Chromosomal assignment of retinoic acid receptor (RAR) genes in the human, mouse, and rat genomes.

The human genes encoding the alpha and beta forms of the retinoic acid receptor are known to be located on chromosomes 17 (band q21.1:RARA) and 3 (band p24:RARB). By in situ hybridization, we have now localized the gene for retinoic acid receptor gamma, RARG, on chromosome 12, band q13. We also mapped the three retinoic acid receptor genes in the mouse, by in situ hybridization, on chromosomes 11, band D (Rar-a); 14, band A (Rar-b); and 15, band F (Rar-g), respectively, and in the rat, using a panel of somatic cell hybrids that segregate rat chromosomes, on chromosomes 10 (RARA), 15 (RARB), and 7 (RARG), respectively. These assignments reveal a retention of tight linkage between RAR and HOX gene clusters. They also establish or confirm and extend the following homologies: (i) between human chromosome 17, mouse chromosome 11, and rat chromosome 10 (RARA); (ii) between human chromosome 3, mouse chromosome 14, and rat chromosome 15 (RARB); and (iii) between human chromosome 12, mouse chromosome 15, and rat chromosome 7 (RARG).     

Chromosomal mapping of the mouse IL-4 and human IL-5 genes

We mapped the mouse interleukin (IL)-4 gene on chromosome 11 by restriction fragment length polymorphism using recombinant inbred mouse strains. The human IL-5 gene was mapped on chromosome 5q 23.3-31.1 by in situ hybridization. Because the granulocyte macrophage colony-stimulating factor (GM-CSF) and IL-3 genes were previously mapped on mouse chromosome 11 (within a 230-kb region) and human chromosome 5, the IL-4 and IL-5 genes are likely to cluster on the same chromosomes with the GM-CSF and IL-3 genes in both species.     

Localization of the tumour protein, TP53, on porcine chromosome 12q12-q14

A human cDNA probe of the tumour protein p53 (TP53) was used to localize the homologous porcine gene by in situ hybridization. The gene was mapped to chromosome 12q12-q14. Together with already known mapping data, these results confirm the localization of an evolutionary conserved linkage group on porcine chromosome 12 which is localized in man on chromosome 17, in cattle on chromosome 19, and in mice on chromosome 11.     

Molecular cloning of the porcine inhibin-betaB gene and reassignment to chromosome 15

Inhibins are gonadal glycoproteins belonging to the transforming growth factor-beta superfamily that act to suppress pituitary follicle stimulating hormone and are composed of a common alpha-subunit linked by disulphide bonds to either a betaA- or betaB-subunit. The porcine inhibin-alpha, -betaA (INHBA) and -betaB (INHBB) subunit genes have previously been mapped to chromosomes 15, 18 and 12, respectively. Over 6.7 kb of the INHBB gene was sequenced from a porcine genomic cosmid clone and found to contain two microsatellites, one in intron 1 and the other in the 3'-untranslated region. Both microsatellites mapped to pig chromosome 15 at relative position 48 cm. This sequence was greater than 99% identical to two previously reported partial non-contiguous cDNAs for porcine INHBB. Non-coding regions also had a high degree (79-88%) of identity with the corresponding regions of the human gene. Based on sequence information and mapping of two novel microsatellite markers, we reassigned porcine INHBB to chromosome 15, which is consistent with comparative physical and linkage maps of this chromosome and human chromosome 2.     

Characterization of the porcine FABP5 gene and its association with the FAT1 QTL in an Iberian by Landrace cross

We have characterized and mapped the porcine fatty acid binding protein 5, epidermal (FABP5) gene. According to linkage and RH mapping, this gene is located close to the FABP4 (fatty acid binding protein 4, adipocyte) gene on swine chromosome 4. We resequenced 4.7 kb of the FABP5 gene in the parental population of an Iberian x Landrace cross (IBMAP), identifying seven SNPs arranged in two distinct FABP5 haplotypes. QTL and association analyses in the IBMAP population showed that this gene is strongly associated with fat deposition. QTL and haplotype analysis revealed that both FABP4 and FABP5 (clustered in mammals) are major candidate genes for the FAT1 QTL; the most likely position for the FAT1 QTL is between these two genes. Finally, our results suggest the presence of more than one QTL affecting fatness traits on porcine chromosome 4.     

