Androgen receptor immunoreactivity in the male and female Syrian hamster brain

To investigate potential mechanisms for sex differences in the physiologic response to androgens, the present study compared the hormonal regulation of intracellular androgen receptor partitioning and the distribution of androgen receptor immunoreactivity in select brain regions from male and female hamsters. Androgen receptors were visualized on coronal brain sections. Two weeks after castration, androgen receptor immunoreactivity filled the neuronal nuclei and cytoplasm in males and females. In gonad‐intact males and females, androgen receptor immunoreactivity was limited to the cell nucleus. Whereas exogenous dihydrotestosterone prevented cytoplasmic immunoreactivity, estrogen at physiologic levels did not. These results suggest that nuclear androgen receptor immunoreactivity in gonad‐intact females is maintained by endogenous androgens, and that androgens have the potential to influence neuronal activity in either sex. However, sex differences in the number and staining intensity of androgen‐responsive neurons were apparent in select brain regions. In the ventral premammillary nucleus, ventromedial nucleus of the hypothalamus, and medial amygdaloid nucleus, androgen receptor staining was similar in gonadectomized males and females. In the lateral septum, posteromedial bed nucleus of the stria terminalis (BNSTpm), and medial preoptic nucleus, the number of androgen receptor–immunoreactive neurons was significantly lower in females (p < .05). Moreover, the integrated optical density/cell in BNSTpm was significantly less in females (1.28 ± 0.3 units) than in males (2.21 ± 0.2 units; p < .05). These sex differences in the number and staining intensity of androgen‐responsive neurons may contribute to sex differences in the behavioral and neuroendocrine responses to androgens. © 1999 John Wiley & Sons, Inc. J Neurobiol 39: 359–370, 1999     

Androgen receptor immunoreactivity in the male and female Syrian hamster brain.

To investigate potential mechanisms for sex differences in the physiologic response to androgens, the present study compared the hormonal regulation of intracellular androgen receptor partitioning and the distribution of androgen receptor immunoreactivity in select brain regions from male and female hamsters. Androgen receptors were visualized on coronal brain sections. Two weeks after castration, androgen receptor immunoreactivity filled the neuronal nuclei and cytoplasm in males and females. In gonad-intact males and females, androgen receptor immunoreactivity was limited to the cell nucleus. Whereas exogenous dihydrotestosterone prevented cytoplasmic immunoreactivity, estrogen at physiologic levels did not. These results suggest that nuclear androgen receptor immunoreactivity in gonad-intact females is maintained by endogenous androgens, and that androgens have the potential to influence neuronal activity in either sex. However, sex differences in the number and staining intensity of androgen-responsive neurons were apparent in select brain regions. In the ventral premammillary nucleus, ventromedial nucleus of the hypothalamus, and medial amygdaloid nucleus, androgen receptor staining was similar in gonadectomized males and females. In the lateral septum, posteromedial bed nucleus of the stria terminalis (BNSTpm), and medial preoptic nucleus, the number of androgen receptor-immunoreactive neurons was significantly lower in females (p < .05). Moreover, the integrated optical density/cell in BNSTpm was significantly less in females (1.28+/-0.3 units) than in males (2.21+/-0.2 units; p < .05). These sex differences in the number and staining intensity of androgen-responsive neurons may contribute to sex differences in the behavioral and neuroendocrine responses to androgens.     

Androgen receptor immunoreactivity in rat occipital cortex after callosotomy

Gonadal steroidogenesis can be influenced by direct neural links between the central nervous system and the gonads. It is known that androgen receptor (AR) is expressed in many areas of the rat brain involved in neuroendocrine control of reproduction,such as the cerebral cortex.It has been recently shown that the occipital cortex exerts an inhibitory effect on testicular stereoidogenesis by a pituitary-independent neural mechanism. Moreover, the complete transection of the corpus callosum leads to an increase in testosterone (T) secretion of hemigonadectomized rats. The present study was undertaken to analyze the possible corticocortical influences regulating male reproductive activities. Adult male Wistar rats were divided into 4 groups: 1) intact animals as control; 2) rats undergoing sham callosotomy; 3) posterior callosotomy; 4) gonadectomy and posterior callosotomy. Western blot analysis showed no remarkable variations in cortical AR expression in any of the groups except in group I where a significant decrease in AR levels was found. Similarly, both immunocytochemical study and cell count estimation showed a lower AR immunoreactivity in occipital cortex of callosotomized rats than in other groups. In addition, there was no difference in serum T and LH concentration between sham-callosotomized and callosotomized rats. In conclusion, our results showthat posterior callosotomy led to a reduction in AR in the right occipital cortex suggesting a putative inhibiting effect of the contralateral cortical area.     

