UV and chemical mutagenesis in rev7 mutants of yeast

Summary We have examined induced mutagenesis in rev7-1 mutants of Baker's yeast' Saccharomyces cerevisiae, using a variety of contrasting test systems and several different mutagens. UV-induced reversion frequencies of the ochre allele arg4-17, the putative missense allele ilv1-92 and the frameshift allele his4-38 were 10 to 200 fold lower in haploid and diploid rev7-1 mutants compared with wild type strains, but UV-induced reversion frequencies of the frameshift allele leu2-3 and the proline missense allele cyc1-115 were reduced only a few fold. Ilv1-92 reversion frequencies induced by methyl methane sulfonate or by N-methyl-N-nitro-N-nitrosoguanidine were 10 to 20 times lower in rev7-1 mutants, but normal frequencies of these revertants were induced with ethyl methane sulfonate, even though rev7-1 strains are slightly sensitive to this mutagen as well as to the others tested. We conclude that the rev7 mutants, like the rev3 mutants they closely resemble, have a substantial but not total deficiency concerning induced mutagenesis.     

REV7, a new gene concerned with UV mutagenesis in yeast

Summary Three allelic mutations of a new yeast gene, which we have named REV7, have been isolated by testing 313 methyl methane sulfonate sensitive mutants for UV-induced reversion of a lys2 allele. Rev7 mutants are markedly deficient with respect to UV-induced reversion of lys2, are slightly sensitive to UV and appear to be in the RAD6 epistasis group for UV survival. Rev7-1, which is probably an amber mutation, does not appear to affect sporulation in homozygous diploids. The REV7 gene is located about 12 cM distal to HIS5 on chromosome IX.     

Induction of forward mutations in mutationally defective yeast

Summary The 3 rev loci that reduce ultraviolet light (UV)-induced reversion in S. cerevisiae had a similar effect on forward mutation to auxotrophy induced by a single 400 erg/mm² UV dose: rev1-1, rev2-1 and rev3-1 reduced average frequencies of auxotrophs to 4%, 64% and 4% that in wild type and reduced frequencies of mutants at ade1 or ade2 to 19%, 88% and 2% wild type, respectively. The rev2-1 strain exhibited high frequencies of spontaneous mutation. It is suggested that rev1-1 and rev3-1 block steps in a general UV mutation mechanism controlling forward and reverse mutation throughout the genome. The small effect of rev2-1, compared to the effect of rev1-1 or rev3-1, is consistent with previously obtained data on UV reversion and could be due to a specificity for induced mutation involving only certain types of UV damage or, on the other hand, it may be related to mutator activity. Although rev caused varying degrees of sensitivity to ethylmethanesulfonate (EMS), there was little or no significant effect on mutation induced by a single 30 min. dose of 3% EMS. Auxotroph frequencies were 79%, 109% and 94% wild type, whild frequencies at ade1 or ade2 were 82%, 56% and 51% wild type in the respective strains. It is suggested that steps blocked by rev, although they may participate in repair of lethal EMS damage, do not themselves generate EMS-induced mutations.     

UV-induced reversion of his4 frameshift mutations in rad6, rev1, and rev3 mutants of yeast

Summary The UV-induced reversion of two his4 frameshift alleles was much reduced in rad6 mutants of Saccharomyces cerevisiae, an observation that is consistent with the hypothesis that RAD6 function is required for the induction of all types of genetic alteration in misrepair mutagenesis. The reversion of these his4 alleles, together with two others of the same type, was also reduced in rev1 and rev3 mutant strains; in these, however, the extent of the reduction varied considerably with test allele used, in a manner analogous to the results in these strains for base repair substitution test alleles. The general features of UV-induced frameshift and substitution mutagenesis therefore appear quite similar, indicating that they may depend on related processes. If this conclusion is correct, greater attention must be given to integrating models which account for the production of nucleotide additions and deletions into those concerning misrepair mutagenesis.     

