Introgression of nuclear and mitochondrial DNA markers of Mus musculus musculus to aboriginal populations of wild mice from Central Asia (M. m. wagneri) and South Siberia (M. m. gansuensis)

Variability of the nucleotide sequences of the second intron of the b1-chain of hemoglobin (Hbb-b1) and complete control region of mitochondrial DNA (D-loop) was studied in aboriginal and synanthropic populations of M. m. wagneri from Central Asia and M. m. gansuensis from South Siberia. A difference in the frequency of the Hbb^w1 hemoglobin variant for natural and urban populations of mice was shown. All mice from natural habitats of studied areas have musculus type of mtDNA. Apparently, the substitution of taxon-specific mitochondrial haplotypes of wagneri, and gansuensis might occur due to the absorbing hybridization with nominate subspecies musculus, which is consistent with the results on nuclear DNA (Hbb-b1 gene) obtained in this work. Two differentiated haplogroups among aboriginal subspecies wagneri (d = 0.01), one of which included house mice from Turkmenistan, were discovered for the first time. This may indicate mtDNA introgression from synanthropic forms of Turkmenistan into natural populations of Kazakhstan mice. The type of mtDNA typical for the castaneus subspecies was detected in two individuals from the natural habitat of Kazakhstan and Turkmenistan; it had not been encountered in Central Asia before. It has been suggested that the gene flow of nuclear and mitochondrial genomes in microevolution processes in M. musculus is directed from the synanthropic forms towards wild populations.     

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.     

Oxygenation properties and oxidation rates of mouse hemoglobins that differ in reactive cysteine content

House mice (genus Mus) harbor extensive allelic variation at two tandemly duplicated genes that encode the β-chain subunits of adult hemoglobin (Hb). Alternative haplotypes differ in the level of sequence divergence between the two β-globin gene duplicates: the Hbb^d and Hbb^p haplotypes harbor two structurally distinct β-globin genes, whereas the Hbb^s haplotype harbors two β-globin duplicates that are identical in sequence. One especially salient difference between the s-type Hbs relative to the d- and p-type Hbs relates to the number of reactive β-chain cysteine residues. In addition to the highly conserved cysteine residue at β93, the d- and p-type Hbs contain an additional reactive cysteine residue at β13. To assess the functional consequences of allelic variation in β-globin cysteine content, we measured O₂-binding properties and H₂O₂-induced oxidation rates of mono- and dicysteinyl β-Hbs from 4 different inbred strains of mice: C57BL/6J, BALB/cJ, MSM/Ms, and CAROLI/EiJ. The experiments revealed that purified Hbs from the various mouse strains did not exhibit substantial variation in O₂-binding properties, but s-type Hb (which contains a single reactive β-chain cysteine residue) was far more readily oxidized to Fe^3 + metHb by H₂O₂ than other mouse Hbs that contain two reactive β-chain cysteine residues. These results suggest that the possession of an additional reactive cysteine residue may protect against metHb formation under oxidizing conditions. The allelic differences in β-globin cysteine content could affect aspects of redox signaling and oxidative/nitrosative stress responses that are mediated by Hb-S-nitrosylation and Hb-S-glutathionylation pathways.     

Further evidence for recombination between mouse hemoglobin beta b1 and b2 genes based on the nucleotide sequences of intron, UTR, and intergenic spacer regions

Nucleotide sequences of the intron regions and UTRs (Untranslated regions) of the hemoglobin beta adult genes, b1 and b2, and of the intergenic spacer region were determined for mouse strains representing the d, p, and w1 hemoglobin haplotypes defined by protein electrophoretic analyses. The hypothesis of recombination of the b1 and b2 genes between the d and w1 haplotypes previously reported in the cDNA nucleotide sequences was confirmed by neighbor-joining analyses of the intron regions and UTRs within the b1 and b2 genes, suggesting that all of the structures of hemoglobin beta adult genes support the hypothesis that the p haplotype was established by hybridization between d and w1 haplotype mice. The resultant recombinant of the p haplotype was found to have a d-like b1 gene and a w1-like b2 gene. In addition to the possible recombination, a break point was suggested around 2-3 kb downstream of the b1 gene within the intergenic spacer region, despite the absence of clear properties that could stimulate the recombination machinery. Some large insertions or deletions (indels) specific to the p or d haplotypes were located within the intergenic spacer region, in which the 1010-bp indel specific to the p haplotype was shared by all examined strains representing the p haplotype.     

