[HSM6 gene is identical to PSY4 gene in Saccharomyces cerevisiae yeasts].

Previously, we isolated mutant yeasts Saccharomyces cerevisiae with an increased rate of spontaneous mutagenesis. Here, we studied the properties of HSM6 gene, the hsm6-1 mutation of which increased the frequency of UV-induced mutagenesis and decreased the level of UV-induced mitotic crossover at the centromere gene region, ADE2. HSM6 gene was mapped on the left arm of chromosome 11 in the region where the PSY4 gene is located. The epistatic analysis has shown that the hsm6-1 mutation represents an allele of PSY4 gene. Sequencing of hsm6-1 mutant allele has revealed a frameshift mutation, which caused the substitution of Lys218Glu and the generation of a stop codon in the next position. The interactions of hsm6-1 and rad52 mutations were epistatic. Our data show that the PSY4 gene plays a key role in the regulation of cell withdrawal from checkpoint induced by DNA disturbances.

[Interaction of the HSM3 gene with genes initiating homologous recombination repair in yeast Saccharomyces cerevisiae].

It was assumed previously that the mutator phenotype of the hms3 mutant was determined by processes taking place in the D-loop. As a next step, genetic analysis was performed to study the interactions between the hsm3 mutation and mutations of the genes that control the initial steps of the D-loop formation. The mutations of the MMS4 and XRS2 genes, which initiate the double-strand break formation and subsequent repair, were shown to completely block HSM3-dependent UV-induced mutagenesis. Mutations of the RAD51, RAD52, and RAD54 genes, which are also involved in the D-loop formation, only slightly decreased the level of UV-induced mutagenesis in the hsm3 mutant. Similar results were observed for the interaction of hsm3 with the mph1 mutation, which stabilizes the D-loop. In contrast, the shu1 mutation, which destabilizes the D-loop structure, led to an extremely high level of UV-induced mutagenesis and displayed epistatic interactions with the hsm3 mutation. The results made it possible to assume that the hsm3 mutation destabilizes the D-loop, which is a key substrate of both Rad5- and Rad52-dependent postreplicative repair pathways.

[Interaction of gene HSM3 with genes of the epistatic RAD6 group in yeast Saccharomyces cerevisiae].

In eukaryotes, damage tolerance of matrix DNA is mainly determined by the repair pathway under the control of the RAD6 epistatic group of genes. T this pathway is also a main source of mutations generated by mutagenic factors. The results of our recent studies show that gene HSM3 participating in the control of adaptive mutagenesis increases the frequency of mutations induced by different mutagens. Mutations rad18, rev3, and mms2 controlling various stages of the RAD6 pathway are epistatic with mutation hsm3 that decreases UV-induced mutagenesis to the level typical for single radiation-sensitive mutants. The level of mutagenesis in the double mutant srs2 hsm3 was lower than in both single mutants. Note that a decrease in the level of mutagenesis relative to the single mutant srs2 depends on the mismatch repair, since this level in the triple mutant srs2 hsm3 pms 1 corresponds to that in the single mutant srs2. These data show that the mutator phenotype hsm3 is probably determined by processes occurring in a D loop. In a number of current works, the protein Hsm3 was shown to participate in the assembly of the proteasome complex S26. The assembly of proteasomes is governed by the N-terminal domain. Our results demonstrated that the Hsm3 protein contains at least two domains; the N-terminal part of the domain is responsible for the proteasome assembly, whereas the C-terminal portion of the protein is responsible for mutagenesis.

[Genetic analysis of the Hsm3 protein domain structure in yeast Saccharomyces cerevisiae].

Gene HSM3 encodes the Hsm3 protein involved in the minor branch in the system responsible for the correction of mismatched bases in DNA structure and controls replicative and reparative spontaneous mutagenesis in yeast Saccharomyces cerevisiae. Spontaneous and UV-induced mutagenesis was studied in three mutant alleles of gene HSM3, and repair effectivity of artificial heteroduplexes was assessed in DNA molecule. The resuts of these studies allowed establishment of the protein domain structure of protein Hsm3 and functions of each domain: the N-terminal domain is responsible for binding to mispaired bases, and the C-terminal domain ensures the interaction with other proteins involved in the system of mismatched base correction.

