Disproportionate reduction of actin synthesis in hearts of starved rats

We examined the synthesis of proteins in rat myocardium after starvation. Rates of total protein synthesis in myofibrillar and nonmyofibrillar fractions of myocardium of starved animals were reduced similarly (to 70-80% of the rates in hearts of fed animals, p less than 0.002), but rates of synthesis of some individual proteins were affected discoordinately. Radiolabeled proteins from atrial and ventricular explants, separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, revealed that starvation for 2 days reduced the rate of cardiac actin synthesis to 26-38% of control levels, while the rate of myosin heavy chain synthesis in the same hearts was only moderately reduced (74-80% of control levels). This starvation-induced reduction in actin synthesis could be accounted for at least in part by disproportionately decreased levels of actin mRNA in starved hearts, as revealed by Northern blot hybridization and by in vitro translation analysis. The dramatic decrease in cardiac actin synthesis was rapidly reversible, and actin synthesis returned to normal after a single day of refeeding. The selective reduction of actin synthesis after starvation was specific for the heart: rates of myosin heavy chain and actin synthesis in skeletal muscles (soleus and extensor digitorum longus) were coordinately reduced in response to starvation. To our knowledge, this is the first example of such dramatic discoordinate regulation of myofibrillar protein synthesis in response to a physiological stimulus.     

Eyestalk ablation has little effect on actin and myosin heavy chain gene expression in adult lobster skeletal muscles

The organization of skeletal muscles in decapod crustaceans is significantly altered during molting and development. Prior to molting, the claw muscles atrophy dramatically, facilitating their removal from the base of the claw. During development, lobster claw muscles exhibit fiber switching over several molt cycles. Such processes may be influenced by the secretion of steroid molting hormones, known collectively as ecdysteroids. To assay the effects of these hormones, we used eyestalk ablation to trigger an elevation of circulating ecdysteroids and then quantified myofibrillar mRNA levels with real-time PCR and myofibrillar protein levels by SDS-PAGE. Levels of myosin heavy chain (MHC) and actin proteins and the mRNA encoding them were largely unaffected by eyestalk ablation, but in muscles from intact animals, myofibrillar gene expression was modestly elevated in premolt and postmolt animals. In contrast, polyubiquitin mRNA was significantly elevated (about 2-fold) in claw muscles from eyestalk-ablated animals with elevated circulating ecdysteroids. Moreover, patterns of MHC and actin gene expression are significantly different among slow and fast claw muscles. Consistent with these patterns, the three muscle types differed in the relative amounts of myosin heavy chain and actin proteins. All three muscles also co-expressed fast and slow myosin isoforms, even in fibers that are generally regarded as exclusively fast or slow. These results are consistent with other recent data demonstrating co-expression of myosin isoforms in lobster muscles.     

Sepsis stimulates release of myofilaments in skeletal muscle by a calcium-dependent mechanism.

Sepsis is associated with a pronounced catabolic response in skeletal muscle, mainly reflecting degradation of the myofibrillar proteins actin and myosin. Recent studies suggest that sepsis-induced muscle proteolysis may reflect ubiquitin-proteasome-dependent protein breakdown. An apparently conflicting observation is that the ubiquitin-proteasome pathway does not degrade intact myofibrils. Thus, it is possible that actin and myosin need to be released from the myofibrils before they can be ubiquitinated and degraded by the proteasome. We tested the hypothesis that sepsis results in disruption of Z-bands, increased expression of calpains, and calcium-dependent release of myofilaments in skeletal muscle. Sepsis induced in rats by cecal ligation and puncture resulted in increased gene expression of micro-calpain, m-calpain, and p94 and in Z-band disintegration in the extensor digitorum longus muscle. The release of myofilaments from myofibrillar proteins was increased in septic muscle. This response to sepsis was blocked by treating the rats with dantrolene, a substance that inhibits the release of calcium from intracellular stores to the cytoplasm. The present results provide evidence that sepsis is associated with Z-band disintegration and a calcium-dependent release of myofilaments in skeletal muscle. Release of myofilaments may be an initial and perhaps rate-limiting component of sepsis-induced muscle breakdown.     