East asian hemoglobin type (Hbb p) in wild populations of the house mouse in Israel

Electrophoretic studies of hundreds of individuals showed that all wild populations of the house mouse in Israel are polymorphic for alleles Hbb ^d and Hbb ^p of the hemoglobin locus. No mouse carrying Hbb ^s was found. This finding contradicts the notion that Hbb ^p is limited to East Asian house mice.     

Strain distribution and linkage relationship of a mouse embryonic hemoglobin variant

Search for structural variants of three globin chains (x, y, z), synthesized only during mouse embryonic hematopoiesis, was carried out by electrophoretic analysis of blood from 12-day embryos, all with C57BL/6 mothers, and fathers from 115 inbred stocks selected for their diverse genetic origins. Structure of the -chains of adult hemoglobins differed among the tested strains, with 57 carrying the Hbb ^sallele, 56 the Hbb ^dallele, and two the Hbb ^pallele. The search revealed no x- or z-chain variants but confirmed and extended knowledge of a previously described y-chain variant. Blood of all embryos sired by males from the 57 Hbb ^sstrains contained only y¹-chains, while blood of all embryos sired by Hbb ^dor Hbb ^pmales contained y2-chains as well as the y¹-chains inherited from their C57 BL/6 mother. The locus controlling structure of the y-chain of mouse embryonic hemoglobins is thus extremely closely linked to the locus controlling structure of adult hemoglobin -chain, with maximum possible recombination frequency less than 0.019.This work was supported in part by Grants CA-01074 from the National Cancer Institute, USPHS, and GM 18684 from the National Institute of General Medical Sciences, in part by Grant ACS-VC58 from The American Cancer Society, in part by grants to the Jackson Laboratory from the Bushrod H. Campbell and Adah F. Hall Charity Fund and the Robert Sterling Clark Foundation, and in part by the Jackson Laboratory Endowment Fund. The Jackson Laboratory is fully accredited by the American Association for Accreditation of Laboratory Animal Care.     

The adult β-globin genes of the “single” type mouse C57BL

A set of four clones containing the two adult β-globin genes of the “single” type mouse C57BL/10 (genotype Hbb^s/Hbb^s) were isolated from a library of cloned restriction fragments. The two genes, designated βs and βt, were physically mapped onto a 32 kb segment of the chromosome carried by the four clones. βs and βt form a stable heteroduplex 1850 bp long, indicating that they are intact and conserved at this level of resolution throughout their length, including their intervening sequences. The βs gene is allelic with the βdmaj gene of the BALB/ c mouse (genotype Hbb^d/Hbb^d). These two alleles, as well as their surrounding sequences, are highly conserved. In contrast, heteroduplexes of βt with its BALB/c allele, βdmin, revealed three extensive but localized rearrangements. One region of non-homology falls within the large intervening sequence, IVS2. To the 5′ side of the βt/βdmin gene position two unequal substitutions were observed; each results in the net insertion of about 1000 bp into the Hbb^d chromosome. The β/βdmin gene position is bracketed by a 1450 bp inverted repeat. One of the 1000 bp substitutions maps within this inverted repeat.     

