Carole Berry

Myostatin regulates fiber-type composition of skeletal muscle by regulating MEF2 and MyoD gene expression

Myostatin (Mstn) is a secreted growth factor belonging to the tranforming growth factor (TGF)-beta superfamily. Inactivation of murine Mstn by gene targeting, or natural mutation of bovine or human Mstn, induces the double muscling (DM) phenotype. In DM cattle, Mstn deficiency increases fast glycolytic (type IIB) fiber formation in the biceps femoris (BF) muscle. Using Mstn null ((-/-)) mice, we suggest a possible mechanism behind Mstn-mediated fiber-type diversity. Histological analysis revealed increased type IIB fibers with a concomitant decrease in type IIA and type I fibers in the Mstn(-/-) tibialis anterior and BF muscle. Functional electrical stimulation of Mstn(-/-) BF revealed increased fatigue susceptibility, supporting increased type IIB fiber content. Given the role of myocyte enhancer factor 2 (MEF2) in oxidative type I fiber formation, MEF2 levels in Mstn(-/-) tissue were quantified. Results revealed reduced MEF2C protein in Mstn(-/-) muscle and myoblast nuclear extracts. Reduced MEF2-DNA complex was also observed in electrophoretic mobility-shift assay using Mstn(-/-) nuclear extracts. Furthermore, reduced expression of MEF2 downstream target genes MLC1F and calcineurin were found in Mstn(-/-) muscle. Conversely, Mstn addition was sufficient to directly upregulate MLC promoter-enhancer activity in cultured myoblasts. Since high MyoD levels are seen in fast fibers, we analyzed MyoD levels in the muscle. In contrast to MEF2C, MyoD levels were increased in Mstn(-/-) muscle. Together, these results suggest that while Mstn positively regulates MEF2C levels, it negatively regulates MyoD expression in muscle. We propose that Mstn could regulate fiber-type composition by regulating the expression of MEF2C and MyoD during myogenesis.

Mighty is a novel promyogenic factor in skeletal myogenesis

Genetic analysis has revealed an important function in myogenesis for Myostatin, a member of the TGF-beta superfamily. However, the cascade of genes that responds to Myostatin signalling to regulate myogenesis is not well understood. Thus, a suppressive subtraction hybridization to identify such genes was undertaken and here we report the cloning and characterization of a novel gene, Mighty. Mighty is expressed in a variety of different tissues but appears to be specifically regulated by Myostatin in skeletal muscle. Overexpression of Mighty in C2C12 cells results in early withdrawal of myoblasts from the cell cycle, enhanced and accelerated differentiation and hypertrophy of myotubes. Most importantly, Mighty overexpression leads to increased and earlier expression of MyoD and increased secretion of another known differentiation inducing factor, IGF-II. Furthermore, viral expression of Mighty in mdx mice resulted in an increase in the number of larger healthy muscle fibers. Given its role in myogenesis, we propose that Mighty is a critical promyogenic factor which plays a key role in the signalling pathway downstream of Myostatin.

Myostatin negatively regulates the expression of the steroid receptor co-factor ARA70.

Myostatin is a transforming growth factor‐β (TGF‐β) superfamily member and a key negative regulator of embryonic and postnatal muscle growth. In order to identify downstream target genes regulated by Myostatin, we performed suppressive subtraction hybridization (SSH) on cDNA generated from the biceps femoris muscle of wild‐type and myostatin‐null mice. Sequence analysis identified several known and unknown genes as Myostatin downstream target genes. Here, we have investigated the regulation of gene expression of an androgen receptor (AR) binding co‐factor, androgen receptor associated protein‐70 (ARA70), by Myostatin. We show that in mouse there are two isoforms of ARA70 with high homology (79%) to human ARA70; an α‐isoform which is a canonical ARA70 and a β‐isoform which has a 9 consecutive amino acid deletion and 6 amino acid substitutions in the carboxyl‐terminal portion. Reverse Northern analysis on the differentially expressed cDNA library indicated that there is increased expression of ARA70 in the muscles of myostatin‐null mice. In addition, Northern blot, together with semi‐quantitative PCR analysis, confirmed that there is increased expression of ARA70 in myostatin‐null biceps femoris muscle when compared to wild‐type muscle. In corroboration of these results, addition of exogenous Myostatin results in down‐regulation of ARA70 expression confirming that Myostatin is a negative regulator of ARA70 gene expression. Expression analysis further confirmed that ARA70 is up‐regulated during myogenesis and that peak expression of ARA70 is observed following the peak expression of MyoD in differentiating myoblasts. Given that lack of Myostatin and increased expression of AR leads to hypertrophy, we propose that absence of Myostatin, at least in part, induces the hypertrophy phenotype by increasing the activity of AR by up‐regulating the expression of ARA70, a known stimulating co‐factor of AR.

