斑鳜肌球蛋白轻链2基因cDNA的克隆及其纵向表达分析

从斑鳜(Siniperca scherzeri)背部白色肌肉组织中提取总RNA,利用RT-PCR法克隆到斑鳜肌球蛋白轻链2基因(MLC2)(GenBank:GQ283000).斑鳜MLC2基因cDNA序列的开放阅读框的长度为513 bp,编码170个氨基酸,理论相对分子质量为19 105.61 Da,等电点为4.73.该开放阅读框具有4个EF-手相结构.斑鳜MLC2推导的氨基酸序列与已报道的其它6种鱼类MLC2氨基酸序列同源性在89%以上,其中与Ca2+结合的区域非常保守,氨基酸序列同源性为100%.用实时荧光定量PCR对斑鳜MLC2纵向表达分析显示,MLC2在斑鳜背肌的前部、中部和后部都有表达,但无显著差异.     

Isolation and sequencing of porcine fast skeletal muscle alkali myosin light chain 3 cDNA

Abstract

A cDNA coding for alkali myosin light chain 3 (MLC3_F) was isolated from a porcine skeletal muscle library. This clone has an insert of 859 bp encompassing the complete CDS (coding sequence) plus the 5’ and 3’ untranslated regions. Computer analysis showed that porcine MLC3_F cDNA is highly homologous to the corresponding cDNAs of human, rabbit and rat. Moreover, Northern analysis showed the presence of two bands that represent the mature mRNAs of the MLCl_F and MLC3_F isoforms according to data observed in other species.     

鳜碱性肌球蛋白轻链基因cDNA的克隆及其发育表达分析

肌球蛋白轻链是构成鱼类肌纤维主要组成部分,在鱼类肌肉生长和收缩过程中具有重要作用。鳜鱼具有生长快、肉质细嫩、味道鲜美、营养成分高等优良的性状。研究通过构建鳜肌肉组织cDNA文库分离到两个碱性肌球蛋白轻链基因,即MLC1和MLC3基因。序列分析显示MLC1和MLC3基因cDNA序列全长分别为1237bp和1070bp,分别编码192和150个氨基酸,除去MLC1N端多出的42个氨基酸残基,MLC1与MLC3氨基酸序列同源性为80.3%。通过PROSITEtools软件预测显示两种轻链都具有两个保守的EF-手相结构,其中第二个EF-hand结构除前三个氨基酸外同源性达100%。鱼类MLC3轻链N端没有高等脊椎动物MLC3特有标志序列。采用实时荧光定量PCR方法对鳜鱼MLC1和MLC3发育性表达分析表明,在原肠期开始有低量表达,与原肠期、尾芽期和肌肉效应期相比,心搏期和仔鱼期MLC1和MLC3表达量显著升高。研究结果首次提供了鳜肌肉组织肌球蛋白主要结构基因的分子生物学信息以及它们在鳜肌肉组织发生和功能的相关性。       

Comparison of myosin isoenzymes present in skeletal and cardiac muscles of the Arctic charr Salvelinus alpinus (L.). Sequential expression of different myosin heavy chains during development of the fast white skeletal muscle.

The expression of myosin isoforms and their subunit composition in the white skeletal body musculature of Arctic charr (Salvelinus alpinus) of different ages (from 77-day embryos until about 5 years old) was studied at the protein level by means of electrophoretic techniques. Myosin from the white muscle displayed three types of light chain during all the developmental stages examined: two myosin light chains type 1 (LC1F) differing in both apparent molecular mass and pI, one myosin light chain type 2 (LC2F) and one myosin light chain type 3 (LC3F). The fastest-migrating form of LC1F seemed to be predominant during the embryonic and eleutheroembryonic periods. The slowest-migrating form of LC1F was predominant in the 5-year-old fish. Between 1 year and 4 years, both types of LC1F were present in similar amounts. Cardiac as well as red muscle myosin from 3-year-old fish had two types of light chain. The myosin light chains from atria and ventriculi were indistinguishable by two-dimensional electrophoresis, but were different from the myosin light chains from red muscle. Neither the light chains from cardiac nor red muscle were coexpressed with the myosin light chains of white muscle at any of the developmental stages examined. Two myosin heavy chain bands were resolved by SDS/glycerol/polyacrylamide gel electrophoresis of the extract from embryos. One of the bands was present in minor amounts. The other, and most abundant, band comigrated with the only band found in the extracts of white muscle myosin from older fish. One-dimensional Staphylococcus aureus V8 protease peptide mapping of these bands revealed some differences during development of the white muscle tentatively interpreted as follows. The myosin heavy chain band present in minor amounts in the embryos may represent an early embryonic form that is replaced by a late embryonic or foetal form in the eleutheroembryos. The foetal myosin heavy chain appears to be present until the resorption of the yolk sack and beginning of the free-swimming stage. A new form of myosin heavy chain, termed neonatal and probably expressed around hatching, is present until about 1 year of age.(ABSTRACT TRUNCATED AT 400 WORDS)     

