Synaptic competition during the reformation of a neuromuscular map.

We have been studying the mechanisms whereby pools of motor neurons establish a rostrocaudal bias in the position of their synapses in some skeletal muscles. The serratus anterior (SA) muscle of the rat displays a rostrocaudal topographic map before birth, and the topography is re-established after denervation. In this report, we explore the potential role of synaptic competition between innervating axons as a means of generating topographic specificity. We followed the progress of the reformation of this map in neonatal animals under conditions that enhanced the likelihood of observing synaptic competition. This was accomplished by forcing caudal axons to regenerate ahead of rostral axons onto a surgically reduced SA muscle. In this way, caudal (C7) motor neurons had unopposed access to vacated synaptic sites on the remaining rostral half of the SA before the return of the rostral (C6) axons. Intracellular recording revealed that 2 d after the second denervation, most of the reinnervated end plates contained only axons from the C7 branch; the remaining reinnervated end plates received input from C6 only or were multiply innervated by C6 and C7 axons. After 6 d, the pattern was reversed, with most end plates innervated exclusively by C6. After 17 d, axons from C6 were the sole input to reinnervated end plates. During the transition from C7- to C6-dominated input, at end plates coinnervated by C6 and C7 axons, the average quantal content from C6 was the same as that from C7; after 7 d, the quantal content of C6 was greater than that of C7. We have thus developed an experimental situation in which the outcome of synaptic competition is predictable and can be influenced by the positional labels associated with axons from different levels in the spinal cord.