UMLS:C0036341 - FACTA Search

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Query: UMLS:C0036341 (schizophrenia)
60,220 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Numerous reports, ranging from molecular investigations to clinical studies, demonstrate the potency of estrogens to modulate brain function and their implications in schizophrenia and depression. Alterations of dopaminergic, cholinergic, GABAergic, glutamatergic and serotonergic neurotransmission through estrogen-mediated mechanisms have been consistently established. Moreover, studies using in vivo and in vitro models as well as epidemiological data suggest that estrogens provide neuroprotection of central nervous system (CNS) cells implicated in the etiology of neurodegenerative disorders such as Alzheimer s (AD) and Parkinson s (PD) diseases. Numerous genomic or non-genomic mechanisms of actions of estrogens in the brain have been documented implicating classical nuclear estrogen receptors as well as possible estrogen membrane receptors, antioxidant activity of steroids, their effect on fluidity as well as on antiapoptotic proteins and growth factors. Selective estrogen receptor modulators (SERMs) have estrogenic and/or antiestrogenic activity depending on the target tissue. Hence, SERMs have the same beneficial effect as estrogen in skeleton and cardiovascular systems but act as antagonists in breast and uterus. The finding of beneficial side effects of SERMs in the CNS might improve their risk-benefit ratio in traditional indications. In this review, we will survey schizophrenia and depression as examples of mental diseases and AD and PD as neurodegenerative diseases. We will review brain effects of estrogens, steroids possibly acting as pro-drugs of estrogens such as testosterone and dehydroepiandrosterone (DHEA) and present novel findings with SERMs. Drugs with estrogen activity in the brain may have therapeutic potential either by modulating brain neurotransmitter transmission or through neuroprotective activity.
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PMID:Drugs with estrogen-like potency and brain activity: potential therapeutic application for the CNS. 1090 93

This review highlights recent evidence from clinical and basic science studies supporting a role for estrogen in neuroprotection. Accumulated clinical evidence suggests that estrogen exposure decreases the risk and delays the onset and progression of Alzheimer's disease and schizophrenia, and may also enhance recovery from traumatic neurological injury such as stroke. Recent basic science studies show that not only does exogenous estradiol decrease the response to various forms of insult, but the brain itself upregulates both estrogen synthesis and estrogen receptor expression at sites of injury. Thus, our view of the role of estrogen in neural function must be broadened to include not only its function in neuroendocrine regulation and reproductive behaviors, but also to include a direct protective role in response to degenerative disease or injury. Estrogen may play this protective role through several routes. Key among these are estrogen dependent alterations in cell survival, axonal sprouting, regenerative responses, enhanced synaptic transmission and enhanced neurogenesis. Some of the mechanisms underlying these effects are independent of the classically defined nuclear estrogen receptors and involve unidentified membrane receptors, direct modulation of neurotransmitter receptor function, or the known anti-oxidant activities of estrogen. Other neuroprotective effects of estrogen do depend on the classical nuclear estrogen receptor, through which estrogen alters expression of estrogen responsive genes that play a role in apoptosis, axonal regeneration, or general trophic support. Yet another possibility is that estrogen receptors in the membrane or cytoplasm alter phosphorylation cascades through direct interactions with protein kinases or that estrogen receptor signaling may converge with signaling by other trophic molecules to confer resistance to injury. Although there is clear evidence that estradiol exposure can be deleterious to some neuronal populations, the potential clinical benefits of estrogen treatment for enhancing cognitive function may outweigh the associated central and peripheral risks. Exciting and important avenues for future investigation into the protective effects of estrogen include the optimal ligand and doses that can be used clinically to confer benefit without undue risk, modulation of neurotrophin and neurotrophin receptor expression, interaction of estrogen with regulated cofactors and coactivators that couple estrogen receptors to basal transcriptional machinery, interactions of estrogen with other survival and regeneration promoting factors, potential estrogenic effects on neuronal replenishment, and modulation of phenotypic choices by neural stem cells.
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PMID:Neuroprotection by estradiol. 1104 Apr 17