Mutator Activity of Petite Strains of SACCHAROMYCES CEREVISIAE

Petite strains in Saccharomyces exhibit enhanced spontaneous mutation rates of nuclear genes regardless of whether they are cytoplasmically or nuclearly inherited, or whether or not the cytoplasmic petite strains have mitochondrial DNA. In petite strains, the mutation rate for the nonsense allele lys1-1 is enhanced by a factor of 3-6 and for the missense allele his1-7 by a factor of 2 as compared with their grande counterparts. The reversion of a third allele, the putative frameshift mutation, hom3-10 , is not enhanced in a petite background. The results indicate that the spontaneous mutation rate of an organism can be altered by indirect intracellular influences.     

Emergence of a mutagenic ochre suppressor mutation under lactose selection in appm mutant ofEscherichia coli harbouring the F′lacZU118 episome

WhenEscherichia coli harbouring theppm (earlier calledadi) mutation and the F′lacZU118 episome is subjected to lactose selection in the presence of suboptimal concentrations of glycerol, Lac⁺ colonies emerge after 5–6 days. They are shown to harbour an ochre suppressor mutation at 15.15 min. Inactivation ofrecA results in approximately four-fold reduction in the response. In theppm — ochre suppressor double mutant background the leakiness of thelacZ allele carried by F′ CC105 is enhanced, suggesting misreading of a valine codon (GUG) as glutamic acid codon (GAG). This is accompanied by reversion of thelacZ mutation tolacZ ⁺ (GTG → GAG). In LB medium both the leakiness and reversion are inhibited by streptomycin. Inactivation ofrecA did not affect leakiness but abolished reversion. These data are discussed in relation to the importance of allele leakiness and restricted growth in stationary-phase (adaptive) mutagenesis.     

The Saccharomyces cerevisiae rev6-1 mutation, which inhibits both the lesion bypass and the recombination mode of DNA damage tolerance, is an allele of POL30, encoding proliferating cell nuclear antigen

The rev6-1 allele was isolated in a screen for mutants deficient for UV-induced reversion of the frameshift mutation his4-38. Preliminary testing showed that the rev6-1 mutant was substantially deficient for UV-induced reversion of arg4-17 and ilv1-92 and markedly UV sensitive. Unlike other REV genes, which encode DNA polymerases and an associated subunit, REV6 has been found to be identical to POL30, which encodes proliferating cell nuclear antigen (PCNA), the subunit of the homotrimeric sliding clamp, in which the rev6-1 mutation produces a G178S substitution. This substitution appears to abolish all DNA damage-tolerance activities normally carried out by the RAD6/RAD18 pathway, including translesion replication by DNA polymerase zeta/Rev1 and DNA polymerase eta, and the error-free, recombination-dependent component of this pathway, but has little effect on the growth rate, suggesting that G178S may prevent ubiquitination of lysine 164 in PCNA. We also find that rev6-1 mutation can be fully complemented by a centromere-containing, low copy-number plasmid carrying POL30, despite the presumed occurrence in the mutant of sliding clamp assemblies that contain between one and three G178S PCNA monomers as well as the fully wild-type species.     

Pathways of ultraviolet mutability in Saccharomyces cerevisiae. III. Genetic analysis and properties of mutants resitant to ultraviolet-induced forward mutation.

Non-allelic mutants of Saccharomyces cerevisiae with reduced capacity for ultraviolet light (UV)-induced forward mutation from CAN1 to can1 were assigned to seven distinct genetic loci, each with allele designations umr1-1, umr2-1, …, umr7-1 to indicate UV mutation resistance. Each allele complemented rev1-1, rev2-1, and rev3-1. None conferred a great deal of UV sensitivity. When assayed on yeast extract-peptone-dextrose complex growth agar, umr1, umr3, and umr7 (a mating type) were the most UV-sensitive, with a dose-reduction factor of approximately 1.2 at 10% survival. When assayed on synthetic agar lacking arginine, however, umr3 was the most UV-sensitive (dose-reduction factor of 1.5 at 10% survival). UV revertability of his5-2, lys1-1, and ura4-1 was normal in strains carrying the single genes umr4, umr5, umr6 and umr7; umr1 reduced revertibility of his5-2 and ura4-1 but not lys1-1; umr2 reduced only ura4-1 revertibility; umr3 reduced UV reversion of all three test alleles. Five a/α homozygous umr diploids (except umr1 and umr4) failed to sporulate. One of these, umr7, blocked normal secretion of alpha hormone in α segregants and could not conjugate with a strains. The phenotypes of umr mutants are consistent with the existence of branched UV mutation pathways of different specificity, some of which may function in the single RAD6-dependent error-prone pathway for repair of UV damage. Other possible pathways of action are discussed. It is also suggested that regulatory functions interacting with the mating-type locus or its gene products may play some role in UV mutagenesis or error-prone repair.     

