Angiotensin 1-7 increases fiber cross-sectional area and force in juvenile mouse skeletal muscle.

Recent studies reported that in skeletal muscle angiotensin 1-7 (Ang 1-7), via its receptor Mas (MasR), prevents the atrophy induced by angiotensin II and by cast immobilization; it also improves muscle integrity and function in the mdx mouse, a muscular dystrophy model. The objectives of this study were to document 1) the extent of the Ang 1-7's hypertrophic effect in terms of muscle mass and muscle fiber cross-sectional area (CSA), 2) how Ang 1-7 affects muscle contractile function in terms of twitch and tetanic force, force-frequency relationship, and 3) whether the effect involves MasR. Wild-type and MasR-deficient [Mas receptor knockout mouse model (MasR-/-)] mice were treated with Ang 1-7 (100 ng/kg body wt·min using an osmotic pump) for 4 or 16 wk. Ang 1-7 significantly increased skeletal muscle/body weight ratio of soleus, tibialis, and gastrocnemius, but not of extensor digitorum longus (EDL). It significantly increased fiber cross-sectional area in the order of type I > IIA > IIB. In EDL and soleus muscles, it significantly increased twitch and tetanic force while causing a shift in the force-frequency relationship toward lower stimulation frequencies. It had no effect on fiber type composition. None of the Ang 1-7 effects observed in wild-type mice were observed in MasR-/- muscles. It caused a transient increase in phosphorylated protein kinase B (Akt) and 4EBP proteins while having no effect on S6 phosphorylation, MuRF-1, and atrogin-1 and a decrease in PAX7 expression in satellite cells. This is the first study demonstrating the hypertrophic effects of Ang 1-7 in normal muscle acting via its MasR.

The role of L-type amino acid transporter 1 (Slc7a5) during in vitro myogenesis.

Satellite cells are required for muscle regeneration, remodeling, and repair through their activation, proliferation, and differentiation; however, how dietary factors regulate this process remains poorly understood. The L-type amino acid transporter 1 (LAT1) transports amino acids, such as leucine, into mature myofibers, which then stimulate protein synthesis and anabolic signaling. However, whether LAT1 is expressed on myoblasts and is involved in regulating myogenesis is unknown. The aim of this study was to characterize the expressional and functional relevance of LAT1 during different stages of myogenesis and in response to growth and atrophic conditions in vitro. We determined that LAT1 is expressed by C2C12 and human primary myoblasts, and its gene expression is lower during differentiation (P < 0.05). Pharmacological inhibition and genetic knockdown of LAT1 impaired myoblast viability, differentiation, and fusion (all P < 0.05). LAT1 protein content in C2C12 myoblasts was not significantly altered in response to different leucine concentrations in cell culture media or in two in vitro atrophy models. However, LAT1 content was decreased in myotubes under atrophic conditions in vitro (P < 0.05). These findings indicate that LAT1 is stable throughout myogenesis and in response to several in vitro conditions that induce muscle remodeling. Further, amino acid transport through LAT1 is required for normal myogenesis in vitro.

C/EBPß promotes the expression of atrophy-inducing factors by tumours and is a central regulator of cancer cachexia.

BACKGROUND: CCAAT/enhancer-binding protein ß (C/EBPß) is a transcription factor whose high expression in human cancers is associated with tumour aggressiveness and poor outcomes. Most advanced cancer patients will develop cachexia, characterized by loss of skeletal muscle mass. In response to secreted factors from cachexia-inducing tumours, C/EBPß is stimulated in muscle, leading to both myofibre atrophy and the inhibition of muscle regeneration. Involved in the regulation of immune responses, C/EBPß induces the expression of many secreted factors, including cytokines. Because tumour-secreted factors drive cachexia and aggressive tumours have higher expression of C/EBPß, we examined a potential role for C/EBPß in the expression of tumour-derived cachexia-inducing factors. METHODS: We used gain-of-function and loss-of-function approaches in vitro and in vivo to evaluate the role of tumour C/EBPß expression on the secretion of cachexia-inducing factors. RESULTS: We report that C/EBPß overexpression up-regulates the expression of 260 secreted protein genes, resulting in a secretome that inhibits myogenic differentiation (-31%, P < 0.05) and myotube maturation [-38% (fusion index) and -25% (myotube diameter), P < 0.05]. We find that knockdown of C/EBPß in cachexia-inducing Lewis lung carcinoma cells restores myogenic differentiation (+25%, P < 0.0001) and myotube diameter (+90%, P < 0.0001) in conditioned medium experiments and, in vivo, prevents muscle wasting (-51% for small myofibres vs. controls, P < 0.01; +140% for large myofibres, P < 0.01). Conversely, overexpression of C/EBPß in non-cachectic tumours converts their secretome into a cachexia-inducing one, resulting in reduced myotube diameter (-41%, P < 0.0001, EL4 model) and inhibition of differentiation in culture (-26%, P < 0.01, EL4 model) and muscle wasting in vivo (+98% small fibres, P < 0.001; -76% large fibres, P < 0.001). Comparison of the differently expressed transcripts coding for secreted proteins in C/EBPß-overexpressing myoblasts with the secretome from 27 different types of human cancers revealed ~18% similarity between C/EBPß-regulated secreted proteins and those secreted by highly cachectic tumours (brain, pancreatic, and stomach cancers). At the protein level, we identified 16 novel secreted factors that are present in human cancer secretomes and are up-regulated by C/EBPß. Of these, we tested the effect of three factors (SERPINF1, TNFRSF11B, and CD93) on myotubes and found that all had atrophic potential (-33 to -36% for myotube diameter, P < 0.01). CONCLUSIONS: We find that C/EBPß is necessary and sufficient to induce the secretion of cachexia-inducing factors by cancer cells and loss of C/EBPß in tumours attenuates muscle atrophy in an animal model of cancer cachexia. Our findings establish C/EBPß as a central regulator of cancer cachexia and an important therapeutic target.

