Effects of neuroactive steroids on the recombinant GABAA receptor in Xenopus oocyte

Rahman, Mozibur

January 2007

Introduction: Neuroactive steroids represent a class of both synthetic and naturally occurring steroids that have an effect on neural function. In addition to classical genomic mechanism by the hormones progesterone, deoxycorticosterone and testosterone 3α-OH metabolites of these hormones enhance GABAA receptor through rapid non-genomic mechanism. The site(s) of action of these neuroactive steroids namely 3α-OH-5α-pregnan-20 one, (3α,5α)-3,21-deoxycorticosterone(3α5α-THDOC) and 5α androstane-3α,17β-diol on GABAA receptor are distinct from that of benzodiazepines and barbiturate binding sites. The modulation site(s) has a well-defined structure activity relationship with a 3α-hydroxy and a 20-ketone configuration in the pregnane molecule required for agonistic action. Pregnenolone sulfate is a noncompetitive GABAA receptor antagonist and inhibit GABA activated Cl- current in an activation dependant manner. 3β-hydroxy A-ring reduced pregnane steroids are also GABAA receptor antagonist and inhibit GABAA receptor function and its potentiation induced by their 3α-diesteromers in a noncompetitive manner. Aim: The aim was to investigate if the effect of GABA, pentobarbital antagonism by bicuculline and if the effect of GABA-agonist and antagonist neuroactive steroids including pregnenolone sulfate is dependant on the α-subunits of GABAA receptor. Furthermore, the studies aimed at investigating the binding site of pregnenolone sulfate and if its effect is dependent on γ-subunit. In addition, the inhibitory effect of pregnenolone sulfate and 3β-hydroxy steroids has been characterized. We also wanted to investigate if the neuroactive steroids effect vary between the human and rat recombinant α1β2γ2L receptors and between the long (L) and short (S) variants of γ2-subunit. Method: Experiments were performed by the two electrodes voltage-clamp technique using oocytes of Xenopus laevis expressed with recombinant GABAA receptors containing α1, α4 or α5, β2, γ2L and γ2S-subunits. Results: There was no difference between the α1, α4 and α5-containing subunits regarding GABA and pentobarbital inhibition by bicuculline. GABA-activated current in the binary αβ was potent than that of ternary αβγ receptor. Unlike Zn2+ effect, inhibition by pregnenolone sulfate on the GABAA receptor is not dependant on the γ-subunit. It is likely that the 2’ residue closest to the N-terminus of the protein at M2 helix on both α1 and β2 subunit are critical to the inhibitory actions of PS and the function of Cl- channels. Point mutation at M2 helix of the β2-subunit (b2A252S) can dramatically reduce the inhibitory effect of PS on the GABAA receptors without affecting the inhibitory properties of 3β-hydroxysteroids. Agonist and antagonist steroids also varied in their efficacy between the human and rat α1β2γ2L receptor. Neuroactive steroids also showed difference between human γ2L and γ2S-containing receptor. Conclusions: GABA and pentobarbital antagonism by bicuculline is not dependant on α-subunit. Pregnenolone sulfate binding site is different from that of Zn2+. 3β-hydroxysteroids and pregnenolone sulfate inhibit GABAA receptor through different mechanisms. Neuroactive steroids also differ between species and between the long and short variant of γ- subunit.

GABA

GABAA receptor

neuroactive steroids

Obstetrics and gynaecology

Obstetrik och gynekologi

Neurosteroids : endogenous analgesics?

Humble, Stephen R.

