Phylogenetic analysis of the myostatin gene sub-family and the differential expression of a novel member in zebrafish

The myostatin (MSTN)-null phenotype in mammals is characterized by extreme gains in skeletal muscle mass or "double muscling" as the cytokine negatively regulates skeletal muscle growth. Recent attempts, however, to reproduce a comparable phenotype in zebrafish have failed. Several aspects of MSTN biology in the fishes differ significantly from those in mammals and at least two distinct paralogs have been identified in some species, which possibly suggests functional divergence between the different vertebrate classes or between fish paralogs. We therefore conducted a phylogenetic analysis of the entire MSTN gene sub-family. Maximum likelihood, Bayesian inference, and bootstrap analyses indicated a monophyletic distribution of all MSTN genes with two distinct fish clades: MSTN-1 and -2. These analyses further indicated that all Salmonid genes described are actually MSTN-1 orthologs and that additional MSTN-2 paralogs may be present in most, if not all, teleosts. An additional zebrafish homolog was identified by BLAST searches of the zebrafish Hierarchical Tets Generation System database and was subsequently cloned. Comparative sequence analysis of both genes (zebrafish MSTN (zfMSTN)-1 and -2) revealed many differences, primarily within the latency-associated peptide regions, but also within the bioactive domains. The 2-kb promoter region of zfMSTN-2 contained many putative cis regulatory elements that are active during myogenesis, but are lacking in the zfMSTN-1 promoter. In fact, zfMSTN-2 expression was limited to the early stages of somitogenesis, whereas zfMSTN-1 was expressed throughout embryogenesis. These data suggest that zfMSTN-2 may be more closely associated with skeletal muscle growth and development. They also resolve the previous ambiguity in classification of fish MSTN genes.     

Sequence conservation among fish myostatin orthologues and the characterization of two additional cDNA clones from Morone saxatilis and Morone americana

Myostatin (MSTN) negatively regulates mammalian skeletal muscle growth and development by inhibiting myoblast proliferation. Mice and cattle possessing mutant MSTN alleles display a 'double muscling' phenotype characterized by extreme skeletal muscle hypertrophy and/or hyperplasia. MSTN orthologues have been previously characterized in 12 vertebrate species, including the white bass Morone chrysops. Presented herein is the identification and characterization of novel cDNA clones from two additional Morone species: saxatilis (striped bass) and americana (white perch), which were obtained by PCR amplification and subsequent TA-cloning. The predicted amino acid sequence of each cDNA clone contains a putative signal sequence, conserved cysteine residues and a RXXR proteolytic processing site. The different Morone proteins were 97-99% identical to each other and approximately 91, 81, 68 and 67% identical to the tilapia, zebrafish, mammalian and avian proteins, respectively. However, the bioactive domains, which lie downstream of each processing site, were considerably more conserved. They were 99-100% identical within the genus and were approximately 99, 95, 88 and 88% identical to the tilapia, zebrafish, mammalian and avian domains, respectively. This high level of sequence conservation among all known MSTN orthologues suggests that the structure/function relationship of each is equally well conserved among vertebrates.     

Overexpression of the dominant-negative form of myostatin results in doubling of muscle-fiber number in transgenic medaka (Oryzias latipes)

In addition to altering the phenotypes of gene-modified animals, transgenesis also has the potential to facilitate access to the various mechanisms underlying the development and functioning of specific phenotypes and genes, respectively. Myostatin (MSTN) is implicated in double-muscling when mutated in mammals, indicating that MSTN is a negative regulator of skeletal muscle formation. In order to elucidate the role of an MSTN equivalent in fish muscle formation, we created a transgenic medaka strain that expresses dominant-negative MSTN exclusively in skeletal muscle, d-rR-Tg(OlMA1–C315Y–MSTN–hrGFPII–FLAG). The transgenic fish exhibited increased production of skeletal muscle fibers at the adult stage (hyperplasia), although gross muscle mass was not altered. During embryogenesis, ectopic accumulation and misalignment of muscle fibers, possibly due to muscle-fiber hypertrophy, were observed in the transgenic medaka. Our findings suggest that MSTN function is required for regulating the appropriate growth of skeletal muscle in medaka. Unlike in mammals, MSTN loss-of-function failed to induce double-muscling in medaka, despite the highly conserved nature of MSTN function among taxa.     

