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     

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.     

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     

Recruitment of multiple alleles within the Eb recombinational hotspot in murine MHC

Genetic recombination has been proposed to have played a major role in generating the extensive polymorphism that distinguishes the genes of the major histocompatibility complex (MHC). The proximal region of the murine H-2 represents a unique segment of DNA encompassing at least four hotspots for meiotic recombination. One of these hotspots lies within the second intron of the class II Eb gene and has been defined at the nucleotide level for a number of simple two-allele crosses. In this report we studied two crosses in which one or both parents in themselves were H2Eb recombinants and three alleles were present within the hotspots of each pair of the parental haplotypes. Nucleotide analysis indicated that the break points in these secondary recombinants, like those in the primary recombinants, were also discrete and clustered within the H2Eb second intron. Thus, in one instance two and in the other instance three alleles were present within the hotspots of these recombinants. These observations strongly suggest that meiotic recombination could be an important mechanism contributing to MHC polymorphism.     

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.     

Polymorphism of the MHC class II Eb gene determines the protection against collagen-induced arthritis

Collagen-induced arthritis (CIA) is an animal model of auto immune polyarthritis, sharing similarities with rheumatoid arthritis (RA). Paradoxally, susceptibility to mouse CIA is controlled by the H2A loci (DQ homologous) while RA is linked to HLA.DR genes (H2E homologous). We recently showed that the E^d molecule prevents CIA development in susceptible H2 ^q mice. We addressed the question of whether H2Eb polymorphism will influence CIA incidence as HLA.DRB1 polymorphism does in RA. In F₁ mice, only H2Eb^d and H2Eb^s molecules showed protection. Using recombinant B10.RDD (Eb ^d/b) mice, we found that CIA protection was mediated by the first domain of the E^d molecule. Using peptides covering the third hypervariable region of the E chain, we found a perfect correlation between presentation of E peptides by the H2A^q molecule and protection on CIA. Therefore, the mechanism by which H2Eb protects against CIA seems to rely on the affinity of E peptides for the H2A_q molecule.     

Intrachromosomal gene conversion frequency in the H2 differs between haplotypes

 We examined two intrachromosomal gene conversion events with a polymerase chain reaction assay at the DNA level between the two major histocompatibility complex class II genes Eb and Ab in mice sperm before selection has occurred. The frequency of the intrachromosomal gene conversion event between Ebd and Abd was found to be at least one order of magnitude higher than between Ebk and Abk in the same mice. Parental imprinting of the genes appears not to have an effect on gene conversion, as both (d×k)F₁ and (k×d)F₁ mice have indistinguishable frequencies in both haplotypes. The number of DNA copies of the donor and acceptor genes present in the cell at the time of mutation does not seem to influence the frequency of the intrachromosomal gene conversion in the k haplotype, whereas the frequency in the d haplotype is increased when double the number of donor and acceptor genes is present. The DNA fragment transferred between Ebd and Abd is invariably short, and need not comprise more than six nucleotides. The fragment transferred within the k haplotype varies in length, and can attain at least 100 nucleotides. The difference between the haplotypes both in length and frequency might be attributed to a six-nucleotide deletion in the Abk gene, which might make base-pairing between the genes less efficient and less precise. Received: 24 October 1997 / Revised: 5 January 1998     

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.     

Identification of a broad-spectrum recessive gene in Brassica rapa and molecular analysis of the eIF4E gene family to develop molecular markers

Two Chinese cabbage (Brassica rapa L. ssp. pekinensis) lines resistant to Turnip mosaic virus (TuMV) CHN5 were identified and found to have broad-spectrum resistance against three other TuMV strains (CHN2, 3, and 4). Genetic analysis indicated that this TuMV resistance is recessive, and a candidate gene approach was used to identify the resistance gene, which we named trs (TuMV resistance discovered at Seoul National University). Based on previous research in Arabidopsis showing that mutations in eIF(iso)4E determine TuMV resistance, the eIF(iso)4E gene was selected as a candidate for the trs gene in Brassica rapa. Three copies of eIF(iso)4E, Braiso4Ea, Braiso4Eb, and Braiso4Ec, were amplified, and polymorphisms between resistant and susceptible lines were analyzed. Sequence polymorphisms were found in Braiso4Ea and Braiso4Eb; in contrast, no sequence differences were found in Braiso4Ec between resistant and susceptible lines. A CAPS marker developed to test the linkage between Braiso4Eb and TuMV resistance displayed no linkage. A SCAR marker, trsSCAR, developed using allele-specific deletions and SNPs in Braiso4Ea, did co-segregate perfectly with trs in three F ₂ populations. However, the presence or absence of the Braiso4Ea sequence deletion was not consistent between resistant lines and susceptible lines, indicating that Braiso4Ea is not the actual resistance gene. Results from mapping analysis indicated that the trs is located at chromosome A04, between scaffold 000104 and scaffold 040552. This location demonstrated that trs may be another recessive resistance gene tightly linked to retr02 or another allele. The molecular markers developed in this study will be useful for breeding durable resistance.     

