Regulation of synaptic position, size, and strength in anuran skeletal muscle.

An analysis of the physiology, morphology, and position of endplates on identified fibers in the Xenopus laevis pectoralis muscle has revealed the following. 1. The percentage of fibers with one endplate is lower in large muscles, and within the same muscle, singly innervated fibers are smaller than dually innervated fibers. 2. Single junctions tend to be stronger than junctions on dually innervated fibers. 3. Single junctions typically are located near the middle of their fibers, while the endplates on dually innervated fibers are located toward either end and usually are separated by at least 20% of the total fiber length. A significant proportion of dually innervated fibers appears to be innervated by the same axon at both junctions. 4. Junctions on the same dually innervated fiber tend to be more similar in length than do junctions on different fibers of the same input resistance. This observation is the same whether both junctions on a given fiber are formed by the same or different axons. There is no corresponding tendency for greater similarity in physiological strength of paired junctions, which frequently show large differences in endplate potential amplitude. 5. The total terminal length on dually innervated fibers of equivalent input resistance is inversely correlated with the mean release per unit length and total release of both junctions. There is no apparent correlation between the distance separating endplates and their strength or length. The data support a model of synaptic regulation in which nerve terminals are attracted, grow, and are maintained in proportion to the amount of a substance supplied by muscle fibers. Our findings suggest that such a substance is produced or distributed uniformly throughout each fiber in amounts proportional to the fiber size and inversely proportional to the total transmitter output of all junctions innervating the fiber. A form of competitive interaction between the terminals which helps to determine synaptic spacing may involve local depletion or inactivation of this substance.