The roles of testicular nuclear receptor 4 (TR4) in male fertility-priapism and sexual behavior defects in TR4 knockout mice

Analyses of steroid receptors are important for understanding molecular details of transcriptional control, as well as providing insight as to how an individual transacting factor contributes to cell identity and function. These studies have led to the identification of a superfamily of regulatory proteins that include receptors for thyroid hormone and the vertebrate morphogen retinoic acid. Although animals employ complex and often distinct ways to control their physiology and development, the discovery of receptor-related molecules in a wide range of species suggests that mechanisms underlying morphogenesis and homeostasis may be more ubiquitous than previously expected.

Previously, it was shown that the lack of a functional estrogen receptor (ER) alpha gene (ERalpha) greatly affects reproduction-related behaviors in both female and male mice. However, widespread expression of a novel second ER gene, ERbeta, demanded that we examine the possible participation of ERbeta in regulation of these behaviors. In dramatic contrast to our results with ERalpha knockout (alphaERKO) males, betaERKO males performed at least as well as wild-type controls in sexual behavior tests. Moreover, not only did betaERKO males exhibit normal male-typical aggressive behavior, including offensive attacks, but they also showed higher levels of aggression than wild-type mice under certain conditions of social experience. These data revealed a significant interaction between genotype and social experience with respect to aggressive behavior. Finally, females lacking a functional beta isoform of the ER gene showed normal lordosis and courtship behaviors, extending in some cases beyond the day of behavioral estrus. These results highlight the importance of ERalpha for the normal expression of natural reproductive behaviors in both sexes and also provide a background for future studies evaluating ERbeta gene contributions to other, nonreproductive behaviors.

The molecular mechanism for priapism is not well characterized. Although the nitric oxide (NO) pathway is known to mediate penile erection under normal conditions, we hypothesized that the mechanism of priapism rests in aberrant downstream signaling of this pathway based on our previous findings that mice lacking the gene for endothelial nitric oxide synthase (eNOS-/-) and mice lacking both neuronal NOS (nNOS) and eNOS (nNOS-/-, eNOS-/-) have a tendency for priapic activity. We investigated the role of downstream guanylate cyclase and phosphodiesterase type 5 (PDE5A) expression and function in mediating these responses in eNOS-/- and nNOS-/-, eNOS-/- mice. Erectile responses to both cavernous nerve stimulation and intracavernosal injection of the NO donor diethylamine-NONOate were augmented in eNOS-/- and nNOS-/-, eNOS-/- mice but not in WT or nNOS-/- mice. PDE5A protein expression and activity and cGMP levels were significantly lower in eNOS-/- and nNOS-/-, eNOS-/- mice, and this effect was reproduced in WT corpus cavernosum exposed to NOS inhibitors. Moreover, cavernous nerve stimulation was associated with a marked augmentation of cavernosal cGMP levels, suggesting that, although lower at baseline, the production of cGMP is unchecked in eNOS-/- and nNOS-/-, eNOS-/- mice upon neurostimulation. Transfection of eNOS-/- mice with an adenovirus encoding eNOS resulted in a normalization of PDE5A protein and activity as well as a correction of priapic activity. Coupled with the observation that sickle cell disease mice (which show a priapism phenotype) evince dysregulated PDE5A expression/activity, these data suggest that PDE5A dysregulation is a fundamental mechanism for priapism.