Comparative mapping of a region on chromosome 10 containing QTL for reproduction in swine

Several quantitative trait loci (QTL) for important reproductive traits (age of puberty, ovulation rate, nipple number and plasma FSH) have been identified on the long arm of porcine chromosome 10. Bi-directional chromosome painting has shown that this region is homologous to human chromosome 10p. Because few microsatellite or type I markers have been placed on SSC10, we wanted to increase the density of known ESTs mapped in this region of the porcine genome. Genes were chosen for their position on human chromosome 10, sequence availability from the TIGR pig gene indices, and their potential as a candidate gene. The PCR primers were designed to amplify across introns or 3'-UTR to maximize single nucleotide polymorphism (SNP) discovery. Parents of the mapping population (one sire and seven dams) were amplified and sequenced to find informative markers. The SNPs were genotyped using primer extension and mass spectrometry. These amplification products were also used to probe a BAC library (RPCI-44, Roswell Park Cancer Institute) for positive clones and screened for microsatellites. Six genes from human chromosome 10p (AKR1C2, PRKCQ, ITIH2, ATP5C1, PIP5K2A and GAD2) were mapped in the MARC swine mapping population. Gene order was conserved within these markers from centromere to telomere of porcine chromosome 10q, as compared with human chromosome 10p. Four of these genes (PIP5K2A, ITIH2, GAD2 and AKR1C2), which map under QTL, are potential candidate genes. Identification of porcine homologues near important QTL and development of a comparative map for this chromosome will allow further fine- mapping and positional cloning of candidate genes affecting reproductive traits.     

The structure of a conserved region of porcine genome, represented in human genome by chromosome 17

Radiation mapping of nine genes (H3F3B, HLR1, MYL4, STAT5B, THRA1, TOP2A, MCP1, NF1, and MPO) to porcine chromosome 12 was carried out. Also, subchromosomal location of the NF1 gene along with the two loci containing the DNA sequences homologous to the DNA of the two human BAC clones was determined. The NF1 position was ascertained via microdissection of chromosome 12 with subsequent PCR amplification of the gene fragment with specific primers. BAC clones were mapped using FISH. Comparative analysis of the gene order in porcine chromosome 12 and in the homologous human chromosome 17 was performed. It was demonstrated that the gene orders in these chromosomes differed relative to the position of the MPO gene.     

Characterization, chromosomal localization, and genetic variation of the α subunit of porcine eighth component of complement

The complete amino acid sequence of the porcine a subunit of the eighth component of complement (C8A) was determined by characterizing the full length cDNA clone isolated from a porcine liver cDNA library. Porcine C8A was found to be similar to human and rabbit C8A in length, leader sequence, conserved cysteine residues, cysteine-rich modules, and overall sequence. Differences in the amino acid sequence among the three species were detected in the proposed candidate site for CD59 recognition (amino acids 352±389). The porcine C8A gene was physically mapped to chromosome 6q33±35 by in situ hybridization using the porcine bacterial artificial chromosome (BAC) clone as a hybridization probe. Polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) analysis of C8A was performed using the restriction enzyme Hha I. Distribution of the alleles was determined in pigs (n = 173) of several different breeds. Estimates of allele frequency of the 201 bp fragment were 0.22, . 0.43, . 0.04, . 0.50, . 0.58, . 0.50, . 0.98, and 0.91 in Landrace, Large White, Duroc, Berkshire, Jinhua, Crown Miniature Pig, wild boar, and Meishan, respectively.     

Polymerase chain reaction-based polymorphisms in the porcine cholecystokinin (CCK) gene and assignment to chromosome 13

Polymorphisms were identified in the porcine cholecystokinin (CCK) gene by digestion of products from polymerase chain reaction (PCR) with the restriction enzyme Dpn II. Individuals from the European pig gene mapping project (PiGMaP) consortium reference families (eight full-sib families, 91 total progeny) were genotype to determine linkage relationships between the CCK gene and previously mapped loci. Linkage analysis revealed that the CCK gene is located on porcine chromosome 13.     

A novel porcine gene,alpha-1-antichymotrypsin 2 (SERPINA3-2): sequence,genomic organization,polymorphism and mapping

A novel porcine gene, alpha-1-antichymotrypsin 2 (SERPINA3-2), a member of the serpin superfamily, was isolated from a porcine genomic library and sequenced. The genomic organization of the approximately 9.0 kb gene was determined on the basis of the porcine liver cDNA of SERPINA3-1 and SERPINA3-2, and comprises five exons and four introns. The coding sequence of SERPINA3-2 shares 86% identity with the paralogue, SERPINA3-1. Porcine SERPINA3-2 was found to be an orthologue of human SERPINA3 (71% identity of the coding sequences) and both genes have a similar genomic organization. Polymorphisms were found in intron 4 of the porcine gene using polymerase chain reaction-restriction fragment length polymorphism. The gene was mapped by linkage analysis and radiation hybrid mapping to the distal end of chromosome 7q, to the gene cluster of the protease inhibitors including PI1 (SERPINA1), PI2, PI3, PI4 (apparently paralogues of SERPINA3), and PO1A and PO1B. SERPINA3-2 is the first porcine serpin gene whose genomic organization has been determined.     

