microRNAs调控骨骼肌分化的分子机制

microRNA（miRNA）是一大类广泛存在于真核细胞当中的长度约22nt的内源性单链非编码RNA,通过与靶基因mRNA的3’非翻译区（3’untranslated region,3’UTR）结合在转录后水平调控靶基因的表达。miRNA作为调控基因表达的重要分子在骨骼肌分化调控中的作用越来越受到关注,阐明miRNA在骨骼肌增殖与分化中的作用机制具有重要的理论意义,同时也可为骨骼肌相关疾病的治疗提供新的思路。文章总结了miRNA,尤其是miR-1、miR-133和miR-206等肌肉特异性miRNA,在调控骨骼肌分化过程中作用机制的研究进展,以便于进一步工作的开展。     

miRNA调控成肌分化的研究进展

成肌分化过程包括成肌细胞的增殖,然后分化为肌细胞,最后融合形成肌管;microRNA(miRNA)是一类在转录后水平调控基因表达的微小非编码RNA,它通过靶向靶基因mRNA的3'UTR,抑制其翻译或诱导其降解。已有研究表明,miRNA在成肌分化中起重要调控作用。根据表达方式的不同,分为肌肉特异表达的miRNA,有miR-1,miR-133,miR-206,miR-208,miR-499和miR-486;和非肌肉特异表达的miRNA,其中miR-27,miR-29,miR-128,miR-199a和miR-431在成肌分化过程中具有重要的调控功能。另外,阐述了几个与miRNA相互作用从而调控成肌分化的lncRNA的功能。通过介绍两类miRNA的靶基因及调控机制,阐述了最新的研究进展。     

microRNA在肌肉发育中的功能研究进展

microRNA(miRNA)是一类非编码的小RNA分子,它通过对靶mRNA的翻译抑制和降解对基因表达起负调节作用。现在人们已经清楚地知道miRNA参与了增殖、分化、凋亡、发育等许多生物过程。一些miRNA在肌肉中特异表达,参与肌肉发育。该文重点介绍了参与肌肉发育的miRNA。已有证据表明肌肉miRNA在肌肉的增殖和分化过程中起了重要的调节作用,miRNA的调节异常和肌肉疾病有关。因此,miRNA是一类新的肌肉调控因子,它有可能成为畜禽肉产量提高和肌肉相关疾病治疗的新型靶标。     

miR-21在头颈肿瘤中的研究进展

微小RNA(micro RNA,miRNA)是一类小分子非编码RNA,可引起靶m RNA的降解或翻译抑制,从而对基因进行转录后表达调控,它在细胞生长、发育和衰老等生命过程中扮演着重要角色。miR-21在人类组织和细胞中较早发现,是广泛存在的miRNA之一,也是实体肿瘤中最常见的过高表达miRNA之一,在肿瘤的发生发展中可能发挥癌基因的作用。该文就miR-21在头颈肿瘤中的研究作一综述。     

肌肉特异表达microRNA的功能研究

MicroRNA作为非编码小RNA分子在转录和后转录水平调控基因表达过程中扮演重要角色,已成为当前分子生物学的研究热点之一。近期已有研究证实,一些在肌肉细胞中特异表达microRNA包括miR-1、miR-206和miR-133可能对肌肉生长和发育很关键。众所周知,肌肉不仅是机体重要结构组织和运动器官,而且还是水产畜牧产品的重要蛋白源。聚焦这些肌肉特异myomiRs在肌肉生长和发育中的功能机理研究,不仅有助于揭示某些疾病的分子机制和解决医学上基因治疗难题;同时也为畜牧水产养殖提供科学应用理论依据。综述我们概括了miR-1, miR-206和miR-133最新研究进展,这将有助于深入了解其作用于肌肉生长和发育的功能和分子机制。       

miR-196b-5p促进成肌细胞增殖分化

MicroRNA (miRNA)是一类由内源基因编码的长度约为22个核苷酸的非编码单链RNA分子，在动植物中参与转录后基因表达调控。大量研究表明，miRNA调控骨骼肌的发育，主要表现在肌卫星细胞的激活及增殖、分化、肌管的形成等生物学过程。本实验室前期对大白猪背最长肌(longissimus dorsi,LD)和比目鱼肌(soleus muscle,Sol)进行miRNA测序，筛选鉴定到一个在不同骨骼肌中差异表达并且序列高度保守的miR-196b-5p，目前miR-196b-5p在骨骼肌方面的研究尚未见报道。本研究进一步设计合成miR-196b-5p mimics和inhibitor对C2C12细胞进行miR-196b-5p过表达及干扰表达，利用蛋白免疫印迹、实时荧光定量PCR检测、流式细胞术、免疫荧光染色等方法探究miR-196b-5p对成肌细胞增殖分化的影响，并利用生物信息学预测和双荧光素酶报告系统鉴定了miR-196b-5p的靶基因。结果显示，过表达miR-196b-5p显著增加细胞周期基因Cyclin B、Cyclin D和Cyclin E的mRNA和蛋白表达水平(P<0....     