Myostatin-deficient medaka exhibit a double-muscling phenotype with hyperplasia and hypertrophy, which occur sequentially during post-hatch development

Myostatin (MSTN) functions as a negative regulator of skeletal muscle mass. In mammals, MSTN-deficient animals result in an increase of skeletal muscle mass with both hyperplasia and hypertrophy. A MSTN gene is highly conserved within the fish species, allowing speculation that MSTN-deficient fish could exhibit a double-muscled phenotype. Some strategies for blocking or knocking down MSTN in adult fish have been already performed; however, these fish show either only hyperplastic or hypertrophic growth in muscle fiber. Therefore, the role of MSTN in fish myogenesis during post-hatch growth remains unclear. To address this question, we have made MSTN-deficient medaka (mstnC315Y) by using the targeting induced local lesions in a genome method. mstnC315Y can reproduce and have the same survival period as WT medaka. Growth rates of WT and mstnC315Y were measured at juvenile (1–2 wk post-hatching), post-juvenile (3–7 wk post-hatching) and adult (8–16 wk post-hatching) stages. In addition, effects of MSTN on skeletal muscle differentiation were investigated at histological and molecular levels at each developmental stage. As a result, mstnC315Y show a significant increase in body weight from the post-juvenile to adult stage. Hyper-morphogenesis of skeletal muscle in mstnC315Y was accomplished due to hyperplastic growth from post-juvenile to early adult stage, followed by hypertrophic growth in the adult stage. Myf-5 and MyoD were up-regulated in mstnC315Y at the hyperplastic growth phase, while myogenin was highly expressed in mstnC315Y at the hypertrophic growth phase. These indicated that MSTN in medaka plays a dual role for muscle fiber development. In conclusion, MSTN in medaka regulates the number and size of muscle fiber in a temporally-controlled manner during posthatch growth.     

肌肉生长抑制素调控动物骨骼肌生长机制的研究进展

肌肉生成抑制素（myostatin, MSTN）在动物机体骨骼肌的增殖、分化和生长中起着重要的负调控作用。MSTN基因的过表达会阻碍骨骼肌增殖分化及生长发育,而缺失或表达降低则会导致肌肉肥大,形成双肌现象（double muscle phenomenon, DMP）。MSTN能作用于多个基因及结合多种细胞因子广泛参与生理生化、物质代谢、病理调控等过程,在动物机体生长发育过程中扮演着重要的角色。本文将从MSTN基因的历史渊源、基因定位、时空表达特性、部分相关作用机制等方面进行论述,旨在对MSTN调控动物骨骼肌生长部分机制作梳理,以期为后期研究提供理论依据。     

Production of bioactive extracellular domain of pig and chicken activin type IIB receptors in Pichia pastoris

Myostatin (MSTN) is a potent negative regulator for skeletal muscle growth, and binds to activin type IIB receptor (ActRIIB) for its cellular signal transduction. Administration of the extracellular domain of ActRIIB (ActRIIB-ECD) improved skeletal muscle growth in laboratory animals, suggesting that ActRIIB-ECD can be a useful pharmacological agent to improve skeletal muscle growth of meat-producing animals. In the current study, pig and chicken ActRIIB-ECDs were produced in the Pichia pastoris GS115, and the recombinant proteins were purified from induced culture media by Ni-NTA affinity chromatography. The digestion of pig and chicken ActRIIB-ECDs with PNGase F and glycoprotein staining demonstrated an N-linked glycosylation of these recombinant proteins. Glycoprotein staining also indicated an additional presence of glycosylation in chicken ActRIIB-ECD. Both the pig and chicken ActRIIB-ECDs were shown to inhibit MSTN activity in a reporter gene assay system in vitro. When MSTN-inhibitory potencies were compared by analyzing EC₅₀ values, no difference in MSTN-inhibitory potency was observed between the glycosylated and N-deglycosylated forms of pig or chicken ActRIIB-ECD, suggesting that glycosylation does not affect the bioactivity of ActRIIB-ECD. MSTN-inhibitory potency of chicken ActRIIB-ECD was greater (P < 0.01) than that of pig ActRIIB-ECD. Results of this study demonstrate that bioactive pig and chicken ActRIIB-ECDs can be produced from P. pastoris. In addition, the study indicates that the N-glycosylation status of ActRIIB-ECD does not affect its bioactivity in vitro.     

