The regulation of synaptogenesis during normal development and following activity blockade.

The mature neuromuscular junction is characterized by the tight spatial colocalization of synaptic vesicles and acetylcholine receptor (AChR) clusters. Although a large body of work exists on the interactions between motoneurons and myotubes leading to synaptogenesis in tissue culture, how the neuromuscular junction acquires its highly specialized structure in vivo is not well understood, particularly during the earliest period of synaptogenesis. In this study, the development of the neuromuscular synapse in chick hindlimb muscles was examined and quantified by simultaneously labeling the pre- and postsynaptic elements from the time the main nerve trunks leave the lumbosacral plexus region to enter the developing limb (St 24) through the end of the motoneuron cell death period (St 36). Based on these results, synaptogenesis can be divided into several distinct stages that are intimately connected to the innervation sequence described in a previous paper (Dahm and Landmesser, 1988). Briefly, as large nerve trunks approach the developing muscles and the first AChR clusters are induced to form on nearby myotubes, none of these initial receptor clusters are in direct contact with a nerve profile. The first appearance of nerve-contacted clusters (synapses) is coincident with the growth of large, unbranched nerve trunks into the muscles. The next step is initiated by the formation of small nerve side branches that grow out from the larger intramuscular nerve trunks to bring most axons and myotubes into contact for the first time. As side branches form, synapses appear around them, and non-nerve-contacted receptor clusters disappear from around the main intramuscular nerve trunks. The next step in synaptogenesis is the restriction of synaptic vesicle antigen to sites of synaptic contact. These early stages of synaptogenesis are also characterized by the growth of the presynaptic terminal to match the length of the postsynaptic receptor cluster. This study showed that AChR cluster formation during early in vivo neuromuscular development does not require close anatomical nerve contact, but that the presence of the nerves is necessary for AChR clusters to form. This suggests that the nerves normally induce AChR clustering via the release of a diffusible substance, a suggestion substantiated by the observation that AChR clusters do not form on aneural myotubes in vivo. In order to assess the role of synapse formation in the regulation of motoneuron number, synaptogenesis was quantitatively examined after chronic neuromuscular blockade, which prevents motoneuron cell death.(ABSTRACT TRUNCATED AT 400 WORDS)