Evidence suggests the estrogens may play a role in various mental and neurodegenerative diseases. We review the evidence implicating estradiol in schizophrenia and Parkinson's disease. Epidemiologic and clinical studies on the effects of estrogens in schizophrenia are surveyed, and animal studies and in vitro models of the modulatory effects of estrogens on neurotransmitters associated with schizophrenia (i.e., dopamine, serotonin, glutamate) are reviewed. Epidemiologic and clinical data suggesting a role for estrogens in Parkinson's disease and in vivo and in vitro models demonstrating neuroprotective effects of estrogens are then examined. Despite the numerous animal studies on the effects of estrogens in the brain, clinical data are sparse and often contradictory. Compounds with more specific and potent estrogenic activity in the brain are required to further research efforts in this area. Possible candidates are the selective estrogen receptor modulators (SERMs), whose agonist or antagonist properties depend on the target tissue. The effects of various SERMs in the brain are reviewed, and our novel findings on the effects of SERMs on 5-HT2A receptors in the rat cortex and nucleus accumbens are presented. We suggest that drugs with estrogenic activity in the brain may have therapeutic potential, either by modulating brain neurotransmission or through neuroprotective activity.
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PMID:Estrogenic modulation of brain activity: implications for schizophrenia and Parkinson's disease. 1183 73

Tardive dyskinesia (TD) is an involuntary movement disorder induced by long-term antipsychotic treatments. Estrogen is suggested to modulate dopamine receptors in the central nervous system and may decrease the incidence and/or relieve the symptoms of TD. In this study, 118 schizophrenia patients with antipsychotic-induced TD and 128 sex- and age-matched non-TD schizophrenia patients were recruited. All patients were assessed by the Abnormal Involuntary Movement Scale and genotyped for the polymorphisms of estrogen receptor-alpha gene (ESR 1). There was a marginal association of the genotypes determined by PVU II between TD and non-TD patients (p = 0.057), but not of the genotypes determined by XBA I (p = 0.896). However, further studies on other polymorphisms of ESR 1 or other estrogen receptors are necessary to clarify the role of estrogen in the pathogenesis of TD.
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PMID:Association study of the estrogen receptor polymorphisms with tardive dyskinesia in schizophrenia. 1256 32

Numerous reports demonstrate the potency of estrogens to modulate brain function and their implications in schizophrenia and depression. The 5-HT(1A) receptor has been suggested to be implicated in depression and anxiety. Selective estrogen receptor modulators (SERMs), like tamoxifen and raloxifene, have estrogenic and/or antiestrogenic activity depending on the target tissue. Hence, SERMs have beneficial effects in skeleton and cardiovascular systems but act as antagonists in breast and uterus. The aim of the present study was thus to investigate in ovariectomized rats the effects of 17beta-estradiol, tamoxifen and raloxifene treatments on 5-HT(1A) receptor binding sites (agonist and antagonist) and mRNA levels in the hippocampal formation, prefrontal and cingulate cortex, as well as dorsal raphea nucleus which are known to express estrogen receptors (ER). Two weeks ovariectomy of female rats led to a 60% decrease of uterine weight, which was prevented by a 2-week 17beta-estradiol treatment; tamoxifen and raloxifene increased uterine weights by 35% and 15%, respectively, but significantly less than estradiol treatment. Specific binding to 5-HT(1A) receptors was determined by autoradiography of brain sections using the selective ligands: [3H]8-OH-DPAT and [3H]MPPF. Ovariectomy and hormone replacement therapy did not significantly affect 5-HT(1A) receptor agonist and antagonist specific binding sites as well as mRNA levels in all subregions of the hippocampus, prefrontal and cingulate cortex as well as dorsal raphea nucleus. Although the present treatments had functional effects as assessed with uterine weights, ovariectomy and estrogen-receptor directed drugs had no effect on hippocampal 5-HT(1A) receptors as compared to 5-HT(2A) receptors previously reported.
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PMID:Effect of chronic estradiol, tamoxifen or raloxifene treatment on serotonin 5-HT1A receptor. 1267 Jul 5

