Chromosomal assignment of six muscle-specific genes in cattle

Six genes expressed in skeletal or smooth muscle were assigned to bovine chromosomes using rodent, human or bovine cDNA probes. Myogenic determination factor (MYOD1) was 100% concordant with Bos taurus chromosome (BTA) 15, and myogenin (MYOG) was 95% concordant with BTA 16. Smooth muscle caldesmon (CALD1) and the skeletal muscle chloride channel gene (CLCN1) were 100% concordant with BTA 4. Myogenic factor 5 (MYF5) was 90% concordant with BTA 5; this assignment was confirmed by fluorescence in situ hybridization of a bovine genomic MYF5 probe to BTA 5 band 13 and the homologous band on river buffalo 4q. In some metaphases, specific hybridization signals were also observed on BTA 15 band 23, and the equivalent river buffalo homologue, with the MYF5 genomic probe. Because MYOD1 and MYF5 share both nucleotide and functional homology and because MYOD1 was mapped in somatic cell hybrids to BTA 15, we suggest that MYOD1 may be located at BTA 15 band 23. Herculin/myogenic factor 6 (MYF6) was assigned indirectly to BTA 5 by the hybridization of MYF5 and MYF6 probes to the same Hin dIII fragment in bovine genomic DNA. The assignment of MYF6 to BTA 5 is consistent with the tandem arrangement of MYF5 and MYF6 in human, mouse and chicken, where these tightly linked genes are separated by < 6·5 kb of DNA.     

Allelic Variation in the Porcine MYF5 Gene Detected by PCR–SSCP

The MYF5 gene has been reported to be integral to muscle growth and development, and hence it has been considered as a candidate gene for meat selection programs in pig. To ascertain whether there was variation in the porcine MYF5 gene, we have developed a method of PCR–single-strand conformational polymorphism (PCR–SSCP) analysis. In this study, two coding regions of the MYF5 gene were investigated. Four unique SSCP patterns were detected in exon 1 and three patterns were identified in exon 3. Two SNPs detected in exon 1 led to a non-synonymous alanine/proline substitution. A nucleotide change in exon 3 did not affect the amino acid sequence. Five extended haplotypes were observed across the two regions. The variation detected in this study might underpin the development of gene markers for improved muscle growth in pig breeding.     

Assignment of the porcine loci for MYOD1 to chromosome 2 and MYF5 to chromosome 5

Porcine-specific polymerase chain reaction (PCR) and a pig–rodent somatic cell hybrid panel were used to map two members of the MyoD gene family. MYOD1 was assigned to pig chromosome 2 and MYF5 to chromosome 5.     

Myogenin is in an evolutionarily conserved linkage group on human chromosome 1q31-q41 and unlinked to other mapped muscle regulatory factor genes

Myogenin is a member of a family of muscle-specific regulatory factors which includes MyoD1, Myf-5, and Myf-6 (also called MRF4 and herculin). Extensive regions of sequence homology in genes for these three factors suggest duplication events associated with their evolution. In the present study, the chromosomal location of the myogenin gene in humans (MYOG), mice (Myog), and Chinese hamsters (MYOG) was determined using in situ hybridization to human metaphase chromosomes as well as segregation analysis among interspecific somatic cell hybrid panels and interspecific backcrossed mice. We localize the gene encoding myogenin to human chromosome 1q31-q41 within a linkage group homologous with a region on mouse chromosome 1 and Chinese hamster chromosome 5. The results verify the nonlinkage of MYOG to MYOD1, MYF5, and MYF6 genes and indicate that events associated with the duplication of MYOG with respect to MYOD1, MYF5, or MYF6 loci were not chromosome-wide.     

Preface

The aim of the study was to introduce a convenient method for identification of differences among individual animals in genes supposed to influence meat performance in pigs. The set of seven candidate genes (IGF2, FOS, MC4R, DGAT1, MYF4, MYF, and MC3R) was used. To determine the genotypes, multiplex polymerase chain reaction (PCR) and minisequencing using SNaPshot system (Applied Biosystems; Forster City, CA, USA) were applied. The efficiency of this gene panel for routine testing in pigs was verified in the Black Pied P?e?tice pig breed by the statistical general linear model. The results showed that both the method and the gene panel are convenient for meat quality testing and offer reproducible results.     

