Motor, somatosensory, and executive cortical areas directly modulate firing activity in the auditory midbrain

Abstract

AbstractWe have recently reported that the central nucleus of the inferior colliculus (the auditory midbrain) is innervated by glutamatergic pyramidal cells originating not only in auditory cortex (AC) but also in multiple ‘non-auditory’ regions of the cerebral cortex. Using optogenetics and electrical stimulation, we investigated the functional properties of these descending connections in vivo in anaesthetised rats. A retrograde virus encoding green fluorescent protein (GFP) and channelrhodopsin (ChR2) injected into the central nucleus of the inferior colliculus (ICC), labelled discrete groups of cells in multiple areas of the cerebral cortex. Light stimulation of AC and M1 caused local activation of cortical neurones and increased the firing rate of neurones in ICc indicating a direct excitatory input from AC and M1 to ICC. Electrical stimulation of M1, secondary motor, somatosensory and prefrontal cortical regions evoked short, fixed latency firing events in ICC as well as longer latency, longer duration increases in firing activity. The short latency events were singular spikes of consistent shape and size likely resulting from monosynaptic excitation of individual ICC units. The longer latency responses comprised multiple units and spikes occurred with significant temporal jitter suggesting polysynaptic activation of local circuits within the ICC. The probability of the monosynaptic event, the magnitude of the polysynaptic response, and the area of ICC affected were dependent on the stimulus current. Our data are consistent with cortical regions exerting an important excitatory direct and indirect regulation of ICc neurones.Significance statementWe have recently described inputs from motor, somatosensory, and executive cortices to the inferior colliculus (IC, auditory midbrain). Here we provide functional evidence for such connections. Optogenetics, using a retrograde virus encoding channelrhodopsin injected into IC revealed a direct excitatory influence of neurones in auditory and motor cortices on firing in IC. Electrical stimulation of discrete cortical regions revealed that multiple non-auditory cortical regions have a direct monosynaptic excitatory influence on neurones in the IC which, in turn, activates local circuits increasing the firing probability of multiple neurones in the IC. This is the first evidence for circuitry by which auditory processing can be influenced at an early stage by activity in the sensory, motor and executive domains.