Meng-Er Huang

POL32, a subunit of the Saccharomyces cerevisiae DNA polymerase δ, defines a link between DNA replication and the mutagenic bypass repair pathway

Abstract Pol32 is a subunit of Saccharomyces cerevisiae DNA polymerase δ required in DNA replication and repair. To gain insight into the function of Pol32 and to determine in which repair pathway POL32 may be involved, we extended the analysis of the pol32Δ mutant with respect to UV and methylation sensitivity, UV-induced mutagenesis; and we performed an epistasis analysis of UV sensitivity by combining the pol32Δ with mutations in several genes for postreplication repair (RAD6 group), nucleotide excision repair (RAD3 group) and recombinational repair (RAD52 group). These studies showed that pol32Δ is deficient in UV-induced mutagenesis and place POL32 in the error-prone RAD6/REV3 pathway. We also found that the increase in the CAN1 spontaneous forward mutation of different rad mutators relies entirely or partially on a functional POL32 gene. Moreover, in a two-hybrid screen, we observed that Pol32 interacts with Srs2, a DNA helicase required for DNA replication and mutagenesis. Simultaneous deletion of POL32 and SRS2 dramatically decreases cellular viability at 15u2009°C and greatly increases cellular sensitivity to hydroxyurea at the permissive temperature. Based on these findings, we propose that POL32 defines a link between the DNA polymerase and helicase activities, and plays a role in the mutagenic bypass repair pathway.

DISRUPTION OF SIX NOVEL YEAST GENES REVEALS THREE GENES ESSENTIAL FOR VEGETATIVE GROWTH AND ONE REQUIRED FOR GROWTH AT LOW TEMPERATURE

We describe here the construction of six deletion mutants and their basic phenotypic analysis. Six open reading frames (ORFs) from chromosome X, YJR039w, YJR041c, YJR043c, YJR046w, YJR053w and YJR065c, were disrupted by deletion cassettes with long (LFH) or short (SFH) flanking regions homologous to the target locus. The LFH deletion cassette was made by introducing into the kanMX4 marker module two polymerase chain reaction (PCR) fragments several hundred base pairs (bp) in size homologous to the promoter and terminator regions of a given ORF. The SFH gene disruption construct was obtained by PCR amplification of the kanMX4 marker with primers providing homology to the target gene. The region of homology to mediate homologous recombination was about 70u2009bp. Sporulation and tetrad analysis revealed that ORFs YJR041c, YJR046w and YJR065c are essential genes. Complementation tests by corresponding cognate gene clones confirmed this observation. The non‐growing haploid segregants were observed under the microscope. The yjr041cΔ haploid cells gave rise to microcolonies comprising about 20 to 50 cells. Most yjr046wΔ cells were blocked after one or two cell cycles with heterogeneous bud sizes. The yjr065cΔ cells displayed an unbudded spore or were arrested before completion of the first cell division cycle with a bud of variable size. The deduced protein of ORF YJR065c, that we named Act4, belongs to the Arp3 family of actin‐related proteins. Three other ORFs, YJR039w, YJR043c and YJR053w are non‐essential genes. The yjr043cΔ cells hardly grew at 15°C, indicating that this gene is required for growth at low temperature. Complementation tests confirmed that the disruption of YJR043c is responsible for this growth defect. In addition, the mating efficiency of yjr043cΔ and yjr053wΔ cells appear to be moderately a ffected.

IDENTIFICATION OF ACT4, A NOVEL ESSENTIAL ACTIN-RELATED GENE IN THE YEAST SACCHAROMYCES CEREVISIAE

Actin molecules are major cytoskeleton components of all eukaryotic cells. All conventional actins that have been identified so far are 374–376 amino acids in size and exhibit at least 70% amino acid sequence identity when compared with one another. In the yeast Saccharomyces cerevisiae, one conventional actin gene ACT1 and three so‐called actin‐related genes, ACT2, ACT3 and ACT5, have been identified. We report here the discovery of a new actin‐related gene in this organism, which we have named ACT4. The deduced protein, Act4, of 449 amino acids, exhibits only 33·4%, 26·7%, 23·4% and 29·2% identity to Act1, Act2, Act3 and Act5, respectively. In contrast, it is 68·4% identical to the product of the Schizosaccharomyces pombe Act2 gene and has a similar level of identity to other Sch. pombe Act2 homologues. This places Act4 in the Arp3 family of actin‐related proteins. ACT4 gene disruption and tetrad analysis demonstrate that this gene is essential for the vegetative growth of yeast cells. The act4 mutants exhibit heterogenous morphological phenotypes. We hypothesize that Act4 may have multiple roles in the cell cycle. The sequence has been deposited in the Genome Sequence Data Base under Accession Number L37111.

Construction of a cosmid contig and of an EcoRI restriction map of yeast chromosome X

We report here the construction of a complete physical map of the chromosome X of yeast Saccharomyces cerevisiae. Fragments resulting from partial Sau3AI digestion of DNA from a diploid strain derived from S288C were ligated to linearized pWE15, a cosmid vector with T3 and T7 promoters. Another library, made in the cosmid vector pOU61 cos, that lacks T3 and T7 promoters, was also used as a source of target clones. Chromosome-X-specific clones were sorted out by hybridization with radiolabelled pulse-field-gel-purified chromosome X as a probe. Then, 254 cosmids were ordered by walking from one to another by hybridization with end-specific T3 or T7 RNA transcripts as probes. The construction was put to the test by hybridization with a battery of chromosome X gene markers, that showed that the physical map and the genetic map were colinear. The validity of the contig was further strengthened by the results of chromosome nested fractionation with meganuclease I-SceI. An EcoRI restriction map of the contig enabled further verification and measurement of the total length of the contig, that was found to be approximately 700 kb in size. In addition to providing a base for the ongoing yeast genome sequencing project, the physical map can be used to map any sequence belonging to chromosome X.

Analysis of a 62 kb DNA sequence of chromosome X reveals 36 open reading frames and a gene cluster with a counterpart on chromosome XI

We have sequenced a 61,989 bp stretch located between genes RAD7 and FIP1 of Saccharomyces cerevisiae chromosome X. This stretch contains 36 open reading frames (ORFs) of at least 100 codons. Fourteen of these correspond to sequences previously published as HIT1, CDC8, YAP17, CBF1, NAT1, RPA12, CCT5, TOR1, RFC2, PEM2, CDC11, MIR1, STE18 and GRR1. The proteins deduced from four ORFs (YJR059w, YJR065c, YJR075w, YJR078w) have significant similarity to proteins of known function from yeast or other organisms, including S. cerevisiae serine/threonine‐specific protein kinase, Schizosaccharomyces pombe Act2 protein, S. cerevisiae mannosyltransferase OCH1 protein and mouse indoleamine 2,3‐dioxygenase, respectively. Four of the remaining 18 ORFs have similarity to proteins with unknown function, six are weakly similar to other known sequences, while another eight exhibit no similarity to any known sequence. In addition, three tRNA genes have been recognized. Three genes clustered within 22 kb (YJR059w, YJR061w and TOR1) have counterparts arranged within 15 kb on the left arm of chromosome XI. The sequence has been deposited in the Genome Sequence Data Base under Accession Number L47993.