Myostatin三维结构模建及分子进化分析

Myostatin(MST)为肌肉生长负调节因子,其功能受抑制可导致肌肉量增加.对MST核酸序列进行序列比对,构建进化树;采用同源模建方法首次模建MST成熟肽生物活性二聚体的四级结构,并预测MST与其受体ActRIIB的相互作用模式.进化树将肌肉生长抑制素基因(MSTN)分成4个亚家族:哺乳动物MSTN,鸟类MSTN以及鱼类MSTN 1和2.MST受纯化选择作用,在不同物种的直系同源基因具有较高的刚源性,其中哺乳动物、鸟类MST C端活性肽氨基酸序列高度保守.表明哺乳动物、鸟类MST的结构、功能类似,且信号传导路径可能一致;而鱼类MST的调控机制可能存在较大差异.MST结构及其表面静电势和疏水氨基酸分布表明静电力和疏水相互作用在MST与其受体结合过程中可能起到十分重要的作用.     

军曹鱼肌生成抑制素基因的克隆与序列分析

肌生成抑制素(Myostation,MSTN)是一种骨骼肌生长的负调控因子,其生物功能主要是抑制骨骼肌的生长。肌生成抑制素的活性降低或丧失,可使肌肉与其他组织的比例大大提高,因此在动物育种和医疗上有很大的潜在应用价值。目前包括鱼类在内的20多种脊椎动物的MSTN cDNA已经得到克隆和测序。本实验依据已知的鱼MSTN cDNA的保守区域设计一对特异引物,利用PCR技术分别从军曹鱼基因组中扩增出一个约1000bp的特异片段和300bp片段,所得目的片段回收纯化,将其酶切产物连接到pMDl8-T克隆载体上,转化入JM109感受态细胞中,挑取阳性克隆进行转化子鉴定,其质粒测序结果与文献报道的一致,证明成功地克隆了军曹鱼肌生成抑制素基因。     

肌肉生长抑制因子对肌细胞发育的调控研究

肌肉生长抑制因子（MSTN）是动物肌肉生长发育的一个重要的负调控主效基因。它的表达受其他肌肉发育的调控因子如MyoD,FoxO等的调控。MSTN原蛋白经蛋白酶修饰变成的活性蛋白存在于血液循环系统中,它可以结合到细胞膜表面受体,激活细胞内信号通路,与其他因子的协同作用对肌肉发育和脂肪生成产生不同生理效应。本文将对MSTN基因及其蛋白的结构特点,表达调控因子,细胞内信号传导,及其对组织发育的影响进行探讨。     

AMPK activation by AICAR inhibits myogenic differentiation and myostatin expression in Cattle

AMP-activated protein kinase (AMPK) regulates metabolism in skeletal muscle, and myostatin (MSTN) negatively regulates skeletal muscle development and growth. In the present study, AMPK activation and the relationship between AMPK and MSTN during myogenic differentiation were investigated in cultures derived from bovine skeletal muscle. Myoblasts capable of forming myotubes were obtained from bovine skeletal muscle and treated with AICAR to activate AMPK, resulting in suppressed myotube formation. AICAR treatment significantly reduced the expression of MSTN mRNA during myogenic differentiation. Combined treatment with AICAR and MSTN suppressed myotube formation to a greater extent than AICAR alone. SB431542, an inhibitor of MSTN signaling, promoted myotube formation during myogenic differentiation. However, simultaneous treatment with AICAR blocked this effect of SB431542. Therefore, AMPK activation inhibits myogenic differentiation but may suppress MSTN expression to balance muscle development.     