Regulation of muscle gene expression: The accumulation of messenger RNAs coding for muscle-specific proteins during myogenesis in a mouse cell line

The expression of RNA sequences coding for myofibrillar proteins has been followed during terminal differentiation in a mouse skeletal muscle cell line. Cloned complementary DNA probes hybridizing with the actins, skeletal muscle α-actin, myosin heavy chain and the myosin alkali light chains were employed in Northern blotting experiments with total cellular poly (A)-containing RNA extracted from the cultures at different times after plating. At the same times, parallel cultures were pulse-labelled with [³⁵S]methionine and the pattern of newly synthesized proteins was analysed by two-dimensional gel electrophoresis. Synthesis of skeletal muscle α-actin and of the myosin alkali light chains (LC_lemb, LC₁, LC₃) was not detectable in dividing myoblast cultures. From the onset of cell fusion, the synthesis of myosin heavy chain, LC_lemb and α-actin increases with similar kinetics. Synthesis of LC₃ (and trace amounts of LC_1F) is detectable and subsequently increases at later stages of myotube formation. The corresponding messenger RNAs coding for myosin heavy chain and skeletal muscle α-actin are first detectable immediately before the initiation of myofibrillar protein synthesis. mRNAs coding for the non-muscle actins are accumulated in myoblasts and diminish after cell fusion. Comparisons between muscle mRNAs depend on the relative sensitivities of the different probes, reflecting mainly their homology with the isoform of the actin or myosin multigene family expressed. Quantitative analysis of Northern blots gives an estimated increase in skeletal muscle α-actin mRNA, with an homologous probe, of at least 130-fold with a minimum level of detection of 40 to 80 molecules per cell. Accumulation of this species and of the myosin heavy chain mRNA follows similar kinetics. mRNA coding for LC₃, the principal myosin light chain detected with the probe, appears to accumulate to a lesser extent initially, paralleling synthesis of the corresponding protein. These results using cloned probes demonstrate a close temporal correlation between muscle mRNA accumulation and protein synthesis during terminal myogenesis in this muscle line.     

Mode of action of rabbit skeletal muscle cathepsin B towards myofibrillar proteins and the myofibrillar structure.

1. The mode of degradation of myofibrillar proteins and the structural changes in myofibrils due to the action of cathepsin B highly purified from rabbit skeletal muscle were studied. 2. Cathepsin B degraded myosin heavy chain, actin and troponin T, but not alpha-actinin, tropomyosin, troponin I or troponin C among myofibrillar proteins. 3. Cathepsin B optimally degraded myosin heavy chain, actin and troponin T at around pH 5. Degradation of myosin heavy chain produced 6 fragments, 180,000, 150,000, 87,000, 81,000, 75,000 and 69,000 Da, respectively. Actin was hydrolyzed into fragments of 41,000, 38,000 and 30,000 Da. Troponin T was degraded into fragments of 21,000, 12,000 and 10,000 Da. 4. Cathepsin B caused the fragmentation of myofibrils and disturbance of the lateral arrangement of myofibrils. 5. Cathepsin B partly disintegrated the Z-line and the M-line, and induced disordering of the arrangement of filaments in the I-band.     

Effect of chronic excess of tumour necrosis factor-alpha on contractile proteins in rat skeletal muscle

The effect of chronic tumour necrosis factor-alpha (TNF-alpha) treatment on the synthesis of specific myofibrillar proteins such as heavy chain myosin, light chain myosin and G-actin in rat diaphragm were evaluated. Muscles (diaphragm) from control and experimental groups (TNF-alpha i.v. at 50 microg/kg body wt for 5 days) were incubated in the presence of 35S-methionine for 2 h. Myofibrillar protein extracts were prepared and protein was electrophoresed on sodium dodecyl sulphate-polyacrylamide gels. Heavy chain myosin, light chain myosin and G-actin were identified by Western blot analysis using specific monoclonal antibodies. Polyacrylamide gel electrophoresis (PAGE) followed by Western blot analysis revealed two types of heavy chain myosin (206 and 212 kD), all four types of light chain myosin (15, 16.5, 18 and 20 kD) and a single type of G-actin (42 kD). Chronic TNF-alpha treatment produced a significant decline in the synthesis of all types of myofibrillar proteins, namely heavy chain myosin, light chain myosin and G-actin. TNF-alpha impaired peptide-chain initiation in diaphragm muscle which was reversed by the branched-chain amino acids (BCAA) therapy of TNF-alpha treated rats. These findings indicate a significant role for TNF-alpha in the translational regulation of protein synthesis in skeletal muscle.     