SNaPshot minisequencing and a panel of candidate genes for complex routine testing of meat performance traits in pigs

The aim of the study was to introduce a convenient method for identification of differences among individual animals in genes supposed to influence meat performance in pigs. The set of seven candidate genes (IGF2, FOS, MC4R, DGAT1, MYF4, MYF, and MC3R) was used. To determine the genotypes, multiplex polymerase chain reaction (PCR) and minisequencing using SNaPshot system (Applied Biosystems; Forster City, CA, USA) were applied. The efficiency of this gene panel for routine testing in pigs was verified in the Black Pied Prestice pig breed by the statistical general linear model. The results showed that both the method and the gene panel are convenient for meat quality testing and offer reproducible results.     

Genomic organization of the IGF1, IGF2, MYF5, MYF6 and GRF/PACAP genes across Salmoninae genera

Whole-genome duplication in the ancient ray-finned fish and subsequent tetraploidization in the ancestor to the salmonids have complicated genomic and candidate gene studies in these organisms as many genes with multiple copies are present throughout their genomes. In an attempt to identify genes with a potential influence on growth and development, we investigated the genomic positions of insulin-like growth factors 1 and 2 (IGF1, IGF2), myogenic factors 5 and 6 (MYF5, MYF6) and growth hormone-releasing factor/pituitary adenylate cyclase-activating polypeptide (GRF/PACAP) in three salmonid species: rainbow trout (Oncorhynchus mykiss), Atlantic salmon (Salmo salar) and Arctic charr (Salvelinus alpinus). Our results suggest a tight association between the IGF1, MYF5 and MYF6 genes in all three species. We further localized the duplicated copies of IGF1 to the homeologous linkage groups RT-7/15 in rainbow trout and AC-3/24 in Arctic charr, and the two copies of MYF6 to homeologous linkage groups AS-22/24 in Atlantic salmon. Localization of GRF/PACAP to RT-7, AS-31 and AC-27 and IGF2 to RT-27, AS-2 and AC-4 in rainbow trout, Atlantic salmon and Arctic charr respectively is consistent with previously reported homologies among these chromosomal segments identified using other genetic markers. However, localization of the second copy of GRF/PACAP to RT-19 and AC-14 and the duplicated copy of IGF2 to AC-19 suggest a possible new homology/homeology between these chromosomes. These results might also be an indication of a more ancient polyploidization event that occurred deep in the ray-finned fish lineage.     

Assignment of six genes to bovine chromosomes 5 and 16 by fluorescence in situ hybridization, radiation hybrid mapping and genetic linkage analysis

Several quantitative trait loci for beef carcass traits have been mapped to bovine chromosome 5. The objective of this study was to map six candidate genes for these traits by fluoresence in situ hybridization, genetic linkage analysis and radiation hybrid mapping. MYF5 and MYF6 were assigned to 5q13, WIF1 to 5q23 and MMP19 to 5q25. A paralog of MYF5 (putatively MYOG) was assigned to 16q12. A novel microsatellite placed MYF5 and MYF6 10.4 cM from BM6026 and 19.1 cM from BL23 on the genetic linkage map. MYF5 (62.6 cR), WNT10B (319.5 cR), WIF1 (500.8 cR) and MMP19 (701.2 cR) were also integrated into the 5000(Rad) radiation hybrid map.     

Myogenic Differentiation Potential of Mesenchymal Stem Cells Derived from Fetal Bovine Bone Marrow

The myogenic potential of bovine fetal MSC (bfMSC) derived from bone marrow (BM) remains unknown; despite its potential application for the study of myogenesis and its implications for livestock production. In the present study, three protocols for in vitro myogenic differentiation of bfMSC based on the use of DNA methyltransferase inhibitor 5-Aza-2′-deoxycytidine (5-Aza), myoblast-secreted factor Galectin-1 (Gal-1), and myoblast culture medium SkGM-2 BulletKit were used. Plastic-adherent bfMSC were isolated from fetal BM collected from abattoir-derived fetuses. Post-thaw viability analyses detected 85.6% bfMSC negative for propidium iodine (PI). Levels of muscle regulatory factors (MRF) MYF5, MYF6, MYOD, and DES mRNA were higher (P?MYOD mRNA (Days 7 to 21) and up-regulation of MYF6 (Day 7), MYF5, and DES mRNA (Day 21). Gal-1 and SkGM-2 BulletKit induced sequential down-regulation of early MRF (MYF5) and up-regulation of intermediate (MYOD) and late MRF (DES) mRNA. Moreover, DES and MYF5 were immunodetected in differentiated bfMSC. In conclusion, protocols evaluated in bfMSC induced progress into myogenic differentiation until certain extent evidenced by changes in MRF gene expression.     

