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Porcine Skeletal Muscle (porcine + skeletal_muscle)

Distribution by Scientific Domains

Life Sciences	78%

Selected Abstracts

Sensitive Monoclonal Antibody-based Sandwich ELISA for the Detection of Porcine Skeletal Muscle in Meat and Feed Products

JOURNAL OF FOOD SCIENCE, Issue 1 2006
Lihua Liu
ABSTRACT: A monoclonal antibody-based sandwich enzyme-linked immunosorbent assay (ELISA) was developed for the sensitive detection of porcine skeletal muscle in raw and heat-processed meat and feed products. Heat treatment of meat samples up to 132 °C for 2 h did not affect the assay performance. The assay uses a pair of monoclonal antibodies (MAbs 8F10 and 5H9) specific to skeletal muscle troponin I (TnI). MAb 8F10, reacting to mammalian TnI, is the capture antibody and the biotin-conjugated MAb 5H9, specific to porcine TnI, the detection antibody. The sandwich ELISA is able to detect 0.05% (w/w) of laboratory-adulterated pork in chicken, 0.1% (w/w) pork in beef mixtures, 0.05% (w/w) pork meal in soy-based feed, and 1% commercial meat and bone meal (MBM), containing an unknown amount of pork, in soy-based feed. This new assay provides a rapid and reliable means to detect the contamination of meat and feed products with trace amounts of porcine muscle tissue to ensure product quality and safety. [source]

Porcine skeletal muscle differentially expressed gene CMYA1: isolation, characterization, mapping, expression and association analysis with carcass traits

ANIMAL GENETICS, Issue 3 2009
X. L. Xu
Summary To investigate the differences in gene expression between some obese and lean pig breeds, differential display of mRNA was employed in our previous research. One differentially expressed EST (BI596262) was further identified as the porcine cardiomyopathy associated 1 (CMYA1) gene because of its homology to the human CMYA1 gene. The full-length DNA of the porcine CMYA1 gene encompasses 9379 bp, including a complete open reading frame encoding 1839 amino acid residues, a 158-bp 5,-untranslated region and a 630-bp 3,-untranslated region. The porcine CMYA1 gene was assigned to chromosome 13 by the radiation hybrid panel (IMpRH). The porcine CMYA1 gene was expressed only in the striated muscle. Single nucleotide polymorphism (SNP) scanning in the coding region identified one synonymous mutation (c.1053C>T) and three missense mutations, c.1394A>G (p.His465Arg), c.1751A>G (p.Asp582Gly) and c.3290C>A (p.Thr1097Asp). The allele frequencies were tested among about 200 unrelated pigs from several pig breeds. Linkage mapping was further conducted with the SNP c.1751A>G (p.Asp582Gly) in a Berkshire × Yorkshire resource family and this confirmed that porcine CMYA1 is closely linked with Sw344 (distance = 2 cM, LOD score is 129.47), an interesting region harbouring a QTL for back fat thickness. Association analysis in our experimental pig population showed that different genotypes of CMYA1 gene were associated with different back fat thicknesses (P < 0.05). Our results suggest that the porcine CMYA1 gene has effects on porcine back fat deposition and further investigation will be necessary to illustrate the underlying mechanisms. [source]

Molecular cloning and characterization of bovine PRKAG3 gene: structure, expression and single nucleotide polymorphism detection

