Responses to selection for postmeiotic segregation frequencies in Ascobolus immersus

A composite cross was made between 12 strains of the fungus Ascobolus immersus, six with wild-type red ascospores (w1+) and six with white ascospore mutation w1-78. A high postmeiotic segregation (PMS) frequency line was set up from colonies from ascospores from dehisced octads showing PMS, 5+ : 3w and 3+ : 5w. A low PMS line was started from ascospores from 4+ : 4w or 6+ : 2w octads, and a 'no selection' line was set up from ascospores from random octads. Colonies were crossed to tester strains to determine PMS frequencies and the selected lines were continued from ascospores of crosses of the red ascospore strain with the most extreme (e.g. high for the high line) PMS frequency with the white-ascospore strain of most extreme PMS frequency and of opposite mating type. Significant responses to selection were obtained for increased (+100%) and decreased (-58%) PMS, giving a 4.8-times difference in generation 4, with little change in the frequencies of conversion classes showing meiotic segregation (6+ : 2w and 2+ : 6w). The continuous, symmetrical, roughly normal distributions for PMS frequencies obtained when generation 5 strains were crossed to unselected tester strains are those expected if PMS frequencies are controlled by a number of polygenes, not major genes. Crosses of selected fifth-generation red-ascospore strains with extreme PMS values to base-substitution mutant w1-78, to frame-shift mutant w1-3C1 and to white-ascospore mutants w-BHj and w-9 at two loci unlinked to w1 showed that the effects of selection were not allele specific, locus specific or mutation-type specific.     

The Interactions of Three Widely Separated Loci Controlling Conversion Properties of w Locus I in ASCOBOLUS IMMERSUS

Gene conversion properties of white (w) ascospore locus I in the Pasadena strains of Ascobolus immersus are controlled by complex interactions between three separate conversion control factors ( ccfs), which can give conversion frequencies at wI ranging from less than 1% up to 33%. ccf-2, which has three alleles, is very closely linked to wI but does not usually co-convert with it. ccf-2(K) and ccf-2(91) give lower conversion frequencies than ccf-2(P) and are incompletely dominant to ccf-2(P), with cis/trans position effects on conversion of wI. The "super" factor ( Helmi and Lamb 1979) has two interacting but unlinked components, ccf-3E and ccf-4r, which approximately double the conversion frequency at wI. ccf-2 (linkage group VIII), ccf-3 (linkage group I) and ccf-4 are probably all unlinked but interact and specifically control conversion at wI. ccf-3E could code for a diffusible product that affects the action of different ccf-2 alleles, which probably act by controlling the frequency of initiation of hybrid-DNA, which spreads into the adjacent wI locus. ccf-4R could code for a diffusible inhibitor of ccf-3E product, or be an alternative binding site for ccf-3E product. The dominance of ccf-4R depends on which ccf-2 alleles are present in the cross.     

The control of gene conversion properties and corresponding-site interference: the effects of conversion control factor 5 on conversion at locus w9 in Ascobolus immersus

The controls of various aspects and parameters of gene conversion at locus w-9 in the fungus Ascobolus immersus were investigated, along with positive and negative corresponding-site interference in meiotic chromatid pairing. When conversion control factor 5 alleles A and B were heterozygous, conversion frequencies at the closely linked target locus w9 were reduced to 3%, compared with 10.7% when A or B was homozygous, through effects on hybrid-DNA (h-DNA) formation parameters gamma1 and gamma2. In different ways, not related to whether ccf-5 alleles were homozygous or heterozygous, ccf-5 also affected parameters relating to the relative frequencies of asymmetric and symmetric h-DNA, the frequency with which the chromatid bearing the wild-type allele was the invading chromatid in asymmetric h-DNA, and h-DNA correction parameters for the frequency and direction of correction of mispairs. Corresponding-site interference is interference between the two pairs of non-sister chromatids of a bivalent in h-DNA formation at exactly corresponding sites. This interference was positive in the high conversion frequency crosses homozygous for ccf-5 alleles but was strongly negative in the low conversion frequency crosses heterozygous for ccf-5 alleles, through differential effects on parameters gamma1 and gamma2. Models of chromatid pairing are discussed.     

