Cell cycles and in vitro transdifferentiation and regeneration of isolated, striated muscle of jellyfish

Isolated, mononucleated, cross-striated muscle cells of a medusa can transdifferentiate in vitro to various new cell types and even form a complex regenerate. The transdifferentiation events follow a strict pattern. The first new cell type resembles smooth muscle and is formed without a preceding DNA replication. This cell type behaves like a stem cell and by quantal cell cycles produces all other new cell types. Some preparations develop an inner and an outer layer separated by a basal lamella. Formation of these layers does not depend on DNA replication. When layers do not form, each division results in nerve cells and smooth muscle cells. If separation into layers occurs, then a regenerate will be formed, and in the course of only two cell cycles all necessary cell types to form a functional regenerate will differentiate.     

The homeobox gene Msx in development and transdifferentiation of jellyfish striated muscle

Bilaterian Msx homeobox genes are generally expressed in areas of cell proliferation and in association with multipotent progenitor cells. Likewise, jellyfish Msx is expressed in progenitor cells of the developing entocodon, a cell layer giving rise to the striated and smooth muscles of the medusa. However, in contrast to the bilaterian homologs, Msx gene expression is maintained at high levels in the differentiated striated muscle of the medusa in vivo and in vitro. This tissue exhibits reprogramming competence. Upon induction, the Msx gene is immediately switched off in the isolated striated muscle undergoing transdifferentiation, to be upregulated again in the emerging smooth muscle cells which, in a stem cell like manner, undergo quantal cell divisions producing two cell types, a proliferating smooth muscle cell and a differentiating nerve cell. This study indicates that the Msx protein may be a key component of the reprogramming machinery responsible for the extraordinary transdifferentation and regeneration potential of striated muscle in the hydrozoan jellyfish.     

Trichomonas vaginalis Hmp35, a putative pore-forming hydrogenosomal membrane protein,can form a complex in yeast mitochondria

An abundant integral membrane protein, Hmp35, has been isolated from hydrogenosomes of Trichomonas vaginalis. This protein has no known homologue and exists as a stable 300-kDa complex, termed HMP35, in membranes of the hydrogenosome. By using blue native gel electrophoresis, we found the HMP35 complex to be stable in 2 m NaCl and up to 5 m urea. The endogenous Hmp35 protein was largely protease-resistant. The protein has a predominantly beta-sheet structure and predicted transmembrane domains that may form a pore. Interestingly, the protein has a high number of cysteine residues, some of which are arranged in motifs that resemble the RING finger, suggesting that they could be coordinating zinc or another divalent cation. Our data show that Hmp35 forms one intramolecular but no intermolecular disulfide bonds. We have isolated the HMP35 complex by expressing a His-tagged Hmp35 protein in vivo followed by purification with nickel-agarose beads. The purified 300-kDa complex consists of mostly Hmp35 with lesser amounts of 12-, 25-27-, and 32-kDa proteins. The stoichiometry of proteins in the complex indicates that Hmp35 exists as an oligomer. Hmp35 can be targeted heterologously into yeast mitochondria, despite the lack of homology with any yeast protein, demonstrating the compatibility of mitochondrial and hydrogenosomal protein translocation machineries.     

The proportion altering factor (PAF) and the in vitro transdifferentiation of isolated striated muscle of jellyfish into nerve cells

The effect of proportion altering factor (PAF) on the transdifferentiation of isolated striated muscle into RFamide-positive nerve cells was investigated. The factor reduces incorporation of 3H-thymidine into replicating DNA; the effect is concentration-dependent and reversible. Transdifferentiation to nerve cells increases by up to 60% if PAF is applied shortly before or at the time of initiation of DNA synthesis. When treatment was terminated 4 h before the start of S-phase or when PAF was applied at the peak of S-phase no increase in nerve cell formation was observed.     

Heat shock protein 27 and alpha B-crystallin can form a complex, which dissociates by heat shock.

