Localization of the beta-like globin gene cluster and the genes for parathyroid hormone and c-Harvey-ras 1 to region q14----q21 of rabbit chromosome 1 by in situ hybridization

Localization of the beta-subunit of follicle stimulating hormone in cattle and sheep by in situ hybridization

The locus for the beta-subunit of the follicle stimulating hormone gene (FSHB) has been determined in both cattle and sheep by in situ hybridization of a bovine and an ovine cDNA probe, respectively, to metaphase chromosomes. Our results show that the FSHB locus is on cattle chromosome 15 in the region of bands q24-qter and in sheep on the cytogenetically homologous chromosome 15, also in the region q24-qter. The mapping of the FSHB gene in cattle together with the location of other genes (CAT, HBB and PTH) previously found to be syntenic in cattle and on human chromosome 11p, defines an evolutionarily conserved synteny. The localization of the FSHB gene to a cytogenetically homologous region in cattle and sheep is consistent with the hypothesis of extensively conserved chromosome structure in these two species.

Reduced introgression of the Y chromosome between subspecies of the European rabbit (Oryctolagus cuniculus) in the Iberian Peninsula

The role of the Y chromosome in speciation is unclear. Hybrid zones provide natural arenas for studying speciation, as differential introgression of markers may reveal selection acting against incompatibilities. Two subspecies of the European rabbit (Oryctolagus cuniculus) form a hybrid zone in the Iberian Peninsula. Previous work on mitochondrial DNA (mtDNA), Y- and X-linked loci revealed the existence of two divergent lineages in the rabbit genome and that these lineages are largely subspecies-specific for mtDNA and two X-linked loci. Here we investigated the geographic distribution of the two Y chromosome lineages by genotyping two diagnostic single nucleotide polymorphisms in a sample of 353 male rabbits representing both subspecies, and found that Y chromosome lineages are also largely subspecies-specific. We then sequenced three autosomal loci and discovered considerable variation in levels of differentiation at these loci. Finally, we compared estimates of population differentiation between rabbit subspecies at 26 markers and found a surprising bimodal distribution of F(ST)values. The vast majority of loci showed little or no differentiation between rabbit subspecies while a few loci, including the SRY gene, showed little or no introgression across the hybrid zone. Estimates of population differentiation for the Y chromosome were surprisingly high given that there is male-biased dispersal in rabbits. Taken together, these data indicate that there is a clear dichotomy in the rabbit genome and that some loci remain highly differentiated despite extensive gene flow following secondary contact.

Evidence for contrasting modes of selection at interacting globin genes in the European rabbit (Oryctolagus cuniculus)

In hybrid zones between genetically differentiated populations, variation in locus-specific rates of introgression may reflect adaptation to different environments or adaptation to different genetic backgrounds. The European rabbit, Oryctolagus cuniculus, is well-suited to studies of such hybrid zone dynamics because it is composed of two genetically divergent subspecies that hybridize in a zone of secondary contact in central Iberia. A species-wide survey of allozyme variation revealed a broad range of locus-specific divergence levels (F(ST) ranged from 0 to 0.54, mean F(ST)=0.16). Interestingly, the two loci that fell at opposite ends of the distribution of F(ST) values, haemoglobin alpha-chain (HBA) and haemoglobin beta-chain (HBB), encode interacting subunits of the haemoglobin protein. The contrasting patterns of spatial variation at these two loci could not be reconciled under a neutral model of population structure. The HBA gene exhibited higher-than-expected levels of population differentiation, consistent with a history of spatially varying selection. The HBB gene exhibited lower-than-expected levels of population differentiation, consistent with some form of spatially uniform selection. Patterns of linkage disequilibrium and allele frequency variation do not appear to fit any simple model of two-locus epistatic selection.

