The influence of solvent stress on MMS-induced genetic change in Saccharomyces cerevisiae

MMS induced mitotic recombination but not mitotic chromosome loss when tested in pure form in strain D61.M of Saccharomyces cerevisiae, confirming previous results of Albertini (1991), whereas in Aspergillus nidulans it also induced chromosomal malsegregation in addition to mitotic recombination (Käfer, 1988). However, induction of mitotic chromosome loss was observed in combination with strong inducers of chromosome loss such as the aprotic polar solvents ethyl acetate and to a lesser extent methyl ethyl ketone but not with γ-valerolactone and propionitrile. In addition to this, 4 solvents, dimethyl formamide, dimethyl sulfoxide, dioxane and pyridine, enhanced the MMS-induced mitotic recombination in strain D61.M. An enhancement of MMS-induced mitotic recombination and reverse mutation could be demonstrated for ethyl acetate and γ-valerolactone in yeast strain D7.     

The influence of solvent stress on MMS-induced genetic change in Saccharomyces cerevisiae

MMS induced mitotic recombination but not mitotic chromosome loss when tested in pure form in strain D61.M of Saccharomyces cerevisiae, confirming previous results of Albertini (1991), whereas in Aspergillus nidulans it also induced chromosomal malsegregation in addition to mitotic recombination (Käfer, 1988). However, induction of mitotic chromosome loss was observed in combination with strong inducers of chromosome loss such as the aprotic polar solvents ethyl acetate and to a lesser extent methyl ethyl ketone but not with γ-valerolactone and propionitrile. In addition to this, 4 solvents, dimethyl formamide, dimethyl sulfoxide, dioxane and pyridine, enhanced the MMS-induced mitotic recombination in strain D61.M. An enhancement of MMS-induced mitotic recombination and reverse mutation could be demonstrated for ethyl acetate and γ-valerolactone in yeast strain D7.     

Role of DNA Sequences in Genetic Recombination in the Iso-1-Cytochrome c Gene of Yeast. I. Discrepancies between Physical Distances and Genetic Distances Determined by Five Mapping Procedures

Recombination rates have been examined in two-point crosses of various defined cyc1 mutants using five mapping methods. Nucleotide sequences of mutant codons were identified in previous studies from alterations in functional iso-1-cytochromes c produced by intragenic revertants. Heteroallelic diploids were analyzed for rates of mitotic recombination that occurred spontaneously and that were induced with x-rays, ultraviolet light and the near-ultraviolet light emitted by sunlamps, as well as rates of meiotic recombination that occur after sporulation. Frequencies of both mitotic and meiotic recombination do not necessarily correspond with physical distances separating altered nucleotides. The most extreme discrepancy involved two adjacent intervals of thirteen basepairs which differed approximately thirty-fold in their spontaneous and X-ray-induced recombination rates. Marked disproportions between genetic and physical distances appear to be due to the interaction of the two nucleotide sequences in the heteroallelic combination and not to the sequences of the mutant codons alone. Recombination values that were obtained by all five methods could not be used to establish to correct order of mutant sitesmrelationships of the recombination rates for the various pairwise crosses are different after mitosis from those after meiosis, suggesting that these two recombinational processes are to some extent different in their dependence on particular nucleotide configurations. On the other hand, the relationships of the rates induced by UV-, sunlamp- and X-irradiation were identical or very similar. In addition to the intrinsic properties of the alleles affecting frequencies of mitotic and meiotic recombination rates, two- to threefold variations in recombination rates could be attributed to genetic backgrounds.     