A WNT/beta-catenin signaling activator, R-spondin, plays positive regulatory roles during skeletal myogenesis

R-spondins (RSPOs) are a recently characterized family of secreted proteins that activate WNT/β-catenin signaling. In this study, we investigated the potential roles of the RSPO proteins during myogenic differentiation. Overexpression of the Rspo1 gene or administration of recombinant RSPO2 protein enhanced mRNA and protein expression of a basic helix-loop-helix (bHLH) class myogenic determination factor, MYF5, in both C2C12 myoblasts and primary satellite cells, whereas MYOD or PAX7 expression was not affected. RSPOs also promoted myogenic differentiation and induced hypertrophic myotube formation in C2C12 cells. In addition, Rspo2 and Rspo3 gene knockdown by RNA interference significantly compromised MYF5 expression, myogenic differentiation, and myotube formation. Furthermore, Myf5 expression was reduced in the developing limbs of mouse embryos lacking the Rspo2 gene. Finally, we demonstrated that blocking of WNT/β-catenin signaling by DKK1 or a dominant-negative form of TCF4 reversed MYF5 expression, myogenic differentiation, and hypertrophic myotube formation induced by RSPO2, indicating that RSPO2 exerts its activity through the WNT/β-catenin signaling pathway. Our results provide strong evidence that RSPOs are key positive regulators of skeletal myogenesis acting through the WNT/β-catenin signaling pathway.     

Genetic variants in MYF5 affected growth traits and beef quality traits in Chinese Qinchuan cattle

Myogenic factor 5 plays actively roles in the regulation of myogenesis. The aims of this study are to identify the evolution information of MYF5 protein among 10 domestic and mammalian animals, to uncover the expression patterns of MYF5 gene in calves and adults of Qinchuan cattle, and to expose the genetic variants of the MYF5 gene and explore its effect on cattle growth traits and beef quality traits in Qinchuan cattle. The bioinformatics results showed that the MYF5 proteins highly conserved in different mammalian or domestic animals apart from chicken. The expression level of MYF5 gene in the heart, muscle, lung, large intestine and liver was greater than that of other tissues. PCR amplicons sequencing identified four novel SNPs at g.5738A>G, g.5785C>T and g.5816A>G in the 3rd exon region and g.6535A>G in the 3’ UTR. Genotypic frequencies of g.5785C>T was harshly deviated from the HWE (P < .05). Genetic diversity was low or intermediate for the four SNPs and those SNPs were in the weak linkage disequilibrium. Association analysis results indicated g.5785C>T, g.5816A>G and g.6535A>G significant effect on growth performance and beef quality traits of Qinchuan cattle. H1H3 diplotype had greater body size and better beef quality. All the results implicate that the MYF5 gene might be applied as a promising candidate gene in Qinchuan cattle breeding.     

猪POU1F1基因部分序列变异和同源性分析

对长白、杜洛克、约克夏、姜曲海、梅山和香猪等六个猪种的POU1F1基因第四、第五和第六外显子分别进行PCR扩增,并对含有第四、第六外显子的PCR产物和含有第五外显子的克隆产物进行测序。结果表明：六个猪种中,POU1F1基因的第四外显子存在碱基突变,为T→C。对该序列进行Nla Ⅲ 酶消化,产生两种不同的基因型(GG和HH);而第五和第六外显子则高度保守,未发现任何突变。将人POU1F1基因第四外显子、POU同源区核苷酸编码序列和氨基酸序列,分别与猪、小鼠、牛的POU1F1基因相应的核苷酸序列和氨基酸序列进行同源性比较,结果发现：人与猪、小鼠、牛的POU1F1基因第四外显子的核苷酸同源性分别高达93.9%、86.7%、92.1%,而由第四外显子编码的部分POU特异区的氨基酸序列则完全一致;人与猪、小鼠、牛POU同源区的核苷酸同源性分别为91.4%、85.1%、87.9%,氨基酸同源性分别为96.6%、94.8%、90.2%。这说明在哺乳动物中,其POU1F1蛋白的POU同源区和由第四外显子编码的POU特异区部分是高度保守的;猪可作为实验动物,建立人类相关疾病模型,为医学研究提供参考依据。