SMAD2 promotes myogenin expression and terminal myogenic differentiation.

SMAD2 is a transcription factor, the activity of which is regulated by members of the transforming growth factor ß (TGFß) superfamily. Although activation of SMAD2 and SMAD3 downstream of TGFß or myostatin signaling is known to inhibit myogenesis, we found that SMAD2 in the absence of TGFß signaling promotes terminal myogenic differentiation. We found that, during myogenic differentiation, SMAD2 expression is induced. Knockout of SMAD2 expression in primary myoblasts did not affect the efficiency of myogenic differentiation but produced smaller myotubes with reduced expression of the terminal differentiation marker myogenin. Conversely, overexpression of SMAD2 stimulated myogenin expression, and enhanced both differentiation and fusion, and these effects were independent of classical activation by the TGFß receptor complex. Loss of Smad2 in muscle satellite cells in vivo resulted in decreased muscle fiber caliber and impaired regeneration after acute injury. Taken together, we demonstrate that SMAD2 is an important positive regulator of myogenic differentiation, in part through the regulation of Myog.

Combinatorial Utilization of Murine Embryonic Stem Cells and In Vivo Models to Study Human Congenital Heart Disease.

We have established an in vitro model of the human congenital heart defect (CHD)-associated mutation NKX2.5 R141C. We describe the use of the hanging drop method to differentiate Nkx2.5R141C/+ murine embryonic stem cells (mESCs) along with Nkx2.5+/+ control cells. This method allows us to recapitulate the early stages of embryonic heart development in tissue culture. We also use qRT-PCR and immunofluorescence to examine samples at different time points during differentiation to validate our data. The in vivo model is a mouse line with a knock-in of the same mutation. We describe the isolation of RNA from embryonic day 8.5 (E8.5) embryos and E9.5 hearts of wild-type and mutant mice. We found that the in vitro model shows reduced cardiomyogenesis, similar to Nkx2.5R141C/+ embryos at E8.5, indicating a transient loss of cardiomyogenesis at this time point. These results suggest that our in vitro model can be used to study very early changes in heart development that cause CHD. © 2018 by John Wiley & Sons, Inc.

In Vitro Modeling of Congenital Heart Defects Associated with an NKX2-5 Mutation Revealed a Dysregulation in BMP/Notch-Mediated Signaling.

The Nkx2-5 gene codes for a transcription factor that plays a critical role in heart development. Heterozygous mutations in NKX2-5 in both human and mice result in congenital heart defects (CHDs). However, the molecular mechanisms by which these mutations cause the disease are still unknown. Recently, we have generated the heterozygous mouse model of the human CHDs associated mutation NKX2-5 R142C (Nkx2-5R141C/+ mouse ortholog of human NKX2-5 R142C variant) that developed septal and conduction defects. This study generated a heterozygous Nkx2-5 R141C mouse embryonic stem cell line (Nkx2-5R141C/+ mESCs) to model CHDs in vitro. We observed that Nkx2-5R141C/+ mESCs display an alteration in the expression of genes that are essential for normal heart development. Furthermore, the reduced cardiomyogenesis is paralleled by a reduction in nuclear import of Nkx2-5 protein. Examination of the Nkx2-5R141C/+ embryos at E8.5 revealed a transient loss of cardiomyogenesis, which is consistent with the phenotype observed in vitro. Moreover, gene expression profiling of Nkx2-5R141C/+ cells at an early stage of cardiac differentiation revealed pronounced deregulation of several cardiac differentiation and function genes. Collectively, our data showed that heterozygosity for the R141C mutation results in disruption of the cellular distribution of Nkx2-5 protein, a transient reduction in cardiomyogenesis that may disrupt the early patterning of the heart, and this, in turn, affects the intricate orchestration of signaling pathways leading to downregulation of Bone morphogenetic protein (BMP) and Notch signaling. Therefore, we have developed mESCs model of a human CHD, providing an in vitro system to examine early stages of heart development, which are otherwise difficult to study in vivo. Stem Cells 2018;36:514-526.