Linkage analyses using biochemical variants in mice. I. Linkage of the hemoglobin beta-chain and glucosephosphate isomerase loci

At least five alleles have been reported at the Hba locus, and each specifies the structure of an -chain variant of mouse (Mus musculus) hemoglobin. Hba ^c has proved to be especially useful in genetic linkage experiments and is present in the inbred strains BDP/J, C3H/HeJ, C3HeB/FeJ, DE/J, FL/2ReJ, P/J, SEA/GnJ, SJL/J, SWR/J, ST/bJ, and WB/ReJ. There are three alleles at the hemoglobin -chain locus, Hbb. Hbb ^p is found in strain AU/SsJ; other strains have either Hbb ^s or Hbb ^d . The -chains of Hbb ^d and Hbb ^p hemoglobins can be alkylated with iodoacetate and have two reactive sites per molecule. The -chains of Hbb ^s hemoglobins do not react. If hemoglobins are alkylated before electrophoresis to determine phenotype, alleles at Hbb are codominant. Evidence is presented that the -chain of Hbb ^p hemoglobin, like that of Hbb ^d hemoglobin, has a reactive cysteinyl residue at position 13. Tests for genetic linkage between ^Hba, Hbb, and 11 other loci showed linkage between glucosephosphate isomerase (Gpi-1) and Hbb with 32±5% recombination. Gpi-1, therefore, is in linkage group I. The Hba locus was not linked with any marker tested.Supported by the Roche Institute of Molecular Biology, Nutley, New Jersey.     

Haplotype diversity in the endosperm specific β-amylase gene Bmy1 of cultivated barley (Hordeum vulgare L.)

Five single nucleotide polymorphism (SNP) sites corresponding to substitutions in the protein sequence of the β-amylase gene Bmy1 at amino acid (AA) positions 115, 165, 233, 347 and 430 were genotyped in 493 cultivated barley accessions by Pyrosequencing and a CAPS assay. A total of 6 different haplotypes for the Bmy1 gene were discovered of which 4 haplotypes were identified as previously described alleles Bmy1-Sd1, Bmy1-Sd2L, Bmy1-Sd2H and Bmy1-Sd3, while 2 haplotypes were new. A broad spectrum of haplotypes was found in spring barleys, while the winter barleys were dominated by the newly described haplotype Bmy1-Sd4. Individual haplotype frequencies varied between the geographic regions.Three pairs of SNP loci within the gene showed highly significant (P<0.0001) elevated values of linkage disequilibrium (LD) with r ² > 0.6. In the European and Asian subpopulations different loci were in linkage disequilibrium due to the differences in haplotype frequency distributions. By applying LD data to select haplotype tagging SNPs, three SNP sites corresponding to AA positions 115, 233 and 347 were identified that allowed to discriminate 4 haplotypes and to capture 91.6% of the available diversity by distinguishing 452 out of 493 accessions. In a subset of 2-rowed German spring barley varieties 4 SNPs and 2 haplotypes had a significant association with the malting quality parameter final attenuation limit which is related to the total amylolytic enzymatic activity.     

Crassostrea angulata Bindin Gene and the Divergence of Fucose-Binding Lectin Repeats Among Three Species of Crassostrea

Bindin is a major protein for species-specific recognition between sperm and congenetic egg in many free-spawning marine invertebrates. We cloned a novel bindin gene from the oyster Crassostrea angulata by 3′ and 5′ rapid amplification of cDNA ends. The full-length bindin cDNA was 1,049 bp with a 771-bp open reading frame encoding 257 amino acids. The deduced amino acid sequence contained a putative signal peptide of 24 amino acids. The length of the bindin genomic DNA was 8,508 bp containing four exons and three introns. Three haplotypes of F-lectin repeat were detected from seven sequences of F-lectin repeat of six male oysters. Both neighbor-joining and minimum-evolution phylogenetic trees show that haplotype an1 was close to Crassostrea gigas while an2 and an3 were close to Crassostrea sikamea. Intron-4 in the middle of F-lectin repeat is highly variable in both size and sequence. We classified intron-4 into three types according to their size and the F-lectin repeat they were located in. Intron-4 may play an important role in recombination. We compared the number of nonsynonymous substitutions (Dn) and synonymous substitutions (Ds) per nucleotide site among 19 F-lectin haplotypes of the three species. Dn/Ds ratios suggested that positive selection occurred between C. gigas and C. sikamea and between C. gigas and C. angulata. Nine positive selected positions (p > 90%) are identified among 19 haplotypes of three species. They are located on the F-lectin binding face around the three recognition motif residues. We assume that these nine clustered amino acids are related with species-specific recognition.     

