Comparison of red and white muscle wet weight changed by age, denervation and morbid states

[Na]i, [K]i and wet weight of the extensor digitrum longus (EDL) and soleus (SOL) muscles of 9- and 52-week-old rats were measured for 7 days after sectioning of the sciatic nerve. The changes in wet weight of the EDL and SOL muscles of rats over 52 weeks and those of morbid state rats were also measured. There was no significant difference in wet weights between the EDL and SOL muscles in infant rats, but the EDL muscle became much heavier than the SOL muscle with aging. The decrease in rate of growth of wet weight of the EDL and SOL muscles caused by denervation, was greater in young rats than in mature rats. In addition, the rate of decrease was greater in the SOL muscles than in the EDL muscles in both young and mature rats. The [Na]i increased while [K]i was decreased by denervation, and the net Na+ increase and the net K+ loss were greater in young rats than in mature rats. The changing rate was more remarkable in the EDL muscles than in the SOL muscles throughout the aging process. During DOCA treatment over 4 weeks, the decrease of muscle wet weight was greater in the EDL muscles. The mechanisms which serve to maintain normal muscle wet weight in the SOL muscle after denervation or treatment with DOCA, were discussed.     

哺乳动物不活动化肌纤维的动作电位

用河豚毒素(TTX)慢性阻断大鼠坐骨神经的冲动传导,使后肢不活动,经过不同时间(最长7d)后离体观察了快肌伸趾长肌(EDL)和慢肌比目鱼肌(SOL)肌纤维终板区的诱发动作电位。我们发现在不活动期间动作电位超射和上升速率逐步下降,并从第4天起部分肌纤维能在含有1×10~(-7)g/ml TTX的溶液中被诱发产生动作电位(称抗TTX动作电位),待至第7天时全部SOL肌纤维和90％的EDL肌纤维都能被诱发出抗TTX动作电位。与去神经肌纤维相比,不仅抗TTX动作电位出现较晚,并且其超射和上升速率较低。在去掉TTX阻断使肌肉恢复活动后,动作电位超射和上升速率渐趋恢复,抗TTX动作电位逐渐消失。无论是动作电位的恢复还是抗TTX动作电位的消失,EDL肌纤维均快于SOL肌纤维。本文还讨论了不活动化使肌纤维动作电位变化以及快、慢肌差别的可能原因。     

Modification of motoneuron size after partial denervation in neonatal rats

Our previous studies have shown that partial denervation of extensor digitorum longus muscle (EDL) in the rat at 3 days of age causes an increase in the activity of the intact motoneurons. The originally phasic pattern of activity of EDL became tonic after partial denervation. These modifications of motoneuron activity were associated with the change in the phenotype of the muscle from fast to slow contracting and with a conversion of the muscle fibres from a fast to a slow type. The present study investigates whether the size of the cell body of the active EDL motoneurons change in parallel with the altered muscular activity. The study involved partial denervation of rat EDL muscle by section of the L4 spinal nerve at 3 days of age. Then the remaining motoneurons from L5 spinal nerve supplying the EDL muscle were retrogradly labelled with horseradish peroxidase two months later. The results show a reduction in motoneuron size in parallel with an increase in activity of the motoneurons after partial denervation of EDL muscle.     

Activity dependent characteristics of fast and slow muscle: biochemical and histochemical considerations

The effects of denervation and hindlimb suspension induced disuse on concentrations of ATP, phosphocreatine (PC), and fiber type profile were investigated in slow twitch soleus and fast twitch extensor digitorum longus (EDL) muscles. The results show that the soleus and EDL muscles differ in their dependency on loadbearing as a stimulus for maintaining normal energy metabolism and the biochemical and morphological characteristics of muscle fibers. As determined by R-P methodology, suspension reduced ATP and PC concentrations of the soleus to 26% and 56%, respectively, while, in EDL only, PC is reduced to 71% of control with no change in ATP. Both muscles, however, show identical losses in ATP and PC following denervation. The energy charge, an indicator of Pi availability in muscle was reduced significantly in both denervated muscles to 82% and 85% in soleus and EDL, respectively. No significant reduction of the energy charge was seen in the muscles from suspended rats. Thus, in parallel with the indirect regulation through muscle loadbearing, the nerve can effectively modulate the levels of high-energy phosphates more directly by some regulatory mechanisms independent of muscle type. Denervation and suspension disuse increased the proportion of type 2 fibers in the soleus with a concomitant decrease in type 1 fibers and a relative rise in the number of very small diameter fibers. The EDL showed only variation in fiber size.     

