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ABSTRACT: Estradiol affects hippocampal-dependent spatial memory and underlying structural and electrical synaptic plasticity in female mice and rats. Using estrogen receptor (ER) alpha and beta knockout mice and wild-type littermates, we investigated the role of ERs in estradiol effects on multiple pathways important for hippocampal plasticity and learning. Six hours of estradiol administration increased immunoreactivity for phosphorylated Akt throughout the hippocampal formation, whereas 48 h of estradiol increased immunoreactivity for phosphorylated TrkB receptor. Estradiol effects on phosphorylated Akt and TrkB immunoreactivities were abolished in ER alpha and ER beta knockout mice. Estradiol also had distinct effects on immunoreactivity for post-synaptic density 95 (PSD-95) and brain derived-neurotrophic factor (BDNF) mRNA in ER alpha and beta knockout mice. Thus, estradiol acts through both ERs alpha and beta in several subregions of the hippocampal formation. The different effects of estradiol at 6 and 48 h indicate that several mechanisms of estrogen receptor signaling contribute to this female hormone's influence on hippocampal synaptic plasticity. By further delineating these mechanisms, we will better understand and predict the effects of endogenous and exogenous ovarian steroids on mood, cognition, and other hippocampal-dependent behaviors.
Neuroscience 11/2011; 202:131-46. · 3.38 Impact Factor
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ABSTRACT: Like estrogens in female rats, androgens can affect dendritic spine density in the CA1 subfield of the male rat hippocampus [J Neurosci 23:1588 (2003)]. Previous light microscopic studies have shown that androgen receptors (ARs) are present in the nuclei of CA1 pyramidal cells. However, androgens may also exert their effects through rapid non-genomic mechanisms, possibly by binding to membranes. Thus, to investigate whether ARs are at potential extranuclear sites of ARs, antibodies to ARs were localized by light and electron microscopy in the male rat hippocampal formation. By light microscopy, AR immunoreactivity (-ir) was found in CA1 pyramidal cell nuclei and in disperse, punctate processes that were most dense in the pyramidal cell layer. Additionally, diffuse AR-ir was found in the mossy fiber pathway. Ultrastructural analysis revealed AR-ir at several extranuclear sites in all hippocampal subregions. AR-ir was found in dendritic spines, many arising from pyramidal and granule cell dendrites. AR-ir was associated with clusters of small, synaptic vesicles within preterminal axons and axon terminals. Labeled preterminal axons were most prominent in stratum lucidum of the CA3 region. AR-containing terminals formed asymmetric synapses or did not form synaptic junctions in the plane of section analyzed. AR-ir also was detected in astrocytic profiles, many of which apposed terminals synapsing on unlabeled dendritic spines or formed gap junctions with other AR-labeled or unlabeled astrocytes. Collectively, these results suggest that ARs may serve as both a genomic and non-genomic transducer of androgen action in the hippocampal formation.
Neuroscience 02/2005; 130(1):151-63. · 3.38 Impact Factor
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ABSTRACT: Estrogen (E) treatment of ovariectomized animals increases dendritic spines and/or synaptic protein expression in the hippocampus of female rats [J Neurosci 12 (1992) 2549; Endocrinology 142 (2001) 1284; Endocrinol Rev 20 (1999) 279; Annu Rev Pharmacol Toxicol 41 (2001) 569], mice [Proc Natl Acad Sci USA 101 (2004) 2185], rhesus monkeys [Proc Natl Acad Sci USA 98 (2001) 8071; Endocrinology 144 (2003) 4734; J Comp Neurol 465 (2003) 540] and hippocampal cells in vitro [J Neurosci 16 (1996) 4059; Neuroscience 124 (2004) 549]. The role of E in hippocampal synaptic structural plasticity in males is less well understood. In the present study, we have used a recently developed technique to count spinophilin immunogold-reactive (Ir) puncta as well as in situ hybridization to compare E effects on spinophilin-Ir and mRNA in gonadectomized female and male rats 48 h after E treatment. Spinophilin is an established spine marker, which interacts with several proteins (including actin and protein phosphatase 1) that are highly enriched in spines [Proc Natl Acad Sci USA 94 (1997) 9956; Proc Natl Acad Sci USA 97 (2000) 9287]. We report that E exerts sex-specific effects on dendritic spinophilin-labeled spines in the CA1 region: E treatment significantly increased spinophilin-Ir puncta, indicative of spines, in females, but led to a decrease in males. Furthermore, while hippocampal spinophilin mRNA changes could have occurred earlier, spinophilin mRNA levels were unchanged after 48 h of E in both males and females. This suggests the possibility that E regulates spinophilin protein expression and or stability within dendrites via post-transcriptional mechanisms.
