Summary
The postnatal development, between 0 and 90 days, of three hindlimb muscles and diaphragm of the rat was investigated with respect to fiber types and diameter (histochemistry) and substrate oxidation rates and enzyme activities (biochemistry). The process of muscle fiber differentiation into mature patterns was evaluated by visual classification into 3 or 4 groups having different staining intensities for 3 enzyme-histochemical reactions, enabling 26 fiber types to be distinguished. These exhibited specific sizes and growth rates that varied among the muscles. One of the hindleg muscles (flexor digitorum brevis) remained much more immature than soleus and extensor digitorum longus.
The histochemical and biochemical findings correlated well. The capacity for pyruvate and palmitate oxidation, and the activities of cytochrome c oxidase and citrate synthase, increased markedly between 9 and 37 days in soleus and extensor digitorum longus (except citrate synthase in the latter) but not in flexor digitorum brevis. Creatine kinase activity increased in all hindlimb muscles. Both the capacity and the activity of pyruvate oxidation (determined in homogenates and intact isolated muscles, respectively), were in accordance with the fiber type composition. In contrast to oxidation capacity, the activity of pyruvate oxidation decreased after birth until the mature stage, when a value of 18–42% of that of early postnatal muscles was recorded.
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References
Baldwin KM, Hooker AM, Campbell PJ, Lewis RE (1978a) Enzyme changes in neonatal skeletal muscle: effect of thyroid deficiency. Am J Physiol 235:C97-C102
Baldwin KM, Hooker AM, Herrick RE (1978b) Lactate oxidative capacity in different types of muscle. Biochem Biophys Res Commun 83:151–157
Betz WJ, Caldwell JH, Ribchester RR (1979) The size of motor units during post-natal development of rat lumbrical muscle. J Physiol 297:463–478
Brown MC, Jansen JKS, Van Essen D (1976) Polyneural innervation of skeletal muscle in new-born rats and its elimination during maturation. J Physiol 261:387–422
Burke RE, Levine DN, Zajac FE, Tsairis P, Engel WK (1971) Mammalian motor units: physiological-histochemical correlation in three types in cat gastrocnemius. Science 174:709–712
Close RI (1972) Dynamic properties of mammalian skeletal muscles. Physiol Rev 52:129–197
Curless RG, Nelson MB (1976) Developmental patterns of rat muscle histochemistry. J Embryol Exp Morphol 36:355–363
Davies AS, Gunn HM (1972) Histochemical fibre types in the mammalian diaphragm. J Anat 112:41–60
Dubowitz V (1965) Enzyme histochemistry of skeletal muscle. Part I. Developing animal muscle. J Neurol Neurosurg Psychiat 28:516–524
Dubowitz V, Brooke MH (1973) Muscle biopsy, a modern approach. Sounders, London, p 32
Edgerton VR, Smith LA, Eldred E, Cope TC, Mendell LM (1980) Muscle and motor unit properties of exercised and non-exercised chronic spinal cats. In: Pette D (ed) Plasticity of muscle. Walter de Gruyter, Berlin New York, pp 355–371
Essén B, Jansson E, Henriksson J, Taylor AW, Saltin B (1975) Metabolic characteristics of fibre types in human skeletal muscle. Acta Physiol Scand 95:153–165
Evans OB (1983) Muscle pyruvate oxidation following denervation and reinnervation. Muscle Nerve 6:557–560
Glatz JFC, Veerkamp JH (1982) Postnatal development of palmitate oxidation and mitochondrial enzyme activities in rat cardiac and skeletal muscle. Biochim Biophys Acta 711:327–335
Goldspink G (1972) Postembryonic growth and differentiation of striated muscle. In: Bourne GH (ed) The structure and function of muscle. Academic Press, New York, 2nd ed, pp 179–236
Goodman MN, Dluz SM, McElaney MA, Belur E, Ruderman NB (1983) Glucose uptake and insulin sensitivity in rat muscle: changes during 3–96 weeks of age. Am J Physiol 244:E93-E100
Gottschall J (1981) The diaphragm of the rat and its innervation. Muscle fiber composition; Perikarya and axons of efferent and afferent neurons. Anat Embryol 161:405–417