Studies on the effect of denervation in developing muscle

Summary Ultrastructural diversification of muscle fibers, with regard particularly to myofibrillar changes, has been investigated in the fast-twitch extensor digitorum longus (EDL) and the slow-twitch soleus muscles of the rat during fetal and postnatal development in the presence and in the absence of motor innervation. The band pattern and the shape of the myofibrils were uniform in fetal and neonatal muscle fibers and underwent differential changes during the first weeks after birth, concomitantly with fiber type specialization. The most evident variations in myofibrillar structure arising in this period concern the thickness of the Z band and the arrangement of the myofibrils. Myofibril formation was at first not impaired by denervation of rat muscles performed in utero and, although focal disintegration of myofibrils and detachment and loss of orientation of filaments became apparent by one week, atrophic muscle fibers with well-organized myofibrils could be seen as late as 2 months after birth. However, denervated muscle fibers of EDL and soleus did not display any significant and consistent difference in myofibrillar band pattern and shape. No variation in mitochondrial content and sarcoplasmic reticulum development was likewise seen in muscle fibers of EDL and soleus after fetal denervation. The findings emphasize the importance of neuromuscular interactions in muscle differentiation.This investigation was supported in part by a grant from Muscular Dystrophy Associations of America, Inc. to Prof. M. Aloisi. A preliminary report of part of this work was presented at the XL Congress of the Italian Zoological Society, Garda, 1971 (Schiaffino, 1972).     

Reinnervation of murine muscle following fetal sciatic nerve transection.

A technique is reported that permits transection of the sciatic nerve of mouse fetuses without interfering with fetal viability. Sciaticotomy was performed on Swiss Webster mice at day 17 of gestation; the contralateral side served as control. Six weeks later the extensor digitorum longus (EDL) muscles on both sides were injected with horseradish peroxidase (HRP). Examination of the lumbar spinal cord revealed that while a substantial number of motor neurons in the region of the spinal cord giving rise to the sciatic nerve died, the EDL muscle did become reinnervated. The size of the EDL motor neuron pool on the denervated-reinnervated side was approximately 43% of that seen on the control side. While the control EDL motor neuron pool was located in lumbar segments L3-L5, the location of the pool to the denervated-reinnervated EDL was shifted cranially to L2-L4. Denervated-reinnervated EDL muscles were analyzed immunohistochemically to study the effect of fetal denervation on the neuronal cell adhesion molecule (N-CAM) expression. At 2 weeks postnatal, N-CAM immunoreactivity in control muscle was segregated to the motor end-plate region, while fetally denervated muscle continued to express N-CAM along the length of the sarcolemma. Thus fetally denervated muscle does not develop the same pattern of N-CAM expression as normal, innervated muscle. By 6 weeks of age, the denervated-reinnervated muscle showed the same level and distribution of N-CAM immunoreactivity as did age-matched control muscle, indicating that most, if not all, of its myofibers had been reinnervated.     

Phospholipid distribution and stimulation of methylation during denervation and reinnervation in skeletal muscle

Denervation of the rat soleus and extensor digitorum longus muscles was induced by nerve crush. Functional signs of denervation were noted within 48 h with recovery beginning about the 12th day following denervation. There was also a marked decrease in muscle weight but only a small decrease in protein content per mg of muscle, subsequent to denervation. At 1, 2 and 3 weeks following nerve crush there was a relative decrease in muscle phosphatidylethanolamine (PE) and a corresponding increase in phosphatidylcholine (PC). The proportion of the other phospholipids did not significantly change. The levels of PC and PE returned to, or in some cases slightly overshot, control values at 4 and 5 weeks following nerve crush, i.e. during the period of reinnervation. Levels in non-denervated contralateral muscles did not significantly change. At 1 and 3 weeks following nerve crush a marked increase was observed in the activities of the enzymes PE-methyltransferases I and II, as measured by [³H]methyl group incorporation from S-adenosyl methionine into phosphatidylmonomethylethanolamine, phosphatidyldimethylethanolamine and PC. Increased activity of these methylases was seen in the contralateral control muscle, although less than in the denervated muscle. These enzymatic changes could be responsible for the changes in PE and PC distribution which we observed. Methylation of PE might also decrease the microviscosity of the membrane, thereby leading to other changes associated with denervation. Activation of this system might be another form of supersensitivity induced by denervation.     

