Neural control of phenotypic expression in mammalian muscle fibers

In this review, the present knowledge about the mechanisms involved in the control of the phenotypic expression of mammalian muscle fibers is summarized. There is a discussion as to how the activity imposed on the muscle fibers by the motoneuron finally induces in the muscle cells the expression of those genes that define its particular phenotype. The functional and molecular heterogeneity of skeletal muscle is thus defined by the existence of motor units with varied function, while the homogeneity of muscle fibers belonging to the same motor unit is yet another indication of the importance of activity in the control of gene expression of the mammalian muscle fiber.

The influence of activity on some contractile characteristics of mammalian fast and slow muscles

1. The time course of contraction and relaxation in the isometric twitch of a rabbit soleus muscle becomes more rapid following tenotomy and spinal cord section. This increase in speed could be prevented by long-term electrical stimulation at frequencies of 5 or 10/sec. It was not prevented by stimulation at frequencies of 20 or 40/sec.2. Long-term electrical stimulation of fast rabbit and cat muscles at a frequency of 10/sec had a slowing effect on the time course of contraction and relaxation.3. It is concluded that the almost continuous low frequency discharge of motoneurones innervating postural muscles plays an important part in establishing and maintaining the slow time course of contraction of these muscles. The characteristically different speeds of contraction of fast and slow striated muscles can in this way be related to the different patterns of impulse activity which they normally receive.

Observations on the elimination of polyneuronal innervation in developing mammalian skeletal muscle

1. The mechanism responsible for the elimination of polyneuronal innervation in developing rat soleus muscles was studied electrophysiologically and histologically. 2. Initially all the axons contacting a single end-plate have simple bulbous terminals. As elimination proceeds one axon develops terminal branches while the other terminals remain bulbous and may be seen in contact with, or a short distance away from, the end-plate. It is suggested that the branched terminal remains in contact with the muscle fibre while the other terminals withdraw. 3. At a time when polyneuronal innervation can no longer be detected electrophysiologically, the histological technique still shows the presence of end-plates contacted by more than one nerve terminal. 4. The effect of activity on the disappearance of polyneuronal innervation was examined. Activity was increased by electrical stimulation of the right sciatic nerve. This procedure also produced reflex activity in the contralateral limb. In both cases polyneuronal innervation was eliminated more rapidly in the active muscles. 5. The finding that proteolytic enzymes are released from muscles treated with acetylcholine (ACh), and the observation of the more rapid elimination of supernumerary terminals at the end-plates of active muscles, lead to the suggestion that superfluous nerve-muscle contacts are removed by the proteolytic enzymes in response to neuromuscular activity. The selective stabilization of only one of the terminals is discussed in the light of these results.

Time dependent effects on contractile properties, fibre population, myosin light chains and enzymes of energy metabolism in intermittently and continuously stimulated fast twitch muscles of the rabbit

Fast-twitch tibialis anterior and extensor digitorum longus rabbit muscles were subjected to long-term intermittent (8 h daily) or continuous (24 h daily) indirect stimulation with a frequency pattern resembling that of a slow motoneuron. Increases in time to peak of isometric twitch contraction were observed without parallel changes in the pattern of myosin light chains or alterations in the distribution of slow and fast fibres as discernible by the histochemical ATPase reaction. However, changes in the fibre population and in the myosin light chain pattern were observed after intermittent stimulation periods exceeding 40 days or continuous stimulation periods longer than 20 days. Under these conditions even higher increases were found in contraction time. In one animal a complete change in fbire population was observed. In this case myosin light chains of the slow (LCS1, LCS2) and of the fast type (LCf1) were obviously synthetized simultaneously within the same fibre. Early changes in the enzyme activity pattern of energy metabolism indicated a conversion of the fibres including their mitochondrial population. These changes and the earlier reported changes in the sarcoplasmic reticulum are probably responsible for the early changes in contractile properties which occur before the transformation of the myosin.

