Genetic analysis of the gene for porcine submaxillary gland mucin: physical assignment of the MUC and interferon gamma genes to chromosome 5

The complete cDNA sequence and structural polymorphism of the polypeptide chain of porcine submaxillary mucin

The complete structure of the DNA encoding the polypeptide chain of porcine submaxillary mucin has been determined. The polypeptide is composed of distinct domains. A large central domain containing tandem repeats of 81 residues each is flanked by much shorter domains with sequences similar to the tandem repeats. Four disulfide-rich domains, three at the amino terminus and one at the carboxyl terminus, complete the chain. The disulfide-rich domains have significant sequence identity to those of other mucins and prepro-von Willebrand factor. The coding region of the mucin gene is highly polymorphic, and three alleles were identified in a single animal that encoded different numbers of the 81-residue tandem repeats. A single large exon devoid of introns encodes the tandem repeat domains. The largest allele with 135 tandem repeats encoded 13,288 amino acids to give a polypeptide with Mr = 1,184,106. The other two alleles contained 99 and 125 tandem repeats, respectively. Each allele also showed different restriction fragment length polymorphisms, which is consistent with the different patterns seen in individual animals. Fragment length polymorphism was also seen within two different families of animals, indicating that the polymorphism observed occurs in a single generation.

FISH mapping of seven cDNA sequences in the pig

Fluorescence in situ hybridization (FISH) technique was applied to localize seven clones derived from a porcine (SSC) intestinal directionally cloned cDNA library. The size of the clones ranged from 1.1 to 1.3 kb. Three of the clones corresponded to histidyl-tRNA synthetase (HARS), immunoglobulin alpha (IGA) and lysozyme (LYZ) and mapped to SSC2q28-q29, 7q2.6 and 5p11 respectively. The available human-pig comparative painting data and sequence homology comparisons assisted in a tentative identification of the other three clones as glutathione-S-transferase (GST), glutathione-S-transferase mu (GSTM1) and immunoglobulin lambda gene cluster (IGL@). These clones mapped to SSC14q21, 5q2.4 and 14q22-q23 respectively. The remaining clone representing an EST mapped to 1p24-p25. These localizations contribute to the transcript map in pig and are significant as comparative markers. Difficulties associated with the mapping of small sequences using FISH are discussed.

A comprehensive map of the porcine genome

We report the highest density genetic linkage map for a livestock species produced to date. Three published maps for Sus scrofa were merged by genotyping virtually every publicly available microsatellite across a single reference population to yield 1042 linked loci, 536 of which are novel assignments, spanning 2286.2 cM (average interval 2.23 cM) in 19 linkage groups (18 autosomal and X chromosomes, n = 19). Linkage groups were constructed de novo and mapped by locus content to avoid propagation of errors in older genotypes. The physical and genetic maps were integrated with 123 informative loci assigned previously by fluorescence in situ hybridization (FISH). Fourteen linkage groups span the entire length of each chromosome. Coverage of chromosomes 11, 12, 15, and 18 will be evaluated as more markers are physically assigned. Marker-deficient regions were identified only on 11q1.7-qter and 14 cen-q1.2. Recombination rates (cM/Mbp) varied between and within chromosomes. Short chromosomal arms recombined at higher rates than long arms, and recombination was more frequent in telomeric regions than in pericentric regions. The high-resolution comprehensive map has the marker density needed to identify quantitative trait loci (QTL), implement marker-assisted selection or introgression and YAC contig construction or chromosomal microdissection.

The PiGMaP consortium linkage map of the pig (Sus scrofa)

A linkage map of the porcine genome has been developed by segregation analysis of 239 genetic markers. Eighty-one of these markers correspond to known genes. Linkage groups have been assigned to all 18 autosomes plus the X Chromosome (Chr). As 69 of the markers on the linkage map have also been mapped physically (by others), there is significant integration of linkage and physical map data. Six informative markers failed to show linkage to these maps. As in other species, the genetic map of the heterogametic sex (male) was significantly shorter (approximately 16.5 Morgans) than the genetic map of the homogametic sex (female) (approximately 21.5 Morgans). The sex-averaged genetic map of the pig was estimated to be approximately 18 Morgans in length. Mapping information for 61 Type I loci (genes) enhances the contribution of the pig gene map to comparative gene mapping. Because the linkage map incorporates both highly polymorphic Type II loci, predominantly microsatellites, and Type I loci, it will be useful both for large experiments to map quantitative trait loci and for the subsequent isolation of trait genes following a comparative and candidate gene approach.

Linkage maps of porcine chromosomes 3, 6, and 9 based on 31 polymorphic markers

Linkage maps of porcine Chromosomes (Chrs) 3, 6, and 9, based on 31 polymorphic markers, are reported. The markers include 14 microsatellites, 12 RFLPs, three protein polymorphisms, and two blood group loci. The genetic interpretations of 11 RFLPs are documented. The markers were scored in a three-generation Wild Boar/Large White pedigree, and genetic maps were constructed on the basis of two-point and multi-point linkage analysis. Altogether the maps span a genetic distance of 216 cM, and previous physical assignments indicate that the linkage groups cover major parts of the three chromosomes. Significant differences in recombination rates between the sexes were observed for all three chromosomes. The recombination rate on the q arm of Chr 6 was markedly low. Sixteen loci are informative with regard to comparative mapping, that is, they have previously been mapped in the human and/or mouse genomes.

Genetic variation at pig plasma protein locus PLP1 and its assignment to chromosome 5

A new genetic polymorphism of an unidentified plasma protein (PLP1) in pigs was described by using a method of two-dimensional gel electrophoresis and protein staining. Two codominant alleles, with frequencies of 0.83 and 0.17, were found in the Swedish Yorkshire breed. The PLP1 marker was typed in a three-generation pedigree and tested for linkage against a set of 128 markers. The PLP1 locus showed significant LOD score values with three different microsatellite markers (S0092, DAGK and S0005), previously assigned to chromosome 5.

Mapping of the pig genome

The past year has seen major developments in both the genetic (linkage) and physical maps of the porcine genome. Landmark loci have been established on all pig chromosomes and outline genetic maps have been elaborated. The use of pigs as models of human genetic diseases is likely to expand through the use of transgenic pigs.

Variable SINE 3' poly(A) sequences: an abundant class of genetic markers in the pig genome

Previous studies on human DNA have shown that the 3' poly(A) tracts of Alu elements may display considerable genetic polymorphism. To explore whether this marker type is generally applicable in mammalian genomes, I analyzed porcine SINEs. A database screening revealed 17 porcine sequences with significant homology to a previously identified pig SINE. The occurrence in the database suggested a SINE frequency of one copy every 12 kb of pig DNA. All SINEs contained a 3' poly(A) tract with an average of 12 uninterrupted adenines. The repetitive regions were analyzed for polymorphism by locus-specific PCR amplification. Allelic length variation (two to five alleles among 10 pigs) was found at 8 out of 10 loci investigated, in most cases probably because of varying number of iterated adenine residues. There was a positive relationship between repeat length and the degree of polymorphism. Stable Mendelian inheritance was documented in 200 meioses each at four loci. The high genomic frequency of SINEs implies that a potentially informative marker may be found near any gene or in any cosmid clone. These SINE 3' poly(A) polymorphisms, termed SINEVA [SINE variable poly(A)s], thus provide an abundant and useful class of genetic marker in mammalian genomes.