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.     

Mutagenesis at the ad-3A and ad-3B loci in haploid UV-sensitive strains of Neurospora crassa. IV. Comparison of dose-response curves for MNNG, 4NQO and ICR-170 induced inactivation and mutation-induction

The genetic effects of MNNG, 4NQO and ICR-170 have been compared on 5 different UV-sensitive strains and a standard wild-type strain of Neurospora crassa with regard to inactivation and the induction of forward-mutations at the ad-3A and ad-3B loci. Whereas all UV-sensitive strains (upr-1, uvs-2, uvs-3, uvs-5 and uvs-6) are more sensitive to inactivation by MNNG and ICR-170 than wild-type, only uvs-5 shows survival comparable to wild-type after 4NQO treatment, all other strains are more sensitive to 4NQO. In contrast to the effects on inactivation, a wide variety of effects were found for the induction of ad-3A and ad-3B mutations: higher forward-mutation frequencies than were found in wild-type were obtained after treatment with MNNG or 4NQO for upr-1 and uvs-2, no significant increase over the spontaneous mutation frequency was found with uvs-3 after MNNG, 4NQO or ICR-170 treatment; mutation frequencies comparable to that found in wild-type were obtained with uvs-6 after MNNG, 4NQO or ICR-170 treatment and with upr-1 after ICR-170 treatment. Lower forward-mutation frequencies than were found in wild-type were obtained with uvs-2 after ICR-170 treatment and with uvs-5 after MNNG, 4NQO or ICR-170 treatment. These data clearly show that the process of forward-mutation at the ad-3A and ad-3B loci is under genetic control by mutations at other loci (e.g. upr-1, uvs-2, uvs-3, uvs-5 and uvs-6) and that the effect is markedly mutagen-dependent.     

Mutagenesis at the ad-3A and ad-3B loci in haploid UV-sensitive strains of Neurospora crassa. VI. Genetic characterization of ad-3 mutants provides evidence for qualitative differences in the spectrum of genetic alterations between wild-type and nucleotide excision-repair-deficient strains

Genetic characterization of ad-3B mutants induced in wild-type and UV-sensitive strains has revealed qualitative differences between the spectra of genetic alterations at the molecular level. Ad-3B mutants induced in the two nucleotide excision-repair-deficient strains upr-1 and uvs-2 (Worthy and Epler, 1973) had significantly lower frequencies of nonpolarized complementation patterns and higher frequencies of noncomplementing mutants than ad-3B mutants induced in the wild-type strain in samples induced by either UV, gamma-rays, 4NQO or MNNG. In these same samples ad-3B mutants induced in uvs-4, uvs-5 or uvs-6 did not differ significantly from those induced in the wild-type strain. After ICR-170 treatment, ad-3B mutants induced in the UV-sensitive strains did not differ significantly from those induced in wild-type. The comparisons in the present and previous studies demonstrate that the process of mutation-induction in the ad-3 region is under the control of other loci that not only alter mutant recovery quantitatively (de Serres, 1980; Schüpbach and de Serres, 1981; Inoue et al., 1981a, b) but also qualitatively. These data have important implications for comparative chemical mutagenesis, since the spectrum of genetic alterations produced by a given agent can be modified markedly as a result of defects in DNA repair.     

Mutagenesis at the ad-3A and ad-3B loci in haploid UV-sensitive strains of Neurospora crassa. I. Development of isogenic strains and spontaneous mutability

7 different mutations that confer sensitivity to inactivation by ultraviolet light have been investigated for their effect on spontaneous mutation at the ad-3A and ad-3B loci in haploid strains of Neurospora crassa. The collection and development of strains isogenic to wild-type 74A is described as well as experiments to determine the effects of each mutation on the spontaneous ad-3 mutation frequency. 6 of the strains showed spontaneous ad-3 mutant frequencies not significantly different from the wild-type strain. Strain uvs-3 is highly mutable spontaneously with marked variation from experiment to experiment; the mean mutation frequency in this strain in about 40-fold higher than that found in the wild-type strain.     