Androgen sulphate formation in male and female rats

1. After large doses of androsterone, epiandrosterone, dehydroepiandrosterone and testosterone, female rats excreted more of the dose conjugated with sulphuric acid than did the males. 2. Androgens were also incubated with liver slices from male and female rats. Slices from females conjugated androgens with sulphuric acid to a greater extent than did slices from males. 3. The amount of unchanged androgen present in the faeces of orally dosed animals was 4-35% of the dose.     

Androgen sulphate formation in male and female mice

1. After the administration of large doses of androsterone, epiandrosterone, dehydroepiandrosterone and testosterone to mice, females excreted more of the dose conjugated with sulphuric acid than did males. 2. Liver slices from female mice conjugated androgens with sulphuric acid to a greater extent than did slices from males. 3. Sulphotransferase preparations from livers of female rats and mice catalysed the formation of dehydroepiandrosterone sulphate at a faster rate than preparations from livers of the male animals. 4. A possible explanation for the observed sex differences is discussed.     

Dopamine receptors regulate NMDA receptor surface expression in prefrontal cortex neurons

Interactions between dopamine (DA) and glutamate systems in the prefrontal cortex (PFC) are important in addiction and other psychiatric disorders. Here, we examined DA receptor regulation of NMDA receptor surface expression in postnatal rat PFC neuronal cultures. Immunocytochemical analysis demonstrated that surface expression (synaptic and non-synaptic) of NR1 and NR2B on PFC pyramidal neurons was increased by the D1 receptor agonist SKF 81297 (1 microM, 5 min). Activation of protein kinase A (PKA) did not alter NR1 distribution, indicating that PKA does not mediate the effect of D1 receptor stimulation. However, the tyrosine kinase inhibitor genistein (50 microM, 30 min) completely blocked the effect of SKF 81297 on NR1 and NR2B surface expression. Protein cross-linking studies confirmed that SKF 81297 (1 microM, 5 min) increased NR1 and NR2B surface expression, and further showed that NR2A surface expression was not affected. Genistein blocked the effect of SKF 81297 on NR1 and NR2B. Surface-expressed immunoreactivity detected with a phospho-specific antibody to tyrosine 1472 of NR2B also increased after D1 agonist treatment. Our results show that tyrosine phosphorylation plays an important role in the trafficking of NR2B-containing NMDA receptors in PFC neurons and the regulation of their trafficking by DA receptors.     

Androgen receptor expression in the rat prostate is down-regulated by dietary phytoestrogens

Background  

It is well established that the growth of the prostate gland is a hormone-dependent phenomenon involving both androgenic and estrogenic control. Proliferation of prostate cells is, at least in part, under control of estrogen receptor beta (ER-beta). Phytoestrogens bind ER-beta with high affinity and therefore may have antiproliferative effects in the prostate.     

Sleep enhances plasticity in the developing visual cortex

During a critical period of brain development, occluding the vision of one eye causes a rapid remodeling of the visual cortex and its inputs. Sleep has been linked to other processes thought to depend on synaptic remodeling, but a role for sleep in this form of cortical plasticity has not been demonstrated. We found that sleep enhanced the effects of a preceding period of monocular deprivation on visual cortical responses, but wakefulness in complete darkness did not do so. The enhancement of plasticity by sleep was at least as great as that produced by an equal amount of additional deprivation. These findings demonstrate that sleep and sleep loss modify experience-dependent cortical plasticity in vivo. They suggest that sleep in early life may play a crucial role in brain development.     

Effects of L-triiodothyronine on tubulin content in developing male and female rat brain

The tubulin content and biochemical components were determined in the cerebrum, cerebellum and hypothalamus from intact and T3-treated male and female rats during early life. T3-treatment between 0 and 9 days of age increased soluble protein, RNA DNA and tubulin content (mg per g tissue) in the 10-day-old male cerebellum but not in the cerebrum and hypothalamus except for soluble protein and tubulin (mg per g tissue), respectively. Intracellular tubulin content (mg per mg DNA) was increased by the T3-treatment in the 10-day-old male hypothalamus but not the other regions. When T3 was administered between 10 and 19 days, there was little effect of the treatment; increased tubulin (mg per g tissue) in the cerebrum and decreased RNA (mg per g tissue) and a ratio of tubulin to protein in the cerebellum from 20-day-old males. Less response to T3-treatment was observed in female cerebrum and hypothalamus but not in the cerebellum, compared with the male. These results suggest that the effect of T3-treatment on brain is modified by several factors such as tissue specificity, age-dependency and sexual differences. Modification by these factors might depend, at least in part, on changes in the number of T3-receptors due to the hormone treatment.     

