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.     

Mapping genes located on human chromosomes 2 and 12 to porcine chromosomes 15 and 5

Informative microsatellites associated with two genes on HSA12 (lysozyme, LYZ; tumour necrosis factor receptor, TNFR) and one gene on HSA2 (glutamic acid decarboxylase 1, GAD1) were mapped in the US Meat Animal Research Center (MARC) swine reference population and the physical assignment of a-lactalbumin (LALBA) was determined. A comparative map for HSA2 and HSA12 with SSC15 and SSC5, respectively, was developed by combining the results from this study with published type I loci mapped in both species. One rearrangement between HSA2 and SSC15 was detected while the number of rearrangements between HSA12 and SSC5 were numerous. These results indicated that conservation of synteny does not imply a conservation of gene order and that additional type I markers need to be mapped in the pig to fully understand the chromosomal rearrangements that occurred during the evolution of mammals.     

猪核糖体蛋白基因RPLP0的cDNA全长、染色体定位和多态性分析

RPLP0基因编码酸性核糖体磷蛋白大亚基P0, 是核糖体60S亚基的组成成分之一。从本室构建的猪胚胎骨骼肌cDNA文库中分离得到猪RPLP0基因的全长cDNA,并提交 GenBank 数据库。比较猪 RPLP0 基因和人及小鼠同源基因的cDNA序列和蛋白质序列,结果表明该基因在 3 个物种中具有高的相似性。用 PCR-RFLP 方法在猪 RPLP0基因cDNA 545处检测到 C→A 的单碱基突变,为 Csp6Ⅰ的酶切位点。统计分析结果表明 3 种基因型 (AA,AC,CC)在外来品种杜洛克,大约克, 长白和中国地方品种通城猪,小梅山,玉山猪中的分布各不相同。同时使用体细胞杂种板(SCHP)和辐射杂种板(IMpRH) 对 RPLP0 基因进行染色体定位,该基因被定位于 SSC 14q22-q24 并且和SW1321微卫星标志紧密连锁 (25cR, LOD = 14.54)。     

Characterization of the PGK2 associated microsatellite S0719 on SSC7 suitable for parentage and QTL diagnosis

We isolated and characterized the highly polymorphic tetra-nucleotide microsatellite S0719 on SSC7q14-q15 adjacent to the porcine testis-specific phosphoglycerate kinase 2 (PGK2) gene and assigned it to the USDA-MARC linkage map on SSC7 position 77.5 cM closely linked to markers SW859 (76.3 cM) and SWR2036 (79.0 cM). In a panel of 344 individuals representing 11 pig breeds (European, Chinese, and North American), a total of 32 alleles were observed, and the overall breeds' calculated PIC (polymorphism information content), HE (heterozygosity), and NE (effective allele number) were 0.94, 0.94, and 16.41. Breed-specific PIC and HE ranged from 0.66 to 0.87, whereas NE was as low as 2.95 and as high as 7.96. Considering the high allelic variation of S0719 within and among pig breeds (79% of the genotyped animals were heterozygous), the marker is useful for individual animal identification and parentage determination. Finally, S0719 is also a valuable STS marker for fine-mapping QTL on SSC7 as position 77.5 cM is located in 25 QTL intervals.     

Detection of novel SNPs and mapping of the fatness QTL on pig chromosome 7q1.1-1.4 region

Many QTLs for fatness traits have been mapped on pig chromosome 7q1.1-1.4 in various pig resource populations. Eight novel markers, including seven SNPs and one insertion or deletion within BTNL1, COL21A1, PPARD, GLP1R, MDFI, GNMT, ABCC10, and PLA2G7 genes, as well as two previously reported SNPs in SLC39A7 and HMGA1 genes, were genotyped in Large White and Meishan pig breeds. Except for two SNPs in HMGA1 and ABCC10 genes, allele frequencies of the other eight markers are highly significant different between Chinese indigenous Meishan breeds and Large White pig breeds. Eight polymorphic sites were then used for linkage and QTL mapping to refine the fatness QTL in a Large White × Meishan F(2) resource population. Five chromosome-wise significant QTLs were detected, of which the QTLs for leaf fat weight, backfat thickness at 6-7th rib and rump, and mean backfat thickness were narrowed to the interval between PPARD and GLP1R genes and the QTL for backfat thickness at thorax-waist between GNMT and PLA2G7 genes on SSC7p1.1-q1.4.     

