New concepts of the neuroendocrine regulation of gonadotropin surges in rats

In species that ovulate spontaneously, two key events mediate the stimulation of preovulatory gonadotropin surges: 1) neurosecretion of a preovulatory LHRH surge and 2) an acute increase in responsiveness of the pituitary gland to the LHRH neurosecretory trigger. These processes, in turn, depend upon both the positive feedback actions of preovulatory estrogen secretions and specific neural signals for initiation of the surge. In female rats, the neural signals for the surge are principally derived from the 24-h neural clock, thereby limiting the timing of surges to the afternoon of proestrus. It remains unclear, however, how neural signals converge with endocrine signals (estrogen) in specific brain cells and how their cellular integration leads to appropriate secretion of gonadotropin surges. Previous work has suggested that estrogen may exert its facilitatory actions by opening a neural "gate," thereby allowing transmission of the daily neural signal to surge-initiating neuronal groups. How may estrogen act to render a neural pathway patent? A conventional view holds that steroid hormones can exert permissive effects on signaling efficacy by modulating neurotransmitter receptor expression, intracellular second messenger production, and protein kinase activity. However, recent evidence has suggested that estrogen may also have the capacity to permit cross-talk between neurotransmitter signaling pathways and parallel transcriptional regulatory pathways. The progesterone receptor is an estrogen-inducible transcription factor that has been shown to be transactivated--even in the absence of its cognate ligand--after stimulation of neurotransmitter receptors coupled to adenylate cyclase stimulation. Thus, the convergence of neural and endocrine signals for the stimulation of gonadotropin surges could occur at the level of the progesterone receptor: estrogen may stimulate expression of progesterone receptors, which in turn may be initially transactivated by synaptic signals. Activated progesterone receptors may thereafter regulate transcription of target genes that control transmitter synthesis and release in neural circuitries governing LHRH gene expression and/or pulsatile LHRH release. An analogous mechanism may operate in pituitary gonadotrophs, in which ligand-independent transactivation of progesterone receptors mediates integration of neurosecretory and estrogen positive feedback signals, leading to increased pituitary responsiveness to LHRH. It is propo