We have previously demonstrated that in non-oncogenic adenovirus-transformed baby rat kidney cells a complex of hsp27 and a 22-kDa protein is present, which is lacking in oncogenic cells (Zantema, A., de Jong, E., Lardenoije, R., and van der Eb, A. J. (1989) J. Virol. 63, 3368-3375). Here we show that the 22-kDa protein is identical to alpha B-crystallin. The complex of hsp27 and alpha B-crystallin is also found in some other (non-transformed) cells. However, in most cells tested only hsp27 and no alpha B-crystallin is synthesized. Gel filtration studies show that both proteins are present almost exclusively in a 700-kDa complex. Heat treatment makes the complex fall apart, which is accompanied by a change in the conformation of alpha B-crystallin. Upon recovery, complexes are formed again from both pre-existing and newly synthesized proteins.     

A binary complex of troponin-I and troponin-T from Akazara scallop striated adductor muscle.

A binary complex consisting of Mr 19,000 and Mr 40,000 components was co-purified with troponin from a crude troponin fraction of Akazara scallop (Chlamys nipponensis akazara) striated adductor muscle. This complex is incapable of conferring Ca(2+)-sensitivity to rabbit reconstituted actomyosin Mg-ATPase activity, rather strongly inhibiting it, but became capable on further complexing with Akazara scallop troponin-C. To examine the effects of the Mr 19,000 and Mr 40,000 components on the ATPase activity, they were separated from each other by CM-Toyopearl column chromatography. The Mr 19,000 component strongly inhibited the Mg-ATPase activity of actomyosin-tropomyosin and the inhibition was reversed by further addition of the Akazara scallop troponin-C. On the other hand, the Mr 40,000 component slightly increased it. On hybridization with the Akazara scallop troponin subunits, the Mr 19,000 and Mr 40,000 components were shown to be able to substitute for troponin-I and troponin-T, respectively. The amino acid compositions of the Mr 40,000 component and troponin-T were almost identical, and those of the Mr 19,000 component and Mr 17,000 C-terminal fragment of the troponin-I resembled each other fairly well. From these results, it may be concluded that the Mr 19,000-40,000 binary complex is the troponin-I-troponin-T complex.     

Studies on the endoplasmic reticulum. III. Its form and distribution in striated muscle cells

Several types of striated muscle have been examined by the technics of electron microscopy and the findings in myotome fibers of Amblystoma larvae, the sartorius, and cardiac muscle of the rat are reported on in some detail. Particular attention has been given to structural components of the interfibrillar sarcoplasm and most especially to a finely divided, vacuolar system known as the sarcoplasmic reticulum. This consists of membrane-limited vesicles, tubules, and cisternae associated in a continuous reticular structure which forms lace-like sleeves around the myofibrils. It shows a definable organization which repeats with each sarcomere of the fiber so that the entire system is segmented in phase with the striations of the associated myofibrils. Details of these repetitive patterns are presented diagrammatically in Text-figs. 1, 2, and 3 on pages 279, 283, and 288 respectively. The system is continuous across the fiber at the H band level and largely discontinuous longitudinally because of interruptions in the structure at the I and Z band levels. The structure of the system relates it to the endoplasmic reticulum of other cell types. The precise morphological relation of the reticulum to the myofibrils, with specializations opposite the different bands, prompts the supposition that the system is functionally important in muscle contraction. In this regard it is proposed that the membrane limiting the system is polarized like the sarcolemma and that the corresponding potential difference is utilized in the intracellular distribution of the excitatory impulse.     

Effects of tumor promoters and diacylglycerol on the transdifferentiation of striated muscle cells of the medusa Podocoryne carnea to RF-amide positive nerve cells

Artemia sp (Tuticorin strain) was cultured at a density of 250 individuals 1^–1 at 35, 45, 60, 75 salinity using five combinations of groundnut oil cake, decayed cabbage leaves, single superphosphate and Baker's yeast as feed. Effects on survival, growth, and fecundity were noted.     