Production of Bioactive Rockfish (<Emphasis Type="Italic">Sebastes schlegeli</Emphasis>) Myostatin-1 Prodomain in an <Emphasis Type="Italic">Escherichia coli</Emphasis> System

Myostatin (MSTN) is a potent negative regulator of skeletal muscle growth in mammalian species, and its activity is inhibited by MSTN prodomain, the N-terminal part of proMSTN cleaved during post-translational MSTN processing. In fish, MSTN also appears to suppress fish muscle growth with its activity being inhibited by prodomain. The objective of this study was to produce bioactive MSTN-1 prodomain of rockfish (S. schlegeli), a commercial aquaculture species in East Asia, in E. coli using maltose binding protein (MBP) as a fusion partner. Rockfish MSTN-1 prodomain (sMSTN1pro) cDNA was cloned into the pMALc2x vector, and proteins (MBP-sMSTN1pro) were expressed in Rosetta-gami 2(DE3)pLysS cells by IPTG induction. The MBP-sMSTN1pro was expressed in soluble forms, and affinity purified using amylose resin. The affinity purified MBP-sMSTN1pro suppressed MSTN activity in vitro. The results suggest that MBP is probably a useful fusion partner in producing bioactive MSTN prodomains of various animal species in E. coli.     

GH overexpression causes muscle hypertrophy independent from local IGF-I in a zebrafish transgenic model

The aim of the present study was to analyse the morphology of white skeletal muscle in males and females from the GH-transgenic zebrafish (Danio rerio) lineage F0104, comparing the expression of genes related to the somatotrophic axis and myogenesis. Histological analysis demonstrated that transgenic fish presented enhanced muscle hypertrophy when compared to non-transgenic fish, with transgenic females being more hypertrophic than transgenic males. The expression of genes related to muscle growth revealed that transgenic hypertrophy is independent from local induction of insulin-like growth factor 1 gene (igf1). In addition, transgenic males exhibited significant induction of myogenin gene (myog) expression, indicating that myog may mediate hypertrophic growth in zebrafish males overexpressing GH. Induction of the α-actin gene (acta1) in males, independently from transgenesis, also was observed. There were no significant differences in total protein content from the muscle. Our results show that muscle hypertrophy is independent from muscle igf1, and is likely to be a direct effect of excess circulating GH and/or IGF1 in this transgenic zebrafish lineage.     

Enhanced hyperplasia in muscles of transgenic zebrafish expressing <Emphasis Type="Italic">Follistatin1</Emphasis>

Myostatin is a member of the transforming growth factor-β (TGF-β) super-family and functions as a negative regulator of muscle growth. Binding of the specific receptor, Activin receptor IIB (Act RIIB), with myostatin or other related TGF-β members, could be inhibited by the activin-binding protein follistatin (Fst) in mammals. Overexpressing Fst in mouse skeletal muscle leads to muscle hypertrophy and hyperplasia. To determine if Fst has similar roles in fish, we generated transgenic zebrafish expressing high levels of zebrafish Fst1 using the promoter of the zebrafish skeletal muscle-specific gene, myosin, light polypeptide 2, skeletal muscle (Mylz2). Independent transgenic zebrafish lines exhibited elevated expression levels of myogenic regulatory genes MyoD and Pax7 in muscle cells. Adult Fst1 overexpressing transgenic zebrafish exhibited a slight body weight increase. The high level of Fst1 expression dramatically increased myofiber numbers in skeletal muscle, without significantly changing the fiber size. Our findings suggest that Fst1 overexpression can promote zebrafish muscle growth by enhancing myofiber hyperplasia.     

Myostatin gene silenced by RNAi show a zebrafish giant phenotype

Myostatin is a member of the transforming growth factor-beta (TGF-beta) family that functions as a negative regulator of skeletal muscle development and growth. Recently, it has been reported that the transgenic zebrafish expressing myostatin prodomain exhibited an increased number of fiber in skeletal muscle. Other novel results suggest that myostatin plays a mayor role during myogenesis, apart from inhibition of proliferation as well as differentiation. We have investigated the ability of double-stranded RNA (dsRNA) to inhibit myostatin function in the zebrafish. By microinjection dsRNA, corresponding to biologically active C-terminal domain from aminoacid 268 to end codon of tilapia myostatin protein, we produced an increased body mass in treated fish. The dsRNA injection in early development stage in zebrafish produced hyperplasia or hypertrophy. In addition, the interference of gene function showed a strong dependence on the amount of dsRNA.