Mismatch-stimulated plasmid integration in yeast

Summary A single base pair mismatch (G:T or A:C) in the CYC1 gene of the integrative plasmid pAB218 stimulates up to a five-fold integration into the yeast chromosome. Analysis of chromosomal sites of plasmid integration suggests that the mismatch-stimulated integration is not targeted as would be expected if crossovers, localised in the region of the mismatch, were a necessary step in mismatch repair. Instead, the observed mismatch-stimulated plasmid integration could be due to potentially recombinogenic structures formed during mismatch repair, such as single-stranded gaps or denatured DNA regions extending around the plasmid molecule.     

Influence of homology size and polymorphism on plasmid integration in the yeast CYC1 DNA region

We studied the influence of homology size and polymorphism on the integration of circular plasmids into the yeast CYC1 region. The plasmids used also contained the URA3 gene, and the proportion of Ura⁺ transformants resulting from plasmid integration into the CYC1 region was determined by Southern-blot analysis. A size-dependent decrease in integration into the CYC1 region was observed from 858 bp to 363 bp of homology. However, with a homology size of 321, 259 or 107 bp, about 2% of the transformants still contained plasmid molecules integrated in the CYC1 region. A single point mutation in the 858-bp fragment decreased the proportion of integrations to the CYC1 gene, but the presence of additional mutations did not have a cumulative effect. For plasmids isolated in a single-stranded (ss) form, the presence of two or six point mutations did not influence integration. These results were compared with those obtained in other assays designed to study substrate requirements for homologous recombination. Received: 18 October / 15 December 1999     

A mitochondrial frameshift suppressor maps in the tRNASer-var1 region of the mitochondrial genome of the yeast S. cerevisiae

Summary A polypeptide chain-terminating mutation (M5631) previously has been shown to be a +1T insertion in the yeast mitochondrial gene oxi1, coding for subunit II of the cytochrome c oxidase. A spontaneously arisen frameshift suppressor (mfs-1) that is mitochondrially inherited suppresses this mutation to a considerable extent. The suppressor mutation was mapped by genetic and molecular analyses in the mitochondrial tRNA^Ser-var1 region of the mitochondrial genome of the yeast S. cerevisiae. Genetic analyses show that the suppressor mfs-1 does not suppress other known mitochondrial frameshift mutations, or missense and nonsense mutations.     

Second-site antibiotic resistance mutations in the ribosomal region of yeast mitochondrial DNA

Summary A large proportion of the spontaneous erythromycin resistant mutants isolated from a strain carrying a previously-induced chloramphenicol resistance mutation at cap3 do not map at ery1, the locus most often associated with mitochondrial erythromycin resistance. Most of the new mutations are also nonallelic at spil, spi2, and other known antibiotic resistance loci within the 21S rRNA gene; they are allelic with each other and define the new locus, ery2. Induced second-site erythromycin resistant mutants from the cap ^r3 strain, as well as spontaneous or induced mutants from strains carrying a cap ^r 1 mutation, all tend to map at eryl. The cap ^r3 mutation is apparently necessary for the expression of erythromycin resistance resulting from a second mutation at ery2.     

Respiration deficient mutants in the A+T-rich region on yeast mitochondrial DNA containing the var1 gene

Summary Several mit mutants mapping within or near the var1 determinant region have been characterized genetically and biochemically. These mutants were isolated using a new enrichment protocol which simplifies the isolation and identification of rare respiration-deficient mutants of yeast. Two of the mutants, PZ200L and PZ206, map in genome segments which flank the known varl gene reading frame; nevertheless, both belong to the same complementation group, apparently that of the varl gene. A third mutant, PZ200R is closely linked to one of the varl allelic determinants now known to be a short insertion within the gene. All three var1 mutants exhibit decreased levels of mitochondrial protein synthesis and negligible activity of the respiratory enzyme complexes. Another cluster of mutants belonging to a separate complementation group from that defined by PZ200L and PZ206 was also mapped and it contains mutants in the nearby serine tRNA gene.The isolation of these mutants in the varl region shows that the varl locus contains information essential for the maintenance of respiration-competent mitochondria. Because these mutants affect mitochondrial protein synthesis, their existence supports the previous hypothesis that the varl protein is an integral component of mitochondrial ribosomes. Furthermore, the mutant sites are present in a DNA sequence that is highly, rich in A+T residues that also contains a gene. Since approximately 50% of the yeast mitochondrial genome is similarly rich in A+T and since most of those regions have not yet been sequenced it is quite possible that other A+T-rich genes may exist.     

