The repair-deficient mei-9a drosophila female potentiates chromosome loss induced in the paternal genome by diethylnitrosamine

Following matings of DEN-treated X^c2/B^SYy⁺ males with repair-deficient mei-9^a females and ordinary females, significant increases in complete and partial sex chromosome loss as well as dramatic shifts in sex ratio were found with mei-9^a but not ordinary females. Accordingly, the mei-9^a female enhances the detection of chromosome lesions leading to chromosome loss induced in the male genome by DEN. To date, the 4 compounds tested in this way (DMN, DEN, MMS and procarbazine) exhibit strong potentiation of chromosome loss with mei-9^a females suggesting the possibility that a protocol involving treatment (or not) of X^c2/B^sYy⁺ males mated with mei-9^a females may hold promise as an alternative to traditional tests for chromosome loss using repair-proficient females. Comparison with published translocation data on the 4 compounds indicated above suggests an overall greater sensitivity of the described mei-9^a chromosome-loss test compared with the traditional translocation test in the detection of chemically induced chromosome lesions.     

Review of the current status of the mei-9a test for chromosome loss in Drosophila melanogaster: An assay with radically improved detection capacity for chromosome lesions induced by methyl methanesulfonate (MMS), dimenthylnitrosamine (DMN), and especially diethylnitrosamine (DEN) and procarbazine

A review of previous findings as well as new data are included in the present paper on recent invetigations by Zimmering and co-workers regarding a radical improvement in the detection capacity of the conventional test for chromosome loss to assay for induced chromosome lesions/breakage. The improvement has been achieved through the use of mei-9^a repair-deficient P1 females to which treated males are mated. 4 compounds have been tested including MMS, DMN, DEN and procarbazine. Not only the mei-9^a test yielded significantly higher frequencies of induced chromosome loss with MMS and DMN than the conventional test, preliminary data, in fact, providing evidence of a positive response in the mei-9^a test at a concentration one order of magnitude below that producing no effect in the conventional test, but, more critically, it has permitted detection of highly significant increases in induced chromosome loss with DEN and procarbazine, compounds proving negative in the conventional tests for chromosome loss and heritable traslocations at all concentrations employed including those producing substantial to high frequencies of recessive lethal.     

Induced chromosome loss following treatment of postmeiotic cells of the Drosophila melanogaster male with MMS and DMN and matings with repair-proficient females and the repair-deficient females mei-9a and st mus302

Drosophila melanogaster ring-X males carrying a double marked Y chromosome, BsYy+, were treated with MMS or DMN and mated with repair-proficient females or the repair-deficient females mei-9a and st. mus302. Frequencies of induced complete loss (principally the ring-X) and partial losses of the Y chromosome (loss of Bs or Y+) decreased in the sequence st must302 greater than mei-9a greater than repair-proficient females agreeing with the sequence obtained previously with procarbazine and DEN. With MMS and DMN, some 30-40% or more or partial Y chromosome losses are mosaics from mei-9a and only 0.4% from st mus302 females and a delay in mei-9a females. Similar findings with procarbazine and DEN are indicated. That the higher sensitivity of st mus302 relative to mei-9a results from impairments in both postreplication and excision repair in the former remains to be determined.     

Evaluation in Drosophila melanogaster of the mutagenic potential of furfural in the mei-9a test for chromosome loss in germ-line cells and the wing spot test for mutational activity in somatic cells.

The mutagenic potential of furfural was evaluated by means of the chromosome loss test in germ cells and the wing spot test in somatic cells of Drosophila melanogaster. The chromosome loss test was carried out employing repair-proficient as well as repair-deficient females. Males carried the compound Y chromosome, BSYy+. Two routes of administration were used: injection and feeding of adult males. Genetic damage was demonstrable after matings of treated males with females carrying the excision repair-deficient mutant mei-9a. The somatic mutation and recombination test was carried out treating 72-h transheterozygous mwh+/+flr3 larvae. Acute treatment of larvae was chosen as the method of exposure. Evidence indicates that furfural induces somatic damage as measured in the wing spot test.     