Reinnervation of murine muscle following fetal sciatic nerve transection

A technique is reproted that permits transection of the sciatic nerve of mouse fetuses without interfering with fetal viability. Sciaticotomy was performed on Swiss Webster mice at day 17 of gestation; the contralateral side served as a control. Six weeks later the extensor digitorum longus (EDL) muscles on both sides were injected with horseradish peroxidase (HRP). Examination of the lumbar spinal cord revealed that while a substantial number of motor neurons in the region of the spinal cord giving rise to the sciatic nerve died, the EDL muscle did become reinnervated. The size of the EDL motor neuron pool on the denervated-reinnervated side was ～43% of that seen on the control side. While the control EDL motor neuron pool was located in lumbar segments L3–L5, the location of the pool to the denervated-reinnervated EDL was shifted cranially to L2–L4. Denervated-reinnervated EDL muscles were analyzed immunohistochemically to study the effect of fetal denervation on the neuronal cell adhesion molecule (N-CAM) expression. At 2 weeks postnatal, N-CAM immunoreactivity in control muscle was segregated to the motor end plate region, while fetally denervated muscle continued to express N-CAM along the length of the sarcolemma. Thus fetally denervated muscle does not develop the same pattern of N-CAM expression as normal, innervated muscle. By 6 weeks of age, the denervated-reinnervated muscle showed the same level and distribution of N-CAM immunoreactivity as did age-matched control muscle, indicating that most, if not all, of its myofibers had been reinnervated.     

Neural Regulation of Muscle Glucose 6-Phosphate Dehydrogenase: Effect of Batrachotoxin and Tetrodotoxin

Abstract: We tested the hypothesis that glucose 6-phosphate dehydrogenase (G6PD) activity in the rat skeletal muscle is regulated by putative axonally derived neurotrophic factors. This was accomplished by comparing the effects of nerve section and subperineural injection of batrachotoxin (BTX) or tetrodotoxin (TTX) on G6PD in rat extensor digitorum longus (EDL) muscle. BTX, an agent known to block nerve impulse conduction and axonal transport, increased G6PD activity to 155% and 163% of control by days 2 and 4 after injection. Denervation of the EDL muscle by section of the peroneal nerve 10–20 mm from its entrance to the muscle caused G6PD activity to increase to 170% of control by day 1 and to 200% and 180% of control by days 2 and 4, respectively. The increase in enzyme activity after denervation and after subperineural injection of BTX was due in part to muscle inactivity resulting from blockade of nerve impulses. This conclusion is based upon the observation that subperineural injection of TTX at an identical site in the peroneal nerve caused a small but significant (30%) increase in G6PD activity after 4 days. Choline acetyltransferase (CAT) activity was assessed as a measure of the efficacy of blockade of slow axonal transport. Decreases in CAT activity following denervation or injection of BTX or TTX were parallel to increases in G6PD activity observed under these conditions. These results argue for a role of axonal transport in neural regulation of muscle G6PD, with a small contribution by neuromuscular activity.     

Influence of denervation on the molecular forms of junctional and extrajunctional acetylcholinesterase in fast and slow muscles of the rat.

