Project description:The ovine Callipyge mutation causes postnatal muscle hypertrophy localized to the pelvic limbs and torso, as well as body leanness. The mechanism underpinning enhanced muscle mass is unclear, as is the systemic impact of the mutation. Using muscle fibre typing immunohistochemistry we confirmed muscle specific effects and demonstrated that affected muscles had greater prevalence and hypertrophy of type 2X fast twitch glycolytic fibres and decreased representation of types 1, 2C, 2A and/or 2AX fibres. To investigate potential systemic effects of the mutation, proton NMR spectra of plasma taken from lambs at 8 and 12 weeks of age were measured. Multivariate statistical analysis of plasma metabolite profiles demonstrated effects of development and genotype but not gender. Plasma from Callipyge lambs at 12 weeks of age, but not 8 weeks, was characterized by a metabolic profile consistent with contributions from the affected hypertrophic fast twitch glycolytic muscle fibres. Microarray analysis of the perirenal adipose tissue depot did not reveal a transcriptional effect of the mutation in this tissue. We conclude that there is an indirect systemic effect of the Callipyge mutation in skeletal muscle in the form of changes of blood metabolites, which may contribute to secondary phenotypes such as body leanness. Microarrays were used for transcription profiling of kidney fat samples taken from Callipyge (n=4) and wild type (n=4) lambs at 12 weeks of age.

Project description:The ovine Callipyge mutation causes postnatal muscle hypertrophy localized to the pelvic limbs and torso, as well as body leanness. The mechanism underpinning enhanced muscle mass is unclear, as is the systemic impact of the mutation. To investigate potential systemic effects of the mutation, 1H NMR spectra of plasma taken from lambs at 8 and 12 weeks of age were measured. Multivariate statistical analysis of plasma metabolite profiles demonstrated effects of development and genotype but not gender. Plasma from Callipyge lambs at 12 weeks of age, but not 8 weeks, was characterized by a metabolic profile consistent with contributions from the affected hypertrophic fast twitch glycolytic muscle fibres. We conclude that there is an indirect systemic effect of the Callipyge mutation in skeletal muscle in the form of changes of blood metabolites, which may contribute to secondary phenotypes such as body leanness.

Project description:The callipyge mutation causes postnatal muscle hypertrophy in heterozygous lambs that inherit a paternal callipyge allele (+/CLPG). Our hypothesis was that the up-regulation of one or both of the affected paternally expressed genes (DLK1 or PEG11) initiates changes in biochemical and physiological pathways in skeletal muscle to induce hypertrophy. The goal of this study was to identify changes in gene expression during the onset of muscle hypertrophy in order to identify the pathways that are involved in the expression of the callipyge phenotype. Gene expression was analyzed in longissimus dorsi total RNA from lambs at 10, 20, and 30 days of age using the Affymetrix Bovine Expression Array. Experiment Overall Design: Longissimus dorsi were collected from 10, 20, and 30 day old callipyge and normal lambs with 2 biological replicates for each group. Total RNA was isolated and hybridized to Affymetrix Bovine Expression arrays. Data were analyzed in SAS and all genotype effects were followed up by qPCR in 42 lambs ranging from 10 to 200 days of age.

Project description:The callipyge mutation causes postnatal muscle hypertrophy in heterozygous lambs that inherit a paternal callipyge allele (+/CLPG). Our hypothesis was that the up-regulation of one or both of the affected paternally expressed genes (DLK1 or PEG11) initiates changes in biochemical and physiological pathways in skeletal muscle to induce hypertrophy. The goal of this study was to identify changes in gene expression during the onset of muscle hypertrophy in order to identify the pathways that are involved in the expression of the callipyge phenotype. Gene expression was analyzed in longissimus dorsi total RNA from lambs at 10, 20, and 30 days of age using the Affymetrix Bovine Expression Array. Keywords: time course

Project description:Lambs that inherit a callipyge allele from their dam have an up-regulation of maternally imprinted transcripts near the callipyge mutation but do not exhibit muscle hypertrophy. It is not clear what effects these maternally expressed transcripts have in the muscle or how the inheritance of a maternal callipyge allele prevents the expression of the callipyge phenotype which is seen paternal heterozygotes only. This experiment utilized bovine gene expression arrays to profile the gene expression of the semimembranosus muscle of 30 day old half-sibling lambs of all four possible genotypes with respect to the callipyge allele (+/+, C/+, +/C, and C/C). Keywords: allele effect

Project description:Lambs that inherit a callipyge allele from their dam have an up-regulation of maternally imprinted transcripts near the callipyge mutation but do not exhibit muscle hypertrophy. It is not clear what effects these maternally expressed transcripts have in the muscle or how the inheritance of a maternal callipyge allele prevents the expression of the callipyge phenotype which is seen paternal heterozygotes only. This experiment utilized bovine gene expression arrays to profile the gene expression of the semimembranosus muscle of 30 day old half-sibling lambs of all four possible genotypes with respect to the callipyge allele (+/+, C/+, +/C, and C/C). Experiment Overall Design: 10 lambs were used for this study. N=3 biological reps for C/C genotype, N=3 biological reps for Cmat/+ genotype, N=2 biological reps for +/Cpat genotype, and N=2 biological reps for +/+ genotype. Pairwise contrasts were performed to analyze the presence of a maternally inherited callipyge allele and the effect on a homozygous animal (+/C vs CC; +/+ vs C/+; and C/+ vs C/C). Experiment Overall Design: These data make up two experiments. Experiment Overall Design: [1] The maternal allele (4 genotype) experiment compares all four possible genotypes of a particular allele at one age and one tissue (30 days semimembranosus). Experiment Overall Design: [2] The paternal allele (2 genotype) experiment compares only the NC and the NN genotypes in one tissue (SM) across 4 ages (10, 20, 30, and 80 days). Experiment Overall Design: Images were interpreted with Microarray Suite version 5.0 (MAS5.0) in GCOS with no scaling or normalization (i.e., Samples GSM298143-GSM298164). Images were also interpreted by RMA using Bioconductor package of R (i.e., Samples GSM298165-GSM298186).