O-alkylation in DNA does not correlate with the formation of chromosome breakage events in D. melanogaster

Postmeiotic cell stages of repair-proficient ring-X (RX) males were treated with methyl methanesulfonate (MMS), ethyl methanesulfonate (EMS), diethylnitrosamine (DEN) or ethylnitrosourea (ENU) and then mated to either repair-defective (mei-9L1) or to repair-competent females (mei-9+). Absence of the mei-9+ function resulted in a hypermutability effect to all alkylating agents (AAs) when they were assayed for their ability to induce chromosomal aberrations (chromosome loss; CL), irrespective of marked differences in distribution of DNA adducts brought about by these AAs. This picture is different from that described previously for the induction of point mutations (Vogel et al., 1985a). There, evidence was presented indicating that reduction in DNA excision repair does not affect point mutation induction (recessive lethals) by those AAs most efficient in ring-oxygen alkylation such as ENU, DEN, N-ethyl-N'-nitro-N-nitrosoguanidine (ENNG), and isopropyl methanesulfonate (iPMS): the order of hypermutability of AAs with mei-9L relative to mei-9+ was MMS greater than MNU greater than DMN = EMS greater than iPMS = ENU = DEN = ENNG. When the percentage of lethal mutations induced in mei-9L1 females were plotted against those determined for mei-9+ females, straight lines of following slopes were obtained: MMS = 7.6, MNU = 5.4, DMN = 2.4, EMS = 2.4, and iPMS = ENU = DEN = ENNG = 1. Those findings, together with the recent observation that AAs do not split into two groups when assayed for their ability to cause CL, point to the involvement of different DNA alkylation products in ENU- and DEN-induced chromosome loss vs. that of point mutations. It is concluded that with ENU and DEN chromosomal loss results from N-alkylation products whereas point mutations (SLRL) are the consequence of interactions with oxygen-sites in DNA. Thus, as a consequence of a very dominating role of O-ethylguanine (and possibly O4-alkylation of thymine), N-alkylation in DNA does not contribute measurably to mutation induction in the case of ENU-type mutagens while O-alkylation, very clearly, does not show a positive correlation with the formation of chromosome breakage events in Drosophila. Conversely, it appeared that with MMS-type mutagens (MMS; dimethyl sulfate, DMS; trimethyl phosphate, TMP), alkylation products such as 7-methylguanine and 3-methyladenine, if unrepaired or misrepaired, are potentially mutagenic lesions causing both mutations and chromosomal aberrations.     

Genetic study on the effects of the repair-deficient mutant females mei-9a, mei-41D5, mus101D1, mus104D1 and mus302D1 of Drosophila on spontaneous and X-ray-induced chromosome loss in the paternal genome

The repair-deficient mutants mei-9a, mei-41D5, mus101D1, mus104D1 and mus302D1 in Drosophila melanogaster were investigated regarding their effects on spontaneous and X-ray-induced chromosome loss in postmeiotic cells. Each mutant was incorporated singly into XC2, and the ring-X male provided with BSYy+. From matings of males carrying mus101D1, mus302D1 or mei-41D5, mutants identifying a caffeine-sensitive (CAS) postreplication-repair pathway, with corresponding mutant females, and non-mutant males to non-mutant females, overall frequencies of spontaneous partial loss and spontaneous complete loss were significantly increased in each mutant cross except for spontaneous complete loss with mus302 where an increase was noted only in brood 2. Similar findings were noted when males carrying the excision-repair mutant mei-9a were mated with mei-9a females. Males carrying the mutant mus104D1, identifying a caffeine-insensitive (CIS) postreplication-repair pathway, tested with mus104D1 females, produced results that were not significantly different from non-mutant controls. When males were given 3000 rad X-irradiation, frequencies of induced partial loss were significantly higher with mus101D1, mus302D1, mei-41D5 and mei91, and not significantly higher with mus101D1, mus302D1, mei41D5 and mei-9a, and not significantly different from controls with mus104D1. It was suggested that the functional CAS postreplication-repair pathway primarily promotes repair of breaks while an alternative pathway(s) not defined by mus104 promotes misrepair. Therefore, the significant increases in both spontaneous and induced partial loss with the excision-repair-deficient mutant mei-9a suggests the possibility that (a) the excision-repair-pathway may not function in misrepair and (b) the undefined misrepair pathway may be dominant pathway for postreplication repair in Drosophila since mei-9a females presumably have functional postreplication repair and misrepair capacity. The suggestion that the CAS postreplication-repair pathway and the excision-repair pathway function primarily in repair, and an undefined pathway in misrepair is in line with the finding that with mus104D1, no significant increase was found in spontaneous complete loss, but with mus101D1, mus302D1, mei-41D5 and mei-9a significant increases were observed. Results on induced complete loss, with the exception of those with mei-41D5, show a poor correlation with other classes of loss of each of the mutants. Possible explanations for this discrepancy are discussed.     

