Molecular cloning of chromosome I DNA from Saccharomyces cerevisiae: isolation of the ADE1 gene.

The ADE1 gene of Saccharomyces cerevisiae was isolated by complementation in S. cerevisiae from a yeast genomic DNA library carried on plasmid YEp13. Electron microscopy of R-loop-containing DNA indicated the location of the ADE1 gene on the plasmid insert. Gene disruption and gene replacement were used to demonstrate that the ade1-complementing sequence was the actual ADE1 gene that maps on chromosome I. ade1 strains which normally form red colonies form white ones when transformed with the cloned ADE1 gene. This property should be very useful, since it enables detection of plasmids carrying this gene under nonselective conditions.     

Molecular cloning of chromosome I DNA from Saccharomyces cerevisiae: isolation and analysis of the CEN1-ADE1-CDC15 region.

To continue the systematic examination of the physical and genetic organization of an entire Saccharomyces cerevisiae chromosome, the DNA from the CEN1-ADE1-CDC15 region from chromosome I was isolated and characterized. Starting with the previously cloned ADE1 gene (J. C. Crowley and D. B. Kaback, J. Bacteriol. 159:413-417, 1984), a series of recombinant lambda bacteriophages containing 82 kilobases of contiguous DNA from chromosome I were obtained by overlap hybridization. The cloned sequences were mapped with restriction endonucleases and oriented with respect to the genetic map by determining the physical positions of the CDC15 gene and the centromeric DNA (CEN1). The CDC15 gene was located by isolating plasmids from a YCp50 S. cerevisiae genomic library that complemented the cdc15-1 mutation. S. cerevisiae sequences from these plasmids were found to be represented among those already obtained by overlap hybridization. The cdc15-1-complementing plasmids all shared only one intact transcribed region that was shown to contain the bona fide CDC15 gene by in vitro gene disruption and one-step replacement to delete the chromosomal copy of this gene. This deletion produced a recessive lethal phenotype that was also recessive to cdc15-1. CEN1 was located by finding a sequence from the appropriate part of the cloned region that stabilized the inheritance of autonomously replicating S. cerevisiae plasmid vectors. Finally, RNA blot hybridization and electron microscopy of R-loop-containing DNA were used to map transcribed regions in the 23 kilobases of DNA that went from CEN1 to CDC15. In addition to the transcribed regions corresponding to the ADE1 and ADC15 genes, this DNA contained five regions that gave rise to polyadenylated RNA, at least two regions complementary to 4S RNA species, and a Ty1 transposable element. Notably, a higher than average proportion of the DNA examined was transcribed into RNA.     

DNA sequence analysis of the transposon Tn3: three genes and three sites involved in transposition of Tn3.

The complete nucleotide sequence of the transposon Tn3 and of 20 mutations which affect its transposition are reported. The mutations, generated in vitro by random insertion of synthetic restriction sites, proved to contain small duplications or deletions immediately adjacent to the new restriction site. By determining the phenotype and DNA sequence of these mutations we were able to generate an overlapping phenotypic and nucleotide map. This 4957 bp transposon encodes three polypeptides which account for all but 350 bp of its total coding capacity. These proteins are the transposase, a high molecular weight polypeptide (1015 amino acids) encoded by the tnpA gene; the Tn3-specific repressor, a low molecular weight polypeptide (185 amino acids) encoded by the tnpR gene; and the 286 amino acid beta-lactamase. The 38 bp inverted repeats flanking Tn3 appear to be absolutely required in cis for Tn3 to transpose. Genetic data suggest that Tn3 contains a third site (Gill et al., 1978), designated IRS (internal resolution site), whose absence results in the insertion of two complete copies of Tn3 as direct repeats into the recipient DNA. We suggest that these direct repeats of complete copies of Tn3 are intermediates in transposition, and that the IRS site is required for recombination and subsequent segregation of the direct repeats to leave a single copy of Tn3 (Gill et al., 1978). A 23 nucleotide sequence within the amino terminus of the transposase which shares strong sequence homology with the inverted repeat may be the internal resolution site.     

