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.     

Evidence that the actin site is impaired by Ca2+-activated degradation of the heavy chain of dystrophic myosin

At pathophysiological concentrations of Ca²⁺, the heavy chain of dystrophic myosin was degraded by an endogenous protease. This was not the case for normal myosin. However, normal myosin was a substrate of Ca²⁺-activated neutral protease (CAF) from platelets. This indicated that the endogenous protease in preps of dystrophic myosin was CAF. The pathophysiological effect of heavy chain degradation was restricted to the actin site. Under Vmax conditions hydrolytic activities remained within the normal range, whereas the Kapp of actin for myosin increased 3-fold following extensive heavy chain degradation of dystrophic myosin. Removal of those heavy chain fragments which were soluble at low inoic strength restored Kapp to normal levels.     

Easily releasable myofilaments from skeletal and cardiac muscles maintained in vitro. Role in myofibrillar assembly and turnover

Gentle treatment with an ATP-containing relaxing solution of isolated myofibrils from rat diaphragm, soleus, extensor digitorum longus, and left atria maintained in vitro releases a small amount of myofilaments constituting less than 5% of total myofibrillar protein. Successive extraction of myofibrils produced little further filament release. Releasable myofilaments lack alpha-actinin (Mr = 95,000), certain very high molecular weight proteins (greater than 200,000), and possibly M-line protein but contain other myofibrillar proteins. After pulse-labeling with [3H]leucine for 8 min, specific activity of the myosin heavy chain in the easily releasable myofilaments is 3-6 times higher than the specific activity of myosin heavy chain in the residual myofibrils, although 85-90% of total label is in the myofibrillar myosin. In the absence of protein synthesis, releasable filament specific activity decreases, with a half-time of 60-90 min, to that of the myofibrillar myosin. This labeling pattern appears inconsistent with a simple precursor-product relationship between releasable filaments and myofibrils suggesting that the filaments originate largely from myofibrils. Preincubation of muscles with several factors known to decrease proteolysis, i.e. passive stretch, leupeptin, colchicine, and cycloheximide, reduced the size of the releasable filament fraction. Treatment of muscles with the calcium ionophore A23187, which accelerates proteolysis, and pretreatment of myofibrils with either trypsin or calcium-dependent protease increased filament release. Therefore, the releasable filament fraction may contain intermediates in the breakdown of myofibrils. The labeling kinetics may indicate a mixing of myofilaments within myofibrils which functions in the movement of contractile protein to its possible site of degradation, i.e. the myofibrillar surface.     

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.     

Leucine pools in normal and dystrophic chicken skeletal muscle cells in culture

The specific radioactivity of [3H]Leu in the extracellular, intracellular, and Leu-tRNA pools of normal (white leghorn) and dystrophic (line 307) embryonic chick breast muscle cultures was analyzed as a function of equilibration time and extracellular Leu concentration (0.05-5 mM). The primary results were the following 1) [3H]Leu equilibrated to a constant specific radioactivity in the intracellular and Leu-tRNA pools within 2 min after addition to both normal and dystrophic cultures. 2) After equilibration, the extracellular [3H] Leu specific radioactivity in dystrophic cell culture medium was lower than that of medium exposed to normal cells (especially at low Leu concentrations), probably because of increased release of unlabeled Leu from the dystrophic cells as a result of faster protein breakdown. Accordingly, the specific radioactivities in the intracellular and the Leu-tRNA pools were also lower in dystrophic cells. 3) At 5 mM extracellular Leu, the specific radioactivity in the Leu-tRNA pool was approximately 40% lower than the specific radioactivity in the intracellular pool in both normal and dystrophic cells. Thus, high concentrations of extracellular Leu cannot be used to "flood out" reutilization of unlabeled Leu (released by protein degradation) during protein synthesis. 4) At 5.0 mM extracellular Leu, the specific radioactivity of [3H]Leu in the intracellular pool was comparable to that in the extracellular pool in normal and dystrophic cells; however, the specific radioactivity of Leu-tRNA (i.e. the immediate precursor to protein synthesis) was only 55-65% of the extracellular specific radioactivity in normal and dystrophic cells. In conclusion, reutilization of Leu from protein degradation is higher in dystrophic muscle cell cultures than in normal muscle cell cultures, and accurate rates of protein synthesis in cell cultures can only be obtained if specific radioactivity of amino acid in tRNA is measured.     

