Discovery of a new HBB haplotype <Emphasis Type="Italic">w2</Emphasis> in a wild-derived house mouse, <Emphasis Type="Italic">Mus musculus</Emphasis>

Genetic characterization of a wild-derived house mouse, Mus musculus, originally collected near Lake Balkhash in the Republic of Kazakhstan, was performed by examining protein polymorphisms and nucleotide sequences for the hemoglobin beta chain (HBB) subunits. Protein electrophoresis, which was performed on a cellulose-acetate plate, showed an independent mobility pattern representing a new, previously undiscovered haplotype. Neighbor-joining analyses of the HBB adult genes, i.e., HBB-T1 and HBB-T2, and the intergenic spacer region showed that the Lake Balkhash mouse possessed genomic components that were mixed from different haplotypes. Compared to the previously determined HBB haplotypes, d, p, and w1, the HBB-T1 gene and ca. 11 kb of the spacer region were most similar to the w1 haplotype; however, the remainder of the spacer region and the HBB-T2 gene were most similar to the d haplotype but may represent a still uncharacterized and divergent haplotype. The recombination event is predicted to have occurred 2.5 kb upstream of the HBB-T2 gene and may have occurred through intersubspecific hybridization between mice of the musculus subspecies group (with the w1 haplotype) and the castaneus subspecies group (with the d-like haplotype). Alternatively, an unknown subspecies group that is equidistantly divergent from each of these subspecies groups may have been involved. Our findings suggest reticulate evolution among the subspecies groups during the evolution of M. musculus.     

Genetic analysis of the H-2D region using a new intra-D-region recombinant mouse strain

A rare D-region recombination event which gave rise to the B10.RQDB major histocompatibility complex haplotype has been examined to ascertain the nature of the crossover and to determine which class I genes are present in the new alignment of D-region genes. Serologic analysis have shown that the B10 . RQDB major histocompatibility complex recombinant mouse inherited the H-2Dd gene from the B10.T(6R) parental line and the H-2Db gene from the B10.A(2R) parental line, representing the first example of an intra-D-region crossover resulting from an intercross. Previous molecular genetic analyses of the d and b haplotypes revealed structural diversity in the organization of their D-region gene clusters. Hence, the D region is comprised of five class I genes in the d haplotype and only one in the b haplotype. Because allelic relationships among the various D-region genes are not defined, either a homologous or nonhomologous alignment of genes has generated the RQDB crossover. Therefore, the possibility that all three D-region antigen-presenting molecules (Dd, Ld, and Db) might be encoded by the RQDB haplotype was examined. Fluorescence-activated cell sorter and cytotoxic T lymphocyte analyses revealed no detectable levels of H-2Ld cell-surface expression, confirming earlier studies with antibody-mediated cytotoxicity and immunoprecipitation. Southern blot analysis localized the recombination point to within a 1-kb region at the centromeric end of the H-2Ld gene on the B10 . T(6R) chromosome in a region of high homology to the H-2Db gene on the B10 . A(2R) chromosome. Together, these studies define the D region of the RQDB haplotype as containing the five class I genes: Dd, D2d, D3d, D4d, and Db. In addition to providing insight into rare recombination events in the D region, the B10.RQDB mouse should be a useful tool for exploring the function of D-region genes.     

The E beta hot spot of recombination in wild-derived natural recombinant MHC haplotypes. Cross-over site mapping and the identification of a 1.0-kb E beta deletion in the p and w14 haplotypes

Detailed molecular analysis of three wild-derived MHC haplotypes provided evidence for an important role of the E beta recombinational hot spot in the recent evolution of the mouse I region. Examination of RFLP and restriction maps of cloned DNA permitted the mapping of the natural cross-over events in the haplotypes carried by strains B10.GAA37 (w21) and B10.KPB128 (w19) to a fragment of DNA not exceeding 4.1 kb, which lies almost entirely within the intron separating the beta 1 and beta 2 exons of the E beta gene. In the w14 haplotype (strain B10.STC77), which appears to be a natural recombinant between a p-like parental haplotype and another wild-derived haplotype, the site of crossing over can be mapped to a segment between the beta 2 exon of the E beta gene (left border) and the E beta 2 gene (right border). This segment containing the cross-over site in the w14 haplotype includes the E beta hot spot. In addition, the w14 haplotype as well as the standard p haplotype contain a deletion of approximately 1.0 kb in the second intron of the E beta gene, which may represent the product of an unequal cross-over event in a E beta recombinational hot spot.     