The relationship between reaction kinetics and mutagenic action of monofunctional alkylating agents in higher eukaryotic systems. IV. The effects of the excision-defective mei-9L1 and mus(2)201D1 mutants on alkylation-induced genetic damage in Drosophila

Repair-defective mutants of Drosophila melanogaster which identify two major DNA excision repair loci have been examined for their effects on alkylation-induced mutagenesis using the sex-linked recessive lethal assay as a measure of genotoxic endpoint. The alkylating agents (AAs) chosen for comparative analysis were selected on the basis of their reaction kinetics with DNA and included MMS, EMS, MNU, DMN, ENU, DEN and ENNG. Repair-proficient males were treated with the AAs and mated with either excision-defective mei-9L1 or mus(2)201D1 females or appropriate excision-proficient control females. The results of the present work suggest that a qualitative and quantitative relationship exists between the nature and the extent of chemical modification of DNA and the induction of of genetic alterations. The presence of either excision-defective mutant can enhance the frequency of mutation (hypermutability) and this hypermutability can be correlated with the Swain-Scott constant S of specific AAs such that as the SN1 character of the DNA alkylation reaction increases, the difference in response between repair-deficient and repair-proficient females decreases. The order of hypermutability of AAs with mei-9L1 relative to mei-9+ is MMS greater than MNU greater than DMN = EMS greater than iPMS = ENU = DEN = ENNG. When the percentage of lethal mutations induced in mei-9L1 females are plotted against those determined for control females, straight lines of different slopes are obtained. These mei-9L1/mei-9+ indices are: MMS = 7.6, MNU = 5.4, DMN = 2.4, EMS = 2.4 and iPMS = ENU = DEN = ENNG = 1. An identical order of hypermutability with similar indices is obtained for the mus(2)201 mutants: MMS(7.3) greater than MNU (5.4) greater than EMS(2.0) greater than ENU(1.1). Thus, absence of excision repair function has a significant effect on mutation production by AAs efficient in alkylating N-atoms in DNA but no measurable influence on mutation production by AAs most efficient in alkylating O-atoms in DNA. The possible nature of these DNA adducts has been discussed in relation to repair of alkylated DNA. In another series of experiments, the effect on alkylation mutagenesis of mei-9L1 was studied in males, by comparing mutation induction in mei-9L1 males vs. activity in Berlin K (control). Although these experiments suggested the existence of DNA repair in postmeiotic cells during spermatogenesis, no quantitative comparisons could be made.(ABSTRACT TRUNCATED AT 400 WORDS)     

Studies on mutagen-sensitive strains of Drosophila melanogaster. II. Detection of qualitative differences between genetic damage induced by X-irradiation of mature spermatozoa in oxygenated and anoxic atmospheres through the use of the repair-deficient mutant mei-9a

