Optogenetic Stimulation of Novel Tph2-Cre Rats Advances Insight into Serotonin’s Role in Locomotion, Reinforcement, and Compulsivity

Serotonin critically modulates the activity of many brain networks, including circuits that control motivation and responses to rewarding and aversive stimuli. Furthermore, the serotonin system is targeted by first-line pharmacological treatments for several psychiatric disorders, including obsessive–compulsive disorder. However, understanding the behavioral function of serotonin is hampered by methodological limitations: the (brainstem) location of serotonergic neuron cell-bodies is difficult to access, their innervation of the brain is diffuse, and they release serotonin in relatively low concentrations. Here, we advance this effort by developing novel Tph2-Cre rats, which we utilized to study serotonin in the context of motor, compulsive, and reinforced behaviors using optogenetics in both male and female rats. Specificity and sensitivity of Cre recombinase expression and Cre-dependent processes were validated immunohistochemically, and optogenetic induction of in vivo serotonin release was validated with fast-scan cyclic voltammetry. Optogenetic stimulation of serotonin neurons in the dorsal raphe nucleus did not initiate locomotion or alter aversion-induced locomotion, nor did it elicit (real-time) place preference, and it had no measurable effect on compulsive behavior in the schedule-induced polydipsia task. In contrast, this optogenetic stimulation moderately sustained ongoing spontaneous locomotion and robustly reinforced operant lever pressing for self-stimulation of serotonin neurons, which was exacerbated by food restriction. Together, this work both introduces a novel rat Cre line to study serotonin and advances our understanding of serotonin’s behavioral functions. Complementing previous findings, we find that brainwide serotonin release has an overall relatively mild effect on behavior, which manifested only in the absence of natural reinforcers and was modulated by physiological state.