Nerve-dependent recovery of metabolic pathways in regenerating soleus muscles

SummaryThe metabolic recovery potential of muscle was studied in regenerating soleus muscles of young adult rats. Degeneration was induced by subfascial injection of a myotoxic snake venom. After regeneration for selected periods up to 2 weeks, samples of whole muscle were analysed for hexokinase (EC 2.7.1.1), phosphofructokinase (EC 2.7.1.11), lactate dehydrogenase (EC 1.1.11.27), adenylokinase (EC 2.7.4.3), creatine kinase (EC 2.7.3.2), malate dehydrogenase (EC 1.1.11.37), citrate synthase (ED 4.1.3.7) and β-hydroxyacyl CoA dehydrogenase (EC 1.1.1.35). Lactate dehydrogenase, adenylokinase, malate dehydrogenase and β-hydroxyacyl CoA dehydrogenase were also measured in individual fibres of muscle regenerating up to 4 weeks. We found that in the presence of nerve there was complete recovery of muscle metabolic capacity. However, there were differences in the rate of recovery of the activity of enzymes belonging to different energy-generating pathways. Lactate dehydrogenase, an enzyme representing glycolytic metabolism, reached normal activity immediately upon myofibre formation, only 3 days after venom injection, while oxidative enzymes required a week or more to reach normal activity levels. The delay in oxidative enzyme recovery coincided with physiological parameters of reinnervation. Therefore, to further test the role of nerve on the metabolic recovery process, muscle regeneration was studied following venom-induced degeneration coupled with denervation. In the absence of innervation, most enzymes failed to recover to normal activity levels. Lactate dehydrogenase was the only enzyme to achieve normal levels, and it did so as rapidly as in innervated-regenerating soleus muscles. The remainder of the glycotytic enzymes and the high energy phosphate enzymes recovered only partially. Oxidative enzymes showed no recovery and were severely reduced in the absence of reinnervation. Thus, it appears that enzymes of oxidative metabolism are more dependent upon innervation than enzymes of glycolytic metabolism for full expression in regenerating soleus muscle.

[1]  M. Cullen,et al.  The effect of denervation on the morphology of regenerating rat soleus muscles , 2004, Acta Neuropathologica.

[2]  Gerta Vrbová,et al.  Changes of activity patterns in slow and fast muscles during postnatal development , 1983 .

[3]  E. Widdowson,et al.  Chemical changes in skeletal muscle during development. , 1960, The Biochemical journal.

[4]  E. Coyle,et al.  Effects of detraining on enzymes of energy metabolism in individual human muscle fibers. , 1983, The American journal of physiology.

[5]  T. Mansour,et al.  Changes in phosphofructokinase isozymes during development of myoblasts to myotubes. , 1990, Archives of biochemistry and biophysics.

[6]  G. Butler-Browne,et al.  Three myosin heavy-chain isozymes appear sequentially in rat muscle development , 1981, Nature.

[7]  G. Vrbóva,et al.  Differentiation of slow and fast muscles in chickens , 1977, Cell and Tissue Research.

[8]  G. Butler-Browne,et al.  Expression of myosin isoforms during notexin-induced regeneration of rat soleus muscles. , 1990, Developmental biology.

[9]  G. Vrbóva,et al.  Effects of long-term electrical stimulation on some contractile and metabolic characteristics of fast rabbit muscles , 1973, Pflügers Archiv.

[10]  D. Ford,et al.  Changes in weight and volume of rat spinal cord motor neurons with increasing age. , 1968, Acta Anatomica.

[11]  B. Nyström FIBRE DIAMETER INCREASE IN NERVES TO “SLOW‐RED” AND “FAST‐WHITE” CAT MUSCLES DURING POSTNATAL DEVELOPMENT , 1968, Acta neurologica Scandinavica.

[12]  M. Brooke,et al.  THREE "MYOSIN ADENOSINE TRIPHOSPHATASE" SYSTEMS: THE NATURE OF THEIR pH LABILITY AND SULFHYDRYL DEPENDENCE , 1970, The journal of histochemistry and cytochemistry : official journal of the Histochemistry Society.

[13]  W. Kraus,et al.  Mitochondrial biogenesis in striated muscles: rapid induction of citrate synthase mRNA by nerve stimulation. , 1991, The American journal of physiology.

[14]  A. Kelly,et al.  Metabolic specialization in fast and slow muscle fibers of the developing rat , 1989, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[15]  N. Mizuno,et al.  Postnatal differentiation of cell body volumes of spinal motoneurons innervating slow‐twitch and fast‐twitch muscles , 1977, The Journal of comparative neurology.

