Content and synthesis of several abundant glycolytic enzymes in skeletal muscles of normal and dystrophic mice

• 1.1. In both 2- and 3-month-old 129 ReJ mice, the catalytic activity levels of three enzymes involved in glycogen breakdown (phosphorylase, enolase, and aldolase) were found to be 35–50% lower in hind limb muscles of dystrophic mice as compared with normal mice.
• 2.2. The reduced activities of these enzymes in the diseased tissue was directly due to corresponcling reductions in the number of enzyme molecules rather than being due to inactivation of the enzymes in the dystrophic muscle.
• 3.3. Results of short term double isotope incorporation experiments conducted with muscle expiants in vitro suggested that the rates of synthesis of these enzymes, and of most other abundant cytosolic proteins, relative to each other, were similar in hind limb muscles of normal and dystrophic mice.
• 4.4. The present work on murine muscular dystrophy is discussed in terms of our previous studies into the influence of avian muscular dystrophy on the content and synthesis of abundant glycolytic enzymes in chicken skeletal muscles.

     

Synthesis of apolipoprotein A1 in skeletal muscles of normal and dystrophic chickens

We recently observed that, around the time of hatching, chick skeletal muscles synthesize and secrete apolipoprotein A1 (apo-A1) at high rates and that reinitiation of synthesis of this serum protein to high levels occurs in mature chicken breast muscle following surgical denervation (Shackelford, J. E., and Lebherz, H. G. (1983) J. Biol. Chem. 258, 7175-7180; 14829-14833). In the present work we investigate the effect of avian muscular dystrophy on the synthesis of apo-A1 in chicken muscles. The relative rate of synthesis of apo-A1 and levels of apo-A1 RNA in mature dystrophic breast (fast-twitch) muscle were about 6-fold higher than normal, while synthesis of apo-A1 in breast muscles derived from 2-day-old dystrophic chicks was close to normal. These observations suggest that the elevated apo-A1 synthetic rate in mature dystrophic breast muscle results from a failure of the diseased tissue to "shut down" apo-A1 synthesis to the normal level during postembryonic maturation. Apo-A1 synthesis in the "slow-twitch" lateral adductor muscle of dystrophic chickens was found to be normal. Our work is discussed in terms of the apparent similarities between the effects of surgical denervation and muscular dystrophy on the protein synthetic programs expressed by chicken skeletal muscles.     

Protein synthesis in muscles from normal and dystrophic hamsters.

Homogenates of hindleg muscle were obtained from control and dystrophic male hamsters, 30 and 190 days of age, and were used to prepare the postmicrosomal pH5-supernatant fraction. The activity of this fraction in the incorporation of [14C]phenylalanyl-tRNA into peptides was increased in the dystrophic-muscle preparations. No such increase was found in brain or liver preparations from dystrophic hamsters. The increased capacity for aminoacyl-tRNA binding that was observed in preparations from dystrophic animals is discussed.     

The levels of creatine kinase and adenylate kinase in the plasma of dystrophic chickens reflect the rates of loss of these enzymes from the circulation

