Long,interrupted conversion tracts initiated by cog in Neurospora crassa.

Multiple polymorphisms distinguish Emerson and Lindegren strains of Neurospora crassa within the histidine-3 gene and in its distal flank. Restriction site and sequence length polymorphism in a set of 14 PCR products covering this 6.9-kb region were used to identify the parental origin of DNA sequence information in prototrophic progeny of crosses heterozygous for auxotrophic mutations in his-3 and the silent sequence differences. Forty-one percent of conversion tracts are interrupted. Where the absence of rec-2+ permits activity of the recombination hotspot cog, conversion appears to originate at cog and conversion tracts are up to 5.9 kb long. The chromosome bearing cog(L), the dominant allele that confers a high frequency of recombination, is almost invariably the recipient of information. In progeny from crosses heterozygous rec-2/rec-2+, conversion tracts are much shorter, most are not initiated at cog and either chromosome seems equally likely to be converted. Although 32% of his-3 prototrophs have a crossover that may be associated with conversion, it is suggested that the apparent association between conversion and crossing over at this locus may be due to confounding of coincidental events rather than to a mechanistic relationship.     

The control of allelic recombination at histidine loci in Neurospora crassa

The gene rec-1⁺ which reduces allelic recombination at the his-1 locus by a factor of between 15 and 30 has no effect upon allelic recombination at the his-2, his-3, his-5, his-6 and his-7 loci. Other genes controlling recombination at two of these loci, namely rec-x at his-2 and rec-w at his-3, have been found. There is a strong possibility that rec-x may be identical with rec-3, so far known to regulate recombination only at the am-1 locus. It is probable that the stocks used all carry a rec⁺ gene which regulates recombination at the his-6 locus, since all prototroph frequencies are low, but no regulatory gene active at the his-5 and his-7 loci.     

A yeast centromere acts in cis to inhibit meiotic gene conversion of adjacent sequences

The centromere of chromosome III (CEN3) of yeast has been examined for its ability to inhibit meiotic recombination in adjacent sequences. The effect of the centromere was investigated when it was adjacent to both of the recombining sequences (homozygous) or adjacent to only one of the two recombining DNA segments (hemizygous). When homozygous, CEN3 exerts a bidirectional repression of crossing over and a strong inhibition of gene conversion. This suggests that CEN3 reduces the frequency of crossing over by interfering with the initiation of proximal recombination events. When hemizygous, CEN3 impairs the ability of adjacent sequences to act as the recipient of genetic information during gene conversion. These results support the idea that the initiating event in yeast meiotic recombination involves the recipient molecule.     

Alleles of the hotspot cog are codominant in effect on recombination in the his-3 region of Neurospora

There are two naturally occurring functional alleles of the recombination hotspot cog, which is located 3.5 kb from the his-3 locus of Neurospora crassa. The presence of the cog+ allele in a cross significantly increases recombination in the his-3 region compared to a cross homozygous for the cog allele. Data obtained shortly after discovery of cog+ suggested that it was fully dominant to cog. However, a dominant cog+ conflicts with observations of hotspots in Saccharomyces cerevisiae and Schizosaccharomyces pombe, in which recombination is initiated independently of homolog interactions, and suggests recombination mechanisms may differ in Neurospora and yeast. We present evidence that cog alleles are codominant in effect on both allelic recombination in his-3 and crossing over between loci flanking his-3. In addition, we show that genetic background variation has at least a twofold effect on allelic recombination. We speculate that variation in genetic background, together with the complexities of recombination in crosses bearing close mutant alleles, accounts for the previous conclusion that cog+ is dominant to cog.     

Recombination at his-3 in Neurospora declines exponentially with distance from the initiator,cog

By deletion of 1.8 kb of sequence between cog(L) and his-3 and replacement with sequences of different lengths, we have generated a set of Neurospora strains in which the distance between cog(L) and the site at which recombination is selected varies from 1.7 to nearly 6 kb. Each of the manipulated strains includes cog(L), a highly active recombination hotspot, and rec-2, thus allowing high-frequency recombination. In addition, each is a his-3 mutant, either K26 or K480. The frequency of His(+) recombinants in progeny of these crosses is inversely proportional to the distance between his-3 and cog. Specifically, there is a linear relationship between log(10) (recombination frequency) and the distance in base pairs, indicating that as distance decreases, the rate of interallelic recombination increases exponentially. An exponential relationship between distance separating markers and the chance of co-conversion has been found in both Drosophila and fission yeast, indicating that the extension of recombination events may be a stochastic process in most organisms. On the basis of these and additional data presented in this article, we conclude that recombination is initiated at cog(L) in >17% of meioses, that most conversion tracts are very short, and that few extend >14 kb.     

