Effects of ovariectomy and steroid replacement on hypothalamic LHRH content in aging female rats

Aging-Related Changes in Ovarian Hormones, Their Receptors, and Neuroendocrine Function

Ovarian steroid hormones exert a broad range of effects on the body and brain. In the nervous system, estrogen and progesterone have crucial feedback actions on the hypothalamic neurons that drive the reproductive axis. In addition, hormones exert a variety of actions on other traditionally nonreproductive functions such as cognition, learning and memory, neuroprotection, mood and affective behavior, and locomotor activity. The actions of hormones on the hypothalamus are largely mediated by their nuclear hormone receptors, the two estrogen receptors, ERα and ERβ, and the two progesterone receptor isoforms, PR-A and PR-B. Thus, changes in the circulating concentrations of estrogens and progestins during the life cycle can result in differential activation of their receptors. Furthermore, changes in the numbers, activity, and distribution of hypothalamic ERs and PRs can occur as a function of developmental age. The purpose of this article is to review the literature on the causes and consequences of alterations in steroid hormones, their neural receptors, and their interactions on reproductive senescence. We have also discussed several important experimental design considerations, focusing on rodent models in current use for understanding the mechanisms of menopause in women.

Living and dying for sex. A theory of aging based on the modulation of cell cycle signaling by reproductive hormones

A mechanistic understanding of aging has yet to be described; this paper puts forth a new theory that has the potential to explain aging in all sexually reproductive life forms. The theory also puts forth a new definition of aging - any change in an organism over time. This definition includes not only the changes associated with the loss of function (i.e. senescence, the commonly accepted definition of aging), but also the changes associated with the gain of function (growth and development). Using this definition, the rate of aging would be synonymous with the rate of change. The rate of change/aging is most rapid during the fetal period when organisms develop from a single cell at conception to a multicellular organism at birth. Therefore, 'fetal aging' would be determined by factors regulating the rate of mitogenesis, differentiation, and cell death. We suggest that these factors also are responsible for regulating aging throughout life. Thus, whatever controls mitogenesis, differentiation and cell death must also control aging. Since life-extending modalities consistently affect reproduction, and reproductive hormones are known to regulate mitogenesis and differentiation, we propose that aging is primarily regulated by the hormones that control reproduction (hence, the Reproductive-Cell Cycle Theory of Aging). In mammals, reproduction is controlled by the hypothalamic-pituitary-gonadal (HPG) axis hormones. Longevity inducing interventions, including caloric restriction, decrease fertility by suppressing HPG axis hormones and HPG hormones are known to affect signaling through the well-documented longevity regulating GH/IGF-1/PI3K/Akt/Forkhead pathway. This is exemplified by genetic alterations in Caenorhabditis elegans where homologues of the HPG axis pathways, as well as the daf-2 and daf-9 pathways, all converge on daf-16, the homologue of human Forkhead that functions in the regulation of cell cycle events. In summary, we propose that the hormones that regulate reproduction act in an antagonistic pleiotrophic manner to control aging via cell cycle signaling; promoting growth and development early in life in order to achieve reproduction, but later in life, in a futile attempt to maintain reproduction, become dysregulated and drive senescence.

Estrogen and aging affect the subcellular distribution of estrogen receptor-alpha in the hippocampus of female rats

Estrogen replacement increases both the number of dendritic spines and the density of axospinous synapses in the hippocampal CA1 region in young rats, yet this is attenuated in aged rats. The estrogen receptor-alpha (ER-alpha) is localized within select spines of CA1 pyramidal cells in young animals and thus may be involved locally in this process. The present study investigated the effects of estrogen on the ultrastructural distribution of ER-alpha in the CA1 of young (3-4 months) and aged (22-23 months) Sprague Dawley rats using postembedding immunogold electron microscopy. Within dendritic spines, most ER-alpha immunoreactivity (IR) was seen in plasmalemmal and cytoplasmic regions of spine heads, with a smaller proportion within 60 nm of the postsynaptic density. In presynaptic terminals, ER-alpha-IR was clustered and often associated with synaptic vesicles. Significant effects of both aging and estrogen were observed. Quantitative analysis revealed that nonsynaptic pools of ER-alpha-IR within the presynaptic and postsynaptic compartments were decreased (35 and 27%, respectively) in the young estrogen-replaced animals compared with those that received vehicle. Such localized regulation of ER-alpha in response to circulating estrogen levels might directly affect synaptic signaling in CA1 pyramidal cells. No estrogen treatment-related differences were observed in the aged animals. However, 50% fewer spines contained ER-alpha in the aged compared with young hippocampus. These data suggest that the decreased responsiveness of hippocampal synapses to estrogen in aged animals may result from age-related decrements in ER-alpha levels and its subcellular localization vis-à-vis the synapse. Such a role for spinous ER-alpha has important implications for age-related attenuation of estrogen-induced hippocampal plasticity.

