Evidence that nucleotide sequence identity is a requirement for meiotic crossing over within the mouse Eb recombinational hot spot

Meiotic recombination in the mouse is sometimes restricted to specific chromosomal sites. For example, when recombinants within the I region of the mouse major histocompatibility complex (MHC) are examined, the breakpoints between standard alleles can usually be mapped to the Eb gene. DNA sequence analysis of five cases of meiotic crossing over associated with this gene suggests that the recombinational hot spot may be confined to large regions of nucleotide identity located within the second intron of the Eb gene.     

Multiple sites of crossing over within the Eb recombinational hotspot in the mouse

The Eb gene of the mouse major histocompatibility complex (MHC) contains a well-documented hotspot of recombination. Twelve cases of intra-Eb recombination derived from the b, d, k and s alleles of the Eb gene were sequenced to more precisely position the sites of meiotic recombination. This analysis was based on positioning recombination breakpoints between nucleotide polymorphisms found in the sequences of parental haplotypes. All twelve cases of recombination mapped within the second intron of the Eb gene. Six of these recombinants, involving the k and s haplotypes, mapped to two adjoining DNA segments of 394 and 955 base pairs (bp) in the 3 half of the intron. In an additional two cases derived by crossing over between the d and s alleles, breakpoints were positioned to adjoining segments of 28 and 433 bp, also in the 3 half of the intron. Finally, four b versus k recombinants were mapped to non-contiguous segments of DNA covering 2.9 kb and 1005 bp of the intron. An analysis of the map positions of crossover breakpoints defined in this study suggests that the second intron of the Eb gene contains a recombinational hotspot of approximately 800–1000 bp which contains at least two closely linked recombinationally active sites or segments. Further examination of the sequence data also suggests that the postulated location for the recombinational hotspot corresponds almost precisely to an 812 bp sequence that shows nucleotide sequence similarity to the MT family of middle repetitive DNA.     

Structural and genetic properties of the Eb recombinational hotspot in the mouse

The Eb gene of the mouse contains a recombinational hotspot which plays a predominant role in meiotic crossing-over within the I region of the mouse major histocompatibility complex (MHC). The nucleotide sequences of five recombinants derived from H-2 ^k /H-2 ^b heterozygotes at the Eb locus placed the sites of recombination in each recombinant haplotype within a 2.9 kilobase (kb) segment located fully within the second intron of the Eb gene. Further resolution of the crossover sites was not possible since the nucleotide sequences of the parental and recombinant haplotypes are identical within this segment. The molecular characterization of these five recombinants considered in conjunction with three previously reported intra-Eb recombinants indicates that there are at least two distinct sites of recombination within the Eb recombinational hotspot. In a related study, an examination of the nucleotide sequence of the H-2 ^p allele of the Eb gene revealed a major genetic rearrangement in the 5' half of the intron in this haplotype. A 597 base pair (bp) nucleotide sequence found in the H-2 ^p haplotype is replaced by a 1634 bp segment found in the H-2 ^b and H-2 ^k haplotypes. Sequence analysis of this 1634 bp segment shows strong nucleotide sequence similarity to retroposon long terminal repeat (LTR), env, and pol genes indicating that this segment of the second intron has evolved through retroposon insertion. The location of these retroposon sequences within the 2.9 kb recombination segment defined by the five H-2 ^k /H-2 ^b recombinant haplotypes suggests a possible relationship between these retroviral elements and site-specific recombination within the second intron of the Eb gene. Offprint requests to: H. C. Passmore     

No dosage effect of recombinational hotspots in the mouse major histocompatibility complex