The effects of different patterns of muscle activity on capillary density, mechanical properties and structure of slow and fast rabbit muscles

When rabbit fast muscles were chronically stimulated at a frequency naturally occurring in nerves to slow muscles (10 Hz), there was a transformation towards a slow muscle type such as an increase of capillary density, increased activity of the oxidative enzyme, succinic dehydrogenase, and a decrease of muscle fibre diameters. After 28 days the intensity and distribution of SDH and the capillary density were similar to those of soleus. The increases in capillary density preceded the changes in activity of SDH; there was a significantly greater capillary/muscle fibre ratio and number of capillaries/mm2 in muscles stimulated for only 4 days at which time no change could be detected in SDH. These changes were induced by slow frequency stimulation only, and not by an overall increase of activity. Stimulation of fast muscles for 4 days at a higher frequency naturally occurring in the nerves to fast muscles (short bursts of tetani), with the same total number of stimuli as that used in slow frequency stimulation did not produce any changes in capillary density, activity of SDH or contraction times. No changes were observed in either fast or slow muscles stimulated with short bursts of tetani (and lower total number of impulses) up to 28 days. Activation of fast muscles at 5 Hz continuously or 10 Hz intermittently also caused an increase in capillary density. It is therefore concluded that only low frequency activation of fast muscles brings about a transformation of the muscle fibres towards a slow type and that the first noticeable change is an increase in the capillary density.

Dependence of postnatal motoneurones on their targets: review and hypothesis

Motoneurones are known to die (1) during embryonic development (naturally occurring cell death), (2) early in postnatal development after axonal injury, and (3) as a consequence of disease, such as spinal muscular atrophy or (in later life) amyotrophic lateral sclerosis. Naturally occurring motoneurone death has been extensively investigated, and interaction with the target muscle has emerged as an important factor for survival of embryonic motoneurones. Evidence that this target dependence of motoneurones continues postnatally is discussed in this review, as is the possible nature of the retrograde signal from the muscle. An explanation for the role of the muscle in motoneurone survival is also proposed, which may be applicable in situations where motoneurone death occurs postnatally. This proposal takes into account the changing functional demands imposed on motoneurones as a result of the gradual maturation of the CNS, and suggests that during development the muscle induces the motoneurones to become competent to carry out these requirements.

What does chronic electrical stimulation teach us about muscle plasticity?

The model of chronic low-frequency stimulation for the study of muscle plasticity was developed over 30 years ago. This protocol leads to a transformation of fast, fatigable muscles toward slower, fatigue-resistant ones. It involves qualitative and quantitative changes of all elements of the muscle fiber studied so far. The multitude of stimulation-induced changes makes it possible to establish the full adaptive potential of skeletal muscle. Both functional and structural alterations are caused by orchestrated exchanges of fast protein isoforms with their slow counterparts, as well as by altered levels of expression. This remodeling of the muscle fiber encompasses the major, myofibrillar proteins, membrane-bound and soluble proteins involved in Ca2+ dynamics, and mitochondrial and cytosolic enzymes of energy metabolism. Most transitions occur in a coordinated, time-dependent manner and result from altered gene expression, including transcriptional and posttranscriptional processes. This review summarizes the advantages of chronic low-frequency stimulation for studying activity-induced changes in phenotype, and its potential for investigating regulatory mechanisms of gene expression. The potential clinical relevance or utility of the technique is also considered.

Two factors responsible for the development of denervation hypersensitivity

1. Innervated adult skeletal muscle is sensitive to acetylcholine at the end-plate region only. After denervation the entire muscle membrane becomes chemosensitive. The period of greatest increase in sensitivity in rat soleus muscles following section of the sciatic nerve in the thigh is between 48 and 72 hr post-operatively.2. Direct electrical stimulation was found to prevent the onset of the development of denervation hypersensitivity during the first 2-3 days after nerve section. Thereafter, electrical stimulation only reduced the sensitivity of denervated muscles to acetylcholine (ACh).3. The period of greatest increase in sensitivity follows loss of transmission and degeneration of the nerve terminals. Once this degeneration is under way, electrical stimulation is no longer as effective in preventing the development of denervation hypersensitivity.4. Hypersensitivity is also seen in muscles on which a small piece of thread or degenerating nerve has been placed. Hypersensitivity following these procedures declines within a few days, unlike denervation hypersensitivity which persists until innervation is restored.5. The present results suggest that activity alone cannot prevent the development of hypersensitivity in the presence of degenerating nerve fibres, or muscle damage. Activity does however counteract increased sensitivity. It is suggested that two factors interact to produce denervation hypersensitivity; the presence of degenerating nerve tissue and concomitant cellular changes bring about changes in the muscle fibre membrane causing it to become hypersensitive; and the loss of muscle activity, resulting in the persistence of hypersensitivity until innervation is restored.