Diazepam: endocrine effects and hypothalamic binding sites in the developing male and female rat

The ontogeny of diazepam's endocrine effects in male and female rats, and of 3H-diazepam binding in the hypothalami of both sexes was studied. Diazepam inhibited basal prolactin levels in 38 day-old male rats and, if prolactin levels were stimulated by Haloperidol the inhibition occurred in 28 day-old males, indicating that the hypoprolactinemic effect of the drug could be evidenced earlier if prolactin titers were high. The prolactin inhibition in females did not reach statistical significance at any studied age. Diazepam significantly released LH only in male rats at 12 days, showing thus, a period of special sensitivity of LH release to the drug. Benzodiazepine-hypothalamic binding sites increased in number from birth to puberty, reaching a plateau at 20 days of age. No sexual differences or changes in affinity were found throughout the studied period. These results suggest that the maturation of diazepam's hypoprolactinemic effect could be partially related to the increase in hypothalamic binding sites, whereas the sexual differences observed in diazepam's endocrine actions could be due to sexual differentiation of endocrine control mechanisms.     

Sexual differences in the numerical density of synaptic profiles of developing rat visual cortex

Axo-dendritic synaptic profiles were quantified along the whole depth of the visual cortex of 10-day-old male and female rats. In both sexes the numerical density of synaptic profiles on spine-like structures was greater than the numerical density of synapses on dendritic shafts. Females had a significantly greater numerical density of synaptic profiles on spine-like structures, than did males at a distance of 200–400 and 500–600 μm from the pia surface, which corresponds to layers II–III and IV of the cortex, respectively. A small percentage (2%–4%) of spine-like structures received two presynaptic terminals. This type of double synapses was three times more abundant in females. No sex differences were found in the numerical density of synapses on dendritic shafts in any cortical layer. 1994 John Wiley & Sons, Inc.     

Differential expression of ryanodine receptor in the developing rat cochlea

Ryanodine receptors (RyRs) are one of the intracellular calcium channels involved in regulation of intracellular free calcium concentration ([Ca²⁺]i). The immunolocalization of RyRs was investigated in the developing rat cochlea at different postnatal days (PND). The change of [Ca²⁺]i in isolated outer hair cells (OHCs) was determined. Morphological results showed low expression of RyRs in the Kolliker’s organ from the PND 5 group. RyR expression in inner hair cells (IHCs) increased as the rats aged, and was mature after PND 14. RyRs in OHCs were expressed near the synaptic area of afferent and efferent nerves. RyRs in supporting cells were expressed widely and strongly. The application of ACh, ryanodine + ACh, and thapsigargin + ACh could induce a significant increase in [Ca²⁺]i in OHCs in the presence of extracellular calcium. This increase of [Ca²⁺]i induced by ACh was caused by not only the calcium influx through surface calcium channels, but also the calciuminduced calcium release (CICR) from intracellular RyR-sensitive calcium stores. Morphological and Ca imaging results suggested that RyRs expression is related to cochlear maturity, and may play an important role in its function.Key words: ryanodine receptor, development of cochlea, Ca²⁺, calcium-induced calcium release.Changes in intracellular Ca²⁺ concentration ([Ca²⁺]i) play an important role in cellular communication. The intracellular Ca²⁺ concentration is mainly mediated by two pathways: calcium entry via membrane calcium channels and calcium release from intracellular stores. The latter is mediated by 1, 4, 5-inositol triphosphate receptors (IP3R) and ryanodine receptors (RyRs). Mechanism of calcium release induced by RyRs has been believed to be calcium-induced calcium release (CICR) (Chakraborti et al., 2007). In the mammalian auditory system, calcium released from intracellular calcium stores in inner hair cells (IHCs), outer hair cells (OHCs), Deiters’ cells, and basal cells of stria vascularis plays an important role in the regulation of auditory transduction and electrochemical equilibrium of the cochlea (Bobbin, 2002; Marcotti et al., 2004). Neural transmitters, such as glutamate, ATP, acetylcholine (ACh), and substance P, can activate calcium signaling in spiral ganglia neurons, and then regulate the excitability of auditory neurons (Skinner et al., 2003). It has been reported that RyRs are widely expressed in the IHCs, OHCs, supporting cells in the organ of Corti’s, and in spiral ganglia neurons (SGNs) (Lioudyno et al., 2004; Morton-Jones et al., 2006). In the OHCs, the RyRs are mainly expressed under the reticular lamina, where BK channels are also strongly expressed (Beurg et al., 2005). Other studies also revealed that RyRs expressed in the synaptic area at the bottom of OHCs and the adjacent Deiters’ cells called as synaptoplasmic cistern (Lioudyno et al., 2004; Morton-Jones et al., 2006). Lioudyno et al., 2004; Morton-Jones et al., 2006).Three subtypes of RyRs have been identified expressed in the cochlea. RyR1 was observed in the synapses of OHCs using an SP6-RNA probe. RyR2 was mainly expressed in Corti’s organ and the cytoplasm of IHCs. RyR3 was found in the axons of SGNs located in the inner spiral plexus and the terminal of outer spiral fiber innervating OHCs (Lioudyno et al., 2004; Morton-Jones et al., 2006). These distinct expression patterns suggest that RyRs mediated calcium signaling plays important roles in auditory function.