Epistasis, photoreactivation and mutagen sensitivity of DNA repair mutants upr-1 and mus-26 in Neurospora crassa

Double mutants were constructed combining mus-26, formerly designated uvs-(SA3B), with other UV-sensitive mutants. Tests of sensitivity of these double mutants to UV and to chemical mutagens revealed that mus-26 and upr-1 belong to the same epistatic group. The UV dose-response curve of mus-26 showed a characteristic plateau in the range of 100-200 J/m2. The same characteristic was also shown in the dose-response curves of upr-1 and the double mutant, upr-1 mus-26. Photoreactivation of UV damage in mus-26, upr-1 and upr-1 mus-26 was defective but not null. Assays were made of the reversion rate of ad-8 in strains that also carried UV-sensitive mutations. The reversion frequencies of the strains with upr-1 and upr-1 mus-26 were very low for the UV dose range below 300 J/m2, similarly to mus-26. Previously reported homozygous sterility of mus-26 was not caused by the mus-26 locus itself, and fertile strains were obtained among progeny. The results of this study suggest that mus-26 and upr-1 have similar properties in DNA repair.     

Biochemical basis of radiation-sensitivity in mutants of Neurospora crassa

The available UV-sensitive mutants of Neurospora crassa were examined for their ability to excise and photoreactive cytosine-containing dimers invivo. All strains exhibited in vivo photoreactivation, including upr-1, which was originally thought to be deficient in photoreactivation. Two strains, uvs-2 and upr-1 were shown to be deficient in excision repair; uvs-3 was shown to contain a residual amount of excision capabilit. The remaining strains, uvs-1, uvs-5, and uvs-6, were normal in their ability to excise dimers. Based on these results, tentative analogies were drawn between the Neurospora mutants and the known classes of UV-sensitive mutants in E. coli. Accordingly, the N. crassa mutants were classified as uvs-1, -lon; uvs-2, -uvr; uvs-3, -uvr (rec?); uvs-5, -lon; uvs-6, -rec; and upr-1, -uvr. A comparison was made between the biochemical responses and the available published data on mutation induction in the Neurospora mutants. Althoughsome relationships were seen between repair defects and mutation induction, too little data were available for any definitive conclusions.     

A new ultraviolet-light sensitive mutant of Neurospora crassa with unusual photoreactivation property

A mutant, uvs-(SA3B), which shows high sensitivity to UV light segregated among the progeny in a back-cross of a presumptive MMS-sensitive mutant to a wild-type strain. At 37% survival, this mutant was approximately 5 times more sensitive to UV and also 6 times more sensitive to 4-NQO than the wild type. But it was only slightly sensitive to gamma-ray, MMS, MNNG, MTC and histidine. It showed an unusual photoreactivation response. Its time course of photorecovery was similar to the photoreactivation-defective strain upr-1 of Neurospora crassa. Mutation induction by UV at the ad-3 loci in this mutant strain was lower than that at the same loci in the wild-type strain. The uvs-(SA3B) mutant maps between met-1 and col-4 in linkage group IV, and it was not allelic with the mutagen-sensitive mutant mus-8 which is located in this area. We have concluded, therefore, that uvs-(SA3B) has resulted from mutation in a new DNA-repair gene. This new mutant was barren in homozygous crosses.     

Effect of the homokaryotic state of the uvs-2 allele in Neurospora crassa on formaldehyde-induced killing and ad-3 mutation

Formaldehyde was tested for its killing and mutagenic activities in the ad-3 forward-mutation test in Neurospora crassa. The test was conducted in 3 two-component heterokaryons (dikaryons) of N. crassa in order to determine the effect of the uvs-2 allele, which causes a defect in nucleotide excision repair, on formaldehyde-induced killing and the induction of ad-3 mutants. These dikaryons were homokaryotic for uvs-2+ (H-12), homokaryotic for usv-2 (H-59), and heterokaryotic for uvs-2 (H-71). Formaldehyde induced killing and ad-3 mutants in H-12, but the presence of uvs-2 in the homokaryotic state (H-59) resulted in a 9-fold increase in killing and a 40-fold increase in the induction of ad-3 mutants. This increased sensitivity to formaldehyde-induced killing and mutation conferred by uvs-2 in the homokaryotic state (H-59 vs. H-12) is similar to that noted by others in Escherichia coli. Salmonella typhimurium and Saccharomyces cerevisiae. The dikaryon heterokaryotic for uvs-2 (H-71) has the same sensitivity to formaldehyde-induced ad-3 mutation as H-12, indicating that uvs-2 is recessive to uvs-2+.     