The effect of long-term stimulation of fast muscles on their blood flow, metabolism and ability to withstand fatigue

Chronic stimulation of fast rabbit muscles (tibialis anterior, extensor digitorum longus and the peroneal muscle group) at a frequency naturally occurring in nerves to slow muscles increased their ability to withstand fatigue. Isometric tension decreased during a 10-min period of contractions at 4 Hz by 75% in control muscles, but only 55% in muscles chronically stimulated for 4 days, and 23% in muscles stimulated for 28 days. Chronic stimulation had little effect on resting blood flow, oxygen or glucose consumption. The output or consumption of lactate and free fatty acids (FFA) at rest were also unaffected. The glycogen content was regularly increased, and was apparent after only 2 days of stimulation. The activity of fatty acid activating enzyme was increased after 28 days. During a 10-min period of isometric contractions at 4 Hz, there was a markedly greater increase in blood flow and oxygen consumption in muscles stimulated for 14-28 days than in control muscles; lactic acid output was lower in muscles stimulated for 28 days, and the uptake of FFA was significantly higher. It is therefore suggested that muscles chronically stimulated for 14-28 days use fats as the main source of energy during isometric contractions. The predominantly oxidative metabolism is probably facilitated by the higher density of capillaries. The latter also enables more efficient delivery of oxygen, and therefore smaller fatiguability, already after 4 days of chronic stimulation.

Permanent changes in muscle and motoneurones induced by nerve injury during a critical period of development of the rat

The sciatic nerve was crushed in rats at different times during the first two weeks after birth. Following reinnervation the recovery of the fast and slow muscles and their motoneurones was compared. The main factor affecting recovery of muscle weight and tension was the age at which the nerve was crushed; the earlier the injury the greater the impairment. However, recovery also depended upon muscle type. The fast muscles, tibialis anterior and extensor digitorum longus, always recovered less well than the slow soleus muscle. The greatest difference in recovery was seen when the nerve was crushed between 3 and 6 days of age. The fatigue resistance of fast muscles was markedly increased after nerve injury at any time during the first two postnatal weeks and was greatest when the nerve crush was done soon after birth. However, this change was not just related to muscle weakness as the increase in fatigue resistance after nerve crush at 5 and 12 days was similar regardless of the difference in recovery of the muscles. Retrograde labelling of motoneurones with HRP demonstrated that about 60-70% of motoneurones innervating fast or slow muscles were lost following sciatic nerve crush at birth. It is concluded that motoneurone loss probably accounts for most of the impairment of soleus after postnatal nerve crush but only partly explains the poor recovery of fast muscles.

The role of muscle activity in the differentiation of neuromuscular junctions in slow and fast chick muscles

The differentiation of neuromuscular junctions of multiply innervated, slow anterior latissimus dorsi (ALD) and focally innervated, fast, posterior latissimus dorsi (PLD) muscles was studied in normal and curarized chick embryos. At 16 days of incubation, fibres of both muscles are contacted by several axon profiles, the number of which falls with age. In 18-day-old embryos individual endplates in ALD are usually contacted by three axon profiles, whereas in PLD, endplates are contacted only by a single large terminal profile. At this time, there is already a significant accumulation of cell organelles in the postsynaptic area. Treatment of embryos with curare during the 7th and 12th day of incubation delays the differentiation of the neuromuscular junction in both muscles. The paralysis dramatically affects the decrease of the number of axon profiles at individual endplates in both muscles. At 16 days the number of axon profiles was greater in embryos treated with curare than in the untreated controls. At 18 days when the number of axon profiles normally decreases, the endplates of both types of curarized muscles have an even greater number of axon profiles than at 16 days. Endplates in curarized PLD had up to 13 and in curarized ALD up to 12 axon profiles. The effects of curare gradually wore off and when the movements of the embryos again became more vigorous, the normal differentiation of neuromuscular junctions continued. At 21 days of incubation many embryos recover from curare and show endplates of normal appearance in both muscles. These results suggest that activity of the muscle is essential for the maturation of the neuromuscular junctions.