Recombination events in Neurospora crassa may cross a translocation breakpoint by a template-switching mechanism

To assist investigation of the effect of sequence heterology on recombination in Neurospora crassa, we inserted the Herpes simplex thymidine kinase gene (TK) as an unselected marker on linkage group I, giving a gene order of Cen-his-3-TK-cog-lpl. We show here that in crosses heterozygous for TK, conversion of a his-3 allele on one homolog is accompanied by transfer of the heterologous sequence between cog and his-3 from the other homolog, indicating that recombination is initiated centromere-distal of TK. We have identified a 10-nucleotide motif in the cog region that, although unlikely to be sufficient for hotspot activity, is required for high-frequency recombination and, because conversion of silent sequence markers declines on either side, may be the recombination initiation site. Additionally, we have mapped conversion tracts in His(+) progeny of a translocation heterozygote, in which the translocation breakpoint separates cog from the 5' end of his-3. We present molecular evidence of recombination on both sides of the breakpoint. Because recombination is initiated close to cog and the event must therefore cross the translocation breakpoint, we suggest that template switching occurs in some recombination events, with repair synthesis alternating between use of the homolog and the initiating chromatid as template.     

Occurrence in wild strains of Neurospora crassa of genes controlling genetic recombination.

Each of the main laboratory wild stocks of N. crassa carries one of two alleles at the rec-1 and rec-2 loci and one of three at the rec-3 locus. The constitutions of the stocks are given in Fig. 1. Some of those conserved are evidently not the originals. The third rec-3 gene (rec-3L), found in Lindegren A, controls recombination at the am-1 locus to a level between that of rec-3+ and rec-3, the relative levels being 1 : 8 : 25. At the his-2 locus rec-3L is indistinguishable from rec-3+ in its level of control. This proves that there are minor differences between the control (con) genes, near to am-1 and his-2, which recognize products of rec-3 genes. Further, this is the first clear evidence, though indirect, that the binding sites for products of rec genes are situated in the chromosome regions where recombination is modulated.     

Mutation of msh-2 in Neurospora crassa does not reduce the incidence of recombinants with multiple patches of donor chromosome sequence

The Neurospora homologue msh-2 of the Escherichia coli mismatch repair gene mutS was mutated by repeat-induced point mutation (RIP) of a 1.9-kb duplication covering 1661bp of the coding sequence and 302 bp 5' of the gene. msh-2(RIP-LK1) exhibited a mutator phenotype conferring a 17-fold increase in the frequency of spontaneous mitotic reversion of his-3 allele K458. In msh-2(RIP-LK1) homozygotes, recombination frequency at the his-3 locus increased up to 2.9-fold over that in msh-2(+) diploids. Progeny of crosses homozygous msh-2(RIP-LK1), like those from crosses homozygous msh-2(+) frequently had multiple patches of donor chromosome sequence, suggesting that patchiness in msh-2(+) crosses is not explained by incomplete repair of heteroduplex DNA by MSH-2. These findings are consistent with data from the analysis of events in a Neurospora translocation heterozygote that suggested multiple patches of donor chromosome sequence arising during recombination reflect multiple template switches during DNA repair synthesis.     

Evidence for negative interference: clustering of crossovers close to the am locus in Neurospora crassa among am recombinants.

In response to a conflict between two mapping studies in the predicted orientation of the allele map with respect to the centromere, Fincham proposed that recombination events at the Neurospora am locus rarely have an associated crossover. Fincham considered that the elevated levels of crossing over between flanking markers in am recombinants resulted from negative interference, an increased probability of a nearby second event, and on this basis predicted a clustering of crossing over near am in these recombinants. In this article we reevaluate the data from three mapping studies of the am locus and report molecular evidence that shows crossovers to be clustered immediately proximal to am in am recombinants.     