Comparison of targeted-gene replacement frequencies in Drosophila melanogaster at the forked and white loci.

P element-induced gene conversion has been previously used to modify the white gene of Drosophila melanogaster in a directed fashion. The applicability of this approach of gene targeting in Drosophila melanogaster, however, has not been analyzed quantitatively for other genes. We took advantage of the P element-induced forked allele, f(hd), which was used as a target, and we constructed a vector containing a modified forked fragment for converting f(hd). Conversion frequencies were analyzed for this locus as well as for an alternative white allele, w(eh812). Combination of both P element-induced mutant genes allowed the simultaneous analysis of conversion frequencies under identical genetic, developmental, and environmental conditions. This paper demonstrates that gene conversion through P element-induced gap repair can be applied with similar success rates at the forked locus and in the white gene. The average conversion frequency at forked was 0.29%, and that at white was 0.17%. These frequencies indicate that in vivo gene targeting in Drosophila melanogaster should be applicable for other genes in this species at manageable rates. We also confirmed the homolog dependence of reversions at the forked locus, indicating that P elements transpose via a cut-and-paste mechanism. In a different experiment, we attempted conversion with a modified forked allele containing the su(Hw) binding site. Despite an increased sample size, there were no conversion events with this template. One interpretation (under investigation) is that the binding of the su(Hw) product prevents double-strand break repair.     

CYS3, a hotspot of meiotic recombination in Saccharomyces cerevisiae. Effects of heterozygosity and mismatch repair functions on gene conversion and recombination intermediates

We have examined meiotic recombination at the CYS3 locus. Genetic analysis indicates that CYS3 is a hotspot of meiotic gene conversion, with a putative 5'-3' polarity gradient of conversion frequencies. This gradient is relieved in the presence of msh2 and pms1 mutations, indicating an involvement of mismatch repair functions in meiotic recombination. To investigate the role of mismatch repair proteins in meiotic recombination, we performed a physical analysis of meiotic DNA in wild-type and msh2 pms1 strains in the presence or absence of allelic differences at CYS3. Neither the mutations in CYS3 nor the absence of mismatch repair functions affects the frequency and distribution of nearby recombination-initiating DNA double-strand breaks (DSBs). Processing of DSBs is also similar in msh2 pms1 and wild-type strains. We conclude that mismatch repair functions do not control the distribution of meiotic gene conversion events at the initiating steps. In the MSH2 PMS1 background, strains heteroallelic for frameshift mutations in CYS3 exhibit a frequency of gene conversion greater than that observed for either marker alone. Physical analysis revealed no modification in the formation of DSBs, suggesting that this marker effect results from subsequent processing events that are not yet understood.     

Mapping and Gene Conversion Studies with the Structural Gene for Iso-1-Cytochrome C in Yeast

We have investigated the order of the four genes cyc1, rad7, SUP4, and cdc8 which form a tightly linked cluster on the right arm of chromosome X in the yeast Saccharomyces cerevisiae. Crossing over and coconversion data from tetrad analysis established the gene order to be centromere-cyc1-rad7-SUP4. Also cdc8 appeared to be distal to SUP4 on the basis of crossovers that were associated with conversion of SUP4. The frequencies of recombination and the occurrence of coconversions suggest that these four genes are contiguous or at least nearly so. Gene-conversion frequencies for several cyc1 alleles were studied, including cyc1-1, a deletion of the whole gene that extends into the rad7 locus. The cyc1-1 deletion was found to be capable of conversion, though at a frequency some fivefold less than the other alleles studied, and both 3:1 and 1:3 events were detected. In general 1:3 and 3:1 conversion events were equally frequent at all loci studied, and approximately 50% of conversions were accompanied by reciprocal recombination for flanking markers. The orientation of the cyc1 gene could not be clearly deduced from the behavior of the distal marker SUP4 in wild-type recombinants that arose from diploids heteroallelic for cyc1 mutations.     