[16]  Margaret A. Johnson,et al.  Pathological responses of rat skeletal muscle to a single subcutaneous injection of a toxin isolated from the venom of the Australian tiger snake, Notechis scutatus scutatus , 1975 .

[17]  S Salmons,et al.  The adaptive response of skeletal muscle to increased use , 1981, Muscle & nerve.

[18]  J. Harris,et al.  FURTHER OBSERVATIONS ON THE PATHOLOGICAL RESPONSES OF RAT SKELETAL MUSCLE TO TOXINS ISOLATED FROM THE VENOM OF THE AUSTRALIAN TIGER SNAKE, NOTECHIS SCUTATUS SCUTATUS , 1978, Clinical and experimental pharmacology & physiology.

[19]  H. Reichmann,et al.  Biochemical and ultrastructural changes of skeletal muscle mitochondria after chronic electrical stimulation in rabbits , 1985, Pflügers Archiv.

[20]  Oliver H. Lowry,et al.  Enzymatic Analysis: A Practical Guide , 1993 .

[21]  D. Pette,et al.  Influence of intermittent long-term stimulation on contractile, histochemical and metabolic properties of fibre populations in fast and slow rabbit muscles , 1975, Pflügers Archiv.

[22]  R. Reinking,et al.  Uniformity of metabolic enzymes within individual motor units , 1986, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[23]  O. H. Lowry,et al.  Effect of microgravity on metabolic enzymes of individual muscle fibers , 1990, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[24]  Stanley Salmons,et al.  The reorganization of subcellular structure in muscle undergoing fast-to-slow type transformation , 1981, Cell and Tissue Research.

[25]  O. H. Lowry,et al.  Enzyme patterns in single human muscle fibers. , 1978, The Journal of biological chemistry.

[26]  J. Simoneau,et al.  Species-specific effects of chronic nerve stimulation upon tibialis anterior muscle in mouse, rat, guinea pig, and rabbit , 1988, Pflügers Archiv.

[27]  S. Salmons,et al.  Restoration of fast muscle characteristics following cessation of chronic stimulation , 1984, Cell and Tissue Research.

[28]  C. Catani,et al.  Myosin light and heavy chains in muscle regenerating in absence of the nerve: Transient appearance of the embryonic light chain , 1983, Experimental Neurology.

[29]  G. Maréchal,et al.  Isozymes of myosin in growing and regenerating rat muscles. , 1984, European journal of biochemistry.

[30]  O. H. Lowry,et al.  Chronic stimulation of mammalian muscle: enzyme changes in individual fibers. , 1986, The American journal of physiology.

[31]  F. E. Weber,et al.  Contractile activity enhances the synthesis of hexokinase II in rat skeletal muscle , 1988, FEBS letters.

[32]  G. S. Sohal,et al.  Role of innervation on the embryonic development of skeletal muscle , 2004, Cell and Tissue Research.

[33]  O. H. Lowry,et al.  Chronic stimulation of mammalian muscle: changes in enzymes of six metabolic pathways. , 1986, The American journal of physiology.

[34]  J. Westerga,et al.  Changes in the electromyogram of two major hindlimb muscles during locomotor development in the rat , 2004, Experimental Brain Research.

[35]  B. Kirschbaum,et al.  Neural control of gene expression in skeletal muscle. Effects of chronic stimulation on lactate dehydrogenase isoenzymes and citrate synthase. , 1986, The Biochemical journal.

[36]  A Brunetti,et al.  Role of myogenin in myoblast differentiation and its regulation by fibroblast growth factor. , 1990, The Journal of biological chemistry.

[37]  F. Jolesz,et al.  Development, innervation, and activity-pattern induced changes in skeletal muscle. , 1981, Annual review of physiology.

[38]  O. H. Lowry,et al.  Enzyme levels in individual rat muscle fibers. , 1980, The American journal of physiology.

[39]  S. Schiaffino,et al.  Metabolic and contractile protein expression in developing rat diaphragm muscle , 1991, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[40]  R. Reinking,et al.  Association between biochemical and physiological properties in single motor units , 1988, Muscle & nerve.

[41]  A. Minty,et al.  Sequential accumulation of mRNAs encoding different myosin heavy chain isoforms during skeletal muscle development in vivo detected with a recombinant plasmid identified as coding for an adult fast myosin heavy chain from mouse skeletal muscle. , 1983, Journal of Biological Chemistry.

[42]  G. Butler-Browne,et al.  Denervation of newborn rat muscles does not block the appearance of adult fast myosin heavy chain , 1982, Nature.