Cytogenetic mapping with centromeric bacterial artificial chromosomes contigs shows that this recombination‐poor region comprises more than half of barley chromosome 3H

Genetic maps are based on the frequency of recombination and often show different positions of molecular markers in comparison to physical maps, particularly in the centromere that is generally poor in meiotic recombinations. To decipher the position and order of DNA sequences genetically mapped to the centromere of barley (Hordeum vulgare) chromosome 3H, fluorescence in situ hybridization with mitotic metaphase and meiotic pachytene chromosomes was performed with 70 genomic single‐copy probes derived from 65 fingerprinted bacterial artificial chromosomes (BAC) contigs genetically assigned to this recombination cold spot. The total physical distribution of the centromeric 5.5 cM bin of 3H comprises 58% of the mitotic metaphase chromosome length. Mitotic and meiotic chromatin of this recombination‐poor region is preferentially marked by a heterochromatin‐typical histone mark (H3K9me2), while recombination enriched subterminal chromosome regions are enriched in euchromatin‐typical histone marks (H3K4me2, H3K4me3, H3K27me3) suggesting that the meiotic recombination rate could be influenced by the chromatin landscape.     

On the mechanism of mitotic recombination in Aspergillus nidulans. I. Intragenic recombination and DNA replication

Summary Adenine or pABA starvation induce mitotic recombination within the ad9 and paba1 cistrons respectively. Adenine concentrations in the plating medium as low as 1×10^-8 M increase recombination frequency; the concentration optimal in respect to induced recombination frequency is 5×10^-7 M.Recombination within the paba1 cistron is stimulated by low pABA concentrations, or caseine hydrolysate, or methionine.Aminopterin applied for one or two hours before conidia of pABA-requiring diploid are plated on proper selective media, induces recombination within the pro1, ad9 and paba1 cistrons. Conclusion is drawn that it is adenine or thymine starvation which induce mitotic recombination.The implications of this and other similar evidence are discussed.     

Effect of tumor promoter TPA on spontaneous and mitomycin C induced mitotic recombination in Drosophila melanogaster

It has been proposed that mitotic recombination is involved in tumor promotion. To test this idea, we investigated the effect of a tumor promoter, 12-O-tetradecanoylphorbol-13-acetate (TPA), on spontaneous and mitomycin C (MMC)-induced mitotic recombination in Drosophila melanogaster. The test system used was the wing-spot assay. Third instar larvae (mwh+/+flr) were treated with MMC (0-0.3 mM) for 6 h and fed media containing TPA (0-10 micrograms/ml), and the wings of surviving adults were analyzed for the presence of mutant spots. The results are: (1) MMC induced twin spots as well as single spots dose dependently (0.03-0.3 mM). (2) TPA itself did not induce twin spots or single spots in the range of doses examined (0.1-10 micrograms/ml). (3) TPA did not enhance the frequencies of twin or single spots induced by MMC. These results indicate that TPA induced neither mitotic recombination nor mutations under these experimental conditions. Thus the results would not support the mitotic recombination theory in tumor promotion. Rather, in this study, TPA posttreatment resulted in reduced frequencies of mutant single spots induced by MMC.     

Genetic control of recombination processes in Aspergillus nidulans. I. Effect of uvs-mutations on the frequency of spontaneous and ultraviolet ray-induced intergenic recombination]

Effect of 3 uvs mutations (uvs 12, 19 and 25) on recombination processes in Aspergillus nidulans is studied. All the mutations are found either to affect the fertility of carp bodies and germination ability of askospores, or result in complete inability of heterokaryons to form cleistocarpia. Two mutations change the frequency of spontaneous meitotic crossing-over at pro-paba region of the chromosome I and do not affect the rate of mitotic recombination at w-centromeric region of the chromosome II: uvs 12 mutation increases, and uvs 19 mutation decreases the frequency of meiotic recombination. One mutation (uvs 25) decreases the rate of spontaneous mitotic crossing-over. All uvs mutations decrease the frequency of VU light induced mitotic recombination at w-centromeric region of the chromosome II. The data obtained, together with earlier reported characteristics of uvs mutants, suggest that recombination mechanisms in yeast participate in reparation processes more actively than in prokariotes. Different effects of the same uvs mutations on spontaneous frequency of meiotic and mitotic crossing-over draw to the conclusion that genetic control and molecular mechanisms of these processes in A. nidulans are not identical.     

