Genomic analysis of the H-2 complex region associated with mouse t Haplotypes

Naturally occurring t haplotypes suppress recombination over a region of mouse chromosome 17 that includes the H-2 complex. Each of these t haplotypes is associated with a specific set of H-2 alleles and can be placed into one of a limited number of complementation groups. Genetic studies have demonstrated the existence of a basic homology in genomic organization among all t haplotypes. We used an H-2 cDNA probe to investigate, at the molecular level, possible relationships among the H-2 regions of different t haplotypes. We identified a family of t haplotype-specific restriction fragments that carry DNA sequences homologous to the H-2-like genes. Surprisingly, the H-2-defined restriction patterns from all five complete t haplotypes analyzed are highly homologous, even though H-2 gene products expressed are antigenically distinct. These data lead to two major conclusions. First, all t haplotypes were derived from a small number of closely related ancestors. Second, the H-2 complex region associated with each primordial t chromosome has been maintained within at least the five present-day t haplotypes analyzed here. Hence the H-2 complex is an integral component of naturally occurring t haplotypes.     

Serological analysis of sperm of antigenically cross-reactingT/t-haplotypes and their recombinants

ThreeT/t-locus haplotypes (t ⁹,t ⁰, andt ^w2), which specifiy cross-reacting antigens on sperm, were examined by absorption analysis and found to contain a minimum of six specificities. Some specificities were common to more than one haplotype but each haplotype contained a unique specificity. Exceptional recombinant haplotypes fromt ⁰ andt ^w2 retained some of the common specificities but all had lost the unique specificity of the parental haplotype.T/t genes specifying antigens on sperm are apparently complex, and can be separated by recombination into at least two serologically detectable regions.     

A region flanking H-2K is duplicated to a distant site in most mouse t haplotypes

Mouse t haplotypes contain at least one inversion, which encompasses the major histocompatibility complex, relative to their wild-type counterparts. A DNA probe for a single copy sequence which flanks the H-2K region in inbred strains was found to have undergone further rearrangements in the t haplotypes. In most t haplotypes, this sequence is duplicated at a distant site, and the two regions show 1 % recombination. The length of homology shared by the two sites is likely to be at least 10–15 kb. Three different alleles, as defined by restriction fragment length polymorphisms, were found for each of the two sites among different t haplotypes. These may reveal evolutionary relationships among these chromosomes.     

Designation by restriction fragment length polymorphism of major histocompatibility complex class IV haplotypes in meat-type chickens

Major histocompatiblity complex (MHC) class IV haplotypes were identified in a population of meat-type chickens by restriction fragment length polymorphism (RFLP) analysis. Fourteen different haplotypes were designated on the basis of restriction patterns obtained from Southern blots of PvuII- or BglII-digested DNA, hybridized with the MHC class IV cDNA probe bg32.1. Digestion with each restriction enzyme yielded the same level of polymorphism among individuals. For each haplotype, 4–10 restriction fragments ranging from 0–8 to 8 kb were observed. Such a designation of meat-type chicken MHC class IV haplotypes enables a rapid recognition of previously defined haplotypes, is readily adjustable to additional, newly found restriction patterns and could prove useful in practical breeding programmes.     

An unstable family of large DNA elements in the center of the mouse t complex

We have cloned 363 kb (× 10³ bases) from a novel, locally dispersed family of 11 large DNA elements, called T66 elements, within the center of complete mouse t haplotypes. Homologies among individual members of the T66 family are observed along a repeated unit of at least 75 kb in length. Individual T66 homology units are classified into three subfamilies through hybridization studies with a series of diagnostic subfamily-specific probes. The organization and number of elements in wild-type forms of chromosome 17 are very different from those found within t haplotype forms of this chromosome. The number of T66 elements present within individual chromosomes is highly polymorphic among both inbred strains of mice and among independently derived t haplotypes. Wild-type chromosomes have between five and nine T66 elements distributed between two loci that are separated by a genetic distance of at least three map units, whereas t haplotypes have between 9 and 11 T66 elements within a single cluster. Many of the rare recovered products of recombination between a t haplotype and a wild-type form of chromosome 17 have resulted from recombination within or near the T66 regions present on each chromosome. Molecular and genetic data lead to the speculation that portions of individual T66 homology units could be involved in t haplotype effects on sperm differentiation.     

