Biochemical control of recombination in Saccharomyces cerevisiae. I. L-histidine inhibition of intragenic mitotic recombination at the ad 3 locus

Summary A yeast strain heteroallelic at the ad ₃ locus is used to study mitotic intragenic recombination. L-histidine inhibits the recombination at this locus in strains heteroallelic for all possible combinations between the four alleles studied. No other amino acid has this effect. The kinetic of recombination was studied by addition of L-histidine at different times or by compeating the L-histidine present with D-histidine added at different times. The two techniques gave similar results showing that the recombination takes place between the 8th and 24th hour after plating although it is expressed a few days later.Taking advantage of the early interval in which the recombination takes place and of the fact than the petite mutation is induced by acriflavine only in new formed buds, we developed a technique to study the recombination in liquid medium, thanks to which, we were able to show that L-histidine inhibits the genetic event itself.     

Control of recombination ability of vegetative cells in Saccharomyces cerevisiae

Summary In a diploid strain heteroallelic at the ade3 locus, the mitotic intragenic recombination frequency is enhanced ten fold when the cell population is starved for histidine (Hénaut et Luzzati, 1971). By studying simultaneous recombinational events at two independant loci, it is shown that the effect of histidine starvation is most simply explained in term of an increase in the frequency of cells capable of recombination. In these competent cells, intragenic recombination frequencies during mitosis are equal to those found during meiosis. However, the frequency of recombination between the gene and the centromere appears to be lower during mitosis than during meiosis.We believe that histidine starvation in ade3 strains stimulates chromosome pairing, and that there is no fundamental difference between mitotic and meiotic recombination.     

Hydroxylamine-induced purple adenine (ad-3) mutants in Neurospora crassa. I. Characterization of mutants by genetic tests

The genetic effects of hydroxylamine (HA) on Neurospora crassa were studied in an effort to understand the difference between the results obtained on very simple prokaryotic systems and those obtained with mammalian systems. A 2-component heterokaryon was used to study the inactivation of conidia and the induction of recessive lethal mutations at specific loci and over the entire genome. The heterokaryon is heterozygous for 2 closely linked loci, ad-₃A and ad-₃B, in the ad-₃ region. Specific locus mutations can result from either point mutation or chromosome deletion. The results were as follows: (1) Both homokaryotic and heterokaryotic conidia had multi-hit survival curves, and there was no difference between the survival levels of the two as a function of treatment time. (2) The frequency of recessive lethal mutations in the ad-₃ region increased as the square of treatment time.     

Influence of edeine on intergenic and interallelic recombination in Neurospora crassa

Summary The effect of edeine and the mutation ed ^r-2 to edeine resistance on genetic recombination in Neurospora crassa was investigated. For this purpose crosses between pairs of edeine sensitive and edeine resistant strains respectively were set up without or in the presence of the drug (0–750 g/ml). The genetic markers ylo-1, ad-1, pan-2 (B ₃ and B ₅) and tryp-2, all on linkage group VI, were used for scoring recombinants. These were ad ⁺, tryp ⁺ (intergenic recombination) and pan ⁺ (interallelic recombination).Frequencies of about 6–7% for intergenic and of about 0.4% for interallelic recombination were found in crosses between ed^s strains and ed^r strains respectively, if edeine was absent. However, crosses in the presence of edeine gave higher frequencies of both intergenic and interallelic recombination (about 12% intergenic and 1% interallelic with 180 to 200 g ed/ml).The pan⁺ prototrophs (interallelic recombinants) obtained in the different crosses were tested for distribution of outside markers. The data thus obtained revealed, that under the effect of both the mutation to edeine resistance and edeine itself the relative number of non-crossover (gene conversion) recombinants decrease in favour of crossover recombinants, and the relative number of double crossover recombinants (events outside the pan locus) decreases in favour of single crossover recombinants.It is concluded that a) edeine and the mutation ed ^r-2 to edeine resistance affect recombination via related pathways, and b) noncrossover and crossover recombinants are caused by different molecular mechanisms, in agreement with the work of other authors.     