Acetylcholinesterase (AChE) molecular forms in denervated rat muscles, as revealed by velocity sedimentation in sucrose gradients, were examined from three aspects: possible differences between fast and slow muscles, response of junctional vs extrajunctional AChE, and early vs late effects of denervation. In the junctional region, the response of the asymmetric AChE forms to denervation is similar in fast extensor digitorum longus (EDL) and slow soleus (SOL) muscle: (a) specific activity of the A12 form decreases rapidly but some persists throughout and even increases after a few weeks; (b) an early and transient increase of the A4 AChE form lasting for a few weeks may be due to a block in the synthetic process of the A12 form. In the extrajunctional regions, major differences with regard to AChE regulation exist already between the normal EDL and SOL muscle. The extrajunctional asymmetric AChE forms are absent in the EDL because they became completely repressed during the first month after birth, but they persist in the SOL. Differences remain also after denervation and are, therefore, not directly due to different neural stimulation patterns in both muscles: (a) an early but transient increase of the G4 AChE occurs in the denervated EDL but not in the SOL; (b) no significant extrajunctional activity of the asymmetric AChE forms reappears in the EDL up till 7 wk after denervation. In the SOL, activity of the asymmetric AChE forms is decreased early after denervation but increases thereafter.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulation of Taurine Transport in Rat Skeletal Muscle

Taurine concentration of soleus muscle (SL, slow-twitch) was initially about twofold higher than that of extensor digitorum longus muscle (EDL, fast-twitch). Taurine concentration in gastrocnemius muscle (GC) was intermediate between that of EDL and SL. Four days after sciatic nerve section, taurine concentration in the EDL but not in the SL was increased by 2.5-fold. The increase was not due to the muscle atrophy and was observed 28 days after denervation. Tenotomy did not increase the total taurine content of the EDL. The increase in taurine concentration of the denervated EDL was prevented by simultaneous ingestion of guanidinoethane sulfonate, a competitive inhibitor of taurine transport. The initial and the maximal rates of [3H]taurine uptake were significantly higher in SL than in EDL. Denervation dramatically accelerated the initial and the maximal rates of the transport in EDL, whereas it significantly reduced those in SL. In contrast, the electrical stimulation of sciatic nerve accelerated the uptake of taurine by EDL and SL of the control but not of the curare-treated rats. These results suggest that transport of taurine into rat skeletal muscles is regulated differently by neural information and by muscular activity, and that the regulation is dependent on the muscle phenotype.     

Effects of partial denervation on the distribution of acetylcholine receptors and other membrane properties in innervated and paralyzed fibers of rat skeletal muscle

The origin of the membrane changes induced in skeletal muscle by denervation has been investigated by examining partially denervated rat hindlimb muscles rendered inactive for 2-3 days by a chronic conduction block in the sciatic nerve. Extra-junctional sensitivity to acetylcholine and spike resistance to tetrodotoxin developed to the same extent in the denervated and the adjacent innervated but inactive fibres. On the other hand, impulse-blocked fibres of control muscles not containing denervated fibres showed, at this early time, little membrane changes. These results are interpreted as indicating that the response of muscle to denervation is due to the combined action of inactivity and products of nerve degeneration.     

Effect of Denervation and Reinnervation on Oxidation of [6-14C]Gucose by Rat Skeletal Muscle Homogenates

Abstract: We studied the effects of denervation and reinnervation of the rat extensor digitorum longus muscle (EDL) on the oxidation of [6-¹⁴C]glucose to ¹⁴CO₂. The rate of ¹⁴CO₂ production decreased dramatically following denervation, and the decrease became significant 20 days after nerve section. Prior to day 20, changes apparently reflected the decline of muscle mass. Decreased ¹⁴CO₂ production was due to reduced capacity of the enzymatic system (apparent V_max); there was no change in apparent affinity for glucose (apparent K _m). Mixing experiments revealed that the loss of oxidative capacity following denervation is not caused by production of soluble inhibitors by degenerating muscle. Oxidative metabolism, as measured by ¹⁴CO₂ evolution, recovered during reinnervation. Surprisingly, the specific activity in reinnervated muscles displayed an "overshoot" of approximately 50%, which returned to control by day 60, possibly reflecting increased energy demand by the growing muscle. The time-course of the denervation-mediated change indicates that altered oxidative capacity is secondary to events that initiate denervation changes in muscle. Nevertheless, diminished oxidative capacity may be of considerable metabolic significance in denervated muscle.     

Effects of denervation and colchicine treatment on the chloride conductance of rat skeletal muscle fibers.

