Project description:Myostatin is a highly conserved Transforming Growth Factor beta family member which negatively regulates muscle development. Double-muscled (DM) cattle have a loss-of-function mutation in their myostatin gene responsible for a hypermuscular phenotype mainly due to hyperplasia. Thus these animals represent a good model for understanding the mechanisms at the origin of muscular hypertrophy. In order to identify individual genes or networks that may be myostatin targets, we looked for genes differentially expressed between DM and normal (NM) animals (n=3 per group) in the semitendinosus muscle (a hypertrophied muscle in DM animals) at 260 days of fetal development (intensive muscle biochemical differentiation). The experiment was carried out using muscle-dedicated high density oligonucleotide arrays of around 6,000 muscle specific genes. A great number of genes was found to be differentially expressed according to the genetic type (some with a change higher than 5-fold), and according to the zygosity of the myostatin mutation. They belonged to various functional categories. The genes down-regulated in DM fetuses corresponded mainly to genes encoding extracellular matrix proteins, slow contractile proteins and ribosomal proteins. On the other hand, the genes up-regulated in DM fetuses were involved mainly in the regulation of transcription, cell cycle/apoptosis, translation, or DNA metabolism. These data singled out features indicating that DM muscle had shifted towards a more glycolytic metabolism, had an altered extracellular matrix composition (e.g. down-regulation of COL1A1, COL1A2, and up-regulation of collagen IV) and a decreased adipocyte differentiation (down-regulation of C1QTNF3). Altered gene expression in the three major muscle compartments (e.g. fibers, connective tissue and intramuscular adipose tissue) is in agreement with the well known characteristics of DM cattle. In addition, novel potential targets of the myostatin gene were identifed. Thus, the myostatin loss-of-function mutation affected several physiological processes involved in the development and the determinism of the functional characteristics of the muscle tissue. Transcriptomic profiling of Semitendinosus (ST) muscle of three double-muscled fetuses were analyzed relative to three conventional fetuses. Each individual sample was compared to a reference pool. Four chips were hybridized per sample comparison.

Project description:Background: The aim of this study is to improve our understanding of the mechanisms underlying the sparing of masticatory muscles relative to limb muscles in ICU patients with acute quadriplegic myopathy (AQM) by using a unique porcine ICU model, i.e., 5-day longitudinal experiments where animals are sedated, mechanically ventilated and exposed to factors triggering AQM, such as muscle unloading, endotoxin-induced sepsis, and systemic exposure to CS and NMBA. Results: An altered expression was notably observed in heat-shock proteins genes, sarcomeric proteins and myostatin genes were noticed. Hence, modifications in heat-shock proteins, sarcomeric proteins and myostatin genes are in sharp contrast to alterations in the limb muscles and it is postulated that elevated heat-shock proteins and decreased sarcomeric protein and myostatin genes play a protective role in the masticatory muscle relative to limb muscle in ICU patients with AQM. Conclusions: This intervention had no significant effect on masseter muscle fiber size or force-generation capacity. This is in sharp contrast to the dramatic decrease observed in specific force in limb muscle fibers from the same animals. However, significant differences were observed between the craniofacial and the limb muscle with a masseter muscle specific regulation of i) transcriptional and growth factors like RUNX1, FOXO1A, TBX1, PGC1-β and myostatin, ii) several heat shock protein genes like HSP 90, HSP 105/110 and αB-crystallin, iii) a matrix metalloproteinase inhibitor (TIMP2) and iv) oxidative stress responsive elements such as SRXN1 and SOD2. These muscle-type specific differences, the alterations in heat shock protein, sarcomeric protein and myostatin genes are forwarded as important factors underlying the sparing of masticatory muscles compared with limb muscles in critically ill ICU patients with Acute Quadriplegic Myopathy. Keywords: Treatment, immobilization, muscle function.

