Pre-reproductive stress in adolescent female rats alters maternal care and DNA methylation patterns across generations

Stress during development affects maternal behavior and offspring phenotypes. Stress in adolescence is particularly consequential on brain development and maturation, and is implicated in several psychiatric disorders. We previously showed that pre-reproductive stress (PRS) in female adolescent rats affects behavior and corticotropin releasing hormone receptor 1 (CRHR1) expression in first- (F1) and second- (F2) generation offspring. We further showed that offspring phenotypes are partially reversed by post-stress treatment with fluoxetine (FLX) or the CRHR1 antagonist NBI27914 (NBI). Epigenetic processes, such as DNA methylation, are implicated in the stress response and interact with maternal care quality across generations. Here, we asked whether PRS and FLX or NBI exposure would affect maternal care and global DNA methylation in the brains of exposed dams and their adult F1 and paternally-derived F2 offspring. We found that PRS decreased self-care while increasing pup-care behaviors. PRS also increased DNA methylation in the amygdala of dams and their F1 male offspring, but decreased it in F2 females. Drug treatment had no effect on maternal care, but affected DNA methylation patterns in F0 and F1 generations. Furthermore, PRS altered the expression of DNA methylating enzymes in brain, blood and oocytes. Finally, maternal care variables differentially predicted methylation levels in PRS and control offspring. Thus, the effects of adolescent stress are long-lasting and impact methylation levels across three generations. Combined with our findings of epigenetic changes in PRS-exposed oocytes, the present data imply that biological changes and social mechanisms act in concert to influence adult offspring phenotypes.

Posttreatment Strategy Against Hypoxia and Ischemia Based on Selective Targeting of Nonnuclear Estrogen Receptors with PaPE-1

Newly synthesized Pathway Preferential Estrogen-1 (PaPE-1) selectively activates membrane estrogen receptors (mERs), namely, mERα and mERβ, and has been shown to evoke neuroprotection; however, its effectiveness in protecting brain tissue against hypoxia and ischemia has not been verified in a posttreatment paradigm. This is the first study showing that a 6-h delayed posttreatment with PaPE-1 inhibited hypoxia/ischemia-induced neuronal death, as indicated by neutral red uptake in mouse primary cell cultures in vitro. The effect was accompanied by substantial decreases in neurotoxicity and neurodegeneration in terms of LDH release and Fluoro-Jade C staining of damaged cells, respectively. The mechanisms of the neuroprotective action of PaPE-1 also involved apoptosis inhibition demonstrated by normalization of both mitochondrial membrane potential and expression levels of apoptosis-related genes and proteins such as Fas, Fasl, Bcl2, FAS, FASL, BCL2, BAX, and GSK3β. Furthermore, PaPE-1-evoked neuroprotection was mediated through a reduction in ROS formation and restoration of cellular metabolic activity that had become dysregulated due to hypoxia and ischemia. These data provide evidence that targeting membrane non-GPER estrogen receptors with PaPE-1 is an effective therapy that protects brain neurons from hypoxic/ischemic damage, even when applied with a 6-h delay from injury onset.

Neuroprotective effect of 3,3'-Diindolylmethane against perinatal asphyxia involves inhibition of the AhR and NMDA signaling and hypermethylation of specific genes

Each year, 1 million children die due to perinatal asphyxia; however, there are no effective drugs to protect the neonatal brain against hypoxic/ischemic damage. In this study, we demonstrated for the first time the neuroprotective capacity of 3,3’-diindolylmethane (DIM) in an in vivo model of rat perinatal asphyxia, which has translational value and corresponds to hypoxic/ischemic episodes in human newborns. Posttreatment with DIM restored the weight of the ipsilateral hemisphere and normalized cell number in the brain structures of rats exposed to perinatal asphyxia. DIM also downregulated the mRNA expression of HIF1A-regulated Bnip3 and Hif1a which is a hypoxic marker, and the expression of miR-181b which is an indicator of perinatal asphyxia. In addition, DIM inhibited apoptosis and oxidative stress accompanying perinatal asphyxia through: downregulation of FAS, CASP-3, CAPN1, GPx3 and SOD-1, attenuation of caspase-9 activity, and upregulation of anti-apoptotic Bcl2 mRNA. The protective effects of DIM were accompanied by the inhibition of the AhR and NMDA signaling pathways, as indicated by the reduced expression levels of AhR, ARNT, CYP1A1, GluN1 and GluN2B, which was correlated with enhanced global DNA methylation and the methylation of the Ahr and Grin2b genes. Because our study provided evidence that in rat brain undergoing perinatal asphyxia, DIM predominantly targets AhR and NMDA, we postulate that compounds that possess the ability to inhibit their signaling are promising therapeutic tools to prevent stroke.

Triclocarban impairs autophagy in neuronal cells and disrupts estrogen receptor signaling via hypermethylation of specific genes

Although an increasing body of evidence suggests that triclocarban, a phenyl ether classified as a contaminant of emerging concern, presents a risk to development, there is limited data available on the potential interplay of triclocarban with the developing mammalian nervous system. This study was aimed to investigate the impact of environmentally pervasive chemical triclocarban on autophagy and estrogen receptor-mediated signaling pathways in mouse neurons. The study showed that triclocarban impaired autophagy and disrupted estrogen receptor signaling in mouse embryonic neurons in primary culture. Triclocarban used at environmentally relevant concentrations inhibited the mRNA and protein expression of ESR1 and GPER1 but not ESR2. The triclocarban-induced decrease in the expression of estrogen receptors was supported by the colocalization of the receptors in mouse neurons and corresponded to hypermethylation of the Esr1 and Gper1 genes. Selective antagonists increased the effects of triclocarban, which suggests that the neurotoxic effects of triclocarban, in addition to decreasing estrogen receptor expression, are mediated via inhibition of the neuroprotective capacity of the receptors. Furthermore, Becn1 and Atg7 siRNAs potentiated the caspase-3-dependent effect of triclocarban, which points to triclocarban-induced impairment of autophagy. Indeed, triclocarban dysregulated the expression of autophagy-related genes, and caused a time-dependent inhibition of the mRNA expression of Becn1, Map1lc3a, Map1lc3b, Nup62, and Atg7, which was correlated with a decrease in the protein levels of MAP1LC3B, BECN1 and autophagosomes, but not NUP62 protein level which was increased. Intriguingly, the Esr1 and Gper1 siRNAs did not affect the level of autophagosomes, suggesting that the triclocarban-induced impairment of autophagy is independent of the triclocarban-induced disruption of estrogen receptor signaling in mammalian neurons. Because our data provided evidence that triclocarban has the capacity to impair autophagy and disrupt estrogen receptor signaling in brain neurons at an early developmental stage, we postulate to categorize the compound as a neurodevelopmental risk factor.