Calmidazolium, a calmodulin antagonist, stimulates calcium-troponin C and calcium-calmodulin-dependent activation of striated muscle myofilaments

Although regulatory Ca2+-binding domains of calmodulin (CaM) and troponin C (TnC) are similar, it is interesting that agents that act as CaM antagonists appear to be TnC "agonists" in that they sensitize cardiac myofilaments to activation by Ca2+ (El-Saleh, S., and Solaro, R. J. (1987) Biophys. J. 51, 325 (abstr.). This indicates that the effects of agents that react with Ca2+-binding proteins may depend on protein-protein interactions involved in a particular Ca2+-dependent process. In experiments described here, we have explored this idea by testing effects of calmidazolium (CDZ), a potent calmodulin antagonist on striated muscle myofilaments regulated by cardiac TnC, skeletal TnC, and CaM. CDZ was shown to increase submaximal calcium activation of myofilament force and ATPase activity in both cardiac and skeletal muscle, but the effect was greater in the case of the cardiac preparations. In the presence of 10 microM CDZ, the free Ca2+ giving half-maximal activation was reduced to about 60% of the control value in the case of cardiac myofilaments. Analogous differential effects of CDZ were also seen in studies in which we measured direct effects of CDZ on Ca2+-dependent fluorescence changes of cardiac TnC and skeletal TnC labeled with probes reporting Ca2+ binding to the regulatory sites. Measurements were also done with myofibrillar preparations of psoas muscle in which the native skeletal TnC was removed and exchanged with cardiac TnC and CaM, both of which could substitute for skeletal TnC as a regulatory protein. CDZ was more effective in sensitizing Ca2+-dependent MgATPase activity of skeletal myofibrils containing CaM than in preparations containing the native TnC. However, CDZ was most effective in its Ca2+-sensitizing effect in the case of the preparations containing cardiac TnC. Our results indicate that effects of agents that bind to Ca2+-binding proteins depend not only on the particular variant, but also on the specific environment in which the Ca2+-binding proteins operate.     

Myomesin 3, a novel structural component of the M-band in striated muscle

The M-band is the cytoskeletal structure that cross-links the myosin and titin filaments in the middle of the sarcomere. Apart from the myosin tails and the C-termini of titin, only two closely related structural proteins had been detected at the M-band so far, myomesin and M-protein. However, electron microscopy studies revealed structural features that do not correlate with the expression of these two proteins, indicating the presence of unknown constituents in the M-band.Using comparative sequence analysis, we have identified a third member of this gene family, myomesin 3, and characterised its biological properties. Myomesin 3 is predicted to consist of a unique head domain followed by a conserved sequence of either fibronectin- or immunoglobulin-like domains, similarly to myomesin 3 and M-protein. While all three members of the myomesin family are localised to the M-band of the sarcomere, each member shows its specific expression pattern. In contrast to myomesin, which is ubiquitously expressed in all striated muscles, and M-protein, whose expression is restricted to adult heart and fast-twitch skeletal muscle, myomesin 3 can be detected mainly in intermediate speed fibers of skeletal muscle. In analogy to myomesin, myomesin 3 targets to the M-band region of the sarcomere via its N-terminal part and forms homodimers via its C-terminal domain. However, despite the high degree of homology, no heterodimer between distinct members of the myomesin gene family can be detected. We propose that each member of the myomesin family is a component of one of the distinct ultrastructures, the M-lines, which modulate the mechanical properties of the M-bands in different muscle types.     