The nucleotide sequence of the murine I-E beta b immune response gene: evidence for gene conversion events in class II genes of the major histocompatibility complex.

We have determined the DNA sequence of the murine I-E beta b immune response gene of the major histocompatibility complex (MHC) of the C57BL/10 mouse and compared it with the sequence of allelic I-E and non-allelic I-A genes from the d and k haplotypes. The polymorphic exon sequences which encode the first extracellular globular domain of the E beta domain show approximately 8% nucleotide substitutions between the E beta b and E beta d alleles compared with only approximately 2% substitutions for the intron sequences. This suggests that an active mechanism such as micro gene conversion events drive the accumulation of these mutations in the polymorphic exons. The fact that several of the nucleotide changes are clustered supports this hypothesis. The E beta b and E beta k genes show approximately 2-fold fewer nucleotide substitutions than the E beta d/E beta b pair. The A beta bm12, a mutant I-A beta b gene from the C57BL/6 mouse, has been shown to result from three nucleotide changes clustered in a short region of the beta 1 domain, which suggests that a micro gene conversion event caused this mutation. We show here that the E beta b gene is identical to the non-allelic A beta bm12 DNA sequence in the mutated region and suggest, therefore, that the E beta b gene was the donor sequence for this intergenic transfer of genetic information. Diversity in class II MHC genes appears therefore to be generated, at least in part, by the same mechanism proposed for class I genes: intergenic transfer of short DNA regions between non-allelic genes.     

Variant chromosomal arrangement of adult beta-globin genes in rat

The genomic organization of three haplotypes of beta-globin genes was determined to resolve the question of the number of those genes in rat. Haplotype a, found in inbred strain DA, has three genes or pseudogenes, while haplotypes b, found in AO, Y5 and Wistar strains, and c, found in Wistar strain, have five genes or pseudogenes each. In haplotypes b and c, the first gene is of beta major type and the remaining four are of beta minor type. Partial sequencing of six out of 13 genes shows that duplications of beta minor genes are causing polymorphism in a number of genes. Also, in haplotype b two beta minor genes have a 6.5-kb intron 2, while in haplotype c only one beta minor gene contains such a large intron 2. The three structurally different haplotypes described are not interconvertible by single recombination events. The results indicate that the rat has the highest number of adult beta-globin genes found in mammals so far.     

Cross-species amplification of mitochondrial DNA sequence-tagged-site markers in conifers: the nature of polymorphism and variation within and among species in Picea

Primers previously developed to amplify specific non-coding regions of the mitochondrial genome in Angiosperms, and new primers for additional non-coding mtDNA regions, were tested for their ability to direct DNA amplification in 12 conifer taxa and to detect sequence-tagged-site (STS) polymorphisms within and among eight species in Picea. Out of 12 primer pairs, nine were successful at amplifying mtDNA in most of the taxa surveyed. In conifers, indels and substitutions were observed for several loci, allowing them to distinguish between families, genera and, in some cases, between species within genera. In Picea, interspecific polymorphism was detected for four loci, while intraspecific variation was observed for three of the mtDNA regions studied. One of these (SSU rRNA V1 region) exhibited indel polymorphisms, and the two others ( nad1 intron b/c and nad5 intron1) revealed restriction differences after digestion with Sau3AI (PCR-RFLP). A fourth locus, the nad4L- orf25 intergenic region, showed a multibanding pattern for most of the spruce species, suggesting a possible gene duplication. Maternal inheritance, expected for mtDNA in conifers, was observed for all polymorphic markers except the intergenic region nad4L- orf25. Pooling of the variation observed with the remaining three markers resulted in two to six different mtDNA haplotypes within the different species of Picea. Evidence for intra-genomic recombination was observed in at least two taxa. Thus, these mitotypes are likely to be more informative than single-locus haplotypes. They should be particularly useful for the study of biogeography and the dynamics of hybrid zones.     