The myosin alkali light chains of mouse ventricular and slow skeletal muscle are indistinguishable and are encoded by the same gene

We have isolated a cDNA recombinant plasmid (pA29) identified as encoding part of the ventricular muscle myosin light chain MLC1v. This cDNA contains a 300-base pair fragment which under conditions of moderate stringency shows specific hybridization to MLC1v mRNA with no detectable cross-hybridization with the mRNAs encoding the fast skeletal muscle isoforms MLC1F and MLC3F, or the atrial muscle isoform MLC1A. Under these conditions hybridization is seen with an abundant mRNA present in slow skeletal muscle (soleus) which is indistinguishable from ventricular MLC1V mRNA on the basis of size and of thermal stability of hybrids formed with plasmid pA29. The mouse MLC1V and MLC1S proteins are found to co-migrate on two-dimensional gels. We therefore conclude that these isoforms are the same and are encoded by the same mRNA. Analysis of mouse DNA has identified a single region of the genome which hybridizes to this same fragment of pA29. This region has been isolated in a recombinant phage and has been shown to contain a single gene showing homology with MLC1V mRNA by R-loop analysis. We therefore conclude that MLC1V and MLC1S are encoded by a single gene. The pattern of segregation of a restriction fragment length polymorphism identified for this gene between Mus musculus and Mus spretus has been followed in an F1 backcross between these two mouse species. The results show the MLC1V/MLC1S gene to be closely linked to a marker at the distal end of mouse chromosome 9.     

Primary structure of myosin heavy chain from fast skeletal muscle of Chum salmon Oncorhynchus keta

The nucleotide sequence of the cDNA encoding myosin heavy chain of chum salmon Oncorhynchus keta fast skeletal muscle was determined. The sequence consists of 5,994 bp, including 5,814 bp of translated region deducing an amino acid sequence of 1,937 residues. The deduced sequence showed 79% homology to that of rabbit fast skeletal myosin and 84-87% homology to those of fast skeletal myosins from walleye pollack, white croaker and carp. The putative binding-sites for ATP, actin and regulatory light-chains in the subfragment-1 region of the salmon myosin showed high homology with the fish myosins (78-100% homology). However, the Loop-1 and Loop-2 showed considerably low homology (31-60%). On the other hand, the deduced sequences of subfragment-2 (533 residues) and light meromyosin (564 residues) showed 88-93% homology to the corresponding regions of the fish myosins. It becomes obvious that several specific residues of the rabbit LMM are substituted to Gly in the salmon LMM as well as the other fish LMMs. This may be involved in the structural instability of the fish myosin tail region.     

Nonmuscle and smooth muscle myosin light chain mRNAs are generated from a single gene by the tissue-specific alternative RNA splicing

We have isolated two cDNA clones for myosin alkali light chain (MLC) mRNA from two respective cDNA libraries of chick gizzard and fibroblast cells by cross-hybridization to the previously isolated cDNA of skeletal muscle MLC. Sequence analysis of the two cloned cDNAs revealed that both of them are homologous to but distinct from the cDNA sequence used as the probe so that they may be classified into members of the MLC family, that they are identical with each other in the 3' and 5' untranslated sequence as well as in the coding sequence with a notable exception of a 39-nucleotide insertion in the fibroblast cDNA, 26 nucleotides of which are used for encoding the C-terminal amino acid sequence, and, therefore, that they encode the identical 142-amino acid sequence with different C-terminals of nine amino acids, each specific for fibroblast and gizzard smooth muscle MLC. The position of the inserted block corresponds exactly to one of the exon-intron junctions in the other MLC genes whose structures have so far been elucidated. DNA blot analysis suggested that the two MLC mRNAs of gizzard (smooth muscle) and fibroblast cells (nonmuscle) are generated from a single gene, probably through alternative RNA splicing mechanisms. RNA blot analysis and S1 nuclease mapping analysis using RNA preparations from fibroblast and gizzard tissues showed that the fibroblast MLC mRNA is expressed predominantly in fibroblast cells, but not, or very scantily if at all, in the gizzard, whereas the reverse is true for the gizzard smooth muscle MLC mRNA.     

Regulation of myosin heavy-chain gene expression during skeletal-muscle hypertrophy.