The sites of meiotic recombination in the proximal region of the mouse major histocompatibility complex (MHC) are clustered at hotspots. Some MHC haplotypes derived from Asian wild mice increase the frequency of recombination at such hotspots when heterozygous with standard laboratory haplotypes. The wm7 and cas3 haplotypes, have a hotspot close to the Lmp-2 gene (Lmp-2 hotspot), and the cas4 haplotype has a hotspot about 100 kilobase (kb) proximal, close to the Pb gene (Pb hotspot). To examine the effect of a double dose of hotspots, we estimated the rate of recombination and determined the location of the breakpoints in crosses of wm7/cas3 and wm7/cas4. In 3570 backcross progeny we identified 29 new recombinants in the H-2K to Ab interval, at a frequency of 0.81%. This frequency is 40-fold higher than in crosses between laboratory haplotypes and very similar to those previously obtained in crosses between these wild and standard laboratory haplotypes. Thus, a double dose of hotspots has no additive effect on the frequency of meiotic recombination. The site-specificity of recombination was also conserved. Twenty-three breakpoints were confined within 5.4 kb in the Lmp-2 hotspot, and six breakpoints from the cas4 cross were located in the Pb hotspot, which we have now confined to a 15 kb segment. Correspondence to: T. Shiroishi.     

Recombination in the class III region of the mouse major histocompatibility complex

The sites of meiotic recombination in the class II region of the mouse major histocompatibility complex (MHC) are clustered at hotspots. To search for hotspots in the class III region, we mapped combiantional break-points of 79 Ab: H2-D recombinants with 11 DNA markers; these included Tnx, the gene for an extracellular matrix protein, tenascin X, the Notch-related Int3 gene, and a microsatellite marker, D17Mit13, none of which had previously been mapped precisely. The results gave the gene order Eb-61.11-Int3-Tnx-Cyp21/C4-Bf-Hsp68c-D17Mit13-Tnfa/Tnfb-D. The crossover sites in 40 of the 79 recombinants were cofiend within the Eb/Int3:Tnx/Cyp21 interval. The result demonstrated that an unequal distribution of recombination is a general feature of the mouse MHC, suggesting the presence of a recombinational hotsopt within the Int3:Tnx interval.     

Evidence that nucleotide sequence identity is a requirement for meiotic crossing over within the mouse Eb recombinational hot spot.

Meiotic recombination in the mouse is sometimes restricted to specific chromosomal sites. For example, when recombinants within the I region of the mouse major histocompatibility complex (MHC) are examined, the breakpoints between standard alleles can usually be mapped to the Eb gene. DNA sequence analysis of five cases of meiotic crossing over associated with this gene suggests that the recombinational hot spot may be confined to large regions of nucleotide identity located within the second intron of the Eb gene.     

Molecular analysis of a recombinational hotspot adjacent to Lmp2 gene in the mouse MHC: Fine location and chromatin structure

Meiotic recombinations in the proximal region of the mouse major histocompatibility complex (MHC) are clustered within certain segments of chromosome, known as hotspots. In this study, we found that one of such hotspots, previously mapped between the Pb and Ob genes, is located very close to the 3′ end of the Lmp2 gene, which encodes a subunit of a proteolytic proteasome. To analyze the molecular basis of the site specificity of hotspots, we examined the structure of the chromatin around this Lmp2 hotspot and another one located in the MHC class II Eb gene, by monitoring DNase I-hypersensitive sites (DHSSs) of the chromatin. DHSSs were detected at the both hotspots in the somatic cells. In the meiotic cells, DHSS was detected within the Eb hotspot, as previously reported, but not in the Lmp2 hotspot. Thus, open structure of chromatin during meiosis, as monitored by hypersensitivity to DNase I, is not a general feature of mouse recombinational hotspots, contrasting the case of the lower eukaryote, S. cerevisiae, in which hotspots are always associated with DHSSs. Received: 25 January 1996 / Accepted: 21 March 1996     

Genetic structure and contrasting selection pattern at two major histocompatibility complex genes in wild house mouse populations