Project description:Expression data from Sheep longissimus dorsi (LD) muscle during development; fetal lambs (80, 100, 120 days gestation), new born lambs at birth (150 d) and lambs at 12 weeks (230 d) The fetal to neonatal developmental transition corresponds with profound changes in skeletal muscle function as it adapts to the new physiological demands of locomotion and postural support against gravity. The mechanisms underpinning this adaption process are unclear but are likely to be initiated by changes in hormone levels occurring during the major developmental transition. We tested the hypothesis that this period is associated with changes in the transcription of skeletal muscle genes, particularly genes involved in oxidative metabolism. Using an ovine model, transcriptional profiling was performed on longissimus dorsi skeletal muscle taken at three fetal developmental time points (80, 100 and 120 d of fetal development) as well as two postnatal time points, one within 3 days after birth and a second at 12 weeks of age. The developmental time course was dominated by large changes in the expression of 2471 genes during the period from late fetal development (120 d fetal development) to birth (within 1-3 days of birth). Analysis of the functions of the genes that were uniquely up-regulated in this period showed strong enrichment for oxidative metabolism and the TCA cycle indicating enhanced mitochondrial activity. Indeed, histological examination of tissues from these developmental time points directly demonstrated a marked increase in mitochondrial activity between the late fetal and early post-natal samples. The genes that were down-regulated in this period suggested de-emphasis of an array of biological functions including Wnt signaling, cell adhesion and differentiation. There were also changes in the expression of genes prior to this late fetal – postnatal transition and between the two postnatal time points that involved a variety of biological functions. It is concluded that there is substantial and coordinated changes in the transcription of a large number of genes in skeletal muscle which underpin the adaption of muscle to the new physiological demands in the postnatal environment. Microarrays were used for transcription profiling of skeletal muscle samples taken from fetal lambs (80, 100, 120 days gestation), new born lambs at birth (150 d) and lambs at 12 weeks (230 d) Sheep used in this experiment were bred from a research flock of Dorset/Suffolk/Rambouillet cross-bred sheep raised at Utah State University and cared for and euthanased for sample collection in accordance with the animal ethics guidelines of Utah State University (Utah, USA). Longissimus dorsi (LD) skeletal muscle samples were taken from fetal lambs at 80, 100 and 120 days of gestation, new born lambs within 1 to 3 days of birth (i.e. 150 days of development) and young lambs at 12 weeks of age (230 days of development). Three individuals were sampled at each developmental time

Project description: In fish, the slow-twitch skeletal muscle fibres have an oxidative metabolism, present peripherical location in the red muscle, and are used for sustained movements. They may respond to alterations in food availability differently than the fast-twitch muscle. The aim of this manuscript was to study the slow-twitch muscle fibres of Piaractus Mesopotamicus, a neotropical fish, submitted to 30 days of fasting (D30) followed by one day (D31) or 30 days of refeeding (D60). The treated animals were compared with regularly fed fish. To verify the presence of atrophy and hypertrophy, we performed histological analysis of muscle fibre diameter in D30 and D60, and RT-qPCR gene expression analysis of catabolic (murfa, murfb, mafbx) and anabolic genes (igf-1, mTOR) in D30, D31 and D60. The gene expression of the allergen and Ca2+-carrier parvalbumin (pvalb) was also measured in D30, D31 and D60. The proteome of slow-twitch fibres at D30 and D60 was obtained by shotgun proteomics (digestion of proteins with trypsin followed by LC-MS/MS identification), and the proteins differentially expressed were used to construct protein interaction networks. The histological analysis showed no difference between treated fish in relation to the control. The expression of catabolic and anabolic genes was not changed, except for the negative regulation of igf-1 in D30 and of mtor in D31. The expression of pvalb was not changed in D30 and D60, but it was decreased in D31. The proteomic analysis identified 169 proteins in D30 (24 upregulated and 18 downregulated) and 170 proteins in D60 (17 upregulated and 21 downregulated). Many of them were related to energetic metabolism, including lipid metabolism, as shown by the protein network analysis. These results enlarge our understanding of the acclimation of slow-twitch fibres to changes in nutrient availability and set a path for future research.

Project description:Muscle gene expression of lambs with maternal callipyge allele

Project description:Transcriptome analysis by RNA-seq of tibialis anterior muscle from control and Smyd1 myocyte-specific conditional knockout mice at 6 weeks of age. Smyd1 is a methyltransferase specifically expressed in striated muscle and CD8+ T cells. Smyd1 deficiency resulted in centronuclear myopathy primarily affecting fast-twitch muscle fibers. These results provide insight into how loss of Smyd1 altered transcriptional programs resulting in centronuclear myopathy.