X-ray-induced specific-locus mutations in the ad-3 region of two-component heterokaryons of Neurospora crassa. IV. Irreparable mutants of genotype ad-3A and ad-3B result from multilocus deletion and an unexpectedly high frequency of multiple-locus mutations

The induction of specific-locus mutations in the ad-3 region of Neurospora crassa after X-irradiation was studied in a two-component heterokaryon to determine: (1) the ratio of reparable ad-3 mutants (presumed gene/point mutations, designated ad-3R) to irreparable ad-3 mutants (presumed multilocus deletions, designated ad-3IR), and (2) the induction kinetics of each class (Webber and de Serres, 1965). More extensive genetic tests made subsequently (de Serres, 1989a) on the 832 X-ray-induced specific-locus mutations recovered in those experiments showed that unexpected high frequencies of reparable and irreparable ad-3 mutants are actually multiple-locus mutants that have additional, but separate, sites of recessive lethal (RLCL) damage in the immediately adjacent genetic regions (designated ad-3R + RLCL or ad-3IR + RLCL). The frequencies of these X-ray-induced multiple-locus mutants in the ad-3 region are orders of magnitude higher than expected on the basis of target theory (where the frequency of the double mutant is expected to be the product of the frequencies of each single mutant) and classical models of chromosome structure during interphase (de Serres, 1989a). In the present paper, a random sample of 832 X-ray-induced ad-3 mutants of genotype ad-3A or ad-3B that are irreparable have been subjected to more extensive genetic fine-structure analysis. These experiments were designed to determine the extent of the functional inactivation in individual mutants in the ad-3 and immediately adjacent genetic regions in mutants classified as presumptive multilocus deletions or multiple-locus mutations. These experiments have shown that in Neurospora crassa most X-ray-induced irreparable mutants of genotype ad-3A or ad-3B map as a series of overlapping multilocus deletions. Among the 29 irreparable mutants of genotype ad-3A, there are 16 different subgroups of complementation patterns; and among the 63 irreparable mutants of genotype ad-3B, there are also 16 different subgroups. In addition, mutants classified as presumptive multiple-locus mutants result from a variety of separate, but closely linked, sites of genetic damage.(ABSTRACT TRUNCATED AT 400 WORDS)     

UV-induced recessive lethals in uvs strains of Neurospora which are deficient in UV mutagenesis

The frequencies of spontaneous and UV-induced recessive lethal mutations were compared for UV-sensitive and wild-type heterokaryons of Neurospora crassa. These heterokaryons were homokaryotic either for one of two alleles of uvs-3, or for uvs-6 or uvs+. For uvs-3, which is known to have mutator effects, spontaneous recessive lethals were found to be 4-6 times more frequent than observed in uvs+. After correction for clonal distribution of spontaneous mutants, an observed 2-fold increase for uvs-6 was not statistically significant and may have been due to chance occurrence of a few large clones of mutants. Treatment with low doses of UV (50-200 J/m2) produced very similar overall rates of increase for recessive lethals in uvs and uvs+ heterokaryons. This means, that in contrast to results obtained when mutation to ad-3 was measured, both uvs-3 alleles showed highly significant increases for recessive lethals when treated with UV. It is proposed that certain types of UV damage may be processed into recessive lethal mutations by an alternate mechanism from that responsible for viable mutations.     

Ultraviolet-inactivation of conidia from heterokaryons of Neurospora crassa containing uv-sensitive mutations.

