Identification of the genetic alteration at the molecular level of ultraviolet light-induced ad-3B mutants in Neurospora crassa

Comparison of the spectra of genetic damage in N4-hydroxycytidine-induced ad-3 mutations between nucleotide excision repair-proficient and -deficient heterokaryons of Neurospora crassa

A comparison has been made of the mutagenic effects of N4-hydroxycytidine (HC) in the adenine-3 (ad-3) region of two-component heterokaryons of Neurospora crassa: nucleotide excision repair-proficient (uvs-2+/uvs-2+) heterokaryon 12 (H-12) and nucleotide excision repair-deficient (uvs-2/uvs-2) heterokaryon 59 (H-59). HC was found to produce mutations predominantly, if not exclusively, by AT to GC base-pair transitions in Escherichia coli strain K12 by Janion and Glickman (1980, Mutation Res., 72, 43-47) and Sledziewska-Gojska et al. (1992, Mutagenesis, 7, 41-46). The ad-3 forward-mutation, specific-locus assay system permits the recovery of ad-3A and/or ad-3B mutants resulting from gene/point mutation, multiple-locus mutation, and multilocus deletion mutation. Uvs-2, which is homokaryotic in H-59, results in a recovery of HC-induced ad-3 forward mutations at a frequency in H-59 that is comparable to that found in H-12. Genetic analysis of ad-3 mutants recovered from experiments with HC treatment demonstrates that predominantly gene/point mutations were found in both strains: 99.3% (540/544) in H-12, and 97.4% (531/545) in H-59. Genetic analysis of allelic complementation among the ad-3BR mutations demonstrated that HC induced the highest percentage of complementing mutants ever found with base analogs both in H-12 (99.7% [328/329]) and H-59 (91.2% [290/318]). As a result of these findings, the majority of HC-induced ad-3 mutations are postulated to have resulted from missense mutations. Thus, we conclude that the results in Neurospora are consistent with the observations in E. coli strain K-12, where HC induces predominantly AT to GC base-pair transitions.

Utilization of the specific-locus assay in the ad-3 region of two-component heterokaryons of Neurospora for risk assessment of environmental chemicals

The utilization of the specific-locus assay in the ad-3 region of two-component heterokaryons of Neurospora crassa is compared with that of other eukaryotic assay systems for the evaluation of the mutagenic effects of environmental chemicals. In contrast to other in vitro specific-locus assays, the Neurospora assay can detect mutations not only at the ad-3A and ad-3B loci but also recessive lethal mutations elsewhere in the genome. Mutational damage in this system can be characterized readily by means of classical genetic techniques involving heterokaryon tests to determine genotype, and allelic complementation among ad-3BR mutations. The percentages of ad-3BR mutations showing allelic complementation with polarized or nonpolarized complementation patterns provide a presumptive identification of the genetic alterations at the molecular level in individual mutants. Dikaryon and trikaryon tests (using 3 strains carrying multilocus deletion mutations as tester strains) distinguish ad-3 mutations resulting from gene/point mutation, multilocus deletion mutation, and various types of multiple-locus mutation. The array of ad-3 mutations recovered from forward-mutation experiments can be expressed in terms of Mutational Spectra, which make it possible to make comparisons of mutational types between different doses of the same mutagen, different mutagens, or the effects of the same mutagen on different strains. Another important feature of this specific-locus assay system is that the effects of mutagens can be studied in both DNA excision repair-proficient (H-12) and -deficient (H-59) two-component heterokaryons to evaluate both quantitative and qualitative differences between the spectra of induced ad-3 mutations. The utilization of this assay on large numbers of environmental chemicals has shown that some chemicals produce predominantly, or exclusively, gene/point mutations, whereas other agents produce both gene/point mutations and multilocus deletion mutations in H-12. When the mutagenic effects of the same chemicals were compared in H-12 and H-59, marked differences between forward-mutation frequencies and Mutational Spectra of ad-3 mutations were detected.

2-Amino-N6-hydroxyadenine induces gene/point mutations and multiple-locus mutations, but not multilocus deletion mutations, in the ad-3 region of a two-component heterokaryon of Neurospora crassa

