Immunochemical analysis of protein isoforms in thick myofilaments of regenerating skeletal muscle

The expression of myosin heavy chain (MHC) and C-protein isoforms has been examined immunocytochemically in regenerating skeletal muscles of adult chickens. Two, five, and eight days after focal freeze injury to the anterior latissimus dorsi (ALD) and posterior latissimus dorsi (PLD) muscles, cryostat sections of injured and control tissues were reacted with a series of monoclonal antibodies previously shown to specifically bind MHC or C-protein isoforms in adult or embryonic muscles. We observed that during the course of regeneration in each of these muscles there was a reproducible sequence of antigenic changes consistent with differential isoform expression for these two proteins. These isoform switches appear to be tissue specific; i.e., the isoforms of MHC and C-protein which are expressed during the regeneration of a "slow" muscle (ALD) differ from those which are synthesized in a regenerating "fast" muscle (PLD). Evidence has been obtained for the transient expression of a "fast-type" MHC and C-protein during ALD regeneration. Furthermore, during early stages of PLD regeneration this muscle contains MHCs which antigenically resemble those found in the pectoralis muscle at embryonic and early posthatch stages of development. Both regenerating muscles express an isoform of C-protein which appears immunochemically identical to that normally expressed in embryonic and adult cardiac muscle. These results support the concept that isoform transitions in regenerating skeletal muscles qualitatively resemble those found in developing muscles but differences may exist in temporal and tissue-specific patterns of gene expression.     

Expression of a novel tropomyosin isoform in axolotl heart and skeletal muscle

TPM1κ is an alternatively spliced isoform of the TPM1 gene whose specific role in cardiac development and disease is yet to be elucidated. Although mRNA studies have shown TPM1κ expression in axolotl heart and skeletal muscle, it has not been quantified. Also the presence of TPM1κ protein in axolotl heart and skeletal muscle has not been demonstrated. In this study, we quantified TPM1κ mRNA expression in axolotl heart and skeletal muscle. Using a newly developed TPM1κ specific antibody, we demonstrated the expression and incorporation of TPM1κ protein in myofibrils of axolotl heart and skeletal muscle. The results support the potential role of TPM1κ in myofibrillogenesis and sarcomeric function. J. Cell. Biochem. 110: 875–881, 2010. © 2010 Wiley‐Liss, Inc.     

Heart C-protein is transiently expressed during skeletal muscle development in the embryo, but persists in cultured myogenic cells

The expression of cardiac and white skeletal C-protein isoforms was analyzed in developing chicken embryos and in primary skeletal muscle cell cultures by immunoblot and immunofluorescence staining using polyclonal antibodies specific for both of the two different proteins. In the embryo, cardiac C-protein was detected in the developing heart from very early stages through adulthood. In skeletal muscle, cardiac C-protein is shown to be transiently expressed between Days 3 and 15 during development. In contrast, the expression of white skeletal C-protein is gradual and progressive starting approximately from Day 15 on in development. In primary cell cultures of skeletal muscle, however, cardiac C-protein remained expressed throughout prolonged culture time, this in conjunction with white skeletal C-protein. Thus the down regulation of cardiac C-protein and the transition from cardiac C-protein to adult skeletal (white) C-protein which was observed during skeletal muscle development in vivo, does not seem to go to completion in the in vitro system.     

Changes in tropomyosin subunits and myosin light chains during development of chicken and rabbit striated muscles.

We have selected tropomyosin subunits and myosin light chains as representative markers of the myofibrillar proteins of the thin and thick filaments and have studied changes in the type of proteins present during development in chicken and rabbit striated muscles. The β subunit of tropomyosin is the major species found in all embryonic skeletal muscles studied. During development the proportion of the α subunit of tropomyosin gradually increases so that in adult skeletal muscles the α subunit is either the only or the major species present. In contrast, cardiac muscles of both chicken and rabbit contain only the α subunit which remains invariant with development. Two subspecies of the α subunit of tropomyosin which differ in charge only were found in adult and embryonic chicken skeletal muscles. Only one of these subspecies seems to be common to chicken cardiac tropomyosin. With respect to myosin light chains, embryonic skeletal fast muscle myosin of both species resembles the adult fast muscle myosin except that the LC₃ light chain characteristic of the adult skeletal fast muscle is present in smaller amounts. The significance of these isozymic changes in the two myofibrillar proteins is discussed in terms of a model of differential gene expression during development of chicken and rabbit skeletal muscles.     