January 2013

Peripheral sensitisation and central sensitisation are implicated in the development of neuropathic pain with neuroplasticity occurring at multiple levels of the pain pathway. Hypersensitivity of the spinothalamic tract has been described in neuropathic animal models of diabetes. Spinal dorsal horn neurones of diabetic rats exhibit abnormally high spontaneous firing, suggesting an imbalance between excitatory and inhibitory signals converging within this structure. GABAergic neurones within the spinal cord and thalamus are crucial for the transmission of painful stimuli to higher centres of the brain that are involved in pain perception. GABAA receptors (GABAARs) are an important target for many clinical drugs, and certain endogenous neurosteroids act as potent allosteric modulators of these receptors. A developmental change in the rate of exponential decay of GABAergic synaptic events has been observed in other types of neurones and this may be related in part to fluctuations in endogenous neurosteroid tone. The objective of this study was to investigate changes to inhibitory neurotransmission with development in three levels of the pain pathway and to explore potential mechanisms underlying diabetic neuropathy. The whole-cell patch-clamp technique was used on slices of neural tissue. Electrophysiological recordings were obtained from wild type mice between the ages of 6 and 80 days in lamina II of the spinal cord, the nucleus reticularis (nRT) of the thalamus and the cerebral cortex. Recordings were also obtained from mice with diabetic neuropathy (ob/ob and db/db) between the ages of 60 and 80 days. Neurosteroids and their precursors were employed along with compounds that prevented their activity at the GABAAR such as ?-cyclodextrin, which is a barrel-shaped cyclic oligosaccharide with a lipophilic interior that sequesters neurosteroids. Behavioural experiments were also performed using von Frey filaments and the tail flick test to examine mechanical and thermal nociception. Recordings from the spinal cord, the thalamus and the cerebral cortex revealed that the decay time of miniature inhibitory postsynaptic currents are significantly reduced with development. The neurosteroids allopregnanolone and ganaxolone were significantly more effective in neurones from the older mice. In contrast, ?-cyclodextrin had significantly less effect in neurones from the older mice. In mature diabetic mice (ob/ob mice), the endogenous neurosteroid tone is reduced compared to control mice, but certain neurosteroid compounds have a greater effect on the GABAARs of these diabetic mice. In addition, the diabetic mice exhibit mechanical allodynia and hyperalgesia, which is responsive to exogenously applied neurosteroids. These results are consistent with the hypothesis that a dramatic reduction in endogenous neurosteroid tone occurs as development progresses and that this impacts on the exponential decay time of GABAergic mIPSCs within neurones of the pain pathway. The higher neurosteroid tone in the youngest mice may confer a degree of neural protection over the nervous system as it develops. The reduction of endogenous neurosteroid tone in diabetic mice may be associated with their hypersensitivity. It is possible that pregnane-derived neurosteroids may exert analgesic effects in pathological pain states by attempting to restore the physiological GABAergic inhibitory tone that is observed in immature animals.