The rates of loss of adenylate kinase and creatine kinase from the circulation after intravenous injection of homogenous chicken skeletal muscle enzymes were examined to determine the role of plasma clearance rates in determining the plasma levels of these enzymes in normal and dystrophic chickens. The rapid clearance of adenylate kinase activity (average half-life of 5 min) and the slower biphasic clearance of creatine kinase activity (average half-lives of 0.95 and 11 hr) are consistent with the elevation of creatine kinase but not adenylate kinase in the blood plasma of dystrophic chickens compared to normal chickens. The rates of clearance of these enzymes were similar in normal chickens compared to dystrophic chickens. Radioiodinated enzymes were cleared at similar, but slightly more rapid rates than the loss of enzyme activity. The loss of adenylate kinase activity from the circulation may be due in part to inactivation since adenylate kinase activity is rapidly inactivated in serum in vitro, and because no increase in adenylate kinase activity is observed in the most specific sites of clearance of the radioiodinated enzyme, the liver and spleen. The comparison of enzyme activities in press juices to the activities in high-ionic-strength homogenates of muscle tissue from normal and dystrophic muscle, indicates that adenylate kinase activity is not associated with intracellular structures to the extent that would prohibit release from dystrophic muscle tissue. These results, and those presented previously with regard to plasma levels and clearance rates of AMP aminohydrolase and pyruvate kinase in normal and dystrophic chickens (11) support our hypothesis that the rates of loss of muscle enzyme activities from the circulation are important in determining the circulating levels of muscle enzymes in dystrophic chickens. Furthermore, from the measurement of plasma levels and clearance rates of creatine kinase, it was estimated that the efflux rate of creatine kinase from dystrophic muscle tissue is 2.0% of the total breast muscle creatine kinase per day.     

Myosin isoforms in normal and dystrophic chickens

The myosin isoform content in the affected fibers of chickens with inherited muscular dystrophy has been investigated with a new high-performance liquid chromatographic procedure for separation of the tryptic fragments of myosin subfragment 1 (S-1). The results indicate that dystrophic muscle contains substantial amounts of normal adult myosin, together with various myosin species present in normal 5-day posthatch chickens. Confirmation was obtained by comparative peptide mapping of the S-1 tryptic fragments and by N-terminal sequencing of 20-kDa species. Together with data on other contractile proteins and certain metabolic enzymes [Obinata, T., Takano-Ohmura, H., & Matsuda, R. (1980) FEBS Lett. 120, 195-198; Mikasa, T., Takeda, S., Shimizu, T., & Kitaura, T. (1981) J. Biochem. (Tokyo) 89, 1951-1962; Feit, H., & Domke, R. (1982) Cell Motil. 2, 309-315; Cosmos, E. (1966) Dev. Biol. 13, 163-181; Cosmos, E., & Butler, J. (1967) in Exploratory Concepts in Muscular Dystrophy and Related Disorders (Milhorat, A. R., Ed.) pp 197-204, Excerpta Medica, Amsterdam], the results are consistent with the hypothesis that there is a general defect in muscle maturation in avian dystrophy.     

Regulation of concentrations of glycolytic enzymes and creatine-phosphate kinase in “fast-twitch” and “slow-twitch” skeletal muscles of the chicken

The distinctive contractile and metabolic characteristics of different skeletal muscle fiber types are associated with different protein populations in these cells. In the present work, we investigate the regulation of concentrations of three glycolytic enzymes (aldolase, enolase, glyceraldehyde-3-phosphate dehydrogenase) and creatine-phosphate kinase in “fast-twitch” (breast) and “slow-twitch” (lateral adductor) muscles of the chicken. Results of short-term amino acid incorporation experiments conducted both in vivo and with muscle explants in vitro showed that these enzymes turnover at different rates and that aldolase turns over 2 to 3 times faster than the other three enzymes. However, these differences in turnover rates were difficult to detect in long-term double-isotope incorporation experiments, presumably because extensive reutilization of labeled amino acids occurred during these long-term experiments. Mature muscle fibers synthesize these four cytosolic enzymes at very high rates. For example, 11 to 14% of the total labeled leucine incorporated into protein by breast muscle fibers was found in the enzyme aldolase. Results of short-term amino acid incorporation experiments also showed that the relative rates of synthesis of the three glycolytic enzymes were about fourfold higher in mature “fast-twitch” muscle fibers than in mature “slow-twitch” ones while the relative rates of synthesis of creatine-phosphate kinase were similar in the two fiber types. The relative rates of synthesis of these four enzymes and cytosolic proteins in general were found to be very similar in immature muscles of both types. More profound changes in the relative rates of synthesis of major cytosolic proteins, including the glycolytic enzymes, occurred during postembryonic maturation of fast-twitch fibers than occurred during maturation of slow-twitch fibers. Our work demonstrates that (1) the synthesis of creatine-phosphate is independently regulated with respect to the synthesis of the glycolytic enzymes in muscle fibers; and (2) the approximate fourfold higher steady-state concentrations of glycolytic enzymes in fast-twitch muscle fibers as compared with slow-twitch fibers are determined predominantly by regulatory mechanisms operating at the level of protein synthesis rather than protein degradation. Our demonstration that more profound changes in the relative rates of synthesis of major cytosolic proteins occur during maturation of fast-twitch fibers as compared with slow-twitch fibers is discussed in terms of the mode(s) of fiber-type differentiation proposed by others.     