Muller-5 males were irradiated with X-rays in nitrogen, in air or in oxygen (followed by nitrogen or oxygen post-treatments in the nitrogen and oxygen series) and were mated to females of a repair-proficient strain (mei+) or to those of a strain known to be deficient in excision repair of UV damage (in somatic cells). The latter strain, designated as mei-9a, is also known to be sensitive, in the larval stages, to the killing effects of UV, X-rays and to a number of chemical mutagens. The frequencies of sex-linked recessive lethals and autosomal translocations induced in the spermatozoa of males were determined and compared. The frequencies of sex-linked recessive lethals in the mei-9 control groups were consistently higher than in the mei+ groups. Irradiation in air or in nitrogen led to significantly higher yields of recessive lethals when the irradiated males were mated to mei-9 females, whereas, after irradiation in oxygen, the yields were similar with both kinds of female. No significant differences in the frequencies of reciprocal translocations were observed between the mei+ and mei-9 groups after irradiation of the males in nitrogen, in air or in oxygen. Likewise, no differential effects of the contrasting post-treatments (nitrogen versus oxygen), either for recessive lethals or for translocations, could be discerned. These results are considered to support the notion that the kinds of genetic damage induced in mature spermatozoa in air or in nitrogen are qualitatively similar (at least with respect to the component(s) that lead to the production of recessive lethal mutations), but clearly different when induced in an oxygen atmosphere. The enhanced yields of recessive lethals with mei-9 females (after irradiation of the males either in air or in nitrogen) has been interpreted on the assumption that the mei-9 mutant is also deficient for the repair of X-ray-induced, recessive lethal-generating premutational lesions. Possible reasons for the lack of differences between the mei+ and mei-9 groups with respect to translocation yields and for the absence of measurable differences in response between the contrasting post-treatments (after irradiation of the males in nitrogen) are discussed.     

Studies on mutagen-sensitive strains of Drosophila melanogaster. IV. Modification of genetic damage induced by X-irradiation of spermatozoa and spermatids in N2 or O2 by mei-9a, mei-41D5 and mus(1)101D1

The influence of defects in DNA repair processes on X-ray-induced genetic damage in post-meiotic male germ cell stages of Drosophila melanogaster was studied using the 'maternal effects approach'. Basc males were irradiated in N2, air or O2 either as 48-h-old pupae (to sample spermatids) or as 3-4-day-old adults (to sample mature spermatozoa) and mated to females of 3 repair-deficient strains (mei-9a: excision-repair-deficient; mei-41D5: post-replication-repair-deficient; mus(1)101D1: post-replication-repair-deficient and impaired in DNA synthesis). Simultaneous controls involving mating of males to repair-proficient females (mei+) were run. The frequencies of sex-linked recessive lethals and of autosomal translocations were determined following standard genetic procedures. The responses elicited in the different crosses with repair-deficient females were compared with those in mei+ crosses. The main findings are the following: with mei-9 females, the frequencies of recessive lethals are higher after irradiation of spermatids in N2, but not after irradiation in air of O2 (relative to those in the mei+ crosses); this result is different from that obtained in earlier work with spermatozoa, in which cell stage, higher yields of recessive lethals were obtained after irradiation of males in either N2 or air; in the mei-9 crosses, there are no significant differences in response (relative to mei+) after irradiation of either spermatozoa or spermatids in O2; the translocation frequencies in the mei-9 crosses are similar to those in the mei+ crosses, irrespective of the treated germ cell stage or the irradiation atmosphere; irradiation of either spermatozoa or spermatids in N2, air or O2 does not result in any differential recovery of recessive lethals in the mei-41 relative to mei+ crosses; irradiation of spermatids in N2 and of spermatozoa in air leads to a higher recovery of translocations in the mei-41 crosses; and after irradiation of spermatids or spermatozoa in any of the gaseous atmospheres, the frequencies of recessive lethals and of translocations are lower in the mus-101 crosses. The differences in responses (between cell stages, in different gaseous atmospheres and with different repair-deficient females) are explained on the basis of both qualitative and quantitative differences in the composition of the initial lesions and the extent to which their repair may be affected by the defects present in the different repair-deficient females. Several discrepancies between expectations based on biochemical results and the genetic results are pointed out.(ABSTRACT TRUNCATED AT 400 WORDS)     

Radiation and transposon-induced genetic damage in Drosophila melanogaster: X-ray dose-response and synergism with DNA-repair deficiency.