Double recombinants in mitosis

A mathematical model for the random process of repeated cell division and recombination in two nonoverlapping genetic intervals is formulated and investigated. From this model, a test for statistical independence of recombination in the two intervals and a method of estimating the rate of double recombination are developed. Crossing over in both intervals, crossing over in one and gene conversion in the other, and gene conversion in both are treated. For markers on the same chromosome, all possible arrangements of the loci relative to the centromere are considered.Supported by National Science Foundation Grant DEB81-03530.     

Gene Conversion Alone Accounts for More than 90% of Recombination Events at the Am Locus of Neurospora Crassa

We have used closely flanking molecular markers located ~4 kb distal and 6 kb proximal of the am locus to investigate the incidence of crossover events associated with the generation of prototrophic recombinants in a cross heteroallelic am(1) am(6). Ninety-three percent of prototrophs were generated by events that did not recombine the molecular markers, indicating that simple conversion accounts for the formation of most prototrophs and that associated crossovers are much less frequent (~0.07) than estimated previously using more distant flanking markers. This suggests that conversion and crossing over during meiosis may arise from distinct mechanisms or that if, as is widely supposed, conversion and crossing over result from alternate modes of resolution of Holliday junctions then, at least for the am locus of Neurospora, the mode of resolution is strongly biased in favor of retaining the parental association of flanking sequences. Because estimates of the association of conversion and crossing over based on more distant gene markers are similar for yeast and Neurospora (~0.35), our observation may have general significance.     

Crossing-over across the centromere in the mating-type chromosome ofNeurospora crassa

The frequency of crossing-over in the two short regions on opposite arms, adjacent to the centromere of the mating-type chromosome ofNeurospora crassa is controlled, independently in each arm, by at least two genes with equal and additive effect. These genes segregate on inbreeding and cause great variability in both the frequency of recombination and the frequency of second-division segregation of loci situated within these regions. Recombination values between loci situated beyond these sensitive regions is not affected; the relative increase or decrease in their centromere distances may be attributed to change in the recombination frequency about the centromere only.     

Genetic factors affecting allelic recombination at the histidine-3 locus ofNeurospora crassa

Summary In addition to the generec-4, other genetic factors affect the frequency of allelic recombination in thehis-3 locus. One dominant factor, designated asrec-6 ⁺, in association withrec-4 ⁺ causes greater reduction in prototrophic frequency than obtained withrec-4 ⁺ alone. The action ofrec 6 ⁺ in crosses recessive homozygous forrec-4 is not established at the present. The effect ofrec-6 ⁺ is recognised only with onehis-3 allele but not with another. Interaction ofrec-4 ⁺ orrec-4 with other genetic factors can give approximately ten fold variation in the prototrophic frequencies obtained with a pair of alleles. It is suggested that the control of the rate of mutations during meiosis might be one of the roles of the recombination genes.     

Targeting vectors for gene diversification by meiotic recombination in Neurospora crassa.

We have constructed a pair of vectors, pDV2 and pDV3, that enable targeted insertion of exogenous DNA into Linkage Group I of Neurospora crassa at the his-3 locus. Transplaced sequences are inserted between his-3 and the cog(L) recombination hot spot and include his-3 mutations that allow meiotic recombination initiated by cog(L) to be monitored. Selection of correctly placed transforming DNA is based on complementation between different his-3 alleles borne by the plasmids and transformation hosts. The system allows investigation of the effect of any given sequence on recombination as well as diversification of sets of related sequences in vivo for directed evolution of genes.     

Recombination, gene conversion, and identity-by-descent at three loci

We investigate the probabilities of identity-by-descent at three loci in order to find a signature which differentiates between the two types of crossing over events: recombination and gene conversion. We use a Markov chain to model coalescence, recombination, gene conversion and mutation in a sample of size two. Using numerical analysis, we calculate the total probability of identity-by-descent at the three loci, and partition these probabilities based on a partial ordering of coalescent events at the three loci. We use these results to compute the probabilities of four different patterns of conditional identity and non-identity at the three loci under recombination and gene conversion. Although recombination and gene conversion do make different predictions, the differences are not likely to be useful in distinguishing between them using three locus patterns between pairs of DNA sequences. This implies that measures of genetic identity in larger samples will be needed to distinguish between gene conversion and recombination.     