The effect of three UV-sensitive mutations of Neurospora crassa, upr-I, uvs-4 and uvs-6, on the ultraviolet-inactivation of conidia from two-component heterokaryons was investigated. In two-component heterokaryons with wild-type sensitivity to radiation inactivation, all three conidial fractions exhibited similar ultraviolet-inactivation curves. Each UV-sensitive mutation studied uniquely modified the ultraviolet-inactivation curves of conidia from two-component heterokaryons. In heterokaryons heterokaryotic for upr-I, the upr-I mutation was recessive and the repair function determined by the wild type allele was functional to some degree in homokaryotic upr-I conidia. All three conidial fractions of heterokaryons containing upr-I in both components showed increased sensitivity to ultraviolet light. The uvs-4 mutation was recessive and resulted in conidia with increased UV-sensitivity only when included in both components of a heterokaryon. Homokaryotic uvs-4 conidia, which arose from heterokaryons containing both uvs-4 and wild-type components, exhibited wild-type survival. Therefore, as with upr-I, there was a carryover the repair capability to conidia which were genetically UV-sensitive. The uvs-6 mutation, when included in one component of a two-component heterokaryon, resulted in increased UV-sensitivity of both heterokaryotic and homokaryotic uvs-6 conidia. When both components contained uvs-6, the UV-sensitivity of all three conidial fractions was increased and all showed similar inactivation curves. Thus, as with upr-I and uvs-4, there was a carryover of the wild-type repair capability to genetically uvs-6 conidia. Heterokaryon tests for complementation between two non-allelic UV-sensitive mutations showed that in heterokaryotic conidia, complete complementation occurred between upr-I and uvs-4.     

X-ray-induced specific-locus mutations in the ad-3 region of two-component heterokaryons of Neurospora crassa. V. Irreparable mutants of genotype ad-3A ad-3B, ad-3A ad-3B nic-2, and ad-3B nic-2 result from multilocus deletion and an unexpectedly high frequency of multiple-locus mutations

More extensive complementation tests than those performed initially (Webber and de Serres, 1965) on a series of 832 X-ray-induced specific-locus mutations in the adenine-3 (ad-3) region of a two-component heterokaryon (H-12) of Neurospora crassa (de Serres, 1989a) showed that unexpectedly high frequencies of specific-locus mutations in the ad-3 region have additional, but separate, sites of recessive lethal (RLCL) damage in the immediately adjacent genetic regions. The frequencies of these X-ray-induced multiple-locus mutants in the ad-3 region are orders of magnitude higher than that expected on the basis of target theory and classical models of chromosome structure during interphase (de Serres, 1989a). Genetic fine structure analyses, by means of homology tests with tester strains carrying genetic markers in the ad-3 and immediately adjacent regions, have been performed to map the presumed multiple-locus mutations. In a previous paper (de Serres, 1989c), X-ray-induced irreparable ad-3 mutants of the following genotypes and numbers (ad-3A or ad-3B were analyzed, and the high frequency of multiple-locus mutations was confirmed. In the present paper, X-ray-induced irreparable ad-3 mutants of the following genotypes and numbers (ad-3A ad-3B, ad-3A ad-3B nic-2, and ad-3B nic-2 have also been subjected to the same genetic fine structure analysis. These experiments, in the previous (de Serres, 1989c) and present papers, were designed to determine the extent of the functional inactivation in the ad-3 and immediately adjacent genetic regions in individual mutants classified as presumptive multilocus deletions or multiple-locus mutations.     

Effects of heat shock on the induction of mutations by chemical mutagens in Neurospora crassa

Preheating of Neurospora conidia increased their susceptibility to mutation induction by chemical mutagens. Optimal conditions of heat shock for enhanced mutagenesis were determined in 2.5 X 10(7) conidia/ml 0.067 M KH2PO4-Na2HPO4 (pH 7.0) buffer to be treatment at 43 degrees C for 60 min. When protein synthesis during heat stock was eliminated by cycloheximide or by use of the temperature-sensitive mutation psi-1, induction of thermotolerance was inhibited while induction of the enhanced state of mutability was not. Therefore, inducible protein synthesis is not involved in this process. To discover whether DNA-repair systems are altered by heat shock and, as a result, whether reversion frequencies increase, DNA-repair mutants (upr-1, uvs-2, uvs-3, uvs-6, mus-7, mus-16) were heated and their reversion frequencies at the ad-8 locus were measured. All the DNA-repair mutants showed higher reversion frequencies with MNNG treatment after heat shock than in non-heated control. It therefore seems that DNA repair is not involved in the enhancement of chemical mutagenesis by heat shock. Heat shock does not increase frequencies of reversion induced by ultraviolet light, and heat shock after treatment with chemical mutagens does not affect reversion frequencies. These results suggest that heat shock may change the structure and function of cellular membranes and thereby increase the influx of mutagens into cells.     