Cloning of chromosome I DNA from Saccharomyces cerevisiae: mutational analysis of the FUN2 transcribed region

To increase the number of mutationally defined genes on chromosome I from Saccharomyces cerevisiae, most of the FUN2 (Function Unknown Now) transcribed region was deleted by gene replacement. Strains containing the deletion were viable, but grew with a 20% longer generation time. The mutation was recessive. Mutant haploids were able to mate, and homozygous mutant diploids were able to sporulate, giving asci containing four viable ascospores. These results indicate FUN2 is dispensable for the life cycle of S. cerevisiae, but required for an optimal growth rate.     

Molecular cloning of chromosome I DNA from Saccharomyces cerevisiae: isolation and characterization of the CDC24 gene and adjacent regions of the chromosome.

Molecular cloning techniques were used to isolate and characterize the DNA including and surrounding the CDC24 and PYK1 genes on the left arm of chromosome I of the yeast Saccharomyces cerevisiae. A plasmid that complemented a temperature-sensitive cdc24 mutation was isolated from a yeast genomic DNA library in a shuttle vector. Plasmids containing pyk1-complementing DNA were obtained from other investigators. Several lines of evidence (including one-step gene replacement experiments) demonstrated that the complementing plasmids contained the bona fide CDC24 and PYK1 genes. These sequences were then used to isolate additional DNA from chromosome I by probing a yeast genomic DNA library in a lambda vector. A total of 28 kilobases (kb) of contiguous DNA surrounding the CDC24 and PYK1 genes was isolated, and a restriction map was determined. Electron microscopy of R-loop-containing DNA and RNA blot hybridization analyses indicated that an 18-kb segment contained at least seven transcribed regions, only three of which corresponded to previously known genes (CDC24, PYK1, and CYC3). Southern blot hybridization experiments suggested that none of the genes in this region was duplicated elsewhere in the yeast genome. The centers of CDC24 and PYK1 were only approximately 7.5 kb apart, although the genetic map distance between them is approximately 13 centimorgans. As previous studies with S. cerevisiae have indicated that 1 centimorgan generally corresponds to approximately 3 kb, the region between CDC24 and PYK1 appears to undergo meiotic recombination at an unusually high frequency.     

a/alpha-specific effect on the mms3 mutation on ultraviolet mutagenesis in Saccharomyces cerevisiae.

A new gene involved in error-prone repair of ultraviolet (UV) damage has been identified in Saccharomyces cerevisiae by the mms3-1 mutation. UV-induced reversion is reduced in diploids that are homozygous for mms3-1, only if they are also heterozygous (MATa/MAT alpha) at the mating type locus. The mms3-1 mutation has no effect on UV-induced reversion either in haploids or MATa/MATa or MAT alpha/MAT alpha diploids. The mutation confers sensitivity to UV and methyl methane sulfonate in both haploids and diploids. Even though mutation induction by UV is restored to wild-type levels in MATa/MATa mms3-1/mms3-1 or MAT alpha/MAT alpha mms3-1/mms3-1 diploids, such strains still retain sensitivity to the lethal effects of UV. Survival after UV irradiation in mms3-1 rad double mutant combinations indicates that mms3-1 is epistatic to rad6-1 whereas non-epistatic interactions are observed with rad3 and rad52 mutants. When present in the homozygous state in MATa/MAT alpha his1-1/his1-315 heteroallelic diploids, mms3-1 was found to lower UV-induced mitotic recombination.     

Cloning of chromosome I DNA from Saccharomyces cerevisiae: analysis of the FUN52 gene, whose product has homology to protein kinases.

A gene whose product has homology to protein kinases and is closely related to the Aspergillus nidulans nimA cell-cycle gene was identified on chromosome I of the yeast, Saccharomyces cerevisiae. This gene has been temporarily designated FUN52, where FUN is the acronym for 'function unknown now'. In A. nidulans, nimA is required to enter mitosis. In addition, overexpression of nimA causes premature onset of mitosis and cell cycle arrest. In contrast, S. cerevisiae cells that were either deleted for FUN52 or were overexpressing it had no detectable growth phenotypes. FUN52 proved to be the same as the previously identified KIN3 gene [Jones and Rosamond, Gene 90 (1990) 87-92] that was reported to map on chromosome VI.     

