Reinnervation of fast and slow mammalian muscles by a superfluous number of motor axons.

In this study peripheral nerves from flexor digitorum longus, (alien nerve) as well as the deep branch of the muscle's own lateral popliteal nerve were cut and connected to the distal stump of the lateral popliteal nerve. Extensor digitorum longus and tibialis anterior muscles then became reinnervated to a similar extent by either nerve, showing no preference for its own nerve. A significant proportion of the endplates in these muscles remained permanently supplied by more than one axon, and a proportion of the muscle fibres was supplied by both nerves. No ectopic endplates were formed on fast muscle fibres. The same two nerves were also connected to the slow soleus muscle and this muscle became preferentially reinnervated by the nerve to flexor digitorum longus. In contrast to fast muscles, endplates of soleus muscle fibres were only rarely contacted by more than one axon, and ectopic endplates were often found in this muscle. In both types of muscles that had an excess of motor nerves, extensive sprouting persisted for many months. Thus, identical motor nerves induce different patterns of innervation in slow and fast muscles, and muscle fibres do not show a preference for their own nerve.

Protease inhibitors reduce the loss of nerve terminals induced by activity and calcium in developing rat soleus muscles in vitro.

The end-plate of a mammalian skeletal muscle fibre is innervated by several axons at the time of birth but by only one axon in the adult. In the rat soleus muscle the transition from polyneuronal to single innervation occurs during the first 2-3 weeks after birth. While it is evident that the loss of the excess nerve terminals depends to some extent on neuromuscular activity, the mechanism involved is not known. In the present experiments neonatal rat soleus muscles were stimulated in vitro in the presence of a variety of combinations of calcium, the cholinesterase inhibitor edrophonium and the proteolytic enzyme inhibitors leupeptin, pepstatin and Ep-475. Electron microscopical examination revealed that stimulation alone had little effect on the morphology of the end-plate region but stimulation in the presence of raised levels of calcium caused severe disruption of the nerve terminals and a marked reduction in the number of intact nerve terminal profiles contacting each end-plate. Contraction measurements showed that, in spite of this, the muscles were not functionally denervated to any large extent. The addition of edrophonium potentiated the morphological alterations but caused no further reduction in the number of profiles. Conversely, the protease inhibitors wholly or partially (in the case of Ep-475) prevented the effects of stimulation and calcium on the nerve terminals. These results are consistent with the idea that neuromuscular activity induces the secretion of proteolytic enzymes into the end-plate region, where they digest the immature nerve terminals. The importance of calcium suggests that the calcium-dependent neutral protease may be involved, and is also consistent with a secretory mechanism. The possibility that the nerve terminals are digested by their own proteases is also discussed.

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.

A quantitative comparison of the formation of synapses in the rat superior cervical sympathetic ganglion by its own and by foreign nerve fibres.

The rat superior cervical sympathetic ganglion (SCG) has about 36,000 neurones in a volume of about 1 cu.mm. There are about 8.8 X 10(6) synapses, and 6000-9000 preganglionic axons. Section of the preganglionic chain causes a loss of 93% of the synapses. In the denervated SCG there are 0.6 X 10(6) remaining ('intrinsic') synapses, and a proportion of the synaptic sites are identifiable as vacated synaptic thickenings (3 X 10(6) per SCG, as compared with 0.5 X 10(6) in the normal intact SCG). After deducting the intrinsic synapses, this indicates that each preganglionic axon forms about 1100 (900-1400) synapses. After freezing the preganglionic chain, subsequent axonal regeneration restores synapse numbers to 85% of normal (7.5 X 10(6) synapses per SCG). After anastomotic repair by suture of the cut ends of the preganglionic chain (a necessary control for the foreign nerve anastomoses), the SCG contains only 60% of the normal complement of synapses (5.2 X 10(6) synapses per SCG). The results of this anastomosis are very variable. However, in individual ganglia the numbers of synapses are directly correlated with the numbers of axons which reach the SCG. After deducting the intrinsic synapses it can be calculated that each axon forms about 700 synapses. This is probably an underestimation of the numbers which would be achieved at longer survival times. After anastomosis of the vagal nerve into the denervated SCG there are about 4.4 X 10(6) synapses per SCG. Morphologically the majority have axon terminals with large dense cored vesicles, and it is likely that these belong to the axons of the parasympathetic preganglionic neurones in the dorsal motor nucleus of the vagus. A smaller population of axon terminals are devoid of large dense cored vesicles; their origin is unknown. The dorsal motor nucleus of the vagus has between 1000 and 2000 neurones. After deducting the intrinsic synapses, this indicates that each axon may form up to 1900-3800 synapses. To the extent that other, unidentified vagal fibres also contribute to the synapses found after this anastomosis, this figure is an overestimate. After anastomosis of the hypoglossal nerve into the denervated SCG, there are 1.5 X 10(6) synapses per SCG. A morphologically distinctive type of axon terminal is found, and it is argued that this may belong to a special category of skeletomotor neurones located in the caudoventral part of the hypoglossal nucleus and distinguished by pseudocholinesterase staining. There are about 600 of these neurones, which would indicate that they form about 1500 synapses per axon (after deducting the numbers of intrinsic synapses). The majority of the hypoglossal neurones do not form intraganglionic synapses; this suggests that although the possession of a cholinergic mechanism may be necessary for axons to be able to form ganglionic synapses, it is not in itself sufficient. For each of the types of anastomosis, the numbers of vacated thickenings are inversely proportional to the numbers of synapses...