Regulation of myofibrillar accumulation in chick muscle cultures: evidence for the involvement of calcium and lysosomes in non-uniform turnover of contractile proteins

The effect of calcium on myofibrillar turnover in primary chick leg skeletal muscle cultures was examined. Addition of the calcium ionophore A23187 at subcontraction threshold levels (0.38 microM) increased significantly rates of efflux of preloaded 45Ca+2 but had no effect on total protein accumulation. However, A23187 as well as ionomycin caused decreased accumulation of the myofibrillar proteins, myosin heavy chain (MHC), myosin light chain 1f (LC1f), 2f (LC2f), alpha-actin (Ac), and tropomyosin (TM). A23187 increased the degradation rate of LC1f, LC2f, and TM after 24 h. In contrast, the calcium ionophore caused decreased degradation of Ac and troponin-C and had no effect on the degradation of MHC, troponin-T, troponin-I, or alpha, beta-desmin (Dm). In addition, A23187 did not alter degradation of total myotube protein. The ionophore had little or no effect on the synthesis of total myotube proteins, but caused a marked decrease in the synthesis of MHC, LC1f, LC2f, Ac, TM, and Dm after 48 h. The mechanisms involved in calcium-stimulated degradation of the myofibrillar proteins were also investigated. Increased proteolysis appeared to involve a lysosomal pathway, since the effect of the Ca++ ionophore could be blocked by the protease inhibitor leupeptin and the lysosomotropic agents methylamine and chloroquine. The effects of A23187 occur in the presence of serum, a condition in which no lysosomal component of overall protein degradation is detected. The differential effect of A23187 on the degradative rates of the myofibrillar proteins suggests a dynamic structure for the contractile apparatus.     

Degradation of myofibrillar proteins by a calpain-like proteinase in the arm muscle of Octopus vulgaris

The effects of a calpain-like proteinase (CaDP) isolated from the arm muscle of Octopus vulgaris on the myofibrils and myofibrillar proteins isolated from the same tissue were examined. Our studies clearly showed that treatment of intact myofibrils with CaDP in the presence of 5 mM Ca²⁺ results in the degradation of the major myofibrillar proteins myosin, paramyosin, and actin. From the isolated α- and β-paramyosins only β-paramyosin is degraded by CaDP in the presence of 5 mM Ca²⁺ producing three groups of polypeptides of 80, 75, and 60 kDa, respectively. The degradation rate depends on the proteinase to substrate ratio, temperature, and time of proteolysis and is inhibited by the endogenous CaDP inhibitory factor (CIF), as well as by various known cysteine proteinase inhibitors (E-64, leupeptin, and antipain). From the other myofibrillar proteins examined myosin, but not actin, is degraded by CaDP; myosin heavy chain (MHC, 200 kDa) is degraded by CaDP producing four groups of polypeptides of lower molecular masses (155, 125, 115, and 102 kDa, respectively); the degradation rate depends on the incubation time and the proteinase to substrate ratio. Furthermore, CaDP undergoes limited autolysis in the presence of both the exogenous casein and the endogenous β-paramyosin producing two large active fragments of 52 and 50.6 kDa, respectively; CIF reversibly inhibits this CaDP autolysis. Accepted: 26 May 2000     

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.     

Coordinate synthesis of two myosins in wild-type and mutant nematode muscle during larval development

In this paper we examine the role of two myosins in body-wall muscle cells of the nematode Caenorhabditis elegans. Large populations of nematodes are synchronized, and the synthesis and accumulation of myosin heavy chains and total protein are followed through postmitotic larval development. Growth is exponential with time for both the wild-type N2 and the body-wall muscledefective mutant E675, with a longer doubling time for the mutant. Utilizing the electrophoretic polymorphism of the E675 myosin heavy chains, we show that distinguishable classes of heavy chains accumulate differentially throughout development. Immunochemical measurements confirm a similar result in N2. Total myosin heavy chain accumulation is also quantitatively similar for the two strains. Myosin heavy chain relative synthetic rates as determined by pulse-labeling are constant throughout development and are equivalent for the two strains. The final fraction of accumulated unc-54 to total heavy chains of approximately 0.63 equals the constant synthetic fraction of approximately 0.62.Since myosin heavy chain accumulation and relative synthesis are equivalent, we conclude that the turnover of heavy chains is also similar in N2 and E675 despite the extensive structural and functional disruption within body-wall muscle cells of the latter strain. Since the accumulated fraction of unc-54 myosin heavy chains reaches a plateau at the constant synthetic fraction, myosin accumulation In the body-wall muscle cells may be attributed to a constant ratio of synthetic rates of the two body-wall myosin species. The coordinate synthesis of two myosins in the same body-wall muscle cells is discussed.     