Directed isolation and mapping of microsatellites from swine Chromosome 1q telomeric region through microdissection and RH mapping

Several quantitative trait loci (QTLs) (vertebrate number, birth weight, age at puberty, growth rate, gestation length, and backfat depth) have been independently mapped to the distal region of swine Chromosome (SSC) 1q in several resource populations. In order to improve the map resolution and refine these QTLs more precisely on SSC1q, we have isolated and mapped additional microsatellites (ms), using chromosome microdissection and radiation hybrid (RH) mapping. Five copies of the telomeric region of SSC1q were microdissected from metaphase spreads and pooled. The chromosomal fragment DNA was randomly amplified by using degenerate oligonucleotide primed polymerase chain reaction (DOP-PCR), enriched for ms, and subcloned into a PCR vector. Screening of subsequent clones with ms probes identified 23 unique ms sequences. Fifteen of these (65%) were subjected to radiation hybrid (RH) mapping by using the INRA-University of Minnesota porcine RH panel (IMpRH); and the remaining eight were not suited for the RH mapping. Twelve microsatellites were assigned to SSC1q telomeric region of IMpRH map (LOD >6), and three remain unlinked (LOD <6). Out of the 15 microsatellite markers, 9 were polymorphic in NIAI reference population based on the Meishan and G?ttingen miniature pig. In summary, we have used microdissection and radiation hybrid mapping to clone and map 12 new microsatellites to the swine gene map to increase the resolution of SSC1q in the region of known QTLs. Received: 19 December 2000 / Accepted: 28 February 2001     

Mapping of 443 porcine EST improves the comparative maps for SSC1 and SSC7 with the human genome

Numerous mapping studies of complex traits in the pig have resulted in quantitative trait loci (QTL) intervals of 10-20 cM. To improve the chances to identify the genes located in such intervals, increased expressed sequence tags (EST)-based marker density, coupled with comparative mapping with species whose genomes have been sequenced such as human and mouse, is the most efficient tool. In this study, we mapped 443 porcine EST with a radiation hybrid (RH) panel (384 had LOD > 6.0) and a somatic cell hybrid panel. Requiring no discrepancy between two-point and multipoint RH data allowed robust assignment of 309 EST, of which most were located on porcine chromosomes (SSC) 1, 4, 7, 8 and X. Moreover, we built framework maps for two chromosomes, SSC1 and SSC7, with mapped QTL in regions with known rearrangement between pig and human genomes. Using the Blast tool, we found orthologies between 407 of the 443 pig cDNA sequences and human genes, or to existing pig genes. Our porcine/human comparative mapping results reveal possible new homologies for SSC1, SSC3, SSC5, SSC6, SSC12 and SSC14 and add markers in synteny breakpoints for chromosome 7.     

猪Mx1基因第14外显子多态性分析及新突变位点的 发现

采用PCR-RFLP方法对国内外7个猪种Mx1基因第14外显子的多态性进行分析, 共检测到3个等位基因, 6种基因型。其中杜洛克中仅存在AA基因型, 苏太猪中存在全部基因型, 只有在梅山猪和具有梅山猪血统的苏太猪中出现基因型BB。所有猪种中, 只有在地方猪种和培育猪种中出现等位基因B, 所有猪种除松辽黑猪外均以A为优势等位基因。卡方检验结果表明, 不同猪种间基因型分布差异较大, 梅山猪和松辽黑猪与其他所有猪种的基因型频率差异极显著(P＜0.01) , 苏太猪与除皮特兰猪外的所有猪种的基因型频率差异也极显著(P＜0.01) , 淮猪与杜洛克和约克夏这两个国外猪种基因型频率差异不显著(P＞0.05), 而与皮特兰和其他地方猪种的基因型频率均存在极显著差异(P＜0.01) 。通过测序在扩增片段中新发现了3种类型的碱基突变, 前2个分别导致了Thr和Glu向Ala和Arg的替换, 最后一个突变不引起氨基酸的变化, 且后两个突变位点为BB基因型所特有。     

Quantitative trait loci mapping for fatty acid contents in the backfat on porcine chromosomes 1, 13, and 18

A partial genome scan using microsatellite markers was conducted in order to detect quantitative trait loci (QTLs) for 10 fatty acid contents of the backfat in a pig reference population. Two QTLs were found by studying SSC1, SSC13, and SSC18, where QTLs had already been identified for backfat thickness. A QTL was located between marker loci S0113 and SW974 on chromosome 1; this QTL was only significantly detected (P < 0.05) for linoleic acid. The other QTL was discovered between markers S0062 and S0120 on chromosome 18, and its significance only showed (P < 0.05) for myristic acid. The two QTLs mapped to the same location as the backfat thickness QTL. A third of the phenotypic variation was explained for linoleic acid by the QTL on chromosome 1, and a quarter for myristic acid by the QTL on chromosome 18. Further studies on fine mapping and positional comparative candidate gene analyses will be the next step toward a better understanding of the genetic architecture of fatty acid contents.     

