The ability to discriminate competing external stimuli and initiate contextually appropriate behaviours is a key brain function. Neurons in the deep superior colliculus (dSC) integrate multisensory inputs and activate descending projections to premotor pathways responsible for orienting, attention and defence, behaviours which involve adjustments to respiratory and cardiovascular parameters. However, the neural pathways that subserve the physiological components of orienting are poorly understood. We report that orienting responses to optogenetic dSC stimulation are accompanied by short‐latency autonomic, respiratory and electroencephalographic effects in awake rats, closely mimicking those evoked by naturalistic alerting stimuli. Physiological responses were not accompanied by detectable aversion or fear, and persisted under urethane anaesthesia, indicating independence from emotional stress. Anterograde and trans‐synaptic viral tracing identified a monosynaptic pathway that links the dSC to spinally projecting neurons in the medullary gigantocellular reticular nucleus (GiA), a key hub for the coordination of orienting and locomotor behaviours. In urethane‐anaesthetized animals, sympathoexcitatory and cardiovascular, but not respiratory, responses to dSC stimulation were replicated by optogenetic stimulation of the dSC–GiA terminals, suggesting a likely role for this pathway in mediating the autonomic components of dSC‐mediated responses. Similarly, extracellular recordings from putative GiA sympathetic premotor neurons confirmed short‐latency excitatory inputs from the dSC. This pathway represents a likely substrate for autonomic components of orienting responses that are mediated by dSC neurons and suggests a mechanism through which physiological and motor components of orienting behaviours may be integrated without the involvement of higher centres that mediate affective components of defensive responses. Key points Neurons in the deep superior colliculus (dSC) integrate multimodal sensory signals to elicit context‐dependent innate behaviours that are accompanied by stereotypical cardiovascular and respiratory activities. The pathways responsible for mediating the physiological components of colliculus‐mediated orienting behaviours are unknown. We show that optogenetic dSC stimulation evokes transient orienting, respiratory and autonomic effects in awake rats which persist under urethane anaesthesia. Anterograde tracing from the dSC identified projections to spinally projecting neurons in the medullary gigantocellular reticular nucleus (GiA). Stimulation of this pathway recapitulated autonomic effects evoked by stimulation of dSC neurons. Electrophysiological recordings from putative GiA sympathetic premotor neurons confirmed short latency excitatory input from dSC neurons. This disynaptic dSC–GiA–spinal sympathoexcitatory pathway may underlie autonomic adjustments to salient environmental cues independent of input from higher centres.
The ability to discriminate competing, ecologically relevant stimuli, and initiate contextually appropriate behaviors, is a key brain function. Neurons in the deep superior colliculus (dSC) integrate multisensory inputs and activate descending projections to premotor pathways responsible for orienting and attention, which often involve adjustments to respiratory and cardiovascular parameters. However, the neural pathways that subserve physiological components of orienting are poorly understood. We report that orienting responses to optogenetic dSC stimulation are accompanied by short-latency autonomic, respiratory and electroencephalographic effects in conscious rats, closely mimicking those evoked by naturalistic alerting stimuli. Physiological responses occurred in the absence of detectable aversion or fear and persisted under urethane anesthesia, indicating independence from emotional stress. Moreover, autonomic responses were replicated by selective stimulation of dSC inputs to the medullary reticular formation, a major target of dSC motor efferents, This disynaptic pathway represent a likely substrate for autonomic components of orienting.
The superior colliculus (SC) is a sensory integration hub in the dorsal brainstem where multimodal information is combined and, depending on the saliency of the competing sensory inputs, appropriate motor commands and supportive autonomic changes initiated. In rodents, the SC is indispensable for initiating behavioral responses to stereotypical visual stimuli that resemble approaching objects, such as looming (an expanding overhead black circle). Here we report that presentation of overhead looming or naturalistic stimuli drove acute surges in blood pressure in telemetered conscious rats, an effect that was replicated by optogenetic stimulation of the deep SC (dSC). dSC stimulation also evoked increases in respiratory rate and tail vasoconstriction in the absence of detectable anxiety‐like behaviors and continued to exert excitatory effects on heart rate, respiratory rate, and sympathetic nerve activity under urethane anesthesia. The objective of the current study was to identify the central pathways responsible for mediating these physiological effects. Anterograde labeling of dSC neurons revealed a previously uncharacterized axonal projections to brainstem cell groups associated with arousal and autonomic control, including the locus coeruleus, A5 group and, most extensively, neurons within a region that spanned the medullary gigantocellular and raphe cell groups, collectively called the rostral ventromedial medulla (RVMM). Optogenetic stimulation of dSC terminals within the RVMM recapitulated some of the sympathetic and respiratory effects evoked by dSC stimulation, and optogenetic dSC activation evoked powerful excitatory effects on extracellular recordings of putative RVMM sympathetic premotor neurons, suggesting that elements of the physiological response dSC stimulation are mediated by direct activation of medullary autonomic neurons. To investigate the contribution of environmental stimuli to the excitability of this pathway we conducted single‐unit recordings of SC neuronal responses to visual and acoustic stimuli using high‐density silicon probes. In addition to responding to stereotypical audio‐visual looming stimuli, we report the presence of SC neurons with higher‐order visual capabilities relating to object detection that differ by subregion and are several orders of magnitude more complex than previously recognized. These tuning properties were also found in subpopulations of opto‐tagged SC neurons that project to the RVMM. Our data suggest that the SC is not only capable of nuanced object recognition, but can translate naturalistic visual cues into fast‐acting autonomic changes via direct medullary projections Support or Funding Information Research was supported by the NHMRC and Hillcrest Foundation
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