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 recombination survey using microsatellites: the O chromosome of <Emphasis Type="Italic">Drosophila subobscura</Emphasis>

Recombination plays an important role in species adaptation since it acts as an evolutionary force that can influence genome pattern organization. However, recombination can be detrimental in some situations, causing the breakdown of some adaptive gene combinations such as coadapted gene complexes. Genetic and cytological chromosome maps allow recombination throughout the genome to be analyzed. In this study we compare the recombination rate of two types of homokaryotypic lines of D. subobscura (O_ST and O ₃₊₄ ) using a set of at least 13 microsatellite loci. The genetic maps obtained present similar lengths: 184 and 196 cM for O_ST and O ₃₊₄ chromosomes, respectively. For most pairs of markers analyzed, a sample size of about 150 individuals appeared sufficient to obtain appropriate recombination values, with the exception of markers located in the same cytological band. Recombination rates seemed to be fairly uniform along the O chromosome, but some regional differences were observed. Several recombination hot and coldspots were detected, and their numbers were different in the homokaryotypic line types (O_ST and O ₃₊₄ ). This variability could be attributed to differences between the genetic content of the two arrangements or to differences between the lines.     

Construction of pBR322-ara hybrid plasmids by in vivo recombination

Summary In vivo recombination was used to clone deletions of the araBAD-araC genes of Escherichia coli onto a hybrid pBR322-ara plasmid. Genetic and physical analysis demonstrated that the desired deletions had been recombined onto the plasmid. In addition to permitting a detailed physical analysis of various ara deletions, this procedure has generated a series of plasmid cloning vehicles that can be used to clone, by in vivo recombination, any ara point mutation located within the region covered by the deletions. Hybrid plasmids containing the cloned point mutation can be distinguished from the original cloning vehicle by genetic complementation. The desired recombinant plasmid can be easily obtained because the frequency of recombination between the plasmid ara region and the chromosomal ara region is 0.025%–3%. A plasmid containing a deletion which removes the ara controlling site region and the araC gene was used to clone two types of araBAD promoter mutations and an araCmutation by in vivo recombination. Genetic and physical analysis of these plasmids established that the mutations in question had been recombined on to the ara deletion plasmid. The application of this procedure to the ara genes and to other genetic systems is discussed.     

Asymptotic behavior of a Moran model with mutations, drift and recombination among multiple loci

In this paper, we extend the theoretical treatment of the Moran model of genetic drift with recombination and mutation, which was previously introduced by us for the case of two loci, to the case of n loci. Recombination, when considered in the Wright–Fisher model, makes it considerably less tractable. In the works of Griffiths, Hudson and Kaplan and their colleagues important properties were established using the coalescent approach. Other more recent approaches form a body of work to which we would like to contribute. The specific framework used in our paper allows finding close-form relationships, which however are limited to a set of distributions, which jointly characterize allelic states at a number of loci at the same or different chromosome(s) but which do not jointly characterize allelic states at a single locus on two or more chromosomes. However, the system is sufficiently rich to allow computing, albeit in general numerically, all possible multipoint linkage disequilibria under recombination, mutation and drift. We explore the algorithms enabling construction of the transition probability matrices of the Markov chain describing the process. We find that asymptotically the effects of recombination become indistinguishable, at least as characterized by the set of distributions we consider, from the effects of mutation and drift. Mathematically, the results are based on the foundations of the theory of semigroups of operators. This approach allows generalization to any Markov-type mutation model. Based on these fundamental results, we explore the rates of convergence to the limit distribution, using Dobrushin’s coefficient and spectral gap.     

Untersuchungen zur Genetik eines Esterasepolymorphismus bei Saccharomyces cerevisiae

On the genetics of an esterase polymorphism of Saccharomyces cerevisiae. The inheritance of unspecific esterases of Saccharomyces cerevisae was investigated by tetrad analysis. It was shown that the four bands, found in the strains investibated, and distinguished by their electrophoretic mobility, are controlled by two loci with two alleles each. The loci E1 and E2 segregate independently whereas E2 is closely linked to the ad₂ locus. The E1 locus could not be mapped; however, there was evidence for free recombination with the contromere.     

Frequent recombination shapes the epidemic population structure of Planktothrix (Cyanoprokaryota) in Italian subalpine lakes

The planktonic genus Planktothrix, as other cyanobacteria, shows signals of both homologous and nonhomologous recombination. However, the frequency of recombination and its effect on Planktothrix population structuring is unknown. We isolated 290 Planktothrix strains from seven neighboring lakes in the subalpine Italian region and analyzed these using multilocus sequence typing. Four of six loci analyzed were polymorphic, resulting in 20 distinct multilocus genotypes. Association indices among alleles at different loci were suggestive of an “epidemic population structure,” resulting from an explosive (and temporary) dominance of one genotype against a panmictic background. ClonalFrame analyses supported this view by detecting: (i) three major clades affected by three distinct recombination events, (ii) a recombination rate about equal to the mutation rate, and (iii) the fact that recombination had an impact on introducing molecular diversity more than double the mutation rate. Furthermore, analysis of molecular variance over an annual cycle in three of seven lakes revealed that both local clonal expansion and recombination processes affected among‐lake diversity. Our observations suggest that recombination affects microevolution of Planktothrix and that an epidemic structure can emerge in populations of this genus.     