612.8

Stress and GABAA receptor regulation

Skilbeck, Kelly Johanne

January 2009

Doctor of Philosophy (PhD) / GABAA receptors are implicated in the pathology of psychiatric disorders such as schizophrenia and depression. They are rapidly affected by stress in a sex-dependent fashion, suggesting that GABAA receptors may be relevant to understanding the association between stress and psychiatric disorders. Thus, this thesis examined how GABAA receptors are affected in both male and female mice exposed to stress in adulthood (Chapter 2), early-life (Chapter 3-5) and a combination of both early-life and adulthood stress (Chapter 6). 2. The effects of acute adulthood stress (3 minute warm swim stress) on GABAA receptor binding in the brains of male and female mice were examined using quantitative receptor autoradiography. The total number of GABAA receptor [3H]GABA binding sites was increased following swim stress in specific forebrain cortical regions of female mice swum individually or in a group, but decreased in male mice when swum in a group only. These findings confirm and extend previous studies, identifying the cortical regions involved in rapid stress-induced changes in GABAA receptors. 3. Post-natal handling models in rodents comparing control (brief handling sessions; EH) with no intervention stress conditions (NH), indicate that the NH condition results in an anxious adulthood phenotype and this was confirmed in the present thesis using the elevated plus-maze behavioural test. Using this model the effects of early-life stress on adulthood GABAA receptors were then examined. 4. Regional densities of GABAA receptor α1 and α2 subunit proteins were observed in the adult brain of male and female mice using immunoperoxidase histochemistry. NH males showed a loss of the α2 subunit from the thalamus and the lower layers (IV-VI) of the primary somatosensory cortex, whilst NH females showed a reduction of α2 but an increase in α1 protein in the lower layers of the primary somatosensory cortex only. These regionally specific alterations in the α1:α2 subunit ratio suggest that early-life stress disrupts the developmental α subunit switch, which occurs in a regionally-dependent fashion over the first two weeks of rodent life. 5. Double-labelling immunofluorescence and confocal microscopy were used to examine the effects of sex and early-life stress on GABAA receptor synaptic clustering. Regardless of sex, mice exposed to early-life stress (NH) showed reduced colocalisation of the GABAA receptor α2 subunit with the synaptic marker protein gephyrin relative to the control condition (EH). This suggests that early-life stress impairs adulthood inhibitory synaptic strength and is consistent with the increased anxiety of the stressed relative to control mice. 6. Finally, the effects of early-life stress on adulthood swim stress-induced changes in GABAA receptor binding were examined using quantitative receptor autoradiography in forebrain cortical regions. Findings showed that the effect of adulthood stress on the total number of GABAA receptor binding sites for [3H]GABA in forebrain cortical regions was altered by early-life stress in both male and female mice, suggesting that the rapid adulthood stress response of GABAA receptors is affected by early-life experience. 7. Together these results show that GABAA receptors are sensitive to subtle changes in the environment in both early-life and adulthood and that these neurochemical responses to stress in adulthood are sex-dependent. The short and long-term stress-sensitivity of the GABAergic system implicates GABAA receptors in the non-genetic aetiology of psychiatric illnesses in which sex and stress are important factors.

GABAA receptor

Stress

sex differences

immunohistochemistry, immunofluorescence

quantitative receptor autoradiography

Stress and GABAA receptor regulation

Skilbeck, Kelly Johanne

January 2009

Doctor of Philosophy (PhD) / GABAA receptors are implicated in the pathology of psychiatric disorders such as schizophrenia and depression. They are rapidly affected by stress in a sex-dependent fashion, suggesting that GABAA receptors may be relevant to understanding the association between stress and psychiatric disorders. Thus, this thesis examined how GABAA receptors are affected in both male and female mice exposed to stress in adulthood (Chapter 2), early-life (Chapter 3-5) and a combination of both early-life and adulthood stress (Chapter 6). 2. The effects of acute adulthood stress (3 minute warm swim stress) on GABAA receptor binding in the brains of male and female mice were examined using quantitative receptor autoradiography. The total number of GABAA receptor [3H]GABA binding sites was increased following swim stress in specific forebrain cortical regions of female mice swum individually or in a group, but decreased in male mice when swum in a group only. These findings confirm and extend previous studies, identifying the cortical regions involved in rapid stress-induced changes in GABAA receptors. 3. Post-natal handling models in rodents comparing control (brief handling sessions; EH) with no intervention stress conditions (NH), indicate that the NH condition results in an anxious adulthood phenotype and this was confirmed in the present thesis using the elevated plus-maze behavioural test. Using this model the effects of early-life stress on adulthood GABAA receptors were then examined. 4. Regional densities of GABAA receptor α1 and α2 subunit proteins were observed in the adult brain of male and female mice using immunoperoxidase histochemistry. NH males showed a loss of the α2 subunit from the thalamus and the lower layers (IV-VI) of the primary somatosensory cortex, whilst NH females showed a reduction of α2 but an increase in α1 protein in the lower layers of the primary somatosensory cortex only. These regionally specific alterations in the α1:α2 subunit ratio suggest that early-life stress disrupts the developmental α subunit switch, which occurs in a regionally-dependent fashion over the first two weeks of rodent life. 5. Double-labelling immunofluorescence and confocal microscopy were used to examine the effects of sex and early-life stress on GABAA receptor synaptic clustering. Regardless of sex, mice exposed to early-life stress (NH) showed reduced colocalisation of the GABAA receptor α2 subunit with the synaptic marker protein gephyrin relative to the control condition (EH). This suggests that early-life stress impairs adulthood inhibitory synaptic strength and is consistent with the increased anxiety of the stressed relative to control mice. 6. Finally, the effects of early-life stress on adulthood swim stress-induced changes in GABAA receptor binding were examined using quantitative receptor autoradiography in forebrain cortical regions. Findings showed that the effect of adulthood stress on the total number of GABAA receptor binding sites for [3H]GABA in forebrain cortical regions was altered by early-life stress in both male and female mice, suggesting that the rapid adulthood stress response of GABAA receptors is affected by early-life experience. 7. Together these results show that GABAA receptors are sensitive to subtle changes in the environment in both early-life and adulthood and that these neurochemical responses to stress in adulthood are sex-dependent. The short and long-term stress-sensitivity of the GABAergic system implicates GABAA receptors in the non-genetic aetiology of psychiatric illnesses in which sex and stress are important factors.