Methionine biosynthesis in Saccharomyces cerevisiae: mutations at the regulatory locus ETH2. I. Genetic data

Summary Evidence has been obtained that sodium azide is an inhibitor of cell division in wild-type and aziA strains of Salmonella typhimurium. The bacteria grown in media containing sodium azide and glucose formed long filaments. It has been found that sodium azide had a stronger inhibitory effect on DNA synthesis than on cell mass increase. When filaments produced by azide action were transferred to azide-free medium very rapid increase in DNA content was observed during the first 45 min. After this time, when relative DNA content was increased the rate of DNA synthesis was reduced and cell divisions reappeared.Inhibitory effect of azide on DNA biosynthesis in vitro was observed with toluenized cells of S. typhimurium. Only ATP-dependent radioactive dTMP incorporation into DNA was affected by sodium azide. It had no effect on the incorporation in the absence of ATP.Mutant aziC was isolated in S. typhimurium by scoring for clones with normal cell division in the presence of sodium azide. Azide had much less effect on DNA biosynthesis in vivo and in vitro in aziC cells as compared with isogenic controls.This work was supported by the Polish Academy of Sciences within the project 09.3.1., and by the U.S. Public Health Service, grant No. 05-032-1.     

Construction of transposon Tn3phoA: its application in defining the membrane topology of the Agrobacterium tumefaciens DNA transfer proteins

Protein fusion with the Escherichia coli alkaline phosphatase is used extensively for the analysis of the topology of membrane proteins. To study the topology of the Agrobacterium T-DNA transfer proteins, we constructed a transposon, Tn 3phoA . The transposon mobilizes into plasmids at a high frequency, is stable after transposition, can produce phoA translational fusions and can be used for the analysis of protein topology directly in the bacterium of interest. For studies on the DNA transfer proteins, an Agrobacterium strain deficient in phoA under our experimental conditions was constructed by chemical mutagenesis. A plasmid containing virB and virD4 was used as a target for mutagenesis. Twenty-eight unique phoA -positive clones that mapped to eight virB genes were isolated. Multiple insertions throughout VirB1, VirB5, VirB7, VirB9 and VirB10 indicated that these proteins primarily face the periplasm. Insertions in VirB2, VirB6 and VirB8 allowed the identification of their periplasmic domains. No insertions were found in VirB3, VirB4 and VirB11. These proteins either lack or have a short periplasmic domain. No insertions mapped to VirD4 either. To study VirD4 topology, targeted phoA fusions and random lacZ fusions were constructed. Analysis of the fusion proteins indicated that VirD4 contains a single periplasmic domain near the N-terminus, and most of the protein lies in the cytoplasm. A hypothetical model for the T-DNA transport pore is presented.     

Biochemical control of recombination in Saccharomyces cerevisiae. I. L-histidine inhibition of intragenic mitotic recombination at the ad 3 locus

Summary A yeast strain heteroallelic at the ad ₃ locus is used to study mitotic intragenic recombination. L-histidine inhibits the recombination at this locus in strains heteroallelic for all possible combinations between the four alleles studied. No other amino acid has this effect. The kinetic of recombination was studied by addition of L-histidine at different times or by compeating the L-histidine present with D-histidine added at different times. The two techniques gave similar results showing that the recombination takes place between the 8th and 24th hour after plating although it is expressed a few days later.Taking advantage of the early interval in which the recombination takes place and of the fact than the petite mutation is induced by acriflavine only in new formed buds, we developed a technique to study the recombination in liquid medium, thanks to which, we were able to show that L-histidine inhibits the genetic event itself.     

Dual cell cycle checkpoints sensitive to chromosome replication and DNA damage in the budding yeast Saccharomyces cerevisiae.

In eucaryotic cells chromosomes must be fully replicated and repaired before mitosis begins. Genetic studies indicate that this dependence of mitosis on completion of DNA replication and DNA repair derives from a negative control called a checkpoint which somehow checks for replication and DNA damage and blocks cell entry into mitosis. Here we summarize our current understanding of the genetic components of the cell cycle checkpoint in budding yeast. Mutants were identified and their phase and signal specificity tested primarily through interactions of the arrest-defective mutants with cell division cycle mutants. The results indicate that dual checkpoint controls exist in budding yeast, one control sensitive to inhibition of DNA replication (S-phase checkpoint), and a distinct but overlapping control sensitive to DNA repair (G2 checkpoint). Six genes are required for arrest in G2 phase after DNA damage (RAD9, RAD17, RAD24, MEC1, MEC2, and MEC3), and two of these are also essential for arrest in S phase when DNA replication is blocked (MEC1 and MEC2).     