The mammalian major histocompatibility complex (MHC) is a tightly linked cluster of immune genes, and is often thought of as inherited as a unit. This has led to the hope that studying a single MHC gene will reveal patterns of evolution representative of the MHC as a whole. In this study we analyse a 1000-km transect of MHC variation traversing the European house mouse hybrid zone to compare signals of selection and patterns of diversification at two closely linked MHC class II genes, H-2Aa and H-2Eb. We show that although they are 0.01 cM apart (that is, recombination is expected only once in 10 000 meioses), disparate evolutionary patterns were detected. H-2Aa shows higher allelic polymorphism, faster allelic turnover due to higher mutation rates, stronger positive selection at antigen-binding sites and higher population structuring than H-2Eb. H-2Eb alleles are maintained in the gene pool for longer, including over separation of the subspecies, some H-2Eb alleles are positively and others negatively selected and some of the alleles are not expressed. We conclude that studies on MHC genes in wild-living vertebrates can give substantially different results depending on the MHC gene examined and that the level of polymorphism in a related species is a poor criterion for gene choice.     

TrackingH-2 alleles in transgenic mice by RFLP and heteroduplex analysis

Transgenic mice provide valuable tools for biological research including many areas of immunology. In studies involving the major histocompatibility complex (MHC), it is often necessary to place the desired transgene in a specificH-2 (the murine MHC) environment. In this regard, the strains commonly used for the production of transgenic mice also carry well characterizedH-2 alleles and provide an appropriate genetic background for MHC related experiments. In this study, a highly polymorphic microsatellite of tetranucleotide repeats from the second intron of the class IIEb gene within theH-2 complex was used in order to identify the corresponding alleles. The relevantH-2 allele(s) along with the transgene were then tracked throughout the production of a chicken ovalbumin-specific transgenic strain. The technique involved PCR-amplification of a DNA sequence encompassing theH-2 specific microsatellite followed by RFLP and heteroduplex analyses. This approach is likely to find wide application in the background checking of trangenic mice, especially in immunological research requiring a definedH-2 background.     

High-resolution mapping and recombination interval analysis of mouse Chromosome 17

Analysis of homologous recombination in eukaryotes has shown that some meiotic crossing-over occurs preferentially at specific genomic sites of limited physical distance called recombinational hotspots. In the mouse, recombinational hotspots have only been defined in the major histocompatibility complex (MHC) on chromosome (Chr) 17. In an attempt to examine whether hotspots are unique to the MHC or are present throughout the genome, high-resolution linkage maps of Chr 17 based on five backcrosses involving different inbred strains have been generated. These maps separate many markers that were previously shown at the same map position and allow a detailed analysis of recombination patterns across Chr 17. Corresponding recombination intervals in these maps have been compared for the identification of intervals with very little or no recombination in certain genetic crosses and considerable recombination in other genetic crosses. This approach has been termed Recombination Interval Analysis. Possible haplotype-dependent non-MHC hotspots, as well as previously identified MHC hotspots, have been detected by interval analysis. Received: 1 December 1997/ Accepted: 27 February 1998     

Evolution of introns and exons of class II major histocompatibility complex genes of vertebrates

 The phylogenetic relationships and patterns of nucleotide substitution were compared for introns and exons of class II major histocompatibility complex (MHC) genes in three datasets: human DRB1, human DQA1, and cyprinid fish DAB1. In both human DRB1 and cyprinid DAB1, there was strong evidence that recombination events between alleles have occurred in such a way that intron and exon sequences of a given allele do not necessarily share the same evolutionary history. In the case of human DRB1, recombination was found to have homogenized intron 1 and intron 2 sequences relative to exon 2 sequences within lineages of alleles but not between lineages. As a result, mean divergence times of intron sequences are much more recent than those of exonic sequences. Thus, the divergence time of DRB1 introns cannot be used to date that of exons in the same alleles, and the hypothesis that most human DRB1 polymorphism is of very recent origin is not supported. Received: 5 September 1999 / Revised: 30 December 1999     

