Motoneuron responses to the inhibitory amino acids glycine and GABA, and the contribution of inhibitory synapses to developing sensorimotor synapses were studied in rat spinal cords during the last week in utero. In differentiating motoneurons, glycine and GABA induced Cl(-)-dependent membrane depolarizations and large decreases in membrane resistance. These responses gradually decreased during embryonic development, and at birth they were significantly smaller than in embryos. In motoneurons of embryos and neonates, dorsal root stimulation produced only depolarizing potentials, some of which reversed at -50 mV membrane potential. Reduction of extracellular Cl- concentrations increased the amplitude of these potentials, suggesting that they are generated by Cl- current. Contribution of Cl(-)-dependent potentials to compound dorsal root-evoked potentials was studied by determining the effects of glycine and GABA antagonists on them. In motoneurons of embryos at days 16-17 of gestation (D16-D17), strychnine or bicuculline blocked dorsal root-evoked potentials. This suppression was neither the result of a decrease in neuronal excitability nor the inhibition of glutamate receptors. Strychnine-evoked depression was not blocked by atropine, indicating that it was not due to disinhibition of muscarinic synapses. By D19, strychnine and bicuculline significantly increased dorsal root-evoked potentials rather than blocking them. This reversed function did not result from an increase in neuronal excitability or changes in the specificity of strychnine and bicuculline antagonism. The number of glycine- and GABA-immunoreactive cells increased 20% between D17 and D19. The number of immunoreactive cells and fibers significantly increased in the motor nuclei and dorsal horn laminae. These morphological changes may contribute to establishment of new synaptic contacts on motoneurons, thus changing the actions of strychnine and bicuculline on dorsal root-evoked potentials.