猪核糖体蛋白基因RPLP0的cDNA全长、染色体定位和多态性分析

RPLPO基因编码酸性核糖体磷蛋白大亚基P0,是核糖体60S亚基的组成成分之一。从本室构建的猪胚胎骨骼肌cDNA文库中分离得到猪RPLPO基因的全长cDNA,并提交GenBank数据库。比较猪RPLPO基因和人及小鼠同源基因的cDNA序列和蛋白质序列,结果表明该基因在3个物种中具有高的相似性。用PCR．RFLP方法在猪RPLPO基因cDNA545处检测到C—A的单碱基突变,为Csp6Ⅰ的酶切位点。统计分析结果表明3种基因型（AA,AC,CC）在外来品种杜洛克,大约克,长白和中国地方品种通城猪,小梅山,玉山猪中的分布各不相同。同时使用体细胞杂种板（SCHP）和辐射杂种板（IMpRH）对RPLPO基因进行染色体定位,该基因被定位于SSC14q22．q24并且和SW1321微卫星标志紧密连锁（25cR,LOD=14．54）。     

猪a1-岩藻糖转移酶基因(FUT1)在26个中外猪种中的遗传变异研究

肠毒素大肠杆菌F18(ECF18)是引起仔猪断奶后水肿和腹泻病的主要病原菌,a1—岩藻糖转移酶基因(FUT1)是ECF18侵染猪小肠的受体蛋白候选基因。通过采用PCR—RFLP方法检测了5个西方商业猪种以及21个中国地方猪种(群)1458个个体在FUT1基因开放阅读框架的307核苷酸位点的G-A点突变(M307^G-A)遗传变异。结果表明：5个外来猪种以及中国地方猪种中的临高猪在该FUT1基因位点存在多态性,其他中国地方猪种均表现为极端的单态分布,只有易感的GG基因型,没有多态性。由此提示：1)如果猪FUT1 M307^G-A点突变是决定猪小肠上ECF18受体表达与否的关键因素,则绝大部分中国地方猪种均不具备抵抗ECF18的遗传基础,这除了表明ECF18抗性基因有可能起源于西方猪种外,同时也表明对中国地方猪种中在这个位点惟一存在多态性的海南临高猪的品种资源保存具有非常重要的意义。2)一般而言,在中国的养猪生产实践中,中国地方猪种的仔猪抗水肿与腹泻病能力普遍强于外来猪种,研究的结果提示有必要对中国地方猪种所具备的上述遗传抗性做更深入的研究,寻找、定位其相应的QTL或／和抗性基因。     

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.     

Genetic Variation of Exon 2 of SLA-DQB Gene In Chinese Pigs

A 273 base pair (bp) fragment of the SLA-DQB gene including parts of intron 1 and exon 2 has been investigated using PCR-RFLP in 38 indigenous Chinese pig breeds, two Chinese wild boars, and three foreign pig breeds. The restriction enzyme RsaI revealed three polymorphic sites in the 273 bp fragment for the pig breeds studied. In total, four alleles resulting in 10 genotypes were found. Twenty pig breeds are not in Hardy–Weinberg equilibrium at this locus. The allele frequency of a chi-square test showed that there is significant difference (P < 0.05) among six Chinese pig groups, and an even greater significant difference (P < 0.01) was found between Chinese and European pig breeds.     

Evaluation of quantitative trait loci affecting intramuscular fat and reproductive traits in pigs using marker‐assisted introgression

We investigated the effects of previously identified quantitative trait loci (QTL) in an experimental backcross (BC) between Chinese Meishan pigs and commercial Duroc pigs. We performed marker‐assisted introgression of two QTL for intramuscular fat (IMF) content (IMF population) and three QTL for reproductive traits (reproduction population) from a donor Meishan pig into a recipient Duroc pig. At the fourth BC generation of the IMF population and third BC generation of the reproduction population, carrier animals were selected for the production of animals homozygous for the QTL. Our previous studies have shown that the presence of a Meishan allele on the IMF QTL is associated with low IMF values, and the Meishan allele on the reproductive QTL is associated with large litters. In this study, the presence of a Duroc allele at the IMF QTL on SSC9 resulted in a 0.27% increase in IMF (additive effect = 0.27 ± 0.08), whereas the presence of a Meishan allele at the IMF QTL on SSC7 resulted in a 0.34% increase in IMF (additive effect = ?0.34 ± 0.09). The presence of the Meishan allele at the IMF QTL on SSC7 thus had the opposite effect to our previous studies, that is, increased IMF. In the reproduction population, we observed no differences between the genotypes of the three QTL in regard to number of corpora lutea or litter size. Marker‐assisted introgression at these QTL is thus unlikely to result in an associated increase in litter size. These results show that it is possible to introgress alleles from other breeds into a selection population using molecular markers; any unexpected results might be associated with the genetic background.     

