Project description:We generated and analyzed a conditional Dystrophin flox52/Y: human alpha-skeletal actin muscle knockout (Dmd flox52/Y: HSA mKO) model by targeting exon 52 deletion in the Dystrophin gene to study the consequences of dystrophin loss in skeletal muscle lineages. The generated DMD mouse model ablates dystrophin protein expression after mating with a Cre recombinase transgenic mouse under the control of HSA promoter element that is restricted to the skeletal muscle. The resulting Dmd mKO mice have been assessed using histopathological, phenotypical, functional and biochemical assays based on TRET-NMD standard operating protocols (SOPs) for mdx mouse models. Phenotypic analysis of these conditional Dmd mKO mice revealed a significant decline in locomotor activity and reduced muscle force, motor and muscular function. The histochemical analysis revealed an increase in centralized myonuclei and fibrotic area similar to mdx mice. Immunoassays including western blot and immunohistochemistry confirmed low expression levels of dystrophin in skeletal muscles of Dmd mKO mice. Bulk RNA sequencing analysis revealed that dystrophin loss in myofiber significantly disrupted the expression of cytokines and extracellular matrix genes.

Project description:Myopalladin (MYPN) is a striated muscle-specific protein located in the Z-line and I-band of the sarcomere as well as the nucleus. Analysis of MYPN knockout (MKO) mice showed a 48% reduction in myofiber cross-sectional area in MKO mice and a consequent reduction in isometric force generation and power output. Similarly, reduced myotube width was observed in MKO primary myoblast cultures. RNA-Seq studies revealed downregulation of serum response factor (SRF)-target genes in MKO mice, important for muscle growth and differentiation, and further studies revealed that MYPN, like its homologue PALLD, can bind and bundle filamentous actin as well as interact with MRTF-A, both major players in the regulation of the SRF pathway. Consistently, MYPN increased MRTF-A-mediated activation of SRF signaling in myogenic cells, and transduction of MKO myoblasts with constitutive active SRF rescued the reduced myotube width, demonstrating that MYPN promotes skeletal muscle growth through activation of the SRF pathway.

Project description:Transcriptome analysis of total RNA samples from heart tissue of knockout mice Alternative splicing is the main mechanism to increase protein diversity from an mRNA. Heterogeneous ribonucleoprotein (hnRNP) family members are vital regulators of alternative splicing. The hnRNP A1 is the most well-known protein in this family, but its role in embryonic development is not well understood. We generated hnRNP A1 knockout mice to study the function of hnRNP A1 in vivo. The hnRNP A1-depleted mice showed embryonic lethality because of muscle developmental defects. In a previous study, cellular hnRNP A2/B1 was reported to be capable of compensating for the expression of hnRNP A1. However, this phenomenon did not occur in the hnRNP A1 heterozygous mice in vivo. We demonstrated that hnRNP A1 regulated muscle-related genes expression and alternative splicing. In summary, our data demonstrated that hnRNP A1 plays a critical role in embryonic muscle development. Understanding the effects of hnRNP A1 in vivo may help to define the function of hnRNP A1 in alternative splicing.

Project description:In the present study we have studied the mechanistic and functional aspects of NCoR1 function in mouse skeletal muscle. NCoR1 muscle-specific knockout mice exhibited an increased oxidative metabolism. Global gene expression analysis revealed a high overlap between the effects of NCoR1 deletion and peroxisome proliferator-activated receptor (PPAR) gamma coactivator 1alpha (PGC-1alpha) overexpression on oxidative metabolism in skeletal muscle. The repressive effect of NCoR1 on oxidative phosphorylation gene expression specifically antagonizes PGC-1alpha-mediated coactivation of ERRalpha. We therefore delineated the molecular mechanism by which a transcriptional network controlled by corepressor and coactivator proteins determines the metabolic properties of skeletal muscle, thus representing a potential therapeutic target for metabolic diseases. Gene expression of a total of 20 gastrocnemius samples from control (CON, n = 5), NCoR1 muscle-specific knockout (NCoR1 MKO, n = 5), wild type (WT, n = 5) and PGC-1alpha muscle-specific transgenic (PGC-1alpha mTg, n = 5) adult male mice was analyzed using GeneChip® Gene 1.0 ST Array System (Affymetrix). NCoR1 MKO and PGC-1alpha mTg samples were compared to CON and WT samples, respectively.

