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.     

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.     

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.     

A search for allelic recombination in Chinese hamster cell hybrids

Summary Mutants resistant to 6-thioguanine were selected from CHO cells which were either temperature sensitive or proline requiring. These mutants were stable and had low levels of hypoxanthine guanine phosphoribosyl transferase (HGPRT). Hybrids were selected which were heteroallelic at the hgprt locus and complementation between the mutants used was not observed. Interallelic recombination at this locus would generate hgprt ⁺ cells which could be selected in Littlefield's HAT medium. Selection experiments with hybrids containing three different pairs of mutants yielded no recombinants among populations of 4x10⁶-2x10⁷ cells. After treatment with the recombinagen mitomycin C, 3 putative recombinants were detected amongst 1.4x10⁷ surviving cells from one hybrid. One of these strains was examined and shown to have a normal level of HGPRT and its heterozygosity at this locus was demonstrated by the segregation of colonies resistant to 6-thioguanine. It cannot be excluded that the rare hgprt ⁺ colonies seen arose by mutation rather than by recombination. Mitotic allelic recombination therefore appears to be a much less frequent event in CHO cells than it is in lower eukaryotes. It is possible that mitotic recombination is effectively suppressed in mammalian cells to prevent the expression of deleterious recessive mutants.     

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.     

Time of Recombination in the DROSOPHILA MELANOGASTER Oocyte. III. Selection and Characterization of Temperature-Sensitive and -Insensitive, Recombination-Deficient Alleles in Drosophila

The procedure for the selection of a temperature-sensitive recombination mutant in Drosophila is described. Use of this procedure has led to the recovery of three alleles at a new recombination locus called rec-1, located within the region of chromosome 3 circumscribed by Deficiency (3R)sbd¹⁰⁵. One allele, rec-1²⁶, is temperature sensitive, and the other two alleles, rec-1⁶ and rec-1¹⁶, are temperature insensitive. Gene dosage studies reveal rec-1²⁶ to be a leaky mutant with greater recombination activity in two doses than in one. The other two alleles show no dose response, implying that they may be null mutants. The temperature response curves of rec-1²⁶ as a homozygote and in heteroallelic combination with rec-1¹⁶ suggest that the sharp decrease in recombination between 28° and 31° indicates temperature denaturation of an enzyme or other protein specified by the mutant and associated with the recombination process. The ability of small changes in temperature to reverse or abolish polarity in recombination along the X chromosome arm in rec-1 ²⁶/rec-1¹⁶ females brings into question the use of the "polarity" criterion to partition mutants into two functional types, i.e., precondition mutants that display polarity and exchange mutants that do not. Evidence that rec-1 may be part of a complex locus residing in a chromosome segment harboring a variety of recombination-related genes is presented.     

Identification and physical characterization of yeast glucoamylase structural genes

Summary Each one of at least three unlinked STA loci (STA1, STA2 and STA3), in the genome of Saccharomyces diastaticus controls starch hydrolysis by coding for an extracellular glucoamylase. Cloned STA2 sequences were used as hybridization probes to investigate the physical structure of the family of STA genes in the genomes of different Saccharomyces strains. Sta⁺ strains, each carrying a single genetically defined STA locus, were crossed with a Sta^– strain and the segregation behavior of the functional locus (i.e. Sta⁺) and sequences homologous to a cloned STA2 glucoamylase structural gene at that locus were analyzed. The results indicate that in all strains examined there is a multiplicity of sequences that are homologous to STA2 DNA but that only the functional STA loci contain extensive 5 and 3 homology to each other and can be identified as residing on unique fragments of DNA; that all laboratory yeast strains examined contain extensive regions of the glucoamylase gene sequences at or closely linked to the STA1 chromosomal position; that the STA1 locus contains two distinct glucoamylase gene sequences that are closely linked to each other; and that all laboratory strains examined also contain another ubiquitous sequence that is not allelic to STA1 and is nonfunctional (Sta^–), but has retained extensive sequence homology to the 5 end of the cloned STA2 gene. It was also determined that the DEX genes (which control dextrin hydrolysis in S. diastaticus), MAL5 (a gene once thought to control maltose metabolism in yeast) and the STA genes are allelic to each other in the following manner: STA1 and DEX2, STA1 and MAL5, and STA2 and DEX1 and STA3 and DEX3.     