Prdm9 Polymorphism Unveils Mouse Evolutionary Tracks

PR/SET domain containing 9 (Prdm9) mediates histone modifications such as H3K4me3 and marks hotspots of meiotic recombination. In many mammalian species, the Prdm9 gene is highly polymorphic. Prdm9 polymorphism is assumed to play two critical roles in evolution: to diversify the spectrum of meiotic recombination hotspots and to cause male hybrid sterility, leading to reproductive isolation and speciation. Nevertheless, information about Prdm9 sequences in natural populations is very limited. In this study, we conducted a comprehensive population survey on Prdm9 polymorphism in the house mouse, Mus musculus. Overall M. musculus Prdm9 displays an extraordinarily high level of polymorphism, particularly in regions encoding zinc finger repeats, which recognize recombination hotspots. Prdm9 alleles specific to various M. musculus subspecies dominate in subspecies territories. Moreover, introgression into other subspecies territories was found for highly divergent Prdm9 alleles associated with t-haplotype. The results of our phylogeographical analysis suggest that the requirement for hotspot diversity depends on geographical range and time span in mouse evolution, and that Prdm9 polymorphism has not been maintained by a simple balanced selection in the population of each subspecies.     

Genetic control of sex-dependent meiotic recombination in the major histocompatibility complex of the mouse.

Meiotic recombination within the proximal region of the major histocompatibility complex (MHC) of the mouse is not random but occurs in clusters at certain restricted sites, so-called recombinational hotspots. The wm7 haplotype of the MHC, derived from the wild mouse, enhances recombination specifically during female meiosis within a fragment of 1.3 kb of DNA located between the A beta 3 and A beta 2 genes in genetic crosses with laboratory haplotypes. Previous studies revealed no significant strain differences in nucleotide sequences around the hotspot, irrespective of the ability of the strain to enhance the recombination. It appeared that a distant genetic element might, therefore, control the rate of recombination. In the present study, original recombinants whose breakpoints were defined by direct sequencing of PCR-amplified DNAs were tested for the rate of secondary recombination in the crosses with laboratory strains in order to determine the location of such a genetic element. The results clearly demonstrated that the chromosomal segment proximal to the hotspot is essential for enhancement of recombination. Moreover, the male recombination is suppressed by a segment distal to the hotspot.     

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     

Inter- and Intralocus Recombination Drive MHC Class IIB Gene Diversification in a Teleost, the Three-Spined Stickleback Gasterosteus aculeatus

The mutational mechanism underlying the striking diversity in MHC (major histocompatibility complex) genes in vertebrates is still controversial. In order to evaluate the role of inter- and intragenic recombination in MHC gene diversification, we examined patterns of nucleotide polymorphism across an exon/intron boundary in a sample of 31 MHC class IIB sequences of three-spined stickleback (Gasterosteus aculeatus). MHC class IIB genes of G. aculeatus were previously shown to be under diversifying (positive) selection in mate choice and pathogen selection experiments. Based on recoding of alignment gaps, complete intron 2 sequences were grouped into three clusters using maximum-parsimony analysis. Two of these groups had >90% bootstrap support and were tentatively assigned single locus status. Intron nucleotide diversity within and among loci was low (p-distance within and among groups = 0.016 and 0.019, respectively) and fourfold lower than the rate of silent mutations in exon 2, suggesting that noncoding regions are homogenized by frequent interlocus recombination. A substitution analysis using GENECONV revealed as many intergenic conversion events as intragenic ones. Recombination between loci may explain the occurrence of sequence variants that are particularly divergent, as is the case in three-spined stickleback, with nucleotide diversity attaining d_N = 0.39 (peptide-binding residues only). For both MHC class II loci we also estimated the amount of intragenic recombination as population rate (4N_er) under the coalescent and found it to be approximately three times higher compared to point mutations (Watterson estimate per gene, 4N_eμ). Nonindependence of molecular evolution across loci and frequent recombination suggest that MHC class II genes of bony fish may follow different evolutionary dynamics than those of mammals. Our finding of widespread recombination suggests that phylogenies of MHC genes should not be based on coding segments but rather on noncoding introns. [Reviewing Editor: Dr. Richard Kliman]     

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.     