Contractile properties and susceptibility to exercise-induced damage of normal and mdx mouse tibialis anterior muscle

1. The functional properties of tibialis anterior muscles of normal adult (C57BL/10) and age-matched dystrophin-deficient (C57BL/10 mdx) mice have been investigated in situ. Comparisons were made between tibialis anterior muscle strength, rates of force development and relaxation, force-frequency responses and fatiguability. Subjecting mdx and C57 muscles to a regimen of eccentric exercise allowed the hypothesis to be tested that dystrophin-deficient muscles are more susceptible to exercise-induced muscle damage. 2. mdx muscles were, on average, 30% stronger than C57 muscles and almost 80% heavier, but both had similar muscle lengths. Thus, although mdx muscles were stronger in absolute terms, their estimated force per unit cross-sectional area was significantly less than that of C57 muscles. 3. The force-frequency relationships of C57 and mdx muscles differed in that whilst, at 40 Hz, the former developed 70% of the force developed at 100 Hz, the latter developed only 55% of the maximal force. Twitch force was normal in mdx muscles, but contraction time was shortened, and the consequent reduction in fusion frequency probably explains the force-frequency differences observed between the two groups. 4. mdx muscles were less fatiguable than normal muscles when stimulated repeatedly at a frequency of 40 Hz. It is possible that the lower relative force at 40 Hz in mdx muscles entailed a lower energy demand and thus a slower rate of fatigue than seen in normal muscles. 5. Eccentrically exercised C57 muscles showed a large loss of maximal force for up to 12 days after exercise. Maximal force loss occurred 3 days after exercise (55% of non-exercised tibialis anterior muscle), which also corresponded with the period of greatest fibre necrosis. C57 muscles showed a significantly reduced 40 Hz/100 Hz force-frequency ratio at 1 and 3 days after exercise. This was primarily due to a reduced twitch amplitude rather than to a change in the time course of the twitch. It is unlikely, therefore, that the altered contractile characteristics of mdx muscle were a result of the presence of damaged but otherwise normal fibres. 6. C57 and mdx tibialis anterior muscles displayed similar degrees of force loss after exercise. Furthermore, the rate of recovery after the nadir of force loss was very similar for the two groups. By 12 days after exercise, force recovered to 76% and 80% of control in C57 and mdx muscles, respectively. Our findings do not support the hypothesis that dystrophin-deficient muscle is more susceptible to exercise-induced muscle damage.

Activity-dependent interactions between motoneurones and muscles: their role in the development of the motor unit

In this review article we have attempted to provide an overview of the various forms of activity-dependent interactions between motoneurones and muscles and its consequences for the development of the motor unit. During early development the components of the motor unit undergo profound changes. Initially the two cell types develop independently of each other. The mechanisms that regulate their characteristic properties and prepare them for their encounter are poorly understood. However, when motor axons reach their target muscles the interaction between these cells profoundly affects their survival and further development. The earliest interactions between motoneurones and muscle fibres generate a form of activity which is in many ways different from that seen at later stages. This difference may be due to the immature types of ion channels and neurotransmitter receptors present in the membranes of both motoneurones and muscle fibres. For example, spontaneous release of acetylcholine may influence the myotube even before any synaptic specialization appears. This initial form of activity-dependent interaction does not necessarily depend on the generation of action potentials in either the motoneurone or the muscle fibre. Nevertheless, the ionic fluxes and electric fields produced by such interactions are likely to activate second messenger systems and influence the cells. An important step for the development of the motor unit in its final form is the initial distribution of synaptic contacts to primary and secondary myotubes and their later reorganization. Mechanisms that determine these events are proposed. It is argued that the initial layout of the motor unit territory depends on the matching of immature muscle fibres (possibly secondary myotubes) to terminals with relatively weak synaptic strength. Such matching can be the consequence of the properties of the muscle fibre at a particular stage of maturation which will accept only nerve terminals that match their developmental stage. Refinements of the motor unit territory follows later. It is achieved by activity-dependent elimination of nerve terminals from endplates that are innervated by more than one motoneurone. In this way the territory of the motor unit is established, but not necessarily the homogeneity of the physiological and biochemical properties of its muscle fibres. These properties develop gradually, largely as a consequence of the activity pattern that is imposed upon the muscle fibres supplied by a given motoneurone. This occurs when the motor system in the CNS completes its development so that specialized activity patterns are transmitted by particular motoneurones to the muscle fibres they supply.(ABSTRACT TRUNCATED AT 400 WORDS)