Attenuated lesion-induced N-methyl-D-aspartate receptor (NMDAR) plasticity in the dentate gyrus of aged rats following perforant path lesions

Young animals demonstrate a significant upregulation of N-methyl-d-aspartate receptor 1 (NMDAR1) in the outer molecular layer (OML) of the dentate gyrus following a total unilateral ablation of the perforant path, and this response presumably facilitates a degree of functional recovery. Aged animals have attenuated responses to lesion-induced synaptic plasticity as compared with young subjects, and in fact display decreased synaptogenesis and sprouting following a unilateral perforant path lesion. To investigate the response of NMDAR1 in the dentate gyrus of aged animals to perforant path ablation, 24-month-old Sprague-Dawley male rats received a unilateral knife cut of the angular bundle. Our results demonstrated that aged animals displayed a blunted response to lesion-induced NMDA receptor-mediated plasticity, suggesting that aged animals have an impaired ability to respond to deafferentation through an increase in NMDA receptor levels in the deafferented zone.

Length of postovariectomy interval and age, but not estrogen replacement, regulate N-methyl-D-aspartate receptor mRNA levels in the hippocampus of female rats

Estrogens and N-methyl-D-aspartate (NMDA) receptors regulate multiple aspects of morphological and functional plasticity in young animals. For example, estrogens increase spine density in the hippocampus, and NMDA antagonists block these effects. Few studies have examined the effects of age, postovariectomy interval, and duration of estrogen replacement in the hippocampus and more specifically on NMDA receptor subunits. Therefore, the present study was designed to investigate the effects of short- and long-term estrogen replacement or deprivation on mRNA levels of three NMDA receptor subunits, NR1, NR2A, and NR2B, in the hippocampus of aging female Sprague-Dawley rats. Young (3- to 4-month-old) and middle-aged (12- to 13-month-old) rats were ovariectomized for 1 month and then treated with estrogen or vehicle for either 2 days or 2 weeks. Another set of middle-aged and aged (24-to 25-month-old) animals were ovariectomized for 6 months and treated with estrogen or vehicle for 2 days or 2 weeks. RNase protection assay was used to assess changes in the NMDA receptor subunit mRNA levels. Our results demonstrated significant effects of age and length of ovariectomy on NMDA receptor mRNA levels, with little effect of the estrogen status of the animals on these parameters. The largest effect was seen for the length of the postovariectomy interval, with the results demonstrating that rats with a short-term ovariectomy have substantially higher NMDA receptor subunit mRNA levels than animals with long-term ovariectomy. The most dramatic effects of aging were seen for NR1 and NR2B mRNAs in ventral hippocampus, with large age-related increases. These data suggest that age and duration of ovariectomy impact NMDA receptor mRNA levels in the hippocampus, potentially affecting the stoichiometry and/or function of these receptors. These findings have important implications for postmenopausal or hysterectomy/oophorectomy estrogen depletion and replacement in humans.

Different modes of hippocampal plasticity in response to estrogen in young and aged female rats

Estrogen regulates hippocampal dendritic spine density and synapse number in an N-methyl-D-aspartate (NMDA) receptor-dependent manner, and these effects may be of particular importance in the context of age-related changes in endocrine status. We investigated estrogen's effects on axospinous synapse density and the synaptic distribution of the NMDA receptor subunit, NR1, within the context of aging. Although estrogen induced an increase in axospinous synapse density in young animals, it did not alter the synaptic representation of NR1, in that the amount of NR1 per synapse was equivalent across groups. Estrogen replacement in aged female rats failed to increase axospinous synapse density; however, estrogen up-regulated synaptic NR1 compared with aged animals with no estrogen. Therefore, the young and aged hippocampi react differently to estrogen replacement, with the aged animals unable to mount a plasticity response generating additional synapses, yet responsive to estrogen with respect to additional NMDA receptor content per synapse. These findings have important implications for estrogen replacement therapy in the context of aging.

Neuroendocrine mechanisms for reproductive senescence in the female rat: gonadotropin-releasing hormone neurons

Reproductive aging in female rats is characterized by profound alterations in the neuroendocrine axis. The preovulatory luteinizing hormone (LH) surge is attenuated, and preovulatory expression of the immediate early gene fos in gonadotropin-releasing hormone (GnRH) neurons is substantially reduced in middle-aged compared with young rats. We tested the hypothesis that alterations in GnRH gene expression may be correlated with the attenuation of the LH surge and may be a possible mechanism involved in neuroendocrine senescent changes. Sprague-Dawley rats ages 4 to 5 mo (young), 12-14 mo (middle-aged), or 25 to 26 mo (old) were killed at 10:00 AM or 3:00 PM on proestrus, the day of the LH surge, or diestrus I in cycling rats, and on persistent estrus or persistent diestrus in acyclic rats. RNase protection assays of GnRH mRNA and GnRH primary transcript were performed. GnRH mRNA levels increased significantly with age, whereas GnRH primary transcript levels, an index of GnRH gene transcription, decreased in old compared to young and middle-aged rats. This latter result suggests that an age-related change in GnRH mRNA levels occurs independently of a change in gene transcription, indicating a potential posttranscriptional mechanism. On proestrus, GnRH mRNA levels increased significantly from 10:00 AM to 3:00 PM in young rats. This was in contrast to proestrous middle-aged rats, in which this afternoon increase in GnRH mRNA levels was not observed. Thus, the normal afternoon increase in GnRH mRNA levels on proestrus is disrupted by middle age and may represent a substrate for the attenuation of the preovulatory GnRH/LH surge that occurs in rats of this age, prior to reproductive failure.