[IXR1 and HMO1 genes jointly control the level of spontaneous mutagenesis in yeast Saccharomyces cerevisiae].

The yeast genes IXR1 and HMO1 encode proteins belonging to the family of chromatin nonhistone proteins, which are able to recognize and bind to irregular DNA structures. The full deletion of gene IXR1 leads to an increase in cell resistance to the lethal action of UV light, gamma-rays, and MMS, increases spontaneous mutagenesis and significantlly decreases the level of UV-induced mutations. It was earlier demonstrated in our works that the hmo 1 mutation renders cells sensitive to the lethal action of cisplatin and virtually does not affect the sensitivity to UV light. Characteristically, the rates of spontaneous and UV-induced mutagenesis in the mutant are increased. Epistatic analysis of the double mutation hmo 1 ixr1 demonstrated that the interaction of these genes in relation to the lethal effect of cisplatin and UV light, as well as UV-induced mutagenesis, is additive. This suggests that the products of genes HMO1 and IXR1 participate in different repair pathways. The ixr1 mutation significantly increases the rate of spontaneous mutagenesis mediated by replication errors, whereas mutation hmo 1 increases the rate of repair mutagenesis. In wild-type cells, the level of spontaneous mutagenesis was nearly one order of magnitude lower than that obtained in cells of the double mutant. Consequently, the combined activity of the Hmo 1 and the Ixr1 proteins provides efficient correction of both repair and replication errors.

[The geptrong pharmaceutical product increases efficiency of postreplication repair of permutation intermediates in yeast Saccharomyces cerevisiae].

Geptrong is a medication from pure defermentated honey. In medical practice, it is used as hepatoprotector. Genotoxicity analysis revealed antimutagenic activity of the preparation. The spontaneous mutation rate at the ADE4-ADE8 and CAN1 loci was several times lower in case that the yeast cells were plated on the geptrong-containing medium, and the mutation rate was scored using the method of ordered plating. If spontaneous mutation rate was measured by means of the fluctuation method of median, no antimutagenic activity was detected. Geptrong had no effect on the yeast cell survival. At the same time, it substantially decreased the frequency of direct mutations at the ADE4-ADE8 locus, induced by UV- and gamma-radiation, and ethylmetansulfonate. The effect of the geptrong antimutagenic activity on the level of UV-induced mutagenesis in the yeast strains defective for the repair systems rad2, rad51, rad54, rad59, msh2, and hsm3 was examined. Antimutagenic activity was detected in the wild type, as well as in the rad2, rad54, rad59, and hsm3 strains, while rad51, pmsl, and msh2 mutants lacked this activity. Based on these data, it is suggested that antimutagenic effect of geptrong is associated with activated repair of mismatches, appeared during the postreplicative recombination repair.

[Repair of cisplatin-DNA adducts in mutants for genes controlling spontaneous and induced mutagenesis in Saccharomyces cerevisiae].

Sensitivity to the lethal action of the anticancer substance cisplatin was studied in the yeast mutants himl, hsm2, hsm3, and hsm6, deficient for repair of spontaneous and induced mutations. The himl and hsm3 mutants were as resistant to the agent under study as the wild-type strain. The survival of the double mutant rad2 hsm3 was higher than that of the single mutant rad2. The hsm2 and hsm6 mutants were more cisplatin-sensitive than the wild type. Cisplatin was shown to have high mutagenic and recombinogenic effects on yeast cells.

[Mutator genes of the yeast Saccharomyces cerevisiae. Interaction of mutations him and his with mutations blocking three principal pathways of repair of induced DNA damage]. / Geny-mutatory drozhzhei Saccharomyces cerevisiae. Vzaimodeistvie mutatsii him i hsm s mutatsiiami, blokiruiushchimi tri osnovnykh puti reparatsii indutsirovannykh povrezhdenii DNK.

During recent years, genes controlling mutation in higher eukaryotes have been found to be involved actively in carcinoma regeneration in cells. In this respect, studying the genetic control of mutagenesis becomes a key direction of research into mechanisms responsible for cancer generation. The results of studying interaction of mutations in the HIM and HSM genes, controlling spontaneous and induced mutagenesis in yeasts, and mutations impairing three known pathways of DNA damage repair in this microorganism, are described in this work. It was shown that mutation rev3 completely blocks UV-induced mutagenesis in all mutants studied. On the other hand, mutation rad2 synergistically interacts with mutations him1, hsm1, hsm3, hsm6, and hsm2, thus enhancing the frequency of UV-induced mutagenesis in double mutants multiple times. Mutations him2 and him3 manifested epistatic interaction with mutation rad2. With mutation rad54, the interaction was epistatic for mutations him1 and hsm2 and was additive for mutations hsm1, him2, and him3. On the basis of the data obtained, we developed a scheme for the appearance of mismatch bases in the process of repair of UV-induced DNA damage.