Effect of low calcium and protease inhibitors on synapse elimination during postnatal development in the rat soleus muscle

The mechanisms controlling the reorganisation of synaptic inputs to developing skeletal muscle fibres was studied using electrophysiological and histological methods. In the developing rat soleus muscle there is a rapid reduction of polyneuronal innervation between 9 and 12 days. Reducing the local concentration of calcium by applying chelating agents such as EGTA or BAPTA in vivo to 9-day-old rat soleus muscles over a period of 3 days slowed the rate of elimination of polyneuronal innervation. It was established that the reduction of calcium induced by EGTA or BAPTA was not sufficient to produce a detectable reduction in neuromuscular activity. The possibility that a calcium-dependent enzyme such as CANP may play a role in synapse reorganisation was therefore tested. Local application of inhibitors of calcium-activated neutral protease (CANP), leupeptin or E-64, to 9-day-old rat soleus muscles over 3 days had similar effects to those of EGTA or BAPTA, i.e. the elimination of polyneuronal innervation that usually takes place was much slower. Since the inhibition of thiol proteases had similar effects on synapse elimination as a reduction of calcium concentration, it is concluded that CANP is important in the reorganisation of the developing neuromuscular junction.

Comparison of enzyme activities among single muscle fibres within defined motor units

1. Muscle fibres from single motor units of rat extensor digitorum longus were depleted of their glycogen by electrical stimulation and identified by the periodic acid-Schiff stain after treatment in a medium that selectively enhanced glycogen content in the non-depleted fibres. 2. Malate dehydrogenase (MDH) and fructose-1,6-diphosphatase (FDPase) activities were studied quantitatively in single dissected fibres of individual motor units and in fibres selected randomly from the same muscle. 3. In contrast to the large variability of MDH and FDPase in muscle fibres taken randomly, the muscle fibres from the same motor units had similar enzyme activities. 4. The resistance to fatigue of the motor units correlated well with the capacity of aerobic oxidative metabolism, as judged by the activity of MDH in the muscle fibres.

Recovery of slow and fast muscles following nerve injury during early post-natal development in the rat

1. The sciatic nerve was crushed in 5-6-day-old rats and the recovery of function of slow and fast muscles was studied. The first signs of recovery of function were seen 10-12 days after the operation. 2. Maximal tetanic tension developed by the reinnervated muscles was recorded and taken as an indication of their recovery. Two months after nerve crush, slow soleus muscles developed only slightly less tension than the control unoperated soleus muscles. The reinnervated fast muscles tibialis anterior (t.a.) and extensor digitorum longus (e.d.l.) developed only about 50% of the tension of the unoperated controls. 3. The fast muscles never recovered, remaining weaker and smaller throughout the animals' life. 4. The number of muscle fibres in the reinnervated fast muscles was substantially reduced and their fibre composition altered in that they contained mainly muscle fibres with high levels of oxidative enzymes. 5. The reinnervated fast muscles became much more fatigue resistant than the unoperated controls. 6. The possibility that these changes are due to motoneurone death was examined. The motoneurones innervating the fast muscles were labelled by retrograde transport of HRP. No significant reduction in the number of motoneurones innervating the operated muscles was found. 7. These results show that nerve injury during early post-natal life causes permanent changes in fast muscles that are not caused by motoneurone death.

Motoneurons destined to die are rescued by blocking N-methyl-D-aspartate receptors by MK-801

Motoneurons to soleus muscle die if their axons are injured at birth. We tested the possibility that their death may be caused by toxic effects of excitatory transmitters such as glutamate. Animals that had their sciatic nerves crushed at birth were treated either with a blocker of the N-methyl-D-aspartate receptor, dizocilpine maleate (MK-801), or saline. The number of surviving soleus motoneurons and motor units was assessed 60-90 days later. Treatment of rats with MK-801 rescued a large proportion of injured motoneurons destined to die. Moreover, the weight loss of soleus muscles seen after nerve injury at birth was reduced in animals treated with MK-801. These results suggest that motoneurons axotomized at birth are unable to withstand the excitotoxic effects of glutamate and die. Blocking glutamate receptors in conditions where motoneuron loss occurs could be an effective way of rescuing them.