Haltia M, Berlin Ö, Schucht H, Sourander P (1978) Postnatal differentiation and growth of skeletal muscle fibres in normal and undernourished rats. A histochemical and morphometric study. J Neurol Sci 36:25–39
Heilig A, Pette D (1980) Changes induced in the enzyme activity pattern by electrical stimulation of fast-twitch muscle. In: Pette D (ed) Plasticity of muscle. Walter de Gruyter, Berlin New York, pp 409–420
Hintz CS, Lowry CV, Kaiser KK, McKee D, Lowry OH (1980) Enzyme levels in individual rat muscle fibers. Am J Physiol 239:C58-C65
Ho KW, Heusner WW, Van Huss J, Van Huss WD (1983) Postnatal muscle fibre histochemistry in the rat. J Embryol Exp Morphol 76:37–49
Hoh JFY, Kwan BTS, Dunlow C, Kim BH (1980) Effects of nerve cross-union and cordotomy on myosin isoenzymes in fast-twitch and slow-twitch muscles of the rat. In: Pette D (ed) Plasticity of muscle. Walter de Gruyter, Berlin New York, pp 339–352
Hommes FA, Wilmink CW (1968) Developmental changes of glycolytic enzymes in rat brain, liver and skeletal muscle. Biol Neonate 12:181–193
Hooker AM, Baldwin KM (1979) Substrate oxidation specificity in different types of mammalian muscle. Am J Physiol 236:C66-C69
Hudlicka O, Tyler KR, Aitman T (1980) The effect of long-term electrical stimulation on fuel uptake and performance in fast skeletal muscles. In: Pette D (ed) Plasticity of muscle. Walter de Gruyter, Berlin New York, pp 401–408
Imura M, Takatani O (1983) Change of skeletal muscle pyruvate dehydrogenase complex activities in congenital diabetic mice (KK mice) by aging or contraction. Horm Metabol Res 15:373–377
Kelly AM, Rubinstein NA (1980) Why are fetal muscles slow? Nature 288:266–269
Kloosterboer HJ, Stoker-De Vries SA, Hulstaert CE, Hommes FA (1979) Quantitative analysis of morphological changes in skeletal muscle of the rat after hormone administration. Biol Neonate 35:106–112
Kugelberg E (1976) Adaptive transformation of rat soleus motor units during growth. J Neurol Sci 27:269–289
Kugelberg E, Lindegren B (1979) Transmission and contraction fatigue of rat motor units in relation to succinic dehydrogenase activity of motor unit fibers. J Physiol 288:285–300
Lojda Z, Gossrau R, Schiebler TH (1979) Enzyme histochemistry, a laboratory manual. Springer, Berlin Heidelberg New York, p 235
Lømo T, Westgaard RH, Engebretsen L (1980) Different stimulation patterns affect contractile properties of denervated rat soleus muscles. In: Pette D (ed) Plasticity of muscle. Walter de Gruyter, Berlin New York, pp 297–308
Lowry OH (1984) The heterogeneity of muscle. Carlsberg Res Commun 49:309–314
Lowry OH, Rosebrough NJ, Farr AL, Randall RJ (1951) Protein measurement with the Folin phenol reagent. J Biol Chem 193:265–275
Lowry CV, Kimmey JS, Felder S, Chi MM-Y, Kaiser KK, Passonneau PN, Kirk KA, Lowry OH (1978) Enzyme patterns in single human muscle fibers. J Biol Chem 253:8269–8277
Lubek BM, Mainwood GW (1983) Lactate and pyruvate production in isolated thiamine-deficient rat diaphragm strips. Can J Physiol Pharmacol 62:277–281
Lyons GE, Haselgrove J, Kelly AM, Rubinstein NA (1983) Myosin transitions in developing fast and slow muscles of the rat hindlimb. Differentiation 25:168–175
Meijer AEFH, De Vries GP (1978) Enzyme histochemical studies on the Purkinje fibers of the atrioventricular system of bovine and porcine hearts. Histochem J 10:399–408
Nachlas MM, Tsou KC, De Souza E, Cheng CS, Seligman AM (1957) Cytochemical demonstration of succinic dehydrogenase by the use of a new p-nitrophenyl substituted ditetrazole. J Histochem Cytochem 5:420–436
Nemeth P, Pette D (1980a) The interrelationship of two systems of fiber classification in rat EDL muscle. J Histochem Cytochem 28:193
Nemeth P, Pette D (1980b) The limited correlation of myosin-based and metabolism-based classifications of skeletal muscle fibers. J Histochem Cytochem 29:89–90
Nemeth P, Hofer HW, Pette D (1979) Metabolic heterogeneity of muscle-fibers classified by myosin ATPase. Histochemistry 63:191–201
Novák E, Drummond GI, Skála J, Hahn P (1972) Developmental changes in cyclic AMP, protein kinase, phosphorylase kinase, and phosphorylase in liver, heart, and skeletal muscle of the rat. Arch Biochem Biophys 150:511–518