[Mutator genes from Saccharomyces cerevisiae. Repair of artificial heteroduplexes in him and hsm mutants]. / Geny-mutatory drozhzhei Saccharomyces cerevisiae. Reparatsiia iskusstvennykh geterodupleksov u mutantov him i hsm.

During recent years, genes controlling mutation in higher eukaryotes have been found to be involved actively in carcinoma regeneration in cells. In this respect, studying the genetic control of mutagenesis becomes a key direction of research into mechanisms responsible for cancer generation. The results of studying interaction of mutations in the HSM3 and HSM6 genes, controlling spontaneous and induced mutagenesis in yeasts, and mutations impairing three known pathways of DNA damage repair in this microorganism, are described in this work. It was shown that mutation rev3 completely blocks UV-induced mutagenesis in all mutants studied. On the other hand, mutation rad2 synergistically interacts with mutations him1, hsm1, hsm3, hsm6, and hsm2, thus enhancing the frequency of UV-induced mutagenesis in double mutants multiple times. Mutations him2 and him3 manifested epistatic interaction with mutation rad2. With mutation rad54, the interaction was epistatic for mutations him1 and hsm2 and was additive for mutations hsm1, him2, and him3. On the basis of the data obtained, we developed a scheme for the appearance of mismatch bases in the process of repair of UV-induced DNA damage.

[Mutator genes from Saccharomyces cerevisiae. Interaction between HIM- and HSM-genes]. / Geny-mutatory drozhzhei Saccharomyces cerevisiae. Vzaimodeistvie mezhdu HIM- i HSM-genami.

The interaction of six mutator genes of the yeast Saccharomyces cerevisiae with respect to UV-induced mutagenesis was studied. To this effect, double mutants with a genotype containing pairs of mutations at genes analyzed were synthesized. Analysis of the type of interaction of these mutations revealed four epistatic gene groups: (1) HIM1, HSM3, and HSM6; (2) HSM1; (3) HSM2; and (4) HIM2 and HIM3. The possible role of genes studied in different repair pathways of mispaired bases was discussed.

[A strain of the yeast Saccharomyces cerevisiae for testing environmental mutagens based on interaction of the mutations rad2 and him1]. / Shtamm drozhzhei Saccharomyces cerevisiae dlia testirovaniia mutagenov okruzhaiushchei sredy, osnovannyi na vzaimodeistvii mutatsii rad2 i him1.

The interaction between mutations at the RAD2 and HIM1 genes was studied. The RAD2 gene encodes endonuclease involved in nucleotide excision repair. Mutants at this gene are highly sensitive to the lethal effect of a variety of mutagens. The product of the HIM1 gene is needed for correction of mismatched bases and repair of premutational DNA damage. Mutations in this gene lead to the formation of the mutator phenotype and high sensitivity to induced mutagenesis. The double rad2 him1 mutant manifested the synergic type of interaction. The level of UV-induced mutagenesis in the double mutant was five times higher than in single mutants, and the absolute yield of forward mutations in five genes controlling adenine biosynthesis was 1 to 2%. UV-induced mutagenesis was increased, at low doses, by several orders of magnitude in the double mutant, compared to the wild-type strain. The high level of mutagenesis in this mutant was caused by ethyl and methyl methanesulfonate. These properties of the stock with the double rad2 him1 mutation makes it promising as a tester in analysis of the gene toxicity of different substances.

[Effect of hms mutations increasing spontaneous mutability on induced mutagenesis and mitotic recombination in the yeast Saccharomyces cerevisiae]. / Vliianie mutatsii hms, povyshaiushchikh spontannuiu mutabil'nost', na industsirovannyi mutagenez i mitotcheskuiu rekombinatsiiu u drozhzhei Saccharomyces cerevisiae.