Table 1

Location of RyR expression in previous references.

Cholinergic induction of seizures in the rat prefrontal cortex

Intracerebral microinjection of the cholinergic agonist, carbachol, into the medial prefrontal cortex of the rat, induced a profound behavioral syndrome consisting of repetitive, stereotyped forepaw treading in an upright posture. Electroencephalographic analysis revealed multiple bursts of sharp waves, 200-300 microV, accompanying the carbachol-elicited motor behavior. Pretreatment with intraperitoneal doses of three anticonvulsant drugs, clonazepam, diazepam, and pentobarbital, blocked the manifestation of the motor behavior. These observations suggest that activation of cholinergically innervated regions of the rat medial prefrontal cortex induces an atypical form of seizures.     

Repeated stress causes cognitive impairment by suppressing glutamate receptor expression and function in prefrontal cortex

Chronic stress could trigger maladaptive changes associated with stress-related mental disorders; however, the underlying mechanisms remain elusive. In this study, we found that exposing juvenile male rats to repeated stress significantly impaired the temporal order recognition memory, a cognitive process controlled by the prefrontal cortex (PFC). Concomitantly, significantly reduced AMPAR- and NMDAR-mediated synaptic transmission and glutamate receptor expression were found in PFC pyramidal neurons from repeatedly stressed animals. All these effects relied on activation of glucocorticoid receptors and the subsequent enhancement of ubiquitin/proteasome-mediated degradation of GluR1 and NR1 subunits, which was controlled by the E3 ubiquitin ligase Nedd4-1 and Fbx2, respectively. Inhibition of proteasomes or knockdown of Nedd4-1 and Fbx2 in PFC prevented the loss of glutamatergic responses and recognition memory in stressed animals. Our results suggest that repeated stress dampens PFC glutamatergic transmission by facilitating glutamate receptor turnover, which causes the detrimental effect on PFC-dependent cognitive processes.     

Serotonin receptor expression in human prefrontal cortex: balancing excitation and inhibition across postnatal development

Serotonin and its receptors (HTRs) play critical roles in brain development and in the regulation of cognition, mood, and anxiety. HTRs are highly expressed in human prefrontal cortex and exert control over prefrontal excitability. The serotonin system is a key treatment target for several psychiatric disorders; however, the effectiveness of these drugs varies according to age. Despite strong evidence for developmental changes in prefrontal Htrs of rodents, the developmental regulation of HTR expression in human prefrontal cortex has not been examined. Using postmortem human prefrontal brain tissue from across postnatal life, we investigated the expression of key serotonin receptors with distinct inhibitory (HTR1A, HTR5A) and excitatory (HTR2A, HTR2C, HTR4, HTR6) effects on cortical neurons, including two receptors which appear to be expressed to a greater degree in inhibitory interneurons of cerebral cortex (HTR2C, HTR6). We found distinct developmental patterns of expression for each of these six HTRs, with profound changes in expression occurring early in postnatal development and also into adulthood. However, a collective look at these HTRs in terms of their likely neurophysiological effects and major cellular localization leads to a model that suggests developmental changes in expression of these individual HTRs may not perturb an overall balance between inhibitory and excitatory effects. Examining and understanding the healthy balance is critical to appreciate how abnormal expression of an individual HTR may create a window of vulnerability for the emergence of psychiatric illness.