Genetic and physical mapping, expression analysis and partial sequence of porcine PER1

The porcine PER1 gene was mapped to chromosome 12q1.4-->q1.5 using fluorescence in situ hybridisation. A polymorphic microsatellite marker (S0601) was isolated from a BAC clone shown to contain the PER1 gene. Linkage analysis assigned S0601 distal to ALOX12 on SSC12, providing further evidence for the conservation of synteny between HSA17 and SSC12. RT-PCR analysis demonstrated the expression of PER1 in all 11 tissues tested, consistent with the data from other mammalian species. Part of the PER1 gene was sequenced, homologous to exons 2-14 of the human gene and encoding the N-terminus of porcine PER1. The predicted amino acid sequence of the partial pig PER1 protein shares over 96% identity with its human orthologue.     

A Single Nucleotide Polymorphism and Sequence Analysis of CSN1S1 Gene Promoter Region in Chinese BOS Grunniens (YAK)

The aim of this study was to investigate the polymorphism of the CSN1S1 gene promoter region in 4 Chinese yak breeds, and compare the yak CSN1S1 gene promoter region sequences with other ruminants. A Polymerase Chain Reaction-Single Strand Conformation Polymorphism protocol was developed for rapid genotyping of the yak CSN1S1 gene. One hundred fifty-eight animals from 4 Chinese yak breeds were genotyped at the CSN1S1 locus using the protocol developed. A single nucleotide polymorphism of the CSN1S1 gene promoter region has been identified in all yak breeds investigated. The polymorphism consists of a single nucleotide substitution G→A at position 386 of the CSN1S1 gene promoter region, resulting in two alleles named, respectively, G₃₈₆ and A₃₈₆, based on the nucleotide at position 386. The allele G₃₈₆ was found to be more common in the animals investigated. The corresponding nucleotide sequences in GenBank of yak (having the same nucleotides as allele G₃₈₆ in this study), bovine, water buffalo, sheep, and goat had similarity of 99.68%, 99.35%, 97.42%, 95.14%, and 94.19%, respectively, with the yak allele A_386.     

Localization, expression change in PRRSV infection and association analysis of the porcine TAP1 gene

The transporter associated with antigen processing (TAP) translocates antigenic peptides from the cytosol into the lumen of the endoplasmic reticular and plays a critical role in the major histocompatibility complex (MHC) class I molecule-mediated antigenic presentation pathway. In this study, the porcine TAP1 gene was mapped to the pig chromosome 7 (SSC7) and was closely linked to the marker SSC2B02 (retention fraction=43%, LOD=15.18). Subcellular localization of TAP1 by transient transfection of PK15 cells indicated that the TAP1 protein might be located in the endoplasmic reticulum (ER) in pig kidney epithelial cells (PK-15). Gene expression analysis by semi-quantitative RT-PCR revealed that TAP1 was selectively expressed in some immune and immune-related tissues. Quantitative real-time PCR (qRT-PCR) analysis revealed that this gene was up-regulated after treatments that mimic viral and bacterial infection (polyriboinosinic-polyribocytidylic acid (poly(I:C)) and lipopolysaccharide (LPS), respectively). In addition, elevated TAP1 expression was detected after porcine reproductive and respiratory syndrome virus (PRRSV) infection in porcine white blood cells (WBCs). One single nucleotide polymorphism (SNP) in exon 3 of TAP1 was detected in a Landrace pig population by Bsp143I restriction enzyme digestion. Different genotypes of this SNP had significant associations (P<0.05) with the red blood cell distribution width (RDW) of 1-day-old (1 d) pigs (P=0.0168), the PRRSV antibody level (PRRSV Ab) (P=0.0445) and the absolute lymphocyte count (LYM#) (P=0.024) of 17 d pigs. Our results showed that the TAP1 gene might have important roles in swine immune responses, and these results provide useful information for further functional studies.     

Characterization and Physical Mapping of the Porcine CDS1 and CDS2 Genes

CDP-diacylglycerol synthase (CDS) catalyzes the conversion of phosphatidic acid to CDP-diacylglycerol, an important precursor for the synthesis of phosphatidylinositol, phosphatidylglycerol, and cardiolipin. We amplified and sequenced 2,053 bp of the pig CDS1 mRNA. The structure of the pig CDS1 gene was determined, being very similar to that of the human, rat, and mouse genes with respect size and organization of the 13 exons. In addition, we identified three polymorphic positions in exons 10 and 11. One of them, the A/C₁₀₀₆, was genotyped in samples belonging to Iberian, Landrace, Large White, Pietrain, and Meishan pig breeds. Expression of this gene was also analyzed by real-time polymerase chain reaction (PCR) in different tissues showing a high CDS1 expression in testis. Moreover, a 1240-bp fragment of the pig CDS2 mRNA was amplified and sequenced. Finally, the CDS1 and CDS2 genes were physically mapped to porcine chromosomes 8 and 17, respectively, by using the INRA, University of Minnesota porcine Radiation Hybrid panel (IMpRH).