The interaction of X-ray-induced and transposon-induced damage was investigated in P-M hybrid dysgenesis in Drosophila melanogaster. The X-ray dose-response of 330-1320 rad was monitored for sterility, fecundity and partial X/Y chromosome loss among F2 progeny derived from the dysgenic cross of M strain females xP strain males (cross A) and its reciprocal (cross B), using a weaker and the standard Harwich P strain subline. The synergistic effect of P element activity and X-rays on sterility was observed only in cross A hybrids and the dose-response was nonlinear in hybrids derived from the strong standard reference Harwich subline, Hw. This finding suggests that the lesions induced by both mutator systems which produce the synergistic effect are two-break events. The effect of increasing dose on the decline of fecundity was synergistic, but linear, in hybrids of either subline. There was no interaction evident and thus no synergism in X/Y nondisjunction and in partial Y chromosome loss measured by the loss of the Bs marker alone or together with the y+ marker. Interaction was detected in the loss of the y+ marker alone from the X and Y chromosomes. The possible three-way interaction of X-rays (660 rad), post-replication repair deficiency and P element mobility was assessed by measuring transmission distortion in dysgenic males derived from the II2 P strain. X-Irradiation of spermatids significantly increased the preferential elimination of the P-element-bearing second chromosome in mei-41, DNA-repair-deficient dysgenic males, but had no effect in their DNA-repair-proficient brothers. These findings indicate that the post-replication repair pathway is required for processing lesions induced by the combined effect of P element mobility and X-rays, and that the unrepaired lesions ultimately lead to chromosome loss.     

A genetic study of the effects of the repair-deficient mei-9 mutation in drosophila on spontaneous and X-ray-induced paternal sex chromosome loss

The repair-deficient mutant, mei-9^a in Drosophila melanogaster was investigated regarding its effect on spontaneous and X-ray-induced chromosome loss in male postmeiotic cells. From matings of males carrying a mei-9^a or an ordinary ring-X and a doubly marked Y chromosome (B^SYy⁺) with mei-9^a or ordinary females, the spontaneous frequencies of complete loss, partial loss, and inferred ring-X loss (based on shifts in sex ratio female:male) were significantly higher with mei-9^a than with non-mei-9^a. When males were given 3000 rad X-irradiation, frequencies of induced partial loss, inferred ring-X loss and the reduction in the number of progeny per female were significantly greater with mei-9^a than with non-mei-9^a. The results provide evidence that the mei-9^a is a potentiator of both spontaneous and X-ray-induced chromosome lesions in sperm of the Drosophila male. Evidence is presented which implicates the presence of mei-9^a in the P₁ female and not the male as (at least) largely responsible for the characteristic mei-9^a effects.     

DNA Repair Dependence of Somatic Mutagenesis of Transposon-Caused WHITE Alleles in DROSOPHILA MELANOGASTER after Treatment with Alkylating Agents