Effect of the mouse scid mutation on meiotic recombination

The goal of this study was to determine the effect of the mouse severe combined immunodeficiency (scid) mutation on the rate of meiotic recombination, by standard backcross linkage analysis. For this purpose, we examined four crosses that involved F₁ hybrid animals heterozygous for the strain C57BL/6 and BALB/c genomes. In one set of reciprocal crosses, F₁ animals were homozygous scid/scid, and in a second set of reciprocal crosses, F₁ mice were homozygous wild-type (+/+) at the scid locus. Backcross progeny were typed for recombination between selected genetic markers on mouse Chromosomes (Chrs) 1, 4, 6, 7, 9, 15, and 17. Although some differences in recombination were observed over some intervals, the expression of the SCID phenotype did not appear to have a major or consistent effect on meiotic recombination. Received: 4 October 1995 / Accepted: 2 April 1996     

The contribution of recombination to heterozygosity differs among plant evolutionary lineages and life-forms

Background  

Despite its role as a generator of haplotypic variation, little is known about how the rates of recombination evolve across taxa. Recombination is a very labile force, susceptible to evolutionary and life trait related processes, which have also been correlated with general levels of genetic diversity. For example, in plants, it has been shown that long-lived outcrossing taxa, such as trees, have higher heterozygosity (H _e) at SSRs and allozymes than selfing or annual species. However, some of these tree taxa have surprisingly low levels of nucleotide diversity at the DNA sequence level, which points to recombination as a potential generator of genetic diversity in these organisms. In this study, we examine how genome-wide and within-gene rates of recombination evolve across plant taxa, determine whether such rates are influenced by the life-form adopted by species, and evaluate if higher genome-wide rates of recombination translate into higher H _e values, especially in trees.     

Suppression of recombination in wide hybrids of Petunia hybrida as revealed by genetic mapping of marker transgenes

In the course of a heterologous transposon tagging experiment in Petunia hybrida (n=7), 135 independent T-DNA loci were tested for linkage to the target genes Hf1 and Fl, which are located on the two largest chromosomes. Approximately one-third (47) of these T-DNA loci were linked to one of these two markers. Of these 47 linkedloci, 19 mapped within 1 cM of its marker, indicating a highly non-random genetic distribution of introduced loci. However, rather than non-random integration within both of the marked chromosomes, this probably reflects a suppression of recombination around these marker loci in the particular wide hybrids used for mapping. This hypothesis was tested by measuring recombination between linked T-DNAs in an inbred background. Inbred recombination levels were found to be at least 3-fold higher around the Hf1 locus and 12-fold higher around Fl compared to the wide hybrids. These findings may reflect the origin of P. hybrida by hybridization of wild species, and while relevant to genetic mapping in petunia in particular they may also have more general significance for any mapping strategies involving the use of wide hybrids in other species.     

Footprints of intragenic recombination at HLA loci

 To evaluate the effect of balancing selection and intragenic recombination (or gene conversion) at six individual HLA loci, synonymous nucleotide diversity in different exon groups is examined within (π_w) and between (π_b) allelic lineages that may be defined by either serological or DNA sequence differences. Both π values are high in exons which encode for the peptide binding region (PBR) and tend to decrease in other exons. The value of π_w is significantly smaller than that of π_b in any exon of any locus. However, even π_w is much greater than nucleotide diversity at non-HLA loci. These observations provide additional strong evidence for the operation of balancing selection in PBR-encoding exons and its indirect effects on polymorphism at linked neighboring regions. It appears that allelic lineages have generally evolved in isolation but the linkage relationships within and between exons are incomplete throughout the long evolutionary history. To quantify intragenic recombination and account for the large discrepancy between the HLA and non-HLA diversity, a population genetics model is analyzed with special reference to the evolution of modern humans. The analysis suggests that the recombination rate between two sites 1000 base pairs apart is about 10^–5 per generation and that the effective size of human populations (equivalent roughly to the number of breeding individuals in a randomly mating population) has dropped from 10⁵ to 10⁴ in most of the Quaternary. One possibility for this reduction is discussed. Received: 11 August 1997 / Revised: 8 October 1997     

Allelspezifische suppressormutationen vonSchizosaccharomyces pombe

By comparing the intragenic distribution of suppressor sensitive mutants in fine structure maps, 13 allele specific suppressor mutations (isolated from revertants in adenine dependent mutants of constitutionad ₇) have been analyzed for their allele specific patterns of action in three different groups of mutants blocked in adenine biosynthesis. The 13 suppressor mutations, which have resulted from mutations at seven different suppressor loci, are characterized by four different suppression patterns. Three of these patterns, which partially overlap, are not locus specific since they include sensitive mutants at each of the three lociad ₇, ad₆ andad ₁ studied. The relative frequency of mutants sensitive to one or the other of the suppressors of this type, the absence of osmotic-remedial strains among the suppressor sensitive mutants, and the polarized complementation behaviour of one suppressiblead ₆ mutant and two suppressiblead ₁ mutants capable of interallelic complementation, suggest that the suppression mechanism involves misreading of a mutant triplet of the nonsense type.     

