Estrous cycle-dependent modulation of sexual receptivity in female mice by estrogen receptor beta-expressing cells in the dorsal raphe nucleus

The sexual receptivity of female mice, shown as lordosis response, is mainly regulated by estradiol action on estrogen receptor alpha (ERα) and beta (ERβ), depending on the day of the estrous cycle. Previous studies revealed that ERα in the ventromedial nucleus of the hypothalamus (VMH) plays an essential role in the induction of lordosis on the day of estrus (Day 1). However, the mechanisms of the transition to non-receptive states on the day after estrus (Day 2) are not completely understood. In the present study, we investigated the possible role of ERβ, which is highly expressed in the dorsal raphe nucleus (DRN), in lordosis expression. We found that ERβ-Cre female mice, which were ovariectomized and primed with estradiol and progesterone to mimic the estrous cycle, showed high levels of lordosis on Day 2 when ERβ-expressing DRN (DRN-ERβ+) neuronal activity was chemogenetically suppressed. This finding suggests that excitation of DRN-ERβ+ neurons is necessary for the decline of lordosis on Day 2. Fiber photometry recordings during female-male behavioral interactions revealed that DRN-ERβ+ neuronal activation in response to male intromission was significantly more prolonged on Day 2 compared to Day 1. Chemogenetic over-stimulation of DRN-ERβ+ neurons induced c-Fos expression in brain areas known to be inhibitory for lordosis expression, even though they did not express anterogradely labeled fibers of DRN-ERβ+ cells. These findings collectively suggest that DRN-ERβ+ neuronal excitation serves as an inhibitory modulator and is responsible for the decline in receptivity during non-estrus phases. Significance Statement In females, switching from a sexually receptive state to a non-receptive phase during the estrous cycle is essential for effective behavioral interactions with males and successful reproduction. Here, we delineate the possible brain regions that regulate the decline in receptive behavioral responses, such as lordosis, from those shown on the day of estrus to those on the day after estrus. We found that excitation of neurons expressing estrogen receptor (ER) β in the midbrain dorsal raphe nucleus is crucial for the suppression of lordosis during the day after estrus. This is contrasted with the facilitatory action of ERα, another type of ER, and provides new insights for understanding the neural basis of the adaptive expression of female reproductive behavior.