Changes in the myosin phenotype of differentiated muscle are a prominent feature of the adaptation of the tissue to a variety of physiological stimuli. In the present study the molecular basis of changes in the proportion of myosin isoenzymes in rat skeletal muscle which occur during compensatory hypertrophy caused by the combined removal of synergist muscles and spontaneous running exercise was investigated. The relative amounts of sarcomeric myosin heavy (MHC)- and light (MLC)-chain mRNAs in the plantaris (fast) and soleus (slow) muscles from rats was assessed with cDNA probes specific for different MHC and MLC genes. Changes in the proportion of specific MHC mRNA levels were in the same direction as, and of similar magnitude to, changes in the proportion of myosin isoenzymes encoded for by the mRNAs. No significant changes in the proportion of MLC proteins or mRNA were detected. However, high levels of MLC3 mRNA were measured in both normal and hypertrophied soleus muscles which contained only trace amounts of MLC3 protein. Small amounts of embryonic and neonatal MHC mRNAs were induced in both muscles during hypertrophy. We conclude that the change in the pattern of myosin isoenzymes during skeletal-muscle adaptation to work overload is a consequence of changes in specific MHC mRNA levels.     

Alkali myosin light chains in man are encoded by a multigene family that includes the adult skeletal muscle, the embryonic or atrial, and nonsarcomeric isoforms

A set of cDNA clones coding for alkali myosin light chains (AMLC) was isolated from fetal human skeletal muscle. Nucleotide sequence analysis and RNA expression patterns of individual clones revealed related sequences corresponding to (i) fast fiber type MLC1 and MLC3; (ii) the embryonic MLC that is also expressed in fetal ventricle and adult atrium (MLCemb); and (iii) a nonsarcomeric MLC isoform that is found in all nonmuscle cell types and smooth muscle. The AMLC gene family in man comprises unique copies for MLC1, MLC3 and MLCemb, and multiple copies for the nonsarcomeric MLC genes. The gene coding for MLC1 and MLC3 is located on human chromosome 2.     

Characterization and expression of a myosin heavy–chain isoform in juvenile walleye Sander vitreus

In this study, myosin, the major component of myofibrillar protein in the skeletal muscle, was characterized and its expression was monitored during growth in juvenile walleye Sander vitreus. First, the coding region of myosin heavy chain (MyHC) from the fast skeletal muscle of walleye was amplified by long-distance PCR using a full-length cDNA. Phylogenetic analysis was used to determine the evolutionary relationship of this S. vitreus myosin sequence to other vertebrate myosin sequences. Next, it was established that the myosin isoform was most prevalent in the white muscle, compared with the red and cardiac muscle. Myosin expression was monitored over a series of experiments designed to influence growth. Specifically, change in MyHC mRNA was monitored after acute changes in feeding. Fish exposed to a one-week fasting period showed significant decreases in MyHC mRNA levels by the end of the fast. The effect of feeding was also examined more closely over a 24 h period after feeding, but results showed no significant change in myosin expression levels through this time period. Finally, fish with higher growth rates had higher MyHC mRNA and protein expression levels. This study indicates that MyHC mRNA expression is sensitive to the factors that may influence growth in juvenile S. vitreus .     

Functional activity of the two promoters of the myosin alkali light chain gene in primary muscle cell cultures: comparison with other muscle gene promoters and other culture systems.

Proximal upstream flanking sequences of the mouse myosin alkali light chain gene encoding MLC1F and MLC3F, the mouse alpha-cardiac actin gene and the chicken gene for the alpha-subunit of the acetylcholine receptor were linked to the bacterial chloramphenicol acetyl transferase (CAT) gene and transfected into primary cultures derived from mouse skeletal muscle or into myogenic cell lines. We demonstrate that the mouse MLC1F/MLC3F gene has two functional promoters. In primary muscle cultures, a 1200 bp sequence flanking exon 1 (MLC1F) and a 438 bp sequence flanking exon 2 (MLC3F) direct CAT activity in myotubes, but not in myoblasts or in non myogenic 3T6 and CV1 cells. Developmentally regulated expression is also seen with the alpha-cardiac actin (320 bp) and acetylcholine receptor alpha-subunit (850 bp) upstream sequences in the primary culture system. Transfection experiments with myogenic cell lines show different results with a given promoter construct, reflecting possible differences in the levels of regulatory factors between lines. Different muscle gene promoters behave differently in a given cell line, suggesting different regulatory factor requirements between these promoters.     