Neuroscience 02/2004; 127(4):983-8. · 3.38 Impact Factor
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R D Romeo
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ABSTRACT: During perinatal development, steroid hormones act on the central nervous system (CNS) to organize neural circuits. These circuits remain relatively dormant until hormonal stimulation received in adulthood acts on the CNS to activate adult reproductive physiology and behaviour. In this review, the proposal is put forward that, in addition to perinatal development, puberty serves as another period of neural maturation mediated by both steroid-dependent and -independent events that further organize and shape the behavioural potential of the adult organism. In support of this thesis, data are summarized that clearly show the organizational effects of the pubertal rise in gonadal hormones on mating behaviour and other steroid-mediated behaviours exhibited in adulthood, and on the neural pathways that mediate these behaviours. The importance of determining whether this sensitive period of neural development during puberty is a 'critical period' is also discussed, as well as whether perturbations of the nervous system during pubertal development may result in negative behavioural and physiological outcomes in adulthood. It is concluded that puberty is not merely a time when increasing levels of gonadal steroids activate the neural circuits organized during perinatal development, but also a time of further organization of the CNS, which allows for appropriate behaviours to emerge in adulthood.
Journal of Neuroendocrinology 01/2004; 15(12):1185-92. · 3.14 Impact Factor
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ABSTRACT: The present experiments investigated the effects of pubertal maturation and photoperiod on the size of brain regions that mediate mating behavior in the male Syrian hamster. We hypothesized that the low levels of reproductive behavior exhibited by prepubertal and photoinhibited males would be correlated with morphological changes in the neural circuit that mediates mating behavior. We found that the Nissl-stained cross-sectional area of the posterodorsal subdivision of the medial amygdala was significantly smaller in prepubertal and photoinhibited males compared to photostimulated adult males. These differences appear to be caused by a decrease in somal size of individual cells in the ventral aspect of this nucleus. We also found that prepubertal males have a larger anterior subdivision of the medial amygdala (MeA) compared to adults. This difference in the MeA does not appear to be caused by alteration in somal size since somal size did not differ significantly between juveniles and adults. It is concluded that the neural circuit that mediates male mating behavior in this species is capable of significant morphological plasticity during both pubertal development and in adulthood. Furthermore, these alterations may reflect underlying mechanisms of the deficits in sexual behavior exhibited by prepubertal and photoinhibited males.
Brain Research 02/2001; 889(1-2):71-7. · 2.73 Impact Factor
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ABSTRACT: Perinatal development is often viewed as the major window of time for organization of steroid-sensitive neural circuits by steroid hormones. Behavioral and neuroendocrine responses to steroids are dramatically different before and after puberty, suggesting that puberty is another window of time during which gonadal steroids affect neural development. In the present study, we investigated whether the presence of gonadal hormones during pubertal development affects the number of androgen receptor and estrogen receptor alpha-immunoreactive (AR-ir and ER alpha-ir, respectively) cells in limbic regions. Male Syrian hamsters were castrated either before or after pubertal development, and 4 weeks later they received a single injection of testosterone or oil vehicle 4 h prior to tissue collection. Immunocytochemistry for AR and ER alpha was performed on brain sections from testosterone-treated and oil-treated males, respectively. Adult males that had been castrated before puberty had a greater number of AR-ir cells in the medial preoptic nucleus than adult males that had been castrated after puberty. There were no significant differences in ER alpha-ir cell number in any of the brain regions examined. The demonstration that exposure to gonadal hormones during pubertal development is associated with reduced AR-ir in the medial preoptic nucleus indicates that puberty is a period of neural development during which hormones shape steroid-sensitive neural circuits.
Journal of Neurobiology 10/2000; 44(3):361-8. · 3.05 Impact Factor
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ABSTRACT: Puberty in the male Syrian hamster (Mesocricetus auratus) is characterized by decreased responsiveness to testosterone mediated negative feedback, but the neural mechanism for this change remains elusive. We hypothesized that decreased inhibition of the gonadotropin-releasing hormone (GnRH) system results in increased neurosecretory activity, which includes an increase in GnRH gene expression. This study examined GnRH mRNA in male hamsters before and after puberty, and sought to determine if any increase in mRNA was specific to particular subpopulations of GnRH neurones. Brains were collected from 21-day-old prepubertal males (n = 5) and 56-day-old postpubertal males (n = 5). Alternate 10 microm coronal sections from fresh-frozen brains were collected throughout the septo-hypothalamic region, and 25% of those sections were processed for in-situ hybridization histochemistry using an 35S-riboprobe complementary to hamster GnRH. No differences were observed in the number of GnRH mRNA expressing cells in any region, but in the diagonal band of Broca (DBB)/organum vasculosum of the lamina terminalis (OVLT) there was a significant increase in labelling intensity (defined as area of the cell occupied by silver grains) in postpubertal males. A second analysis compared the frequency distributions of cells based on labelling intensity between prepubertal and postpubertal males. This analysis revealed significant differences between the two frequency distributions in all areas analysed (DBB/OVLT, medial septum (MS), and preoptic area (POA)). Furthermore, examining the distribution of cells in these regions revealed a shift to the right in the postpubertal population of cells, which indicated an increased number of GnRH neurones with greater labelling intensity. These data clearly demonstrate increased GnRH mRNA during puberty. Furthermore, they suggest that the previous observation of brain region specific pubertal decreases in GnRH-immunoreactivity only within the DBB/OVLT and MS but not the POA are not due to differential levels of GnRH gene expression, but could indicate increased release from these neurones during puberty.