A first-generation microsatellite-based integrated genetic and cytogenetic map for the European rabbit (Oryctolagus cuniculus) and localization of angora and albino

Although the European rabbit (Oryctolagus cuniculus) is used both in agronomics and in research, genomic resources for this species are still limited and no microsatellite-based genetic map has been reported. Our aim was to construct a rabbit genetic map with cytogenetically mapped microsatellites so as to build an integrated genetic and cytogenetic map. A reference population of 187 rabbits comprising eight three-generation families with 10-25 offspring per family was produced. One hundred and ninety-four of 305 previously identified microsatellites were included in this study. Of these, 158 were polymorphic with two to seven alleles. The map reported here comprises 111 markers, including 104 INRA microsatellites, five microsatellites from another source and two phenotypic markers (angora and albino). Ninety markers were integrated into 20 linkage groups. The remaining 21 microsatellites mapped to separate linkage groups, 19 with a precise cytogenetic position and two with only a chromosomal assignment. The genetic map spans 2766.6 cM and covers 20 rabbit chromosomes, excluding chromosomes 20, 21 and X. The density of this map is limited, but we used it to verify the location of angora and albino on chromosomes 15q and 1q, respectively, in agreement with previously published data. This first generation genetic/cytogenetic map will help gene identification and quantitative trait loci mapping projects in rabbit.

Mapping of rabbit chromosome 1 markers generated from a microsatellite-enriched chromosome-specific library

A genomic DNA library was produced from flow-sorted rabbit chromosome 1 and enriched for fragments containing CA-repeats. Clones containing CA-repeats were identified and primers for amplification of the microsatellite were developed after sequencing the clone. The degree of polymorphism was tested in rabbits from different breeds. This approach identified 12 microsatellite markers which could be used for studying linkage relationships in the progeny of an F(2)-intercross: (AX/JUxIIIVO/JU) F(2), and two backcrosses: (OS/JxX/J)X/J and (WH/JxX/J)X/J. Seven of these markers were mapped on chromosome 1.

Nuclear protein-binding sites in a transcriptional control region of the rabbit alpha-globin gene

The 5'-flanking and internal regions of the rabbit alpha-globin gene, which constitute a CpG island, are required for enhancer-independent expression in transfected cells. In this study, electrophoretic mobility shift assays revealed that a battery of nuclear proteins from both erythroid and nonerythroid cells bind specifically to these regulatory regions. Assays based on exonuclease III digestion, methylation interference, and DNase I footprinting identified sequences bound by proteins in crude nuclear extracts and by purified transcription factor Sp1. In the 5' flank, recognition sites for the transcription factors alpha-IRP (positions -53 to -44 relative to the cap site), CP1 (-73 to -69), and Sp1 (-95 to -90) are bound by proteins in K562 cell nuclear extracts, as are three extended upstream regions. Two recognition sites for Sp1 in intron 1 are also bound both by proteins in crude nuclear extracts and by purified Sp1. The sequences CCAC in intron 2 and C5 in the 3'-untranslated region also bind proteins. A major binding site found in exon 1, TATGGCGC, matches in sequence and methylation interference pattern the binding site for nuclear protein YY1, and binding is inhibited through competition by YY1-specific oligonucleotides. The protein-binding sites flanking and internal to the rabbit alpha-globin gene may form an extended promoter.

Nuclear protein-binding sites in a transcriptional control region of the rabbit alpha-globin gene

The 5'-flanking and internal regions of the rabbit alpha-globin gene, which constitute a CpG island, are required for enhancer-independent expression in transfected cells. In this study, electrophoretic mobility shift assays revealed that a battery of nuclear proteins from both erythroid and nonerythroid cells bind specifically to these regulatory regions. Assays based on exonuclease III digestion, methylation interference, and DNase I footprinting identified sequences bound by proteins in crude nuclear extracts and by purified transcription factor Sp1. In the 5' flank, recognition sites for the transcription factors alpha-IRP (positions -53 to -44 relative to the cap site), CP1 (-73 to -69), and Sp1 (-95 to -90) are bound by proteins in K562 cell nuclear extracts, as are three extended upstream regions. Two recognition sites for Sp1 in intron 1 are also bound both by proteins in crude nuclear extracts and by purified Sp1. The sequences CCAC in intron 2 and C5 in the 3'-untranslated region also bind proteins. A major binding site found in exon 1, TATGGCGC, matches in sequence and methylation interference pattern the binding site for nuclear protein YY1, and binding is inhibited through competition by YY1-specific oligonucleotides. The protein-binding sites flanking and internal to the rabbit alpha-globin gene may form an extended promoter.