Park JHY, Musgrave KO, Ahn PC, Hegarty PVJ (1981) Electrolyte concentration in different muscles during growth in the rat. Comp Biochem Physiol 69A:161–164
Peter JB, Barnard RJ, Edgerton VR, Gillespie CA, Stempel KE (1972) Metabolic profiles of three fiber types of skeletal muscle in guinea pigs and rabbits. Biochemistry 11:2627–2633
Pette D, Spamer C (1979) Metabolic subpopulations of muscle fibres; a quantitative study. Diabetes 28:25–29
Peuhkurinen KJ, Hassinen IE (1982) Pyruvate carboxylation as an anaplerotic mechanism in the isolated perfused rat heart. Biochem J 202:67–76
Rakusan K, Raman S, Layberry R, Korecky B (1978) The influence of ageing and growth on the postnatal development of cardiac muscle in rats. Circ Res 42:212–218
Salmons S (1980) The response of skeletal muscle to different patterns of use — some new developments and concepts. In: Pette D (ed) Plasticity of muscle. Walter de Gruyter, Berlin New York, pp 387–399
Schadewaldt P, Münch U, Prengel M, Staib W (1983) Estimation of pyruvate decarboxylation in perfused rat skeletal muscle. Biochem Biophys Res Commun 116:456–461
Shepherd D, Garland PB (1969) Citrate synthase from rat liver. Meth Enzymol 13:11–13
Spamer C, Pette D (1977) Activity patterns of phosphofructokinase, glyceraldehydephosphate dehydrogenase, lactate dehydrogenase and malate dehydrogenase in microdissected fast and slow fibres from rabbit psoas and soleus muscle. Histochemistry 52:201–216
Spamer C, Pette D (1979) Activities of malate dehydrogenase, 3-hydroxyacyl-CoA dehydrogenase and fructose-1,6-diphosphatase with regard to metabolic subpopopulations of fast- and slow-twitch fibres in rabbit muscles. Histochemistry 60:9–19
Spurway NC (1980a) Histochemical typing of muscle fibres by microphotometry. In: Pette D (ed) Plasticity of muscle. Walter de Gruyter, Berlin New York, pp 31–44
Spurway NC (1980b) Quantitative histochemistry of some rabbit muscles. J Physiol 305:43P-44P
Spurway N (1981) Interrelationship between myosin-based and metabolism-based classifications of skeletal muscle fibers. J Histochem Cytochem 29:87–90
Timson BF (1982) The effect of varying postnatal growth rate on skeletal muscle fiber number in the mouse. Growth 46:36–45
Van Hinsbergh VWM, Veerkamp JH, Van Moerkerk HTB (1978) Palmitate oxidation by rat skeletal muscle mitochondria. Comparison of polarographic and radiochemical experiments. Arch Biochem Biophys 190:762–771
Villa-Moruzzi E, Locci-Cubeddu T, Bergamini E (1979) Developmental changes of glycogen enzymes in fast and slow muscles of the rat. Growth 43:73–79
Wattenberg LW, Leong JL (1960) Effects of coenzyme Q-10 and menadione on succinic dehydrogenase activity as measured by tetrazolium salt reduction. J Histochem Cytochem 8:296–303
Whalen RG (1980) Contractile protein isozymes in muscle development: the embryonic phenotype. In: Pette D (ed) Plasticity of muscle. Walter de Gruyter, Berlin New York, pp 177–191
Wirtz P, Loermans HMT, Peer PGM, Reintjes AGM (1983a) Postnatal growth and differentiation of muscle fibres in the mouse. I. A histochemical and morphometrical investigation of normal muscle. J Anat 137:109–126
Wirtz P, Loermans HMT, Peer PGM, Reintjes AGM (1983b) Postnatal growth and differentiation of muscle fibres in the mouse. II. A histochemical and morphometrical investigation of dystrophic muscle. J Anat 137:127–142
Zuurveld JGEM, Veerkamp JH (1984) Palmitate oxidation in suspended skeletal muscle fibers from the rat. Biochim Biophys Acta 796:34–41
Zuurveld JGEM, Wirtz P, Veerkamp JH (1984) Skeletal muscle fibers in suspension: a new approach to the study of oxidative and glycolytic metabolism in differentiated muscle. Int J Biochem 16:1107–1114
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Zuurveld, J.G.E.M., Wirtz, P., Loermans, H.M.T. et al. Postnatal growth and differentiation in three hindlimb muscles of the rat. Cell Tissue Res. 241, 183–192 (1985). https://doi.org/10.1007/BF00214640
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DOI: https://doi.org/10.1007/BF00214640