Haplotypic Diversity Within the Ovine Calpastatin <Emphasis Type="Italic">(CAST)</Emphasis> Gene

Calpastatin (CAST) is a protein inhibitor that acts specifically on calpains and plays a regulatory role in postmortem beef tenderization and muscle proteolysis. Polymorphisms in the bovine CAST gene have been associated with meat tenderness, but little is known about how the ovine CAST gene may affect sheep meat quality traits. In this study, we selected two parts of the ovine CAST gene that have been previously reported to be polymorphic (region 1—part of intron 5 and exon 6, and region 2—part of intron 12), to investigate haplotype diversity across an extended region of the ovine gene. First, we developed a simple and efficient polymerase chain reaction-single-strand conformational polymorphism (PCR-SSCP) method for genotyping region 2, which allowed the detection of a novel allele as well as the three previously reported alleles. Next, we genotyped both regions 1 and 2 of the ovine CAST gene from a large number of sheep to determine the haplotypes present. Nine different haplotypes were found across this extended region of the ovine CAST gene and four haplotypes were identified that suggested historical recombination events within this gene. Haplotypes are typically more informative than single nucleotide polymorphisms (SNPs) for analyzing associations between genes and complex production traits, such as meat tenderness, but the potential for intragenic recombination within the ovine CAST may make finding associations challenging.     

Determining the physical limits of the Brassica S locus by recombinational analysis

A genetic analysis was performed to study the frequency of recombination for intervals across the Brassica S locus region. No recombination was observed between the S locus glycoprotein gene and the S receptor kinase gene in the segregating populations that we analyzed. However, a number of recombination breakpoints in regions flanking these genes were identified, allowing the construction of an integrated genetic and physical map of the genomic region encompassing one S haplotype. We identified, based on the pollination phenotype of plants homozygous for recombinant S haplotypes, a 50-kb region that encompasses all specificity functions in the S haplotype that we analyzed. Mechanisms that might operate to preserve the tight linkage of self-incompatibility specificity genes within the S locus complex are discussed in light of the relatively uniform recombination frequencies that we observed across the S locus region and of the structural heteromorphisms that characterize different S haplotypes.     

Maize genome structure variation: interplay between retrotransposon polymorphisms and genic recombination

Although maize (Zea mays) retrotransposons are recombinationally inert, the highly polymorphic structure of maize haplotypes raises questions regarding the local effect of intergenic retrotransposons on recombination. To examine this effect, we compared recombination in the same genetic interval with and without a large retrotransposon cluster. We used three different bz1 locus haplotypes, McC, B73, and W22, in the same genetic background. We analyzed recombination between the bz1 and stc1 markers in heterozygotes that differ by the presence and absence of a 26-kb intergenic retrotransposon cluster. To facilitate the genetic screen, we used Ds and Ac markers that allowed us to identify recombinants by their seed pigmentation. We sequenced 239 recombination junctions and assigned them to a single nucleotide polymorphism-delimited interval in the region. The genetic distance between the markers was twofold smaller in the presence of the retrotransposon cluster. The reduction was seen in bz1 and stc1, but no recombination occurred in the highly polymorphic intergenic region of either heterozygote. Recombination within genes shuffled flanking retrotransposon clusters, creating new chimeric haplotypes and either contracting or expanding the physical distance between markers. Our findings imply that haplotype structure will profoundly affect the correlation between genetic and physical distance for the same interval in maize.     

Contribution of mutation, recombination, and gene conversion to chicken MHC-B haplotype diversity

The Mhc is a highly conserved gene region especially interesting to geneticists because of the rapid evolution of gene families found within it. High levels of Mhc genetic diversity often exist within populations. The chicken Mhc is the focus of considerable interest because of the strong, reproducible infectious disease associations found with particular Mhc-B haplotypes. Sequence data for Mhc-B haplotypes have been lacking thereby hampering efforts to systematically resolve which genes within the Mhc-B region contribute to well-defined Mhc-B-associated disease responses. To better understand the genetic factors that generate and maintain genomic diversity in the Mhc-B region, we determined the complete genomic sequence for 14 Mhc-B haplotypes across a region of 59 kb that encompasses 14 gene loci ranging from BG1 to BF2. We compared the sequences using alignment, phylogenetic, and genome profiling methods. We identified gene structural changes, synonymous and non-synonymous polymorphisms, insertions and deletions, and allelic gene rearrangements or exchanges that contribute to haplotype diversity. Mhc-B haplotype diversity appears to be generated by a number of mutational events. We found evidence that some Mhc-B haplotypes are derived by whole- and partial-allelic gene conversion and homologous reciprocal recombination, in addition to nucleotide mutations. These data provide a framework for further analyses of disease associations found among these 14 haplotypes and additional haplotypes segregating and evolving in wild and domesticated populations of chickens.     