The earliest form of C-protein expressed during striated muscle development is immunologically the same as cardiac-type C-protein

A monoclonal antibody (C-315) specific for cardiac-type C-protein was prepared and, in combination with other antibodies specific for fast and slow skeletal muscle C-proteins, it was used to investigate the expression of C-protein isoforms in developing striated muscle cells in vivo and in vitro. During embryonic development of skeletal muscles, a C-protein recognized by C-315 appeared first but only transiently, it being replaced subsequently by two other isoforms recognized by the antibodies to slow and fast skeletal muscle C-proteins in a fiber-type specific manner as previously demonstrated (Obinata et al. (1984) Develop. Biol. 101, 116-124). In contrast, only cardiac-type C-protein was detected in cardiac muscle throughout the developmental stages. When myogenesis in vitro was monitored using the same antibodies, C-315 binding appeared first in multinucleated myotubes as in vivo which was followed by the sequential expression of two other C-protein variants. The reactivity of C-315 as well as that of anti-slow and anti-fast skeletal C-protein antibodies persisted during muscle development in culture. Thus, this study demonstrates that the earliest form of C-protein expressed in striated muscles may either be a cardiac-type isoform or a unique embryonic protein containing an epitope in common with the adult cardiac-type protein, and that transitions of C-protein isoform expression characteristic of each fiber-type occur during muscle development in vivo but not in vitro.     

A novel variant of cardiac myosin-binding protein-C that is unable to assemble into sarcomeres is expressed in the aged mouse atrium

Cardiac myosin-binding protein-C (MyBP-C), also known as C-protein, is one of the major myosin-binding proteins localizing at A-bands. MyBP-C has three isoforms encoded by three distinct genes: fast-skeletal, slow-skeletal, and cardiac type. Herein, we are reporting a novel alternative spliced form of cardiac MyBP-C, MyBP-C(+), which includes an extra 30 nucleotides, encoding 10 amino acids in the carboxyl-terminal connectin/titin binding region. This alternative spliced form of MyBP-C(+) has a markedly decreased binding affinity to myosin filaments and connectin/titin in vitro and does not localize to A-bands in cardiac myocytes. When MyBP-C(+) was expressed in chicken cardiac myocytes, sarcomere structure was markedly disorganized, suggesting it has possible dominant negative effects on sarcomere organization. Expression of MyBP-C(+) is hardly detected in ventricles through cardiac development, but its expression gradually increases in atria and becomes the dominant form after 6 mo of age. The present study demonstrates an age-induced new isoform of cardiac MyBP-C harboring possible dominant negative effects on sarcomere assembly.     

The Superfast Human Extraocular Myosin Is Kinetically Distinct from the Fast Skeletal IIa,IIb, and IId Isoforms

Humans express five distinct myosin isoforms in the sarcomeres of adult striated muscle (fast IIa, IId, the slow/cardiac isoform I/β, the cardiac specific isoform α, and the specialized extraocular muscle isoform). An additional isoform, IIb, is present in the genome but is not normally expressed in healthy human muscles. Muscle fibers expressing each isoform have distinct characteristics including shortening velocity. Defining the properties of the isoforms in detail has been limited by the availability of pure samples of the individual proteins. Here we study purified recombinant human myosin motor domains expressed in mouse C₂C₁₂ muscle cells. The results of kinetic analysis show that among the closely related adult skeletal isoforms, the affinity of ADP for actin·myosin (K_AD) is the characteristic that most readily distinguishes the isoforms. The three fast muscle myosins have K_AD values of 118, 80, and 55 μm for IId, IIa, and IIb, respectively, which follows the speed in motility assays from fastest to slowest. Extraocular muscle is unusually fast with a far weaker K_AD = 352 μm. Sequence comparisons and homology modeling of the structures identify a few key areas of sequence that may define the differences between the isoforms, including a region of the upper 50-kDa domain important in signaling between the nucleotide pocket and the actin-binding site.     

Characterization of C-protein isoforms expressed in developing, denervated, and dystrophic chicken skeletal muscles by two-dimensional gel electrophoresis

C-Proteins in developing, denervated, and dystrophic chicken skeletal muscles were examined by means of two-dimensional (2D) gel electrophoresis in combination with immunoblotting. In this analysis, the electrophoresis system which was devised by Hirabayashi (Anal. Biochem. 117, 443-451, 1981) provided excellent resolution; three C-protein variants, one fast-type (Cf) and two slow-types (CS3 and CS4) with different Mrs and pIs, were distinguished on a 2D gel. In the neonatal breast muscle, both Cf and CS3 were detected, but during postnatal development, CS3 disappeared from this muscle and Cf became only the C-protein isoform in the adult muscle. In posterior latissimus dorsi (PLD) muscle, both Cf and CS3 were similarly detected at the neonatal stage, but CS3 was replaced by CS4 as this muscle developed. When the breast and PLD muscles were denervated or suffered from muscular dystrophy, both CS3 and CS4 were co-expressed in these muscles in addition to Cf. These results definitely show that the C-protein isoform pattern varies during development and degeneration of chicken skeletal muscles, and in addition the dystrophic or denervated muscle differs from the neonatal muscle with regard to C-protein isoform expression. We suggest that chicken skeletal muscle degenerating due to denervation or muscular dystrophy does not simply recapture the nature of the neonatal muscle, but shifts in a somewhat different direction.     

The second EF-hand is responsible for the isoform-specific sorting of myosin essential light chain.

It has been known that isoforms of myosin essential light chain (LC) exhibit the isoform-specific sorting within cardiac myocytes and fibroblasts. In order to analyze which domain of LC is responsible for the sorting, various chimeric cDNA constructs between human nonmuscle isoform (LC3nm) and chicken fast skeletal muscle isoform (LC3f) were generated and expressed in cultured chicken cardiac myocytes. If chimeras contained LC3f sequence at the place that was restricted by BssHII and PstI, they were preferentially sorted to sarcomeres and precisely localized at A-bands, and their incorporation levels into the A-bands were identical with that of the wild type LC3f. However, other chimeras were distributed throughout the cytoplasm like the wild type LC3nm. Comparison of amino acid sequences revealed that 12 amino acids are different between chicken LC3f and human LC3nm in the BssHII-PstI fragment, and these amino acids are located within the second EF-hand of LC. These results indicated that the second EF-hand is responsible for the isoform-specific sorting of LC. Although the second EF-hand is not included in the key contacts with myosin heavy chain, it is supposed that this domain is important for the relative disposition of neighboring domains. Thus, the 12 amino acids in the second EF-hand might play a key role for modulation of overall configuration of LC, thereby influencing the precise association of the key contacts.     

Structural and phylogenetic analysis of the chicken ventricular myosin heavy chain rod

Summary We have isolated and characterized five overlapping clones that encompass 3.2 kb and encode a part of the short subfragment 2, the hinge, and the light meromyosin regions of the myosin heavy chain rod as well as 143 bp of the 3 untranslated portion of the mRNA. Northern blot analysis showed expression of this mRNA mainly in ventricular muscle of the adult chicken heart, with trace levels detected in the atrium. Transient expression was seen in skeletal muscle during development and in regenerating skeletal muscle following freeze injury. To our knowledge, this is the first report of an avian ventricular myosin heavy chain sequence. Phylogenetic analysis indicated that this isoform is a distant homolog of other ventricular and skeletal muscle myosin heavy chains and represents a distinct member of the multigene family of sarcomeric myosin heavy chains. The ventricular myosin heavy chain of the chicken is either paralogous to its counterpart in other vertebrates or has diverged at a significantly higher rate.Department of Pharmacological and Physiological Sciences, The University of Chicago, Chicago, IL60637, USA     

Isoforms of C-protein in adult chicken skeletal muscle: detection with monoclonal antibodies

Monoclonal antibodies (McAbs) specific for the C-proteins of chicken pectoralis major and anterior latissimus dorsi (ALD) muscles have been produced and characterized. Antibody specificity was demonstrated by solid phase radioimmunoassay (RIA), immunoblots, and immunofluorescence cytochemistry. Both McAbs MF-1 (or MF-21) and ALD-66 bound to myofibrillar proteins of approximately 150,000 daltons; the former antibody reacted with pectoralis but not ALD myofibrils, whereas the latter recognized ALD but not pectoralis myofibrils. Chromatographic elution of the antigens from DEAE-Sephadex, and their distribution in the A-band, support the conclusion that both of these antibodies recognize variant isoforms of C-protein. Since both McAbs react with a protein of similar molecular weight in the A-band of all myofibrils of the posterior latissimus dorsi (PLD) muscle, we suggest that either another isoform of C-protein exists in the PLD muscle or both pectoralis and ALD-like isoforms coexist in the A-bands of PLD muscle.     

Immunochemical analysis of C-protein isoform transitions during the development of chicken skeletal muscle

Isoforms of C-protein in adult chickens which differ in fast (pectoralis major, PM) and slow (anterior latissimus dorsi, ALD) skeletal muscles can be distinguished immunochemically with monoclonal antibodies (McAbs) specific for the respective fast (MF-1) and slow (ALD-66) protein variants (Reinach et al., 1982 and 1983). The expression of these C-proteins during chick muscle development in vivo has been analyzed by immunoblot and immunofluorescence procedures. Neither MF-1 nor ALD-66 reacted with whole-cell lysates or myofibrils from PM of 12-day-old embryos. However, both McAbs bound to peptides of 145 kDa in PM from late embryonic and young posthatched chickens. All of the myofibers in these muscles reacted with both antibodies, but the binding of the anti-slow McAb (ALD-66) diminished progressively with age and was completely negative with PM by 2 weeks after hatching. In contrast, the ALD muscle from 17 days in ovo thru adulthood only reacted with ALD-66; no binding of MF-1 could be detected at these stages. Since both fast and slow myosin light chains (LC) coexist within embryonic pectoralis and ALD muscles (e.g., G. F. Gauthier, S. Lowey, P. A. Benfield, and A. W. Hobbs, 1982, J. Cell Biol.92, 471–484) yet segregate to specific fast and slow muscle fibers at different stages of development, the temporal transitions of C-protein and myosin LC were compared during myogenesis. “Slow-type” C-protein appeared after the disappearance of slow myosin light chains, whereas the accumulation of the “fast-type” light chains occurred before the expression of “fast-type” C-protein. The pattern of isoform transitions appears to be far more complex than previously suspected.     

Phosphorylation of skeletal and cardiac muscle C-proteins by the catalytic subunit of cAMP-dependent protein kinase

Catecholamines are known to influence the contractility of cardiac and skeletal muscles, presumably via cAMP-dependent phosphorylation of specific proteins. We have investigated the in vitro phosphorylation of myofibrillar proteins by the catalytic subunit of cAMP-dependent protein kinase of fast- and slow-twitch skeletal muscles and cardiac muscle with a view to gaining a better understanding of the biochemical basis of catecholamine effects on striated muscles. Incubation of canine red skeletal myofibrils with the isolated catalytic subunit of cAMP-dependent protein kinase and Mg-[gamma-32P]ATP led to the rapid incorporation of [32P]phosphate into five major protein substrates of subunit molecular weights (MWs) 143,000, 60,000, 42,000, 33,000, and 11,000. The 143,000 MW substrate was identified as C-protein; the 42,000 MW substrate is probably actin; the 33,000 MW substrate was shown not to be a subunit of tropomyosin and, like the 60,000 and 11,000 MW substrates, is an unidentified myofibrillar protein. Isolated canine red skeletal muscle C-protein as phosphorylated to the extent of approximately 0.5 mol Pi/mol C-protein. Rabbit white skeletal muscle and bovine cardiac muscle C-proteins were also phosphorylated by the catalytic subunit of cAMP-dependent protein kinase, both in myofibrils and in the isolated state. Cardiac C-protein was phosphorylated to the extent of 5-6 mol Pi/mol C-protein, whereas rabbit white skeletal muscle C-protein was phosphorylated at the level of approximately 0.5 mol Pi/mol C-protein. As demonstrated earlier by others, C-protein of skeletal and cardiac muscles inhibited the actin-activated myosin Mg2+-ATPase activity at low ionic strength in a system reconstituted from the purified skeletal muscle contractile proteins (actin and myosin).(ABSTRACT TRUNCATED AT 250 WORDS)     

Structural evidence for the interaction of C-protein (MyBP-C) with actin and sequence identification of a possible actin-binding domain

C-protein (MyBP-C) is a myosin-binding protein that is usually seen in two sets of seven to nine positions in the C-zones in each half of the vertebrate striated muscle A-band. Skeletal muscle C-protein is a modular structure containing ten sub-domains (C1 to C10) of which seven are immunoglobulin-type domains and three (C6, C7 and C9) are fibronectin-like domains. Cardiac muscle C-protein has an extra N-terminal domain (C0) and also some sequence insertions, one of which provides phosphorylation sites. It is conceivable that C-protein has both a structural and regulatory role within the sarcomere. The precise mode of binding of C-protein to the myosin filament has not been determined. However, detailed ultrastructural studies have suggested that C-protein, which binds to myosin, can give rise to a longer periodicity (about 435A) than the intrinsic myosin filament repeat of 429A. The reason for this has remained a puzzle for over 25 years. Here we show by modelling and computation that the presence of this longer periodicity could be explained if the myosin-binding part of C-protein binds to myosin with the expected 429A repeat, but if there are systematic interactions of the N-terminal end of C-protein with the neighbouring actin filaments in the hexagonal lattice of filaments in the A-band. We also show that if they occur these interactions would probably only arise in defined muscle states. Further analysis of the MyBP-C sequence identifies a possible actin-binding domain in the Pro-Ala-rich sequence found at the N terminus of skeletal MyBP-C and between domains C0 and C1 in the cardiac sequence.     

Induction of zygote formation by ethylene during the sexual development of the cellular slime mold Dictyostelium mucoroides

Immunochemical studies have identified a distinct myosin heavy chain (MHC) in the chicken embryonic skeletal muscle that was undetectable in this muscle in the posthatch period by both immunocytochemical and the immunoblotting procedures. This embryonic isoform, identified by antibody 96J, which also recognises the cardiac and SM1 myosin heavy chains, differs from the embryonic myosin heavy chain belonging to the fast class described previously. Although the fast embryonic isoform is a major species present in the leg and pectoral embryonic muscles, slow embryonic isoform was present in significant amounts during early embryonic development. Immunocytochemical studies using another monoclonal antibody designated 9812, which is specific for SM1 MHC, showed this isoform to be restricted to only presumptive slow muscle cells. From these studies and those reported on the changes in SM2 MHC, it is proposed that as is the case for the fast class, there also exists a slow class of myosin heavy chains composed of slow embryonic, SM1 and SM2 isoforms. The differentiation of a muscle cell involves transitions in a series of myosin isozymes in both presumptive fast and slow skeletal muscle cells.     

Characterization of the C-protein from posterior latissimus dorsi muscle of the adult chicken: heterogeneity within a single sarcomere

Specific isoforms of myofibrillar proteins are expressed in different muscles and in various fiber types within a single muscle. We have isolated and characterized monoclonal antibodies against C-proteins from slow tonic (anterior latissimus dorsi, ALD) and fast twitch (pectoralis major) muscles of the chicken. Although the antibody against "fast" C-protein (MF-1) did not bind to the "slow" isoform and the antibody to the "slow" C-protein (ALD-66) did not bind to the "fast" isoform, we observed that both antibodies bound C-protein from the posterior latissimus dorsi (PLD) muscle. Here we demonstrate that in the PLD muscle the binding sites of these two antibodies reside in two different C-protein isoforms which have different molecular weights and can be separated by hydroxylapatite column chromatography. Since we have shown previously that both these antibodies stain all myofibers and myofibrils derived from PLD muscle, we conclude that all myofibers in this muscle contain both isoforms with all sarcomeres.     

Developmental relationship of myosin binding proteins (myomesin, connectin and C-protein) to myosin in chicken somites as studied by immunofluorescence microscopy

The developmental relationship of myosin binding proteins (myomesin, connectin and C-protein) to myosin was studied in chicken cervical somites by immunofluorescence microscopy. Muscle and non-muscle myosins initially appeared as slender rods at the same sites, and then, fused to form non-striated fibrils. As muscle myosin formed striated structures (A bands), non-muscle myosin disappeared from this structure. Myomesin (reactive with monoclonal antibodies MyB4 and MyBB78) and connectin (carboxy terminal region, reactive with monoclonal antibody T51) were seen as dots in the center of these myosin rods. These proteins then formed characteristic mature striations on non-striated fibrils of myosin. Earlier alignment of these myosin binding proteins rather than myosin indicates that the correct assembly of these proteins seems to be related to the formation of initial myosin rods as well as subsequent linear and periodic alignment of myosin molecules to form early A bands. Connectin spots reactive with 9D10 were scattered around myosin rods/myomesin dots/connectin T51 dots. These spots may represent radiating connectin filaments from these rods/dots to link myosin rods to the I-Z-I structures of myofibrils to be incorporated. Since the slow isoform of C-protein formed its characteristic bands ("doublets") prior to H zone formation within A bands by myosin, this isoform may help to precisely align myosin filaments within the A band region. The presence of the slow, then the slow and the cardiac, and finally the co-existence of the slow and the fast isoforms of C-protein may interfere with the incorporation and co-polymerization of non-adult isoforms into myofibrils.     

Distinction between smooth muscle,fibroblasts and endothelial cells in culture by the use of fluoresceinated antibodies against smooth muscle actin

Summary FITC-labelled antibodies against native actin from chicken gizzard smooth muscle (Gröschel-Stewart et al., 1976) have been used to stain cultures of guinea-pig vas deferens and taenia coli, rabbit thoracic aorta, rat ventricle and chick skeletal muscle. The I-band of myofibrils of cardiac muscle cells and skeletal muscle myotubes stains intensely. In isolated smooth muscle cells, the staining is located exclusively on long, straight, non-interrupted fibrils which almost fill the cell. Smooth muscle cells which have undergone morphological dedifferentiation to resemble fibroblasts with both phase-contrast microscopy and electronmicroscopy still stain intensely with the actin antibody. In those muscle cultures which contain some fibroblasts or endothelial cells, the non-muscle cells are not stained with the actin antibody even when the reactions are carried out at 37° C for 1 h or after glycerination. Prefusion skeletal muscle myoblasts also do not stain with this antibody.It is concluded that the actin antibody described in this report is directed against a particular sequence of amino acids in muscle actin which is not homologous with non-muscle actin. The usefulness of this antibody in determining the origin of cells in certain pathological conditions such as atherosclerosis is discussed.This work was supported by the Life Insurance Medical Research Fund of Australia and New Zealand, the National Heart Foundation of Australia, the Deutsche Forschungsgemeinschaft and the Wellcome Trust (London). We thank Janet D. McConnell for excellent technical assistance     

The cardiac mutant Mexican axolotl is a unique animal model for evaluation of cardiac myofibrillogenesis

Hearts from cardiac mutant Mexican axolotl, Ambystoma mexicanum, do not form organized myofibrils and fail to beat. Though previous biochemical and immunohistochemical experiments showed a possible reduction of cardiac tropomyosin it was not clear that this caused the lack of organized myofibrils in mutant hearts. We used cationic liposomes to introduce both rabbit and chicken tropomyosin protein into whole hearts of embryonic axolotls in whole heart organ cultures. The mutant hearts had a striking increase in the number of well-organized sarcomeric myofibrils when treated with rabbit or chicken tropomyosin. FITC-labeled rabbit tropomyosin was used to examine the kinetics of incorporation of the exogenous protein into mutant hearts and confirmed the uptake of exogenous protein by the cells of live hearts in culture. By 4 h of transfection, both normal and mutant hearts were found to incorporate FITC-labeled tropomyosin into myofibrils. We also delivered an anti-tropomyosin antibody (CH 1) into normal hearts to disrupt the existing cardiac myofibrils which also resulted in reduced heartbeat rates. CH1 antibody was detected within the hearts and disorganization of the myofibrils was apparent when compared to normal controls. Introduction of a C-protein monoclonal antibody (ALD 66) did not result in a disruption of organized myofibrils. The results show clearly that chicken or rabbit tropomyosin could be incorporated by the mutant hearts and that it was sufficient to overcome the factors causing a lack of myofibril formation in the mutant. This finding also suggests that a lack of organized myofibrils is caused primarily by either inadequate levels of tropomyosin or endogenous tropomyosin in mutant hearts is unsuitable for myofibril formation, which we were able to duplicate with the introduction of tropomyosin antibody. Furthermore, incorporation of a specific exogenous protein or antibody into normal and mutant hearts of the Mexican axolotl in whole heart organ culture offers an unique model to evaluate functionalroles of contractile proteins necessary for cardiac development and differentiation.