The uvsC and uvsE genes of Aspergillus nidulans are not required for the mutagenic repair of UV damage

The uvsC gene of Aspergillus nidulans is a homolog of the RAD51 gene of Saccharomyces cerevisiae. However, with respect to its effects on UV mutagenesis, it differs from the yeast gene, since it seems to be required for UV mutagenesis; however, this conclusion is based only on data from resting conidia. To further clarify the functional role of the uvsC gene, we tested the UV mutability of strains bearing a uvsC mutation in resting as well as in germinating conidia, by the p-fluoro-phenyl-alanine resistance test. We also evaluated the mutability of the uvsE mutant which belongs to the same epistatic group. Our results show that the uvsC and uvsE genes do not have a significant role in the mutagenic UV-repair pathway. Received: 20 January 1998 / Accepted: 22 April 1998     

Mutator activity in uvs mutants of Aspergillus nidulans

Summary The frequency of selenate-resistant spontaneous mutants was determined among the conidia of two uvs ⁺, two allelic uvsB, one uvsD, three allelic uvsC and three allelic uvsE strains of Aspergillus nidulans. In the uvsB, uvsD, uvsC and uvsE mutants the median frequencies of mutation were respectively 1.7, 1.8, 8.7 and 4.0 times as high as in the uvs ⁺ strains. The selenate resistance resulted from mutation at the chromosomal loci sB or sC. It is concluded that the uvs alleles enhance spontaneous mutation in chromosomal genes.     

Two uvs genes of Aspergillus nidulans with different functions in error-prone repair: uvsI, active in mutation-specific reversion, and uvsC, a recA homolog, required for all UV mutagenesis

Two genes of Aspergillus nidulans are known to function in UV mutagenesis, but have been assigned to different epistasis groups: uvsC, which is also required for meiosis and mitotic recombination, and uvsI, which may have no other function. To clarify their role in error-prone repair and to investigate their interaction, uvsI and uvsC single and uvsI;uvsC double mutant strains were further tested for mutagen sensitivities and characterized for effects on mutation. Spontaneous and induced frequencies were compared in forward and reverse mutation assays. All results confirmed that uvsI and uvsC are members of different epistasis groups, and demonstrated that these uvs mutants have very different defects in UV mutagenesis. The uvsI strains showed wild-type frequencies in all forward mutation tests, but greatly reduced spontaneous and UV-induced reversion of some, but not other, point mutations. In contrast, uvsC had similar effects in all assay systems: namely pronounced mutator effects and greatly reduced UV mutagenesis. Interestingly, the uvsI;uvsC double mutant strains differed from both single mutants; they clearly showed synergism for all types of reversion tested: none were ever obtained spontaneously, nor after induction by UV or EMS (ethylmethane sulfonate). Based on these results, we conclude that uvsI is active in a mutation-specific, specialized error-prone repair process in Aspergillus. In contrast, uvsC, which is now known to show sequence homology to recA, has a basic function in mutagenic UV repair in addition to recombinational repair, similar to recA of Escherichia coli.     

Isolation and Characterization of Conditional Alleles of Bacteriophage T4 Genes uvsX and uvsY

The bacteriophage T4 uvsW, uvsX and uvsY gene functions are required for wild-type levels of recombination and for normal survival and mutagenesis after treatments with ultraviolet (UV) and ionizing radiations. The ability of uvsX and uvsY mutations to suppress the lethality of gene 49 mutations was used to select temperature-sensitive and amber alleles of these two genes. (uvsW mutations do not suppress gene 49 mutations.) A simple and powerful complementation test was developed to assist in assigning uvs mutations to genes. The amber alleles of uvsX and uvsY behave as simple null alleles, fully suppressing a gene 49 defect, enhancing UV killing and abolishing UV mutagenesis. However, the properties of the ts alleles of uvsX and uvsY demonstrated that suppression of a gene 49 defect, sensitivity to UV-induced inactivation and UV mutability can be partially uncoupled. These results prompt the hypothesis that radiation mutagenesis occurs during DNA chain elongation past template damage within a recombinational intermediate rather than within a conventional replication fork.     