Molt cycle-associated changes in calcium-dependent proteinase activity that degrades actin and myosin in crustacean muscle

The role of calcium-dependent proteinase (CDP) in the proecdysial atrophy of crustacean claw muscle has been investigated. During atrophy the molar ratio of actin to myosin heavy chain decreased 31%, confirming earlier ultrastructural observations that the ratio of thin:thick myofilaments declined from 9:1 to 6:1 (D. L. Mykles and D. M. Skinner, 1981, J. Ultrastruct. Res., 75, 314–325). The release of TCA-soluble material in muscle homogenates at neutral pH was stimulated by Ca²⁺ and completely inhibited by EGTA. The specific degradation of the major myofibrillar proteins (actin, myosin heavy and light chains, paramyosin, tropomyosin, troponin-T, and troponin-I) was demonstrated by SDS-polyacrylamide gel electrophoresis. Proteolytic activity was more than twofold greater in proecdysial muscle homogenates. Degradation of myofibrillar proteins was inhibited by EGTA, and the two inhibitors of cysteine proteinases, leupeptin and antipain, but not pepstatin, an inhibitor of aspartic proteinases. Unlike CDPs from vertebrate muscle, the CDP(s) in crab claw muscle degrades actin and myosin in addition to other myofibrillar proteins.     

Effect of glucocorticoids on the turnover rate of actin and myosin heavy and light chains on different types of skeletal muscle fibres

The catabolic action of glucocorticoids on the molecular level of the two main muscular proteins, myosin and actin, was found to depend on the type of muscle fibres. The synthesis rate of actin and myosin heavy chain was decreased in all types of muscle fibres, and in myosin light chain only in the slow-twitch red fibres. The turnover rate of actin and myosin heavy chain was also found decreased in all types of muscle fibres. The myosin light chains turned over more rapidly in dexamethasone-treated than in the control rats in all types of muscle fibres except in the case of the slow-twitch red ones as was shown by single and double isotope methods. Dexamethasone treatment enhanced the urinary 3-methylhistidine excretion in rats by 60%.     

Atrophy responses to muscle inactivity. I. Cellular markers of protein deficits.

The goal of this study was to use the model of spinal cord isolation (SI), which blocks nearly all neuromuscular activity while leaving the motoneuron muscle-fiber connections intact, to characterize the cellular processes linked to marked muscle atrophy. Rats randomly assigned to normal control and SI groups were studied at 0, 2, 4, 8, and 15 days after SI surgery. The slow soleus muscle atrophied by approximately 50%, with the greatest degree of loss occurring during the first 8 days. Throughout the SI duration, muscle protein concentration was maintained at the control level, whereas myofibrillar protein concentration steadily decreased between 4 and 15 days of SI, and this was associated with a 50% decrease in myosin heavy chain (MHC) normalized to total protein. Actin relative to the total protein was maintained at the control level. Marked reductions occurred in total RNA and DNA content and in total MHC and actin mRNA expressed relative to 18S ribosomal RNA. These findings suggest that two key factors contributing to the muscle atrophy in the SI model are 1). a reduction in ribosomal RNA that is consistent with a reduction in protein translational capacity, and 2). insufficient mRNA substrate for translating key sarcomeric proteins comprising the myofibril fraction, such as MHC and actin. In addition, the marked selective depletion of MHC protein in the muscles of SI rats suggests that this protein is more vulnerable to inactivity than actin protein. This selective MHC loss could be a major contributor for the previously reported loss in the functional integrity of SI muscles. Collectively, these data are consistent with the involvement of pretranslational and translational processes in muscle atrophy due to SI.     