Triclocarban Disrupts the Epigenetic Status of Neuronal Cells and Induces AHR/CAR-Mediated Apoptosis

Triclocarban is a phenyl ether that has recently been classified as a contaminant of emerging concern. Evidence shows that triclocarban is present in human tissues, but little is known about the impact of triclocarban on the nervous system, particularly at early developmental stages. This study demonstrated that triclocarban that was used at environmentally relevant concentrations induced apoptosis in mouse embryonic neurons, inhibited sumoylation, and changed the epigenetic status, as evidenced by impaired activities of HDAC, sirtuins, and DNMT, global DNA hypomethylation, and alterations of methylation levels of bax, bcl2, Ahr, and Car genes. The use of selective antagonists and specific siRNAs, which was followed by the co-localization of aryl hydrocarbon receptor (AHR) and constitutive androstane receptor (CAR) in mouse neurons, points to the involvement of AHR and CAR in triclocarban-induced neurotoxicity. A 24-h treatment with triclocarban enhanced protein levels of the receptors which was paralleled by Car hypomethylation and Ahr hypermethylation. Car hypomethylation is in line with global DNA hypomethylation and explains the increased mRNA and protein levels of CAR in response to triclocarban. Ahr hypermethylation could reflect reduced Ahr mRNA expression and corresponds to lowered protein levels after 3- and 6-h exposures to triclocarban that is likely related to proteasomal degradation of activated AHR. We hypothesize that the triclocarban-induced apoptosis in mouse neurons and the disruption of epigenetic status involve both AHR- and CAR-mediated effects, which may substantiate a fetal basis of the adult onset of neurological diseases; however, the expression of the receptors is regulated in different ways.

Bazedoxifene and raloxifene protect neocortical neurons undergoing hypoxia via targeting ERα and PPAR-γ

Selective estrogen receptor modulators (SERMs) such as bazedoxifene and raloxifene are recognized to mainly act via estrogen receptors (ERs), but there is no study examining the involvement of PPAR-γ in their actions, especially in neurons undergoing hypoxia. Little is also known about age-dependent actions of the SERMs on neuronal tissue challenged with hypoxia. In this study, bazedoxifene and raloxifene protected neocortical cells against hypoxia at early and later developmental stages. Both SERMs evoked caspase-3-independent neuroprotection and increased protein levels of ERα (66 and 46 kDa isoforms) and PPAR-γ. In addition, bazedoxifene enhanced expression of ERα-regulated Cyp19a1 mRNA. Using double siRNA silencing, for the first time we demonstrated a key role of ERα and PPAR-γ in the neuroprotective action of the SERMs in neocortical neurons undergoing hypoxia. This study provides prospects for the development of a new therapeutic strategies against hypoxic brain injury that selectively target ERα and/or PPAR-γ.

Depressive-like effect of prenatal exposure to DDT involves global DNA hypomethylation and impairment of GPER1/ESR1 protein levels but not ESR2 and AHR/ARNT signaling

Several lines of evidence suggest that exposures to Endocrine Disrupting Chemicals (EDCs) such as pesticides increase the risks of neuropsychiatric disorders. Despite extended residual persistence of dichlorodiphenyltrichloroethane (DDT) in the environment, the mechanisms of perinatal actions of DDT that could account for adult-onset of depression are largely unknown. This study demonstrated the isomer-specific induction of depressive-like behavior and impairment of Htr1a/serotonin signaling in one-month-old mice that were prenatally exposed to DDT. The effects were reversed by the antidepressant citalopram as evidenced in the forced swimming (FST) and tail suspension (TST) tests in the male and female mice. Prenatally administered DDT accumulated in mouse brain as determined with gas chromatography and tandem mass spectrometry, led to global DNA hypomethylation, and altered the levels of methylated DNA in specific genes. The induction of depressive-like behavior and impairment of Htr1a/serotonin signaling were accompanied by p,p'-DDT-specific decrease in the levels of estrogen receptors i.e. ESR1 and/or GPER1 depending on sex. In contrast, o,p'-DDT did not induce depressive-like effects and exhibited quite distinct pattern of biochemical alterations that was related to aryl hydrocarbon receptor (AHR), its nuclear translocator ARNT, and ESR2. Exposure to o,p'-DDT increased AHR expression in male and female brains, and reduced expression levels of ARNT and ESR2 in the female brains. The evolution of p,p'-DDT-induced depressive-like behavior was preceded by attenuation of Htr1a and Gper1/GPER1 expression as observed in the 7-day-old mouse pups. Because p,p'-DDT caused sex- and age-independent attenuation of GPER1, we suggest that impairment of GPER1 signaling plays a key role in the propagation of DDT-induced depressive-like symptoms.

Apoptosis Induced by the UV Filter Benzophenone-3 in Mouse Neuronal Cells Is Mediated via Attenuation of Erα/Pparγ and Stimulation of Erβ/Gpr30 Signaling

Although benzophenone-3 (BP-3) has frequently been reported to play a role in endocrine disruption, there is insufficient data regarding the impact of BP-3 on the nervous system, including its possible adverse effects on the developing brain. Our study demonstrated that BP-3 caused neurotoxicity and activated apoptosis via an intrinsic pathway involving the loss of mitochondrial membrane potential and the activation of caspases-9 and -3 and kinases p38/MAPK and Gsk3β. These biochemical alterations were accompanied by ROS production, increased apoptotic body formation and impaired cell survival, and by an upregulation of the genes involved in apoptosis. The BP-3-induced effects were tissue-specific and age-dependent with the most pronounced effects observed in neocortical cells at 7 days in vitro. BP-3 changed the messenger RNA (mRNA) expression levels of Erα, Erβ, Gpr30, and Pparγ in a time-dependent manner. At 3 h of exposure, BP-3 downregulated estrogen receptor mRNAs but upregulated Pparγ mRNA. After prolonged exposures, BP-3 downregulated the receptor mRNAs except for Erβ mRNA that was upregulated. The BP-3-induced patterns of mRNA expression measured at 6 and 24 h of exposure reflected alterations in the protein levels of the receptors and paralleled their immunofluorescent labeling. Erα and Pparγ agonists diminished, but Erβ and Gpr30 agonists stimulated the BP-3-induced apoptotic and neurotoxic effects. Receptor antagonists caused the opposite effects, except for ICI 182,780. This is in line with a substantial reduction in the effects of BP-3 in cells with siRNA-silenced Erβ/Gpr30 and the maintenance of BP-3 effects in Erα- and Pparγ siRNA-transfected cells. We showed for the first time that BP-3-affected mRNA and protein expression levels of Erα, Erβ, Gpr30, and Pparγ, paralleled BP-3-induced apoptosis and neurotoxicity. Therefore, we suggest that BP-3-evoked apoptosis of neuronal cells is mediated via attenuation of Erα/Pparγ and stimulation of Erβ/Gpr30 signaling.