Two uvs genes of Aspergillus nidulans with different functions in error-prone repair: uvsI , active in mutation-specific reversion, and uvsC , a recA homolog, required for all UV mutagenesis

Two genes of Aspergillus nidulans are known to function in UV mutagenesis, but have been assigned to different epistasis groups: uvsC, which is also required for meiosis and mitotic recombination, and uvsI, which may have no other function. To clarify their role in error-prone repair and to investigate their interaction, uvsI and uvsC single and uvsI;uvsC double mutant strains were further tested for mutagen sensitivities and characterized for effects on mutation. Spontaneous and induced frequencies were compared in forward and reverse mutation assays. All results confirmed that uvsI and uvsC are members of different epistasis groups, and demonstrated that these uvs mutants have very different defects in UV mutagenesis. The uvsI strains showed wild-type frequencies in all forward mutation tests, but greatly reduced spontaneous and UV-induced reversion of some, but not other, point mutations. In contrast, uvsC had similar effects in all assay systems: namely pronounced mutator effects and greatly reduced UV mutagenesis. Interestingly, the uvsI;uvsC double mutant strains differed from both single mutants; they clearly showed synergism for all types of reversion tested: none were ever obtained spontaneously, nor after induction by UV or EMS (ethylmethane sulfonate). Based on these results, we conclude that uvsI is active in a mutation-specific, specialized error-prone repair process in Aspergillus. In contrast, uvsC, which is now known to show sequence homology to recA, has a basic function in mutagenic UV repair in addition to recombinational repair, similar to recA of Escherichia coli. Received: 23 September 1996 / Accepted: 2 December 1996     

Partial suppression of the LexA phenotype by mutations (rnm) which restore ultraviolet resistance but not ultraviolet mulability to Escherichia coli B/r uvrA lexA

In Escherichia coli, lexA mutations eliminate expression of UV-inducible functions, causing pleiotropic effects which include sensitivity to ultraviolet (UV) light and loss of UV mutability. Selection for UV resistance, after 5-bromouracil (BU) treatment of E. coli B/r uvr A lexA-102, has yielded derivatives more resistant than lexA but still refractory to UV mutagenesis. The mutation responsible for the UV-resistant UV-nonmutable phenotype (rnm) is cotransducible with malB to about the same extent as is lexA-102 and is tightly linked to lexA-102 in at least one strain. The rnm mutation may therefore be an intragenic partial suppressor of the LexA phenotype. In addition to increased UV resistance and lack of UV mutability, rnm strains show improved ability to perform postreplication repair and to control postirradiation DNA degration compared to the lexA parent. We ascribe the properties of rnm mutants to their having reacquired control of Exonuclease V activity without having reacquired UV-inducible error-prone postreplication repair. We relate our results to current interpretations of UV mutagenesis and to models of coordinate regulation of UV-inducible functions.     

Ultraviolet Mutagenesis in Strains of <Emphasis Type="Italic">E. coli</Emphasis> deficient in DNA Polymerase

CERTAIN mutations in Escherichia coli which cause increased sensitivity to ultraviolet light (UV) drastically change the UV mutability of the sensitive strain. Strains lacking the ability to excise pyrimidine dimers, for example, exhibit greatly increased UV mutability, producing induced mutations at doses of UV far smaller than those required to induce mutations in wild type strains^{1, 2}. Mutants owing their UV sensitivity to reduced ability to perform genetic recombination, on the other hand, show reduced mutability in response to UV compared with the wild type and some (recA or exrA strains, for example) are stable to UV, producing no detectable induced mutations at any dose^3–5. Analysis of UV mutagenesis in such strains has led to the hypothesis that most UV-induced mutations in E. coli are errors in the recombinational repair of gaps in the daughter-strand which are located opposite unexcised pyrimidine dimers^{6, 7}.     

Plate assay for chemical- and radiation-induced mutagenesis of CAN1 in yeast as a function of post-treatment DNA replication: the effect of rad6-1

An agar post-treatment method was used to monitor levels of ultraviolte light-and hydrazine-induced mutagenesis at CAN1 in Saccharomyces cerevisiae as a function of post-treatment cell division prior to selection for canavanine-resistant mutants with a top-agar overlay containing canavanine. The advantage of this method is that its permits reliable measurements of mutation induction during the early period before, during, and after the first round of post-treatment DNA replication. In strains that are wild-type for DNA repair, ultraviolet light mutagenesis appears to be a pre-replicative phenomenon, while mutation by hydrazine involves a replicative or post-replicative mechanism. Most chemical mutagenesis in yeast requires a functional RAD6 gene. Hydrazine mutability is also reduced by rad6-1, suggesting a possible misrepair mechanism.     

Mutagenic DNA repair in Escherichia coli XIII Proofreading exonuclease of DNA polymerase III holoenzyme is not operational during UV mutagenesis

We have introduced a mutD5 mutation (which results in defective 3′–5′-exonuclease activity of the ϵ proofreading subunit of DNA polymerase III holoenzyme) into excision-defective Escherichia coli strains with varying SOS responses to UV light. MutD5 increased the spontaneous mutation frequency in all strains tested, including recA430, umuC122::Tn5, and umuC36 derivatives. It had no effect of UV mutability or immutability in any strain or on misincorporation revealed by delayed photoreversal in UV-irradiated umuC36, umuC122::Tn5, or recA430 bacteria. It is concluded that the ϵ proofreading subunit of DNA polymerase III holoenzyme is excluded, inhibited, or inoperative during misincorporation and mutagenesis after UV.     