Extreme nuclear disproportion and constancy of enzyme activity in a heterokaryon ofNeurospora crassa

Heterokaryons ofNeurospora crassa were generated by transformation of multinucleate conidia of ahistidine-3 auxotroph withhis-3 ⁺ plasmid. In one of the transformants, propagated on a medium with histidine supplementation, a gradual but drastic reduction occurred in the proportion of prototrophic nuclei that contained an ectopically integratedhis-3 ⁺ allele. This response was specific to histidine. The reduction in prototrophic nuclei was confirmed by several criteria: inoculum size test, hyphal tip analysis, genomic Southern analysis, and by visual change in colour of the transformant incorporating genetic colour markers. Construction and analyses of three-component heterokaryons revealed that the change in nuclear ratio resulted from interaction of auxotrophic nucleus with prototrophic nucleus that contained an ectopically integratedhis-3 ⁺ gene, but not with prototrophic nucleus that containedhis-3 ⁺ gene at the normal chromosomal location. The growth rate of heterokaryons and the activity of histidinol dehydrogenase—the protein encoded by thehis-3 ⁺ gene-remained unchanged despite prototrophic nuclei becoming very scarce. The results suggest that not all nuclei in the coenocytic fungal mycelium may be active simultaneously, the rare active nuclei being sufficient to confer the wild-type phenotype.     

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.     

Biogenesis of mitochondria 49 identification and mapping of a new mitochondrial locus (tsr1) which maps within polar region of yeast mitochondrial genome.

Summary An enrichment procedure which facilitates the isolation of conditional respiratory-deficient mutants of Saccharomyces cerevisiae is reported. Detailed genetic analysis of one mutant which exhibits a respiratory deficient phenotype at low temperature (18°C) is also presented. The phenotype is due to a single lesion at a new locus, tsr1, located on the mitochondrial DNA. By analysis of locus retention patterns in a set of physically characterized petite strains, the tsr1 mutation has been mapped within the segment 0–5 map units on the physical map of the yeast mitochondrial genome. This segment of the mitochondrial DNA also contains the cap1 and ery1 loci and the cistron for the mitochondrial 21S rRNA. Studies of the frequencies of co-retention of markers in petite populations, and of the frequencies of recombination of markers in non-polar crosses (⁺ × ⁺), demonstrate linkage of the tsr1 locus to both the cap1 and ery1 loci. The degree of linkage indicates that tsr1 is closer to the ery1 locus. Comparison of pairwise recombination frequencies for these three markers indicate the order cap1-tsr1-ery1. The tsr1 locus lies within the segment of the mitochondrial genome which is influenced by the polarity locus , and analysis of transmission and recombination frequencies and polarities in a polar (⁺ × ^-) cross show that the behaviour of the tsr1 locus is similar to that of ery1. However striking features of this cross are that the recombination frequency between tsr1 and ery1 is comparable to that observed in non-polar crosses, and that the polarity for recombination between tsr1 and cap1 or ery1 is extremely low.     

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.     

Gene Conversion and Intragenic Recombination at at the SUP6 Locus and the Surrounding Region in SACCHAROMYCES CEREVISIAE

Spontaneous secondary mutations of the ochre suppressor SUP6 were selected in a haploid strain of Saccharomyces cerevisiae . Unselected tetrads were dissected from crosses heterozygous for one of three alleles of SUP6 and for three other loci in this region which span a length of 14 map units (his2, cdc14 and met10). The study showed that all of these markers were characterized by high frequency of meiotic gene conversion and long conversion lengths which frequently extended into adjacent marked loci. Despite the high conversion frequency of SUP6 , recombination between alleles of this locus reached a maximum frequency of only 2 x 10^-3 prototrophs/spore. Although the allelic recombination frequencies were not distance dependent and consequently could not be used to order the alleles, the inequality between the two recombinant outside marker combinations among selected intragenic recombinants produced an internally consistent map of the suppressor locus. Recombination at SUP6 (whether detected as conversion in tetrads or the production of recombinants among random spores) was accompanied by significantly less than 50% outside marker recombination.     

