After mating, the physiology of Drosophila females undergo several important changes, some of which are reflected in their rest-activity cycles. To explore the hypothesis that mating modifies the temporal organization of locomotor activity patterns, we recorded fly activity by a video tracking method. Monitoring rest-activity patterns under light/dark (LD) cycles indicated that mated females lose their ability to anticipate the night-day transition, in stark contrast to males and virgins. This postmating response is mediated by the activation of the sex peptide receptor (SPR) mainly on pickpocket (ppk) expressing neurons, since reducing expression of this receptor in these neurons restores the ability to anticipate the LD transition in mated females. Furthermore, we provide evidence of connectivity between ppk+ neurons and the pigment-dispersing factor (PDF)-positive ventral lateral neurons (sLNv), which play a central role in the temporal organization of daily activity. Since PDF has been associated to the generation of the morning activity peak, we hypothesized that the mating signal could modulate PDF levels. Indeed, we confirm that mated females have reduced PDF levels at the dorsal protocerebrum; moreover, SPR downregulation in ppk+ neurons mimics PDF levels observed in males. In sum, our results are consistent with a model whereby mating-triggered signals reach clock neurons in the fly central nervous system to modulate the temporal organization of circadian behavior according to the needs of the new status.
After mating, the physiology of Drosophila females undergoes several important changes, some of which are reflected in their rest-activity cycles. To explore the hypothesis that mating modifies the temporal organization of locomotor activity patterns, we recorded the fly activity by a video tracking method. Monitoring rest-activity patterns under light/dark (LD) cycles indicated that mated females lose their ability to anticipate the night-day transition, in stark contrast to males and virgins; this postmating response is mediated by the sex peptide (SP) acting mainly on pickpocket (ppk) expressing neurons, since reducing expression of the SP receptor (SPR) in these neurons restores the ability to anticipate the LD transition in mated females. We further provide evidence of connectivity between PPK+ neurons and the pigment-dispersing factor (PDF)-positive ventral lateral neurons (sLNv), which play a central role in the temporal organization of daily activity. Since PDF has been associated to the generation of the morning activity peak, we hypothesized that the mating signal could modulate PDF levels. Indeed, mated females have reduced PDF levels at the dorsal protocerebrum; moreover, SPR downregulation in PPK+ neurons mimics PDF levels observed in males. In sum, our results are consistent with a model whereby mating-triggered signals reaches clock neurons in the fly central nervous system to modulate the temporal organization of circadian behavior according to the needs of the new status.Author SummaryAfter mating, Drosophila females undergoes striking behavioral changes, specially in their activity patterns. Despite some of the circuits that deliver mating signals to the female brain are known the connection with the circadian network has not been explored in detail. Here, we show that mating changes the onset of daily activity, masking a central function of the clock. This modulation is mediated by the sex peptide (transferred during courtship) acting on PPK+ neurons, which, in turn, directly contact PDF+ neurons, responsible for the increase of the activity that precedes dawn. Thus, our work identifies a postmating response directly related to the circadian clock, and begins to unravel the underlying neuronal circuit.
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