Meiotic Recombination in Neurospora crassa Proceeds by Two Pathways with Extensive Holliday Junction Migration

Analysis of thousands of Δmsh-2 octads using our fluorescent recombination system indicates that, as in other filamentous fungi, symmetric heteroduplex is common in the his-3 region of Neurospora crassa. Symmetric heteroduplex arises from Holliday junction migration, and we suggest this mechanism explains the high frequency of His⁺ spores in heteroallelic crosses in which recombination is initiated cis to the his-3 allele further from the initiator, cog⁺. In contrast, when recombination is initiated cis to the his-3 allele closer to cog⁺, His⁺ spores are mainly a result of synthesis-dependent strand annealing, yielding asymmetric heteroduplex. Loss of Msh-2 function increases measures of allelic recombination in both his-3 and the fluorescent marker gene, indicating that mismatches in asymmetric heteroduplex, as in Saccharomyces cerevisiae, tend to be repaired in the direction of restoration. Furthermore, the presence of substantial numbers of conversion octads in crosses lacking Msh-2 function suggests that the disjunction pathway described in S. cerevisiae is also active in Neurospora, adding to evidence for a universal model for meiotic recombination.     

Multilocus Analysis for Gene-Centromere Mapping Using First Polar Bodies and Secondary Oocytes

Polar body and oocyte typing is a new technique for gene-centromere mapping and for generating female linkage maps. A maximum likelihood approach is presented for ordering multiple markers relative to the centromere and for estimating recombination frequencies between markers and between the centromere and marker loci. Three marker-centromere orders are possible for each pair of markers: two orders when the centromere flanks the two markers and one order when the centromere is flanked by the two markers. For each possible order, the likelihood was expressed as a function of recombination frequencies for two adjacent intervals. LOD score for recombination frequency between markers or between the centromere and a marker locus was derived based on the likelihood for each gene-centromere order. The methods developed herein provide a general solution to the problem of multilocus genecentromere mapping that involves all theoretical crossover possibilities, including four-strand double crossovers.     

Fission yeast Mus81.Eme1 Holliday junction resolvase is required for meiotic crossing over but not for gene conversion

Most models of homologous recombination invoke cleavage of Holliday junctions to explain crossing over. The Mus81.Eme1 endonuclease from fission yeast and humans cleaves Holliday junctions and other branched DNA structures, leaving its physiological substrate uncertain. We report here that Schizosaccharomyces pombe mus81 mutants have normal or elevated frequencies of gene conversion but 20- to 100-fold reduced frequencies of crossing over. Thus, gene conversion and crossing over can be genetically separated, and Mus81 is required for crossing over, supporting the hypothesis that the fission yeast Mus81.Eme1 protein complex resolves Holliday junctions in meiotic cells.     

Estimating the contribution of mutation, recombination and gene conversion in the generation of haplotypic diversity

Recombination occurs through both homologous crossing over and homologous gene conversion during meiosis. The contribution of recombination relative to mutation is expected to be dramatically reduced in inbreeding organisms. We report coalescent-based estimates of the recombination parameter (rho) relative to estimates of the mutation parameter (theta) for 18 genes from the highly self-fertilizing grass, wild barley, Hordeum vulgare ssp. spontaneum. Estimates of rho/theta are much greater than expected, with a mean rho/theta approximately 1.5, similar to estimates from outcrossing species. We also estimate rho with and without the contribution of gene conversion. Genotyping errors can mimic the effect of gene conversion, upwardly biasing estimates of the role of conversion. Thus we report a novel method for identifying genotyping errors in nucleotide sequence data sets. We show that there is evidence for gene conversion in many large nucleotide sequence data sets including our data that have been purged of all detectable sequencing errors and in data sets from Drosophila melanogaster, D. simulans, and Zea mays. In total, 13 of 27 loci show evidence of gene conversion. For these loci, gene conversion is estimated to contribute an average of twice as much as crossing over to total recombination.     

链孢霉四分体分析连锁基因距离矫正的一种简便方法和计算数据的修正

本文探讨一个在链孢霉四分体分析中连锁基因距离矫正的简便方法。并提出在计算交换值时,当遇到着丝粒在两基因中间的类型时,应该把基因与着丝粒之间发生的四线双交换类型分别计入两个单交换内。 Abstract:The present paper is dealing with a simple method to correct the distance of linked genes in tetrad analysis in Neurospora crassa.It is suggested that the data of 4-thread double crossing over should be added in two single crossing over respectively in centromere maping when calculating crossover value of the two genes locating across the centromere.