Functional specializations of the vascular bed of soleus

1. The venous outflow from the slow soleus muscle, at rest and during exercise, was compared with that of fast muscles. The blood flow through the soleus at rest was found to be, on average, 52 ml./100 g.min, which is about 4 times that of fast muscles.2. On stimulation of soleus through its motor nerve at low frequencies, up to 8/sec, hardly any increase in flow was observed, whereas fast muscles stimulated at the same rates showed a marked increase, the maximal functional hyperaemia being reached at 8/sec. Even when the soleus muscle was stimulated at frequencies of 40/sec the post-contraction hyperaemia was very small and sometimes absent.3. The relative absence of functional hyperaemia in the soleus does not appear to be due to low vascular tone, for small amounts of acetylcholine, injected close arterially, produced a considerable increase in blood flow. Further, in experiments in which the vascular tone was increased by lumbar sympathetic stimulation, no functional hyperaemia was seen. It is concluded that a contracting soleus does not release in adequate amounts the substance causing functional vasodilatation in fast muscles.4. No vasodilator effect of adrenaline could be demonstrated in soleus, and the vasodilator effect of isoprenaline was much smaller than that seen in fast muscles.5. The vasoconstrictor effect of lumbar sympathetic stimulation on the resistance vessels of soleus was much smaller than the effect seen in fast muscles. However, the responses of the resistance vessels in soleus to close arterial injections of noradrenaline were not very different from those of fast muscles, and it is suggested that the density of the terminal sympathetic innervation of the vessels of soleus differs from that of fast muscles.

The influence of innervation on the differentiation of contractile speeds of developing chick muscles

1. The role of innervation of the differentiation of contractile speeds was studied in the slow anterior latissimus dorsi (ALD) and fast posterior latissimus dorsi (PLD) muscle of the chick. 2. These muscles become innervated during the 12th and 15th day of embryonic development. At this time both muscles contract and relax extremely slowly and their contractile speeds are very similar. By the 18th day their contraction and relaxation becomes more rapid. It is at this time that the contractile characteristics of both muscles also become very different from each other, ALD being about 3 times slower than PLD. Thus innervation percedes differentiation of contractile speeds by several days. 3. The influence of innervation on the contractile characteristics of developing slow and fast muscles was studied during muscle regeneration in adults. When a slow ALD muscle was minced and implanted in place of a fast PLD the newly regenerated ALD became innervated by a PLD nerve and resembled a fast PLD. Conversely, when PLD muscles were minced and replaced ALD the regenerated PLD was innervated by ALD nerve and became slow. 4. Histological examination revealed that the regenerated ALD became focally innervated, and the regenerated PLD multiply innervated. 5. Thus, the contractile speeds are not predetermined properties of the muscle fibre. Both contractile characteristic and the pattern of innervation of developing muscles are determined by the motor nerve.

Blockade of N-methyl-D-aspartate receptors by MK-801 (dizocilpine maleate) rescues motoneurones in developing rats

In rats following nerve injury at birth a large proportion of motoneurones to the soleus muscle dies. Blocking of N-methyl-D-aspartate (NMDA) receptors by MK-801 (dizocilpine maleate) for 12 days after nerve injury at birth leads to rescue of a proportion of motoneurones destined to die. Retrograde labelling of soleus motoneurones shows that 6-8 weeks after crushing the sciatic nerve in one hindlimb, only 10.9 +/- 2.3% of the motoneurones have survived. In animals treated with an NMDA receptor blocker MK-801 (2 mg/kg i.p., from birth to 12 days old) 50.6 +/- 3.8% of soleus motoneurones survived. This neuroprotective effect of MK-801 was dose dependant, since after treatment with lower doses (0.5 mg/kg; 1 mg/kg) fewer motoneurones survived (13.7% and 34.5%, respectively). To assess the effect of treatment with MK-801 on survival of alpha-motoneurones only, the number of soleus motor units was established physiologically. After nerve injury alone only 4.2 +/- 1.2 of the 29-30 soleus motor units were present, while in animals treated with MK-801 (2 mg/kg) 14 +/- 1.5 motor units were identified. The neuroprotective effect of MK-801 was not confined to soleus motoneurones but was also apparent on motoneurones to the extensor digitorum longus (EDL). In untreated EDL muscles of the 40 motor units only 5.5 +/- 1.7 motor units survived neonatal nerve injury and this number increased to 18 +/- 2.6 after treatment with MK-801. The neuroprotective effect of MK-801 was apparent regardless of whether the nerve lesion was carried out close to or far from the soleus muscle.