A Physical Map of the Mouseshaker-2Region Contains Many of the Genes Commonly Deleted in Smith–Magenis Syndrome (del17p11.2p11.2)

We report the construction of a physical map of the region of mouse chromosome 11 that encompassesshaker-2(sh2), a model for the human nonsyndromic deafnessDFNB3. DFNB3maps within the common deletion region of Smith–Magenis syndrome (SMS), del(17)(p11.2p11.2). Eleven of the genes mapping within the SMS common deletion region have murine homologs on thesh2physical map. The gene order in this region is not perfectly conserved between mouse and human, a finding to be considered as we engineer a mouse model of Smith–Magenis syndrome.     

Targeted deletion of the antisilencer/enhancer (ASE) element from intron 1 of the myelin proteolipid protein gene (Plp1) in mouse reveals that the element is dispensable for Plp1 expression in brain during development and remyelination

Myelin proteolipid protein gene (Plp1) expression is temporally regulated in brain, which peaks during the active myelination period of CNS development. Previous studies with Plp1‐lacZ transgenic mice demonstrated that (mouse) Plp1 intron 1 DNA is required for high levels of expression in oligodendrocytes. Deletion‐transfection analysis revealed the intron contains a single positive regulatory element operative in the N20.1 oligodendroglial cell line, which was named ASE (a ntis ilencer/e nhancer) based on its functional properties in these cells. To investigate the role of the ASE in vivo, the element was deleted from the native gene in mouse using a Cre/lox strategy. Although removal of the ASE from Plp1‐lacZ constructs profoundly decreased expression in transfected oligodendroglial cell lines (N20.1 and Oli‐neu), the element was dispensable to achieve normal levels of Plp1 gene expression in mouse during development (except perhaps at postnatal day 15) and throughout the remyelination period following cuprizone‐induced (acute) demyelination. Thus, it is possible that the ASE is non‐functional in vivo, or that loss of the ASE from the native gene in mouse can be compensated for by the presence of other regulatory elements within the Plp1 gene.     

Role of mouse and human class II transgenes in susceptibility to and protection against mouse autoimmune nhyroiditis

 Mouse experimental autoimmune thyroiditis (EAT), a model for Hashimoto’s thyroiditis, is induced by immunizing with mouse thyroglobulin (MTg). To study the extent of H2A involvement in EAT, we introduced AaAb genes from susceptible k mice into resistant or intermediately susceptible strains which do not express H2E molecules. Thyroiditis was severe in resistant B10.M (H2 ^f ) mice carrying the double transgene Aa ^k Ab ^k . Likewise, thyroid infiltration was significantly extended in intermediate B10.Q (H2 ^q ) mice with the same transgene. To examine the effect of H2E molecules in the presence of H2A-mediated susceptibility, we introduced an Ea ^k transgene into E^– B10.S mice to express the Eβ^s molecule and observed significant reduction in EAT severity in B10.S(E⁺) mice. On the other hand, the presence of an Eb ^d transgene in B10.RQB3 (H2A ^q ) mice resulting in the expression of H2Eβ^d molecules did not alter EAT susceptibility, suggesting a role for Eb gene polymorphism in protection against EAT. We have shown recently that the HLA-DRB1 ^* 0301 (DR3) transgene conferred EAT susceptibility to B10.M as well as class II-negative B10.Ab⁰ mice. However, we report here that the HLA-DQB1 ^* 0601 (DQ6b) transgene in B10.M or HLA-DQA1 ^* 0301/DQB1 ^* 0302 (DQ8) transgene in class II-negative Ab⁰ mice did not. These studies show the differential effects of class II molecules on EAT induction. Susceptibility can be determined when class II molecules from a single locus, H2A or HLA-DQ, are examined in transgenic mice, but the overall effect may depend upon the presence of both class II molecules H2A and H2E in mice and HLA-DQ and HLA-DR in humans. Received: 28 January 1997 / 24 March 1997     

Gene Structure of MurineGna11andGna15:Tandemly Duplicated Gq Class G Protein α Subunit Genes

