized growth sites or is extracted from membranes by Rho guanine-nucleotide dissociation inhibitors (RhoGDIs) at specific times in the cell cycle. To address these points, localization studies were performed in Saccharomyces cerevisiae using green fluorescent protein (GFP)-tagged Cdc42p and the RhoGDI Rdi1p. GFP-Rdi1p localized to polarized growth sites at specific times of the cell cycle but not to other sites of Cdc42p localization. Overexpression of Rdi1p led to loss of GFP-Cdc42p from internal and plasma membranes. This effect was mediated through the Cdc42p Rho-insert domain, which was also implicated in interactions with the Bni1p scaffold protein. These data suggested that Rdi1p functions in cell cycle-specific Cdc42p membrane detachment. Additional genetic and time-lapse microscopy analyses implicated nucleotide binding in the clustering of Cdc42p. Taken together, these results provide insight into the complicated nature of the relationships between Cdc42p localization, nucleotide binding, and protein–protein interactions.     

Cloning of maltase regulatory genes in Saccharomyces cerevisiae

Summary By hybridization with a putative MAL2p regulatory sequence we have identified a 19 kb long BamH1 DNA fragment to contain the MALp sequence in a MAL4 strain. A mixture of recombinant plasmids was prepared by ligation of purified 19 kb BamH1 fragments partially digested with Sau3A into the multicopy vector YEp1357. The source of DNA was a strain carrying the MAL4 locus. Yeast maltose non-fermenting strains were transformed with the plasmid mixture. A recombinant plasmid, pRM-4, containing the MAL4p regulatory gene was isolated that complements the maltose-negative phenotype. The plasmid was shown to confer the ability to synthesize maltase to recipient strains grown under inducing as well as under repressing conditions.The MAL4p regulatory sequence cloned was used as a probe in hybridization experiments to study the degrees of homology between the different MAL regulatory genes. The results showed that the sequence from MAL4 strains is strongly homologous to that of MAL3 strains whereas it shows significant differences to the ones of MAL1 and MAL2 strains.Southern analysis of the segregants of crosses between maltose-positive strains and ma10 strains allowed us to localize the maltase regulatory sequence of each MAL locus within a characteristic BamH1 fragment of genomic DNA hybridizing to the isolated sequence.     

Inheritance of chromosome length polymorphisms in Saccharomyces cerevisiae

Summary Although Saccharomyces cerevisiae strains generally have similar chromosomal band patterns as revealed by pulsed field gel electrophoresis, individual bands often move slightly differently from one strain to the other. Surveying strains from our stock collection, we found that nearly all the bands of a certain pair of strains differed in their mobility. Some of these chromosome length polymorphisms segregated in a 2:2 ratio, indicating that they resulted from single structural alterations (i.e. additions or deletions). One of these was mapped on the right arm of chromosome 1. Others did not segrate in a simple 2:2 ratio. That is, there were progenies which had bands not present in either parent. We suggest that these new bands are the products of recombination between homologous chromosomes having two or more structural alterations.     

Overexpression of HAM1 gene detoxifies 5-bromodeoxyuridine in the yeast Saccharomyces cerevisiae

5-Bromodeoxyuridine (BrdU) is known to modulate expression of particular genes, and eventually arrest cell division in mammalian and yeast cells. To study a molecular basis for these phenomena, we adopted a genetic approach with a yeast cell system. We screened multicopy suppressor genes that confer resistance to BrdU with a thymidine-auxotrophic strain of the yeast Saccharomyces cerevisiae. One of such genes was found to encode Ham1 protein, which was originally identified as a possible triphosphatase for N-6-hydroxylaminopurine triphosphate. Consistent with this, overexpression of the HAM1 gene reversed growth arrest caused by BrdU, and blocked incorporation of BrdU into genomic DNA. On the contrary, disruption of the gene sensitized cells to BrdU. A crude extract from Ham1-overproducing cells showed a high activity to hydrolyze BrdUTP to BrdUMP and pyrophosphate in addition to abnormal purine nucleotides. Purified recombinant Ham1 protein showed the same activity. These results demonstrate that Ham1 protein detoxifies abnormal pyrimidine as well as purine nucleotides.