Behavior of the [Mi-3] Mutation and Conversion of Polymorphic Mtdna Markers in Heterokaryons of Neurospora Crassa

We have examined the behavior of the [mi-3] mitochondrial mutation and two physical mtDNA markers in heterokaryotic cultures of Neurospora crassa. Previous workers showed that a 1.2-kilobase insertion in the larger polymorphic form of EcoRI-5 restriction fragment is a site of high frequency and rapid unidirectional gene conversion. We have confirmed this observation and determined by DNA sequence analysis that the insertion in the EcoRI-5 fragment corresponds precisely to an optional intron that contains a long open reading frame in the ND1 gene. Thus, the conversion of the short, intron-lacking, form of EcoRI-5 to the longer, intron-containing, form may be analogous to the unidirectional gene conversion events catalyzed by intron-encoded proteins in other organisms. The resolution of two polymorphic forms of the mtDNA EcoRI-9 restriction fragment in our heterokaryons differs from that observed previously and suggests that this locus is not a site of gene conversion in our heterokaryon pair. The size polymorphism of the EcoRI-9 fragments is due to a tandemly reiterated 78-base-pair sequence which occurs two times in the short form and three times in the long form. One copy of the repeat unit and 66 base pairs following it have been duplicated from the ND2 gene which is located about 30 kilobases distant on the mtDNA. In contrast to the [poky] mitochondrial mutant, which was completely dominant over wild-type mitochondria in heterokaryons, the [mi-3] mutant was recovered in only seven of twenty heterokaryons after ten cycles of conidiation and subculturing. The resolution of the [mi-3] or wild-type phenotype in heterokaryons may depend solely on random factors such as allele input frequency, drift, and segregation rather than specific dominant or suppressive effects.     

Diazepam-induced cleft palate in the mouse and lack of correlation with the H-2 locus

Cleft palate frequencies were studied in AJ and SW mice following either 1- or 2-day dosing schedules with the anxiolytic drug diazepam (DAZ). In all cases, mice were food and water deprived for 24 and 48 hours in the 1- and 2-day dosing schedules, respectively. High cleft palate frequencies in control mice of both strains resulting from 48-hour food and water deprivation (on days 13.5 and 14.5 of gestation) were reduced in mice deprived for 24 hours, indicating a stress related effect. Two-day dosing with DAZ (400 mg/kg) produced a net increase in cleft palate frequency in SW (33%) and AJ (18%) mice. Mice treated only on day 13.5 had reduced control and DAZ cleft palate frequencies, neither of which were significant. Clefting was significant but reduced following 1-day dosing on day 13/20 of gestation (13 days 20 hours) in SW mice (18%), whereas no clefting was seen in the AJ strain. This strain difference was shown not to be related to differences in developmental timing. Production of cleft palate seen in AJ mice after 2 days of dosing may be indicative of an interaction of DAZ with the stresses resulting from food and water deprivation. Genes of the major histocompatibility locus, H-2, have been shown to regulate cleft palate formation following glucocorticoid and phenytoin administration to mice. Despite pharmacological similarities between DAZ and phenytoin, comparison of cleft palate frequencies following administration of DAZ to various strains of mice of different H-2 haplotypes indicated that genes associated with the H-2 locus do not regulate DAZ-induced cleft palate in these strains.     

The effects of gene conversion control factors on conversion-induced changes in allele frequencies in populations and on linkage disequilibrium

Conversion control factors (ccfs) are widespread. They control conversion properties at their target loci, affecting the conversion frequency and the amount and even the direction of gene conversion disparity. Three major types of ccf can be recognised. Experimental studies of the effects of ccfs have been combined with theoretical studies and modelling to examine the effects of ccfs on the evolutionary population genetics of alleles at the target locus. The ccf alleles present can greatly affect the rate and the direction of conversion-induced changes in target locus allele frequencies. Gene conversion can both cause and remedy linkage disequilibrium, with causation being related to polymorphismfor ccfs. Disparity in conversion direction does not by itself necessarily cause linkage disequilibrium.     