Accumulated clinical and basic evidence suggests that gonadal steroids affect the onset and progression of several neurodegenerative diseases and schizophrenia, and the recovery from traumatic neurological injury such as stroke. Thus, our view on gonadal hormones in neural function must be broadened to include not only their function in neuroendocrine regulation and reproductive behaviors, but also to include a direct participation in response to degenerative disease or injury. Recent findings indicate that the brain up-regulates both estrogen synthesis and estrogen receptor expression at sites of injury. Genetic or pharmacological inactivation of aromatase, the enzyme involved in estrogen synthesis, indicates that the induction of this enzyme in the brain after injury has a neuroprotective role. Some of the mechanisms underlying the neuroprotective effects of estrogen may be independent of the classically defined nuclear estrogen receptors (ERs). Other neuroprotective effects of estrogen do depend on the classical nuclear ERs, through which estrogen alters expression of estrogen responsive genes that play a role in apoptosis, axonal regeneration, or general trophic support. Yet another possibility is that non-classical ERs in the membrane or cytoplasm alter phosphorylation cascades, such as those involved in the signaling of insulin-like growth factor-1 (IGF-1). Indeed, ERs and IGF-1 receptor interact in the activation of PI3K and MAPK signaling cascades and in the promotion of neuroprotection. The decrease in estrogen and IGF-1 levels with aging may thus result in an increased risk for neuronal pathological alterations after different forms of brain injury.
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PMID:Estrogen and brain vulnerability. 1282 4

In trying to rectify the differences in the risk, onset, and progression of neurodegenerative diseases between men and women, the gonadal hormone estrogen has been the primary focus of investigation for many years. Although this gender difference may encompass disparate and overlapping reasons, estrogen and signaling events mediated by its receptor have been shown to be neuroprotective in a number of neurodegenerative disease models such as Alzheimer's, Parkinson's, and Schizophrenia. Although data from human studies remains highly controversial, a large body of research findings suggests that this hormone plays a pivotal role in retarding and preventing the formation of neurodegenerative diseases through its receptor. By activating common intracellular signaling pathways and initiating "cross talk" with neurotrophins, estrogen plays an influential role in neuronal survival from injuries induced by ischemia or other environmental insults. Gaining a better understanding of these estrogen receptor mediated neuroprotective mechanisms may lead to new therapeutic strategies for the treatment or prevention of neurodegenerative diseases.
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PMID:The role of the estrogen in neuroprotection: implications for neurodegenerative diseases. 1452 47

There is a wealth of historical and circumstantial evidence to suggest that female patients with schizophrenia may suffer from a deficit in estrogenic function. The prolactin-inducing properties of most antipsychotic drugs, and subsequent negative feedback on estrogen levels, is in keeping with this. The functions of estrogen, its complex receptor organization and its numerous actions are the focus of ongoing research activity. Of particular interest are its neuroprotective properties, particularly with regard to cognitive impairment, and its involvement with neurotransmitter systems, which are the substrate for psychotropic drugs. Estrogen has now been used as an adjunct to standard antipsychotic medication in quite a few studies of female schizophrenia patients. However, most of these are not double-blind, randomized, controlled trials. Only two relatively small double-blind, randomized clinical trials returned positive results: one long-term study that selected for hypoestrogenism reported negative findings. Furthermore, recent evidence of the risks of long-term hormone replacement therapy is of concern. The advent of specific estrogen receptor modulators, which may avoid excess risks of cancer and cardiovascular events, will have little to add to schizophrenia treatment if estrogen is, essentially, devoid of any specific antipsychotic or adjuvant mechanism of action relevant to the pathophysiology of this disorder.
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PMID:Relationship between estrogen and schizophrenia. 1718 96