Identification and physical characterization of yeast maltase structural genes

Summary Each of at least five unlinked MAL loci (MAL1 through MAL4 and MAL6) on the yeast genome controls the ability to synthesize an inducible -D-glucosidase (maltase). A subcloned fragment of the coding sequence of the MAL6 maltase structural gene was used as a hybridization probe to investigate the physical structure of the family of MAL structural genes in the genomes of different Saccharomyces strains. Mal⁺ strains, each carrying a genetically defined MAL locus, were crossed with a Mal^- strain and the segregation behavior of the functional locus and of sequences complementary to the maltase structural gene at that locus analyzed. The maltase structural gene sequences of each MAL locus were detected by Southern blot hybridization using BamH1 digests of genomic DNA of the meiotic products. This restriction enzyme was previously shown to cleave outside the confines of the MAL6 locus.The results of such experiments indicate that each MAL locus encompasses at least one maltase structural gene sequence homologous to that of MAL6, that yeast strains that lack functional MAL loci may or may not contain the corresponding maltase structural gene sequence, that the MAL1 maltase structural gene sequence or one of its alleles can be detected in all laboratory yeast strains examined and that each MAL locus can be identified as a characteristic BamH1 fragment of genomic DNA which includes a maltase structural gene.Yeast strains vary in the number of maltase structural gene sequences that they carry. By using the approach described in this report, the ones corresponding to the different functional MAL loci and residing within a BamH1 generated restriction fragment can be identified.     

Mhc-DRB diversity of the chimpanzee (Pan troglodytes)

Fifty-four chimpanzee Patr-DRB and five human HLA-DRB second exons were cloned and sequenced from thirty-five chimpanzees and four B-cell lines and compared with known Mhc-DRB sequences of these two species. Equivalents of the HLA-DRB1 ^* 02,-DRB1 ^* 03, -DRB1 ^* 07 allelic lineages and the HLA-DRB3,-DRB4, -DRB5, -DRB6, and -DRB7 loci were all found in the chimpanzee. In addition, two chimpanzee Patr-DRB lineages (Patr-DRBX and -DRBY) were found for which no human counterparts have been described. None of the Patr-DRB sequences is identical to known HLA-DRB sequences. The Patr-DRB1 ^* 0702 and HLA-DRB1 ^* 0701 alleles are the most similar sequences in a comparison between the two species and differ by only two nucleotides out of 246 sequences. Equivalents of the HLA-DRB1 ^* 01,-DRB1 ^* 04, and -DRB1 ^* 09 alleles were not found in our sample of chimpanzees. A per locus comparison of the number of Patr-DRB alleles with the HLA-DRB alleles shows that the Patr-DRB3, -DRB4, -DRB5, and -DRB6 locus are, thus far, more polymorphic than ther human homologs. The polymorphism of the Patr-DRB1 locus seems to be less extensive than that reported for the HLA-DRB1 locus. Nevertheless, the Patr-DRB1 locus seems to be the most polymorphic of the Patr-DRB loci. Phylogenetic analyses indicate that the HLA-DRB1 ^* 09 allele may have originated from a recombination between a Mhc-DRB5 allele and the DRB1 allele of a Mhc-DR7 haplotype. Although recombination seems to increase the diversity of the Patr-DRB alleles, its contribution to the generation of Patr-DRB variation is probably low. Hence, most Patr-DRB diversity presumably accumulated via recurrent point mutations. Finally, two distinct PAtr-DRB haplotypes are deduced, one of which (the chimpanzee equivalent of the HLA-Dr7 haplotype) is probably older than 6–8 million years.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide database and have been assigned the accession numbers Mg6074-Mg6132. Correspondence to: M. Kenter.     

A Search for Genetic Loci Responsible for Stress-Induced Arterial Hypertension in the ISIAH Rats

Hypertension is a widespread human disease caused by a complex interaction of a series of the genetic factors with both each other and the environmental conditions. In this study we aimed at determining the candidate genetic loci responsible for hypertension in the ISIAH rats and studying the dynamics of the relevant genetic and physiological mechanisms in rat ontogeny. The candidate genetic loci were identified from association of the microsatellite markers linked to these loci with arterial hypertension in rat F₂ hybrids exposed to stress. Two populations of F₂ hybrids of different age (3–4 and 6 months) were obtained by crossing hypertensive ISIAH and normotensive WAG rats. We present the results of cosegregation analysis for the following loci: the gene for the Na⁺, K⁺-ATPase alpha 1 subunit (Atp1a1), the endothelin-2 gene (Edn2), the low affinity nerve growth factor receptor gene (Lngfr), and a region of chromosome 10 marked with the D10Rat58 microsatellile located 3 cM away of the aldolase C gene (AldC). The results obtained allowed us to localize the genes responsible for the stress-induced arterial hypertension in the ISIAH rats to the Atp1a1locus (P < 0.05), chromosome 2 and to the Lngfr gene locus (P < 0.05), chromosome 10. The association of hypertensive status with the Lngfr gene was found only in young ISIAH rats whereas in adult rats of this strain, hypertension was associated with the Atp1a1locus.     

