Jin-Tae Jeon

A paternally expressed QTL affecting skeletal and cardiac muscle mass in pigs maps to the IGF2 locus.

A paternally expressed QTL affecting skeletal and cardiac muscle mass in pigs maps to the IGF2 locus

A radiation hybrid map of the RN region in pigs demonstrates conserved gene order compared with the human and mouse genomes

We recently constructed a 7000-rad porcine whole-genome radiation hybrid (RH) panel with the primary objective of integrating linkage maps of microsatellites with evolutionary conserved genes into one ordered map. In order to evaluate the resolution of this RH panel, we have now constructed a radiation hybrid map of the Chromosome (Chr) 15q2.3-q2.6 region containing the RN gene. This gene has large effects on glycogen content in muscle and meat quality. Ten microsatellites covering a region of 55 centiMorgans and eight genes (AE3, FN1, IGFBP5, INHA, IRS1, PAX3, TNP1, and VIL1) were placed on the Sscr15 RH map. All the genes, except IRS1, were mapped on the RH map between microsatellites located in 15q2.5. The relative order of AE3 and INHA was inverted on the porcine physical map in comparison with the mouse linkage map. The order of other genes already mapped in the mouse (FN1, IGFBP5, TNP1, VIL1, INHA/AE3, and PAX3) was identical in pigs. We found no clear difference between the gene order on pig Chr 15 and human Chr 2q.

A high-density linkage map of the RN region in pigs

The porcine RN locus affects muscle glycogen content and meat quality. We previously mapped the RN locus to chromosome 15. This study describes the identification of polymorphisms for four class I and four class II markers located in the RN region. Resource families were genotyped with F-SSCP markers (fluorescent single strand conformation polymorphism) and microsatellite markers. Subsequent multipoint linkage analysis revealed the order FN1-IGFBP5-S1000-S1001-IL8RB-VIL1-RN-Sw936-Sw906. The gene order is identical to the previously reported porcine RH map of the same region. The described map will facilitate positional cloning of the RN gene.

Comparative sequence analysis of the PRKAG3 region between human and pig: evolution of repetitive sequences and potential new exons

The PRKAG3 gene encodes the γ3 chain of AMP-activated protein kinase (AMPK). A non-conservative missense mutation in the PRKAG3 gene causes a dominant phenotype involving abnormally high glycogen content in pig skeletal muscle. We have determined >126 kb (in 13 contigs) of porcine genomic sequence surrounding the PRKAG3 gene and the corresponding mouse region covering the gene. A comparison of these PRKAG3 sequences and the human sequence was conducted and used to predict evolutionarily conserved regions, including regulatory regions. A comparison of the human genomic sequence and a porcine BAC sequence containing the PRKAG3 gene, revealed a conserved organization and the presence of three additional genes, CYP27A1 (cytochrome P450, family 27, subfamily A, polypeptide 1), STK36 (Serine Threonine Kinase 36), and the homolog of the unidentified human mRNA KIAA0173. Interspersed repetitive elements constituted 51.4 and 38.6% of this genomic region in human and pig, respectively. We were able to reliably align 12.6 kb of orthologous repeats shared between pig and human and these showed an average sequence identity of 72.4%. Our analysis revealed that the human KIAA0173 gene harbors alternative 5′ untranslated exons originating from repetitive elements. This provides an obvious example how transposable elements may affect gene evolution.

Construction of a high-resolution RH map of the human 2q35 region on TNG panel and comparison with a physical map of the porcine homologous region 15q25

Abstract. This article describes the construction of a high-resolution radiation hybrid map of Hsap 2q35 by using the TNG RH panel generated by irradiation with 50,000 rads. We were able to build a framework map of 1300 cR50,000 including 34 markers ordered with odds higher than 1000:1. The comprehensive map includes 77 loci and describes a region of 3 Mb around the SLC11A1 gene. Because of the very small size of the fragments retained and a reduced retention frequency, it was difficult to build a high-resolution multi-point map of this region by using the TNG RH panel. Nevertheless, this study confirmed the very high potential of this RH panel for constructing a human, high-resolution physical map (2.3 kb/cR50,000). Moreover, human ESTs from Hsap 2q35 were hybridized with porcine BAC contigs to establish a porcine transcript map of the homologous region Sscr 15q25 (greater than 2.5 Mb). We identified 17 new genes in this porcine chromosomal region. We were able to compare the location of 26 genes mapped in both species. The gene order was similar except for two possible minor discrepancies in the Desmin sub-region, suggesting the existence of a porcine micro-region between TNP1 and IL8RB with an unknown origin.