Frequency and origin of haplotypes associated with the beta-globin gene cluster in individuals with trait and sickle cell anemia in the Atlantic and Pacific coastal regions of Colombia

Sickle cell anemia is a genetic disease with high prevalence in people of African descent. There are five typical haplotypes associated with this disease and the haplotypes associated with the beta-globin gene cluster have been used to establish the origin of African-descendant people in America. In this work, we determined the frequency and the origin of haplotypes associated with hemoglobin S in a sample of individuals with sickle cell anemia (HbSS) and sickle cell hemoglobin trait (HbAS) in coastal regions of Colombia. Blood samples from 71 HbAS and 79 HbSS individuals were obtained. Haplotypes were determined based on the presence of variable restriction sites within the β-globin gene cluster. On the Pacific coast of Colombia the most frequent haplotype was Benin, while on the Atlantic coast Bantu was marginally higher than Benin. Eight atypical haplotypes were observed on both coasts, being more diverse in the Atlantic than in the Pacific region. These results suggest a differential settlement of the coasts, dependent on where slaves were brought from, either from the Gulf of Guinea or from Angola, where the haplotype distributions are similar. Atypical haplotypes probably originated from point mutations that lost or gained a restriction site and/or by recombination events.     

The rearrangement of the human alpha(1)-acid glycoprotein/orosomucoid gene: evidence for tandemly triplicated genes consisting of two AGP1 and one AGP2

The human alpha(1)-acid glycoprotein (AGP) or orosomucoid (ORM) is controlled by the two tandemly arranged genes, AGP1 and AGP2. The further duplication of the AGP1 gene has been suggested by a few duplicated ORM1 locus haplotypes including ORM1*F1. S and ORM1*B9. S, detected by isoelectric focusing. To clarify the triplication of the AGP gene, 39 DNA samples from Japanese subjects were studied by the long-range PCR of intergenic regions. The analysis of PCR products showed that the tandemly triplicated genes, AGP1A-AGP1B-AGP2, occurred on about 20% of chromosomes. These composites were divided into ORM1A*F1-ORM1B*S-ORM2*M and ORM1A*B9-ORM1B*S-ORM2*M by allelic variations. Furthermore, the former was classified into a few haplotypes by three synonymous sequence variations, which might have arisen through gene conversion-like events. The recombination breakpoints existed between the 5' flanking region and intron 2 of the AGP1B gene. Thus, it is likely that the rearrangement of the AGP gene has often occurred.     

Identification and expression of the Tla region gene T11b and its Qa-like product

In spite of the large number of class I genes in the Qa-Tla region of the H-2 complex, only few membrane-bound Qa and TL Ag have been identified. We show that one of the Qa-Tla region genes, the T11b gene, is transcribed in lymphoid cells, lymphoma cell lines, teratocarcinoma cell lines, and L cells transfected with the cloned T11b gene. The T11b gene potentially encodes a polypeptide with normal class I characteristics. The product as present at the cell surface of L cells transfected with the cloned T11b gene, is a sialylated protein of m.w. 41,000, associated with beta 2-microglobulin. This T11b Ag shares epitopes with H-2K and H-2D molecules of various haplotypes and with Qa-2 molecules, but has distinct biochemical properties. RFLP analysis revealed that the T11b gene is found in mice of the Tlab and Tlaf haplotype. Genes homologous to, but distinct from, T11b (allelic or duplicated) are present in all Tla haplotypes tested.     

Killer Ig-like receptor haplotype analysis by gene content: evidence for genomic diversity with a minimum of six basic framework haplotypes,each with multiple subsets

Killer Ig-like receptor (KIR) genes constitute a multigene family whose genomic diversity is achieved through differences in gene content and allelic polymorphism. KIR haplotypes containing a single activating KIR gene (A-haplotypes), and KIR haplotypes with multiple activating receptor genes (B-haplotypes) have been described. We report the evaluation of KIR gene content in extended families, sibling pairs, and an unrelated Caucasian panel through identification of the presence or absence of 14 KIR genes and 2 pseudogenes. Haplotype definition included subtyping for the expressed and nonexpressed KIR2DL5 variants, for two alleles of pseudogene 3DP1, and for two alleles of 2DS4, including a novel 2DS4 allele, KIR1D. KIR1D appears functionally homologous to the rhesus monkey KIR1D and likely arose as a consequence of a 22 nucleotide deletion in the coding sequence of 2DS4, leading to disruption of Ig-domain 2D and a premature termination codon following the first amino acid in the putative transmembrane domain. Our investigations identified 11 haplotypes within 12 families. From 49 sibling pairs and 17 consanguineous DNA samples, an additional 12 haplotypes were predicted. Our studies support a model for KIR haplotype diversity based on six basic gene compositions. We suggest that the centromeric half of the KIR genomic region is comprised of three major combinations, while the telomeric half can assume a short form with either 2DS4 or KIR1D or a long form with multiple combinations of several stimulatory KIR genes. Additional rare haplotypes can be identified, and may have arisen by gene duplication, intergenic recombination, or deletions.     

