Project description:Skeletal Myosin binding protein-C (MyBP-C) paralogs, slow (sMyBP-C) and fast (fMyBP-C) interacts with myosin and actin filaments within sarcomeres, modulating the force development during contraction. These display differential expression in muscle fibres, with fMyBP-C higher in fast twitch fibres. However, our knowledge about the changes in the fMyBP-C expression in diseased conditions and its role in skeletal muscle aging is lacking. In this study we use mice model lacking fMyBP-C to understand its significance in skeletal muscle physiology. Skeletal muscle samples from wild type and Mybpc2 knockout (C2-/-)old male mice (22 months) were used to define the role of fMyBP-C in aging. Western immunoblotting was employed to analyze the expression of fMyBP-C and sMyBP-C, and phosphorylation status of sMyBP-C. The impact of C2-/- and aging on the fiber type, size, and number as well as general muscle structure was assessed by immunohistochemistry and electron microscopy. The functional effect of C2-/- and aging was measured in terms of in vivo and ex vivo muscle force generation. Lastly, RNA sequencing was performed to identify the molecular pathways dysregulated in the C2-/- mediated muscle dysfunction in young and old mice. The aged male C2-/- mice compared to their wildtype counterparts, display significant deficits in muscle strength and endurance, accompanied by changes in muscle fiber size and molecular signaling pathways critical for muscle homeostasis.Thus, fMyBP-C is an important regulator of muscle function and homeostasis in the young and aged fast-twitch muscle fibers. The absence of fMyBP-C aggravates the effect of aging on muscle structure and function. fMyBP-C has the potential to be a therapeutic target to modulate muscle wasting caused by aging and disease.

Project description:Fast skeletal myosin binding protein-C (fMyBP-C) is one of three MyBP-C paralogs and is predominantly expressed in fast skeletal muscle. Mutations in the gene that encodes fMyBP-C, MYBPC2, is associated with distal arthrogryposis, while fMyBP-C protein is reduced in diseased muscle. However, the functional and structural roles of fMyBP-C in skeletal muscle remain unclear. To address this gap, we generated a homozygous fMyBP-C knockout mouse (C2-/-) and characterized it, both in vivo and in vitro. Ablation of fMyBP-C was benign in terms of muscle weight, fiber type, cross-sectional area, and sarcomere ultrastructure. However, grip strength and plantar-flexor muscle strength were significantly decreased in C2-/- compared to WT. Peak isometric tetanic force (Po) and isotonic speed of contraction were significantly reduced in isolated extensor digitorum longus (EDL) from C2-/- mice. In EDL muscles of C2-/- mice, small-angle X-ray diffraction revealed significant increase in equatorial intensity ratio (I1.1/I1.0) during contraction, indicating a greater degree of myosin head shift towards actin while MLL4 layer-line intensity was decreased at rest, indicating less ordered myosin heads at rest. Interfilament lattice spacing was also significantly increased in C2-/- EDL muscle compared to WT. Consistent with these findings, we observed a significant reduction of steady-state isometric force during Ca2+ activations, myofilament calcium sensitivity, sinusoidal stiffness in skinned EDL muscle fibers from C2-/- mice. Finally, C2-/- muscles displayed disruption of inflammatory and regenerative genes and increased muscle damage upon mechanical overload. Together, our data suggest that fMyBP-C is essential for maximal speed and force of contraction, sarcomere integrity, and calcium sensitivity in fast twitch muscle.

Project description:Muscle is highly hierarchically organized, with functions shaped by genetically controlled expression of protein ensembles with different isoform profiles at the sarcomere scale. However, it remains unclear how isoform profiles shape whole-muscle performance. We compared two mouse hindlimb muscles, the slow, relatively parallel-fibered soleus and the faster, more pennate-fibered tibialis anterior (TA), across scales: from gene regulation, isoform expression and translation speed, to force-length-velocity-power for intact muscles. Expression of myosin heavy-chain (MHC) isoforms directly corresponded with contraction velocity. The fast-twitch TA with fast MHC isoforms had faster unloaded velocities (actin sliding velocity, Vactin; peak fiber velocity, Vmax) than the slow-twitch soleus. For the soleus, Vactin was biased towards Vactin for purely slow MHC I, despite this muscle's even fast and slow MHC isoform composition. Our multi-scale results clearly identified a consistent and significant dampening in fiber shortening velocities for both muscles, underscoring an indirect correlation between Vactin and fiber Vmax that may be influenced by differences in fiber architecture, along with internal loading due to both passive and active effects. These influences correlate with the increased peak force and power in the slightly more pennate TA, leading to a broader length range of near-optimal force production. Conversely, a greater force-velocity curvature in the near-parallel fibered soleus highlights the fine-tuning by molecular-scale influences including myosin heavy and light chain expression along with whole-muscle characteristics. Our results demonstrate that the individual gene, protein and whole-fiber characteristics do not directly reflect overall muscle performance but that intricate fine-tuning across scales shapes specialized muscle function.

