Abstract
The association between perceived stress and reproductive dysfunction is known, yet the underlying mechanisms remain incompletely determined. We previously demonstrated that RF-amide related peptide 3 (RFRP-3)-expressing neurons, putative inhibitors of the central regulation of fertility, are required for both acute restraint stress- and glucocorticoid-induced suppression of LH pulsatility in female mice. The present study complemented this by testing the role of RFRP neurons in the stress-induced suppression of the estrogen-induced preovulatory-like LH surge. We first established a reliable model of acute restraint stress in mice that stimulates glucocorticoid secretion, suppresses a late afternoon estrogen-induced LH surge, and inhibits corresponding kisspeptin neuronal activation in the anteroventral periventricular (AVPV) brain region. Two hours of restraint stress initiated 2-6 h prior to lights off met these criteria. We then ablated RFRP neurons in adult female mice by expressing a diphtheria toxin receptor specifically in these cells and exposing them to diphtheria toxin. RFRP-neuron-ablated and control mice that were ovariectomized and estrogen-treated were exposed to the acute, mid-afternoon restraint stress protocol and assessed for their peak LH concentrations several hours later at the expected time of the LH surge. Control mice exhibited stress-induced suppression of the LH surge, as expected, whereas RFRP-ablated mice did not. No differences in peak LH concentrations were observed between non-stressed controls and stressed RFRP-ablated mice. These data suggest that acute psychosocial stress occurring several hours prior to preovulatory LH surge induction invokes RFRP neuron-mediated blockade of the surge. The neural circuitry involved remains to be fully characterized.