Myofibrillar protein degradation in the chicken. 3-Methylhistidine release in vivo and in vitro in normal and genetically muscular-dystrophic chickens

Myofibrillar protein degradation was measured in 4-week-old normal (line 412) and genetically muscular-dystrophic (line 413) New Hampshire chickens by monitoring the rates of 3-methylhistidine excretion in vivo and in vitro. A method of perfusing breast and wing muscles was developed and the rate of 3-methylhistidine release in vitro was measured between 30 and 90min of perfusion. During this perfusion period, 3-methylhistidine release from the muscle preparation was linear, indicating that changes in 3-methylhistidine concentration of the perfusate were the result of myofibrillar protein degradation. Furthermore, the viability of the perfused muscle was maintained during this interval. After 60min of perfusion, ATP, ADP and creatine phosphate concentrations in pectoral muscle were similar to muscle freeze-clamped in vivo. Rates of glucose uptake and lactate production were constant during the perfusion. In dystrophic-muscle preparations, the rate of 3-methylhistidine release in vitro (nmol/h per g of dried muscle) was elevated 2-fold when compared with that in normal muscle. From these data the fractional degradation rates of myofibrillar protein in normal and dystrophic pectoral muscle were calculated to be 12 and 24% respectively. Daily 3-methylhistidine excretion (nmol/day per g body wt.) in vivo was elevated 1.35-fold in dystrophic chickens. Additional studies revealed that the anti-dystrophic drugs diphenylhydantoin and methylsergide, which improve righting ability of dystrophic chickens, did not alter 3-methylhistidine release in vitro. This result implies that changes in myofibrillar protein turnover are not the primary lesion in avian muscular dystrophy. From tissue amino acid analysis, the myofibrillar 3-methylhistidine content per g dry weight of muscle was similar in normal and dystrophic pectoral muscle. More than 96% of the 3-methylhistidine present in pectoral muscle was associated with the myofibrillar fraction. Dystrophic myofibrillar protein contained significantly less 3-methylhistidine (nmol/g of myofibrillar protein) than protein from normal muscle. This observation supports the hypothesis that there may be a block in the biochemical maturation and development of dystrophic muscle after hatching. Free 3-methylhistidine (nmol/g wet wt.) was elevated in dystrophic muscle, whereas blood 3-methylhistidine concentrations were similar in both lines. In summary, the increased myofibrillar protein catabolism demonstrated in dystrophic pectoral muscle correlates with the increased lysosomal cathepsin activity in this tissue as reported by others.     

Action of two alkaline proteases and a trypsin inhibitor from white croaker skeletal muscle (Micropogon opercularis) in the degradation of myofibrillar proteins

The action of two alkaline proteases from white skeletal muscle on myofibrillar proteins is shown. Purified myosin was readily degraded by both proteases, but only protease I was able to degrade myosin heavy chain from actomyosin. The effect of inhibitor on both proteases was also studied. The activity of protease II on azocasein was not affected, while the action of protease I on both azocasein and myosin was inhibited. The implication of proteases and inhibitor on the turnover of myofibrillar proteins is considered.     

Effects of chymostatin and other proteinase inhibitors on protein breakdown and proteolytic activities in muscle

To learn more about the enzymes involved in protein catabolism in skeletal and cardiac muscle and to identify selective inhibitors of this process, we studied the effects of proteinase inhibitors on protein turnover in isolated muscles and on proteolytic activities in muscle homogenates. Chymostatin (20μm) decreased protein breakdown by 20–40% in leg muscles from normal rodents and also in denervated and dystrophic muscles. These results are similar to our previous findings with leupeptin. The related inhibitors pepstatin, bestatin, and elastatinal did not decrease protein breakdown; antipain slowed this process in rat hind-limb muscles but not in diaphragm. Chymostatin did not decrease protein synthesis and thus probably retards proteolysis by a specific effect on cell proteinase(s). In homogenates of rat muscle, chymostatin, in common with leupeptin and antipain, inhibits the lysosomal proteinase cathepsin B, and the soluble Ca²⁺-activated proteinase. In addition, chymostatin, but not leupeptin, inhibits the chymotrypsin-like proteinase apparent in muscle homogenates. In muscles depleted of most of this activity by treatment with the mast-cell-degranulating agent 48/80, chymostatin still decreased protein breakdown. Therefore inhibition of this alkaline activity probably does not account for the decrease in protein breakdown. These results are consistent with a lysosomal site of action for chymostatin. Because of its lack of toxicity, chymostatin may be useful in maintaining tissues in vitro and perhaps in decreasing muscle atrophy in vivo.     

Catheptic and Trypsin-inhibiting Activities in the Nutritional Muscular Dystrophy

From 50 days on, after vitamin E deficient diet was given to guinea pigs, typical symptoms of muscular dystrophy were observed. Muscle protein of these animals was fractionated into 3 fractions, sarcoplasmic fraction, Triton X–100 soluble fraction and myofibrillar fraction.

Free catheptic activity (hemoglobin-splitting activity in the sarcoplasmic fraction), bound catheptic activity (the same in the Triton X–100 soluble fraction) and trypsin-inhibiting activity (in the sarcoplasm fraction) were determined in normal and dystrophic muscles.