The effect of three rad genes on survival, inter- and intragenic mitotic recombination in Saccharomyces. I. UV irradiation without photoreactivation or liquid-holding post-treatment

The effect of UV irradiation on the survival, inter- and intragenic mitotic recombination of 3 diploid UV sensitive Saccharomyces mutants was studied and compared with the wild type RAD. These strains, homozygous for either the RAD, r1s rad 9-4, or rad 2-20 gene, have DRF values for survival of 1:1.6:3:20.6 respectively, at LD1. Their recombination behaviour is not correlated to their survival characteristics. The RAD, r1s, and rad 2-20 strains showed UV induced mitotic inter- and intragenic recombinants; the induction in the r1s diploid is ca. 100 times greater for both the inter- and intragenic recombinants than in the RAD strain. The rad 9-4 diploid produced no UV induced mitotic recombinants whatsoever, and is therefore considered to be a rec- mutation.     

Testing of chemicals for genetic activity with Saccharomyces cerevisiae: a report of the U.S. Environmental Protection Agency Gene-Tox Program

The yeast Saccharomyces cerevisiae is a unicellular fungus that can be cultured as a stable haploid or a stable diploid . Diploid cultures can be induced to undergo meiosis in a synchronous fashion under well-defined conditions. Consequently, yeasts can be used to study genetic effects both in mitotic and in meiotic cells. Haploid strains have been used to study the induction of point mutations. In addition to point mutation induction, diploid strains have been used for studying mitotic recombination, which is the expression of the cellular repair activities induced by inflicted damage. Chromosomal malsegregation in mitotic and meiotic cells can also be studied in appropriately marked strains. Yeast has a considerable potential for endogenous activation, provided the tests are performed with appropriate cells. Exogenous activation has been achieved with S9 rodent liver in test tubes as well as in the host-mediated assay, where cells are injected into rodents. Yeast cells can be recovered from various organs and tested for induced genetic effects. The most commonly used genetic end point has been mitotic recombination either as mitotic crossing-over or mitotic gene conversion. A number of different strains are used by different authors. This also applies to haploid strains used for monitoring induction of point mutations. Mitotic chromosome malsegregation has been studied mainly with strain D6 and meiotic malsegregation with strain DIS13 . Data were available on tests with 492 chemicals, of which 249 were positive, as reported in 173 articles or reports. The genetic test/carcinogenicity accuracy was 0.74, based on the carcinogen listing established in the Gene-Tox Program. The yeast tests supplement the bacterial tests for detecting agents that act via radical formation, antibacterial drugs, and other chemicals interfering with chromosome segregation and recombination processes.     

Altered Fidelity of Mitotic Chromosome Transmission in Cell Cycle Mutants of S. CEREVISIAE

Thirteen of 14 temperature-sensitive mutants deficient in successive steps of mitotic chromosome transmission (cdc2, 4, 5, 6, 7, 8, 9, 13, 14, 15, 16, 17 and 20) from spindle pole body separation to a late stage of nuclear division exhibited a dramatic increase in the frequency of chromosome loss and/or mitotic recombination when they were grown at their maximum permissive temperatures. The increase in chromosome loss and/or recombination is likely to be due to the deficiency of functional gene product rather than to an aberrant function of the mutant gene product since the mutant alleles are, with one exception, recessive to the wild-type allele for this phenotype. The generality of this result suggests that a delay in almost any stage of chromosome replication or segregation leads to a decrease in the fidelity of mitotic chromosome transmission. In contrast, temperature-sensitive mutants defective in the control step of the cell cycle (cdc28), in cytokinesis (cdc3) or in protein synthesis (ils1) did not exhibit increased recombination or chromosome loss.--Based upon previous results with mutants and DNA-damaging agents in a variety of organisms, we suggest that the induction of mitotic recombination in certain mutants is due to the action of a repair pathway upon nicks or gaps left in the DNA. This interpretation is supported by the fact that the induced recombination is dependent upon the RAD52 gene product, as essential component in the recombinogenic DNA repair pathway. Gene products whose deficiency leads to induced recombination are, therefore, strong candidates for proteins that function in DNA metabolism. Among the mutants that induce recombination are those known to be defective in some aspect of DNA replication (cdc2, 6, 8, 9) as well as some mutants defective in the G2 (cdc13 and 17) and M (cdc5 and 14) phases of the mitotic cycle. We suggest that special aspects of DNA metabolism may be occurring in G2 and M in order to prepare the chromosomes for proper segregation.     