RXRα, PXR and CAR xenobiotic receptors mediate the apoptotic and neurotoxic actions of nonylphenol in mouse hippocampal cells

In the present study, we investigated the role of the retinoid X receptor (RXR), the pregnane X receptor (PXR) and the constitutive androstane receptor (CAR), in the apoptotic and toxic effects of nonylphenol in mouse primary neuronal cell cultures. Our study demonstrated that nonylphenol activated caspase-3 and induced lactate dehydrogenase (LDH) release in hippocampal cells, which was accompanied by an increase in the mRNA expression and protein levels of RXRα, PXR and CAR. Nonylphenol stimulated Rxra, Pxr, and Car mRNA expression. These effects were followed by increase in the protein levels of particular receptors. Immunofluorescence labeling revealed the cellular distribution of RXRα, PXR and CAR in hippocampal neurons in response to nonylphenol, shortening of neurites and cytoplasmic shrinking, as indicated by MAP2 staining. It also showed NP-induced translocation of receptor-specific immunofluorescence from cytoplasm to the nucleus. The use of specific siRNAs demonstrated that Rxra-, Pxr-, and Car-siRNA-transfected cells were less vulnerable to nonylphenol-induced activation of caspase-3 and LDH, thus confirming the key involvement of RXRα/PXR/CAR signaling pathways in the apoptotic and neurotoxic actions of nonylphenol. These new data give prospects for the targeting xenobiotic nuclear receptors to protect the developing nervous system against endocrine disrupting chemicals.

Selective Aryl Hydrocarbon Receptor Modulator 3,3'-Diindolylmethane Impairs AhR and ARNT Signaling and Protects Mouse Neuronal Cells Against Hypoxia

The neuroprotective potential of 3,3'-diindolylmethane (DIM), which is a selective aryl hydrocarbon receptor modulator, has recently been shown in cellular and animal models of Parkinson's disease and lipopolysaccharide-induced inflammation. However, there are no data concerning the protective capacity and mechanisms of DIM action in neuronal cells exposed to hypoxia. The aim of the present study was to investigate the neuroprotective potential of DIM against the hypoxia-induced damage in mouse hippocampal cells in primary cultures, with a particular focus on DIM interactions with the aryl hydrocarbon receptor (AhR), its nuclear translocator ARNT, and estrogen receptor β (ERβ). In the present study, 18 h of hypoxia induced apoptotic processes, in terms of the mitochondrial membrane potential, activation of caspase-3, and fragmentation of cell nuclei. These effects were accompanied by substantial lactate dehydrogenase release and neuronal cell death. The results of the present study demonstrated strong neuroprotective and anti-apoptotic actions of DIM in hippocampal cells exposed to hypoxia. In addition, DIM decreased the Ahr and Arnt mRNA expression and stimulated Erβ mRNA expression level. DIM-induced mRNA alterations were mirrored by changes in protein levels, except for ERβ, as detected by ELISA, Western blotting, and immunofluorescence labeling. We also demonstrated that DIM decreased the expression of AhR-regulated CYP1A1. Using specific siRNAs, we provided evidence that impairment of AhR and ARNT, but not ERβ plays a key role in the neuroprotective action of DIM against hypoxia-induced cell damage. This study may have implication for identifying new agents that could protect neurons against hypoxia by targeting AhR/ARNT signaling.

Neuroprotective action of raloxifene against hypoxia-induced damage in mouse hippocampal cells depends on ERα but not ERβ or GPR30 signalling

Raloxifene is the selective estrogen receptor modulator (SERM) currently used in clinical practice to activate estrogen receptors (ERs) in bone tissue and to antagonise ERs in breast and uterine cancers. Little is known, however, about mechanisms of action of raloxifene on hypoxia-induced neuronal cell damage. The aim of the present study was to investigate the neuroprotective potential of raloxifene against hypoxia-induced damage of mouse hippocampal cells in primary cultures, with a particular focus on raloxifene interactions with the classical nuclear ERs (ERα, ERβ) and the recently identified membrane ER G-protein-coupled receptor 30 (GPR30). In this study, 18 h of hypoxia increased hypoxia inducible factor 1 alpha (Hif1α) mRNA expression and induced apoptotic processes, such as loss of the mitochondrial membrane potential, activation of caspase-3 and fragmentation of cell nuclei based on Hoechst 33342 staining. These effects were accompanied by reduced ATPase and intracellular esterase activities as well as substantial lactate dehydrogenase (LDH) release from cells exposed to hypoxia. Our study demonstrated strong neuroprotective and anti-apoptotic caspase-3-independent actions of raloxifene in hippocampal cells exposed to hypoxia. Raloxifene also inhibited the hypoxia-induced decrease in Erα mRNA expression and attenuated the hypoxia-induced rise in Erβ and Gpr30 mRNA expression levels. Impact of raloxifene on hypoxia-affected Erα mRNA was mirrored by fluctuations in the protein level of the receptor as demonstrated by Western blot and immunofluorescent labelling. Raloxifene-induced changes in Erβ mRNA expression level were in parallel with ERβ immunofluorescent labeling. However, changes in Gpr30 mRNA level were not reflected by changes in the protein levels measured either by ELISA, Western blot or immunofluorescent staining at 24h post-treatment. Using specific siRNAs, we provided evidence for a key involvement of ERα, but not ERβ or GPR30 in neuroprotective action of raloxifene against hypoxia-induced cell damage. This study may have implications for the treatment or prevention of hypoxic brain injury and the administration of current or new generations of SERMs specific to ERα. This article is part of a Special Issue entitled "Sex steroids and brain disorders".