The influence of five nonallelic mutations hsm-1-hsm-5 on the frequency of mutations induced by UV-light, 6-hydroxyl-aminopurine (GAP) and nitrosomethylurea (NMM) at the ADE1 and ADE2 loci was studied. All hsm mutants were resistant to the lethal effect of these mutagens. The frequency of mutations induced by UV-light was increased in hsm2-1, hsm3-1, hsm5-1 and especially in hsm1-1 mutants, the hsm4-1 mutant not differing from the HSM strain. GAP-induced mutagenesis was elevated in all hsm mutants and, particularly, in hsm3-1. No influence of hsm mutations on the frequency of NMM-induced mutations was observed. The frequency of spontaneous mitotic gene conversion was studied in the diploids heteroallelic for mutations in the gene ADE2 (ade2-58 ade2-i) and homo- and heterozygous for the hsm mutations (HSMHSM and HSMhsm). The mutations hsm2-1, hsm3-1 and especially hsm5-1 strongly increased the conversion frequency for all heteroallelic combinations studied. The mutations hsm1-1, hsm4-1 affected this process weakly. The properties of the hsm mutations under study demonstrated common genetic control of spontaneous and induced mutagenesis and recombination in the yeast. Possible belonging of hsm mutations to the class of mutations destroying the repair pathway for mismatch correction is under discussion.

[Isolation and characteristics of new mutants of Saccharomyces cerevisiae with increased spontaneous mutability]. / Vydelenie i kharakteristika novykh mutantov drozhzhei Saccharomyces cerevisiae s povyshennoi spontannoi mutabil'nost'iu.

To isolate some new genes controlling the process of spontaneous mutagenesis, a collection of 16 yeast strains with enhanced rate of spontaneous canavanine resistant mutations was obtained. Genetical analysis allowed to define that the mutator phenotype of these strains is due to a single nuclear mutation. Such mutations were called hsm (high spontaneous mutagenesis). Recombinational test showed that 5 mutants under study carried 5 nonallelic mutations. It was revealed that the mutation hsm3-1 is a nonspecific mutator elevating the rate of both spontaneous canavanine resistant mutations and the frequency of reversions in mutations lys1-1 and his1-7. Genetical analysis revealed that mutation hsm3-1 is recessive. The study of cross sensitivity of mutator strains to physical and chemical mutagens demonstrated that 12 of 16 hsm mutants were resistant to the lethal action of UV, gamma rays and methylmethanesulfonate, and 4 mutants were only sensitive to these factors. Possible nature of hsm mutations is discussed.

[Participation of the HIM1 gene from Saccharomyces cerevisiae in correction of heteroduplex DNA. Molecular cloning of the gene]. / Uchastie gena HIM1 drozhzhei Saccharomyces cerevisiae v korrektsii geterodupleksnoi DNK. Molekuliarnoe klonirovanie gena.

A group of Saccharomyces cerevisiae mutants deficient in repair of induced premutation lesions (him mutants) were previously isolated in our laboratory. Recessive him1 mutant had enhanced level of spontaneous and induced mutagenesis as well as specific altered mitotic conversion. This HIM1 gene was supposed to be involved in the process of mismatch correction of heteroduplexes. In this paper the correction efficiency of in vitro constructed heteroduplex DNA in wild-type cells and him1 mutant was studied. In the former cells heteroduplex DNA was repaired highly efficiently (about 90%), this repair efficiency being reduced in him cells approx. two times as compared with the wild-type cells. Molecular cloning of yeast chromosomal DNA fragments containing HIM1 gene was carried out. The clones were selected from the bank of yeast DNA fragments by complementing him1-1 mutation which enhances conversion frequency in ADE2 gene. One of the DNA fragments was analysed by restriction endonuclease digestion and shown to contain an insert of 6 Kb. Chromosomal integrants were obtained by homologous recombination between the plasmid and chromosomal gene him1.

[Mapping the xrs2 and him1 genes of Saccharomyces cerevisiae by a method based on the chromosome destabilization effect]. / Kartirovanie genov xrs2 i him1 drozhzhei Saccharomyces cerevisiae metodom, osnovannym na éffekte destabilizatsii khromosom.

The methods for chimeric chromosomes' destabilization and the standard tetrad analysis have been used for mapping of the yeast genes XRS2 and HIM1. The genes are localized in the right arm of chromosome IV in the following order: XRS2-31cM-ADE8-28.5cM-HIM1.