The effect of inversions on mitotic recombination in Drosophila melanogaster.

Summary The effect of inversions on mitotic recombination outside the inversion was studied in inversion-heterozygotes. Seven euchromatic inversions of the X-chromosome, with breakpoints within the interval between two cell markers, were chosen. The size of the inverted region and the distance from the proximal breakpoint to the proximal cell marker varied. Mitotic recombination was X-ray induced in larvae and clones scored in the tergites of emerged adults. The frequency of recombinants between both cell markers and the frequency of recombinants proximal to the proximal cell marker was used to estimate the effect of interference in pairing caused by the inversions. Such an effect only occurs in small chromosome intervals. This indicates that homologous sequences are tightly paired in the interphase nuclei of somatic cells. This conclusion is derived from data based on X-ray induced mitotic recombination. The possibility of extending this conclusion to non-irradiated cells is discussed.     

Genetic activity of bleomycin: differential effects on mitotic recombination and mutations in yeast.

The genetic effects of the antitumor antibiotic, bleomycin were studied in different strains of Saccharomyces cerevisiae. It was observed that the drug induced a high frequency of mitotic recombination and gene conversion. In contrast, it produced only a few mutations from adenine independence to adenine dependence and histidine dependence (a missense mutant) to histidine independence. In the strains carrying ochre-suppressible auxotrophic markers, no prototrophs were induced by this drug. The results indicating the specific activity of bleomycin are discussed and, in this connection, the usefulness of yeast as a test organism in mutagenicity screening is emphasized.     

Research inAspergillus nidulans genetics

One of the major goals ofAspergillus nidulans genetical research in Italy has been to set up a series of tests for the evaluation of the genetical risk derived from environmental pollution. The induced frequency of mutation and recombination (mitotic crossing-over and non-disjunction) has been studied for many chemicals and important results have been obtained from a practical and theoretical point of view. Because of the great versatility of Aspergillus as a model organism in genetical research, major basic genetical problems have also been investigated in Italy. Among them it is worth to remember the research on the mitotic intra- and inter-genic recombination. Aspergillus is still used mostly to test non-disjunctional properties of chemicals; in fact it is the only organism where non-disjunction can be properly estimated. Moreover the population genetics and the DNA repair in Aspergillus are currently investigated in our laboratory.     

Chromosomal Translocations Generated by High-Frequency Meiotic Recombination between Repeated Yeast Genes

We have examined meiotic and mitotic recombination between repeated genes on nonhomologous chromosomes in the yeast Saccharomyces cerevisiae. The results of these experiments can be summarized in three statements. First, gene conversion events between repeats on nonhomologous chromosomes occur frequently in meiosis. The frequency of such conversion events is only 17-fold less than the analogous frequency of conversion between genes at allelic positions on homologous chromosomes. Second, meiotic and mitotic conversion events between repeated genes on nonhomologous chromosomes are associated with reciprocal recombination to the same extent as conversion between allelic sequences. The reciprocal exchanges between the repeated genes result in chromosomal translocations. Finally, recombination between repeated genes on nonhomologous chromosomes occurs much more frequently in meiosis than in mitosis.     