DNA repair-defective alleles of the mei-9, mei-41, mus-104 and mus-101 loci of Drosophila melanogaster were introduced into stocks bearing the UZ and SZ marker sets. Males with the UZ marker set, z1 (zeste allele) and w+(TE) (genetically unstable white allele presumably caused by a transposable element), or the SZ marker set, z1 and w+R (semistable white allele caused by partial duplication of the w+ locus plus transposon insert), were exposed to EMS at the first instar. After emergence, adult males bearing red spots on lemon-yellow eyes were scored as flies with somatic reversions of w+(TE) or w+R. The relative mutabilities (relative values of reversion frequency at an equal EMS dose) of either w+(TE) or w+R in a repair-proficient strain and in mei-9, mei-41, mus-104 and mus-101 strains were 1: approximately 1.2:0.3:0.3:0.7, despite the fact that w+(TE) reverted two to three times as frequently as w+R under both the repair-proficient and repair-deficient genetic conditions. Similarly, after treatment with MMS, MNNG and ENNG, w+(TE) was somatically more mutable in the mei-9 strain and less mutable in the mei-41 and mus-104 strains than in the repair-proficient strain. From these results, we propose that mutagenic lesions produced in DNA by treatment with these chemicals are converted to mutant DNA sequences via the error-prone repair mechanisms dependent on the products of the genes mei-41+ (mei-41 and mus-104 being alleles of the same locus) and mus-101+, whereas they are eliminated by mei-9+-dependent excision repair. In contrast to the approximately linear responses of induced reversions of w+(TE) with ENNG in the repair-proficient, mei-9, and mei-41 strains, seemingly there were dosage insensitive ranges for induced reversion with MNNG in the repair-proficient and mei-41 strains, but not for reversion in the mei-9 strain; w+(TE) in the mus-104 strain was virtually nonmutable with MNNG and ENNG. These results suggest that O6-methylguanine (O6MeG) produced in DNA with MNNG, but not O6-ethylguanine produced with ENNG, is almost completely repaired in a low dose range by constitutive activity of DNA O6MeG transmethylase. From the distribution of clone sizes of spontaneous revertant spots and other data, we propose that both w+(TE) and w+R have a similar tendency to spontaneously revert more frequently at early rather than at later developmental stages probably reflecting a common property of their inserted transposons.     

Two new X-autosome Robertsonian translocations in the mouse. I. Meiotic chromosome segregation in male hemizygotes and female heterozygotes.

Two new X-autosome Robertsonian (Rb) translocations, Rb(X.9)6H and Rb(X.12)7H, were found during the course of breeding the Rb(X.2)2Ad rearrangement at Harwell. The influence of these new Rbs on meiotic chromosome segregation was investigated in hemizygous males and heterozygous females and compared to that of Rb(X.2)2Ad. Screening of metaphase II spermatocytes gave incidences of sex chromosome aneuploidy of 9.2% in Rb(X.2)6H/Y and 9.6% in Rb(X.9)2Ad/Y males; no metaphase II cells were present in the testes of the Rb(X.12)7H/Y males examined and no males with this karyotype have so far proved fertile. In breeding tests, 5% of the progeny of Rb(X.2)2Ad/Y males were sex chromosome aneuploids compared to 10% of the Rb(X.9)6H/Y offspring. The difference was not significant, however. Cytogenetic analyses of metaphase II stage oocytes showed elevated rates of hyperhaploidy (n + 1) in Rb heterozygous females over chromosomally normal mice: 4.2% for Rb(X.2)2Ad/+; 2.1% for Rb(X.9)6H/+; 2.2% for Rb(X.12)7H/+ and 1.1% for normal females. There was, however, no statistically significant difference in the rates of hyperhaploidy between the three different Rb types, nor overall between Rb/+ and normal females. Karyotypic analyses of liveborn offspring of Rb heterozygous females revealed low incidences of X0 animals but no other type of sex chromosome aneuploidy. Intercrosses of heterozygous females and hemizygous males yielded 5.5% aneuploidy for Rb(X.2)2Ad and 5.4% for Rb(X.9)6H. In heterozygous females, there was evidence from the metaphase II and breeding test data for all three rearrangements, of preferential segregation of the Rb metacentric to the polar body resulting in a deficiency of cells and progeny carrying a translocation chromosome.     

The Effect of mei-41 on Rdna Redundancy in DROSOPHILA MELANOGASTER

The recombination and repair defective mutant, mei-41, exhibits three rather striking effects on the genetic properties and chromosomal stability of rDNA in Drosophila. First, mei-41 inhibits rDNA magnification. However, mei-9, another recombination and repair defective mutation has no similar effect. This indicates that magnification requires some, but not all, of the gene products necessary for meiotic exchange. Second, under magnifying conditions, mei-41 induces interchanges between the X rDNA and either arm of the Ybb- chromosome. These interchanges occur at high frequency and are independent of rDNA orientation. Third, in mei-41 bb+/Ybb+ males, bobbed mutants in the X, but not the Y, also arise at high frequency. Evidence suggests that these events involve the rDNA type I insertion. The recombination and repair defective properties of mei-41 together with our results regarding its unusual and specific effects involving rDNA are explained in a simple model that has general implications for chromosome structure.     

