A diapause program that anticipates harsh seasonal environments contributes to flexible seasonal adaptation of organisms. Many animals use the photoperiod as a cue for seasonal sensing, and a circadian clock system is suggested to be important for photoperiodic physiological regulation. Although brain regions that are important for photoperiodic responses have been reported, the detailed system linking the circadian clock to photoperiodic diapause switching remains unclear. Here, we show the circadian clock-based neural mechanism for diapause switching by the female insect Riptortus pedestris, which enters reproductive diapause. This study focused on the insect neuroendocrine center, pars lateralis (PL), and analyzed its role in the photoperiodic control of diapause. PL neurons mainly express two types of neuropeptides: corazonin or short neuropeptide F (sNPF). RNA interference (RNAi) has demonstrated the importance of these neuropeptides in controlling diapause. Corazonin is essential for diapause induction under short photoperiod, and sNPF contributes to the appropriate determination of diapause according to the photoperiod. Additionally, electrophysiological analyses revealed that PL peptidergic neurons photoperiodically changed their neural activity, switching from active to silent mode by diapause-averting long photoperiod. We demonstrated that positive and negative regulators of the circadian clock are reciprocally involved in switching of PL activity and diapause. RNAi of a positive regulator cycle activates PL activity and induces reproductive diapause under long photoperiod, whereas that of a negative regulator period silences PL activity and averts diapause under short photoperiod. Our findings highlight that PL peptidergic neurons mediate the circadian clock system and the photoperiodic control of diapause.
Keywords: circadian clock; corazonin; diapause; photoperiodism; short neuropeptide F.
Copyright © 2025 the authors.