Journal of Neuroendocrinology 09/1999; 11(8):621-7. · 3.14 Impact Factor
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ABSTRACT: Estrogen and estrogen receptors (ER) are involved in the expression of steroid-dependent male sexual behavior and negative feedback regulation of the hypothalamic-pituitary-gonadal axis. The purpose of the present experiment was to determine whether there are pubertal changes in ER expression in brain that are correlated with pubertal changes in responsiveness to steroid negative feedback and behavioral activation. We found equivalent numbers of ER-immunoreactive (ER-ir) cells in castrated prepubertal and adult male hamsters in nuclei that comprise the neural circuit that mediate male sexual behavior. Therefore, increases in the number of cells in these nuclei that express ER are not correlated with the increased behavioral responsiveness to steroid hormone shown by hamsters after puberty. The number of ER-ir cells in the ventral medial hypothalamus was less in adults compared with juveniles. This pubertal decrease in ER expression is correlated with the decreased responsiveness to steroid negative feedback in the adult.
Neuroscience Letters 05/1999; 265(3):167-70. · 2.11 Impact Factor
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ABSTRACT: Doses of testosterone that fully activate male reproductive behavior in castrated adult male hamsters fail to elicit mounting and intromissions in prepubertal castrates, even when circulating levels of testosterone are equivalent in the two age groups. We hypothesize that this differential responsiveness to testosterone is mediated at least in part by the efficacy with which testosterone in the hypothalamus is aromatized to estradiol, an important hormone mediating male sexual behavior. Therefore, hypothalamic aromatase activity, as measured by the conversion of [3H]testosterone to [3H]estradiol in tissue homogenates, was assessed in four separate experiments: 1) intact prepubertal and adult male golden hamsters, 2 and 3) castrated adult or prepubertal males that received either a 0- or 2.5-mg dose of testosterone, and 4) castrated adult and prepubertal males treated with the 2.5-mg dose oftestosterone. These studies demonstrate that hypothalamic aromatase activity is significantly higher in adult males compared with prepubertal males, and that hypothalamic aromatase activity is increased by testosterone to the same extent in both the adult and prepubertal male hamster. Therefore, the failure of testosterone-treated castrated prepubertal male hamsters to engage in the full suite of male reproductive behaviors is not due to the inability of testosterone to be converted into estradiol in the hypothalamus. Differences in the ability of testosterone to increase aromatase activity in other brain regions, or differences in the action of testosterone and/or estradiol on other cellular processes must account for the inability of testosterone to facilitate male reproductive behavior in juvenile males.
Endocrinology 02/1999; 140(1):112-7. · 4.46 Impact Factor
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ABSTRACT: Like estrogens in female rats, androgens can affect dendritic spine density in the CA1 subfield of the male rat hippocampus [J Neurosci 23:1588 (2003)]. Previous light microscopic studies have shown that androgen receptors (ARs) are present in the nuclei of CA1 pyramidal cells. However, androgens may also exert their effects through rapid non-genomic mechanisms, possibly by binding to membranes. Thus, to investigate whether ARs are at potential extranuclear sites of ARs, antibodies to ARs were localized by light and electron microscopy in the male rat hippocampal formation. By light microscopy, AR immunoreactivity (-ir) was found in CA1 pyramidal cell nuclei and in disperse, punctate processes that were most dense in the pyramidal cell layer. Additionally, diffuse AR-ir was found in the mossy fiber pathway. Ultrastructural analysis revealed AR-ir at several extranuclear sites in all hippocampal subregions. AR-ir was found in dendritic spines, many arising from pyramidal and granule cell dendrites. AR-ir was associated with clusters of small, synaptic vesicles within preterminal axons and axon terminals. Labeled preterminal axons were most prominent in stratum lucidum of the CA3 region. AR-containing terminals formed asymmetric synapses or did not form synaptic junctions in the plane of section analyzed. AR-ir also was detected in astrocytic profiles, many of which apposed terminals synapsing on unlabeled dendritic spines or formed gap junctions with other AR-labeled or unlabeled astrocytes. Collectively, these results suggest that ARs may serve as both a genomic and non-genomic transducer of androgen action in the hippocampal formation.
Neuroscience.