The upr-1 gene encodes a catalytic subunit of the DNA polymerase zeta which is involved in damage-induced mutagenesis in Neurospora crassa

The upr-1 mutant was one of the first mutagen-sensitive mutants to be isolated in Neurospora crassa. However, the function of the upr-1 gene has not yet been elucidated, although some genetic and biochemical data have been accumulated. In order to clone the upr-1 gene, we performed a chromosome walk from the mat locus, the closest genetic marker to upr-1 for which a molecular probe was available, towards the centromere, and a chromosomal contig of about 300-400 kb was constructed. Some of these clones complemented the temperature sensitivity of the un-16 mutation, which is located between mat and upr-1. The un-16 gene was sequenced, and localized in the MIPS Neurospora crassa genome database. We then searched the regions flanking un-16 for homologs of known DNA repair genes, and found a gene homologous to the REV3 gene of budding yeast. The phenotype of the upr-1 mutant is similar to that of the yeast rev3 mutant. An ncrev3 mutant carrying mutations in the N. crassa REV3 homolog was constructed using the RIP (repeat-induced point mutation) process. The spectrum of mutagen sensitivity of the ncrev3 mutant was similar to that of the upr-1 mutant. Complementation tests between the upr-1 and ncrev3 mutations indicated that the upr-1 gene is in fact identical to the ncrev3 gene. To clarify the role of the upr-1 gene in DNA repair, the frequency of MMS and 4NQO-induced mutations was assayed using the ad-8 reversion test. The upr-1 mutant was about 10 times less sensitive to both chemicals than the wild type. The expression level of the upr-1 gene is increased on exposure to UV irradiation in the uvs-2 and mus-8 mutants, which belong to postreplication repair group, as well as in the wild type. All these results suggest that the product of the upr-1 gene functions in damage-induced mutagenesis and DNA translesion synthesis in N. crassa.     

X-ray-induced specific locus mutations in the ad-3 region of two-component heterokaryons of Neurospora crassa. I. Modification of the heterozygous effects of multilocus deletions covering the ad-3A or ad-3B loci

The basis for the reduced growth rates of heterokaryons between strains carrying nonallelic combinations of gene/point mutations (ad-3R) and multilocus deletion mutations (ad-3IR) has been investigated by a simple genetic test. The growth rates of forced 2-component heterokaryons (dikaryons) between multilocus deletion mutations were compared with forced 3-component heterokaryons (trikaryons) containing an ad-3AR ad-3BR double mutant as their third component. Since the third component has no genetic damage at other loci immediately adjacent to the ad-3A or ad-3B locus, the growth rate on minimal medium depends on the functional activity of the unaltered (and presumed "wild-type") ad-3A and ad-3B loci in the first two components. In many cases, the requirements of the original dikaryons have been satisfied by the addition of unaltered genes (in the third component), and these trikaryons grow at wild-type rate on minimal medium. Those trikaryons growing at less than wild-type rate were shown to be adenine-requiring, and wild-type growth rate was obtained with the addition of low levels of adenine to the medium. Such tests in the present experiments have shown that ad-3IR mutations result not only in inactivation of the ad-3 loci by multilocus deletion but also, in many cases, in partial gene inactivation by an unknown mechanisms at other loci in the immediately adjacent regions. The heterozygous effects observed in our present experiments with multilocus deletions in Neurospora can be explained either by a spreading-type position effect of the type found by others in Drosophila, mice, Oenothera and Aspergillus or by undetected genetic damage ("cryptic mutations") in the immediately adjacent genetic regions. An attempt will be made to distinguish between these two alternative hypotheses with techniques for DNA cloning and sequencing in future experiments.     