Deep Genome-Wide Measurement of Meiotic Gene Conversion Using Tetrad Analysis in Arabidopsis thaliana

Gene conversion, the non-reciprocal exchange of genetic information, is one of the potential products of meiotic recombination. It can shape genome structure by acting on repetitive DNA elements, influence allele frequencies at the population level, and is known to be implicated in human disease. But gene conversion is hard to detect directly except in organisms, like fungi, that group their gametes following meiosis. We have developed a novel visual assay that enables us to detect gene conversion events directly in the gametes of the flowering plant Arabidopsis thaliana. Using this assay we measured gene conversion events across the genome of more than one million meioses and determined that the genome-wide average frequency is 3.5×10⁻⁴ conversions per locus per meiosis. We also detected significant locus-to-locus variation in conversion frequency but no intra-locus variation. Significantly, we found one locus on the short arm of chromosome 4 that experienced 3-fold to 6-fold more gene conversions than the other loci tested. Finally, we demonstrated that we could modulate conversion frequency by varying experimental conditions.     

DNA polymorphisms in the chicken growth hormone gene: response to selection for disease resistance and association with egg production

Analysis of the growth hormone (GH) gene in 12 strains of White Leghorn chickens revealed restriction fragment length polymorphisms (RFLPs) at three Msp I sites and at a Sac I site. Based on linkage disequilibrium analysis, they gave rise to eight different alleles (i.e. combinations of RFLPs), with five occurring at frequencies above 5% in at least one strain. Pairs of GH–RFLPs were at near maximal linkage disequilibrium, suggesting either a lack of recombination or the presence of selection pressure during evolution of the GH gene. Allele frequencies were determined in 12 non-inbred strains derived from three different genetic bases. These strains had been selected either for an array of egg production traits, resistance to Marek's disease or resistance to avian leukosis. Selection for disease resistance was consistently correlated with an increase in the frequency of one of the alleles. One strain segregated for only two alleles, which differed by three RFLPs. Analysis of variance in this strain indicated that the GH allele co-selected with resistance was associated with a delayed onset of ovulation but a higher persistency of ovulation as age progressed, resulting in an overall increase of egg production by 15% (age at first egg to 497 days). The resistance-associated GH allele was dominant for the onset of ovulation and recessive for the persistency of egg production. There was no significant effect of the GH genotype on juvenile body weight, egg weight or egg specific gravity.     

Polygenic and Single Gene Responses to Selection for Resistance to Diazinon in Lucilia Cuprina

Following mutagenesis with ethyl methanesulfonate, selection in a susceptible strain with a concentration of the insecticide diazinon (0.0004%, w/v) above that required to kill 100% of the susceptible strain, the LC100 of that strain, resulted in a single gene response. The resultant four mutant resistant strains have equivalent physiological, genetical and biochemical profiles to a diazinon-resistant strain derived from a natural population and homozygous for the Rop-1 allele. Modification of the microsomal esterase E3 is responsible for resistance in each case. The Rop-1 locus maps approximately 4.4 map units proximal to bu on chromosome IV. Selection within the susceptible distribution, at a concentration of diazinon [0.0001% (w/v)] less than the LC100, resulted in a similar phenotypic response irrespective of whether the base population had been mutagenized. The responses were polygenically based, unique to each selection line and independent of Rop-1. The relevance of the results to selection for insecticide resistance in laboratory and natural populations is discussed.     

Inherited differences in crossing over and gene conversion frequencies between wild strains of Sordaria fimicola from "Evolution Canyon".

