Convergence of central respiratory and locomotor rhythms onto single neurons of the lateral reticular nucleus

We have analyzed the behavior of neurons of the lateral reticular nucleus (LRN) during fictive respiration and locomotion and found that some LRN neurons have both central respiratory and locomotor rhythms. Experiments were conducted on decerebrate, decerebellate, immobilized, and artificially ventilated cats, with the spinal cord transected at the lower thoracic cord. Fictive respiration and fictive forelimb locomotion were ascertained by monitoring activities from the phrenic nerve and forelimb extensor and flexor nerves, respectively. Fictive locomotion was evoked by electrical stimulation of the mesencephalic locomotor region (MLR) or sometimes occurred spontaneously. During fictive locomotion many LRN neurons fired in certain phases of the locomotion cycle; i.e., with respect to the nerve discharge of the ipsilateral forelimb they fired in either the extensor, flexor, extensor-flexor, or flexor-extensor phase. Firing of some LRN neurons was modulated synchronously with central respiratory rhythm. Neurons with inspiratory activity and those with expiratory activity were both found. More than half of these respiration-related LRN neurons had locomotor rhythm as well. The majority of the three types of LRN neurons, i.e., neurons with only locomotor rhythm, those with only respiratory rhythm, and those with both respiratory and locomotor rhythms, were antidromically activated by electrical stimulation of the ipsilateral inferior cerebellar peduncle. Electrical stimulation of the upper cervical cord showed that these LRN neurons, not only locomotion-related but also respiration-related neurons, received short latency inputs from the spinal cord. The LRN neurons studied were distributed widely in the LRN, relatively densely in the caudal two-thirds of the nucleus. No particular differences were detected between the three types of LRN neurons with respect to their location in the nucleus. These results indicate that the information about central respiratory and locomotor rhythms that is necessary for cerebellar control of the coordination between respiration and locomotion converges, at least partly, at the level of the LRN.