Apoptotic and neurotoxic actions of 4-para-nonylphenol are accompanied by activation of retinoid X receptor and impairment of classical estrogen receptor signaling

4-para-Nonylphenol (NP) is a non-ionic surfactant that has widespread and uncontrolled distribution in the environment. Little is known, however, about its actions on neuronal cells during critical developmental periods. This study aimed to investigate the mechanisms underlying the apoptotic and toxic actions of NP on mouse embryonic neuronal cells and the possible interactions of NP with estrogen receptor (ER)- and retinoid X receptor (RXR)-mediated intracellular signaling. Treatment of mouse hippocampal neuronal cell cultures with NP (5 and 10μM) induced apoptotic and neurotoxic effects. The 2 and 7 day-old mouse hippocampal cultures were vulnerable to 5 and 10μM NP, whereas 12 day-old cultures responded only to the highest concentration of NP, thus suggesting an age-dependent action of the chemical on neuronal cells. The use of specific inhibitors did not support the involvement of calpains in NP-induced apoptosis, but indicated caspase-8- and caspase-9-dependent effects of NP. Specific ER antagonists MPP and PHTPP potentiated the NP-induced loss of mitochondrial membrane potential and increase in lactate dehydrogenase (LDH) release whereas, ER agonists PPT and DPN inhibited these effects. RXR antagonist HX531 diminished the NP-evoked loss of mitochondrial membrane potential, the activity of caspase-3 and LDH release. In addition, exposure to NP inhibited ERα- and ERβ-specific immunofluorescence but stimulated RXR-specific immunolabeling in mouse hippocampal cells. In conclusion, our study demonstrated that the apoptotic and toxic actions of NP on neuronal cells in early development is accompanied by an impairment of ER- and stimulation of RXR-mediated signaling pathways. Taking into account NP-induced alterations in mRNA expression levels of particular types of RXRs, we suggest that NP affected mainly RXRα and RXRβ, but not RXRγ signaling.

Isomer-nonspecific action of dichlorodiphenyltrichloroethane on aryl hydrocarbon receptor and G-protein-coupled receptor 30 intracellular signaling in apoptotic neuronal cells

Extended residual persistence of the pesticide dichlorodiphenyltrichloroethane (DDT) raises concerns about its long-term neurotoxic effects. Little is known, however, about DDT toxicity during the early stages of neural development. This study demonstrated that DDT-induced apoptosis of mouse embryonic neuronal cells is a caspase-9-, caspase-3-, and GSK-3β-dependent process, which involves p,p'-DDT-specific impairment of classical ERs. It also provided evidence for DDT-isomer-nonspecific alterations of AhR- and GPR30-mediated intracellular signaling, including changes in the levels of the receptor and receptor-regulated mRNAs, and also changes in the protein levels of the receptors. DDT-induced stimulation of AhR-signaling and reduction of GPR30-signaling were verified using selective ligands and specific siRNAs. Co-localization of the receptors was demonstrated with confocal microscopy, and the presence of functional GPR30 was detected by electrophysiology. This study demonstrates that stimulation of AhR-signaling and impairment of GPR30-signaling play important roles in the propagation of DDT-induced apoptosis during the early stages of neural development.

The key involvement of estrogen receptor β and G-protein-coupled receptor 30 in the neuroprotective action of daidzein

Phytoestrogens have received considerable attention because they provide an array of beneficial effects, such as neuroprotection. To better understand the molecular and functional link between phytoestrogens and classical as well as membrane estrogen receptors (ERs), we investigated the effect of daidzein on the glutamate-mediated apoptotic pathway. Our study demonstrated that daidzein (0.1-10μM) inhibited the pro-apoptotic and neurotoxic effects caused by glutamate treatment. Hippocampal, neocortical and cerebellar tissues responded to the inhibitory action of daidzein on glutamate-activated caspase-3 and lactate dehydrogenase (LDH) release in a similar manner. Biochemical data were supported at the cellular level by Hoechst 33342 and calcein AM staining. The sensitivity of neuronal cells to daidzein-mediated protection was most prominent in hippocampal cultures at an early stage of development 7th day in vitro. A selective estrogen receptor β (ERβ) antagonist, 4-[2-phenyl-5,7-bis(trifluoromethyl)pyrazolo[1,5,-a]pyrimidin-3-yl]phenol (PHTPP), and a selective G-protein-coupled receptor 30 (GPR30) antagonist, 3aS(∗),4R(∗),9bR(∗))-4-(6-Bromo-1,3-benzodioxol-5-yl)-3a,4,5,9b-3H-cyclopenta[c]quinoline (G15), reversed the daidzein-mediated inhibition of glutamate-induced loss of membrane mitochondrial potential, caspase-3 activity, and LDH release. A selective ERα antagonist, methyl-piperidino-pyrazole (MPP), did not influence any anti-apoptotic effect of daidzein. However, a high-affinity estrogen receptor antagonist, 7α,17β-[9-[(4,4,5,5,5-pentafluoropentyl)sulfinyl]nonyl]estra-1,3,5(10)-triene-3,17-diol (ICI) 182,780, and a selective GPR30 agonist, (±)-1-[(3aR(∗),4S(∗),9bS(∗))-4-(6-bromo-1,3-benzodioxol-5-yl)-3a,4,5,9b-tetrahydro-3H-cyclopenta[c]quinolin-8-yl]-ethanone (G1), intensified the protective action of daidzein against glutamate-induced loss of membrane mitochondrial potential and LDH release. In siRNA ERβ- and siRNA GPR30-transfected cells, daidzein did not inhibit the glutamate-induced effects. Twenty-four hour exposure to glutamate did not affect the cellular distribution of ERβ and GPR30, but caused greater than 100% increase in the levels of the receptors. Co-treatment with daidzein decreased the level of ERβ without significant changing of the GPR30 protein level. Here, we elucidated neuroprotective effects of daidzein at low micromolar concentrations and demonstrated that the phytoestrogens may exert their effects through novel extranuclear GPR30 and the classical transcriptionally acting ERβ. These studies uncover key roles of the ERβ and GPR30 intracellular signaling pathways in mediating the anti-apoptotic action of daidzein and may provide insight into new strategies to treat or prevent neural degeneration.

Endocrine disrupters: a review of some sources, effects, and mechanisms of actions on behaviour and neuroendocrine systems

Some environmental contaminants interact with hormones and may exert adverse consequences as a result of their actions as endocrine disrupting chemicals (EDCs). Exposure in people is typically a result of contamination of the food chain, inhalation of contaminated house dust or occupational exposure. EDCs include pesticides and herbicides (such as dichlorodiphenyl trichloroethane or its metabolites), methoxychlor, biocides, heat stabilisers and chemical catalysts (such as tributyltin), plastic contaminants (e.g. bisphenol A), pharmaceuticals (i.e. diethylstilbestrol; 17α-ethinylestradiol) or dietary components (such as phytoestrogens). The goal of this review is to address the sources, effects and actions of EDCs, with an emphasis on topics discussed at the International Congress on Steroids and the Nervous System. EDCs may alter reproductively-relevant or nonreproductive, sexually-dimorphic behaviours. In addition, EDCs may have significant effects on neurodevelopmental processes, influencing the morphology of sexually-dimorphic cerebral circuits. Exposure to EDCs is more dangerous if it occurs during specific 'critical periods' of life, such as intrauterine, perinatal, juvenile or puberty periods, when organisms are more sensitive to hormonal disruption, compared to other periods. However, exposure to EDCs in adulthood can also alter physiology. Several EDCs are xenoestrogens, which can alter serum lipid concentrations or metabolism enzymes that are necessary for converting cholesterol to steroid hormones. This can ultimately alter the production of oestradiol and/or other steroids. Finally, many EDCs may have actions via (or independent of) classic actions at cognate steroid receptors. EDCs may have effects through numerous other substrates, such as the aryl hydrocarbon receptor, the peroxisome proliferator-activated receptor and the retinoid X receptor, signal transduction pathways, calcium influx and/or neurotransmitter receptors. Thus, EDCs, from varied sources, may have organisational effects during development and/or activational effects in adulthood that influence sexually-dimorphic, reproductively-relevant processes or other functions, by mimicking, antagonising or altering steroidal actions.

DDT- and DDE-induced disruption of ovarian steroidogenesis in prepubertal porcine ovarian follicles: a possible interaction with the main steroidogenic enzymes and estrogen receptor beta

We evaluated impact of DDT isomers, o, p'- DDT [1, 1-dichloro-2, 2-bis (p, p'-chlorophenyl) ethylene] and p, p'-DDT [1, 1, 1-trichloro-2, 2-bis (p-chlorophenyl) ethane], and their metabolites, o, p'-DDE and p, p'-DDE, on ovarian steroidogenesis. All these compounds, except for p, p'-DDT, demonstrated estrogenic effects on steroid secretion in co-cultures of porcine prepubertal granulosa and theca cells. p,p'-DDT decreased progesterone and estradiol release, which was reversed by the addition of testosterone. In contrast, o, p'-DDT inhibited progesterone secretion with parallel stimulation of basal and testosterone-stimulated estradiol release. DDEs stimulated progesterone and estradiol secretion. The fluorometric assay confirmed that p,p'-DDE, o,p'-DDT, and o,p'-DDE stimulated aromatase activity. Western blots indicated that o,p-DDT and o,p'-DDE diminished the expression of estrogen receptor beta (ERbeta). This study demonstrated the isomer-dependent action of DDT in pig ovarian cells. We propose that DDT could disrupt ovarian steroidogenesis either by interfering with main steroidogenic enzymes or affecting ERbeta.

Genistein inhibits glutamate-induced apoptotic processes in primary neuronal cell cultures: an involvement of aryl hydrocarbon receptor and estrogen receptor/glycogen synthase kinase-3beta intracellular signaling pathway

Phytoestrogens prevent neuronal damage, however, mechanism of their neuroprotective action has not been fully elucidated. This study aimed to evaluate the effects of genistein on glutamate-induced apoptosis in mouse primary neuronal cell cultures. Glutamate (1 mM) enhanced caspase-3 activity and lactate dehydrogenase (LDH) release in the hippocampal, neocortical and cerebellar neurons in time-dependent manner, and these data were confirmed at the cellular level with Hoechst 33342 and calcein AM staining. Genistein (10-10,000 nM) significantly inhibited glutamate-induced apoptosis, and the effect of this isoflavone was most prominent in the hippocampal cells. Next, we studied an involvement of estrogen and aryl hydrocarbon receptors in anti-apoptotic effects of genistein. A high-affinity estrogen receptor antagonist, ICI 182, 780 (1 microM), reversed, whereas less specific antagonist/partial agonist, tamoxifen (1 microM), either intensified or partially inhibited genistein effects. Aryl hydrocarbon receptor antagonist, alpha-naphthoflavone (1 microM), exhibited a biphasic action: it enhanced genistein action toward a short-term exposure (3 h) to glutamate, but antagonized genistein action toward prolonged exposure (24 h) to that insult. SB 216763 (1 microM), which preferentially inhibits glycogen synthase kinase-3beta (GSK-3beta), potentiated genistein effects. These data point to strong effects of genistein at low micromolar concentrations in various brain tissues against glutamate-evoked apoptosis. Moreover, this study provided evidence for involvement of aryl hydrocarbon receptor and estrogen receptor/GSK-3beta intracellular signaling pathway in anti-apoptotic action of genistein.

Impact of 17beta-estradiol on cytokine-mediated apoptotic effects in primary hippocampal and neocortical cell cultures

Estrogens are developmental regulators of mitochondrial apoptotic pathway in the central nervous system, but little is known about their involvement in cytokine-induced apoptosis. In the present study, we evaluated effects of 17beta-estradiol on pro-inflammatory cytokine- and staurosporine-mediated activation of caspase-3 and LDH-release in primary neuronal/glial cell cultures of mouse hippocampal and neocortical cells at different stages of their development in vitro. Enzyme activities were determined with colorimetric methods 6 h, 14 h, 24 h, and 48 h after exposure to the apoptotic agents. Biochemical data were supported at the cellular level by Hoechst 33342 and MAP-2 stainings, which were carried out 48 h after the treatment. Cytokines (co-treatment with Il-1beta and TNFalpha; 1 ng/ml) increased caspase-3 activity in the hippocampal and neocortical cells up to over 200% of control values, and these effects were mostly observed on 2 and 7 days in vitro (DIV). Moderate, but significant cytokine-mediated increase in LDH-release was demonstrated in both tissues, especially on 7 and 12 DIV. Estradiol (100 nM) inhibited the activation of caspase-3 at early stage of development (2 DIV) in the hippocampal, but not in the neocortical cultures. The cytokine-induced activation of caspase-3 and LDH-release was inhibited by estradiol in estrogen receptor-independent way. These data point to a possible role of estrogens as non-estrogen receptor-related inhibitors of cytokine-activated apoptotic pathway in the developing central nervous system.

The mechanism of 1,2,3,4-tetrahydroisoquinolines neuroprotection: the importance of free radicals scavenging properties and inhibition of glutamate-induced excitotoxicity

1-Methyl-1,2,3,4-tetrahydroisoquinoline (1MeTIQ), unlike several other tetrahydroisoquinolines, displays neuroprotective properties. To elucidate this action we compared the effects of 1MeTIQ with 1,2,3,4-tetrahydroisoquinoline (TIQ), a compound sharing many activities with 1MeTIQ (among them reducing free radicals formed during dopamine catabolism), but offering no clear neuroprotection. We found that the compounds similarly inhibit free-radical generation in an abiotic system, as well as indices of neurotoxicity (caspase-3 activity and lactate dehydrogenase release) induced by glutamate in mouse embryonic primary cell cultures (a preparation resistant to NMDA toxicity). However, in granular cell cultures obtained from 7-day-old rats, 1MeTIQ prevented the glutamate-induced cell death and 45Ca2+ influx, whereas TIQ did not. This suggested a specific action of 1MeTIQ on NMDA receptors, which was confirmed by the inhibition of [3H]MK-801 binding by 1MeTIQ. Finally, we demonstrated in an in vivo microdialysis experiment that 1MeTIQ prevents kainate-induced release of excitatory amino acids from the rat frontal cortex. Our results indicate that 1MeTIQ, in contrast to TIQ, offers a unique and complex mechanism of neuroprotection in which antagonism to the glutamatergic system may play a very important role. The results suggest the potential of 1MeTIQ as a therapeutic agent in various neurodegenarative illnesses of the central nervous system.

Effect of NMDA on staurosporine-induced activation of caspase-3 and LDH release in mouse neocortical and hippocampal cells

To achieve a better understanding of developmentally regulated NMDA- and staurosporine-induced apoptotic processes, we investigated the concerted action of these agents on caspase-3 activity and LDH release in neocortical and hippocampal cell cultures at different stages in vitro (DIV). Hoechst 33342 and MAP-2 stainings were additionally employed to visualize apoptotic changes and cell damage. The vulnerability of neocortical cells to NMDA was more prominent at later culture stages, whereas hippocampal neurons were more susceptible to NMDA treatment at earlier stages. A persistent activation of caspase-3 by staurosporine was found at all experimental stages. Despite of certain differences in susceptibility to NMDA and staurosporine, both tissues responded to regulatory action of NMDA towards staurosporine-activated caspase-3 in a similar way. Combined treatment with NMDA and staurosporine resulted in a substantial increase in caspase-3 activity in neocortical and hippocampal neurons on 2 DIV. Additive effects were also observed in neocortical cultures on 12 DIV. In contrast, NMDA substantially inhibited staurosporine-induced caspase-3 activity on 7 DIV in neocortical and hippocampal cultures. Additionally, pro-apoptotic effects of 17beta-estradiol were attenuated by NMDA on 7 DIV. Changes in vulnerability to NMDA- and staurosporine-mediated activation of caspase-3 were not strictly related to LDH release. Our data revealed that NMDA can both enhance and inhibit the staurosporine-induced neuronal cell apoptosis. The pro-apoptotic effect of NMDA was exhibited at early and late culture stages, whereas the anti-apoptotic effect was transient occurring on 7 DIV only.

Effects of estrone on quisqualate-induced toxicity in primary cultures of rat cortical neurons

Estrogens exert protective effects against neurotoxic changes induced by over-activation of ionotrophic glutamate receptors, whereas little is known about their interaction with changes mediated by metabotropic glutamate receptors. We evaluated effects of estrone on quisqualate (QA)-induced toxicity in neuronal cell cultures on 7 and 12 day in vitro (DIV). Twenty four hour exposure to QA (150 microM and 300 microM) significantly decreased cell survival in 7 day old cultures, but the 12 day old cultures were more resistant to its toxicity. DNQX (10 microM), an AMPA/kainate receptor antagonist, partly attenuated the toxic effects of QA, whereas LY 367 385 (100 microM), a selective mGluR1a antagonist, completely reversed the above effect. QA did not activate, but suppressed spontaneous caspase-3-like activity. Estrone (100 nM and 500 nM) attenuated QA-mediated neurotoxic effects independently of estrogen receptors, as indicated with ICI 182, 780 and without affecting the caspase-3-like activity. At early stage of development in vitro (7 DIV) toxic effects of QA were more profound and mediated mainly by metabotropic glutamate receptors of group I, whereas later (12 DIV) they were mediated mostly by ionotropic AMPA/kainate receptors. The toxic effects of QA were partly accompanied by anti-apoptotic action against spontaneous caspase-3-like activity, possibly due to modulation of neuronal plasticity.

Effects of estrone on N-METHYL-d-aspartic acid- and staurosporine-induced changes in caspase-3-like protease activity and lactate dehydrogenase-release: time- and tissue-dependent effects in neuronal primary cultures

A growing body of evidence indicates that estrogens affect apoptotic processes in neuronal cells. However, their effects seem to depend on type of neuronal tissue, stage of development and apoptosis inducing factors. In the present study we compared effects of estrone (100 and 500 nM) on N-methyl-D-aspartic acid (NMDA) (1 mM)- and staurosporine (1 microM)-induced caspase-3-like activity and lactate dehydrogenase (LDH)-release in primary cultures of rat hippocampal and neocortical neurons. Fluorometric and colorimetric determination of enzyme activity was performed 6 h, 14 h, and 24 h after exposure to apoptotic agents. In the hippocampal cell cultures on 7 days in vitro (DIV), a time-dependent NMDA-induced activation of caspase-3-like proteases was accompanied by increased LDH-release. In neocortical cell cultures on 7 DIV NMDA did not affect caspase activity and decreased LDH-release. In neocortical cell cultures on 12 DIV NMDA inhibited spontaneous caspase activity, but was toxic to neurons after 24 h exposure suggesting that these cells underwent necrotic rather than apoptotic death. Estrone has attenuated both pro- and anti-apoptotic NMDA-induced changes in rat primary neuronal cultures acting independently of estrogen receptors, as detected with ICI 182, 780. In hippocampal neurons estrone antagonized not only the NMDA-induced caspase-3-like activity, but also NMDA-mediated LDH-release. However, in neocortical neurons estrone either attenuated NMDA-induced inhibition of caspase-3-like activity (12 DIV) or partly blocked NMDA-mediated decrease in LDH-release (7 DIV). In contrast to NMDA, staurosporine elevated caspase-3-like activity and LDH-release in a time-dependent manner in all used culture systems. Estrone inhibited pro-apoptotic effects of staurosporine in neocortical neurons, but only at later stage of development in vitro, which points to the protective role of estrogens during the brain tissue maturation. Since estrone triggered its effects via non-genomic mechanisms, it suggests that the other estradiol metabolites exhibiting low affinity to hormone receptors may be potent neuroprotective agents, which could retain the favorable and minimize the adverse side effects of estrogens.

Effect of PCB 126 and PCB 153 on incidence of apoptosis in cultured theca and granulosa cells collected from small, medium and large preovulatory follicles

The aim of the presented study was to evaluate the effects of PCB 126 and PCB 153 on granulosa and theca cell apoptosis. Granulosa and theca cells were collected from small, medium, and large preovulatory porcine follicles and cultured as monolayers. Cells were initially cultured for 24 h to allow attachment to the plates. Media were changed and 100 pg/ml PCB 126 or 100 ng/ml PCB 153 were added. After 48 h, granulosa and theca cells were fixed for assessment of the number of apoptotic cells utilizing a Hoechst staining technique or frozen for measurement of caspase-3 activity. Media were collected for testosterone concentration analysis from theca cell cultures or estradiol from granulosa cell cultures. Neither PCB 153 nor PCB 126 had an effect on testosterone secretion by theca cells collected from small and medium size follicles, while both PCBs decreased testosterone secretion by large follicles. The decrease in testosterone secretion by large follicles under the influence of both PCBs was paralleled by a suppression of caspase-3 activity and a decreased incidence of apoptotic bodies. Neither of the PCBs had an effect on estradiol secretion by granulosa cells collected from small and medium size follicles, while both PCBs increased estradiol in granulosa cells collected from large follicles. PCB-associated increased estradiol secretion by granulosa cells collected from large follicles was accompanied by suppression of caspase-3 activity and a decreased incidence of apoptotic bodies. In conclusion, we have presented evidence that in preovulatory follicles PCBs inhibit both theca and granulosa cells apoptosis. Therefore, an exposure to PCBs may cause alterations in the pattern of terminal differentiation of follicles and attenuate spontaneous elimination of atretic follicles.

Cellular strategies of estrogen-mediated neuroprotection during brain development

The role of estrogen during brain development is well documented. Estrogen influences cell survival and differentiation and also controls the formation and maintenance of neural networks. Knowledge of trophic estrogen action in the central nervous system (CNS) was the basis for the establishment of research programs directed toward a potential function of estrogen as a neuroprotective factor in the adult brain. Considerable evidence has accumulated over the years supporting this hypothesis. Experimental and epidemiologic studies as well as clinical trials have demonstrated that estrogen is beneficial for the course of neurodegenerative disorders such as Parkinson and Alzheimer diseases but may also protect neurons from postischemic neuronal degeneration. In this article, we aim to unravel potential physiologic responses and cell survival strategies that allow a more detailed understanding of estrogen-mediated neuroprotection in the brain. In particular, we focus on the participation of estrogen in the regulation of apoptotic processes. Furthermore, we present data on reciprocal estrogen-growth factor interactions. Both of these mechanisms were found to operate during brain development and to conciliate estrogen effects on neurons. This makes them likely candidates for taking part in conveying estrogen-dependent neuroprotection in the adult CNS.

Polichlorinated biphenyls (PCB126 and PCB 153) action on proliferation and progesterone secretion by cultured in vitro porcine luteal cells

SUMMARY

To characterise PCBs action on luteal cell steroidogenesis and cell viability two PCB congeners were selected as model substances. PCB 126 because of its dioxin-like configuration and high toxicity while 153 because it is one of the most commonly detected congeners in breast milk. Luteal cells collected from mature corpora lutea were cultured in M199 medium at 37 degrees C. Control cultures were maintained in that medium alone, while other cultures were supplemented with either PCB 126 (5, 10, 50 and 100 pg/ml) or PCB 153 (5, 10, 50 and 100 ng/ml). After 24 h, 48 h and 72 h of culture media were collected for P4 content analysis. Cell viability was measured using LDH cytotoxicity test. Exposure of luteal cells to all doses of PCB 126 for 24 h had no effect on progesterone secretion while longer, 48 h and 72 h exposure decreased progesterone secretion in a statistically significant manner. Concentration dependent decrease in progesterone secretion by luteal cells was seen after 24 h and 48 h exposure to PCB153 while concentration dependent increase in progesterone secretion was noted after 72 h exposition to this congener. The toxic effect of both congeners was observed only after 72 h exposition to 50 pg/ml and 100 pg/ml in the case of PCB 126 and 50 ng/ml and 100 ng/ml in the case of PCB 153. In conclusion, these results suggest that there are differences in PCB 153 and 126 action in luteal cells. Since information concerning mechanism of PCBs action on luteal cells is scarce, these preliminary experiments are of pioneering character.

Estrone, but not 17 beta-estradiol, attenuates kainate-induced seizures and toxicity in male mice

Estrogens change the susceptibility to seizures in humans and experimental animals. In this study, the effect of estrone and 17 beta-estradiol on kainate-induced seizures and neurotoxicity was investigated in male mice. Pre-treatment with estrone (250-1000 micrograms/kg) at 24 and 2 hours before kainate (40 mg/kg) administration significantly decreased both the percentage of animals with clonic seizures and their mortality (the latter at a dose of 1000 micrograms/kg only). On the other hand, 17 beta-estradiol (10-500 micrograms/kg) had no effect on seizures, and its dose of 10 micrograms/kg increased mortality. When given alone at a dose of 1 mg/kg, tamoxifen, an antagonist at estrogene receptors, did not affect the kainate-induced seizures, but prevented the anticonvulsant effect of estrone. A histological analysis showed that 73% of mice injected with vehiculum and kainate incurred hippocampal damage. Estrone (2000 micrograms/kg) decreased the percentage of animals with hippocampal neuronal loss down to 43%, and that effect was not antagonized by tamoxifen. Pretreatment of mice with 17 beta-estradiol had no effect on the kainate-induced neuronal loss. Additionally, we found that kainate injected i.p. had a profound effect on the immune system of mice, as reflected by a decrease in the thymus weight and an increased metabolic activity of splenocytes. The anticonvulsive dose of estrone (1000 micrograms/kg) did not change the immunoreactivity of either control or kainate-treated mice. In conclusion, the obtained data indicate that estrone, but not 17 beta-estradiol, attenuates the kainate-induced seizures, mortality and excitotoxicity in male mice. Moreover, it is suggested that the suppressive effect of estrone on clonic seizures involves intracellular receptors, whereas its antineurotoxic activity seems to depend on a non-genomic mechanism.