GABAA receptor

Stress

sex differences

immunohistochemistry, immunofluorescence

quantitative receptor autoradiography

Unique Response Properties and GABA_A Receptor Function in Medial Geniculate Body Neurons of Young and Aged Fischer Brown Norway Rats

Richardson, Ben David

01 December 2012

The auditory thalamus or medial geniculate body (MGB) is the final brain structure for acoustic information processing prior to, and functioning in reciprocity with, auditory cortex. MGB neurons process and gate aspects of acoustic stimuli, functions which depend partly on GABAergic inhibition. To characterize these properties, the inhibitory neurotransmitters involved and how they may be altered in the aged MGB, specific aims sought to: 1) determine the presence of functional high affinity GABAA receptors (GABAARs) in the MGB, 2) determine whether GABAAR function is altered with age and 3) determine to what degree MGB neurons of awake young and aged rats display stimulus-specific adaptation (SSA). Inhibitory neurotransmission is essential for accurate coding of acoustic information in the central auditory system, but appears disrupted in the aged. The present study required the development of a slice preparation that permitted whole cell recordings from juvenile, young adult and aged rat MGB neurons. The presence of high affinity GABAARs and the impact of aging on synaptic and high affinity GABAAR function were examined. Low concentrations of gaboxadol (GABAAR agonist) activated a gabazine-sensitive (GABAAR antagonist) tonic current, providing support for the expression of functional high affinity GABAARs in the MGB. Activation of high affinity GABAARs expressed by MGB neurons decreased input resistance, hyperpolarized resting membrane potential, reduced evoked firing rates and induced a transition from tonic to burst firing mode. In aged MGB neurons there was a significant 50.4% reduction in GABAAR-mediated tonic Cl- current. Synaptic GABAAR inhibition appeared differentially affected by age in lemniscal and non-lemniscal auditory thalamus although gramicidin perforated patch-clamp recordings indicated neuronal Cl- homeostasis was unaltered with age. Anesthetized rodent MGB single units show SSA, during which the firing rate in response to repetitive stimuli decreases/adapts over time but low probability stimuli (i.e. novel) continue to elicit robust responses. To examine the presence of SSA in the MGB of awake rats, a multichannel single unit recording preparation was implemented. This approach involved implanting young and aged rats with an array of four individually-advanceable tetrodes in order to evaluate SSA by recording responses to a frequency oddball paradigm and a random/non-random frequency range paradigm. Single units in the MGB of awake FBN rats were found to display SSA, which was stronger in the non-lemniscal than lemniscal regions of the MGB. SSA was most dramatic at lower intensities where 27 of 57 (47%) young adult single units and 28 of 54 (52%) aged single units displayed SSA. However, there were no significant age-related differences in average magnitude or time course of SSA of MGB single units studied. Data from aims 1 and 2 provide the initial description of functional high affinity GABAARs in the rodent MGB and the plasticity of these receptors with age. These data suggest that GABAAR subtype-selective agonists or modulators could be used to augment MGB inhibitory neurotransmission, possibly improving speech understanding for a subset of elderly individuals. Findings from aim 3 were the first to show that SSA by MGB neurons is not dependent on arousal level nor on the anesthetized state, but is a common response in the MGB of awake rats. SSA did not appear to be overtly altered in the aged auditory thalamus of awake rats.

aging

Auditory

GABAA Receptor

medial geniculate

stimulus-specific adaptation

thalamus

BRAINSTEM GABAA RECEPTOR SHAPE THE RESPONSE AND ADAPTATION TO HYPOXIA

Hsieh, Yee-Hsee

13 July 2007

No description available.

Biology, Neuroscience

HYPOXIA

Hypoxic

sSNA

CHH

GABAA

GABAA RECEPTOR

Pons

Age-Dependent Effects Of Chronic GABAA Receptor Blockade In Barrel Cortex

Gargan, Lynn

05 1900

GABAA receptor binding is transiently increased in rat whisker barrels during the second postnatal week, at a time when neurons in the developing rat cortex are vulnerable to excitotoxic effects. To test whether these GABAA receptors might serve to protect neurons from excessive excitatory input, polymer implants containing the GABAA receptor antagonist bicuculline were placed over barrel cortex for a 4-day period in young (postnatal days 8 - 12) and adult rats. In the cortex of young, but not adult rats, the chronic blockade of GABAA receptors resulted in substantial tissue loss and neuron loss. The greater loss of neurons in young rats supports the hypothesis that a high density of GABAA receptors protects neurons from excessive excitatory input during a sensitive period in development.

GABA -- Receptors.

Rats -- Nervous system.

GABAA receptor binding

Excitotoxic effects

Postnatal development

Envolvimento de vias mediadas por endocanabinoides na modulação do comportamento de defesa induzido pelo bloqueio de receptores GABAA na divisão dorso-medial do hipotálamo ventro-medial: papel do receptor CB1 / Involvement of endocannabinoid-mediated pathways in the modulation of defensive behaviour induced by the GABAA receptor blockade in dorsomedial division of ventromedial hypothalamus: role of CB1 receptor

Garcia, Tayllon dos Anjos

12 February 2014

Os efeitos dos canabinoides em algumas áreas encefálicas que expressam receptores endocanabinoides, como é o caso dos núcleos hipotalâmicos, não são ainda muito bem definidos. Vários estudos têm demonstrado o papel de alguns núcleos hipotalâmicos na organização das reações induzidas pelo medo inato e pelo pânico. As respostas de defesa induzidas pelo medo instintivo caracterizam-se por serem mais elaboradas e dirigidas para algum abrigo ou rota de fuga. O estado de pânico pode ser provocado experimentalmente em animais de laboratório através da diminuição da atividade do sistema GABAérgico. O objetivo deste trabalho foi estudar os padrões comportamentais de fuga elaborada induzidos pelo bloqueio de receptores GABAérgicos do tipo A, com microinjeções intra-hipotalâmicas de bicuculina (BIC), especificamente na divisão dorso-medial do hipotálamo ventro-medial (VMHDM), assim como estabelecer o envolvimento endocanabinoides e o papel do receptor canabinoide do tipo 1 (CB1) na modulação das respostas defensivas organizadas pelo hipotálamo medial. Os resultados mostraram que a administração prévia de doses intermediárias (5pmol) de anandamida (AEA) atenuaram as respostas defensivas induzidas pela microinjeção intra-VMHDM de bicuculina (40ng), efeito este prevenido pelo pré-tratamento intra-hipotalâmica com antagonista de receptores CB1. Os resultados indicam que a AEA pode modular os efeitos pró-aversivos da bicuculina no VMHDM por meio do recrutamento de receptores CB1. / The effects of cannabinoids in some brain areas that express endocannabinoid receptors, such as some hypothalamic nuclei, are not yet well known. Several studies have demonstrated a role of hypothalamic nuclei in the organisation of behavioural responses induced by innate fear and panic attacks. The defensive responses induced by instinctive fear are more elaborated and oriented toward a burrow or alternative route of escape. Panic-prone states are able to be experimentally induced in laboratory animals decreasing the GABAergic system activity. The aim of this work was to study panic-like elaborated defensive behaviour evoked by GABAA receptor blockade with bicuculline (BIC) in the dorsomedial division of the ventromedial hypothalamus (VMHDM), we also aimed to establish the involvement of endocannabinoids and the role of CB1 cannabinoid receptor in the modulation of elaborated defense behavioural responses organised by medial hypothalamus. The results showed that intra-hypothalamic administration of anandamide (AEA) at the intermediate dose (5pmol) attenuated defensive responses induced by intra-VMHDM microinjection of bicuculline (40ng). This effect, however, was prevented by the pre-treatment of VMHDM with the CB1 receptor antagonist AM251. These results indicate that AEA can modulate the pro-aversive effects of bicuculline into the VMHDM, recruiting CB1 receptors.

