Noradrenergic cross-modular reciprocal inhibition within the locus coeruleus

Abstract

AbstractThe Locus Coeruleus (LC) is the primary noradrenergic nucleus in the brain with widespread projections driving changes in cognitive state and animal behaviour. The LC is composed of multiple “modules” with specific efferent target domains enabling discretional neuromodulation. LC neuronal activity releases noradrenaline within the nucleus as a local feedback mechanism, but it is not known how this influences modular output. We address this question using whole-cell recordings and calcium imaging in rat pontine slices in combination with LC neuronal ensemble modelling to assess the influence of local noradrenaline release on cross-modular interactions.Electrophysiological recordings of LC neurons from rats transduced with the optogenetic actuator ChR2 showed auto-inhibition and lateral inhibition (of surrounding non-transduced neurons). This inhibition was strongly frequency dependent and was mediated by noradrenaline acting on alpha2-adrenceptors (α2R). To allow calcium-imaging of LC neuronal ensembles a Canine-Adenoviral vector strategy was developed using the PRS promoter to drive selective expression GCaMP6s. Calcium imaging allowed resolution of both increases and decreases in LC activity (to TTX / clonidine or high potassium). Selective chemogenetic-activation of subsets of LC neurons (expressing the ionotropic actuator PSAM) revealed both a direct excitation (after application of PSEM308, 3-30µM) and an α2R-mediated inhibition of neighbouring LC cells (non-transduced). Differential retrograde targeting of PSAM or GCaMP6s to specific LC modules showed the presence of strong, reciprocal cross-modular inhibition (shown for the LC-olfactory bulb vs LC bulbospinal modules) and a subsequent rebound activity inversion.This represents a preferential, targeted, cross-modular, lateral inhibition within the LC rather than a non-specific surround inhibition. Computational modelling showed the emergence of lateral inhibition and biphasic responses to modular activation when α2R signalling and noradrenergic reuptake saturation were included. This interaction may facilitate recruitment of neuronal ensembles by coherent inputs and represents a bottom-up differential contrast-enhancement mechanism within the LC to produce a modality specific focus.