Chromosomal localization of the mouse prealbumin gene (Ttr) by in situ hybridization.

Prealbumin is a serum protein which plays an important role in plasma transport of retinol and thyroxine. The accumulation of a variant prealbumin is associated with a hereditary disorder, familial amyloidotic polyneuropathy (FAP). In situ hybridization with a mouse prealbumin gene cDNA probe was carried out in mouse fibroblasts. Analysis of 114 R-banded metaphases showed that 13% of the total grains were located on chromosome 4 and 46% of the grains on this chromosome were in the region C6-D1. Linkage and syntenic group analysis showed that the prealbumin gene (Ttr) is located between two syntenic groups on mouse chromosome 4, which corresponded to two syntenic groups present on human chromosomes 1 and 9.     

Linkage and physical mapping of prolactin to porcine chromosome 7

Comparative mapping studies between human and pig have shown that there is conserved synteny between human chromosome 6 and pig chromosomes 1 and 7, but some gene locations are not well established. Prolactin ( PRL ), an anterior pituitary hormone, has been mapped to human chromosome 6, and has tentatively mapped to pig chromosome 7 using Southern-RFLP analysis with a limited number of meioses. To confirm the assignment of prolactin to porcine chromosome 7 by physical and linkage analysis, pig cDNA and human genomic DNA sequences were used to design pig-specific PCR primers. The primers amplified a fragment of ≈2·8 kb. Two polymorphic restriction sites were identified within this fragment with the restriction endonuclease Bst UI. Prolactin was significantly linked to six markers on the published PiGMaP map of pig chromosome 7. Prolactin was physically mapped using a pig × rodent somatic cell hybrid panel. An analysis of these data placed PRL on pig 7p1·1–p1·2 with 100% concordance and was in complete agreement with the linkage data. Both mapping techniques placed PRL in a conserved order with the loci in the syntenic region of human chromosome 6.     

Analysis of allele segregation distortion in a swine resource family

Segregation distortion of alleles was found in several regions of the genome in allele type analyses of genetic markers for a swine resource family that had been constructed by crossing G?ttingen miniature pig and Meishan breeds. From these regions, a region on chromosome 6 presented a distortion over several consecutive markers. This chromosome 6 region was subsequently further investigated to reveal that alleles of a chromosome 6 homologue of the Gottingen miniature pig were not found in a homozygous family member. The litter size of F1-crosses which were able to produce homozygotes in this region were 24% smaller, on average, than F1-crosses which were unable to produce homozygotes. This indicated that this region of the chromosome 6 homologue contained a recessive gene or genes which could terminate fetal development. An additional 10 markers were subsequently used to investigate the region more precisely. These studies revealed that this region spans 7 cM and is located between markers Sw855 and Sw122. Since current comparative maps show that this region corresponds to the human chromosome 19 q-arm, genes positioned on the human chromosome 19 q-arm were screened to select 20 candidate genes. These included the pregnancy-specific beta-1-glycoprotein gene.     

Physical assignments of human chromosome 13 genes on pig chromosome 11 demonstrate extensive synteny and gene order conservation between pig and human

Previous mapping between the human and pig genomes suggested extensive conservation of human chromosome 13 (HSA13) to pig chromosome 11 (SSC11). The objectives of this study were comparative gene mapping of pig homologs of HSA13 genes and examining gene order within this conserved synteny group by physical assignment of each locus. A detailed HSA13 to SSC11 comparison was chosen since the comparative gene map is not well developed for these chromosomes and a rearranged gene order within conserved synteny groups was observed from the comparison between HSA13 and bovine chromosome 12 (BTA12). Heterologous primers for PCR were designed and used to amplify pig homologous fragments. The pig fragments were sequenced to confirm the homology. Six pig STSs (FLT1, ESD, RB1, HTR2A, EDNRB, and F10) were physically mapped using a somatic cell hybrid panel to SSC11, and fluorescent in situ hybridization (FISH) mapping was also applied to improve map resolution and determine gene order. Results from this study increase the comparative information available on SSC11 and suggest a conserved gene order on SSC11 and HSA13, in contrast to human:bovine comparisons of this syntenic group.     