Comportamento de defesa

Defensive behaviour

Endocanabinoides

Endocannabinoid

GABAA receptor

Hipotálamo ventro-medial

Receptor GABAA

Ventromedial hypothalamus

Envolvimento de vias mediadas por endocanabinoides na modulação do comportamento de defesa induzido pelo bloqueio de receptores GABAA na divisão dorso-medial do hipotálamo ventro-medial: papel do receptor CB1 / Involvement of endocannabinoid-mediated pathways in the modulation of defensive behaviour induced by the GABAA receptor blockade in dorsomedial division of ventromedial hypothalamus: role of CB1 receptor

Tayllon dos Anjos Garcia

12 February 2014

Os efeitos dos canabinoides em algumas áreas encefálicas que expressam receptores endocanabinoides, como é o caso dos núcleos hipotalâmicos, não são ainda muito bem definidos. Vários estudos têm demonstrado o papel de alguns núcleos hipotalâmicos na organização das reações induzidas pelo medo inato e pelo pânico. As respostas de defesa induzidas pelo medo instintivo caracterizam-se por serem mais elaboradas e dirigidas para algum abrigo ou rota de fuga. O estado de pânico pode ser provocado experimentalmente em animais de laboratório através da diminuição da atividade do sistema GABAérgico. O objetivo deste trabalho foi estudar os padrões comportamentais de fuga elaborada induzidos pelo bloqueio de receptores GABAérgicos do tipo A, com microinjeções intra-hipotalâmicas de bicuculina (BIC), especificamente na divisão dorso-medial do hipotálamo ventro-medial (VMHDM), assim como estabelecer o envolvimento endocanabinoides e o papel do receptor canabinoide do tipo 1 (CB1) na modulação das respostas defensivas organizadas pelo hipotálamo medial. Os resultados mostraram que a administração prévia de doses intermediárias (5pmol) de anandamida (AEA) atenuaram as respostas defensivas induzidas pela microinjeção intra-VMHDM de bicuculina (40ng), efeito este prevenido pelo pré-tratamento intra-hipotalâmica com antagonista de receptores CB1. Os resultados indicam que a AEA pode modular os efeitos pró-aversivos da bicuculina no VMHDM por meio do recrutamento de receptores CB1. / The effects of cannabinoids in some brain areas that express endocannabinoid receptors, such as some hypothalamic nuclei, are not yet well known. Several studies have demonstrated a role of hypothalamic nuclei in the organisation of behavioural responses induced by innate fear and panic attacks. The defensive responses induced by instinctive fear are more elaborated and oriented toward a burrow or alternative route of escape. Panic-prone states are able to be experimentally induced in laboratory animals decreasing the GABAergic system activity. The aim of this work was to study panic-like elaborated defensive behaviour evoked by GABAA receptor blockade with bicuculline (BIC) in the dorsomedial division of the ventromedial hypothalamus (VMHDM), we also aimed to establish the involvement of endocannabinoids and the role of CB1 cannabinoid receptor in the modulation of elaborated defense behavioural responses organised by medial hypothalamus. The results showed that intra-hypothalamic administration of anandamide (AEA) at the intermediate dose (5pmol) attenuated defensive responses induced by intra-VMHDM microinjection of bicuculline (40ng). This effect, however, was prevented by the pre-treatment of VMHDM with the CB1 receptor antagonist AM251. These results indicate that AEA can modulate the pro-aversive effects of bicuculline into the VMHDM, recruiting CB1 receptors.