[The effect of him mutations characterized by enhanced induced mutagenesis on the spontaneous mitotic recombination in the ADE2 gene in Saccharomyces cerevisiae]. / Vliianie mutatsii him, kharakterizuiushchikhsia povyshennym indutsirovannym mutagenezom, na spontannuiu mitoticheskuiu rekombinatsiiu v gene ADE2 u drozhzhei Saccharomyces cerevisiae.

We have studied the influence of him1, him2, him3 and himX mutations on the frequency of spontaneous mitotic gene conversion in the yeast Saccharomyces cerevisiae using the set of heteroallelic combinations in the ADE2 gene. Data obtained on the HIM/HIM, him/him homozygotes and HIM/him heterozygotes indicate that the him1 mutation is recessive with respect to conversion, whereas the him2, him3 and himX mutations are semidominant. Gene conversion was increased in the majority of heteroalleles of mutant diploids him1/him1. On the contrary, the him2, him3 and himX mutants have hypo-rec phenotypes on mitotic conversion. The him mutations do not affect some heteroalleles, moreover, for some heteroalleles, the effects of the him mutations was opposite. On the basis of the sum of genetical data and, particularly, of conversion event pattern in the him mutants, we suggest that him mutations analysed affect the repair pathway for mismatch correction.

[Mutants of the yeast Saccharomyces cerevisiae characterized by enhanced induced mutagenesis. III. Effect of the him mutation on the effectiveness and specificity of UF-induced mutagenesis]. / Mutanty drozhzhei Saccharomyces cerevisiae, kharakterizuiushchiesia povyshennym indutsirovannym mutagenezom. Soobshchenie III. Vliianie mutatsii him na éffektivnost' i spetsifichnost' UF-indutsirovannogo mutageneza.

We have studied the influence of him1-1, him2-1, him3-1 and himX mutations on induction frequency and specificity of UV-induced adenine-dependent mutations in the yeast Saccharomyces cerevisiae. Him mutations do not render haploid cells more sensitive to the lethal action of UV-light; however, in him strains adenine-dependent mutations (ade1, ade2) were induced more frequently (1.5--2-fold), as compared to the HIM strain. An analysis of the molecular nature of ade2 mutants revealed that him1-1, him2-1 and himX mutations increase specifically the yield of transitions (AT----GC and GC----AT), whereas in the him3-1 strain the yield of transversions was enhanced as well. We suggest him mutations analysed to affect specific repair pathway for mismatch correction.

[Saccharomyces cerevisiae mutants characterized by increased induced mutagenesis. II. Genetic analysis of mutants]. / Mutanty drozhzhei Saccharomyces cerevisiae, kharakterizuiushchiesia povyshennym indutsirovannym mutagenezom. Soobshchenie II. Geneticheskii analiz mutantov.

Induction of forward adenine-dependent (Ade+----Ade-) mutations by HAP was used to analyse genetically yeast mutants with enhanced induced mutagenesis. Three mutations studied in detail segregated as a single mendelian trait and composed independent complementation groups (HIM1, HIM2, HIM3). the him1-1 mutation was centromere-linked, the him3-1 and him2-1 mutations being not. All three mutations did not show any cross-linkage. Uracil-DNA glycosylase activity was determined in crude cell extract from wild type strain and him mutants; no detectable differences were observed.

[Mutants of Saccharomyces cerevisiae characterized by increased level of induced mutagenesis. I. Isolation and preliminary characterization of mutants]. / Mutanty drozhzhei Saccharomyces cerevisiae, kharakterizuiushchiesia povyshennym indutsirovannym mutagenezom. Soobshchenie I. Vydelenie mutantov i ikh predvaritel'noe izuchenie.

6 mutants with enhanced nitrous acid-induced reversibility of the ade2-42 allele were isolated and designated hm (high mutagenesis). Apart from sensitivity to the mutagenic exposure to nitrous acid, hm mutants were also spontaneous mutators and hypermutable under the action of UV-light and 6-N-hydroxyaminopurine. All these effects were detected not only when analysing reversibility of the ade2-42 allele, but also when scoring forward mutations in the ADE1, ADF2 genes. Gamma-mutagenesis, however, was not affected by hm mutations.