果蝇微小RNA及其在衰老过程中的作用

微小RNA（microRNA, miRNA）是一类长度在22 nt左右的内源非编码小RNA,广泛存在于动物、植物、病毒等多种有机体中,是机体正常衰老与疾病的重要调控因子。本文对果蝇不同生长时期miRNA的表达模式、主要衰老相关信号通路以及与衰老相关的miRNA进行了综述。在果蝇的不同发育时期均有特定的miRNA发挥重要作用,其表达模式与功能相关;miRNA参与了主要衰老分子信号通路的调控,如胰岛素/胰岛素样生长因子（IIS）通路和雷帕霉素靶蛋白（TOR）通路。研究表明,miRNA通过调控衰老相关信号通路中的靶基因,进而促进或延缓果蝇衰老,如miR-34, miR-8, miR-14, miR let7和miR-277等。因此,研究参与衰老调控的miRNA,为阐明衰老机制及抗衰老药物的设计奠定了基础。     

微小RNA-29与恶性肿瘤

miR-29家族是人类重要的miRNA分子,在多数恶性肿瘤中扮演抑癌RNA分子的作用,因而呈现低表达水平,它通过上调抑癌基因表达及调控相关肿瘤信号通路等机制,抑制恶性肿瘤的增殖、分化、侵袭和转移。miR-29家族不仅能作为恶性肿瘤治疗的靶点,而且在肿瘤的诊断及预后评估方面具有重要价值。     

应用双荧光报告系统检测斑马鱼microRNA的动态表达

microRNA(miRNA)是一类细胞内源表达的小分子非编码RNA, 主要通过降解靶基因的mRNA或者抑制靶基因的翻译, 在动植物的发育以及其他重要的生理过程中起调控作用。miRNA的功能跟它的表达位置与时间密切相关, 但是目前尚缺乏一个能够在活体与个体水平稳定、持续地实时观察miRNA动态表达的方法。文章以斑马鱼为模式, 建立了一个双荧光报告系统(我们称之为miRNA Tracer), 用于在斑马鱼整体胚胎中追踪特定miRNA的表达谱及动态变化过程。该系统以Tol2转座子为基础, 采用来自斑马鱼hsp70基因的热激启动子分别驱动eGFP和mRFP1荧光报告基因, 同时在其中一个报告基因的3′-UTR区连接待测miRNA的互补序列, 构成Tracer质粒。该互补序列与斑马鱼胚胎中相应的内源miRNA结合后能够使对应报告基因的荧光信号强度减弱, 通过比较两个报告基因在表达谱上的差异辨别miRNA的表达区域, 检测斑马鱼胚胎中miRNA起作用的位置和时间。文章选择在肌肉系统特异表达的miR-206以及在神经系统特异表达的miR-219, 分别在显微注射瞬时表达和转基因稳定整合等两个层次上验证了上述Tracer系统。结果表明, 所用的方法能够如实地在单细胞水平和整体水平检测到目标miRNA的时空表达动态变化。miRNA Tracer系统为在斑马鱼发育过程中对miRNA进行活体、实时的时空定位提供了一个独特而有效的方法, 也为对miRNA进行功能与作用机制等更深入的研究奠定了基础。

补充资料

s219mRFP1-dF转基因胚胎的3-D图像 [视频]     

MicroRNA调控哺乳动物骨骼肌发育

MicroRNA (miRNA)是一类长度大约为22 bp的小分子非编码RNA,广泛存在于哺乳动物中,部分miRNA表达具有时空和组织特异性。哺乳动物中miRNA主要通过与靶基因3° UTR区结合抑制其翻译,调控机体生物学功能。miRNA在哺乳动物骨骼肌发育中发挥重要调节作用。哺乳动物骨骼肌发育是一个复杂的生物学过程,包括骨骼肌干细胞增殖、迁移、分化,成肌细胞增殖、分化、肌管融合,肌纤维肥大,能量代谢,纤维类型转换等。miRNA参与骨骼肌发育的各个环节,通过靶向各个时期的关键因子调控骨骼肌发育。本文对miRNA在骨骼肌发育中的调控作用进行了综述,以期为深入理解骨骼肌发育规律提供参考。     