On the formation of rho? petites in yeast

Summary The inheritance of an extrakaryotic mutation conferring temperature-sensitive growth on nonfermentable substrates and a high frequency of mutation to rho^– has been studied. Multifactorial crosses (rho⁺xrho⁺) involving this mutation T ₈ ^S and mitochondrial mutations conferring resistance to chloramphenicol, erythromycin, oligomycin or paromomycin revealed: a) Mutation T ₈ ^S is localized on the mitDNA, referring to a new gene locus TSM1. b) Locus TSM1 appears to be weakly linked to the locus PAR1 and to the loci RIB1 and RIB3 but unlinked to the locus OLI1. c) The position of TSM1 is between PAR1 and the two closely linked loci RIB1 and RIB3, OLI1 is outside and not linked to the segment PAR-TSM-RIB. d) Mutation T ₈ ^S does not significantly influence the process of mitochondrial recombination and its control by the mitochondrial locus .     

Evolutionary relationship ofHLA-DRB genes inferred from intron sequences

The major histocompatibility complex (Mhc) consists of class I and class II genes. In the humanMhc (HLA) class II genes, nineDRB loci have been identified. To elucidate the origin of these duplicated loci and allelic divergences at the most polymorphicDRBI locus, introns 4 and 5 as well as the 3′ untranslated region (altogether approximately 1,000 base pairs) of sevenHLA-DRB loci, threeHLA-DRBI alleles, and nine nonhuman primateDRB genes were examined. It is shown that there were two major diversification events inHLA-DRB genes, each involving gene duplications and allelic divergences. Approximately 50 million years (my) ago,DRBI ^*04 and an ancestor of theDRB1 ^*03 cluster (DRBI ^*03, DRBI^*15, andDRB3) diverged from each other andDRB5, DRB7, DRB8, and an ancestor of theDRB2 cluster (DRB2, DRB4, andDRB6) arose by gene duplication. Later, about 25 my ago,DRBI ^*15 diverged fromDRBI*03, andDRB3 was duplicated fromDRBI ^*03. Then, some 20 my ago, the lineage leading to theDRB2 cluster produced two new loci,DRB4 andDRB6. TheDRBI ^*03 andDRBI ^*04 allelic lineages are extraordinarily old and have persisted longer than some duplicated genes. The orthologous relationships ofDRB genes between human and Old World monkeys are apparent, but those between Catarrhini and New World monkeys are equivocal because of a rather rapid expansion and contraction of primateDRB genes by duplication and deletion. Correspondence to: Y. Satta     

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     

Genetic determination of ubiquinol-cytochromec reductase

Summary In order to find new genetic loci on the yeast mitochondrial DNA, especially mutations affecting the structure and function of ubiquinol-cytochrome c reductase, 45 independently arisen mutants resistant to mucidin have been isolated after MnCl₂ mutagenesis. The majority of the mutants exhibited increased sensitivity to chloramphenicol, diuron and antimycin A, respectively. it was shown by several criteria that all mutants resulted from mutations localized on the mitochondrial DNA.The allelism tests revealed that these mutations fall into three distinct loci muc1, muc2 and muc3. Mutations at a new locus muc3 were correlated with the changes in the binding or inhibitory sites on the inner mitochondrial membrane. Multifactorial crosses involving the mucidin resistance mutations and mitochondrial mutations conferring resistance to chloramphenicol, erythromycin, oligomycin and diuron revealed that the studied mutations at the loci muc1, muc2 and muc3 did not significantly influence the process of mitochondrial recombination and its control by the mitochondrial locus . The locus muc1 was found to be allelic to the locus diu2. The locus muc2 which was found to be allelic to cob1 locus appears to be linked to the locus oli1 but unlinked to the loci , cap1, ery1 and muc1. The new locus muc3 appears to be weakly linked to the locus diu1 but unlinked to the loci , cap1, ery1, oli1 and muc1.The results are consistent with the gene order oli1-muc2-muc3-diu1-muc1-oli2 and suggest the participation of at least three mucidin resistance loci and one diuron resistance locus in the biogenesis of the bc ₁ complex of the mitochondrial respiratory chain.