UV-light-induced mutability in Salmonella strains containing the umuDC or the mucAB operon: evidence for a umuC function

Multicopy plasmids carrying either the umuDC operon of Escherichia coli or its analog mucAB operon, were introduced into Ames Salmonella strains in order to analyze the influence of UmuDC and MucAB proteins on repair and mutability after UV irradiation. It was found that in uvr+ bacteria, plasmid pICV80:mucAB increased the frequency of UV-induced His+ revertants whereas pSE117:umuDC caused a smaller increase in UV mutagenesis. In delta uvrB bacteria, the protective role of pSE117 against UV killing was weak, and there was a great reduction in the mutant yield. In contrast, in these cells, pICV80 led to a large increase in both cell survival and mutation frequency. These results suggest that in Salmonella, as in E. coli, MucAB proteins mediate UV mutagenesis more efficiently than UmuDC proteins do. Plasmid pICV84:umuD+ C- significantly increased UV mutagenesis of TA2659: delta uvrB cells whereas in them, pICV77:mucA+ B- had no effect on mutability indicating the presence in Salmonella TA2659 of a gene functionally homologous to umuC.     

Bacteriophage T4 DNA polymerase determines the amount and specificity of ultraviolet mutagenesis

Summary Ultraviolet mutagenesis in bacteriophage T4 proceeds via error-prone repair (EPR) and requires the functional integrity of the uvsWXY system which mediates genetic recombination, recombinational repair, and mutability by diverse DNA damaging agents. Current opinion holds that mutagens acting through EPR generate DNA damage which blocks the progress of the replication complex and that EPR consists of the facilitated bypass of such inaccurate, damaged templates. This notion predicts that the T4 DNA polymerase (encoded by gene 43) mediates EPR in UV irradiated phage T4. This prediction is verified by the discovery that gene 43 mutations often enhance or reduce UV mutagenesis (which is scored by the induction of r mutants) and sometimes change its specificity.     

TheisfA mutation inhibits mutator activity and processing of UmuD protein inEscherichia coli recA730 strains

Further studies on theisfA mutation responsible for anti-SOS and antimutagenic activities inEscherichia coli are described. We have previously shown that theisfA mutation inhibits mutagenesis and other SOS-dependent phenomena, possibly by interfering with RecA coprotease activity. TheisfA mutation has now been demonstrated also to suppress mutator activity inE. coli recA730 andrecA730 lexA51(Def) strains that constitutively express RecA coprotease activity. We further show that the antimutator activity of theisfA mutation is related to inhibition of RecA coprotease-dependent processing of UmuD. Expression of UmuD' from plasmid pGW2122 efficiently restores UV-induced mutagenesis in therecA730 isfA strain and partially restores its mutator activity. On the other hand, overproduction of UmuD'C proteins from pGW2123 plasmid markedly enhances UV sensitivity with no restoration of mutability.     

Ribozyme-mediated REV1 inhibition reduces the frequency of UV-induced mutations in the human HPRT gene

In yeast, mutations induced by UV radiation are dependent on the function of the Rev1 gene product, a Y-family DNA polymerase that assists in translesion replication with potentially mutagenic consequences. Human REV1 has been cloned, but its role in mutagenesis and carcinogenesis remains obscure. To examine the role of REV1 in UV mutagenesis in human cells and to evaluate its potential as a therapeutic target to prevent such mutations, we developed a ribozyme that cleaves human REV1 mRNA in vitro. Stable expression of the ribozyme in human cells reduced the target REV1 mRNA up to 90%. We examined the cytotoxic and mutagenic response to UV of seven independent clones that had reduced levels of endogenous REV1 mRNA. In each case, the clonogenic survival after UV was not different from that of the parental cell strains. In contrast, the UV-induced mutant frequencies at the endogenous HPRT locus were reduced up to 75% in cells with reduced levels of REV1 mRNA. The data support the idea that targeting the mutagenic translesion DNA replication pathway can greatly reduce the frequency of induced mutations.     

Synergistic effect of an Escherichia coli mutator gene on mutagenesis by ultraviolet radiation and by alkylating agents

E. coli strains differing in a gene responsible for high spontaneous mutability (mut HI) were compared for their mutability by UV radiation and by the alkylating agents ethyl methanesulfonate and methyl methanesulfonate. All three exogenous mutagenic agents induced significantly higher frequencies of mutants with impaired carbohydrate-fermenting ability when the mutator allele rather than the wild-type allele was present. Thus the mut HI gene product possibly increases the probability of replication error due to alterations in the structure of the template strand of DNA. An attempt to detect an synergistic effect for UV-induced suppressor mutations was unsuccessful. The failure may have been due to the particular method used for scoring this type of mutation.