Effect of the uvs-2 allele of Neurospora crassa on the mutagenic potency of two N-hydroxylaminopurines and 2-aminopurine in the ad-3 forward-mutation test

The mutagenic potencies of 3 purine analogs were determined in the ad-3 forward-mutation test in growing cultures of heterokaryon 59 (H-59), a nucleotide excision repair-deficient (uvs-2/uvs-2) 2-component heterokaryon of Neurospora crassa. Two N-hydroxylaminopurines, 2-amino-6-N-hydroxylaminopurine (AHA) and 6-N-hydroxylaminopurine (HAP), were potent and strong mutagens, respectively, whereas 2-aminopurine (AP) was a moderate mutagen. Dose-response curves showed that AHA and HAP were about equally mutagenic at low doses but that AHA was more mutagenic than HAP at high doses. Comparison of these results in H-59 with our earlier results in heterokaryon 12 (H-12) of N. crassa, which is identical to H-59 except for being DNA-repair-proficient (uvs-2+/uvs-2+), shows that the defect in nucleotide excision repair due to uvs-2 has little or no effect on the mutagenic potencies of these 3 purine analogs. Therefore, the nucleotide excision-repair pathway in N. crassa that is deficient in H-59 does not appear to have a major role in the repair of pre-mutational lesions induced by these 3 purine analogs. On the other hand, based on the controls of these experiments, the frequency of spontaneous ad-3 mutants was 4 greater in H-59 than in H-12. This result suggests that the nucleotide excision-repair pathway in N. crassa that is inactivated by the uvs-2 mutation has a major role in the repair of lesions that would lead to spontaneous mutation at the ad-3+ region if they were not repaired.     

Identification of DNA repair and damage induced proteins from Neurospora crassa

Summary The response of Neurospora crassa to DNA damage induced by UV irradiation has been studied using two-dimensional polyacrylamide gel electrophoresis (2-D PAGE). Whole cell extracts of irradiated and untreated cultures were compared. Five polypeptides that show changes in response to DNA damage have been identified.Several mutagen sensitive strains of Neurospora were also tested for polypeptide changes on 2-D PAGE. Profiles of whole cell extracts of these mutant strains were compared to wild type. Two changes were observed in the meiotic mutant, mei-3 and one change was detected in the excision repair mutant, upr-1. Two changes were also detected in the allelic mutants, uvs-3 and nuh-4. Profiles of uvs-3 and nuh-4 revealed one polypeptide that was missing and another polypeptide which appeared to shift to a more basis position. This same shift was detected in wild type after induction by UV irradiation or heat shock.     

Isolation and genetic characterization of the Neurospora crassa REV1 and REV7 homologs: evidence for involvement in damage-induced mutagenesis

In a previous paper, we reported that the Neurospora crassa upr-1 gene is a homolog of the yeast gene REV3, which encodes the catalytic subunit of DNA polymerase zeta (polzeta). Characterization of the upr-1 mutant indicated that the UPR1 protein plays a role in DNA repair and mutagenesis. To help understand the mechanisms of mutagenic DNA repair in the N. crassa more extensively, we identified N. crassa homologs of yeast REV1 and REV7 and obtained mutants ncrev1 or ncrev7, which had similar phenotypes to the upr-1 mutant. Mutant carrying ncrev7 was more sensitive to UV and 4NQO, and slightly sensitive to MMS than the wild-type. The sensitivity to UV and MMS of the ncrev1 mutant was moderately higher than that of the wild-type, but the sensitivity to 4NQO of the mutant was similar to that of the wild-type. In reversion assay using testers with base substitution or frameshift mutation at the ad-3A locus, each of ncrev1 and ncrev7 mutants showed lower induced-mutability than the wild-type. Expression of ncrev1 and ncrev7 was found to be UV-inducible like the case of upr-1. Genetic analyses showed that the ncrev7 was identical to mus-26, which belongs to the upr-1 epistasis group, and that the ncrev1 was a newly identified DNA repair gene and designated as mus-42. Interestingly, all three mutants have a normal CPD photolyase gene, however, they showed a partial photoreactivation defect (PPD) phenotype, not completely defective but inefficient in photoreactivation. These results suggest that N. crassa REV homolog genes function in DNA repair and UV mutagenesis through the bypass of (6-4) photoproducts.     