In dystrophic muscles, great increase in free and bound catheptic activities was observed.

The increase of free catheptic activity was greater than that of bound catheptic activity.

Trypsin-inhibiting activity was also increased in dystrophic muscles two- or three-fold. At the same time, decrease in the content of myofibrillar protein in dystrophic muscles was observed.

These results were discussed in view of the degradation of protein in dystrophic muscles.     

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.     

Evidence for myosin heterogeneity inDrosophila melanogaster

Summary Electrophoresis of myosin extracts from larvae and adult tissues ofDrosophila melanogaster under non-dissociating conditions indicate that two of the bands seen are myosins. They stain for Ca²⁺ ATPase activity and when cut and re-run under dissociating conditions are found to contain a myosin heavy chain that co-migrates with rabbit skeletal muscle myosin heavy chain. One of the forms of myosin seen is found primarily in extracts from the leg. The other is common to the adult fibrillar flight muscles and the larval body wall muscles.The electrophoretic evidence for two myosin types is strengthened by the histochemical demonstration of two myofibrillar ATPases on the basis of their lability to acid or alkali preincubation. The myofibrillar ATPase in the leg and the Tergal Depressor of the Trochanter (TDT) are shown to be relatively acid labile and alkali stable. The larval body wall muscles and the adult fibrillar flight muscles have an ATPase which is acid stable and alkali labile. This distribution of the two myofibrillar ATPase coincides with that predicted by electrophoresis of extracts from whole tissue and also locates the two myosins to specific muscle types.     

Degradation of smooth-muscle myosin by trypsin-like serine proteinases.

1. Hydrolysis of the myosins from smooth and from skeletal muscle by a rat trypsin-like serine proteinase and by bovine trypsin at pH 7 is compared. 2. Proteolysis of the heavy chains of both myosins by the rat enzyme proceeds at rates approx. 20 times faster than those obtained with bovine trypsin. Whereas cleavage of skeletal-muscle myosin heavy chain by both enzymes results in the generation of conventional products i.e. heavy meromyosin and light meromyosin, the heavy chain of smooth-muscle myosin is degraded into a fragment of mol. wt. 150000. This is dissimilar from heavy meromyosin and cannot be converted into heavy meromyosin. It is shown that proteolysis of the heavy chain takes place in the head region. 3. The 'regulatory' light chain (20kDa) of smooth-muscle myosin is degraded very rapidly by the rat proteinase. 4. The ability of smooth-muscle myosin to have its ATPase activity activated by actin in the presence of a crude tropomyosin fraction on introduction of Ca2+ is diminished progressively during exposure to the rat proteinase. The rate of loss of the Ca2+-activated actomyosin ATPase activity is very similar to the rate observed for proteolysis of the heavy chain and 3-4 times slower than the rate of removal of the so-called 'regulatory' light chain. 5. The significance of these findings in terms of the functional organization of the smooth muscle myosin molecule is discussed. 6. Since the degraded myosin obtained after exposure to very small amounts of the rat proteinase is no longer able to respond to Ca2+, i.e. the functional activity of the molecule has been removed, the implications of a similar type of proteolysis operating in vivo are considered for myofibrillar protein turnover in general, but particularly with regard to the initiation of myosin degradation, which is known to take place outside the lysosome (i.e. at neutral pH).     

Differential turnover of axonally transported glycoproteins

Metabolic turnover of axonally transported glycoproteins has been examined in membranous and soluble subfractions of goldfish optic tectum following intraocular injection of [³H]fucose. Radioactivity in total transported glycoproteins reached a maximum in the tectum after 24–30 hr, then declined with a half-life of approximately 20 days. Radioactivity in the total membranous subfraction declined with a similar half-life of 20–21 days while radioactivity in the soluble fraction showed a significantly shorter half-life of approximately seven days. Various sized glycopeptides derived from the membranous subfraction showed differential rates of loss of radioactivity with the lower molecular weight nondialyzable molecules displaying the most rapid turnover. In contrast, the glycopeptides derived from the soluble fraction showed relatively uniform rates of turnover. The results are discussed in the context of metabolic compartmentalization between membranous and soluble glycoproteins and among the carbohydrate chains of the membranous molecules.Supported by NIH grant NS 11456.     

Living macrophages phosphorylate the 20,000 dalton light chains and heavy chains of myosin

Brief incubation of rabbit alveolar macrophages in medium containing ³²Pi results in the incorporation of radioactivity into the 20 KD light chains and into the 220 KD heavy chains of myosin. Phosphorylation of the heavy chain is mediated by a kinase that is probably not myosin light chain kinase. Limited proteolysis of the phosphorylated myosin shows that radioactivity is associated with the rod portion of the heavy chain.     

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