G protein α subunits are encoded by a multigene family of 16 genes that can be grouped into four classes, Gq, Gs, Gi, and G12. The Gq class is composed of four genes in mouse and human, and two of these genes,Gna11andGna15,cosegregate on mouse chromosome 10. We have characterized the gene structures of murineGna11andGna15.The two genes are tandemly duplicated in a head-to-tail array. The upstream gene,Gna11,is ubiquitously expressed, whereas expression of the downstream gene,Gna15,is restricted to hematopoietic cells. The coding sequence of each gene is contained within seven exons, and the two genes together span 43 kb, separated by 6 kb of intergenic region. We have found no evidence for alternative splicing within the coding sequence of either gene. Sequence alignments show that the positions of the six intervening sequences are conserved in the two genes, consistent withGna11andGna15arising by tandem duplication from a common progenitor gene in vertebrates. Phylogenetic trees reveal unequal evolutionary rates among α subunits of the Gq class. The rate of change is approximately six fold higher inGna15than inGna11.     

Chromosomal Localization of the Human and Mouse Hyaluronan Synthase Genes

We have recently identified a new vertebrate gene family encoding putative hyaluronan (HA) synthases. Three highly conserved related genes have been identified, designatedHAS1, HAS2,andHAS3in humans andHas1, Has2,andHas3in the mouse. All three genes encode predicted plasma membrane proteins with multiple transmembrane domains and approximately 25% amino acid sequence identity to theStreptococcus pyogenesHA synthase, HasA. Furthermore, expression of any oneHASgene in transfected mammalian cells leads to high levels of HA biosynthesis. We now report the chromosomal localization of the threeHASgenes in human and in mouse. The genes localized to three different positions within both the human and the mouse genomes.HAS1was localized to the human chromosome 19q13.3–q13.4 boundary andHas1to mouse Chr 17.HAS2was localized to human chromosome 8q24.12 andHas2to mouse Chr 15.HAS3was localized to human chromosome 16q22.1 andHas3to mouse Chr 8. The map position forHAS1reinforces the recently reported relationship between a small region of human chromosome 19q and proximal mouse chromosome 17.HAS2mapped outside the predicted critical region delineated for the Langer–Giedion syndrome and can thus be excluded as a candidate gene for this genetic syndrome.     

The mouse homolog of FRG1, a candidate gene for FSHD, maps proximal to the myodystrophy mutation on chromosome 8

The human autosomal dominant neuromuscular disorder facioscapulohumeral muscular dystrophy (FSHD) is associated with deletions within a complex tandem DNA repeat (D4Z4) on Chromosome (Chr) 4q35. The molecular mechanism underlying this association of FSHD with DNA rearrangements is unknown, and, thus far, no gene has been identified within the repeat. We isolated a gene mapping 100 kb proximal to D4Z4 (FSHD Region Gene 1:FRG1), but were unable to detect any alterations in total or allele-specific mRNA levels of FRG1 in FSHD patients. Human Chr 4q35 exhibits synteny homology with the region of mouse Chr 8 containing the gene for the myodystrophy mutation (myd), a possible mouse homolog of FSHD. We report the cloning of the mouse gene (Frg1) and show that it maps to mouse Chr 8. Using a cross segregating the myd mutation and the European Collaborative Interspecific Backcross, we showed that Frg1 maps proximal to the myd locus and to the Clc3 and Ant1 genes. Received: 24 September 1996 / Accepted: 7 February 1997     

The Mouse Spam1 maps to proximal Chromosome 6 and is a candidate for the sperm dysfunction in Rb(6.16)24Lub and Rb(6.15)lAld heterozygotes

We have determined the chromosomal localization of the murine gene encoding the 68-kDa sperm adhesion molecule 1, Spam1 or Ph-20. Using two independent approaches, fluorescence in situ hybridization (FISH) and interspecific backcross analysis, we show that Spam1 maps to proximal mouse Chromosome (Chr) 6. This map position is within the conserved linkage group corresponding to human Chr 7q, where the human homolog, SPAM 1, has been shown to map previously. Genetic mapping shows the gene to be very closely linked to Met, one of the most proximal loci on MMU 6. It thus places the gene near the centromere and the junction of the Rb(6.16)24Lub and Rb(6.15)1Ald translocations. The essential role of the Spam1 sperm antigen in mouse sperm-egg interactions and its gene location provide strong support for its candidacy as the gene involved in the dysfunction of mouse sperm bearing the Rb(6.16)24Lub or Rb(6.15)1Ald translocation. Received: 16 July 1996 / Accepted: 23 September 1996