New insights into porcine-human synteny conservation

Eleven genes were mapped to the porcine genome with the aim of improving the human-porcine comparative gene map. Five of these genes were from regions of the human genome painted by porcine chromosomal probes; of these, two mapped to chromosomes not expected from the painting results. Among the six genes from human regions not painted by porcine chromosomal probes, three genes did not map where expected by the principle of parsimony. Several of the gene assignments indicate the existence of small regions of conserved synteny not detected by heterologous chromosome painting, especially in telomeric regions. We have also detected new rearrangements in gene order within the regions of correspondence between human Chromosome (HSA) 15 and porcine Chromosome (SSC) 1 as well as between HSA4 and SSC8. Received: 30 September 1998 / Accepted: 3 December 1998     

Comparative analysis of autosomes in karyotypes from pig and rabbit using RBG-banding and in situ hybridization

The chromosomal location of the porcine gene for glucose phosphate isomerase (GPI) was previously mapped to 6p 12----6q21 in the pig karyotype. The replication patterns and morphology of this chromosome are very similar to those of chromosome 14 in the rabbit karyotype. With combined in situ hybridization and RBG-band induction it was demonstrated that the porcine GPI-probe hybridized most frequently to 14p11----14q12 in the rabbit karyotype, indicating a close relationship between morphology, replication pattern and gene location.     

Genomic organization and assignment of the interleukin 7 gene (IL7) to porcine chromosome 4q11-->q13 by FISH and by analysis of radiation hybrid panels

Interleukin 7 (IL7) is a cytokine that has many immunological functions, including regulation of hematopoiesis and peripheral lymphocytes. cDNA and a genomic DNA segment containing the porcine IL7 gene were isolated and sequenced, showing that porcine IL7 consists of 176 amino acids and that its gene spans over about 13 kb of genomic DNA. Porcine IL7 has 85% and 73% homology with human IL7 in terms of the nucleotide and amino acid sequences, respectively. Whereas the murine IL7 gene does not have an exon corresponding to human exon 5 (Lupton et al., 1990), the porcine IL7 gene was found to contain the same exon-intron structure as the human gene. These findings, together with the upstream structure of the cDNA elucidated in the present study, indicate that the relationship between swine and human IL7 is closer than that between mouse and human IL7. The IL7 gene was mapped to swine chromosome 4q11-->q13 by fluorescence in situ hybridization and, using a radiation hybrid panel, was localized between microsatellite markers Sw1336 and Sw1073 on the same chromosome.     

Genomic organization and chromosomal location of the mouse vasoactive intestinal polypeptide 1 (VPAC1) receptor.

The gene encoding the mouse vasoactive intestinal polypeptide type 1 (VPAC1) receptor was cloned, and its structural organization was determined. The gene (Vipr1) is more than 16 kb in length and is divided into 13 exons. The 5'-flanking region is highly GC-rich and lacks an apparent TATA box, but contains a CCAAT box, three potential Sp1-binding sites, and two potential AP-2-binding sites. Promoter analysis of the 5'-flanking region of Vipr1 using a luciferase gene reporter system revealed that the isolated 5'-flanking region has functional promoter activity. The mouse Vipr1 gene is encoded by a single gene, which was mapped to the distal region of mouse chromosome 9. This region is syntenic with human chromosome 3p, where the human VPAC1 receptor gene has been mapped.     

The porcine gonadotropin-releasing hormone receptor gene (GNRHR): genomic organization, polymorphisms, and association with the number of corpora lutea.

The interaction of gonadotropin-releasing hormone (GNRH) and its receptor (GNRHR) is critical in the endocrine regulation of reproduction. The gene (GNRHR) encoding the receptor has been mapped to porcine chromosome 8. There is evidence for three quantitative trait loci (QTL) influencing ovulation rate on this chromosome. We obtained an almost complete sequence (3993 bp, excluding intron 1) of the porcine GNRHR gene using PCR-based comparative genomic walking and inverse genomic walking approaches. Twelve polymorphisms were detected by sequencing of pooled DNA of Chinese Taihu and European Large White pigs, including 7 base substitutions and 5 insertions-deletions (indels). A F2 population of Meishan x European Large White pigs was genotyped for a TG indel in the promoter region, and a C/G substitution in the 3' UTR (untranslated region). A significant association of the C/G substitution with number of corpora lutea at first parity was observed.     

The porcine TTR locus maps to chromosome 6q

The sequence of a cDNA clone encoding porcine transthyretin (prealbumin) was used to develop polymorphic markers for the TTR locus. The single-strand conformation polymorphism (SSCP) detected is caused by a silent AIT mutation in the penultimate coding codon and can also be revealed as a SacI restriction fragment length polymorphism (RFLP). The TTR locus was mapped to chromosome 6q by segregation and linkage analysis with these polymorphisms. This assignment confirms the predictions of homology between human chromosome 18 and pig chromosome 6q2.5-2.6.