Mounting evidence from clinical and basic research suggests that estrogen signaling may be altered in the brains of people with schizophrenia. Previously, we found that DNA sequence variation in the estrogen receptor (ER) alpha gene, lower ERalpha mRNA levels, and/or blunted ERalpha signaling is associated with schizophrenia. In this study, we asked whether the naturally occurring truncated ERalpha isoform, Delta7, which acts as a dominant negative, can attenuate gene expression induced by the wild-type (WT) receptor in an estrogen-dependent manner in neuronal (SHSY5Y) and non-neuronal (CHOK1 and HeLa) cells. In addition, we determined the extent to which ERalpha interacts with NRG1-ErbB4, a leading schizophrenia susceptibility pathway. Reductions in the transcriptionally active form of ErbB4 comprising the intracytoplasmic domain (ErbB4-ICD) have been found in schizophrenia, and we hypothesized that ERalpha and ErbB4 may converge to control gene expression. In the present study, we show that truncated Delta7-ERalpha attenuates WT-ERalpha-driven gene expression across a wide range of estrogen concentrations in cells that express functional ERalpha at base line or upon co-transfection of full-length ERalpha. Furthermore, we find that ErbB4-ICD can potentiate the transcriptional activity of WT-ERalpha at EREs in two cell lines and that this potentiation effect is abolished by the presence of Delta7-ERalpha. Immunofluorescence microscopy revealed nuclear co-localization of WT-ERalpha, Delta7-ERalpha, and ErbB4-ICD, whereas immunoprecipitation assays showed direct interaction. Our findings demonstrate convergence between ERalpha and ErbB4-ICD in the transcriptional control of ERalpha-target gene expression and suggest that this may represent a convergent pathway that may be disrupted in schizophrenia.
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PMID:Transcriptional interaction of an estrogen receptor splice variant and ErbB4 suggests convergence in gene susceptibility pathways in schizophrenia. 1943 7

Tamoxifen resistance is a major clinical problem in the treatment of estrogen receptor alpha-positive breast tumors. It is, at present, unclear what exactly causes tamoxifen resistance. For decades, chlorpromazine has been used for treating psychotic diseases, such as schizophrenia. However, the compound is now also recognized as a multitargeting drug with diverse potential applications, for example, it has antiproliferative properties and it can reverse resistance toward antibiotics in bacteria. Furthermore, chlorpromazine can reverse multidrug resistance caused by overexpression of P-glycoprotein in cancer cells. In this study, we have investigated the effect of chlorpromazine on tamoxifen response of human breast cancer cells. We found that chlorpromazine worked synergistically together with tamoxifen with respect to reduction of cell growth and metabolic activity, both in the antiestrogen-sensitive breast cancer cell line, MCF-7, and in a tamoxifen-resistant cell line, established from the MCF-7 cells. Tamoxifen-sensitive and tamoxifen-resistant cells were killed equally well by combined treatment with chlorpromazine and tamoxifen. This synergistic effect could be prevented by addition of estrogen, suggesting that chlorpromazine enhances the effect of tamoxifen through an estrogen receptor-mediated mechanism. To investigate this putative mechanism, we applied biophysical techniques to simple model membranes in the form of unilamellar liposomes of well-defined composition and found that chlorpromazine interacts strongly with lipid bilayers of different composition leading to increased permeability. This implies that chlorpromazine can change influx properties of membranes hence suggesting that chlorpromazine may be a promising chemosensitizing compound for enhancing the cytotoxic effect of tamoxifen.
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PMID:The antipsychotic drug chlorpromazine enhances the cytotoxic effect of tamoxifen in tamoxifen-sensitive and tamoxifen-resistant human breast cancer cells. 1958 8

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