Project description:Texel and Ujumqin sheep show obvious differences in muscle and fat growth, so they are ideal models not only to understand the molecular mechanism in prenatal skeletal muscle development, but to identify the potential target genes of myostatin. To elucidate the phenotypic variation between the two sheep breeds and the dynamic characteristics of gene expression in skeletal muscle during the development, we examined the development of skeletal muscle in transcriptome-wide level at 70, 85,100,120 , 135 days post coitus (dpc),birth, 1 month and 2 month. Using the specialized and standardized sheep transcriptome-wide oligo DNA microarray (Agilent), we analyzed the transcriptomic profiles of longissmuss dorsi muscle from fetuses of Texel and Ujumqin sheep. We characterized dynamic transcriptome-wide profiles that accompany the prenatal skeletal muscle and fat development in Texel and Ujumqin sheep respectively, and compared the difference in profiles of gene expression between the two sheep breeds at the same developmental stage.Some potential myostatin target genes and other genes controlling the growth of skeletal muscle and adipose were identified for further examinations. Our findings not only contribute to understand the molecular mechanism of prenatal skeletal muscle development in large precocial species, but also provide some clues for human myopathy and obesity at prenatal stages. Moreover, we also can identify putative candidate genes for meat quality traits in farm animals.

Project description:Background: The aim of this study is to improve our understanding of the mechanisms underlying the sparing of masticatory muscles in ICU patients with acute quadriplegic myopathy (AQM) by using a unique porcine ICU model, i.e., 5-day longitudinal experiments where animals are sedated, mechanically ventilated and exposed to factors triggering AQM, such as muscle unloading, endotoxin-induced sepsis, and systemic exposure to CS and NMBA. Results: An increased expression was notably observed in atrogin-1, cathepsins, FoxO1a, runx1 and heat-shock proteins genes. A decreased expression in some sarcomeric proteins and myostatin genes was also noticed. Hence, modifications in heat-shock proteins and myostatin genes are in sharp contrast to alterations in the limb muscles and it is postulated that elevated heat-shock proteins and decreased myostatin genes play a protective role in the masticatory muscle in ICU patients with AQM. Conclusions: We have observed a general down-regulation of muscle proteins and myostatin. Genes involved in the UPS system, cathepsins, RUNX1, TBX1, TIMP2 and transcripts of heat-shock proteins were up-regulated. However, we have neither observed a decrease in fiber CSA or force generation, suggesting that the expected atrophic changes have been countered by a protective mechanism and myostatin downregulation. Five female domestic piglets were treated with non-depolarizing neuromuscular blocking agents (NMBA), corticosteroids(CS) and sepsis. Five female piglets were untreated.

Project description:In the present study, a oligonucleotide microarray platform is used to compare expression profiles of beef cattle muscle in animals treated with either Dexamethazone (Dex) or Dexamethazone plus 17β-estradiol (Estr) administered at sub-therapeutic dosage, against untreated controls. Seventeen male beef cattle 15-18 months old, around 450 kg mean body weight were randomly allocated in three groups: 6 were untreated (group Ctrl), 5 were administered with dexamethazone via feed 0.75mg/head for 43 days (group D); the last 6 animals were administered via feed for 43 days with Dex (0.75mg/head) and intramuscularly (i.m.) for three times with 17β-oestradiol, 20mg/head, (group DE). Three additional control animals, matching in sex and age, collected in a previous experiment were included in the Ctrl group to increase sample size and to control for biological variation. For each sample, total RNA was extracted from a specific anterior limb muscle (biceps branchii). Data analysis demonstrates that the expression profiles were strongly affected by Dex treatment with hundreds of genes up-regulated with relevant fold-change, whereas the myostatin gene was significantly down-regulated. On the contrary, the administration of Dex-Estr reveals a weaker effect on gene expression.

Project description:GDF8 (myostatin) is a unique cytokine strongly affecting the skeletal muscle phenotype in human and animals. The aim of the present study was to elucidate the molecular mechanism of myostatin influence on the differentiation of mouse C2C12 myoblasts, using the global-transcriptome analysis with the DNA microarray technique. Treatment with exogenous GDF8 strongly affected the growth and development of C2C12 mouse myoblasts. This was manifested by the inhibition of proliferation and differentiation as well as the impairment of cell fusion. DNA microarray analysis revealed 778 genes regulated by GDF8 in differentiating myoblasts. Ontological analysis revealed their involvement in 17 types of biological processes, 10 types of molecular functions and 68 different signaling pathways. The effect of GDF8 was mainly mediated by the disruption of the cell cycle, calcium and insulin signaling pathways and expression of cytoskeletal and muscle specific proteins.

