A Novel Sympathoexcitatory Pathway between The Deep Superior Colliculus and The Rostral Ventromedial Medulla

The superior colliculus plays key roles in the immediate processing of threatening sensory stimuli and generates rapid behavioural responses that are critical for survival. We have previously found that disinhibition of the deep superior colliculus (dSC) unmasks coordinated respiratory, sympathetic and somatomotor outputs that are independent of processing in higher centres. We postulate that these effects are a result of direct innervation of autonomic and respiratory medullary neurons based on the results of neuroanatomical tracing studies that identified dSC synaptic contacts on spinally projecting neurons within the rostral ventromedial medulla (RVMM). In the present study we investigate the physiological significance of this relay and compare effects of dSC stimulation to activation of dSC‐RVMM terminals. Methods We used an AAV vector to express Channelrhodopsin2 (ChR2) in the dSC and chronically implanted a fibre optic cannula into the dSC. After transgene expression electrophysiology experiments were conducted under urethane anesthesia with rats instrumented to record blood pressure, diaphragmatic EMG and splanchnic sympathetic nerve activity (SNA). One subset of experiments then positioned the optrode in the RVMM to deliver light to the terminal projections from the dSC. For the other subset of experiments, extracellular recordings were made of spinally projecting RVMM neurons. Results dSC photoactivation evoked an increase in respiratory frequency (35±8.7%, P=<0.01, N=7) and heart rate (11±2.6 bpm, P=<0.01, N=7), and a modest change in blood pressure when compared to controls. Stimulus‐triggered averaging of SNA revealed short‐latency excitatory potentials in most cases. Photoactivation of ChR2‐expressing dSC‐RVMM terminals evoked similar effects on cardiorespiratory outputs as dSC stimulation, with an increase in respiratory frequency (14 ±9.2%, P<0.001, N=6) and blood pressure (13 ±2 mmHg P<0.01, N=7), as well as qualitatively similar sympathoexcitation. In preliminary experiments that recorded extracellular action potentials in bulbospinal RVMM neurons we recorded excitatory effects of dSC stimulation in 6/8 spontaneously active neurons. Conclusion We conclude that optogenetic activation of dSC neurons that project to the RVMM can drive cardiorespiratory effects that are consistent with our previous findings and that dSC stimulation evokes excitatory effects in some RVMM bulbospinal neurons. This confirms our hypothesis of the existence of a previously uncharacterized excitatory pathway between the dSC and RVMM. Ongoing experiments will functionally characterize RVMM neurons that receive dSC input. This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal .