Degeneration-regeneration as a mechanism contributing to the fast to slow conversion of chronically stimulated fast-twitch rabbit muscle

Summary Extensor digitorum longus muscles of male adult White New Zealand rabbits were indirectly stimulated at 10 Hz for 12 h daily for periods ranging up to 28 days. After four weeks the stimulated muscles showed a nearly uniform profile of high succinate dehydrogenase activity and, when incubated after acid preincubation for myofibrillar adenosine triphosphatase, displayed more dark- and intermediate-staining fibers than their contralateral counterparts. Muscles stimulated from between 6 to 21 days revealed degenerative foci and phagocytosis of degenerated fibers. These fibers were mostly of the fast-twitch, glycolytic type. Small myofibers, which often contained central nuclei, and structures identified as myoblasts or myotubes, reacted with a monoclonal antibody prepared against embryonic myosin heavy chains. The data suggest that under the employed conditions the fast to slow conversion of chronically stimulated fast-twitch rabbit muscle is not exclusively caused by adult fiber transformation, but results in part from the substitution of fast-twitch glycolytic fibers with newly formed fibers that have a high oxidative profile.     

Presence of embryonic myosin in normal postural muscles of the adult rat

Indirect immunofluorescence was used to localize embryonic myosin heavy chains in soleus, adductor longus, tibialis anterior, plantaris, and extensor digitorum longus muscles of 6-month-old rats. A monoclonal antibody (2B6), specifically recognizing rat embryonic myosin, was applied to unfixed, transverse, frozen sections. The number of embryonic myosin-positive (EMP) extrafusal fibers was expressed as a percentage of the total number of fibers. EMP extrafusal fibers were only seen in the soleus and adductor longus muscles, both postural muscles. Approximately 1% of the soleus muscle fibers appeared positively stained for embryonic myosin. The majority of such fibers had a small diameter (<500 ), appeared intensely fluorescent, and typically contained central nuclei. Re-expression of embryonic myosin due to spontaneous fiber denervation is not a likely factor in this study, since alpha-bungarotoxin and N-CAM localization were restricted to the motor end-plate region of EMP fibers. Since embryonic myosin was shown to disappear in all normal-sized myofibers by 2 to 3 months of age, the results suggest that the EMP extrafusal fibers seen in postural muscles of 6 to 12-month-old animals are regenerating myofibers. We speculate that a small number of muscle fibers may be regenerating in normal, adult postural muscles, in response to fiber damage possibly caused by excessive recruitment or overloading.     

Structure and protein composition of sites of papillary muscle attachment to chordae tendineae in avian hearts

Summary Most cardiac myocytes transmit force across fasciae adherentes, specialized sites of cell-cell adhesion. However, some cardiac myocytes in papillary muscle terminate on collagenous connective tissue in the chordae tendineae. These papillary myotendinous junctions (MTJs) are specialized for force transmission from myocytes to extracellular matrix. In the present study, we compared structural molecules at papillary MTJs to those at fasciae adherentes and skeletal MTJs. By using indirect immunofluorescence, we found that papillary MTJs more closely resemble skeletal MTJs in their molecular composition in that they are enriched in talin, vinculin, integrin, and fibronectin. Zeugmatin and -actinin, both components of fasciae adherentes, are absent from papillary MTJs. Although papillary MTJs and skeletal MTJs display strong similarities in structural protein composition, ultrastructural organization of the two junctions is different. Papillary MTJs display little folding of the junctional membrane and, according to morphological criteria, more closely resemble sites of thin filament-membrane association in smooth muscle than skeletal MTJs. Thus, papillary MTJs display a combination of structural characteristics described previously in skeletal and smooth muscles but exhibit few structural features observed previously in cardiac fasciae adherentes.     

Structural differences in the motor domain of temperature-associated myosin heavy chain isoforms from grass carp fast skeletal muscle

We determined coding sequences for three types of grass carp myosin subfragment-1 (S1) heavy chain by extending 5′-regions of the three known genes encoding light meromyosin isoforms (10 °C, intermediate and 30 °C types). The primary structures of these three S1 heavy chain isoforms showed 81.4%, 81.2%, and 97.8% identities between the 10 °C and intermediate types, between the 10 °C and 30 °C types, and between the intermediate and 30 °C types, respectively. Isoform-specific differences were clearly observed between the 10 °C type and the other two types in 97 amino acid residues. Furthermore, among these amino acid mutations, 51 mutations occurred at the conserved residue sites of S1 heavy chain from fish and homoiotherm. Additionally, the 10 °C type showed striking differences compared with the other two types in the two surface loops, loop 1 located near the ATP-binding pocket and loop 2, which is one of the actin-binding sites, suggesting that such structural differences possibly affect their motor functions. Interestingly, this 10 °C-type myosin heavy chain isolated from adult grass carp skeletal muscle was surprisingly similar to the embryonic fast-type myosin heavy chain from juvenile silver carp in the structure of S1 heavy chain, indicating that it may also function as embryonic fast-type myosin heavy chain in juvenile stage.     

Support for a trimeric collar of myosin binding protein C in cardiac and fast skeletal muscle, but not in slow skeletal muscle

Myosin-binding protein C (MyBPC) is proposed to take on a trimeric collar arrangement around the thick filament backbone in cardiac muscle, based on interactions between cardiac MyBPC domains C5 and C8. We have now determined, using yeast two-hybrid and in vitro binding assays, that the C5:C8 interaction is not dependent on the 28-residue cardiac-specific insert in C5. Furthermore, an interaction of similar affinity occurs between domains C5 and C8 of fast skeletal muscle MyBPC, but not between these domains of the slow skeletal muscle protein. These data have implications for the role and quaternary structure of MyBPC in skeletal muscle.     

Embryonic chicken gizzard: expression of the smooth muscle regulatory proteins caldesmon and myosin light chain kinase

The patterns of expression of the smooth muscle regulatory proteins caldesmon and myosin light chain kinase were investigated in the developing chicken gizzard. Immunofluorescent studies revealed that both proteins were expressed as early as E5 throughout the mesodermal gizzard anlage, together with actin, -actinin and a small amount of nonmuscle myosin. These proteins appear to form the scaffold for smooth muscle development, defined by the onset of smooth muscle myosin expression. During E6, a period of extensive cell division, smooth muscle myosin begins to appear in the musculi laterales close to the serosal border and, later, also in the musculi intermedii. Until about E10, myosin reactivity expands into the pre-existing thin filament scaffold. Later in development, the contractile and regulatory proteins co-localize and show a regular uniform staining pattern comparable to that seen in adult tissue. By using immunoblotting techniques, the low-molecular mass form of caldesmon and myosin light chain kinase were detected as early as E5. During further development, the expression of caldesmon switched from the low-molecular mass to the high-molecular mass form; in neonatal and adult tissue, high-molecular mass caldesmon was the only isoform expressed. The level of expression of myosin light chain kinase increased continously during embryonic development, but no embryospecific isoform with a different molecular mass was detected.     

Calcineurin differentially regulates fast myosin heavy chain genes in oxidative muscle fibre type conversion

In skeletal muscle, calcineurin is crucial for myocyte differentiation and in the determination of the slow oxidative fibre phenotype, both processes being important determinants of muscle performance, metabolic health and meat-animal production. Fibre type is defined by the isoform identity of the skeletal myosin heavy chain (MyHC). We have examined the responses of the major MyHC genes to calcineurin signalling during fibre formation of muscle C2C12 cells. We have found that calcineurin acts as a signal to up-regulate the fast-oxidative MyHC2a gene and to down-regulate the faster MyHC2x and MyHC2b genes in a manner that appears to be NFAT-independent. Contrary to expectation, the up-regulation of MyHCslow by calcineurin seems to be time-dependent and is only detectable once the initial differential expression of the post-natal fast MyHC genes has been established. The simultaneous elevated expression of MyHC2a and the repression of MyHC2x and MyHC2b expression indicate that both processes (elevation and repression) are actively coordinated during oxidative fibre conversion. We have further determined that muscle LIM protein (MLP), a calcineurin-binding Z-line co-factor, is induced by calcineurin and that its co-expression with calcineurin has an additive effect on MyHCslow expression. Hence, post-natal fast MyHCs are important early effector targets of calcineurin, whereas MyHCslow up-regulation is mediated in part by calcineurin-induced MLP. This work was supported by the Biotechnology and Biological Sciences Research Council and was carried out in collaboration with the company Genus.     

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     

High resolution scanning electron-microscopic study on the three-dimensional structure of the sarcoplasmic reticulum in the slow (tonic) muscle fibers of the frog,Rana nigromaculata

Summary The three-dimensional structure of the sarcoplasmic reticulum (SR) in the slow (tonic) fibers of the reclus abdominis muscle of the Japanese meadow frog (Rana nigromaculata nigromaculata Hallowell) was examined by high resolution scanning electron microscopy, after removal of the cytoplasmic matrices by the osmium-DMSO-osmium procedure. The SR forms a repetitive network throughout these fibers. At the level of the Z-line, a slender transverse tubule (T-tubule) runs transversely to the longitudinal axis of the myofibril. Small, spherical or ovoid terminal cisternae couple laterally with the T-tubule at intervals of 0.4–1.0 m, and form a terminal cisterna-T-tubule complex on whose surface tiny indentations are occasionally seen. Each terminal cisterna gives rise to a few sarcotubules that run in various directions, divide frequently and form circular or oval meshes of diverse sizes in front of the A- and I-bands. The sarcotubules usually form small meshes in the middle of the A-band, but occasionally fuse and form a poorly developed H-band (fenestrated) collar.     

Autophosphorylation activates Dictyostelium myosin II heavy chain kinase A by providing a ligand for an allosteric binding site in the alpha-kinase domain

Dictyostelium discoideum myosin II heavy chain kinase A (MHCK A), a member of the atypical α-kinase family, phosphorylates sites in the myosin II tail that block filament assembly. Here we show that the catalytic activity of A-CAT, the α-kinase domain of MHCK A (residues 552-841), is severely inhibited by the removal of a disordered C-terminal tail sequence (C-tail; residues 806-841). The key residue in the C-tail was identified as Thr(825), which was found to be constitutively autophosphorylated. Dephosphorylation of Thr(825) using shrimp alkaline phosphatase decreased A-CAT activity. The activity of a truncated A-CAT lacking Thr(825) could be rescued by P(i), phosphothreonine, and a phosphorylated peptide, but not by threonine, glutamic acid, aspartic acid, or an unphosphorylated peptide. These results focused attention on a P(i)-binding pocket located in the C-terminal lobe of A-CAT. Mutational analysis demonstrated that the P(i)-pocket was essential for A-CAT activity. Based on these results, it is proposed that autophosphorylation of Thr(825) activates ACAT by providing a covalently tethered ligand for the P(i)-pocket. Ab initio modeling studies using the Rosetta FloppyTail and FlexPepDock protocols showed that it is feasible for the phosphorylated Thr(825) to dock intramolecularly into the P(i)-pocket. Allosteric activation is predicted to involve a conformational change in Arg(734), which bridges the bound P(i) to Asp(762) in a key active site loop. Sequence alignments indicate that a comparable regulatory mechanism is likely to be conserved in Dictyostelium MHCK B-D and metazoan eukaryotic elongation factor-2 kinases.     

Morphogenesis of nuclear inclusions in the soleplate region of rat skeletal muscle fibers following chronic daily administration of neostigmine

Summary In the course of ultrastructural investigations of motor endplate pathology mediated by calcium ions, intranuclear sarcoplasmic inclusions, either membrane-free (true type) or membrane-delimited (false type), were observed during chronic daily high-dose exposure to the anticholinesterase neostigmine. At the stage in which subjunctional components, including soleplate nuclei, were severely damaged (day 7), the true nuclear inclusions were frequently associated with the disrupted nuclear envelope (fragmentation, vesiculation etc.) and nuclear pores. At a subsequent stage, in which muscle repair was accelerated and most soleplatenuclei were less severely affected (day 21), formation of the false inclusions in these nuclei was enhanced. Analysis of serial sections of the less severely affected nuclei, where only a true inclusion type was present, revealed no sign of invaginated nuclear envelopes or other membranes enclosing the inclusions. Our findings indicate that morphogenesis of true inclusions depends upon the severity of nuclear degeneration, i.e., in severely affected nuclei there is disruption in the nuclear envelope and/or nuclear pores, while in less severely affected nuclei, either a pinched-off invagination or diffusion of excessive sarcoplasmic proteins into the nucleus via nuclear pores occurs.     

Expression of myosin heavy chain isoforms in myogenic clones obtained from developing quail breast muscle

Summary Monoclonal antibodies specifically recognizing cardiac and extraocular muscle myosin heavy chains of the quail (Coturnix coturnix japonica) were used to determine the patterns of expression of these isoforms in clonal cultures of embryonic quail myoblasts. Myoblasts prepared from 9 day embryonic pectoralis are virtually homogeneous in their ability to form clones expressing both cardiac and extraocular isoforms. The majority of myoblasts obtained from day 5 embryos also formed clones which co-express the cardiac and extraocular isoforms, but a small percentage of the clones expressed only cardiac isoforms.     

Characterisation of red and white muscle myosin heavy chain gene coding sequences from antarctic and tropical fish

To understand molecular adaptation for locomotion at different environmental temperatures, we have studied the myosin heavy chain genes as these encode the molecular motors involved. For this purpose, cDNA libraries from white (fast) and red (slow) myotomal muscle of an Antarctic and a tropical fish were constructed and from these different myosin heavy chain cDNAs were isolated. Northern and in situ hybridisation confirmed in which type of muscle these isoform genes are expressed. The cDNAs were sequenced and the structure of the ATPase sites compared. There was a marked similarity between the tropical fast myosin and the Antarctic slow myosin in the loop 1 region, which has similar amino acid side chains, charge distribution and conformation. These findings help to explain why the myofibrils isolated from white muscle of tropical fish show a lower specific ATPase activity than the white muscle of Antarctic fish but a similar activity to the Antarctic red (slow) muscle. It also provides insight into the way molecular motors in Antarctic fish have evolved to produce more power and thus ensure effective swimming at near zero temperatures by the substitution or addition of a few residues in strategic regions, which include the ATPase site.     

Response of rigor cross-bridges to stretch detected by fluorescence lifetime imaging microscopy of myosin essential light chain in skeletal muscle fibers

We applied fluorescence lifetime imaging microscopy to map the microenvironment of the myosin essential light chain (ELC) in permeabilized skeletal muscle fibers. Four ELC mutants containing a single cysteine residue at different positions in the C-terminal half of the protein (ELC-127, ELC-142, ELC-160, and ELC-180) were generated by site-directed mutagenesis, labeled with 7-diethylamino-3-((((2-iodoacetamido)ethyl)amino)carbonyl)coumarin, and introduced into permeabilized rabbit psoas fibers. Binding to the myosin heavy chain was associated with a large conformational change in the ELC. When the fibers were moved from relaxation to rigor, the fluorescence lifetime increased for all label positions. However, when 1% stretch was applied to the rigor fibers, the lifetime decreased for ELC-127 and ELC-180 but did not change for ELC-142 and ELC-160. The differential change of fluorescence lifetime demonstrates the shift in position of the C-terminal domain of ELC with respect to the heavy chain and reveals specific locations in the lever arm region sensitive to the mechanical strain propagating from the actin-binding site to the lever arm.     

Chicken cardiac myofibrillogenesis studied with antibodies specific for titin and the muscle and nonmuscle isoforms of actin and tropomyosin

Summary Myofibrillogenesis was studied in cultured chick cardiomyocytes using indirect immunofluorescence microscopy and antibodies against - and -actin, muscle and nonmuscle tropomyosin, muscle myosin, and titin. Initially, cardiomyocytes, devoid of myofibrils, developed variable numbers of stress fiber-like structures with uniform staining for anti-muscle and nonmuscle actin and tropomyosin, and diffuse, weak staining with anti-titin. Anti-myosin labeled bundles of filaments that exhibited variable degrees of association with the stress fiber-like structures. Myofibrillogenesis occurred with a progressive, and generally simultaneous, longitudinal reorganization of stress fiber-like structures to form primitive sarcomeric units. Titin appeared to attain its mature pattern before the other major contractile proteins. Changes in the staining patterns of actin, tropomyosin, and myosin as myofibrils matured were interpreted as due to longitudinal filament alignment occurring before ordering in the axial direction. Non-muscle actin and tropomyosin were found with sarcomeric periodicity in the initial stages of sarcomere myofibrillogenesis, although their staining patterns were not identical. The localization of the sarcomeric proteins -actin and muscle tropomyosin in stress fiber-like structures and the incorporation of non-muscle proteins in the initial stages of sarcomere organization bring into question the meaning of sarcomeric proteins in regard to myofibrillogenesis.