Recombination generates new combinations of existing genetic variation and therefore may be important in adaptation and evolution. We investigated whether there was natural genetic variation for recombination frequencies and whether any such variation was environment related and possibly adaptive. Crossing over and gene conversion frequencies often differed significantly in a consistent direction between wild strains of the fungus Sordaria fimicola isolated from a harsher or a milder microscale environment in "Evolution Canyon," Israel. First- and second-generation descendants from selfing the original strains from the harsher, more variable, south-facing slope had higher frequencies of crossing over in locus-centromere intervals and of gene conversion than those from the lusher north-facing slopes. There were some significant differences between strains within slopes, but these were less marked than between slopes. Such inherited variation could provide a basis for natural selection for optimum recombination frequencies in each environment. There were no significant differences in meiotic hybrid DNA correction frequencies between strains from the different slopes. The conversion analysis was made using only conversions to wild type, because estimations of conversion to mutant were affected by a high frequency of spontaneous mutation. There was no polarized segregation of chromosomes at meiosis I or of chromatids at meiosis II.     

The Ade6-M26 Mutation of Schizosaccharomyces Pombe Increases the Frequency of Crossing over

The ade6-M26 mutation of Schizosaccharomyces pombe increases conversion frequency in comparison with the nearby mutation ade6-M375. In order to investigate the effect of ade6-M26 on crossover frequency, heteroallelic ade6 duplications were constructed by integration of plasmids carrying the marker gene ura4. One ade6 gene carries either of the mutations M26 or M375 while the other ade6 copy carries the L469 mutation in both duplications. The duplication with ade6-M26 yields Ade(+) recombinants at significantly higher frequencies in meiosis, but not in mitosis. Tetrad analysis and physical characterization of spore clones from recombination tetrads demonstrate that conversions, unequal crossovers and intrachromatid exchanges occur at higher frequencies but with unaltered proportions among them. The conversion events show a pronounced bias when M26 is involved: they take place preferentially at the M26 allele. Thus the ade6-M26 mutation not only enhances conversion frequency as demonstrated before, but also crossover frequency. It displays the properties expected for a preferred site of initiation of general meiotic recombination. The duplications also yielded new information on ectopic recombination in S. pombe: ectopic crossovers occur in the duplications at much higher frequency than among naturally dispersed homologous sequences.     

Effect of 60-Hz magnetic fields on ultraviolet light-induced mutation and mitotic recombination in Saccharomyces cerevisiae.

The purpose of this study was to examine the effect of extremely low frequency (ELF) magnetic fields on the induction of genetic damage. In general, mutational studies involving ELF magnetic fields have proven negative. However, studies examining sister-chromatid exchange and chromosome aberrations have yielded conflicting results. In this study, we have examined whether 60-Hz magnetic fields are capable of inducing mutation or mitotic recombination in the yeast Saccharomyces cerevisiae. In addition we determined whether magnetic fields were capable of altering the genetic response of S. cerevisiae to UV (254 nm). We measured the frequencies of induced mutation, gene conversion and reciprocal mitotic crossing-over for exposures to magnetic fields alone (1 mT) or in combination with various UV exposures (2-50 J/m2). These experiments were performed using a repair-proficient strain (RAD+), as well as a strain of yeast (rad3) which is incapable of excising UV-induced thymine dimers. Magnetic field exposures did not induce mutation, gene conversion or reciprocal mitotic crossing-over in either of these strains, nor did the fields influence the frequencies of UV-induced genetic events.     

Mutation-Selection Balance under Genomic Imprinting at an Autosomal Locus

I model the effect of genomic imprinting on the equilibrium allele frequencies at an autosomal diallelic locus subject to viability selection and mutation. The population size is assumed to be very large; male and female mutation rates may be unequal. Different models examine cases of the inactivation of one gene (with both complete and partial penetrance) and of differential expression of genes according to the parent of origin. In the simplest cases the frequency of the deleterious allele is approximately twice that of a dominant nonimprinting mutant, but considerably less than that of a recessive nonimprinting mutant. Under imprinting, selection and unequal mutation rates interact: other things being equal, male-biased mutation leads to lower mutant frequencies under maternal imprinting and higher frequencies under paternal imprinting. I also model cases where just one allele is imprintable (and the other not). These models allow us to predict the frequency of a failure to imprint in a normally imprinting system, as well as the frequency of imprinting at a standard nonimprinting locus.     