Sequence and comparative analysis of the rabbit alpha-like globin gene cluster reveals a rapid mode of evolution in a G + C-rich region of mammalian genomes

A sequence of 10,621 base-pairs from the alpha-like globin gene cluster of rabbit has been determined. It includes the sequence of gene zeta 1 (a pseudogene for the rabbit embryonic zeta-globin), the functional rabbit alpha-globin gene, and the theta 1 pseudogene, along with the sequences of eight C repeats (short interspersed repeats in rabbit) and a J sequence implicated in recombination. The region is quite G + C-rich (62%) and contains two CpG islands. As expected for a very G + C-rich region, it has an abundance of open reading frames, but few of the long open reading frames are associated with the coding regions of genes. Alignments between the sequences of the rabbit and human alpha-like globin gene clusters reveal matches primarily in the immediate vicinity of genes and CpG islands, while the intergenic regions of these gene clusters have many fewer matches than are seen between the beta-like globin gene clusters of these two species. Furthermore, the non-coding sequences in this portion of the rabbit alpha-like globin gene cluster are shorter than in human, indicating a strong tendency either for sequence contraction in the rabbit gene cluster or for expansion in the human gene cluster. Thus, the intergenic regions of the alpha-like globin gene clusters have evolved in a relatively fast mode since the mammalian radiation, but not exclusively by nucleotide substitution. Despite this rapid mode of evolution, some strong matches are found 5' to the start sites of the human and rabbit alpha genes, perhaps indicating conservation of a regulatory element. The rabbit J sequence is over 1000 base-pairs long; it contains a C repeat at its 5' end and an internal region of homology to the 3'-untranslated region of the alpha-globin gene. Part of the rabbit J sequence matches with sequences within the X homology block in human. Both of these regions have been implicated as hot-spots for recombination, hence the matching sequences are good candidates for such a function. All the interspersed repeats within both gene clusters are retroposon SINEs that appear to have inserted independently in the rabbit and human lineages.

Gene mapping in marsupials: detection of an ancient autosomal gene cluster

The genes HRAS, HBB, and CAT, which are located together on the short arm of human chromosome 11, appear to be part of a conserved synteny group found in many eutherian mammals. These genes were mapped to the chromosomes of two marsupial (metatherian) species by in situ hybridization. All three genes were located together on chromosome 3 in Macropus eugenii. Only HRAS and CAT were used to probe Dasykaluta rosamondae metaphases and these genes both mapped to chromosome 4. This suggests that the HRAS-HBB-CAT gene cluster has been conserved at least since the metatherians and eutherians diverged some 130 million years ago. These findings support the concept of a mammalian genome that has remained highly conserved throughout evolution.

Localization of the alpha-like globin gene cluster to region q12 of rabbit chromosome 6 by in situ hybridization

The rabbit (Oryctolagus cuniculus) alpha-like globin gene cluster (HBAC) contains several block duplications of zeta-, alpha and theta-globin genes. Using in situ hybridizations to metaphase chromosome spreads, the gene cluster has been mapped to region q12 of chromosome 6. Given that human HBAC maps to the short arm of chromosome 16, the mapping of rabbit HBAC to 6q12 confirms the assignment of homology between OCU6q and HSA16p based on similarities of chromosomal banding patterns. In both species, HBAC is in a very G + C-rich region within the most distal band of the chromosome.