MicroRNAs in skeletal and cardiac muscle development

MicroRNAs (miRNAs) are a recently discovered class of small non-coding RNAs, which are approximately 22 nucleotides in length. miRNAs negatively regulate gene expression by translational repression and target mRNA degradation. It has become clear that miRNAs are involved in many biological processes, including development, differentiation, proliferation, and apoptosis. Interestingly, many miRNAs are expressed in a tissue-specific manner and several miRNAs are specifically expressed in cardiac and skeletal muscles. In this review, we focus on those miRNAs that have been shown to be involved in muscle development. Compelling evidences have demonstrated that muscle miRNAs play an important role in the regulation of muscle proliferation and differentiation processes. However, it appears that miRNAs are not essential for early myogenesis and muscle specification. Importantly, dysregulation of miRNAs has been linked to muscle-related diseases, such as cardiac hypertrophy. A mutation resulting in a gain-of-function miRNA target site in the myostatin gene leads to down regulation of the targeted protein in Texel sheep. miRNAs therefore are a new class of regulators of muscle biology and they might become novel therapeutic targets in muscle-related human diseases.     

MicroRNAs Involved in Skeletal Muscle Differentiation

MicroRNAs (miRNAs) negatively regulate gene expression by promoting degradation of target mRNAs or inhibiting their translation. Previous studies have expanded our understanding that miRNAs play an important role in myogenesis and have a big impact on muscle mass, muscle fiber type and muscle-related diseases. The muscle-specific miRNAs, miR-206, miR-1 and miR-133, are among the most studied and best characterized miRNAs in skeletal muscle differentiation. They have a profound influence on multiple muscle differ-entiation processes, such as alternative splicing, DNA synthesis, and cell apoptosis. Many non-muscle-specific miRNAs are also required for the differentiation of muscle through interaction with myogenic factors. Studying the regulatory mechanisms of these miRNAs in muscle differentiation will extend our knowledge of miRNAs in muscle biology and will improve our understanding of the myogenesis regulation.     

Identification and profiling of microRNAs from skeletal muscle of the common carp

The common carp is one of the most important cultivated species in the world of freshwater aquaculture. The cultivation of this species is particularly productive due to its high skeletal muscle mass; however, the molecular mechanisms of skeletal muscle development in the common carp remain unknown. It has been shown that a class of non-coding ～22 nucleotide RNAs called microRNAs (miRNAs) play important roles in vertebrate development. They regulate gene expression through sequence-specific interactions with the 3' untranslated regions (UTRs) of target mRNAs and thereby cause translational repression or mRNA destabilization. Intriguingly, the role of miRNAs in the skeletal muscle development of the common carp remains unknown. In this study, a small-RNA cDNA library was constructed from the skeletal muscle of the common carp, and Solexa sequencing technology was used to perform high throughput sequencing of the library. Subsequent bioinformatics analysis identified 188 conserved miRNAs and 7 novel miRNAs in the carp skeletal muscle. The miRNA expression profiling showed that, miR-1, miR-133a-3p, and miR-206 were specifically expressed in muscle-containing organs, and that miR-1, miR-21, miR-26a, miR-27a, miR-133a-3p, miR-206, miR-214 and miR-222 were differentially expressed in the process of skeletal muscle development of the common carp. This study provides a first identification and profiling of miRNAs related to the muscle biology of the common carp. Their identification could provide clues leading towards a better understanding of the molecular mechanisms of carp skeletal muscle development.     

Hmgb3 Is Regulated by MicroRNA-206 during Muscle Regeneration

Background

MicroRNAs (miRNAs) have been recently involved in most of human diseases as targets for potential strategies to rescue the pathological phenotype. Since the skeletal muscle is a spread-wide highly differentiated and organized tissue, rescue of severely compromised muscle still remains distant from nowadays. For this reason, we aimed to identify a subset of miRNAs major involved in muscle remodelling and regeneration by analysing the miRNA-profile of single fibres isolated from dystrophic muscle, which was here considered as a model of chronic damage.

Methodology/Principal Findings

The miRNA-signature associated to regenerating (newly formed) and remodelling (resting) fibres was investigated in animal models of muscular dystrophies and acute damage, in order to distinguish which miRNAs are primary related to muscle regeneration. In this study we identify fourteen miRNAs associated to dystrophic fibres responsible for muscle regeneration and remodelling, and confirm over-expression of the previously identified regeneration-associated myomiR-206. In particular, a functional binding site for myomiR-206 was identified and validated in the 3′untranslated region (3′UTR) of an X-linked member of a family of sequence independent chromatin-binding proteins (Hmgb3) that is preferentially expressed in hematopoietic stem cells. During regeneration of single muscle fibres, Hmgb3 messenger RNA (mRNA) and protein expression was gradually reduced, concurrent with the up-regulation of miR-206.

Conclusion/Significance

Our results elucidate a negative feedback circuit in which myomiR-206 represses Hmgb3 expression to modulate the regeneration of single muscle fibres after acute and chronic muscle damage. These findings suggest that myomiR-206 may be a potential therapeutic target in muscle diseases.