JOURNAL OF ANIMAL BREEDING AND GENETICS, Issue 5 2005
S.L. Yu
Summary The protein kinase adenosine monophosphate-activated ,3-subunit (PRKAG3) gene encodes a muscle-specific isoform of the regulatory gamma-subunit of adenosine monophosphate-activated protein kinase, which plays a key role in regulating energy homeostasis in eucaryotes. It is well known that mutations in the PRKAG3 gene affect high glycogen content in the porcine skeletal muscle and, consequently, meat quality. The genomic structure and sequence of the bovine PRKAG3 were analysed from a Korean cattle BAC clone. The bovine PRKAG3 gene comprises 13 exons and spans approximately 6.8 kb on BTA2. From 5, and 3,-rapid amplification of cDNA ends experiments, the full-length cDNA of bovine PRKAG3 has been identified, encoding a deduced protein of 465 amino acids. Two splice isoforms, generated by the alternative splicing of exon 2, were also identified. Northern blot analysis demonstrated that, similar to other species, the bovine PRKAG3 transcript was only expressed in skeletal muscle. Seven single nucleotide polymorphisms, including two previously identified variants, were detected in four Bos taurus cattle breeds. The bovine PRKAG3 gene described in this study may be involved in muscle-related genetic diseases or meat quality traits in cattle. [source]

Sensitive Monoclonal Antibody-based Sandwich ELISA for the Detection of Porcine Skeletal Muscle in Meat and Feed Products

MicroRNA expression profiles of porcine skeletal muscle

ANIMAL GENETICS, Issue 5 2010
B. Zhou
Summary MicroRNAs (miRNAs) are endogenous non-coding RNAs of ,22 nucleotides in length that play important roles in multiple biological processes by degrading targeted mRNAs or repressing mRNA translation. To evaluate the roles of miRNA in porcine skeletal muscle, miRNA expression profiles were investigated using longissimus muscle tissue from pigs at embryonic day 90 (E90) and postpartum day 120 (PD120). First, we used previously known miRNA sequences from humans and mice to perform blast searches against the porcine expressed sequence tag (EST) database; 98 new miRNA candidates were identified according to a range of filtering criteria. These miRNA candidates and 73 known miRNAs (miRBase 13.0) from pigs were chosen for porcine miRNA microarray analysis. A total of 16 newly identified miRNAs and 31 previously known miRNAs were detected in porcine skeletal muscle tissues. During later foetal development at E90, miR-1826, miR-26a, miR-199b and let-7 were highly expressed, whilst miR-1a, miR-133a, miR-26a and miR-1826 showed highest abundance during the fast growing stage at PD120. Using the 47 miRNAs detected by the microarray assay, we performed further investigations using the publicly available porcine mRNA database from NCBI and computed potential target hits using the software rnahybrid. This study identified 16 new miRNA candidates, computed potential target hits for 18 miRNA families and determined the miRNA expression profiles in porcine skeletal muscle tissues at different developmental stages. These results provide a valuable resource for investigators interested in post-transcriptional gene regulation in pigs and related animals. [source]

MicroRNA identity and abundance in porcine skeletal muscles determined by deep sequencing

ANIMAL GENETICS, Issue 2 2010
M. Nielsen
Summary MicroRNAs (miRNA) are short single-stranded RNA molecules that regulate gene expression post-transcriptionally by binding to complementary sequences in the 3, untranslated region (3, UTR) of target mRNAs. MiRNAs participate in the regulation of myogenesis, and identification of the complete set of miRNAs expressed in muscles is likely to significantly increase our understanding of muscle growth and development. To determine the identity and abundance of miRNA in porcine skeletal muscle, we applied a deep sequencing approach. This allowed us to identify the sequences and relative expression levels of 212 annotated miRNA genes, thereby providing a thorough account of the miRNA transcriptome in porcine muscle tissue. The expression levels displayed a very large range, as reflected by the number of sequence reads, which varied from single counts for rare miRNAs to several million reads for the most abundant miRNAs. Moreover, we identified numerous examples of mature miRNAs that were derived from opposite sides of the same predicted precursor stem-loop structures, and also observed length and sequence heterogeneity at the 5, and 3, ends. Furthermore, KEGG pathway analysis suggested that highly expressed miRNAs are involved in skeletal muscle development and regeneration, signal transduction, cell-cell and cell-extracellular matrix communication and neural development and function. [source]