Mutators in SACCHAROMYCES CEREVISIAE: MUT1–1, MUT1–2 and MUT2–1

The purpose of this study was to characterize two mutator stocks of yeast which were induced and selected on the basis of high spontaneous reversion rates of the suppressible "ochre" nonsense allele lys1-1. In the mutator stock VA-3, a single mutation, designated mut1-1, is responsible for the increase in the reversion rate of the ochre alleles lys1-1 and arg4-17. In stock VA-105, there are two separate mutator mutations. Tetrad analysis data showed these two loci are loosely linked. Based on complementation data, one of these mutations is at the same locus as mut1-1 and designated mut1-2. The second mutator of stock VA-105 was designated mut2-1. All three mutators are recessive. Both mut1-1 and mut1-2 give a high mutation rate for ochre nonsense suppressor (SUP) loci, but not for the ochre nonsense alleles. On the contrary, the mutation rates of the ochre alleles are greatly reduced. With the mutant mut2-1 there were mutations at both the lys1-1 site and its suppressors; mut2-1 is as effective as mut1-2 but not as effective as mut1-1 in inducing reversions of a missense mutant, his1-7. Neither mut1-1, mut1-2 nor mut2-1 were effective in inducing reversions of a putative frameshift mutation, hom3-10, or in inducing forward mutations to canavanine resistance.     

Involvement of umuDCST genes in nitropyrene-induced -CG frameshift mutagenesis at the repetitive CG sequence in the hisD3052 allele of Salmonella typhimurium

Expression of the umuDC operon is required for UV and most chemical mutagenesis in Escherichia coli. The closely related species Salmonella typhimurium has two sets of umuDC-like operons, umuDC _ST on the chromosome and samAB on a 60-MDa cryptic plasmid. The roles of theumuDC-like operons in chemically induced frameshift mutagenesis of the hisD3052 allele of S. typhimurium were investigated. Introduction of a pBR322-derived plasmid carrying umuDCST increased the rate of reversion of hisD3052, following treatment with 1-nitropyrene (1-NP) or 1,8-dinitropyrene (1,-8DNP) tenfold and fivefold, respectively, whereas it did not substantially increase the rate of reversion induced by other frameshift mutagens, i.e. 2-nitrofluorene (2NF) and 2-amino- 3-methyldipyrido[1,2-a:3 ,2-d]imi-dazole (Glu-P-1). Introduction of a pBR322-derived plasmid carrying samAB did not increase the incidence of reversion of hisD3052 observed with any of the mutagens examined. Deletion of umuDC _STSubstantially lowered the reversion rate induced by l-NP or 1,8-DNP, but it did not affect reversion induced by 2-NF, Glu-P-1 or N-hydroxyacetylaminofluorene (N-OH-AAF). Deletion of samAB had little impact on reversion incidence induced by any of the five frameshift mutagens. DNA amplification using the polymerase chain reaction technique followed by restriction enzyme analysis using BssHII, suggested that the mutations induced by the five frameshift mutagens were all CG deletions at the CGCGCGCG sequence in hisD3052. These results suggest that umuDCST, but not samAB, is involved in the -2 frameshift mutagenesis induced by l-NP and 1,8-DNP at the repetitive CG sequence, whereas neither operon participates in induction of the same type of mutations by 2-NF, Glu-P-1 or N-OH-AAF.     