Responses of muscles of patients with Duchenne muscular dystrophy to chronic electrical stimulation

The effect of chronic low frequency stimulation on the tibialis anterior muscle of children with Duchenne muscular dystrophy was investigated. Baseline data from 16 boys established low values of maximum voluntary contraction which did not improve with age. Studies of the contractile properties revealed significant slowing (p less than 0.001) of mean relaxation time compared to that of normal children's muscles. There was no loss of force during fatigue testing, as in normal children, but in contrast to normal children, there was no potentiation at lower frequencies of stimulation. Intermittent chronic low frequency stimulation of muscles in six young ambulant children with Duchenne muscular dystrophy resulted in a significant increase (p less than 0.05) in mean maximum voluntary contraction compared with the mean forces exerted by the unstimulated control muscles of the contralateral leg.

Independent development of contractile properties and myosin light chains in embryonic chick fast and slow muscle

1. The contractile speeds and tetanus/twitch ratios of the slow anterior latissimus dorsi (ALD) and fast posterior latissimus dorsi (PLD) muscles were studied during embryonic development and correlated with the type of myosin light chains present in these muscles as studied by one and two dimensional polyacrylamide gel electrophoresis. 2. At a time when the contractions of PLD were slow, i.e. in 15 day old embryos, the myosin light chains in this muscle were of the fast type. The slow contraction of this muscle may be due to incomplete and slow activation of the contractile elements. The tetanus/twitch ratio of muscles from 15 day old embryos is low and increases sharply with age. This increase could be due to the maturation of the internal membrane system, and occurs at about the same time as the increase in the speed of contraction. 3. ALD muscles contract slowly during all stages of development, although their tetanus/twitch ratio also increases with age. At 13 days they contain a mixture of fast and slow type myosin light chains and with increasing age the proportion of the slow type myosin light chains increases at the expense of the fast type. The slow time course of contraction of ALD is consistent with the presence of slow type myosin light chains. 4. The possibility that the synthesis of the slow type myosin light chains in ALD is induced by early motor activity in chick embryos is discussed.

Differential effect of nerve injury at birth on the activity pattern of reinnervated slow and fast muscles of the rat

The activity patterns of the reinnervated slow soleus and fast extensor digitorum longus (e.d.l.) muscles were studied in rats during the first 6 months after sciatic nerve crush at birth, using chronic electromyography. When the nerve lesion was inflicted shortly after birth, the recovery of the muscle weight and size was always much less than if the same lesion was inflicted on adult animals. As previously demonstrated, this effect is due to motoneurone and muscle fibre loss. Following reinnervation after a neonatal crush, the soleus muscle recovered its normal tonic activity pattern during postural and spontaneous locomotor activity. By contrast, in the reinnervated e.d.l. muscle, abnormal tonic motor unit activity was recorded during locomotion, in addition to the phasic activity characteristic of the normal muscle. In response to postural reflexes elicited by tilting the animal, tonic motor unit activity was recorded from the reinnervated e.d.l. muscle, whereas the normal muscle was not activated by these stimuli. The aggregate activity recorded from the reinnervated e.d.l. during spontaneous locomotion was about 2-3 times greater than normal, whereas in the reinnervated soleus no significant change took place. In animals which had their nerves crushed as adults, the activity pattern and aggregate activity of both muscles was similar to normal. The firing pattern of individual motor units from normal and reinnervated muscles was compared. After a neonatal crush, the mean frequency of firing of e.d.l. motor units was significantly lower compared to normal or to that after an adult crush, whereas in soleus no significant change was found. These results indicate that peripheral nerve lesions during early development affect predominantly the development of motoneurones with a phasic, high-frequency discharge pattern resulting in a shift towards tonic, lower-frequency motor unit activity.