Effects of 17-beta estradiol and estriol on NMDA-induced toxicity and apoptosis in primary cultures of rat cortical neurons

Estrogens possess neuroprotective and antiapoptotic properties, however, the issue of involvement of estrogen receptors (ER)-dependent genomic pathway in these effects still remains controversial. Moreover, the majority of data on antiapoptotic effects of estrogens concern non-neuronal cells. In the present study we compared effects of the potent ER agonist, estradiol-17beta (E2), and its metabolite with a weak affinity for ER, estriol, on the neurotoxicity induced by high (1 and 5 mM) NMDA concentrations and on the apoptosis induced by low (0.1 mM) concentration of NMDA in rat primary cortical neurons. The obtained data showed that 24-hour exposure of cortical neurons to NMDA (0.1-5 mM) resulted in a dose-dependent increase in LDH level. Twenty four-hour pretreatment with estriol (100 nM and 500 nM) reduced the NMDA (1 and 5 mM)-induced toxicity by 16-26%, while estradiol-17beta (500 nM) reduced NMDA (5 mM)- induced toxicity by 14%. Twenty four hour exposure of cortical neurons to NMDA (0.1 mM) resulted in decrease of the level of antiapoptotic protein - Bcl-2 by 60% and increased the number of apoptotic cells by 50% compared to the control. Twenty four hour pretreatment with estradiol-17beta or estriol (100 and 1000 nM) prevented the NMDA-induced apoptotic changes. The specific estrogen receptor antagonist ICI 182,780 (100 nM) had no effect alone and did not antagonize the effects of estrogens on NMDA-induced toxicity as well as on changes in Bcl-2 level. The higher efficacy of estriol, together with the fact that the specific ER receptor antagonist, ICI 182,780, did not inhibit the above-described effects support the hypothesis about a nongenomic mechanism of the anti-NMDA action of estrogens.

Protective effects of TRH and its stable analogue, RGH-2202, on kainate-induced seizures and neurotoxicity in rodents

Thyrotropin-releasing hormone (TRH) has been postulated to be involved in the regulation of seizures and neural degeneration. We examined the effects of TRH and its stable analogue, RGH-2202, on the kainate-induced seizures and excitotoxicity in mice - a model of a drug-resistant temporal lobe epilepsy. We found that TRH (2.0 and 5.0 mg/kg) and RGH-2202 (2.5 and 5 mg/kg) elevated the ED(50) for kainate-induced convulsions and tended to decrease mortality. A histological analysis showed that kainate caused a neuronal loss of CA(1) and CA(3) hippocampal fields. TRH (10, 20 and 50 mg/kg) and RGH-2202 (2.5, 7.5 and 10.0 mg/kg) markedly reduced the excitotoxic effect of kainate. Further studies showed that TRH (1-100 microM) and RGH-2202 (100 microM) significantly attenuated the kainate (150 microM)-induced lactate dehydrogenase release in a primary cortical cell culture from rat embryos. In conclusion, the present study showed that TRH and RGH-2202 attenuated the kainate-induced seizures and inhibited the kainate-evoked neurotoxicity in vivo and in vitro. These results support the hypothesis of a potential utility of TRH and its analogues in the treatment of seizures and some neurodegenerative diseases.

Oestrogen effects on kainate-induced toxicity in primary cultures of rat cortical neurons

Oestrogens protect neurons against excitatory amino acid-induced toxicity; however data on their interaction with particular subtype of glutamate receptors are sparse. Therefore in the present study we investigated oestrogen effects on kainate neurotoxicity in primary cortical neurons. The data showed that both oestradiol-17 beta and oestrone (100 nM and 200 nM) reduced kainate toxicity by ca. 40%. Since tamoxifen only partly inhibited the above effects, we suggest that both genomic and non-genomic mechanisms are involved in the anti-kainate action of oestrogens.

Allopregnanolone attenuates kainate-induced toxicity in primary cortical neurons and PC12 neuronal cells

In this study, we demonstrated that allopregnanolone at 500 and 1000 nM significantly inhibited kainate-induced lactate dehydrogenase release from primary cortical cells by ca. 25 and 50%, respectively. Furthermore, allopregnanolone doses of 100 and 500 nM decreased cytotoxic effects of kainate (150 microM, 24-hour exposure) in PC12 neuronal cells by about 55 and 37%, respectively. These data strongly support neuroprotective effects of allopregnanolone observed in vivo.

Effect of neurosteroids on glutamate binding sites and glutamate uptake in rat hippocampus

Effects of some neurosteroids on the binding of [3H]-glutamate, [3H]-alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) and [3H]-MK-801, as well as on the [3H]-glutamate uptake were examined in rat hippocampus. The following compounds were evaluated: (a) positive modulators of the GABA(A) receptor: 5alpha-pregnan-3alpha-ol-20-one (allopregnanolone), 5alpha-pregnane-3alpha,21-diol-20-one (allotetrahydrodeoxycorticosterone), 5alpha-pregnan-3alpha-ol-11,20-dione (alphaxalone) and 5alpha-androstan-3alpha-ol-17-one (androsterone); (b) compounds showing GABA(A)-antagonistic and/or N-methyl-D-aspartic acid (NMDA)-agonistic properties: dehydroepiandrosterone sulfate and pregnenolone sulfate; (c) a substance which, apart from its GABA(A)-agonistic potency, has a NMDA-antagonistic action: 5beta-pregnan-3alpha-ol-20-one. None of those neurosteroids tested at concentrations of 0.001-100 microM affected the binding of [3H]-glutamate, [3H]-AMPA and [3H]-MK-801 or the glutamate uptake. The present study suggests that the previously reported inhibitory effects of neurosteroids on excitatory amino acid-induced seizures and neurotoxicity can be linked neither to the direct interaction of these compounds with the above binding sites on glutamate receptor complexes, nor to the glutamate uptake mechanism.