Assignment of the gene for porcine insulin-like growth factor 1 (IGF1) to chromosome 5 by linkage mapping

Investigation of published sequence data from the porcine insulin-like growth factor 1 (IGF1) gene, resulted in the detection of a microsatellite in the first intron of the gene. Polymerase chain reaction (PCR) primers flanking the (CA)₁₉ repeat were constructed. Polymorphism and Mendelian segregation were documented in a three-generation pedigree and allele frequencies were determined in 74 unrelated animals from four different breeds. Seven alleles were encountered. Linkage analysis was performed in a large pedigree established for gene mapping. Linkage between the IGF1 microsatellite and an anonymous microsatellite marker, S0005, was detected. Furthermore, IGF1 and S0005 was found to be linked to the porcine submaxillary gland mucin (MUC) gene, previously assigned to chromosome 5. The results presented here extend the linkage group on pig chromosome 5 and are in accordance with conserved synteny between human chromosome 12, cattle chromosome 5, mouse chromosome 10 and pig chromosome 5.     

Localization of the KRAS2 oncogene in the domestic rabbit (Oryctolagus cuniculus)

The KRAS2 gene was localized in the rabbit by chromosomal in situ hybridization, using a 3H-labeled human cDNA probe. There were 201 silver grains on 144 metaphase spreads; 12.9% of the grains resided on chromosome 16, and 54% of these grains were located close to the centromere at 16p11----q11. Statistical analysis indicated that labeling at this region represents a significant deviation from a random distribution and thus provided evidence for the assignment of KRAS2 to 16p11----q11. In addition to the predominant labeling site on 16, there was a positive signal at the telomere of 9q, possibly representing a sequence of another member of the ras family. Our assignment of KRAS2 to rabbit chromosome 16 strengthens the argument that a fragment on this chromosome is homologous to one on human chromosome 12, which bears the KRAS2 locus.     

Localization on pig chromosome 6 of markers GPI, APOE, and ENO1, carried by human chromosomes 1 and 19, using in situ hybridization

In the pig, the linkage group around the halothane gene (HAL), composed of S-GPI-HAL-H-A1BG-PGD, has been assigned to bands p1.2----q2.2 of chromosome 6. In man, ENO1-PGD and APOE-GPI constitute two syntenic groups situated on different chromosomes (1 and 19, respectively). Since GPI and PGD are linked in the pig, we have hybridized the human cDNA probes for ENO1 and APOE to pig chromosomes. These markers were assigned to pig chromosome 6, in the q2.2----q2.4 and cen----q2.1 regions, respectively, using in situ hybridization. Since GPI and APOE are situated in the same region, we combined the use of high resolution chromosome analysis and in situ hybridization to give a more precise localization in the q1.2 and q1.2----q2.1.2 regions of chromosome 6. A possible linear order of these genes is proposed.     

Construction and analysis of an HN-cDNA library derived from the p-arm of pig Chromosome 12

Our aim is to find unidentified genes on specific pig chromosomes or chromosome fragments. Our approach has involved the construction of a heterogeneous nuclear complementary (hn-c) DNA library of the p-arm of pig Chromosome (Chr) 12, the only pig chromosome present in the pig × hamster hybrid cell line 8990. Total RNA was extracted from the cells and first-strand synthesis of hn-cDNA carried out with random and oligo dT primers. Pig hn-cDNA was isolated by amplification of first-strand synthesized hn-cDNA with primers specific for Short Interspersed Repeat Elements (SINEs) via the polymerase chain reaction (PCR). Hn-cDNAs were size selected and cloned in E. coli XL-1 blue cells with PCR-Script as the vector. The library consisted of 6000 clones. Clone inserts were amplified by PCR with vector-specific primers, and randomly picked inserts greater than 600 bp were sequenced. Homology searches were carried out with the FASTA search program on the GenEmbl database. Thirty clones were sequenced, and of these three showed strong homologies to GenEmbl sequences: (1) to sheep, mouse, human, and rat mammary gland factor (MGF); (2) to MLN-50, a gene that is amplified in human familial breast cancer and is present on human Chr 17; the latter is homologous to pig chromosome 12; (3) to a family of unassigned overlapping human ESTs. Of the other sequenced clones, seven were over 80% homologous with pig SINE sequences; three were over 75% homologous to human LINE sequences; six displayed open reading frames over a mean distance equivalent to 50 amino acids, although these showed no significant similarities with sequences in the databases. Using this approach, we have been able to identify several new genes on the p-arm of pig Chr 12. This is the first report of gene isolation from a library derived from a pig chromosome fragment. Received: 9 February 1996 / Accepted: 14 May 1996     

A gene on pig chromosome 14 suppresses cellular anchorage independence of the mouse cell line GM05267.