Identification of a myofibril-bound serine protease and its endogenous inhibitor in mouse skeletal muscle

Myofibrillar proteins, like all other intracellular proteins, are in a dynamic state of continual degradation and resynthesis. The proteolytic system responsible for degrading myofibrillar proteins in skeletal muscle is not well defined. A proteolytic activity associated to myofibrils was found in mouse skeletal muscle, as show electrophoretic patterns, and denominated by us, as protease M. During incubation of whole myofibrils at 37 degrees C, myosin heavy chain, alpha actinin, actin and troponin T suffered degradation. These effects were inhibited selectively by serine protease inhibitors (soybean trypsin inhibitor, di-isopropyl phosphofluoridate, phenylmethanesulfonyl fluoride). Using myofibrils as protease M source, azocaseinolytic activity was also detected. Endogenous inhibitor and various compounds effects on protease M activity were also quantified by trichloroacetic acid soluble products formation, using radiolabeled myofibrils. An endogenous trypsin inhibitor isolated from the muscle cytoplasmic fraction could inhibit protease M activity on myofibrillar proteins and on azocasein. While K(+) increased protease M activity, the presence of Ca(2+) did not show any effect. Data presented in this study suggest that reported protease M may be implicated in myofibrillar degradation in vivo and isolated endogenous inhibitor may provide a mechanism to control its action in mouse skeletal muscle.     

Inhibition of contraction of cultured muscle fibers results in increased turnover of myofibrillar proteins but not of intermediate- filament proteins

Muscle fibers are maintained in culture in a fully contractile state and are relaxed by the addition of 10(-7) M tetrodotoxin (TTX). This toxin binds to muscle membrane Na+- channels, abolishes spontaneous contractions and causes failure of the fiber to accumulate myosin heavy chains. These effects are reversible on removal of TTX. Synthesis and accumulation kinetics have been obtained for myofibrillar and for cytoplasmic filament proteins in normal, active muscle and in TTX- relaxed muscle fibers in culture. In relaxed fibers the synthesis of most proteins remained normal or slightly elevated. However, the accumulation of all myofibrillar proteins examined was markedly inhibited in TTX-treated cultures, whereas the accumulation of cytoplasmic filament proteins was normal or slightly elevated. Myofibrillar proteins examined were alpha-actin, troponin-C, myosin fast light chain 1, myosin fast light chain 2, alpha, beta-tropomyosins and the phosphorylated forms of tropomyosin and fast light chain 2. Cytoplasmic filament proteins studied were vimentin, alpha, beta-desmin and beta, alpha-actin. We also examined the synthesis and accumulation of six unidentified muscle-specific proteins and nine unidentified nonmuscle-specific proteins. Most of these proteins showed a normal accumulation pattern in TTX-relaxed fibers. We concluded that muscle fibers made inactive by TTX display an increased instability of all myofibrillar proteins while cytoplasmic filament proteins and cytoplasmic proteins in general are relatively unaffected. We suggest that TTX interferes, in a manner as yet unidentified, with assembly and normal stability of myofibrils. Decreased assembly and/or increased instability of myofibrils would lead to increased rates of myofibrillar protein degradation.     

Dietary protein levels affect growth and protein metabolism in trunk muscle of cod,Gadus morhua

Summary Cod (Gadus morhua) of 50 g body weight were kept at 14°C. The fish were fed ad libitum during 80 days a diet containing protein levels which in terms of total energy corresponded to 25%, 45% or 65%. Growth increased in accordance with protein-energy levels. The protein content per gram of wet weight of white trunk muscle was unchanged, as was the myofibrillar protein myosin heavy chain determined by the antigen-antibody reaction of the enzyme-linked immunosorbent assay. The amount of messenger ribonucleic acid (mRNA) coding for myosin heavy chain was lower at 25% than at 45% or 65% protein-energy intake, the differences being significant per gram of wet weight of muscle. Acid proteinase activity was highest at the lowest protein-energy intake. Glycogen content in muscle increased with the protein-energy levels. It is concluded that the metabolic response of white trunk muscle to graded protein-energy intake included a change in the capacity to synthesize myosin heavy chain as judged by its mRNA content. The protein content per gram of wet weight was unaffected by dietary protein-energy levels of 25%, 45% and 65%, but protein accretion and thus growth of the animals increased with the protein intake. Dietary protein-energy restriction caused a rise in acid proteinase activity and a decrease in content of mRNA for myosin heavy chain, resulting in a diminished growth rate at an unchanged protein content per gram of wet weight of muscle.Abbreviations CTP cytidine triphosphate - DNA desoxyribonucleic acid - EDTA ethylenediaminetetra-acetic acid - mRNA messenger ribonucleic acid - TRIS tris(hydroxymethyl)aminomethane     