Evidence that the single CDC8 gene which encodes thymidylate kinase is involved in DNA replication,recombination and mutation in yeast

Summary The conditional cdc8 mutant is known to be defective, under restrictive conditions, in the elongation of DNA during synthesis. In yeast the CDC8 gene encodes thymidylate kinase. We show here that UV-induced gene conversion and gene mutation events require the participation of this CDC8 gene. Thus, the same thymidylate kinase is incolved both in DNA replication and in UV-induced gene conversion and gene mutation in yeast.     

Analysis of meiotic recombination events near a recombination hotspot in the yeast Saccharomyces cerevisiae

The region of yeast chromosome III between the HIS4 and LEU2 genes has an unusually high frequency of meiotic recombination. In order to determine the pattern of cross-over and gene conversion events, we constructed a strain with a number of heterozygous markers in this 25-kb interval. We found that very high levels of reombination are localized to regions of DNA near HIS4. In addition, analysis of the patterns of co-conversion of adjacent markers suggests that there is more than one initiation site contributing to recombination of HIS4.     

Genetic control of plasmid DNA double-strand gap repair in yeast,Saccharomyces cerevisiae

Summary The repair of double-strand gaps (DSGs) in the plasmid DNA of radiosensitive mutants of Saccharomyces cerevisiae has been analyzed. The proportion of repair events that resulted in complete plasmid DNA DSG recovery was close to 100% in Rad⁺ cells. Mutation rad55 does not influence the efficiency and preciseness of DSG repair. The mutant rad57, which is capable of recombinational DNA DSB repair, resulted in no DSG recovery. Mutation rad53 substantially inhibits the efficiency of DSG repair but does not influence the precision of repair. Plasmid DNA DSG repair is completely blocked by mutations rad50 and rad54.     

High frequency FLP-independent homologous DNA recombination of 2 μ plasmid in the yeast Saccharomyces cerevisiae

Summary The purpose of this work is to identify and quantitate in vivo 2 plasmid FLP-independent recombination in yeast, using a nonselective assay system for rapid detection of phenotypic expression of the recombination events. A tester plasmid was constructed such that in vivo recombination between 2 direct repeat sequences produces the resolution of the plasmid into two circular DNA molecules. This recombinational event is detected as a phenotypic shift from red to white colonies, due to the mitotic loss of the plasmid portion containing the yeast ADE8 gene in a recipient ade1 ade2 ade8 genetic background. In the absence of the 2 FLP recombinase and/or its target DNA sequence, recombination is not abolished but rather continues at a high frequency of about 17%. This suggests that the FLP-independent events are mediated by the chromosomally-encoded general homologous recombination system. We therefore conclude that the totality of 2 DNA recombination events occurring in FLP⁺ cells is the contribution of both FLP-mediated and FLP-independent events.     

Formation and stability of linear plasmids in a recombination deficient strain of yeast

Summary Natural termini from macronuclear DNA of the ciliated protozoans Tetrahymena thermophila and Oxytricha fallax can support telomere formation in yeast. However, plasmids carrying these ciliate termini are modified by the addition of DNA which hybridizes to the synthetic oligonucleotide poly [d(C-A)], a sequence which also hybridizes to terminal restriction fragments from yeast chromosomes but not to Tetrahymena or Oxytricha macronuclear DNAs. Thus, in yeast, the creation of new telomeres on ciliate termini involves the acquisition of yeast-specific terminal sequences presumably by either recombination or non-templated DNA synthesis. The RAD52 gene is required for the majority of yeast mitotic and meiotic recombination events. Moreover, the absence of an active RAD52 gene product results in high rates of chromosome loss. Here we demonstrate that terminal restriction fragments from Tetrahymena macronuclear ribosomal DNA (rDNA) support the formation of modified telomeres in a yeast strain carrying a defect in the RAD52 gene. Moreover, linear plasmids bearing these modified ciliate termini are stably propagated in rad52 ^– cells.     

