Regular theta-firing neurons in the nucleus incertus during sustained hippocampal activation

This paper describes the existence of theta‐coupled neuronal activity in the nucleus incertus (NI). Theta rhythm is relevant for cognitive processes such as spatial navigation and memory processing, and can be recorded in a number of structures related to the hippocampal activation including the NI. Strong evidence supports the role of this tegmental nucleus in neural circuits integrating behavioural activation with the hippocampal theta rhythm. Theta oscillations have been recorded in the local field potential of the NI, highly coupled to the hippocampal waves, although no rhythmical activity has been reported in neurons of this nucleus. The present work analyses the neuronal activity in the NI in conditions leading to sustained hippocampal theta in the urethane‐anaesthetised rat, in order to test whether such activation elicits a differential firing pattern. Wavelet analysis has been used to better define the neuronal activity already described in the nucleus, i.e., non‐rhythmical neurons firing at theta frequency (type I neurons) and fast‐firing rhythmical neurons (type II). However, the most remarkable finding was that sustained stimulation activated regular‐theta neurons (type III), which were almost silent in baseline conditions and have not previously been reported. Thus, we describe the electrophysiological properties of type III neurons, focusing on their coupling to the hippocampal theta. Their spike rate, regularity and phase locking to the oscillations increased at the beginning of the stimulation, suggesting a role in the activation or reset of the oscillation. Further research is needed to address the specific contribution of these neurons to the entire circuit. A new neuronal population of the nucleus incertus is described as a possible origin of a theta oscillator synchronized to the hippocampus. Silent neurons in the nucleus incertus acquire regular theta firing under sustained hippocampal activation. These neurons present maximal phase coupling to the hippocampal theta rhythm at the beggining of the oscillations.