Ultraviolet-Induced Reversion of cyc1 Alleles in Radiation Sensitive Strains of Yeast. II. rev2 Mutant Strains

The range of specificity of the rev2-1 mutation, an allele that reduces the frequency of ochre revertants induced by UV in Saccharomyces cerevisiae (LEMONTT 1971a), has been investigated by examining its influence on the reversion of eleven well-defined and contrasting cyc1 mutations. We have shown, in support of a suggestion of LEMONTT (1971a), that the REV2 gene product is concerned only with the reversion of ochre alleles; it plays virtually no role in the reversion of amber, missense or frameshift mutations. We have also shown that its effect is specific and confined to only some highly revertible ochre alleles. The REV2 gene product appears to enhance reversion at these sites by facilitating the conversion of two otherwise nonmutagenic photo-products into a single premutational lesion. UV-induced killing of rev2-1 strains was found to be significantly greater on fermentable rather than on nonfermentable media.     

Effect of Genes Controlling Radiation Sensitivity on Chemically Induced Mutations in SACCHAROMYCES CEREVISIAE

The effect of 16 different genes (rad) conferring radiation sensitivity on chemically induced reversion in the yeast Saccharomyces cerevisiae was determined. The site of reversion used was a well-defined chain initiation mutant mapping in the structural gene coding for iso-1-cytochrome c. High doses of EMS and HNO₂ resulted in decreased reversion of cyc1–131 in rad6, rad9 and rad15 strains compared to the normal RAD+ strains. In addition, rad52 greatly decreased EMS reversion of cyc1–131 but had not effect on HNO ₂-induced reversion; rad18, on the other hand, increased HNO ₂-induced reversion but did not alter EMS-induced reversion. When NQO was used as the mutagen, every rad gene tested, except for rad14 , had an effect on reversion; rad6, rad9, rad15, rad17, rad18, rad22, rev1, rev2 and rev3 lowered NQO reversion while rad1, rad2, rad3, rad4, rad10, rad12 and rad16 increased it compared to the RAD+ strain. The effect of rad genes on chemical mutagenesis is discussed in terms of their effect on UV mutagenesis. It is concluded that although the nature of the repair pathways may differ for UV- and chemically-induced mutations in yeast, a functional repair system is required for the induction of mutation by the chemical agents NQO, EMS and HNO₂.     

Pathways for repair of DNA damaged by alkylating agent in Escherichia coli.

Summary A strain with both the polA12 and the alk-1 mutation is only slightly more sensitive to methyl methane sulfonate (MMS) than isogenic strains with only one of the mutations. On the other hand, alk-1 recA1 double mutant is much more sensitive to MMS than are strains carrying either one of alk or recA mutation. It was suggested that the alk and the polA gene products are involved in the same DNA repair process whereas the recA function is independent from the process. The yield of MMS-induced mutation (Arg^- (argE) to Arg⁺ reversion) in alk mutant is considerably higher than that in wild type strain. Thus, the repair process in which the alk gene product is involved is relatively accurate. When MMS-treated phages were plated on MMS-treated bacteria, there were considerable increases in survival of treated phage even in recA alk double mutant. It seems that a new repair pathway, which is specific for alkylating agent-induced damages and is not dependent on the RecA function, may be induced on exposure of bacteria to the alkylating agent.     

Identification and Characterization of a Novel Yellow Leaf Mutant <i>yl1</i> in Rice

Leaf-color mutants play an important role in the study of chlorophyll metabolism, chloroplast development, and photosynthesis system. In this study, the yellow leaf 1 (yl1) rice mutant was identified from the ethyl methane sulfonate-treated mutant progeny of Lailong, a glutinous japonica rice landrace cultivated in Guizhou Province, China. Results showed that yl1 exhibited yellow leaves with decreased chlorophyll content throughout the growth period. Chloroplast development in the yl1 mutant was disrupted, and the grana lamellae was loosely packed and disordered. RNA sequencing and real-time quantitative polymerase chain reaction (qRT-PCR) analysis revealed that the chlorophyll synthesis-related genes OsCHLH, OsCHLM, OsCHLG, PORB, and YGL8, as well as the chloroplast development-related genes FtsZ, OsRpoTp, and RbcL, were down-regulated in the yl1 mutant. Genetic analysis revealed that the yellow leaf phenotype of yl1 was controlled by recessive nuclear gene. By employing the MutMap method, the mutation responsible for the phenotype was mapped to a 6.17 Mb region between 17.34 and 23.51 Mb on chromosome 3. Two non-synonymous single-nucleotide polymorphisms (SNPs) located in the gene locus LOC_Os03g31210 and LOC_Os03g36760 were detected in this region. The two SNPs were further confirmed by PCR and Sanger sequencing. The expression patterns of the two candidate genes indicated that LOC_Os03g36760 showed greater potential for functional verification. Subcellular protein localization revealed that the encoded product of LOC_Os03g36760 was localized in the nucleus, cytoplasm, and plasma membrane. These results will be useful for further characterization and cloning of the yl1 gene, and for research on the molecular mechanisms controlling biogenesis and chloroplast biochemical processes.     