Project description:Skeletal muscle is highly developed after birth, consisting of glycolytic fast- and oxidative slow-twitch fibers; however, the mechanisms of fiber type-specific differentiation are poorly understood. Here, we found an unexpected role for mitochondrial fission in the differentiation of fast-twitch oxidative fibers. Depletion of the mitochondrial fission factor dynamin-related protein 1 (Drp1) in mouse skeletal muscle and cultured myotubes resulted in the specific reduction of fast-twitch muscle fibers independently of respiratory function. Altered mitochondrial fission caused the activation of the Akt/mammalian target of rapamycin (mTOR) pathway via the mitochondrial accumulation of mTOR complex 2 (mTORC2), and rapamycin administration rescued the reduction of fast-twitch fibers in vivo and in vitro. Under Akt/mTOR activation, the mitochondria-related cytokine growth differentiation factor-15 was upregulated, which repressed fast-twitch fiber differentiation. Our findings reveal a novel role for mitochondrial dynamics in the activation of mTORC2 on mitochondria, resulting in the differentiation of muscle fibers.

Project description:Skeletal muscle is a key tissue in human aging, which affects different muscle fiber types unequally. We developed a highly sensitive single muscle fiber proteomics workflow to study human aging and show that the senescence of slow and fast muscle fibers is characterized by diverging metabolic and protein quality control adaptations. Whereas mitochondrial content declines with aging in both fiber types, glycolysis and glycogen metabolism are upregulated in slow but downregulated in fast muscle fibers. Aging mitochondria decrease expression of the redox enzyme monoamine oxidase A. Slow fibers upregulate a subset of actin and myosin chaperones, whereas an opposite change happens in fast fibers. These changes in metabolism and sarcomere quality control may be related to the ability of slow, but not fast, muscle fibers to maintain their mass during aging. We conclude that single muscle fiber analysis by proteomics can elucidate pathophysiology in a sub-type specific manner.

Project description:Loss of muscle mass and function—a hallmark of skeletal muscle aging—is known as sarcopenia. Moreover, mammalian aging is reportedly driven by loss of epigenetic information. However, the effect of epigenetic alterations on skeletal muscle homeostasis is unknown. In this study, we show that chronic elevation of global DNA methylation results in a myopathy-like phenotype and age-related changes in skeletal muscle. Overexpression of muscle de novo methyltransferase 3a (Dnmt3a) increased central nucleus-positive myofibers, predominantly in fast-twitch myofibers, and shifted muscle fiber type to stress-resistant slow-twitch myofibers, accompanied by upregulation of chemokine and immune system-related genes and reduced basal autophagy in skeletal muscle. Dnmt3a overexpression reduced muscle androgen receptor signaling, decreased muscle mass and strength, and impaired tolerance to endurance exercise with age. Network analysis identified Akt1 as a potential hub gene. Dnmt3a expression reduced sensitivity to starvation-induced muscle atrophy by suppressing the FoxO-regulated autophagy and ubiquitin–proteasome systems. These data suggest that increased global DNA methylation disrupts skeletal muscle homeostasis, promotes age-related decline in muscle function, and reduces muscle plasticity.