Both conserved and non-conserved regions of Spo11 are essential for meiotic recombination initiation in yeast

DNA double-strand breaks (DSBs) are the initiators of most meiotic recombination events. In Saccharomyces cerevisiae, at least ten genes are necessary for meiotic DSB formation. However, the molecular roles of these proteins are not clearly understood. The meiosis-specific Spo11 protein, which shows sequence similarity with a subunit of an archaeal topoisomerase, is believed to catalyze the meiotic DSB formation. Spo11 is also required for induction of meiotic DSBs at long inverted repeats and at large trinucleotide repeat tracts. Here we report the isolation and characterization of temperature-sensitive spo11-mutant alleles to better understand how Spo11 functions, and how meiotic DSBs are generated at various recombination hotspots. Analysis of mutation sites of isolated spo11-mutant alleles indicated that both N-terminal and C-terminal non-conserved residues of Spo11 are essential for the protein’s function, possibly for interaction with other meiotic DSB enzymes. Several of the mutation sites within the conserved region are predicted to lie on the surface of the protein, suggesting that this region is required for activation of the meiotic initiation complex via protein-protein interaction. In addition to the conditional mutants, we isolated partially recombination-defective mutants; analysis of one of these mutants indicated that Ski8, as observed previously, interacts with Spo11 via the latter’s C-terminal residues.     

The detection of post-meiotic segregation without tetrad analysis in Ustilago maydis

Summary Post-meiotic segregation (PMS) results in the formation of mixed genotypes from single meiotic products. A method is described in which single members of tetrads are selected, and these are then tested for their genetic homogeneity. The method is applied to Ustilago maydis using crosses which are heteroallelic for nar 1, the structural gene for nitrate reductase. In the absence of PMS, meiotic products containing a nar ⁺ recombinant are genetically pure (the equivalent of a 6 mutant: 2 wild-type octad). With PMS, a nar ⁺ recombinant clone arises in association with a nar ^- clone and these are otherwise genetically identical (the equivalent of a 7 mutant: 1 wild type octad). The procedure will make it possible to search for mutant strains which are defective in the correction of mismatched bases in hybrid DNA formed during recombination. Among 26 nar ⁺ recombinants from a control cross, PMS was detected on 3 occasions. In an equivalent cross, both parents were uvs 3, a mutant defective in the excision of pyrimidine dimers from DNA. Among 43 nar ⁺ recombinants, 7 arose from PMS. Thus the frequency of PMS for the nar alleles is about 15% and the excision of pyrimidine dimers is probably unrelated to the repair of mismatched bases in hybrid DNA.     

Major histocompatibility complex class IIB allele polymorphism and its association with resistance/susceptibility to Vibrio anguillarum in Japanese flounder (Paralichthys olivaceus)

The full length of major histocompatibility complex (MHC) class IIB cDNA was cloned from a Chinese population of Paralichthys olivaceus by homology cloning and rapid amplification of cDNA ends-polymerase chain reaction (RACE-PCR). The MHC IIB genomic sequence is 1,864 bp long and consists of 34-bp 5′UTR, 741-bp open reading frame, 407-bp 3′UTR, 96-bp intron1, 392-bp intron2, 85-bp intron3, and 109-bp intron4. Phylogenetic analysis showed that the putative MHC class IIB amino acid of the Chinese P. olivaceus shared 28.3% to 85.4% identity with that of the reported MHC class IIB in other species. A significant association between MHC IIB polymorphism and disease resistance/susceptibility was found in Chinese P. olivaceus. Thirteen different MHC IIB alleles were identified among 411 clones from 84 individuals. Among the 280 (268) nucleotides, 32 (11.4%) nucleotide positions were variable. Most alleles such as alleles a, b, c, d, e, f, j, k, i, m were commonly found in both resistant and susceptible stock. Via χ² test, allele d was significantly more prevalent in individuals from susceptible stock than from resistant stock, and their percentages were 23.80% and 7.14%, respectively. In addition, allele g occurred in 9 and allele h in 4 of 42 resistant individuals that were not present in the susceptible stock; their percentages were 21.4% and 9.52%, respectively. Although allele l was found only in 8 individuals from the susceptible stock, its percentage is 19.05%.