Sex chromosomes and origin of males and sex mosaics of the parthenogenetic stick insect Carausius morosus Br.

The chromosome complements of sporadic males and masculinized females of the thelytokous phasmid Carausius morosus Br. could be analysed in spermatogonia and ovarian follicle cells. Masculinized females with ovaries, ovotestes or testes have the female chromosome number, i.e., 61 autosomes and three sex chromosomes. The sex chromosomes, one being longer than the other two, are metacentric. In one masculinized female with testes the three sex chromosomes were different, apparently through a reciprocal translocation. The masculinized females are considered to be intersexes (phenotypic sex determination). The chromosome complement of males differs from that of females by lacking either one of the sex chromosomes or only a segment of one of these chromosomes (genotypic sex determination). The deleted sex chromosomes appear as acrocentrics and may have arisen through a chiasma between a translocated segment in one sex chromosome and its untransposed homologous region in another sex chromosome. One apparently telocentric sex chromosome may have originated from centric fission together with loss of the other arm. The sex chromosomes are positively heteropycntoic in the psermatogonia, also in those of masculinized females. En bloc heterochromatinization of the sex chromosomes, which seems to be under the direct or indirect control of one or more sites on the sex chromosomes themselves, functions in sex determination. The sex determination does not give a decisive answer to the question whether di-, tri-, or tetraploidy is involved.     

Genotoxic potency in Drosophila melanogaster of selected aromatic amines and polycyclic aromatic hydrocarbons as assayed in the DNA repair test

Drosophila melanogaster stock consisting of meiotic recombination deficient (Rec⁻) double mutant mei-9^a mei-41^D5 males and Rec⁺ females was exposed at the larval stage to an aromatic amine or a polycyclic aromatic hydrocarbon. After emergence as adult flies, the males and the females were scored separately. When the treatment caused a dose-dependent reduction in the male to female ratio from the control level, the experiment was repeated with a larval stock consisting of Rec⁺ males and Rec⁺ females under comparable conditions. A preferential killing effect upon Rec⁻ larvae was taken as evidence of DNA damaging effect of the test compound. Among 16 compounds tested, 1-AP, B(a)P, 2-AF, DAF, 4-AAF, 2-AAF, 1-AA, 2-AA, DMA, B(a)A and DMBA were registered as positive; Py and 3-MC were weakly positive; and B(e)P, Fluo and Ant were negative. The selective killing effects of the compounds in each of the pyrene, fluorene and anthracene series varied drastically as a function of structure in a way similar to that reported for the genotoxicity in Drosophila and the carcinogenicity in rodents. The Drosophila DNA repair assay will serve as a simple adjunct to the already available means for studying the genotoxic potency of aromatic amines and polycyclic aromatic hydrocarbons.     

Mutagen-sensitive mutants in Drosophila melanogaster: effects on premutational damage.

Drosophila melanogaster males from a Basc stock were mutagenized with either X-rays, ethyl methanesulfonate (EMS), or nitrogen mustard (HN2). Groups of identically treated males were crossed to different types of female. Sex-linked recessive lethals were scored as a genetic end point. The females used were homozygous for X-chromosomal mutations (mus(1)101D1, mus(1)104D1, mei-9 or mei-41D5) which lead to defective DNA repair and which increase the mutagen sensitivity of larvae. Females from a white stock with normal DNA repair capacities served as controls. The premutational lesions induced in mature sperm are only processed after insemination by the maternal enzyme systems present in the oocytes. Differences in the efficiency of the processing of lesions can lead to maternal effects on the frequency of mutations recovered from mutagenized sperm. It was found that, with the exception of mus(1)104D1, all mutants analysed significantly modify the mutation fixation of one or more types of premutational lesions. The most drastic effect is found with the mus(1)101D1 stock in which HN2-induced DNA cross-links do not lead to sex-linked recessive lethals. It is assumed that mus(1)101D1 is defective in an early step of DNA cross-link repair. Our first set of data clearly demonstrates that the study of maternal effects in Drosophila is an efficient tool to analyse the in vivo function of repair mutations on chemically induced mutagenesis.     