A neuroendocrine overview of aging

The neuroendocrine changes associated with aging are numerous, and tend to vary quantitatively, if not qualitatively between species. The extent to which neuroendocrine dysfunction contributes to the undesirable features of aging remains to be fully determined. Nevertheless, although the aging process itself may not have a neuroendocrine basis, identification and correction of the associated neuroendocrine dysfunction may be important in enhancing the quality of life during this period.

Chronic estradiol administration did not cause loss of hypothalamic LHRH or TIDA neurons in young or middle-aged C57BL/6J mice

Age-related decline in estrous cycle frequency and impaired pre-ovulatory gonadotropin surges at mid-life are modelled in young C57BL/6J mice by chronic (3 months) oral administration of estradiol (E2). However, the cellular events that induce damage to the neuroendocrine center that regulate gonadotropins with age or following E2 treatment are unclear. To address this issue, possible neuron loss was examined in relation to the loss of estrous cyclicity in E2-treated mice, in particular neurons of the hypothalamic luteinizing hormone releasing hormone (LHRH) and/or tuberoinfundibular dopaminergic (TIDA) systems. By immunocytochemical methods, there was no change in the number of LHRH or TIDA neurons in mice that have become acyclic due to age or E2 treatment. We conclude that the onset of acyclicity at middle-age or following chronic E2 treatment is not associated with loss of LHRH or TIDA neurons and that other neuroendocrine changes must be considered for the cause of acyclicity, particularly those involved in the synaptic regulation of LHRH secretion.

Hypothalamic-pituitary axis during reproductive aging in mice

We correlated the content of hypothalamic (HT) GnRH and pituitary (PT) GnRH receptor sites with PT and plasma gonadotropin levels throughout aging in C57BL/6J mice. Female mice of 4-6 months (young), 10-12 months (middle-age) or 15-18 months (old) of age were studied either intact or 15 days post-ovariectomy (OVX) with or without E2 therapy. In intact mice, HT GnRH content increased twofold during aging while GnRH receptor sites in PT remained unchanged. PT content of both FSH and LH gradually rose during aging while plasma concentration rose even more. OVX resulted in a significant decrease in both HT GnRH content and PT receptor sites and no age difference was observed. OVX also resulted in a significant increase in both PT content and plasma levels of gonadotropin in young and middle-age mice while old mice showed a blunted response. After E2 therapy for 7 days, HT GnRH content and PT GnRH receptor sites returned to normal levels in all age groups. By contrast, E2 therapy resulted in no change in PT content of FSH:LH in any age group. Whereas plasma FSH:LH levels returned to intact levels in young mice, they remained elevated to OVX levels in middle-age and old ones. Our results demonstrate an age related dichotomy in the PT production of FSH:LH unrelated to changes in either HT GnRH content or its PT receptor sites, thus suggesting cellular defects in post-receptor binding events within the pituitary.

LHRH neurons in the female C57BL/6J mouse brain during reproductive aging: no loss up to middle age

The numbers of neurons containing luteinizing hormone releasing hormone (LHRH) were examined with specific immunocytochemical techniques in C57BL/6J mice at 5-6 months and 15-16 months of age, the latter being the time of transition to the loss of estrous cycles. No changes were found in the organization, morphology, or numbers of LHRH neurons.

Hypothalamic LHRH in aging rats: effects of ovariectomy and steroid replacement

Hypothalamic LHRH was measured by RIA in young and middle-aged (MA) female rats in several endocrine conditions. Temporal alterations in LHRH content associated with the steroid induced gonadotropin surge were compared in medial basal hypothalamic and anterior hypothalamic-preoptic area fragments of ovariectomized young and MA subjects. LHRH content was also compared in ovariectomized, untreated subjects from the two age groups. Finally, LHRH content in MA constant estrous females was compared with content in young females on the morning of proestrus. In all conditions, LHRH levels in both brain regions of MA females were similar to, or significantly elevated above levels measured in young females, yet both the steroid induced surge and the castration induced hypersecretion of gonadotropins were markedly attenuated in aging females. Because studies have verified the responsiveness of the pituitary of MA rats to LHRH, the data suggest that adequate amounts of hypothalamic LHRH do not reach the pituitary. Rather, high levels of hypothalamic LHRH measured in MA subjects may represent accumulation of the peptide in LHRH neurons due to an age-related impairment in release.