Use of a Yeast Site-Specific Recombinase to Produce Female Germline Chimeras in Drosophila

We describe an efficient method for generating female germline mosaics by inducing site-specific homologous mitotic recombination with a yeast recombinase (FLP) which is driven by a heat shock promoter. These germline mosaics are produced in flies heterozygous for the agametic, germline-dependent, dominant female sterile (DFS) mutation ovoD1, where only flies possessing germline clones are able to lay eggs. This method, the "FLP-DFS" technique, is very efficient because more than 90% of females with germline clones can be recovered. We show that this heat-inducible, site-specific mitotic recombination system does not affect viability and that the germline clones recovered are physiologically the same as those created by X-ray induced mitotic recombination. We describe the parameters of FLP-recombinase induced germline mitotic recombination and the use of the "FLP-DFS" technique to analyze the maternal effect of X-linked zygotic lethal mutations.     

Biochemical control of recombination in Saccharomyces cerevisiae. II. L-histidine inhibition of intragenic mitotic recombination at two unlinked loci

Summary A yeast strain heteroallelic at, two unlinked loci, ad ₃ and ur ₂ is used to study mitotic intragenic recombination. The recombination at these two loci is inhibited by L-histidine. The ad ₃ mutation is necessary to have histidine inhibition, his function is not yet, clear. This mutation gives rise to the double requirement in adenine and histidine, and starvation for this amino acid might be the primary cause of a high level of genetic recombination. On the other hand, the biochemical defect of ad ₃ mutants is related to folic coenzymes, and it might well be that these coenzymes play an unsuspected role in genetic recombination.     

Tests for recombinagens in fungi.

Three types of mitotic recombination can be studied in Aspergillus nidulans and Saccharomyces cerevisiae: (1) The classical type of reciprocal mitotic crossing-over which can be detected when it occurs between non-sister chromatids at the four-strand stage followed by co-segregation of a crossing-over and a non-crossing-over chromatid in the subsequent mitotic division. Consequently, mitotic crossing-over reflects cellular responses to primary genetic damage in the G2 phase of the cell cycle. (2) Mitotic gene conversion is a unidirectional event of a localized transfer of genetic information between non-sister chromatids which in yeast can extend to segments of up to 18 cM and even beyond 22 cM in Aspergillus nidulans. Mitotic gene conversion can also occur between unreplicated chromatids and lead to the expression of the newly created genotype without any need for a subsequent mitotic cell division. It reflects a cellular response in G1. (3) Mitotic sister-strand gene conversion can be studied in a recently constructed strain with the same technical ease as classical non-sister chromatid gene conversion. It can be induced by chemicals which do not induce mutation in the Salmonella system and non-sister chromatid gene conversion. Mitotic segregation in Saccharomyces cerevisiae results almost exclusively from crossing-over and gene conversion whereas mitotic chromosomal malsegregation contributes only very little. In contrast to this, in Aspergillus nidulans, both processes contribute considerably so that mitotic segregants always have to be tested for their mechanistic origin.     

The role of the mismatch repair machinery in regulating mitotic and meiotic recombination between diverged sequences in yeast

Nonidentical recombination substrates recombine less efficiently than do identical substrates in yeast, and much of this inhibition can be attributed to action of the mismatch repair (MMR) machinery. In this study an intron-based inverted repeat assay system has been used to directly compare the rates of mitotic and meiotic recombination between pairs of 350-bp substrates varying from 82% to 100% in sequence identity. The recombination rate data indicate that sequence divergence impacts mitotic and meiotic recombination similarly, although subtle differences are evident. In addition to assessing recombination rates as a function of sequence divergence, the endpoints of mitotic and meiotic recombination events involving 94%-identical substrates were determined by DNA sequencing. The endpoint analysis indicates that the extent of meiotic heteroduplex DNA formed in a MMR-defective strain is 65% longer than that formed in a wild-type strain. These data are consistent with a model in which the MMR machinery interferes with the formation and/or extension of heteroduplex intermediates during recombination.