Comportamento de defesa

Endocanabinoides

Hipotálamo ventro-medial

Receptor GABAA

Defensive behaviour

Endocannabinoid

GABAA receptor

Ventromedial hypothalamus

Neuroactive steroids and rat CNS

Birzniece, Vita

January 2004

Several studies suggest profound effects on mood and cognition by neuroactive steroids. Estrogen alone or in combination with antidepressant drugs affecting the serotonin system has been used to treat mood disorders. On the other hand, progesterone is related to negative effects on mood and memory. A major part of the progesterone effects on the brain can be mediated by its metabolite allopregnanolone, which is also de novo synthesized in the brain, and affects the GABAA receptors. It would be of great importance to find a substance that antagonize allopregnanolone adverse effects. To investigate how long term supplementation of estradiol and progesterone, resembling postmenopausal hormone replacement therapy, affects serotonin receptors in different brain areas important for mood and memory functions, we used ovariectomized female rats. After 2 weeks of supplementation with 17β-estradiol alone or in combination with progesterone, or placebo pellets, estradiol alone decreases but estradiol supplemented together with progesterone increases 5HT1A mRNA expression in the hippocampus. Estradiol decreases the 5HT2C receptor gene expression, while estradiol in combination with progesterone increases the 5HT2A mRNA expression in the ventral hippocampus. Thus, estradiol alone has opposite effects compared to the estradiol/progesterone combination. To detect if acute tolerance develops to allopregnanolone, an EEG method was used where male rats by continuous allopregnanolone infusion were kept on anesthesia level of the silent second (SS). After different time intervals (first SS, 30 min or 90 min of anesthesia) several GABAA receptor subunit mRNAs were measured for detecting if changed expression of any GABAA receptor subunits is involved in development of acute tolerance. There is development of acute tolerance to allopregnanolone and brain regions of importance are hippocampus, thalamus and hypothalamus. The GABAA receptor alpha4 subunit in thalamus and alpha2 subunit in the dorsal hippocampus are related to development of acute tolerance. For assessing allopregnanolone behavioral effects, we studied how this neurosteroid affects spatial learning in the Morris water maze task Allopregnanolone inhibits spatial learning short after the injection and shows a specific behavioral pattern with swimming close to the pool wall. The steroid UC1011 can inhibit the increase in chloride ion uptake induced by allopregnanolone. UC1011 decreases allopregnanoloneinduced impairment of spatial learning in the water maze, as well as the specific behavioral swim pattern. In conclusion, the present work demonstrates that neuroactive steroids affect the 5HT and GABA systems in a brain region specific way. GABAA receptor subunit changes in hippocampus and thalamus are related to acute allopregnanolone tolerance. Allopregnanolone induces cognitive deficits, like spatial learning impairment and UC1011 can inhibit allopregnanolone-induced effects in vitro and in vivo. Key words: Estradiol, progesterone, HRT, allopregnanolone, UC1011, serotonin receptor, GABAA receptor, mRNA, Morris water maze, silent second, tolerance.

Estradiol

progesterone

HRT

allopregnanolone

UC1011

serotonin receptor

GABAA receptor

mRNA

Morris water maze

silent second

tolerance