A polymorphic system related to but genetically independent of the chicken major histocompatibility complex

Analyses of the major histocompatibility complex (Mhc) in chickens have shown inconsistencies between serologically defined haplotypes and haplotypes defined by the restriction fragment patterns of Mhc class I and class II genes in Southern hybridizations. Often more than one pattern of restriction fragments for Mhc class I and/or class II genes has been found among DNA samples collected from birds homozygous for a single serologically defined B haplotype. Such findings have been interpreted as evidence for variability within the Mhc haplotypes of chickens not detected previously with serological methods. In this study of a fully pedigreed family over three generations, the heterogeneity observed in restriction fragment patterns was found to be the result of the presence of a second, independently segregating polymorphic Mhc-like locus, designated Rfp-Y. Three alleles (haplotypes) are identified in this new system.     

Identification and classification of S haplotypes in Raphanus sativus by PCR-RFLP of the S locus glycoprotein (SLG) gene and the S locus receptor kinase (SRK) gene

Polymorphism of the S-locus glycoprotein (SLG) and S-locus receptor kinase (SRK) genes in Raphanus sativus was analyzed by PCR-RFLP using SLG- and SRK-specific primers. Twenty four inbred lines of R. sativus could be grouped into nine S haplotypes. DNA fragments of SLG alleles specifically amplified from five S haplotypes by PCR with Class-I SLG-specific primers showed different profiles upon polyacrylamide-gel electrophoresis after digestion with restriction endonucleases. The five R. sativus SLG alleles were determined for their nucleotide sequences of DNA fragments. Comparison of the amino-acid sequences with a reported Brassica SLG (S₆) showed 77-84% homology. Deduced amino-acid sequences showed 12-conserved cystein residues and three hypervariable regions which are characteristic of Brassicsa SLG. A DNA fragment was also amplified by PCR from two of each S haplotype with Class-II SLG-specific primers, and showed polymorphism when cleaved with restriction endonucleases. The nucleotide sequences of amplified DNA fragments of the Class-II SLG revealed about 60% similarity with those of the Class-I SLG. It is concluded that there exist both Class I and Class II S alleles in R. sativus, as in Brassica campestris and Brassica oleracea. PCR using SRK-specific primers amplified a DNA fragment of about 1.0 kb from seven of each S haplotype out of 24 tested. These DNA fragments showed high polymorphism in polyacrylamide-gel electrophoresis after digestion with restriction endonucleases. Nucleotide sequences of the DNA fragments amplified from the seven S haplotypes showed that the fourth and the fifth exons of SRK are highly conserved, and that there is high variation in the fifth intron, the sixth intron and seventh exon of the SRK which may be responsible for the polymorphic band patterns in PCR-RFLP analysis. The PCR-RFLP method has proven useful for the identification of S alleles in inbred lines and for listing S haplotypes in R. sativus. Phylogenic analysis of the SLG and SRK sequences from Raphanus and Brassica revealed that the Raphanus SLGs and SRKs did not form an independent cluster, but were dispersed in the tree, clustering together with Brassica SLGs and SRKs. Furthermore, SLGs and SRKs from Raphanus were both grouped into Class-I or Class-II S haplotypes. Therefore, these results suggest that the diversification of the SLG and SRK alleles occurred prior to the differentiation of the two genera Brassica and Raphanus.     

Chloroplast Genome Diversity in Portuguese Grapevine (Vitis vinifera L.) Cultivars

Grapevine chloroplast (cp) DNA diversity was analysed for the first time through amplification and digestion of fragments of the large single copy (LSC) region by polymerase chain reaction–restriction fragment length polymorphism methodology and also by amplification of three microsatellite loci, previously described as polymorphic in grapevine. Thirty-eight grapevine cultivars collected mainly in the North of Portugal, including some neglected cultivars, four international cultivars (Chasselas, Muscat of Alexandria, Muscat of Hamburg and Pinot) and Vitis riparia and Vitis rupestris, were used in this study with the main goal of finding out their cpDNA diversity and compare the obtained results with previously published data on cultivars from other regions to ascertain their possible origin. Two different alleles were found in each of the three cpSSR loci. Allele variants of the three loci combined in a total of three different haplotypes (A, B and D). The most frequent haplotype, A, was previously reported as the most frequent in Iberian Peninsula and Occidental Europe. Haplotype B was unique to Rabigato, Muscat of Alexandria, V. riparia and V. rupestris. This haplotype was previously proposed to be an ancestral haplotype. Twenty-seven fragments of the LSC region of Vitis vinifera cpDNA were amplified and then digested with HinfI and TaqI restriction enzymes. Polymorphisms were found in the trnT-psbC (TC) and orf184-petA (OA) fragments. In the TC fragment, the polymorphism corresponds to a point mutation in a restriction site of TaqI and is only present in all cultivars with cpSSR haplotype D. In the OA fragment, a short deletion exclusive to the Rabigato cultivar was found. In this case, one sequence tagged site-based marker was developed and will be very useful in future phylogenetic and fingerprinting studies in a broader number of cultivars and in wild grapevine populations. Inference about the progenitors of the Touriga Franca cultivar is done. The present work supports and completes its origin as a descendent of the female and male parents, Marufo and Touriga Nacional.     