We have generated pig-mouse somatic cell hybrids by fusing normal pig fibroblasts with an anchorage independent mouse cell line GM05267. High quality G-banding analysis was applied to a set of 18 hybrid cell lines derived from 15 independent hybrids and chromosomes were identified. Cytogenetic analysis showed that all hybrids contained one or several pig chromosomes with normal morphology devoid of any structural changes. Out of 18 hybrids tested for colony formation in soft agar, 15 were suppressed for anchorage independence while the remaining three were not suppressed. Correlation of the cellular phenotype with the pig chromosome content of the hybrids suggests that the suppressor function for anchorage independence is located on pig chromosome (SSC) 14. We have previously shown that a suppressor gene for anchorage independence (SAI1) is located on rat chromosome (RNO) 5 and another suppressor gene for the same phenotype is located on human chromosome (HSA) 9. Given the genetic homology of both RNO5 and HSA9 with two pig chromosomes including SSC14, the third suppressor gene we have mapped on SSC14 may well be a functional homologue of the previously identified rat and human genes.     

Regional mapping of the human renin gene to 1q32 by in situ hybridization

Renin, related to other aspartyl proteases, plays an important role in the cascade which regulates blood pressure and salt metabolism. A human renin 1 100 bp long cDNA including most of the coding region and the 3' non coding region has been subcloned by Soubrier et al., 1983. A 1000 b RNA probe derived by subcloning into pSP64 vector was hybridized to EcoRI and HindIII digests of the DNA of a panel of 24 man-rodent somatic cell hybrids. With HindIII, four restriction fragments were observed, two of them revealing polymorphism (8.4 kb and 6.0 kb). Analysis of the distribution of the human signal among the hybrids confirms the localization of the renin gene (REN) to human chromosome 1. The whole plasmid including the 1 100 bp long insert was used for regional mapping by in situ hybridization; 45% of silver grains were found on chromosome 1, with a clear peak at band 1q32 (33% of silver grains on chromosome 1) and a smaller one at band 1q42 (17%). These data favour a regional localization of the renin gene to 1q32-1q42. Mac Gill et al. (1987) have localized the REN gene to 1q25-1q32 using in situ hybridization. Thus, 1q32 could be the most probable localization. No other peak could be observed. This is in agreement with results obtained with somatic cell hybrids.     

Mapping of growth hormone releasing hormone receptor to swine chromosome 18

The growth hormone releasing hormone receptor (GHRHR) was mapped in the pig for study as a potential candidate gene in controlling pig quantitative growth and carcass characteristics. Primers were designed from the pig GHRHR sequence to amplify a 1·65-kb intronic fragment between exons 6 and 7. By using a pig–rodent somatic cell hybrid panel, GHRHR was mapped to pig chromosome 18 (SSC18) with 100% concordance, and the regional assignment was SSC18q24 with 89% concordance. The polymerase chain reaction–restriction fragment length polymorphisms (PCR–RFLPs) with Mse I and Taq I were developed to confirm this assignment with linkage analysis by using the European Pig Gene Mapping Project (PiGMaP) reference families. Pig GHRHR was mapped with strong linkage to SSC18 markers S0062 and S0120 (lod > 8). The GHRHR and IGFBP3 were found to map near to each other on human chromosome 7 (HSA7), and the pig IGFBP3 gene has been mapped to SSC18 by others. Our mapping of pig GHRHR increases the comparative information available on the SSC18 maps and further confirms the synteny conservation between HSA7 and SSC18.     

Regional localisations of VIM, HSD3b, ACTA1 and PGM1 in pigs

The comparative map between human and pig has progressed rapidly over the past 2 years. Nevertheless, some points still need to be clarified, particularly the correspondences between human chromosome 10 (HSA10) and porcine chromosome 10 (SSC10) and between human chromosome 1 (HSA1) and porcine chromosomes. The gene codings for vimentin (VIM) carried by HSA10 and three genes carried by HSA1 (hydroxy delta 5 steroid dehydrogenase 3 beta: HSD3B; alpha actin 1: ACTA1; and phosphoglucomutase 1: PGM1) were selected and the regional localisations on pig chromosomes were determined using a well-characterised somatic cell hybrid panel.     