Heterogeneity of myofibrillar proteins in lobster fast and slow muscles: variants of troponin, paramyosin, and myosin light chains comprise four distinct protein assemblages

Fast and slow muscles from the claws and abdomen of the American lobster Homarus americanus were examined for adenosine triphosphatase (ATPase) activity and for differences in myofibrillar proteins. Both myosin and actomyosin ATPase were correlated with fiber composition and contractile speed. Four distinct patterns of myofibrillar proteins observed in sodium dodecyl sulfate-polyacrylamide gels were distinguished by different assemblages of regulatory and contractile protein variants. A total of three species of troponin-T, five species of troponin-I, and three species of troponin-C were observed. Lobster myosins contained two groups of light chains (LC), termed "alpha" and "beta." There were three alpha-LC variants and two beta-LC variants. There were no apparent differences in myosin heavy chain, actin, and tropomyosin. Only paramyosin showed a pattern completely consistent with muscle fiber type: slow fibers contained a species (105 kD) slightly smaller than the principle variant (110 kD) in fast fibers. It is proposed that the type of paramyosin present could provide a biochemical marker to identify the fiber composition of muscles that have not been fully characterized. The diversity of troponin and myosin LC variants suggests that subtle differences in physiological performance exist within the broader categories of fast- and slow-twitch muscles.     

The correlation between the synthesis of skeletal muscle actin,myosin heavy chain,and myosin light chain and the accumulation of corresponding mRNA sequences during myogenesis

Cloned cDNA probes were used to measure the accumulation of myosin heavy chain, myosin light chain 2, and actin mRNA during differentiation of rat skeletal muscle cell cultures. This was compared with the changes in the rate of synthesis of the corresponding proteins. Accumulation of those mRNA sequences was detectable a few hours before the onset of the phase of cell fusion; however, the main increase in hybridizable RNA occurred during the phase of rapid cell fusion. A close correlation was found between the amounts of mRNAs coding for these proteins and the rate of synthesis of the proteins. The results suggest that the activation of stored mRNA is not a major mechanism for controlling the time at which these proteins are synthesized.     

Role of regulatory proteins (troponin-tropomyosin) in pathologic states

In vertebrate striated muscle, troponon-tropomyosin is responsible, in part, not only for transducing the effect of calcium on contractile protein activation, but also for inhibiting actin and myosin interaction when calcium is absent. The regulatory troponin (Tn) complex displays several molecular and calcium binding variations in cardiac muscles of different species and undergoes genetic changes with development and in various pathologic states.Extensive reviews on the role of tropomyosin (Tm) and Tn in the regulation of striated muscle contraction have been published describing the molecular mechanisms involved in contractile protein regulation. In our studies, we have found an increase in Mg²⁺ ATPase activity in cardiac myofibrils from dystrophic hamsters and in rats with chronic coronary artery narrowing. The abnormalities in myofibrillar ATPase activity from cardiomyopathic hamsters were largely corrected by recombining the preparations with a TnTm, complex isolated from normal hamsters indicating that the TnTm, may play a major role in altered myocardial function. We have also observed down regulation of Ca²⁺ Mg²⁺ ATPase of myofibrils from hypertrophic guinea pig hearts, myocardial infarcted rats and diabetic-hypertensive rat hearts. In myosin from diabetic rats, this abnormality was substantially corrected by adding troponin-tropomyosin complex from control hearts. All of these disease models are associated with decreased ATPase activities of pure myosin and in the case of rat and hamster models, shifts of myosin, heavy chain from alpha to beta predominate.In summary, there are three main troponin subunit components which might alter myofibrillar function however, very few direct links of molecular alterations in the regulatory proteins to physiologic and pathologic function have been demonstrated so far.     

Direct Regulation of Striated Muscle Myosins by Nitric Oxide and Endogenous Nitrosothiols

Background

Nitric oxide (NO) has long been recognized to affect muscle contraction [1], both through activation of guanylyl cyclase and through modification of cysteines in proteins to yield S-nitrosothiols. While NO affects the contractile apparatus directly, the identities of the target myofibrillar proteins remain unknown. Here we report that nitrogen oxides directly regulate striated muscle myosins.