Gene conversion in nonsense suppressors of Schizosaccharomyces pombe. I. The influence of the genetic background and of three mutant genes (rad2, mut1 and mut2) on the frequency of the post-meiotic segregation.

Summary The frequency of gene conversion was assessed at the anticodon site of the sup3 gene of Schizosaccharomyces pombe. In order to detect a possible influence of the genetic background on the relative frequency of post-meiotic segregations amongst conversions, three similar crosses were analyzed which differed as follows: In cross I the two parents were derived by spontaneous mutation from one and the same strain. The heterogeneity of the genetic background between these two parent strains is assumed to be at a minimum level. In cross II the crossing partners were strains of the Bernese stock collection and differ probably in their genetic background to some extent. Last, in cross III, one of the parent strains was ten times repeatedly mutagenized with nitrosoguanidine in order to introduce cryptic mutations in the genome. A maximum degree of background heterogeneity between parents is expected for this cross. Neither the total conversion frequency nor the frequency of post-meiotic segregations amongst conversions were found to be significantly different in these three crosses.In addition, no effect of the radiation-sensitive mutation, rad2-44, and of two mutator mutations, mut1-4 and mut2-9, on the conversion pattern could be detected.     

Identification of a common ecotropic viral integration site, Evi-1, in the DNA of AKXD murine myeloid tumors.

AKXD-23 recombinant inbred mice develop myeloid tumors at a high frequency, unlike other AKXD recombinant inbred strains which develop B-cell lymphomas, T-cell lymphomas, or both. AKXD-23 myeloid tumors are monoclonal, and their DNA contains somatically acquired proviruses, suggesting that they are retrovirally induced. We identified a common site of ecotropic proviral integration that is present in the DNA of all AKXD-23 myeloid tumors that were analyzed and in the DNA of all myeloid tumors that occur in AKXD strains other than AKXD-23. We designated this locus Evi-1 (ecotropic viral integration site 1). Rearrangements in the Evi-1 locus were also detected in the DNA of a number of myeloid tumors and myeloid cell lines isolated from strains other than AKXD. In contrast, few Evi-1 rearrangements were detected in the DNA of T- or B-cell tumors. Evi-1 may thus identify a new proto-oncogene locus that is involved in myeloid disease.     

Use of fluorescent protein to analyse recombination at three loci in Neurospora crassa

We have inserted a histone H1-GFP fusion gene adjacent to three loci on different chromosomes of Neurospora crassa and made mating pairs in which a wild type version of GFP is crossed to one with a mutation in the 5' end of GFP. The loci are his-3, am and his-5, chosen because recombination mechanisms appear to differ between his-3 and am, and because crossing over adjacent to his-5, like his-3, is regulated by rec-2. At his-3, the frequencies of crossing over between GFP and the centromere and of conversion of 5'GFP to GFP(+) are comparable to those obtained by classical recombination assays, as is the effect of rec-2 on these frequencies, suggesting that our system does not alter the process of recombination. At each locus we have obtained sufficient data, on both gene conversion and crossing over, to be able to assess the effect of deletion of any gene involved in recombination. In addition, crosses between a GFP(+) strain and one with normal sequence at all three loci have been used to measure the interval to the centromere and to show that GFP experiences gene conversion with this system. Since any gene expressed in meiosis is silenced in Neurospora if hemizygous, any of our GFP(+) strains can be used as a quick screen to determine if a gene deleted by the Neurospora Genome Project is involved in crossing over or gene conversion.