Project description:This a model from the article: A mathematical model of fatigue in skeletal muscle force contraction. Shorten PR, O'Callaghan P, Davidson JB, Soboleva TK. J Muscle Res Cell Motil 2007;28(6):293-313 18080210 , Abstract: The ability for muscle to repeatedly generate force is limited by fatigue. The cellular mechanisms behind muscle fatigue are complex and potentially include breakdown at many points along the excitation-contraction pathway. In this paper we construct a mathematical model of the skeletal muscle excitation-contraction pathway based on the cellular biochemical events that link excitation to contraction. The model includes descriptions of membrane voltage, calcium cycling and crossbridge dynamics and was parameterised and validated using the response characteristics of mouse skeletal muscle to a range of electrical stimuli. This model was used to uncover the complexities of skeletal muscle fatigue. We also parameterised our model to describe force kinetics in fast and slow twitch fibre types, which have a number of biochemical and biophysical differences. How these differences interact to generate different force/fatigue responses in fast- and slow- twitch fibres is not well understood and we used our modelling approach to bring new insights to this relationship. This model was taken from the CellML repository and automatically converted to SBML. The original model was: Shorten PR, O'Callaghan P, Davidson JB, Soboleva TK. (2007) - version02 This model originates from BioModels Database: A Database of Annotated Published Models (http://www.ebi.ac.uk/biomodels/). It is copyright (c) 2005-2011 The BioModels.net Team. To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information. In summary, you are entitled to use this encoded model in absolutely any manner you deem suitable, verbatim, or with modification, alone or embedded it in a larger context, redistribute it, commercially or not, in a restricted way or not.. To cite BioModels Database, please use: Li C, Donizelli M, Rodriguez N, Dharuri H, Endler L, Chelliah V, Li L, He E, Henry A, Stefan MI, Snoep JL, Hucka M, Le Novère N, Laibe C (2010) BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models. BMC Syst Biol., 4:92.

Project description:The zebrafish u-boot (ubo) gene encodes the transcription factor Prdm1, which is essential for the specification of the primary slow twitch muscle fibres that derive from adaxial cells. Here we show that Prdm1 executes this function by acting as a transcriptional repressor. Expression of the slow twitch isoform of the myosin heavy chain in adaxial cells is achieved by Prdm1 mediated repression of the transcriptional repressor Sox6. Using Chromatin immuno precipitation (ChIP) we found that genes encoding fast specific isoforms of sarcomeric proteins are direct targets of Prdm1. These genes are ectopically expressed in the adaxial cells of ubotp39 mutant embryos, suggesting that Prdm1 promotes slow twitch fibre differentiation by acting both as a global repressor of fast fibre specific genes as well as of a repressor of slow specific genes. Keywords: ChIP-chip

Project description:C18ORF25 is a homolog of Arkadia (RNF111), an E3 ubiquitin ligase with SUMO-interaction motifs (SIMs) (PMID: 31417085). However, C18ORF25 lacks the entire C-terminal RING domain of RNF111 which is required for ubiquitin binding suggesting it lacks ubiquitination activity and may therefore act as an adaptor or signalling scaffold (PMID: 26283374). We have previously shown that mice lacking C18Orf25 throughout the entire body have increased adiposity, decreased lean mass, lower exercise capacity and significantly reduced ex vivo skeletal muscle force production (PMID: 35882232). Skeletal muscle isolated from C18Orf25 knockout (KO) mice have reduced cAMP-dependent protein kinase A (PKA) levels, and reduced phosphorylation of several contractile proteins and proteins involved in calcium handling. Furthermore, analysis of single muscle fibres from C18Orf25 KO mice revealed impaired SR calcium cycling in fast-twitch fibres only (PMID: 35882232). Hence, we investigated these mechanisms by developing an integrated single-fibre physiology and single-fibre proteomic platform. The platform enabled us to identify hundreds of novel phenotype:protein correlations. The analysis also enabled us to identify proteome differences specifically in FT fibres following loss of C18ORF25. Taken together, our data suggest C18ORF25 is likely a multi-functional protein with several underlying mechanisms contributing to skeletal muscle physiology.

Project description:Purpose : The RNA-seq data of 18 skeletal muscle tissues obtained from one Jejunal were sequenced. In this study, we aimed to group multiple tissues by unsupervised clustering of tissues based on expression pattern alone, and to find the criteria for dividing the classified tissues and the causative genes. Method : The raw counts obtained from the STAR 2 pass alignment were obtained. The log2 normalization value of raw counts of each sample is classified by hierarchical clustering. The eighteen samples were classified into two groups of nine each. Differential expression analysis of each group through R package DESeq2 revealed a total of 1104 Differentially expressed genes (DEGs). Result and Conclusion : Based on myosin heavy chain family gene expression in Identified DEGs, the criteria for dividing the two groups were determined by the classification of slow-twitch and fast-twitch muscle according to the content of myosin heavy chain fiber. ?In addition, we confirmed the up-regulation of the genes that are characteristic of the slow-twitch muscle, and identified that the central genes that express these features play a role in maintaining cardiovascular homeostasis.