Repair of gamma ray-induced S1 nuclease hypersensitive sites in yeast depends on homologous mitotic recombination and a RAD18-dependent function

Summary Repair under non-growth conditions of DNA double-strand breaks (DSB) and chromatin sites sensitive to S1 endonuclease (SSS) induced by ⁶⁰Cobalt-gamma rays were monitored in repair-competent and deficient strains of Saccharomyces cerevisiae by pulsed field gelelectrophoresis. In stationary-phase cells of a repair-competent RAD diploid, and an excision-deficient rad3-2 diploid, SSS are repaired as efficiently as DSB, whereas in a repair-competent RAD haploid, and a rad 50-1 diploid, neither SSS nor DSB are repaired. The rad18-2 diploid repairs DSB well but is defective in SSS repair. Obviously, SSS repair in yeast chromatin, like DSB repair, depends on recombination, but unlike DSB repair depends additionally on RAD18 function.     

A regulatory mutation in yeast which affects catalase T formation and metabolism of carbohydrate reserves

Summary Mutations at the GLC1 locus in Saccharomyces cerevisiae result in a major deficiency in synthesis of catalase T, but do not affect catalase A. Three independent glc1 mutations were shown to have the same pleiotropic phenotype: catalase T deficiency, defective glycogen synthesis and defective trehalose accumulation. These three deficiencies appear to be determined by a single, nuclear gene. The possibility that glc1 mutations alter a protein kinase is considered.     

Assembly of the mitochondrial membrane system. Organization of yeast mitochondrial DNA in the Oli1 region

Summary The mitochondrial DNA (mtDNA) of a cytoplasmic petite mutant (DS401) of Saccharomyces cerevisiae genetically marked for the ATPase proteolipid, serine tRNA and varl genes has been characterized by restriction endonuclease analysis and DNA sequencing. The DS401 mtDNA segment is 5.3 kb long spanning the region between 79.1 and 86.8 units of the wild type genome. Most of the DS401 mtDNA consists of A+T rich sequences. In addition, however, there are ten short sequences with a high content of G+C and two sequences that have been identified as the ATPase proteolipid and the serine tRNA genes. The two genes map at 81 and 83 units and are transcribed from the same DNA strand. Even though there are other possible coding sequences in the DNA segment, none are sufficiently long to code for a gene product of the size of the varl protein. Based on the relative organization of the G+C rich clusters and genes, a model has been proposed for the processing of mitochondria) RNA. This model postulates the existence of mitochondrial double strand specific RNases that cleave the RNA at the G+C clusters.     

Newly synthesised DNA of high molecular weight in the yeast Saccharomyces cerevisiae

Summary Two species of newly synthesised DNA larger than average replicons have been found in yeast. Their molecular weights are 60 million and 90 million daltons respectively. The exact nature of these molecules is not certain. They may represent entirely novel species of cellular DNA or they could be concatameric replication intermediates of some particular fraction of DNA, such as mitochondrial DNA or rDNA. Alternatively they could result from the fusion of adjacent completed replicons in a small cluster.     

A recombination execution checkpoint regulates the choice of homologous recombination pathway during DNA double-strand break repair

A DNA double-strand break (DSB) is repaired by gene conversion (GC) if both ends of the DSB share homology with an intact DNA sequence. However, if homology is limited to only one of the DSB ends, repair occurs by break-induced replication (BIR). It is not known how the homology status of the DSB ends is first assessed and what other parameters govern the choice between these repair pathways. Our data suggest that a “recombination execution checkpoint” (REC) regulates the choice of the homologous recombination pathway employed to repair a given DSB. This choice is made prior to the initiation of DNA synthesis, and is dependent on the relative position and orientation of the homologous sequences used for repair. The RecQ family helicase Sgs1 plays a key role in regulating the choice of the recombination pathway. Surprisingly, break repair and gap repair are fundamentally different processes, both kinetically and genetically, as Pol32 is required only for gap repair. We propose that the REC may have evolved to preserve genome integrity by promoting conservative repair, especially when a DSB occurs within a repeated sequence.     

