Project description:The samples consist of cells from two muscle types in mice – rotator cuff and gastrocnemius muscles. The aim of the project is to study the methylation differences between the two muscle types, specifically in genes involved in adipogenesis and muscle regeneration in the rotator cuff muscle with the gastrocnemius muscle being the control.

Project description:Myosteatosis, also known as fatty infiltration, is the pathological accumulation of lipid that occurs in conjunction with atrophy and fibrosis following rotator cuff injury. Little is known about the mechanisms by which lipid accumulates in myosteatosis, but many studies have demonstrated the degree of lipid infiltration negatively correlates with muscle function and regeneration. Identifying how reduced mechanical loading activates molecular pathways that lead to myosteatosis could help to develop targeted therapies to improve functional outcomes after rotator cuff repair. Our objective was to use cutting compare muscle fiber contracility, proteomic, RNA sequencing and shotgun metabolomics along with bioinformatics to identify potential pathways and cellular processes that are dysregulated after rotator cuff teaar.

Project description:Myosteatosis is the pathological accumulation of lipid that occurs in conjunction with atrophy and fibrosis following skeletal muscle injury or disease. Little is known about the mechanisms by which lipid accumulates in myosteatosis, but many studies have demonstrated the degree of lipid infiltration negatively correlates with muscle function and regeneration. Our goal was to identify biochemical pathways that lead to muscle dysfunction and lipid accumulation in injured rotator cuff muscles, a model that demonstrates severe myosteatosis. Adult rats were subjected to a massive tear to the rotator cuff musculature. After a period of either 0 (healthy control), 10, 30, or 60 days, muscles were prepared for RNA sequencing, shotgun lipidomics, metabolomics, biochemical measures, electron microscopy, and muscle fiber contractility. Following rotator cuff injury, there was a decrease in muscle fiber specific force production that was lowest at 30d. There was a dramatic time dependent increase in triacylglyceride content. Interestingly, genes related to not only triacylglyceride synthesis, but also lipid oxidation were largely downregulated over time. Using bioinformatics techniques, we identified that biochemical pathways related to mitochondrial dysfunction and reactive oxygen species were considerably increased in muscles with myosteatosis. Long chain acyl-carnitines and L-carnitine, precursors to beta-oxidation, were depleted following rotator cuff tear. Electron micrographs showed injured muscles displayed large lipid droplets within mitochondria at early time points, and an accumulation of peripheral segment mitochondria at all time points. Several markers of oxidative stress were elevated following rotator cuff tear. The results from this study suggest that the accumulation of lipid in myosteatosis is not a result of canonical lipid synthesis, but occurs due to decreased lipid oxidation in mitochondria. A failure in lipid utilization by mitochondria would ultimately cause an accumulation of lipid even in the absence of increased synthesis. Further study will identify whether this process is required for the onset of myosteatosis.

Project description:Rotator cuff tear is a common disease in elderly patients. The satellite cell has central role of muscle regeneration, however, there are few reports about human muscle. The purpose of this study was to compare features of human myogenic and adipogenic precursors in both torn supraspinatus (SSP) and intact subscapularis (SSC). Comprehensive gene expression patterns were compared between SSP and SSC muscles by microarray analisys.

Project description:Transcriptional Evidence for Transient Regulation of Muscle Regeneration by Brown Adipose Transplant in the Rotator Cuff

Project description:In this study, we collected rabbit supraspinatus muscle tissue with higher temporal resolution (1, 2, 4, 8, 16 weeks) post-tenotomy (n=6/group), where muscle degeneration occurs at later time points, to determine if transcriptional changes occur. RNA sequencing and analyses were performed using standard techniques to identify a transcriptional timeline of rotator cuff muscle changes and related morphological sequelae.

Project description:In this study, we collected rabbit supraspinatus muscle tissue with higher temporal resolution (1, 2, 4, 8 weeks)after 8 wk tear followed by repair (n=4/group), to determine time-depenet transcriptional changes after repair. RNA sequencing and analyses were performed using standard techniques to identify a transcriptional timeline of rotator cuff muscle changes and related morphological sequelae.

Project description:Conditions affecting skeletal muscle, such as chronic rotator cuff tears, low back pain, dystrophies, and many others often share changes in muscle phenotype: intramuscular adipose and fibrotic tissue increase while contractile tissue is lost. The underlying changes in cell populations and cell ratios observed with these phenotypic changes complicate the interpretation of tissue-level transcriptional data. Novel single cell transcriptomics has limited capacity to address this problem because muscle fibers are too long to be engulfed in single cell droplets and single nuclei transcriptomics are complicated by muscle fibers’ multinucleation. Therefore, the goal of this project was to evaluate the potential and challenges of a spatial transcriptomics technology to add dimensionality to transcriptional data in an attempt to better understand regional cellular activity in heterogeneous skeletal muscle tissue.

Project description:Rat Rotator Cuff Tear RNASeq

Project description:Torn supraspinatus muscle vs. intact subscapularis muscle in rotator cuff tears patients