SOX7 Is Required for Muscle Satellite Cell Development and Maintenance.

Satellite cells are skeletal-muscle-specific stem cells that are activated by injury to proliferate, differentiate, and fuse to enable repair. SOX7, a member of the SRY-related HMG-box family of transcription factors is expressed in quiescent satellite cells. To elucidate SOX7 function in skeletal muscle, we knocked down Sox7 expression in embryonic stem cells and primary myoblasts and generated a conditional knockout mouse in which Sox7 is excised in PAX3+ cells. Loss of Sox7 in embryonic stem cells reduced Pax3 and Pax7 expression. In vivo, conditional knockdown of Sox7 reduced the satellite cell population from birth, reduced myofiber caliber, and impaired regeneration after acute injury. Although Sox7-deficient primary myoblasts differentiated normally, impaired myoblast fusion and increased sensitivity to apoptosis in culture and in vivo were observed. Taken together, these results indicate that SOX7 is dispensable for myogenesis but is necessary to promote satellite cell development and survival.

Congenital heart defect causing mutation in Nkx2.5 displays in vivo functional deficit.

The Nkx2.5 gene encodes a transcription factor that plays a critical role in heart development. In humans, heterozygous mutations in NKX2.5 result in congenital heart defects (CHDs). However, the molecular mechanisms by which these mutations cause the disease remain unknown. NKX2.5-R142C is a mutation that was reported to be associated with atrial septal defect (ASD) and atrioventricular (AV) block in 13-patients from one family. The R142C mutation is located within both the DNA-binding domain and the nuclear localization sequence of NKX2.5 protein. The pathogenesis of CHDs in humans with R142C point mutation is not well understood. To examine the functional deficit associated with this mutation in vivo, we generated and characterized a knock-in mouse that harbours the human mutation R142C. Systematic structural and functional examination of the embryonic, newborn, and adult mice revealed that the homozygous embryos Nkx2.5R141C/R141C are developmentally arrested around E10.5 with delayed heart morphogenesis and downregulation of Nkx2.5 target genes, Anf, Mlc2v, Actc1 and Cx40. Histological examination of Nkx2.5R141C/+ newborn hearts showed that 36% displayed ASD, with at least 80% 0f adult heterozygotes displaying a septal defect. Moreover, heterozygous Nkx2.5R141C/+ newborn mice have downregulation of ion channel genes with 11/12 adult mice manifesting a prolonged PR interval that is indicative of 1st degree AV block. Collectively, the present study demonstrates that mice with the R141C point mutation in the Nkx2.5 allele phenocopies humans with the NKX2.5 R142C point mutation.

BRG1 interacts with GLI2 and binds Mef2c gene in a hedgehog signalling dependent manner during in vitro cardiomyogenesis.

BACKGROUND: The Hedgehog (HH) signalling pathway regulates cardiomyogenesis in vivo and in differentiating P19 embryonal carcinoma (EC) cells, a mouse embryonic stem (mES) cell model. To further assess the transcriptional role of HH signalling during cardiomyogenesis in stem cells, we studied the effects of overexpressing GLI2, a primary transducer of the HH signalling pathway, in mES cells. RESULTS: Stable GLI2 overexpression resulted in an enhancement of cardiac progenitor-enriched genes, Mef2c, Nkx2-5, and Tbx5 during mES cell differentiation. In contrast, pharmacological blockade of the HH pathway in mES cells resulted in lower expression of these genes. Mass spectrometric analysis identified the chromatin remodelling factor BRG1 as a protein which co-immunoprecipitates with GLI2 in differentiating mES cells. We then determined that BRG1 is recruited to a GLI2-specific Mef2c gene element in a HH signalling-dependent manner during cardiomyogenesis in P19 EC cells, a mES cell model. CONCLUSIONS: Thus, we propose a mechanism where HH/GLI2 regulates the expression of Mef2c by recruiting BRG1 to the Mef2c gene, most probably via chromatin remodelling, to ultimately regulate in vitro cardiomyogenesis.