Project description:Texel and Ujumqin sheep show obvious differences in muscle and fat growth, so they are ideal models not only to understand the molecular mechanism in prenatal skeletal muscle development, but to identify the potential target genes of myostatin. To elucidate the phenotypic variation between the two sheep breeds and the dynamic characteristics of gene expression in skeletal muscle during the development, we examined the development of skeletal muscle in transcriptome-wide level at 70, 85,100,120 , 135 days post coitus (dpc),birth, 1 month and 2 month. Using the specialized and standardized sheep transcriptome-wide oligo DNA microarray (Agilent), we analyzed the transcriptomic profiles of longissmuss dorsi muscle from fetuses of Texel and Ujumqin sheep. We characterized dynamic transcriptome-wide profiles that accompany the prenatal skeletal muscle and fat development in Texel and Ujumqin sheep respectively, and compared the difference in profiles of gene expression between the two sheep breeds at the same developmental stage.Some potential myostatin target genes and other genes controlling the growth of skeletal muscle and adipose were identified for further examinations. Our findings not only contribute to understand the molecular mechanism of prenatal skeletal muscle development in large precocial species, but also provide some clues for human myopathy and obesity at prenatal stages. Moreover, we also can identify putative candidate genes for meat quality traits in farm animals. Longissimus dorsi muscles were sampled from five prenatal development stages (70, 85, 100, 120 and 135 day of gestation) in Texel and eight development stages (at 70, 85, 100, 120, 135 days post coitus (dpc), birth, 1 month and 2 month) in Ujumqin sheep. There were at least three replicates at each development time in each breed. Two gene expression experiments were conducted with a total of 40 hybridizations.

Project description:Identification of target genes of myostatin loss-of-function in the muscle of bovine fetuses

Project description:Skeletal muscle, the most abundant body’s tissue, plays vital roles in locomotion and metabolism. Myostatin is a negative regulator of skeletal muscle mass. In addition to increase muscle mass, Myostatin inhibition impacts on muscle contractility and energy metabolism. To decipher the mechanisms of action of the Myostatin inhibitors, we used proteomic and transcriptomic approaches to investigate the changes induced in skeletal muscles of transgenic mice overexpressing Follistatin, a physiological Myostatin inhibitor. Our proteomic workflow included a fractionation step to identify weakly expressed proteins and a comparison of fast versus slow muscles. Functional annotation of altered proteins supports the phenotypic changes induced by Myostatin inhibition, including modifications in energy metabolism, fiber type, insulin and calcium signaling, as well as membrane repair and regeneration. Less than 10% of the differentially expressed proteins were found to be also regulated at the mRNA level but the Biological Process annotation and the KEGG pathways analysis of transcriptomic results showed a great concordance with the proteomic data. Thus, this study describes the most extensive omics analysis of muscle overexpressing Follistatin, providing molecular-level insights to explain the observed muscle phenotypic changes

Project description:Inhibition of myostatin signaling induces strong skeletal muscle growth making it an attractive target to treat muscle wasting and sarcopenia. However, the biological function of myostatin in the heart is barely understood. We demonstrate that conditional inactivation of myostatin in the adult murine heart leads to cardiac hypertrophy, heart failure and increased lethality. To induce cardiomyocyte specific loss of myostatin a conditionally active Mstn^fl/fl allele was generated by insertion of loxP elements upstream and downstream of exons 1 and 2 of the mouse myostatin gene. The selection cassette was removed in vivo by flp-recombination. To inactivate myostatin, mice were mated to alphaMyHC-MCM mice (Sohal, DS, et al. (2001) Circulation Research 89, 20-25). Cre-recombination was achieved by intraperitoneal administration of Tamoxifen (40 mg/kg) for 5 consecutive days. The respective control alphaMyHC-MCM animals were equally treated.