Principal Findings

Exposure of skeletal and cardiac myosins to physiological concentrations of nitrogen oxides, including the endogenous nitrosothiol S-nitroso-L-cysteine, reduced the velocity of actin filaments over myosin in a dose-dependent and oxygen-dependent manner, caused a doubling of force as measured in a laser trap transducer, and caused S-nitrosylation of cysteines in the myosin heavy chain. These biomechanical effects were not observed in response to S-nitroso-D-cysteine, demonstrating specificity for the naturally occurring isomer. Both myosin heavy chain isoforms in rats and cardiac myosin heavy chain from human were S-nitrosylated in vivo.

Significance

These data show that nitrosylation signaling acts as a molecular “gear shift” for myosin—an altogether novel mechanism by which striated muscle and cellular biomechanics may be regulated.     

Contents of myofibrillar proteins in cardiac, skeletal, and smooth muscles

The in situ contents of myosin, actin, alpha-actinin, tropomyosin, troponin, desmin were estimated in dog cardiac, rabbit skeletal, and chicken smooth muscles. Whole muscle tissues were dissolved with 8 M guanidine hydrochloride and subjected to two-dimensional gel electrophoresis, which is a nonequilibrium pH gradient electrophoresis (Murakami, U. & Uchida, K. (1984) J. Biochem. 95, 1577-1584) with some modification. The amount of protein in a spot on a slab gel was determined by quantification of the extracted dye. Dye binding capacity of individual myofibrillar proteins was determined by using the purified protein. Myosin contents were 82 +/- 7 pmol/mg wet weight in cardiac muscle, 105 +/- 10 pmol/mg wet weight in skeletal muscle, and 45 +/- 4 pmol/mg wet weight in smooth muscle. Actin contents were 339 +/- 15 pmol/mg wet weight in cardiac muscle, 625 +/- 27 pmol/mg wet weight in skeletal muscle, and 742 +/- 13 pmol/mg wet weight in smooth muscle. The subunit stoichiometry of myosin in the three types of muscles was two heavy chains and four light chains, and there was one light chain 2 for every heavy chain. The molar ratio of actin to tropomyosin was 7/1 in the three types of muscles. Striking differences were seen in the molar ratio of myosin to actin: 1.0/4.1 in cardiac muscle, 1.0/6.0 in skeletal muscle, and 1.0/16.5 in smooth muscle.     

Sinusoidal length oscillation- and receptor-mediated mRNA expression of myosin isoforms and alpha-SM actin in airway smooth muscle

We tested the hypothesis that sinusoidal length oscillation and receptor activation interactively regulate the abundance of mRNA encoding -smooth muscle (-SM) actin and myosin isoforms in intact bovine tracheal smooth muscle. We found that sinusoidal length oscillation significantly downregulated abundance of mRNA encoding -SM actin mRNA in unstimulated tissues but not in histamine- and carbachol-activated tissues. This observation suggests antagonistic interactions between mechanical stretch and receptor-mediated signal transduction in regulating the abundance of mRNA encoding -SM actin in intact airway smooth muscle. This pattern of antagonistic interaction was also observed in cholinergic receptor activation experiments. Whereas carbachol significantly upregulated myosin heavy chain SMA isoform expression in muscle strips held at slack length, carbachol did not significantly alter SMA expression in muscle strips at sinusoidal length oscillation. Carbachol also significantly upregulated GAPDH expression in bovine tracheal smooth muscle. However, unlike SMA expression, upregulation of GAPDH expression mediated by cholinergic receptor activation appeared to be insensitive to the mechanical state of airway smooth muscle. Unlike carbachol, histamine did not significantly alter the expression of GAPDH, myosin heavy chain SMA and SMB, myosin light chain LC17a and LC17b, and -SM actin in bovine tracheal smooth muscle. U0126 (10 µM) completely inhibited carbachol-induced ERK1/2 MAPK phosphorylation but did not significantly affect carbachol-induced upregulation of GAPDH and SMA expression, suggesting that the ERK1/2 MAPK pathway was not the underlying mechanism. A potential implication of these findings is that periodic stretching of airways during respiratory cycles may modulate mRNA expression by receptor agonists in airway smooth muscle cells in vivo. asthma; carbachol; deep inspiration; gene expression; histamine