Studies on mutagen-sensitive strains of Drosophila melanogaster. VII. Effects of repair deficiency in males on X-ray-induced sex-linked recessive lethals in spermatozoa

The response of mature spermatozoa to the X-ray induction (500 R and 3000 R) of sex-linked recessive lethals was studied in Drosophila melanogaster males known to be deficient in excision- or post-replication repair of UV damage in somatic cells. The results show that the induced frequencies of recessive lethals in the excision-repair-deficient males (mei-9a and mei-9L1) are similar to those in the appropriate repair-proficient males (mei+ and Berlin-K). However, in the post-replication-repair-deficient males (w mus(1)101D1), these frequencies are significantly lower than in the comparable repair-proficient males (w) after 500 R, but not after 3000 R.     

Recovery and characterization of hybrid dysgenesis-induced mei-9 and mei-41 alleles of Drosophila melanogaster

X-Linked methyl methanesulfonate (MMS)-sensitive mutations were induced with hybrid dysgenesis using four P strains: pi 2, Harwich, T-007 and OK-1. Mutations were identified after two generations of backcrosses to M strain females to replace the autosomes. Among 51,471 X-chromosomes examined 10 carried stable MMS-sensitive mutations representing 8 independent events. Males of the mutant strains failed to induce gonadal dysgenesis in crosses to Oregon-R females at 28.5 degrees C. Complementation tests showed that 3 of the induced mutations were mei-9 alleles, 2 were mei-41 alleles, 1 was a mus102 allele, and 2 were alleles at a newly identified MMS-sensitive locus, mus112 (map position: 1-32.8). As assayed by in situ hybridization on polytene chromosomes, each X-chromosome had no more than four P element insertions. 4 of the 8 mutations recovered in this study proved to have P element insertions at or very close to sites to which MMS sensitivity has been mapped. Hybrid dysgenesis-induced reversion of 2 mutants, mei-9RT1 and mei-41RT2, is associated with the loss of the P element from regions 4B and 14C respectively.     

Studies on mutagen-sensitive strains of Drosophila melanogaster. VI. The effect of DNA-repair deficiencies in spermatids, spermatocytes and spermatogonia irradiated in N2 or O2

This study was aimed at ascertaining the extent to which paternal repair processes possibly deficient in mei-9a, mei-41D5 and mus-101D1 genotypes would affect the recovery of radiation-induced recessive lethals in early spermatids, spermatocytes and spermatogonia. These germ cell stages were sampled in two 2-day broods from freshly hatched males, that were irradiated as 24-h old pupae in O2, or N2 followed by N2 or O2 post-treatment. Spontaneous mutation frequencies were higher in mei-9 and mei-41 males, and thus appropriate corrections were applied to the radiation data. Only with mei-9 males a clear and consistent increase of the radiation-induced mutation frequency was observed. The effect is somewhat more pronounced in brood B, presumably representing spermatogonia, than in brood A and is observed after radiation in either O2 or N2. The paternal repair process thus differs from the maternal one in that it also responds to radiation damage induced in O2. The finding that, following irradiation under anoxia, post-treatment with O2 (versus that with N2), also lowers the mutation frequency in mei-9 males, indicates that the repair defect in mei-9 does not interfere with oxygen-dependent post-radiation repair. Thus there are two different paternal repair processes in these early stages of spermatogenesis: that is, one controlled by mei-9 and one depending on oxygen. Mei-41 and mus-101 do not appear to interfere with the paternal repair process. The frequency of translocations recovered from these stages was likewise not affected by mus-101.