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.     

Molecular Characterization of the pun Allele of the Mouse Pink-Eyed Dilution Locus

The mouse pink eyed dilution locus, p, located on chromosome 7, mediates coat and eye color. The human correlate of this gene may underlie some forms of tyrosinase-positive oculocutaneous albinism. Mutations at the p locus result in a reduction in pigmentation of the eyes and coat. Although most mutant p alleles (including all spontaneous mutations) affect only pigmentation, several mutant alleles (all radiation induced) are also associated with a variety of other phenotypes. We have focused our attention on the p^un mutant allele, a spontaneous mutation, exhibiting one of the highest reversion frequencies reported for a mammalian mutation. Using a new technique, genome scanning, we have cloned fragments of genomic DNA from the p locus that are associated with a DNA duplication in p^un DNA. These fragments can now be used to locate the p gene-encoding sequences and aid in the molecular characterization of complex mutant p alleles.     

DDG1 and G Protein α Subunit RGA1 Interaction Regulates Plant Height and Senescence in Rice (<i>Oryza sativa</i>)

Many studies have already shown that dwarfism and moderate delayed leaf senescence positively impact rice yield, but the underlying molecular mechanism of dwarfism and leaf senescence remains largely unknown. Here, using map-based cloning, we identified an allele of DEP2, DDG1, which controls plant height and leaf senescence in rice. The ddg1 mutant displayed dwarfism, short panicles, and delayed leaf senescence. Compared with the wild-type, ddg1 was insensitive to exogenous gibberellins (GA) and brassinolide (BR). DDG1 is expressed in various organs, especially in stems and panicles. Yeast two-hybrid assay, bimolecular fluorescent complementation and luciferase complementation image assay showed that DDG1 interacts with the α-subunit of the heterotrimeric G protein. Disruption of RGA1 resulted in dwarfism, short panicles, and darker-green leaves. Furthermore, we found that ddg1 and the RGA1 mutant was more sensitive to salt treatment, suggesting that DDG1 and RGA1 are involved in regulating salt stress response in rice. Our results show that DDG1/DEP2 regulates plant height and leaf senescence through interacting with RGA1.     

Genetic control of chalcone-flavanone isomerase activity in Callistephus chinensis

A mutant blocked in anthocyanin synthesis leads to an accumulation of 4,2,4,6-tetrahydroxy-chalcone-2-glucoside (isosalipurposide) in blossoms of Callistephus chinesis (L.) Nees, whereas in geno-types with the wild-type allele, higher oxidized flavonoids and anthocyanins are synthesized. Measurements of chalcone-flavanone isomerase activity of 18 lines of Callistephus chinensis showed a clear correlation between accumulation of chalcone in the recessive genotypes (ch ch) and deficiency of this enzyme activity. Both the chemogenetic and the enzymologic evidence lead to the following conclusions: 1. The first product of the synthesis of the flavonoid skeleton should be tetrahydroxychalcone.-2. The chalcone-flavanone isomerase catalyzes the formation of flavanone from chalcone in a stereospecific way and there-with furnishes the substrate for the further reactions in the flavonoid biosynthesis.Abbreviations EGME ethylene glycol monomethyl ether - HOAc acetic acid - MeOH methanol - PVP polyvinylpyrrolidone - TBA tert. butanol-acetic acid-water, 3:1:1 - TLC thin-layer chromatography