Transplantation of whole ganglia was used to study the regeneration of four of the neurons that innervate the superficial flexor muscles of the crayfish Procambarus clarkii. The isolated ganglia containing the somas of these neurons were successfully transplanted from one crayfish to another. Reinnervation proceeded across the muscle surface and by 8 to 10 weeks connections were detected across the entire target field. At different time periods after the transplant, junction potentials (JPs) produced in phase with spontaneous neuronal spikes were recorded. The distribution of JP sizes and their decay times were examined. JPs from transplanted preparations were smaller than JPs from control or normal regeneration animals. These JPs also failed to facilitate when stimulated at 1 and 10 Hz. These are normal characteristics of immature terminals, but in the transplant preparations, once established, they remained stable for the duration of the study. Thus, synaptogenesis appears to be arrested at a stage before synaptic efficacy is established in the allotransplants. In addition, connectivity maps were plotted for each axon over the muscle surface. Some muscle fibers did not receive any contacts, and overall innervation leveled off at around 60% of the muscle fibers, remaining stable for the duration of this study. Despite the incomplete physiological innervation, however, three of the four neurons showed the same medial/lateral preferences observed in control animals, regenerating their original patterns of connectivity across the muscle surface.
The superficial flexor muscle of the crayfish is a neuromuscular system in which the neurons form position-dependent connectivity patterns with the muscle fibers. This system could be formed with the help of a single medial-to-lateral gradient during development that embodies positional information. To test this gradient hypothesis we changed the nerve's normal medial entry point into the muscle by transplanting it to the middle of the muscle sheet. When all the muscle fibers were present in the target area, most of the neurons studied passed through a stage during regeneration in which they showed preference for either medial or lateral synapse formation. Those neurons that in normal animals innervated preferentially the medial fibers showed a medial preference for new contacts; the neuron that normally innervated the lateral fibers showed a lateral preference for new contacts; the neuron that normally innervated everywhere regenerated equally well into both medial and lateral fibers. Therefore, these neurons are able to detect information regarding their position within the muscle mass and respond to it by preferential synapse formation. The effect of a positional gradient could not be detected when half of the target field was removed prior to regeneration. In this instance, the neuron that innervated the missing target area now regenerated to almost all the available fibers. It is suggested that the interplay of positional cues with other factors at different points in time could determine the final connectivity patterns formed by these cells.
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