Nucleotide sequences of the mouse globin beta gene cDNAs in a wild derived new haplotype Hbb w1

Haplotypes of the beta-globin gene complex (Hbb) in laboratory mice have been defined as d, p, and s. We previously found a new haplotype w1 in wild mice collected from northwestern China. This study analyzed the nucleotide sequences of b1 and b2-globin gene cDNAs of both the p and w1 haplotypes, in comparison with those of the d haplotype. In Hbb-b1 cDNA, six base substitutions were found between the d and w1 haplotypes and also between p and w1, but none existed between d and p. In Hbb-b2 cDNA, three base substitutions were found between the d and w1 haplotypes and also between d and p, but none between p and w1. This result indicated that the Hbb gene complex of the p haplotype carries b1 ^d and b2 ^w1 genes and is probably a recombinant between d and w1 haplotypes. The hemoglobin containing the W1 phenotype showed oxygen-binding properties identical with those of the hemoglobins containing D and P phenotypes. Received: 5 January 1999 / Accepted: 5 April 1999     

利用ITS1和Cyt b位点的DNA单链空间构型多样性研究黑脚硬蜱的种群结构

黑脚硬蜱 (Ixodesscapularis)是莱姆病的主要传毒媒介。本文利用从 12个不同地点采集的 85 3个样本 ,采用DNA单连构型多样性的分子技术 (DNAsinglestrandconformationpolymorphisms)对黑脚硬蜱的种群结构进行了分析。线粒体细胞色素b (Cytb)和核糖体rRNA基因的内部转录空间ITS1被用为种群目标分子标记位点。在Cytb位点上 ,总共发现 7个单倍基因型。在ITS1位点上 ,共发现 13个基因型。基因型频率分析结果显示 ,沿美国东海岸分布的黑脚硬蜱隶属于两个不同的南北种群 ,但是基因流在地理区域间频繁发生。尽管蜱自身的迁徙扩散能力有限 ,但地理区域内个体间的遗传变异程度仍然较大 ,这可能与黑脚硬蜱寄主动物的频繁迁移有关。另外 ,本研究资料显示 ,南方种群的遗传变异程度明显大于北方种群     

Extent of mitochondrial DNA sequence variation in Atlantic cod from the Faroe Islands: a resolution of gene genealogy

Variation in a 250 base pair (bp) fragment of the mitochondrial cytochrome b (cyt b) has been used extensively for population studies in Atlantic cod Gadus morhua. To study the shape of the gene genealogy and the nature of the polymorphism, sequences of another region of the cyt b gene and the TP intergenic spacer were added, making a total of 566 bp from 74 cod from the Faroe Islands. A total of 44 segregating sites defined 41 haplotypes, many at frequencies greater than 5%. Haplotype diversity was 0.97 and nucleotide diversity 0.73% per base. A topology referred to as a constellation gene genealogy was observed with four major haplotypes at high frequencies, from each of which a number of rare variants were derived. A young relative age of the haplotypes was gauged from the structure of the genealogy. The variation was mostly at synonymous sites within the coding region and thus likely to be neutral or under weak purifying selection. By comparative analysis this also applies to the TP spacer. Applying the locus to study population variation in the Faroe Islands by AMOVA revealed that the overall areas and localities within areas accounted for none of the variation, and all the variation was due to differences among individuals.     

Structure of a hemoglobin gene cluster and nucleotide sequence of three hemoglobin genes from the midge Chironomus thummi piger (Diptera, Insecta)

The aquatic larvae of the genus Chironomus (Diptera, Insecta) contain at least 12 different hemoglobin (Hb) variants in their hemolymph. In the present study we have analysed the structure and part of the nucleotide sequence of a Hb gene cluster cloned from the genomic DNA of Chironomus thummi piger. The cluster contains probably 6 different genes, separated by intergenic regions of various lengths. The nucleotide sequence of three putative Hb genes including the intergenic regions is presented. The inferred amino-acid sequences show clearly that two of these putative genes code for subvariants of the Hb variant VIIB. The third gene codes for a so far unknown Hb protein. As known already for other chironomid Hb genes, there are no intron sequences present in the coding regions.