Sequences homologous to the human D1S1 locus present on human chromosome 3.

We have investigated the segregation, in somatic cell hybrids, of the human D1S1 locus, previously assigned to 1p36 by in situ hybridization. We have shown that the clone which defines this locus, lambda Ch4A-H3, originates from human chromosome 3, but contains a 1.7-kilobase (kb) PstI-HindIII repetitive element that is also present on chromosome 1, probably distal to PGD. The clone recognizes restriction fragment length polymorphisms within the single-copy sequence on chromosome 3 and one for the enzyme StuI in the repeated sequence on chromosome 1. These experiments thus expose a level of complexity in the D1S1 locus not revealed by earlier in situ hybridization studies.     

Saccharomyces cerevisiae CSM1 gene encoding a protein influencing chromosome segregation in meiosis I interacts with elements of the DNA replication complex

We present the characteristics of the Csm1 (Spo86) protein of Saccharomyces cerevisiae that are important for meiotic division. The level of Csm1p does not change throughout the cell cycle, but this protein is absent in mature spores. Deletion of CSM1 causes incorrect spore formation and meiotic chromosome missegregation together with increased sensitivity of vegetative cells to benomyl and manganese. In a two-hybrid analysis with Csm1p as bait, we detected interactions with three members of the Mcm2-7 family of proteins involved in the initiation of DNA replication, and with Clf1p also implicated in replication. The Csm1p-Mcm3, Mcm5 and Mcm7p interactions were confirmed by co-immunoprecipitation. Three other interacting proteins, Mgs1p, Ulp2, and Plp2, participate in chromosome assembling and segregation, whereas the function of two others has not been established. Genetic experiments showed that the two-hybrid isolates MGS1, CLF1, MCM3, 5, 7 (CDC47), and YDL089w, when overexpressed, partially suppress the csm1Delta/csm1Delta sporulation defect. We propose that, besides its other functions, Csm1p may be involved in premeiotic DNA replication.     

A swimy locus on Y chromosome of the platyfish (Xiphophorus maculatus) is derived from a novel DNA transposon Zisupton

A swimy locus derived from a novel DNA transposon Zisupton was located on the sex determination region (SD) of Xiphophorus maculatus. The analysis of expression pattern showed that swimy was exclusively expressed in adult testis in X. maculatus. The putative 939 aa sequence contains four Zn-finger domains, such as two C2H2 type, one NFX type and one SWIM type Zn-finger domain, and one SAP DNA-binding domain. Swimy has about 7 copies per haploid X. maculatus genome with Y-specific copies located in the SD region, and become the second new W-linked marker of platyfish. Analysis of the structure and distribution of this sex-linked marker is benefit to shed new light on the evolutionary dynamics of sex chromosomes in fish.     

A delay in the Saccharomyces cerevisiae cell cycle that is induced by a dicentric chromosome and dependent upon mitotic checkpoints.

Dicentric chromosomes are genetically unstable and depress the rate of cell division in Saccharomyces cerevisiae. We have characterized the effects of a conditionally dicentric chromosome on the cell division cycle by using microscopy, flow cytometry, and an assay for histone H1 kinase activity. Activating the dicentric chromosome induced a delay in the cell cycle after DNA replication and before anaphase. The delay occurred in the absence of RAD9, a gene required to arrest cell division in response to DNA damage. The rate of dicentric chromosome loss, however, was elevated in the rad9 mutant. A mutation in BUB2, a gene required for arrest of cell division in response to loss of microtubule function, diminished the delay. Both RAD9 and BUB2 appear to be involved in the cellular response to a dicentric chromosome, since the conditionally dicentric rad9 bub2 double mutant was highly inviable. We conclude that a dicentric chromosome results in chromosome breakage and spindle aberrations prior to nuclear division that normally activate mitotic checkpoints, thereby delaying the onset of anaphase.