The mutagenicity of 2-amino-N6-hydroxyadenine (AHA) has been studied in Neurospora crassa by treating a two-component heterokaryon (H-12) and recovering specific-locus mutations induced in the ad-3 region. This assay system permits the identification of ad-3A and/or ad-3B mutants resulting from gene/point mutations, multilocus deletion mutations, and multiple-locus mutations of various genotypes, involving one or both loci. Genetic characterization of the ad-3 mutants recovered from experiments with AHA in H-12 shows that 98.9% (270/273) of the ad-3 mutants are gene/point mutations (ad-3R), 1.1% (3/270) are unknowns, and none is a multilocus deletion mutation (ad-3IR). Among the gene/point mutations, 3.3% (9/273) are multiple-locus mutations (gene/point mutations with a closely-linked recessive lethal mutation [ad-3R + RLCL]). Another 25.3% (69/273) are multiple-locus mutations with a recessive lethal mutation located elsewhere in the genome [ad-3R + RL]. Heterokaryon tests for allelic complementation among the ad-3BR mutants showed that 90.8% (139/153) of the mutants were complementing, and 20.3% (31/153) were leaky. In addition, 32.5% (38/117) of the ad-3AR mutants were leaky. These data are consistent with the hypothesis that AHA produces specific-locus mutations in the ad-3 region of N. crassa by base-pair substitution. The data from the present experiments are compared with the data for 2-aminopurine (2AP)-induced ad-3 mutants in H-12 (de Serres and Brockman, 1991). Whereas, 2AP is a weak mutagen in H-12, AHA is extremely potent (Brockman et al., 1987). In contrast with 2AP, AHA induces ad-3 mutants exclusively by gene/point mutation in H-12. We conclude that whereas AHA induces ad-3 mutants predominantly by AT to GC base-pair transitions, 2AP induces ad-3 mutants by a wide variety of mechanisms including: (1) AT to GC and GC to AT base-pair transitions, (2) frameshift mutations, (3) other, as yet unidentified, intragenic alterations, (4) small multilocus deletion mutations, and (5) multiple-locus ad-3R mutations with closely linked recessive lethal mutations.

X-ray-induced specific-locus mutations in the ad-3 region of two-component heterokaryons of Neurospora crassa. VII. Genetic lesions resulting in gene/point mutations at the ad-3B locus have different dose-response relationships

Genetic characterization of X-ray-induced ad-3 mutants, induced in a two-component heterokaryon (H-12) of Neurospora crassa, has been performed to determine genotype, patterns of allelic complementation, and leakiness, and to distinguish gene/point mutations from multilocus deletions and multiple locus mutations (de Serres, 1989c, 1990a). The array of genotypes in the classes and subclasses in the spectrum of ad-3 mutants induced by a mutagenic agent constitute its mutagenicity profile; for X-rays this profile consists of 29 different genotypes. In the present paper, the data on gene/point mutations induced at the ad-3B locus (designated ad-3BR mutations) have been tabulated as a function of X-ray dose to determine the dose-dependent relationships of complementing and noncomplementing mutants. This analysis has shown that the overall percentages of mutants showing allelic complementation and the percentages of complementing mutants with nonpolarized patterns (both leaky and nonleaky) and noncomplementing mutants were dose-dependent; the former class decreased with increasing X-ray dose, and the latter class increased with increasing X-ray dose. The percentages of complementing mutants with polarized patterns were X-ray dose-independent. In addition, an unexpectedly high frequency of mutants with nonpolarized complementation patterns are discontinuous and probably result from multiple-site mutations.

Classical and molecular genetic analyses of his-3 mutants of Neurospora crassa. II. Southern blot analyses and molecular mechanisms of mutagenicity

Previous studies (Overton et al., Mutation Res., 1989) on specific revertibility of 81 his-3 mutants have shown a correlation between complementation pattern and presumed genetic alteration similar to that shown by ad-3B mutants. In the present study, restriction enzyme analyses were used to further characterize the genetic alterations in individual his-3 mutants. The restriction fragment banding patterns of the majority of mutants were identical with that shown by wild-type 74-OR23-1A and were consistent with expectations based on previous data suggesting that they resulted from single base-pair alterations (Overton et al., Mutation Res., 1989). His-3 mutants with altered banding patterns were only found among those with polarized complementation patterns or noncomplementing mutants. One of the mutants with a polarized complementation pattern, 1-189-83, and another noncomplementing mutant, 1-189-85, are associated with genetic alterations proximal to the his-3 locus. In one other mutant, 1-226-565 (with a polarized complementation pattern), an insertion of approx. 2 kb has occurred in the proximal region of the his-3 locus. Two other mutants, 1-155-270 and 1-155-276 (both noncomplementing), contained a large insertion of approx. 12.8 kb in the proximal region of the his-3 locus.

