Novel cellular phenotypes and subcellular sites for androgen action in the forebrain.

Historically, morphological studies of the distribution of androgen receptors in the brain led to conclusions that the major regional targets of androgen action are involved in reproduction, that the primary cellular targets are neurons, and that functional androgen receptors are exclusively nuclear, consistent with the classical view of steroid receptors as ligand-dependent transcription factors. In this review, we discuss three separate but interrelated recent studies highlighting observations made with newer methodologies while assessing the regional, cellular or subcellular distribution of androgen receptors containing cells in the forebrain. Regional studies demonstrated that the largest forebrain target for androgen action in terms of the number of androgen receptor expressing cells is the cerebral cortex, rather than the main hypothalamic and limbic centers for reproductive function. Cellular studies to determine the phenotype of androgen receptor expressing cells confirmed that most of these cells are neurons but also revealed that small subpopulations are astrocytes. The expression of androgen receptors in astrocytes is both region and age dependent. In contrast, reactive astrocytes in the lesioned adult rat brain do not express androgen receptors whereas reactive microglia do. Finally, androgen receptor immunoreactive axons were identified in the cerebral cortex of the rat and human. These observations do not overturn classical views of the cellular and subcellular locus of steroid action in the nervous system, but rather broaden our view of the potential direct impact of gonadal steroid hormones on cellular function and emphasize the regional and developmental specificity of these effects on the nervous system.

Androgen receptor expression in the developing male and female rat visual and prefrontal cortex.

Gonadal steroid hormones are known to influence the development of the cerebral cortex of mammals. Steroid hormone action involves hormone binding to cytoplasmic or nuclear receptors, followed by DNA binding and gene transcription. The goals of the present study were twofold: to determine whether androgen receptors are present during development in two known androgen sensitive regions of the rat cerebral cortex, the primary visual cortex (Oc1) and the anterior cingulate/frontal cortex (Cg1/Fr2); and to determine whether androgen receptor (AR) expression in these regions differs between developing males and females. We used immunocytochemistry to detect AR protein on postnatal days 0, 4, and 10, and in situ hybridization to detect AR mRNA on postnatal day 10 in male and female rats. The level of AR expression was specific to the cortical region, with higher AR immunoreactive cell density and more AR mRNA in Oc1 than in Cg1/Fr2. AR immunoreactive cell density increased with age in both regions. Finally, on postnatal day 10, males had a higher AR immunoreactive cell density and more AR mRNA in Oc1 than did females. Thus, the presence of ARs may allow androgens to directly influence the development the cerebral cortex.

Detection of retrogradely transported WGA-HRP in axotomized adult hamster facial motoneurons occurs after initiation of the axon reaction.

We have previously shown that facial nerve transection at the stylomastoid foramen activates ribosomal RNA transcription in injured facial motoneurons (FMN) of the adult hamster within 30 minutes postoperative. The signal for the initiation of the nerve cell body response to injury in vertebrates is currently unknown. It has been hypothesized that the signal for initiating the injury response is dependent on retrograde transport, where the signal itself is either the loss of a repressor substance from the periphery or the loss of retrogradely transported target-derived factors. To examine if a retrograde transport-mediated signal would be sufficient to produce the rapid ribosomal effects observed in hamster FMN following injury, adult hamsters were subjected to right facial nerve axotomies, with the neuronal tracer wheat germ agglutinin horseradish peroxidase (WGA-HRP; M.W. 80,000) applied at the proximal stump of the transected nerve. At time points ranging from 0.5 to 24 hours postoperative (hpo), the animals were killed and brainstem sections containing bilateral facial nuclei processed for WGA-HRP label using the TMB method. The earliest time point at which WGA-HRP was detected in the axotomized facial nucleus occurred at 3 hpo. To eliminate molecular weight as a confounding factor, an additional retrograde transport study was performed using the smaller tracer, Fluoro-Gold (M.W. 532.59). Fluoro-Gold was not detected until well after the 3 hpo time point. Thus, it appears that initiation of the axon reaction in hamster FMN is likely to be independent of the retrograde transport properties of the injured neuron.

Exacerbation of facial motoneuron loss after facial nerve transection in severe combined immunodeficient (scid) mice.

The immune system functions to protect an organism against microbial infections and may be involved in the reparative response to nerve injury. The goal of this study was to determine whether the immune system plays a role in regulating motoneuron survival after a peripheral nerve injury. After a right facial nerve axotomy, facial motoneuron (FMN) survival in C.B-17 (+/+) wild-type mice was found to be 87 +/- 3.0% of the unaxotomized left side control. In contrast, facial nerve axotomy in C.B-17 (-/-) severe combined immunodeficient (scid) mice, lacking functional T and B lymphocytes, resulted in an average FMN survival of 55 +/- 3.5% relative to the unaxotomized left side control. This represented an approximately 40% decrease in FMN survival compared with wild-type controls. The reconstitution of scid mice with wild-type splenocytes containing T and B lymphocytes restored FMN survival in these mice to the level of the wild-type controls. These results suggest that immune cells associated with acquired immunity play a role in regulating motoneuron survival after a peripheral nerve injury.