Inactivation of carotenoid-producing and albino strains of Neurospora crassa by visible light, blacklight, and ultraviolet radiation.

Suspensions of Neurospora crassa conidia were inactivated by blacklight (BL) radiation (300 to 425 nm) in the absence of exogenous photosensitizing compounds. Carotenoid-containing wild-type conidia were less sensitive to BL radiation than albino conidia, showing a dose enhancement factor (DEF) of 1.2 for dose levels resulting in less than 10% survival. The same strains were about equally sensitive to shortwave ultraviolet (UV) inactivation. The kinetics of BL inactivation are similar to those of photodynamic inactivation by visible light in the presence of a photosensitizing dye (methylene blue). Only limited inactivation by visible light in the absence of exogenous photosensitizers was observed. BL and UV inactivations are probably caused by different mechanisms since wild-type conidia are only slightly more resistant to BL radiation (DEF = 1.2 at 1.0% survival) than are conidia from a UV-sensitive strain (upr-1, uvs-3). The BL-induced lethal lesions are probably no cyclobutyl pyrimidine dimers since BL-inactivated Haemophilus influenzae transforming deoxyribonucleic acid is not photoreactivated by N. crassa wild-type enzyme extracts, whereas UV-inactivated transforming deoxyribonucleic acid is photoreactivable with this treatment.     

Qualitative differences in the spectra of genetic damage in 2-aminopurine-induced ad-3 mutants between nucleotide excision-repair-proficient and -deficient strains of Neurospora crassa.

The mutagenic effects of 2-aminopurine (2AP) have been compared 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). This forward-mutation, morphological and biochemical, specific-locus assay system permits the recovery of ad-3A and/or ad-3B mutants in 3 major classes: gene/point mutations, multilocus deletion mutations, and unknowns, and 3 different subclasses of multiple-locus mutations. Previous studies (Brockman et al., Mutation Res., 218 (1989) 1-11) showed that 2AP treatment of growing cultures of H-12 and H-59 gave no difference between ad-3 forward-mutation frequencies over a wide range of 2AP concentrations in each strain. In the present experiments, genetic analyses of ad-3 mutants recovered from these experiments has demonstrated qualitative differences between the spectra of the 3 main classes of ad-3 mutations. In H-12, 84.2% (203/241) resulted from gene/point mutation, 11.6% (28/241) from multilocus deletion mutation, and 4.1% (10/241) were unknowns. In contrast, in H-59, 43.0% (99/230) resulted from gene/point mutation, 55.7% (128/230) from multilocus deletion mutation, and 1.3% (3/230) were unknowns. In addition, quantitative differences were also found between the spectra of ad-3 mutations in 1 subclass of multiple-locus mutations, but not 2 additional subclasses. The first subclass consisted of 1.7% (4/241) and 9.6% (22/230) gene/point mutations with a closely linked recessive lethal mutation, in H-12 and H-59, respectively. The second two subclasses consisted of (a) 0.4% (1/241) and 0.4% (1/230) multilocus deletion mutations with a closely linked recessive lethal mutation, and (b) 13.3% (32/241) and 15.2% (35/230) gene/point mutations with a separate recessive lethal mutation elsewhere in the genome, in H-12 and H-59, respectively. Data from studies by others have shown that 2AP inhibits adenosine deaminase, resulting in nucleotide precursor pool inbalance, and that 2AP can saturate the mismatch repair system. As a consequence of either effect of 2AP, the spectrum of 2AP-induced mutation could include frameshift mutations and chromosome aberrations such as multilocus deletions in addition to base-pair substitutions. The defect in DNA repair due to the uvs-2 allele, which has been shown to be a deficiency in pyrimidine dimer excision (Worthy and Epler, 1974), most probably has some other excision-repair deficiency (Macleod and Stadler, 1986; Baker et al., 1991).(ABSTRACT TRUNCATED AT 400 WORDS)