Acetylcholinesterase and butyrylcholinesterase released from normal and dystrophic muscles by treatment with proteolytic enzymes

1. Skeletal muscle from C57BL dystrophic mice demonstrated decreased activities of acetylcholinesterase with increased activities of butyrylcholinesterase. These changes were less distinct when compared to those observed with 129 ReJ mice. 2. Collagenase or trypsin treatment solubilized less acetylcholinesterase activity but more butyrylcholinesterase activity from muscle of C57BL dystrophic mice than from muscle of control mice. 3. These treatments resulted in similar pattern of release of acetylcholinesterase activity from muscle of 129 ReJ mice, except that more acetylcholinesterase activity was released from dystrophic muscle (129 ReJ) than from control by pepsin treatment. 4. The acetylcholinesterase activities released by proteolytic enzymes were characterized by sucrose density gradient centrifugation.     

Calpain and calpastatin levels in dystrophic hamster skeletal muscles

1. Two fast-twitch skeletal muscles from normal and dystrophic hamsters were analysed for their calpain and calpastatin contents. 2. Assays of wide-specificity calpain II showed that the activity levels in the two muscles were increased 1.5 and 1.6 times in dystrophic animals. 3. Analysis of calpastatin levels showed that the respective dystrophic muscles had activity levels of 2.2 and 2.8 times those of control muscles. 4. These results contrast with previous studies on denervated hamster muscles which showed that denervation causes an increase in calpain levels but a decrease in calpastatin levels.     

Collagenase-releasable and-resistant cholinesterases in normal and dystrophic muscles

The release of acetylcholinesterase activity by collagenase from the particulate fraction of mouse muscle homogenate into the soluble fraction was dependent on the time of incubation of muscle homogenate with collagenase. The collagenase-stimulated release of acetylcholinesterase was inhibited by 1,10-phenanthroline, an inhibitor of collagenase. Differential effects of inhibitors of specific acetylcholinesterase and nonspecific cholinesterase were observed in both collagenase extract and collagenase-resistant fraction derived from homogenate of muscle of normal and dystrophic mice. The collagenase extract of dystrophic muscle contained distinctly lower activity of acetylcholinesterase than that of normal muscle, while both collagenase extract and collagenase-resistant fraction of dystrophic muscle showed much higher activity of butyrylcholinesterase activity than those from normal muscle.     

Calcium-related defects in cardiac and skeletal muscles of dystrophic mice

Ca2+ ATPase and calcium binding proteins were studied in cardiac and skeletal muscles of normal and dystrophic mice. In normal and dystrophic mice, Ca2+ ATPase was quite reduced in cardiac muscle compared to skeletal muscle and was, unlike skeletal muscle, insensitive to orthovanadate. Ca2+ ATPase in skeletal muscle of dystrophic mice was reduced as compared to normal mice. In both cases (normal and dystrophic), calcium binding proteins were the same (identical molecular weight). The effect of 2 drugs (Polymixine B and Bepridil) which decrease protein bound calcium was studied: the muscle proteins of dystrophic mice did not present the same sensitivity to Bepridil as controls. These findings suggest the existence of a calcium-related defect in skeletal and cardiac muscle of dystrophic mice.