Genetic structure and origin of t haplotypes of mice, analyzed with H-2 cDNA probes

We investigated the genetic organization and evolutionary origin of t chromosomes of mice by examining the restriction fragment patterns of DNA from t haplotypes and normal chromosomes with cDNA probes to H-2 class I genes. On genomic DNA blots, the restriction fragments containing H-2-related sequences were highly variable among different inbred strains of mice, whereas they were very similar among different t haplotypes even when the t haplotypes carried serologically different H-2 haplotypes. These observations suggest that all t haplotypes have a common origin and are not products of independent mutational events. We also mapped the position of several restriction fragments characteristic of t DNA by using a battery of recombinant t haplotypes, defined with respect to their t-lethal factors and H-2 haplotypes. We thus show that restriction fragments containing H-2-related sequences map to the left of the H-2 class I genes in t chromosomes, a region in which the tw32 b-lethal factor also maps. The cloning of these fragments can be expected to provide an entry for the structural analysis of t DNA.     

Molecular cloning and characterization of the chicken gene homologous to the transforming gene of rous sarcoma virus

Four molecular clones containing DNA homologous to the Rous sarcoma virus transforming gene (src) have been isolated from a random library of normal chicken DNA. The four clones are distinct overlapping isolates, which together span approximately 33 kb of cellular DNA. The cloned locus appears to represent the major region of chicken DNA homologous to src, since src-containing restriction fragments of this locus account for the fragments detected by hybridization of src-specific probe to restriction digests of total chicken DNA. Analysis of the cloned chicken src locus by restriction and heteroduplex mapping indicates that the locus contains 1.6-1.9 kb of DNA homologous to the viral src gene. The chicken DNA sequences homologous to viral src are interrupted by five or six nonhomologous regions, totaling approximately 6 kb, which presumably represent introns in the cellular src gene.     

Sequence organisation in nuclear DNA from Physarum polycephalum: Genomic organisation of DNA segments containing foldback sequences

DNA clones containing foldback sequences, derived from Physarum polycephalum nuclear DNA, can be classified according to their pattern of hydridisation to Southern blots of genomic DNA. One group of DNA clones map to unique DNA loci when used as a probe to restriction digests of Physarum nuclear DNA. These cloned segments appear to contain dispersed repetitive sequence elements located at many hundreds of sites in the genome. Similar patterns of hybridisation are generated when these cloned DNA probes are annealed to DNA restriction fragments of genomic DNA obtained from a number of different Physarum strains, indicating that no detectable alteration has occurred at these genomic loci subsequent to the divergence of the strains as a result of the introduction or deletion of mobile genetic elements. However, deletion of segments of some cloned DNA fragments occurs following their propagation in Escherichia coli. A second, distinct group of clones are shown to be derived from highly methylated segments of Physarum DNA which contain very abundant repetitive sequences with regular, though complex, arrangements of restriction sites at their various genomic locations. It is suggested that these DNA segments contain clustered repetitive sequence elements. The results lead to the conclusion that foldback elements in Physarum DNA are located in segments of the genome which display markedly different patterns of sequence organisation and degree of DNA methylation.     