Myosin regulatory light chain expression in trout muscle

Muscle's contractile properties can vary along different trajectories, including between muscle fiber types, along the body (within a muscle fiber type), and between developmental stages. This study explores the role of the regulatory myosin light chain (MLC2) in modulating contractile properties in rainbow trout myotomal muscle. Rainbow trout show longitudinal variations in muscle activation and relaxation, with faster contractile properties in the anterior myotome. The expression of two muscle proteins, troponin T and parvalbumin, vary along the length of trout in concert with shifts in muscle activation and relaxation. However, there is no longitudinal variation in myosin heavy chain in trout. This study explores the role of MLC2 (or regulatory light chain), part of the myosin hexamer, in contributing to longitudinal variations in contractile properties of trout swimming muscle. We cloned and sequenced two isoforms of MLC2 from trout muscle and used real-time quantitative polymerase chain reaction to assess the relative expression of these two isoforms in red and white muscle from different body positions of two ages of rainbow trout: parr and smolt. Longitudinal variations in slow (sMLC2) but not fast (fMLC2) regulatory light chain isoforms were observed in young trout parr but not older trout smolts. The differences in sMLC2 expression correlated with shifts in muscle contractile properties in the parr. J. Exp. Zool. 309A:64-72, 2008. (c) 2007 Wiley-Liss, Inc.     

Pattern of Skeletal Muscle Differentiation in Fish: Molecular Biological Approaches

The initial stages of myogenesis going in myoblasts include the stages of induction, determination, and differentiation. The induction and determination of cells in the myotomes are controlled by morphogenetic signals from neighboring tissues of the notochord and neural tube manifested as expression of genes of Shh and Wnt families, respectively. In fish (at the example of danio), this signal is passed to somite cells neighboring the notochord; later the cells migrate to the embryo surface and differentiate into slow muscle fibers. Synthesis of the main contractile proteins, primarily the components of myosin molecule—heavy chain (MHC) and individual isoforms of light chains (MLC1, MLC2, and MLC3)—are encoded by different genes during different ontogenetic stages. The peptide maps obtained after -chymotrypsin digestion of MHCs from larvae, fast and slow skeletal muscle of loach are different, which points to differences in their primary structure. In addition, considerable differences were revealed in the structure of MLC isoforms at different ontogenetic stages. The definitive fast muscle contained three light chain types, MLC1, MLC2, and MLC3; slow muscle, MLC1 and MLC3; while the larval muscle fibers included a specific larval MLCL in addition to MLC3.     

White muscle differentiation in the eel (Anguilla anguilla L.): changes in the myosin isoforms pattern and ATPase profile during post-metamorphic development

Myosin isoforms and their light and heavy chains subunits were studied in the white lateral muscle of the eel during the post metamorphic development, in relation with the myosin ATPase profile. At elver stage VI A1 the myosin isoforms pattern was characterized by at least two isoforms, FM3 and FM2. The fast isomyosin type 1 (FM1) appeared during subsequent development. It increased progressively in correlation with the increase in the level of the light chain LC3f. FM1 became predominant at stage VI A4. At the elver stage VI A1, sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis showed at least two heavy chains, namely type II-1 and II-2. The type II-1 heavy chain disappeared in the yellow eel white muscle, and V8-protease peptide map showed the appearance of a minor heavy chain type II-3 as early as stage VI B. Comparison of myosin heavy chains and myosin isoforms patterns showed the comigration of different myosin isoforms during white muscle development. The myosin ATPase profile was characterized by a uniform pattern as far as stage VI A4. A mosaic aspect in white muscle was observed as early as stage VI B, showing the appearance of small acid labile fibers. This observation suggests that the type II-3 heavy chain is specific to the small fibers.     

Nerve-dependent accumulation of myosin light chain 3 in developing limb musculature

Myosin alkali light chain accumulation in developing quail limb musculature has been analysed on immunoblots using a monoclonal antibody which recognizes an epitope common to fast myosin light chain 1 (MLC1f) and fast myosin light chain 3 (MLC3f). The limb muscle of early embryos (i.e. up to day 10 in ovo) has a MLC profile similar to that observed in myotubes cultured in vitro; although MLC1f is abundant, MLC3f cannot be detected. MLC3f is first detected in 11-day embryos. To determine whether this alteration in MLC3f accumulation is nerve or hormone dependent, limb buds with and without neural tube were cultured as grafts on the chorioallantoic membrane of chick hosts. Although differentiated muscle develops in both aneural and innervated grafts, innervated grafts contain approximately three times as much myosin as aneural grafts. More significantly, although aneural grafts reproducibly accumulate normal levels of MLC1f, they fail to accumulate detectable levels of MLC3f. In contrast, innervated grafts accumulate both MLC1f and MLC3f, suggesting that the presence of neural tube in the graft promotes the maturation, as well as the growth, of muscle tissue. This is the first positive demonstration that innervation is necessary for the accumulation of MLC3f that occurs during normal limb development in vivo.