Improving the comparative map of SSC2p-q13 by sample sequencing of BAC clones

To improve the comparative map for pig chromosome 2 and increase the gene density on this chromosome, a porcine bacterial artificial chromosome (BAC) library was screened with 17 microsatellite markers and 18 genes previously assigned to pig chromosome 2. Fifty-one BAC clones located in the region of a maternally imprinted quantitative trait locus for backfat thickness (BFT) were identified. From these BACs 372 kb were sample sequenced. The average read length of a subclone was 442 basepair (bp). Contig assembly analysis showed that every bp was sequenced 1.28 times. Subsequently, sequences were compared with sequences in the nucleotide databases to identify homology with other mammalian sequences. Sequence identity was observed with sequences derived from 35 BACs. The average percentage identity with human sequences was 87.6%, with an average length of 143 bp. In total, sample sequencing of all BACs resulted in sequence identity with 29 human genes, 13 human expressed sequence tags (ESTs), 17 human genomic clones, one rat gene, one porcine gene and nine porcine ESTs. Eighteen genes located on human chromosome 11 and 19, and seven genes from other human locations, one rat gene and one porcine gene were assigned to pig chromosome 2 for the first time. The new genes were added to the radiation hybrid map at the same position as the locus from which the BAC that was sequenced was derived. In total 57 genes were placed on the radiation hybrid map of SSC2p-q13.     

Assignment of 12 loci to rat chromosome 5: evidence that this chromosome is homologous to mouse chromosome 4 and to human chromosomes 9 and 1 (1p arm)

Twelve loci have been assigned to rat chromosome 5: aldolase B (ALDOB), atrial natriuretic factor (ANF = pronatriodilatin, PND), D4RP1, DSI1, galactosyltransferase (GGTB2), glucose transporter (GLUT1), interferon alpha 1 and related interferon alpha (INFA), interferon beta (INFB), lymphocyte-specific protein-tyrosine kinase (LCK), oncogene MOS, alpha 2U-globulin (major urinary protein, MUP), and orosomucoid (ORM, also called alpha 1-acid glycoprotein, AGP). Among these, the interferon alpha and beta genes map in the q22-23 region, which also contains a transformation suppressor gene (SAI1). The other loci reside outside this region. This study also indicated that the rat genome contains 2 LCK genes, unlike the human and murine genomes. These new assignments on rat chromosome 5 demonstrate that this chromosome is highly homologous to mouse chromosome 4 and carries synteny groups conserved on human chromosome 9 (interferon alpha and beta, galactosyltransferase, orosomucoid, and aldolase B genes) and on the short arm of human chromosome 1 (MYCL, glucose transporter, protein kinase LCK, and atrial natriuretic factor genes).     

Linkage of the evolutionarily-related serum albumin and alpha-fetoprotein genes within q11-22 of human chromosome 4

Albumin and alpha-fetoprotein are structurally related serum proteins, having a similar gene structure and, conceivably, a common evolutionary origin. To test their relative arrangement in the human genome, the serum albumin and alpha-fetoprotein genes were mapped by in situ hybridization of cloned human albumin or alpha-fetoprotein cDNA to human mitotic chromosome preparations. Analysis of cells hybridized with the serum albumin probe showed that 39% of cells exhibited grains on the proximal portion of the long arm of chromosome 4 (bands q11-22), with these grains comprising 30% of all labeled sites throughout these mitoses. Similarly, in cells hybridized with the alpha-fetoprotein probe, 39% of cells were observed to contain silver grains on 4q11-22, these grains constituting 20% of all labeled sites in these cells. These results demonstrate chromosomal localization and linkage of the serum albumin and alpha-fetoprotein genes within bands q11-22 of the long arm of human chromosome 4.     

Human beta interferon gene localization and expression in somatic cell hybrids.

The human fibroblast interferon gene beta 1 was mapped to human chromosome 9. Sequence homology with a beta 1 cDNA clone was detected in both genomic DNA and induced mRNA of human/mouse or human/hamster somatic cell hybrids containing human chromosome 9, but not in lines lacking this chromosome or those retaining a complex translocation involving chromosomes 9 and 11. Interferon mRNA that did not share sequence homology with the beta 1 cDNA clone was detected in lines containing human chromosomes 2 and 5 but lacking chromosome 9, suggesting the presence of other unlinked interferon sequences in the human genome.     

Localization of the pig luteinizing hormone/choriogonadotropin receptor gene (LHCGR) by radioactive and nonradioactive in situ hybridization.

The porcine gene for luteinizing hormone/choriogonadotropin receptor (LHCGR) was localized to chromosome 3q2.2----q2.3 using radioactive and nonradioactive in situ hybridization. A computer-assisted image-analysis system was developed which facilitated detection of the position of silver grains and fluorescent spots on the chromosomes after in situ hybridization. Compared with autoradiographic visualization, the nonisotopic procedure proved to be more rapid, precise, and highly specific; however, nonradiographic in situ hybridization was much less efficient than the autoradiographic technique for the detection of unique DNA sequences with small probes. From these results and published gene-mapping data, it was concluded that the synteny between LHCGR and MDH1 observed in man is conserved in the pig genome.