Restriction fragment length polymorphism of the major histocompatibility complex of the pig

Human HLA cDNA probes were used to analyze the restriction fragment length polymorphism (RFLP) of the SLA major histocompatibility complex in swine. Cellular genomic DNA from 19 SLA homozygous pigs representing 13 different haplotypes was digested with restriction endonucleases Eco RI, Hind III, or Bam H1, separated by electrophoresis, and transferred onto diazobenzyloxymethyl paper by the Southern blot technique. The blots were probed with ³²P-labeled class I or beta-DR class II cDNA. Depending on the haplotypes and the endonucleases used, seven to ten restriction fragments hybridized with the class I probe, and five to seven with the beta-DR probe. Their sizes ranged from 3.4 to 22 kilobase-pairs. Few bands were common to all 13 haplotypes. With all but one haplotype, identical autoradiogram patterns were obtained from unrelated, but phenotypically SLA-identical pigs, suggesting that most of the RFLP revealed were controlled by the SLA region. Further polymorphism was found in a group of seven unrelated pigs which typed serologically as SLA A15 CI B18 homozygotes but could be divided into two subgroups, with five animals in one subgroup and two in the other, when the genomic DNA was hybridized with the class I probe. When the class 11 beta-DR probe was tested on the same seven pigs, another subdivision was seen, and this correlated with MLR data. These results demonstrate that HLA class I and class II probes can be used to identify certain well-established SLA haplotypes and to identify subclasses within at least one SLA haplotype.Abbreviations MHC major histocompatibility complex - MLR mixed lymphocyte reaction - kbp kilobase pair(s) - RFLP restriction fragment length polymorphism     

Gene mapping within the T/t complex of the mouse. I. t-lethal genes are nonallelic

The t haplotypes of mouse chromosome 17 are natural polymorphisms in wild populations that contain mutations that affect or control such diverse functions as tail length, embryonic lethality and maturation and function of male germ cells. The major impediment to dissecting the genetics of this complex region has been its unusual property of recombination suppression in heterozygotes with wild-type chromosomes. Recently it was shown that recombination suppression does not occur in heterozygotes containing two different t haplotypes, which suggested that t chromosomes may be mismatched with respect to wild-type but share sequences that permit crossing-over between them. Thus for the first time questions of allelism and map positions of the t-lethal mutations can be addressed. We report here the results of three experiments that analyzed the t^w12 haplotype trans to either t^w5, t^w32 or t^w18. In all cases these lethal mutations were nonallelic to t^w12. These results, together with evidence for functional relatedness, suggest the t-lethals may be a gene family spread out over more than 15 centiMorgans of chromosome 17.     

Haplotypes That Are Mosaic for Wild-Type and T Complex-Specific Alleles in Wild Mice

Two outstanding problems pertaining to the population dynamics and evolution of the t complex in mice concern the frequency of t haplotypes in the wild and the degree to which these haplotypes recombine with their wild-type homologs. To address these problems, the frequency and distribution of several t complex-associated restriction fragment variants in wild mice were estimated. Sixty-four versions of chromosome 17 from wild-derived Mus musculus musculus and Mus musculus domesticus were examined with DNA probes for six loci within the t complex that exhibit restriction fragment variation. All six probes detect variants that have heretofore been found exclusively associated with the t complex. Haplotype analysis of wild-derived chromosomes revealed a high frequency (45.3%) of "mosaic" haplotypes with a mixture of t-specific and wild-type variants and only one haplotype with t-specific variants at all six loci. When 12 well-characterized t haplotypes isolated from diverse geographic regions were analyzed, only three had a complete set of t-specific restriction fragments for the six loci examined. The preponderance of mosaic haplotypes in both groups of mice can be explained by any one of the following hypotheses: genetic recombination between t haplotypes and their wild-type homologs, the persistence in wild populations of haplotypes that have descended from ancestral partial t haplotypes, or that the restriction fragment variants fixed in the ancestral t haplotype were also fixed in some wild-type haplotypes. There is evidence to support all three of these hypotheses in our data. The allelic composition of some mosaic haplotypes indicates that they may have been formed by segmental recombination, either double crossing over or gene conversion, rather than by simple single crossovers. The occurrence of indistinguishable mosaic haplotypes in both M. m. musculus and M. m. domesticus suggests that these haplotypes are ancestral rather than recently derived.     

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.     

Genetic diversity in Artemisia halodendron (Asteraceae) based on chloroplast DNA psbA–trnH region from different hydrothermal conditions in Horqin sandy land, northern China

The genetic diversity of Artemisia halodendron (Asteraceae), a constructive and dominant species in the Horqin sandy land, was investigated to examine the genetic relationships with different hydrothermal regions in the Horqin sandy land. We sequenced chloroplast DNA (cpDNA) fragments psbA–trnH of 243 plants from ten populations across the Horqin sandy land. The analyses of cpDNA variation identified seven haplotypes. A high level of haplotype diversity (H _d = 0.831) and low level of nucleotide diversity (π = 0.0018) were detected. Haplotypes clustered into three tentative clades. Low genetic differentiation among regions was consistently indicated by hierarchical analyses of molecular variance (AMOVA).     