Histochemical and ultrastructural characteristics of a new muscle fibre type in avian striated muscle

Synopsis The serratus metapatagialis (SMP) muscle of the pigeon has been studied histochemically and ultrastructurally. At the gross anatomical level the SMP is clearly divisible into a peripheral whitish band and a red portion comprised predominantly of pale and red fibres respectively. The pale fibres possess low succinate dehydrogenase, low mitochondrial content, absence of subsarcolemmal mitochondrial aggregates, low fat, moderate glycogen, high phosphorylase, low-to-moderate regular myofibrillar adenosine triphosphatase (M-ATPase), activation of M-ATPase following acid preincubation and jagged Z bands. On the basis of these characteristics, these physiologically slow muscle fibres have been termed Type I white or slow-twitch glycolytic. The SMP red fibres, however, possess high aerobic as well as glycolytic capacity, high M-ATPase activity which is labile after acid preincubation and thick but straight Z bands; therefore, they are the Type II red or fast-twitch oxidative-glycolytic.Some of data in this paper was presented at the Anatomical Society of Australia and New Zealand, 1978.     

epsilon-sarcoglycan replaces alpha-sarcoglycan in smooth muscle to form a unique dystrophin-glycoprotein complex.

The sarcoglycan complex has been well characterized in striated muscle, and defects in its components are associated with muscular dystrophy and cardiomyopathy. Here, we have characterized the smooth muscle sarcoglycan complex. By examination of embryonic muscle lineages and biochemical fractionation studies, we demonstrated that epsilon-sarcoglycan is an integral component of the smooth muscle sarcoglycan complex along with beta- and delta-sarcoglycan. Analysis of genetically defined animal models for muscular dystrophy supported this conclusion. The delta-sarcoglycan-deficient cardiomyopathic hamster and mice deficient in both dystrophin and utrophin showed loss of the smooth muscle sarcoglycan complex, whereas the complex was unaffected in alpha-sarcoglycan null mice in agreement with the finding that alpha-sarcoglycan is not expressed in smooth muscle cells. In the cardiomyopathic hamster, the smooth muscle sarcoglycan complex, containing epsilon-sarcoglycan, was fully restored following intramuscular injection of recombinant delta-sarcoglycan adenovirus. Together, these results demonstrate a tissue-dependent variation in the sarcoglycan complex and show that epsilon-sarcoglycan replaces alpha-sarcoglycan as an integral component of the smooth muscle dystrophin-glycoprotein complex. Our results also suggest a molecular basis for possible differential smooth muscle dysfunction in sarcoglycan-deficient patients.     

A theory of contraction and a mathematical model of striated muscle

A theory of contraction and an associated model of striated muscle are presented, based on the assumption that chemical energy is being converted into electrical energy which, in turn, is being converted into mechanical energy and heat.The model, set up for the frog sartorius muscle, is able to predict the “rowing” motion of the cross-bridges, the force-velocity relation, the tension-length curve, the isometric force, all energy rates (heat and work rates), the metabolic rates and all known features of the stretched, stimulated muscle (no ATP-splitting, stretching tension higher than isometric tension, etc.). It also offers an alternative explanation for Hill's thermoelastic effect. The significance of Hill's force-velocity equation in the context of this theory is also discussed in detail.     

Decorin and a large dermatan sulfate proteoglycan in bovine striated muscle

Proteoglycans were extracted and isolated from adult bovine muscle tissue by dissociative extraction followed by density gradient centrifugation, gel chromatography and ion-exchange chromatography. Two proteoglycans were characterized; one of large molecular size (PG-L) and one of small molecular size (PG-S). The recovery of PG-L and PG-S was 33% and 67% respectively. By cellulose acetate electrophoresis before and after treatment with chondroitinase AC and ABC both samples were shown to carry predominantly dermatan sulfate chains. The large proteoglycan was recognized with an antibody against a large dermatan sulfate proteoglycan from bovine sclera, whereas the small was recognized by an antibody against decorin from bovine sclera. Chondroitinase ABC treatment of PG-S followed by SDS-PAGe showed a core protein with a molecular weight of 45 kDa, which also reacted with the decorin antibody. Amino-acid analysis of both PG-L and PG-S revealed an amino-acid composition closely similar, although not identical, to the large dermatan sulfate proteoglycan from bovine sclera and decorin respectively. Immunohistochemical analyses of muscle tissue sections showed that decorin and the large dermatan sulfate proteoglycan are present in the perimysium layers of muscle tissue, although with a somewhat different pattern of distribution. Decorin was, in addition, found in the endomysium.