Discovery of a Mammalian Splice Variant of Myostatin That Stimulates Myogenesis

Myostatin plays a fundamental role in regulating the size of skeletal muscles. To date, only a single myostatin gene and no splice variants have been identified in mammals. Here we describe the splicing of a cryptic intron that removes the coding sequence for the receptor binding moiety of sheep myostatin. The deduced polypeptide sequence of the myostatin splice variant (MSV) contains a 256 amino acid N-terminal domain, which is common to myostatin, and a unique C-terminus of 65 amino acids. Western immunoblotting demonstrated that MSV mRNA is translated into protein, which is present in skeletal muscles. To determine the biological role of MSV, we developed an MSV over-expressing C2C12 myoblast line and showed that it proliferated faster than that of the control line in association with an increased abundance of the CDK2/Cyclin E complex in the nucleus. Recombinant protein made for the novel C-terminus of MSV also stimulated myoblast proliferation and bound to myostatin with high affinity as determined by surface plasmon resonance assay. Therefore, we postulated that MSV functions as a binding protein and antagonist of myostatin. Consistent with our postulate, myostatin protein was co-immunoprecipitated from skeletal muscle extracts with an MSV-specific antibody. MSV over-expression in C2C12 myoblasts blocked myostatin-induced Smad2/3-dependent signaling, thereby confirming that MSV antagonizes the canonical myostatin pathway. Furthermore, MSV over-expression increased the abundance of MyoD, Myogenin and MRF4 proteins (P<0.05), which indicates that MSV stimulates myogenesis through the induction of myogenic regulatory factors. To help elucidate a possible role in vivo, we observed that MSV protein was more abundant during early post-natal muscle development, while myostatin remained unchanged, which suggests that MSV may promote the growth of skeletal muscles. We conclude that MSV represents a unique example of intra-genic regulation in which a splice variant directly antagonizes the biological activity of the canonical gene product.

IGF1 stimulates greater muscle hypertrophy in the absence of myostatin in male mice

Insulin-like growth factors (IGFs) and myostatin have opposing roles in regulating the growth and size of skeletal muscle, with IGF1 stimulating, and myostatin inhibiting, growth. However, it remains unclear whether these proteins have mutually dependent, or independent, roles. To clarify this issue, we crossed myostatin null (Mstn-/-) mice with mice overexpressing Igf1 in skeletal muscle (Igf1+) to generate six genotypes of male mice; wild type (Mstn+/+ ), Mstn+/-, Mstn-/-, Mstn+/+:Igf1+, Mstn+/-:Igf1+ and Mstn-/-:Igf1+ Overexpression of Igf1 increased the mass of mixed fibre type muscles (e.g. Quadriceps femoris) by 19% over Mstn+/+ , 33% over Mstn+/- and 49% over Mstn-/- (P < 0.001). By contrast, the mass of the gonadal fat pad was correspondingly reduced with the removal of Mstn and addition of Igf1 Myostatin regulated the number, while IGF1 regulated the size of myofibres, and the deletion of Mstn and Igf1+ independently increased the proportion of fast type IIB myosin heavy chain isoforms in T. anterior (up to 10% each, P < 0.001). The abundance of AKT and rpS6 was increased in muscles of Mstn-/-mice, while phosphorylation of AKTS473 was increased in Igf1+mice (Mstn+/+:Igf1+, Mstn+/-:Igf1+ and Mstn-/-:Igf1+). Our results demonstrate that a greater than additive effect is observed on the growth of skeletal muscle and in the reduction of body fat when myostatin is absent and IGF1 is in excess. Finally, we show that myostatin and IGF1 regulate skeletal muscle size, myofibre type and gonadal fat through distinct mechanisms that involve increasing the total abundance and phosphorylation status of AKT and rpS6.