The multi-locus H-2D w16 region has an organization distinct from the D d region

Genomic DNA blot analyses using probes derived from the BALB/c 3 flanking region of the L ^d gene (L ^d 3 fl-C) and from near the BALB/c D3 ^d gene (50.2A) indicate that the B10.GAA37 mouse strain has a multi-locus D (D ^w16) region distinct from the five-gene organization observed in the D ^d and D ^q regions. To isolate the D ^w16 region class I genes, a genomic B10. GAA37-EMBL3 library was generated and screened with probes that preferentially hybridize to K and D region class I genes. Hybridization analyses of the isolated clones with L ^d derived oligonucleotide probes suggested that one of the clones contained the L ^w16 gene, whereas several other clones contained the L ^w16 gene. The sequence of the D ^w16 gene is most similar to that of the D ^p gene, particularly in the 3 half. Furthermore, the L ^w16 gene is quite similar in the 5 half and virtually identical in the 3 half to the L ^d gene, indicating that L ^w16, but not D ^w16, is a member of the L ^d gene family. Collectively, these data suggest that, through a D region recombination event, the novel D ^w16 region may have been assembled from primordial counterparts of the D ^p and L ^d genes.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession number M60774-M60776, and M62759.     

Comparative Genomics of Mitochondrial DNA in Drosophila simulans

The current study compares the nucleotide variation among 22 complete mitochondrial genomes of the three distinct Drosophila simulans haplotypes with intron 1 of the alcohol dehydrogenase-related locus. This is the first study to investigate the sequence variation of multiple complete mitochondrial genomes within distinct mitochondrial haplotypes of a single species. Patterns of variation suggest distinct forces are influencing the evolution of mitochondrial DNA (mtDNA) and autosomal DNA in D. simulans. First, there is little variation within each mtDNA haplotype but strong differentiation among them. In contrast, there is no support for differentiation of the mitochondrial haplotypes at the autosomal locus. Second, there is a significant deficiency of mitochondrial variation in each haplotype relative to the autosomal locus. Third, the ratio of nonsynonymous to synonymous substitutions is not equal in all branches of the well-resolved phylogeny. There is an excess of nonsynonymous substitutions relative to synonymous substitutions within each D. simulans haplotype. This result is similar to that previously observed within the mtDNA of distinct species. A single evolutionary force may be causally linked to the observed patterns of mtDNA variation—a rickettsia-like microorganism, Wolbachia pipientis, which is known to directly influence mitochondrial evolution but have a less direct influence on autosomal loci. Received: 16 September 1999 / Accepted: 14 March 2000     

Considerable haplotypic diversity in the RT1-CE class I gene region of the rat major histocompatibility complex

The major histocompatibility complex (MHC) class I region extending between the Bat1 and Pou5f1 genes shows considerable genomic plasticity in mouse and rhesus macaque but not in human haplotypes. In the rat, this region is known as the RT1-CE region. The recently published rat MHC sequence gave rise to a complete set of class I gene sequences in a single MHC haplotype, namely the RT1ⁿ haplotype of the widely used BN inbred strain. To study the degree of genetic diversity, we compared the RT1-CE region-derived class I genes of the RT1ⁿ haplotype with class I sequences of other rat haplotypes. By using phylogenetic tree analyses, we obtained evidence for extensive presence and absence polymorphisms of single loci and even small subfamilies of class I genes in the rat. Alleles of RT1-CE region class I genes could also be identified, but the rate of allelic nucleotide substitutions appeared rather low, indicating that the diversity in the RT1-CE region is mainly based on genomic plasticity.     