Recombination mapping of some chromosome 1A-, 1B-, 1D- and 6B-controlled gliadins and low-molecular-weight glutenin subunits in common wheat

 Inheritance of low-molecular-weight glutenin subunits (LMW GS) and gliadins was studied in the segregating progeny from several crosses between common wheat genotypes. The occurrence of a few recombinants in the F₂ grains of the cross Skorospelka Uluchshennaya×Kharkovskaya 6 could be accounted for by assuming that the short arm of chromosome 1D contains two tightly linked loci each coding for at least one gliadin plus one C-type LMW GS. These loci were found to recombine at a frequency of about 2%, and to be linked to the Glu-D3 locus coding for B-type LMW GS. Some proteins showing biochemical characteristics of D-type or C-type LMW GS were found to be encoded by the Gli-B1 and Gli-B2 loci, respectively. Strongly stained B-type LMW GS in cvs Skorospelka Uluchshennaya and Richelle were assigned to the Glu-B3 locus, but recombination between this locus and Gli-B1 was not found. Analogously, in the cross Bezostaya 1×Anda, no recombination was found between Gli-A1 and Glu-A3, suggesting the maximum genetic distance between these loci to be 0.97% (P=0.05). A B-type LMW GS in cv Kharkovskaya 6 was assigned to the Glu-B2 locus, with about 25% recombination from the Gli-B1 locus. The present results suggested that alleles at Gli loci may relate to dough quality and serve as genetic markers of certain LMW GS affecting breadmaking quality. Received: 9 July 1996/Accepted: 15 November 1996     

Super-suppressor induced interallelic complementation

Summary In yeast the dominant super-suppressorS ₅ has a distinct expression in heterozygotes depending on the particular combination of alleles at thead ₁ orad ₂ loci. If thead ₁ combination is represented by two suppressible alleles, the phenotype of diploid is wild. If thead ₁ combination consists of a suppressible and a non-suppressible allele the phenotype of the diploid is partially mutant. Such a difference in the manifestation of suppressor depending on the combination of alleles is more pronounced in the case ofad ₂ mutations. In the case when bothad ₂ alleles are suppressible, the diploid is prototrophic, but when only one allele is suppressible, the diploid is an adenineless auxotroph as a rule.This type ofS ₅-effect gave us the possibility to study interallelic complementation atad ₂ locus in presence of the super-suppressor. It was shown that some combinations of noncomplementing alleles do complement as a result of suppression.Comparison of the two complementation maps with and without suppressor is made for thead ₂ locus. The mechanisms of the phenomena and of super-suppression are discussed.     

Sexual recombination under the joint effects of mutation,selection, and random sampling drift

The advantage or disadvantage of sexual reproduction or recombination for the accumulation of mutant genes in a population is studied under the joint effects of recurrent mutations, selection, and random sampling drift. To obtain the rate at which mutant genes are incorporated three different methods are used; numerical integration of Kolmogorov backward equations, simulation of stochastic difference equations, and Monte Carlo experiments. The first two methods are used in a two-locus system to obtain the fixation probability of double mutants and other related quantities under five different selection models. The third one is conducted for a multiple-locus system and the rate of accumulation of mutant genes per locus is studied. Comparison of the results between sexual and asexual populations shows that the effect of recombination depends on initial linkage disequilibrium, mutation rate v, selection intensity s, and population size N_e. The mode of selection is also an important factor and the large effect of recombination is observed when mutant genes are individually deleterious but collectively favorable. Under a given model of selection, the great advantage or disadvantage of recombination is achieved when a large extent of genetic polymorphism is produced not by mutation but by recombination. Extreme values of N_es and N_ev make the effect insignificant. The results of Monte Carlo experiments also reveal the presence of interaction between selection and sampling drift even when the loci segregate independently and selection is multiplicative. Although this interaction is usually small, there are cases in which one locus theory cannot be used freely. In those cases, the effect of recombination is prominent and one locus theory gives an overestimate of the rate.