Molecular and classical genetic analyses of his-3 mutants of Neurospora crassa. I. Tests for allelic complementation and specific revertibility

A collection of 81 his-3 mutants of Neurospora crassa was analyzed in assays for allelic complementation and specific revertibility. In these studies, the linearity of the complementation map of the his-3 cistron (Webber, 1965) was confirmed and mutants were classified as complementing with non-polarized or polarized complementation patterns, or non-complementing. In the assays for spontaneous or induced revertibility, 89% (71/80) of the mutants reverted either spontaneously or after treatment with the chemical mutagens N-methyl-N'-nitro-N-nitrosoguanidine, ethyl methanesulfonate, 2-methoxy-6-chloro-9-(3-[ethyl-2-chloroethyl]aminopropylamino) acridine dihydrochloride, nitrous acid or hydroxylamine. The frequency of revertible mutants among the non-polarized complementing mutants was 96% (45/47), and 79% (15/19) for the polarized complementing and 79% (11/14) for the non-complementing mutants. The results of these classical genetic assays for allelic complementation and specific revertibility suggest a correlation between complementation pattern and presumptive genetic alterations at the molecular level among his-3 mutants similar to that found with ad-3B mutants induced by nitrous acid (Malling and de Serres, 1967), ethyl methanesulfonate (Malling and de Serres, 1968), or ultraviolet (Kilbey et al., 1971).

Induction and isolation of mutants in fungi at low mutagen doses

Since the yield of mutants per surviving cell increases in general with increasing dose of mutagen, it has often been concluded in the literature that it is the most efficient to apply high mutagen doses so that most spores are killed. As high doses of mutagen produce chromosome rearrangements and unnoticed mutations which disturb the genetic background, the relationship between mutant frequency and survival was analyzed with Aspergillus nidulans as a model. It is shown that for different types of mutants the highest mutant yield is obtained at low mutagen doses (20-50% survival). Mutant frequency increases with increasing dose of mutagen but levels off and even decreases at higher dosages. There is no simple linear relationship between mutant frequency and the logarithm of the mutagen dose or the logarithm of the surviving fraction. If appropriate enrichment procedures are also available auxotrophic mutants can best be isolated at low doses of mutagen. Taking into account the disturbance of the genetic background, mutation induction should be done preferentially at a survival level of at least 70%.

Mutagenesis at the ad-3A and ad-3B loci in haploid UV-sensitive strains of Neurospora crassa. II. Comparison of dose-response curves for inactivation and mutation induced by UV

UV-induced inactivation and induction of mutations at the ad-3A and ad-3B loci of Neurospora crassa have been compared among 7 different UV-sensitive strains and a standard wild-type strain. The 7 strains show varying degrees of sensitivity to UV-induced inactivation, with the relative sensitivity being: uvs-2 greater than uvs-3 greater than uvs-4 greater than uvs-6 greater than upr-1 greater uvs-5 greater than uvs-1. Studies on the induction of ad-3 mutants by UV show that the 2 excision-repair deficient mutants uvs-2 and upr-1 exhibit enhanced ad-3 mutant frequencies, while uvs-4 and uvs-5 exhibit reduced ad-3 mutant frequencies, and uvs-3 completely eliminates UV mutagenesis. The ad-3 mutation-induction curves obtained with uvs-1 or uvs-6 are not significantly different from that found with the wild-type strain.

Mutation-induction in repair-deficient strains of Neurospora

Various mutants sensitive to UV-induced inactivation have been used to study the process of spontaneous and induced mutation in the ad-3 region of Neurospora crassa. Studies on haploid strains have shown that the process of mutation-induction in the ad-3 region is under genetic control. Studies on two-component heterokaryons have shown that this control effects both point mutations and multilocus deletions. Comparisons made between an excision-repair deficient two-component heterokaryon (59) have shown that the level of effect is markedly mutagen-specific. All possible effects on the process of mutation-induction in the ad-3 region have been found in the strains tested.

Effects of chemical and physical mutagens on the frequency of a large genetic duplication in Salmonella typhimurium. I. Induction of duplications

In Salmonella typhimurium a simple selection has been described to detect bacteria that are merodiploid for almost one-third of the chromosome. The selective procedure is based upon improved utilization of L-malate as the sole carbon source in merodiploid strains. The spontaneous frequency of the duplication in haploid strains is approximately 10(-4) per cell plated. Following the exposure of a haploid strain to mutagenic agents, there is a dose-dependent increase in the duplication frequency above the spontaneous level. In this paper we describe the induction of genetic duplications in Salmonella typhimurium by X-rays, ultraviolet light (UV), ethyl methanesulfonate (EMS), nitrous acid, and the azaacridine half mustard, ICR-372.

Azaguanine-resistant mutants induced by several mutagens in a neurospora heterokaryon

This paper reports the development of a new system for the detection of forward mutations in a heterokaryon of Neurospora crassa. This system, designed to detect a wide variety of genetic alterations, is based upon the detection of 8-azaguanine-resistant mutants in an adenine-requiring heterokaryon carrying the aza-3 gene. Induction of mutations in the aza-3 gene was detected after treatment of conidia with ultraviolet light, X-rays, ethyl methanesulfonate (EMS), or the acridine mustard, ICR-170. The pattern of appearance of mutant colonies and various factors in mutant selection are discussed.