Subdivision of the S region of the mouse major histocompatibility complex by identification of genomic polymorphisms of the class III genes

The S region of the mouse major histocompatibility complex (MHC) encodes the class III proteins, the second (C2) and fourth (C4) components of complement, and factor B. Previously, the assignment of S-region haplotypes was based on analysis of protein polymorphisms. The recent availability of C2, C4, and factor B cDNA probes prompted a search for restriction fragment length polymorphisms which would serve as additional genetic markers for these loci. DNA was isolated from livers of mice of all standard inbred H-2 haplotypes and of haplotypes pz and bs. These DNA samples were digested with restriction endonucleases and analyzed by Southern blot. By the pattern of restriction fragment length polymorphism observed, specific markers have been identified in factor B of haplotypes f, u, z, bs, r, and v, and in C4 of haplotypes b, q,f,j,p,s, pz, r, and v. These genetic markers were used in the analysis of S-region composition in strains B10.TFR5 (H-2 ^ap5) and C3H.LG (H-2 ^dx), and a possible intra-S-region recombinant was revealed in the H-2 ^dxhaplotype. The genetic markers identified here subdivide the S region and will be of value in defining further the composition of the complement gene complex of the mouse MHC.     

Common CFTR gene variants influence body composition and survival in rural Ghana

Various studies in mice have found support for the hypothesis that heterozygous carriers of cystic fibrosis transmembrane conductance regulator (CFTR) mutations have an increased resistance to fatal infection compared to both homozygous mutation carriers and non-carriers, while in humans such evidence is scarce. In this study, we assessed the CFTR heterozygotes survival advantage hypothesis in a contemporary rural population that lives under adverse environmental conditions in the Upper-East region of Ghana. We genotyped 30 SNPs throughout the CFTR gene in 4,230 participants and tested their influence on survival and on body composition in the population at large. With a sliding-window haplotype analysis, we identified a set of six common haplotypes that influenced survival probabilities (global p = 6.00 × 10⁻⁰⁵). Individual haplotype analyses revealed two haplotypes of specific interest. One of these haplotypes was enriched (p = 0.003), whereas the other was depleted (p = 0.041) among people of old age (≥65 years) compared to young study participants (≤5 years). In addition, children (n = 474) carrying the latter haplotype had lower body weight (p _trend = 0.020) and height (p _trend = 0.010) compared to non-carriers. For all these analyses, similar associations for heterozygous and homozygous CFTR haplotype carriers were observed, revealing an additive effect of haplotype alleles. In conclusion, we identified common haplotypes in the CFTR gene that influence survival and body composition in the population at large with no evidence for heterozygote advantage.     

Function and evolution of allelic variations of Sr13 conferring resistance to stem rust in tetraploid wheat (Triticum turgidum L.)

The resistance gene Sr13 is one of the most important genes in durum wheat for controlling stem rust caused by Puccinia graminis f. sp. tritici (Pgt). The Sr13 functional gene CNL13 has haplotypes R1, R2 and R3. The R1/R3 and R2 haplotypes were originally designated as alleles Sr13a and Sr13b, respectively. To detect additional Sr13 alleles, we developed Kompetitive allele specific PCR (KASP™) marker KASPSr13 and four semi-thermal asymmetric reverse PCR markers, rwgsnp37–rwgsnp40, based on the CNL13 sequence. These markers were shown to detect R1, R2 and R3 haplotypes in a panel of diverse tetraploid wheat accessions. We also observed the presence of Sr13 in durum line CAT-A1, although it lacked any of the known haplotypes. Sequence analysis revealed that CNL13 of CAT-A1 differed from the susceptible haplotype S1 by a single nucleotide (C2200T) in the leucine-rich repeat region and differed from the other three R haplotypes by one or two additional nucleotides, confirming that CAT-A1 carries a new (R4) haplotype. Stem rust tests on the monogenic, transgenic and mutant lines showed that R1 differed from R3 in its susceptibility to races TCMJC and THTSC, whereas R4 differed from all other haplotypes for susceptibility to TTKSK, TPPKC and TCCJC. Based on these differences, we designate the R1, R3 and R4 haplotypes as alleles Sr13a, Sr13c and Sr13d, respectively. This study indicates that Sr13d may be the primitive functional allele originating from the S1 haplotype via a point mutation, with the other three R alleles probably being derived from Sr13d through one or two additional point mutations.     