Project description:The sarcomere is the muscle contractile unit, whose assembly and disassembly are intimately linked to changes in myofiber size and function. Mutations in sarcomeric proteins are common causes of myopathies, ranging from severe neonatal to adult-onset forms. Here, we identify HECTD1 as an E3 ubiquitin ligase necessary for sarcomere maintenance. We show that silencingHectd1 in myotubesreduces the levels of proteins critical for sarcomere integrity including a-actin, titin, troponins, tropomyosins, and several myosin heavy chain isoforms. We further establish that Hectd1 ubiquitylates and stabilizes the molecular chaperones KLHL40/41, that when dysfunctional destabilize nebulin and other sarcomere thin filament proteins (causing nemaline myopathy). Consequently, skeletal muscle-specific Hectd1 knockout mice (Hectd1 mKO) show progressive muscle weakness, exercise intolerance, and unresolved tissue remodeling. Molecular and histological analysis of Hectd1 mKO muscle revealed subsarcolemmal storage of the scaffold protein desmin, mitochondrial abnormalities, and severe sarcomere disorganization. This work uncovers Hectd1 as an E3 ligase critical for sarcomere assembly, and a novel diagnostic gene for myopathy with features of nemaline and desmin myopathy.

Project description:For additional details see Ebert et al, Identification and Small Molecule Inhibition of an ATF4-dependent Pathway to Age-related Skeletal Muscle Weakness and Atrophy. Quadriceps femoris muscles were harvested from 22-month-old muscle-specfic ATF4 knockout (ATF4 mKO) mice and littermate controls. mRNA levels in ATF4 mKO muscles were normalized to levels in littermate control muscles.

Project description:ATF4 is a fasting-induced trascription factor that promotes skeletal muscle atrophy. The goal of these studies was to determine how of loss of ATF4 affects skeletal muscle mRNA expression. For additional details see Ebert et al, Stress-Induced Skeletal Muscle Gadd45a Expression Reprograms Myonuclei and Causes Muscle Atrophy. JBC epub. June 12, 2012. Muscle-specfic ATF4 knockout (ATF4 mKO) mice and littermate controls were fasted for 24 hours and then tibialis anterior muscles were harvested. mRNA levels in ATF4 mKO muscles were normalized to levels in littermate control muscles.

Project description:Analysis of skeletal muscles with specific knockout (KO) of Phosphatase and tensin homolog (Pten) gene in an animal model of DMD (mdx mice). Pten knockout alleviates myofiber degeneration and restores muscle function in mdx mice.

Project description:Myotonic dystrophy (DM) is a multi-systemic disease that severely impacts cardiac and skeletal muscle functions as well as the central nervous system. DM is unusual because it is RNA-mediated disease due to the expression of C(C)UG expansion RNAs that inhibit the activities of the muscleblind-like (MBNL) proteins. In mice, studies using Mbnl1 and Mbnl2 single knockouts have revealed that Mbnl1 plays a predominant role in skeletal and heart muscle alternative splicing regulation while Mbnl2 performs an analogous splicing function in the brain. However, Mbnl single knockout models fail to recapitulate the full-range of adult-onset DM muscle symptoms. Here, we report that Mbnl1; Mbnl2 double knockouts are embryonic lethal while Mbnl1-/-; Mbnl2+/- mice, which express no Mbnl1 and reduced levels of Mbnl2, are viable but develop cardinal features of adult-onset DM cardiac and skeletal muscle disease including reduced lifespan, heart conduction block, severe myotonia and progressive skeletal muscle weakness. Mbnl2 protein levels are elevated in both Mbnl1-/- and Mbnl1-/-; Mbnl2+/- knockouts where Mbnl2 targets Mbnl1-regulated exons. These findings support the MBNL loss-of-function model for DM and provide novel Mbnl compound knockout models to investigate the molecular pathways disrupted by RNA-mediated disease. Mbnl2 protein-RNA interactions were assessed in 4-month-old WT and Mbnl1-/- quadriceps muscles in triplicates by HITS-CLIP.

Project description:The ubiquitin-proteasome and autophagy-lysosome pathways are the two major routes for protein and organelle clearance. In skeletal muscle, both systems’ excessive activation induces severe muscle loss. Although altered proteasomal function has been observed in various myopathies, the specific role of proteasomal activity in skeletal muscle has not been determined by loss-of-function approaches. Here, we report that muscle-specific deletion of a crucial proteasomal gene, Rpt3, resulted in profound muscle atrophy and decrease in force. Rpt3 null muscles showed reduced proteasomal activity in early age, accumulation of basophilic structure, disorganization of sarcomere, and formation of vacuoles and concentric membranous structures in electronmicroscope. We also observed accumulation of ubiquitin, p62, LC3, TDP43, FUS and VCP proteins. Proteasomal activity is important to preserve muscle mass and to maintain myofiber integrity. Our results suggest that inhibition/alteration of proteasomal activity can contribute to myofiber degeneration and weakness in muscle disorders, such as inclusion body myositis, characterized by accumulation of abnormal inclusions. Tibialis anterior muscles from Rpt3 null and control mice. each 3 mice.