Analysis of the role of the NUC1 endo/exonuclease in yeast mitochondrial DNA recombination

Mitochondrial DNA recombination was reduced in an yeast mutant lacking the NUC1 endo/exonuclease. Between linked markers in either the or cob region the frequency of recombination decreased nearly 50% compared to wild-type. Gene conversion frequencies in the var1 gene and in the region were also lower in the mutant strain. In particular, the gradient of gene conversion at was most affected by the absence of the NUC1 nuclease. In crosses between nuclease-deficient and wild-type strains, gene conversion frequencies at were reduced only when the ₊ allele was contributed to the zygote by the nuclease-deficient parent. We propose that the 5 exonuclease activity of the NUC1 nuclease functions during recombination to enlarge heteroduplex tracts following a double-strand break in DNA. In crosses between nuclease-deficient and wild-type strains, the anisotropy in gene conversion frequencies at is hypothesized to be due to the slow mixing of parental motochondrial membranes as they fuse in the zygote.     

Studies on homologous recombination in the green alga Chlamydomonas reinhardtii

The introduction of exogenous DNA into the nuclear genome of Chlamydomonas reinhardtii occurs predominantly via non-homologous (illegitimate) recombination and results in integration at apparently-random loci. Using truncated and modified versions of the C. reinhardtii ARG7 gene in a series of transformation experiments, we demonstrate that homologous recombination between introduced DNA molecules occurs readily in C. reinhardtii, requires a region of homology of no more than 230 bp, and gives rise to intact copies of ARG7 in the nuclear genome. Evidence is presented for homologous recombination between introduced ARG7 DNA and the resident copy of the gene, and for the de-novo synthesis of the ARG7 sequence during transformation.     

DNA synthesis catalyzed in vitro by yeast extracts using A 2 μm DNA containing plasmid as template for enzymatic DNA synthesis

Summary Partially purified cell-free extracts prepared from growing cells of the yeast Saccharomyces cerevisiae catalyze DNA synthesis directed by the chimeric plasmid BTYP-2 containing the whole 2 m DNA sequence. The biochemical properties of the reaction have been examined and inactivation studies indicate that DNA synthesis is only due to protein factors. Analysis of the products of the DNA synthesis reaction demonstrates that part of the in vitro synthesized DNA is not covalently linked to the template, thus suggesting initiation of new DNA chains. The analysis of the distribution of the labelled products at early times of reaction showed a preferential synthesis on the 2 m portion of the BTYP-2 DNA template.Other abbreviations used are BSA bovine serum albumin - DTT dithiotreitol - EDTA ethylendiaminetetraacetate - EGTA ethylenglycol-bis(-aminoethyl-ether)N,N-tetraacetic acid PhcMeSO₂F, phenylmethylsulfonylfluoride - SDS sodium dodecyl sulfate Abbreviations: The abbreviations used are those recommended by the IUPAC-IUB Commission on Biochemical Nomenclature (CBN).     

The use of a double-marker shuttle vector to study DNA double-strand break repair in wild-type and radiation-sensitive mutants of the yeast Saccharomyces cerevisiae

An episomal DNA vector (YpJA18), encoding two selectable recombinant yeast genes (TRP1, URA3), was constructed to assess the fidelity of DNA repair in haploid repair-competent (RAD) wild-type yeast and several radiation-sensitive mutants. Either a DNA double-strand break (DSB) or a double-strand gap of 169 bp (DSG) was introduced by restriction enzymes in-vitro within the coding sequence of the URA3 gene of this vector. To eliminate transfer artefacts, selection was first applied for the undamaged TRP1 gene followed by counter selection for URA3 gene activity, which indicated correct repair of the DSB and DSG. Correct repair of the damaged URA3 gene was found to be about 90% in RAD cells (normalized for the expression of undamaged URA3 in TRP ⁺ transformants). Plasmids isolated from the transformants (URA ⁺ TRP ⁺) carry both unique sites (ApaI and NcoI) within the URA3 gene indicating the precise restitution of the 169-bp gap. An excision-repair-defective rad4-4 mutant repaired these lesions as correctly as RAD cells, whereas the mutants rad50-1, rad51-1 and rad54-1, proven to be defective in DSB repair and mitotic recombination, showed less than 5% correct repair of such lesions. In contrast, a representative of the RAD6 epistasis group of genes, the rev2-1 mutant which is sensitive towards UV and ionizing radiation, had a significantly reduced ability (about 20%) for the correct repair of both DSBs and DSGs.