Role of peripheral innervation in p-chloroamphetamine-induced ejaculation in anesthetized rats.

The occurrence of ejaculation, which consists of 2 distinct phases (emission and expulsion), requires a tight coordination of peripheral autonomic and somatic nerves. However, some aspects of the mechanism of ejaculation are not clearly defined. To clarify this issue, we used the p-chloroamphetamine (PCA)-induced ejaculation model in anesthetized rats and investigated the effects of selective peripheral nerves lesions on seminal vesicle and bulbospongiosus (BS) muscle activities as representing physiological markers of emission and expulsion phases, respectively. In intact rats, ejaculation induced with PCA (intraperitoneal 5 mg/kg) correlated with coordinated increases in seminal vesicle pressure (SVP) and BS electromyographic activity. PCA-induced ejaculation was still observed in rats with bilateral lesion of hypogastric nerves (HNx), lumbar paravertebral sympathetic chain (LSCx), or dorsal nerves of the penis (DNPx). Conversely, bilateral section of pelvic nerves (PNx) or L6-S1 dorsal roots (DRx) abolished PCA-induced ejaculation. The amplitude of SVP increases induced by PCA was reduced in PNx, HNx, and LSCx rats, whereas it was unchanged in DRx and DNPx rats. The time interval between SVP increases and BS muscle contractions induced by PCA was comparable in the different neural lesion groups. In conclusion, PCA initiates both emission and expulsion independently from each other. In this model, afferents conveyed by the pelvic nerves appear to be unnecessary for occurrence of BS muscle contractions but are essential for a complete ejaculatory response.

Chronic corticosterone manipulations in mice affect brain cell proliferation rates, but only partly affect BDNF protein levels.

We investigated whether the effects of corticosterone (CORT) on brain cell proliferation are mediated via its detrimental effect on brain-derived neurotrophic factor (BDNF). Using a [3H]thymidine tracer study, it was demonstrated that the cell proliferation rate in the neurogenic hippocampus and subventricular zone was increased in placebo-treated adrenalectomized (ADX) mice with low plasma corticosterone levels when compared with chronically CORT-treated ADX animals (25mg or 100mg sustained-release pellet). The cell proliferation rate of SHAM animals was in between the ADX-placebo group and ADX CORT-treated groups. BDNF protein contents in the hippocampus and subventricular zone were not different between the SHAM group and ADX-placebo group, although BDNF contents were decreased in the chronically CORT-treated ADX animals. Thus, other factors besides BDNF are involved in mediating CORT-induced changes in cell proliferation. Further, CORT manipulations did not affect caspase-3-like activity in any of the brain regions investigated, suggesting that caspase-3 is not involved in possible CORT-induced cellular losses.