Polymorphic and autoreactive H-2-specific monoclonal antibody isolated after injections of syngeneic sendai virus-coated lymphocytes

An H-2-specific monoclonal antibody (mAb Q-1) was obtained from B10.Q (H-2 ^q) mice injected with syngeneic Sendai virus-coated cells. The IgM monoclonal antibody recognizes the public determinant H-2.25 shared by H-2 ^k (K ^k) and H-2 ^r haplotypes and cross-reacts with H-2^d, H-2^s, H-2^p, and H-2^q cells, the latter being the haplotype of the challenged B-cell donor. The binding of mAb Q-1 to H-2^d, H-2^s, H-2^q, and H-2^p cells was lower than to H-2^k and H-2^r and of decreasing affinity but could be clearly distinguished from the negative reactions with H-2^b and H-2^f cells. MAb Q-1 distinguishes between Sendai virus-coated and uncoated lymphocytes only cells with low-affinity binding. On virus-coated or infected (H-2^p, H-2^q, H-2^d, H-2^s) cells lysis was stronger than on normal lymphocytes. We interpret the enhanced lysis of Sendai virus-positive cells by mAb Q-1 to be due to recognition of a modified exposure of public H-2 determinants induced by Sendai virus.On leave from The Institute of Immunology and Experimental Therapy, Wroclaw, Poland     

Evolutionary relationship between human major histocompatibility complexHLA-DR haplotypes

 HLA-DR haplotypes of the human major histocompatibility complex are organized in five different groups. They can be identified based on the serological specificity expressed by the polymorphic DRB1 locus and by the presence of a characteristic set of DRB genes. The nucleotide sequences of introns 4 and 5 of the two DRB genes (DRB1 ^* 01 and DRB6 ^* 01) from a DR1 haplotype and the three DRB genes (DRB1 ^* 15, DRB6 ^* 15, and DRB5 ^* 15), from a DR51 haplotype were determined. This study identified endogenous retroviral long terminal repeat elements (ERV9 LTR) located at identical positions in intron 5 of the DRB1 genes in both the DR1 and DR51 haplotypes. Phylogenetic analyses revealed a close evolutionary relationship between these two haplotypes. The DRB5 gene, unique for the DR51 haplotype, may have been lost by a recent gene deletion event creating the DR1 haplotype. A model for the evolution of the human DR haplotypes involving separate duplication and contraction events is presented. Received: 10 October 1995 / Revised: 22 November 1995     

Recombination within mouse <Emphasis Type="Italic">t</Emphasis> haplotypes has replaced significant segments of <Emphasis Type="Italic">t</Emphasis>-specific DNA

Previous studies on the fourth inversion of the t complex, In17(4), suggest that loci near the center of this inversion have been subjected to segmental recombination during the past 1–2 million years. We have used a combination of PCR-based restriction site (PBR) analysis and DNA sequencing to perform a high-resolution analysis of a 2-million base pair (Mbp) segment in the middle of In17(4). We examined 21 restriction sites that are polymorphic between t haplotypes and their wild-type homologs, over nine distinct loci. In addition, we examined several other polymorphic sites through DNA sequence analysis of two of these nine loci. We analyzed several haplotypes in this way, including the “complete” t haplotypes t ^w2 , t ⁰ , t ^w32 , t ^w71 , and t ^w75 . We show that only t ^w32 is a true “complete” t haplotype; the remaining four t haplotypes have segments of wild-type DNA ranging from less than 100 bp to 2 Mbp. The sizes of these wild-type DNA segments are consistent with their being generated by gene-conversion events. The 2-Mbp segment is located in a region that may contain the t-complex distorter gene Tcd2. One of the nine loci examined in this study is Fgd2, a gene that has been proposed to encode Tcd2. Sequencing and PBR data show that at least a portion of the Fgd2 gene has been converted to the wild-type within t ^w71 and t ^w75 mice.