Identification and characterization of microRNAs from porcine skeletal muscle

ANIMAL GENETICS, Issue 2 2010
S. S. Xie
Summary MicroRNAs (miRNAs) are a class of non-coding RNAs that negatively regulate gene expression at the post-transcriptional level. There is increasing evidence to suggest that miRNAs participate in muscle development in mice and humans; however, few studies have focused on miRNAs in porcine muscle tissue. Here, we experimentally detected and identified conserved and unique miRNAs from porcine skeletal muscle. Fifty-seven distinct miRNAs were identified, of which 39 have not been reported earlier in the pig. Of these, two miRNAs appear to be novel and pig-specific. Surprisingly, these two differ only by a single nucleotide. A part of their primary transcript was cloned and confirmed by sequencing analysis. Alignment of the two sequences using ClustalW showed that the precursor sequences were almost identical, but the flanking sequences were different, indicating that these two novel miRNAs may represent rapidly evolving miRNAs in the pig genome. The expression patterns of eight miRNAs were characterized by real-time polymerase chain reaction of eight pig tissue samples. The ssc-let-7e and ssc-miR-181b miRNAs were expressed in all tissues analysed. The ssc-let-7c, ssc-miR-125b, ssc-miR-new1 and ssc-miR-new2 miRNAs were expressed in several tissues, while ssc-miR-122 and ssc-miR-206 were specifically expressed in the liver and muscle respectively. Our results add to existing data on porcine miRNAs and are useful for investigating the biological functions of miRNAs in porcine skeletal muscle development. [source]

Mapping of six miRNAs expressed in porcine skeletal muscle

ANIMAL GENETICS, Issue 1 2008
Y. Feng
No abstract is available for this article. [source]

Radiation hybrid mapping of 24 porcine skeletal muscle expressed sequence tags

ANIMAL GENETICS, Issue 3 2006
V. D. Rilington
No abstract is available for this article. [source]

Relationships between physical and structural properties of intramuscular connective tissue and toughness of raw pork

ANIMAL SCIENCE JOURNAL, Issue 1 2009
Takanori NISHIMURA
ABSTRACT We studied the relationships between the shear-force value and physical and structural properties of the intramuscular connective tissue (IMCT) in six classes of porcine skeletal muscle to elucidate the contribution of IMCT to toughness of raw pork. The shear-force value of raw pork correlated significantly with that of the IMCT model prepared from each class of skeletal muscle (P < 0.05). The correlation suggested that the variable toughness of pork was caused by the mechanical strength of the endomysium and perimysium. The thickness of the secondary perimysium correlated significantly with the shear-force value of raw pork (P < 0.05) and with that of the IMCT model (P < 0.05). The shear-force value of raw pork correlated significantly with the total amount of collagen (P < 0.05) but not with the heat-solubility of collagen. We concluded therefore that the thickness of the secondary perimysium determines the mechanical strength of IMCT and contributes to toughness in raw pork. [source]

Fetal programming of fat and collagen in porcine skeletal muscles

JOURNAL OF ANATOMY, Issue 6 2005
J. F. Karunaratne
Abstract Connective tissue plays a key role in the scaffolding and development of skeletal muscle. Pilot studies carried out in our laboratory have shown that the smallest porcine littermate has a higher content of connective tissue within skeletal muscle compared with its largest littermate. The present study investigated the prenatal development of intralitter variation in terms of collagen content within connective tissue and intramuscular fat of the M. semitendinosus. Twenty-three pairs of porcine fetuses from a Large White,Landrace origin were used aged from 36 to 86 days of gestation. The largest and smallest littermates were chosen by weight and the M. semitendinosus was removed from each. Complete transverse muscle sections were stained with Oil Red O (detection of lipids) and immunocytochemistry was performed using an antibody to collagen I. Slides were analysed and paired t -Tests revealed the smallest littermate contained a significantly higher proportion of fat deposits and collagen I content compared with the largest littermate. Recent postnatal studies showing elevated levels of intramuscular lipids and low scores for meat tenderness in the smallest littermate corroborate our investigations. It can be concluded that the differences seen in connective tissue elements have a fetal origin that may continue postnatally. [source]