MONOSYNAPTIC CONNECTIONS MEDIATE RESISTANCE REFLEX IN CRAYFISH (PROCAMBARUS-CLARKII) WALKING LEGS

In crustacean walking legs, the coxo-basipodite chordotonal organ (CB) composed of about 50 sensory cells, evokes a resistance reflex in the levator (Lev) and depressor (Dep) muscles responsible for the movements of the coxo-basipodite joint where it is located. Mechanical stimulation of the CB strand and electrical stimulation of its sensory nerve have been performed along with systematic intracellular recordings from CB terminals (CB T) and levator (Lev) or depressor (Dep) motoneurons (MNs) in order to study their connections. Measurements of conduction times in the CB nerve demonstrated different pools of sensory fibres, the fastest of which reach the ganglion in 2.5 ms. During imposed movements to the CB strand, intracellularly recorder Lev or Dep MN display EPSPs that are correlated to spikes in the CB nerve, their delays are incompatible with a polysynaptic pathway. Systematic stimulation of the CB nerve demonstrates that about 4 to 8 CB fibres are connected with each Lev or Dep MN. Classical tests for monosynaptic connections indicate that EPSPs occurring between 3 ms and 6 ms correspond mainly to monosynaptic connections with CB T, whereas IPSPs (the latencies of which are above 12 ms) are polysynaptic. In spite of the high selectivity of the CB T onto MNs, eight simultaneous intracellular recordings of coupled CB T and MN (out of more than 300 MNs penetrated) have allowed a direct measurement of synaptic delays (less than 1 ms). The functional significance of these results is discussed in relation to the proprioceptive control of locomotor movements.