Membrane potentials, cable parameters, and component resting conductances were measured in extensor digitorum longus (EDL) muscle fibers from adult rats in vitro at 24 degrees C, after 15 to 18 days of denervation by nerve section, and at seven to ten days following epineural injection of 100 to 450 mug of colchicine in the peroneal nerve. The denervated muscles were paralyzed throughout the experimental period, whereas the colchicine-treated preparations showed no clinical paralysis except for the first day or two. The EDL from the untreated side served as a control. Both the denervated and colchicine-treated fibers were depolarized, showed signs of fibrillation, had tetrodotoxin-resistant potentials, and membrane resistance was increased two- to sevenfold. In the denervated fibers, mean chloride conductance GC1 dropped from a control value of 3196 to 596 mumhos/cm2 while mean potassium conductance GK showed a tendency to rise from 260 to 332 muhos/cm2. Colchicine-treated fibers while showing a similar fall in mean GC1 from 2993 to 1066 mumhos/cm2, also showed a significant fall in mean GK from 213 to 116 mumhos/cm2. It was concluded that factors transported by the microtubular system are important for the maintenance of the high resting GC1 of mammalian skeletal muscle fibers.     

Atrophy, but not necrosis, in rabbit skeletal muscle denervated for periods up to one year

Our understanding of the effects of long-term denervation on skeletal muscle is heavily influenced by an extensive literature based on the rat. We have studied physiological and morphological changes in an alternative model, the rabbit. In adult rabbits, tibialis anterior muscles were denervated unilaterally by selective section of motor branches of the common peroneal nerve and examined after 10, 36, or 51 wk. Denervation reduced muscle mass and cross-sectional area by 50–60% and tetanic force by 75%, with no apparent reduction in specific force (force per cross-sectional area of muscle fibers). The loss of mass was associated with atrophy of fast fibers and an increase in fibrous and adipose connective tissue; the diameter of slow fibers was preserved. Within fibers, electron microscopy revealed signs of ultrastructural disorganization of sarcomeres and tubular systems. This, rather than the observed transformation of fiber type from IIx to IIa, was probably responsible for the slow contractile speed of the muscles. The muscle groups denervated for 10, 36, or 51 wk showed no significant differences. At no stage was there any evidence of necrosis or regeneration, and the total number of fibers remained constant. These changes are in marked contrast to the necrotic degeneration and progressive decline in mass and force that have previously been found in long-term denervated rat muscles. The rabbit may be a better choice for a model of the effects of denervation in humans, at least up to 1 yr after lesion. force; shortening velocity; electron microscopy; histochemistry     

The effects of denervation on protein turnover of the soleus and extensor digitorum longus muscles of adult mice.

1. Changes in protein turnover of the soleus and EDL muscles of adult mice have been studied 1, 7 and 80 days after denervation. 2. Increased rates of protein degradation 7 and 80 days post-denervation correlated with the atrophy and loss of protein from these muscles. 3. Rates of protein synthesis in the EDL decreased 24 hr after nerve section. However, these synthetic rates increased again to become higher in the 7 day denervated muscles compared with their controls. These latter anabolic changes are inconsistent with the concept of a denervated muscle being inactive. 4. These findings have been compared with a similar study on muscles of growing rats. Any passive stretching of the denervated muscles by continued bone growth appears unlikely to be a crucial factor explaining the increased rates of protein synthesis 7 days after denervation.     

Seasonal changes in the response of fast and slow mammalian skeletal muscle fibers to zero potassium.

While investigating the decline in resting membrane potential (RMP) of rat skeletal muscle fibers in zero potassium solution, we discovered that there is seasonal variation in the response of the extensor digitorum longus muscle (EDL). In January, most EDL fibers hyperpolarize in zero K+; in September, most depolarize; the distribution of RMPs recorded in May is bimodal, with some fibers hyperpolarizing and some depolarizing. Fibers from the soleus muscle depolarize in zero K+ irrespective of the season. The ability of EDL fibers to hyperpolarize appears during the 7th and 8th weeks postpartum, and is dependent upon the presence of a functional nerve, since denervation abolished the response. As possible explanations for these findings, inactivation of K(+)-channels and inhibition of the Na-K pump by zero K+ are discussed.