Stoichiometric differences in DNA molecules containing the atpA gene suggest mechanisms for the generation of mitochondrial genome diversity in maize

Four genomic arrangements of the maize mitochondrial atpA gene (encoding the α subunit of the F₁ ATPase), have been characterized. Most N (fertile) and S (male-sterile) cytoplasms contain two atpA arrangements of equal abundance. Prolonged exposure of blots of maize mitochondrial DNA probed with atpA-specific sequences show that cytoplasms previously reported to lack one of the atpA arrangements do contain the second arrangement but at low levels. Similarly, restriction fragments containing the atpA gene previously thought unique to male-sterile S and T cytoplasms are present in low abundance in fertile cytoplasms. These observations suggest that fertile and male-sterile cytoplasms of maize may be more closely related than previously thought, and suggest possible mechanisms to explain the observed mitochondrial genome diversity.     

Polymorphism of the S -locus glycoprotein gene (SLG ) and the S -locus related gene (SLR1 ) in Raphanus sativus L. and self-incompatible ornamental plants in the Brassicaceae

The S-locus glycoprotein gene, SLG, which participates in the pollen-stigma interaction of self-incompatibility, and its unlinked homologue, SLR1, were analyzed in Raphanus sativus and three self-incompatible ornamental plants in the Brassicaceae. Among twenty-nine inbred lines of R. sativus, eighteen S haplotypes were identified on the basis of DNA polymorphisms detected by genomic Southern analysis using Brassica SLG probes. DNA fragments of SLG alleles specifically amplified from eight S haplotypes by PCR with class I SLG-specific primers showed different profiles following polyacrylamide gel electrophoresis, after digestion with a restriction endonuclease. The nucleotide sequences of the DNA fragments of these eight R. sativus SLG alleles were determined. Degrees of similarity of the nucleotide sequences to a Brassica SLG (S? ⁶ SLG) ranged from 85.6% to 91.9%. Amino acid sequences deduced from these had the twelve conserved cysteine residues and the three hypervariable regions characteristic of Brassica SLGs. Phylogenetic analysis of the SLG sequences from Raphanus and Brassica revealed that the Raphanus SLGs did not form an independent cluster, but were dispersed in the tree, clustering together with Brassica SLGs. These results suggest that diversification of the SLG alleles of Raphanus and Brassica occurred before differentiation of these genera. Although SLR1 sequences from Orychophragmus violaceus were shown to be relatively closely related to Brassica and Raphanus SLR1 sequences, DNA fragments that are highly homologous to the Brassica SLG were not detected in this species. Two other ornamental plants in the Brassicaceae, which are related more distantly to Brassica than Orychophragmus, also lacked sequences highly homologous to Brassica SLG genes. The evolution of self-incompatibility in the Brassicaceae is discussed.     

Dominant Sequences of Human Major Histocompatibility Complex Conserved Extended Haplotypes from HLA-DQA2 to DAXX

We resequenced and phased 27 kb of DNA within 580 kb of the MHC class II region in 158 population chromosomes, most of which were conserved extended haplotypes (CEHs) of European descent or contained their centromeric fragments. We determined the single nucleotide polymorphism and deletion-insertion polymorphism alleles of the dominant sequences from HLA-DQA2 to DAXX for these CEHs. Nine of 13 CEHs remained sufficiently intact to possess a dominant sequence extending at least to DAXX, 230 kb centromeric to HLA-DPB1. We identified the regions centromeric to HLA-DQB1 within which single instances of eight “common” European MHC haplotypes previously sequenced by the MHC Haplotype Project (MHP) were representative of those dominant CEH sequences. Only two MHP haplotypes had a dominant CEH sequence throughout the centromeric and extended class II region and one MHP haplotype did not represent a known European CEH anywhere in the region. We identified the centromeric recombination transition points of other MHP sequences from CEH representation to non-representation. Several CEH pairs or groups shared sequence identity in small blocks but had significantly different (although still conserved for each separate CEH) sequences in surrounding regions. These patterns partly explain strong calculated linkage disequilibrium over only short (tens to hundreds of kilobases) distances in the context of a finite number of observed megabase-length CEHs comprising half a population''s haplotypes. Our results provide a clearer picture of European CEH class II allelic structure and population haplotype architecture, improved regional CEH markers, and raise questions concerning regional recombination hotspots.