Effects of the acute administration of delta-opioid receptor ligands on the excitability of rat hippocampal glutamate and brainstem monoamine neurons in vivo.

It was previously reported that the delta opioid receptor (DOR) agonist SNC80 and antagonist naltrindole modulate the excitability of hippocampal glutamate neurons in primary cultures. The present study aimed to investigate the acute effects of these ligands on the firing activity of hippocampal cornu ammonis 1/3 (CA1/3) glutamate, dorsal raphe nucleus (DRN) serotonin (5-HT), locus coeruleus (LC) noradrenaline, and ventral tegmental area (VTA) dopamine neurons in in vivo conditions. Adult Wistar male rats were used. SNC80 and naltrindole were administered intravenously. Neuronal firing activity was assessed using extracellular single-unit electrophysiology. SNC80, administered first at 1-3 mg/kg, dose-dependently inhibited CA1/3 glutamate, DRN 5-HT, and VTA dopamine neurons. Naltrindole, administered at 1-3 mg/kg after SNC80, did not have any additional effect. Naltrindole, administered first at 1-3 mg/kg, stimulated DRN 5-HT neurons in a dose-dependent manner; this stimulation was dose-dependently reversed by 1-3 mg/kg of SNC80. SNC80 and naltrindole inhibited LC noradrenaline neurons when only they were co-administered at 3 mg/kg, and only when SNC80 was administered first. In conclusion, DOR ligands alter the firing activity of hippocampal glutamate and brainstem monoamine neurons in in vivo conditions. The psychoactive effects of DOR ligands, reported in previous studies, might be explained, at least in part, by their ability to modulate the firing activity of hippocampal glutamate and brainstem monoamine neurons.

Stress, depression, and hippocampus: from biochemistry to electrophysiology.

Major depressive disorder is a very common serious mental illness with increasing prevalence in the population. Its pathology includes biochemical, morphological, and electrophysiological changes in various brain areas. In spite of decades of extensive research pathophysiology of depression is still not sufficiently understood. When depression occurs just before or during pregnancy, it may have a detrimental effect on perinatal and/or postnatal brain development, affecting the offspring's behavior. An important role in the pathology of depression is the hippocampus as a center for cognition and memory. Here we review changes in morphology, biochemical, and electrical signaling caused by depression in first and second generation identified in various animal models.

Voltage-dependent CaV3.2 and CaV2.2 channels in nociceptive pathways.

Noxious stimuli like cold, heat, pH change, tissue damage, and inflammation depolarize a membrane of peripheral endings of specialized nociceptive neurons which eventually results in the generation of an action potential. The electrical signal is carried along a long axon of nociceptive neurons from peripheral organs to soma located in dorsal root ganglions and further to the dorsal horn of the spinal cord where it is transmitted through a chemical synapse and is carried through the spinal thalamic tract into the brain. Two subtypes of voltage-activated calcium play a major role in signal transmission: a low voltage-activated CaV3.2 channel and a high voltage-activated CaV2.2 channel. The CaV3.2 channel contributes mainly to the signal conductance along nociceptive neurons while the principal role of the CaV2.2 channel is in the synaptic transmission at the dorsal horn. Both channels contribute to the signal initiation at peripheral nerve endings. This review summarizes current knowledge about the expression and distribution of these channels in a nociceptive pathway, the regulation of their expression and gating during pain pathology, and their suitability as targets for pharmacological therapy.

Role of glucocorticoid- and monoamine-metabolizing enzymes in stress-related psychopathological processes.

Glucocorticoid signaling is fundamental in healthy stress coping and in the pathophysiology of stress-related diseases, such as post-traumatic stress disorder (PTSD). Glucocorticoids are metabolized by cytochrome P450 (CYP) as well as 11-ß-hydroxysteroid dehydrogenase type 1 (11ßHSD1) and 2 (11ßHSD2). Acute stress-induced increase in glucocorticoid concentrations stimulates the expression of several CYP sub-types. CYP is primarily responsible for glucocorticoid metabolism and its increased activity can result in decreased circulating glucocorticoids in response to repeated stress stimuli. In addition, repeated stress-induced glucocorticoid release can promote 11ßHSD1 activation and 11ßHSD2 inhibition, and the 11ßHSD2 suppression can lead to apparent mineralocorticoid excess. The activation of CYP and 11ßHSD1 and the suppression of 11ßHSD2 may at least partly contribute to development of the blunted glucocorticoid response to stressors characteristic in high trait anxiety, PTSD, and other stress-related disorders. Glucocorticoids and glucocorticoid-metabolizing enzymes interact closely with other biomolecules such as inflammatory cytokines, monoamines, and some monoamine-metabolizing enzymes, namely the monoamine oxidase type A (MAO-A) and B (MAO-B). Glucocorticoids boost MAO activity and this decreases monoamine levels and induces oxidative tissue damage which then activates inflammatory cytokines. The inflammatory cytokines suppress CYP expression and activity. This dynamic cross-talk between glucocorticoids, monoamines, and their metabolizing enzymes could be a critical factor in the pathophysiology of stress-related disorders.Lay summaryGlucocorticoids, which are produced and released under the control by brain regulatory centers, are fundamental in the stress response. This review emphasizes the importance of glucocorticoid metabolism and particularly the interaction between the brain and the liver as the major metabolic organ in the body. The activity of enzymes involved in glucocorticoid metabolism is proposed to play not only an important role in positive, healthy glucocorticoid effects, but also to contribute to the development and course of stress-related diseases.

Correction to: Four novel interaction partners demonstrate diverse modulatory effects on voltage-gated CaV2.2 Ca2+ channels.

The article was originally published with one author missing. The name of the co-author Roman Moravcik was inadvertently omitted. His name and affiliation have now been added to the author list. The original article has been corrected.

Four novel interaction partners demonstrate diverse modulatory effects on voltage-gated CaV2.2 Ca2+ channels.

Voltage-gated Ca2+ channels are embedded in a network of protein interactions that are fundamental for channel function and modulation. Different strategies such as high-resolution quantitative MS analyses and yeast-two hybrid screens have been used to uncover these Ca2+ channel nanodomains. We applied the yeast split-ubiquitin system with its specific advantages to search for interaction partners of the CaV2.2 Ca2+ channel and identified four proteins: reticulon 1 (RTN1), member 1 of solute carrier family 38 (SLC38), prostaglandin D2 synthase (PTGDS) and transmembrane protein 223 (TMEM223). Interactions were verified using the yeast split-ubiquitin system and narrowed down to CaV2.2 domain IV. Colocalization studies using fluorescent constructs demonstrated defined regions of subcellular localization. Detailed electrophysiological studies revealed that coexpression of RTN1 modulated CaV2.2 channels only to a minor extent. SLC38 accelerated the cumulative current inactivation during a high-frequency train of brief depolarizing pulses. As neurons expressing CaV2.2 channels were exposed to high-frequency bursts under physiological conditions, observed regulation may have a negative modulatory effect on transmitter release. Coexpression of PTGDS significantly lowered the average current density and slowed the kinetics of cumulative current inactivation. Since the latter effect was not significant, it may only partly compensate the first one under physiological conditions. Expression of TMEM223 lowered the average current density, accelerated the kinetics of cumulative current inactivation and slowed the kinetics of recovery from inactivation. Therefore, TMEM223 and, to a lesser extent, PTGDS, may negatively modulate Ca2+ entry required for transmitter release and/or for dendritic plasticity under physiological conditions.

Structure, function and regulation of CaV 2.2 N-type calcium channels.

N-type or CaV2.2 high-voltage activated calcium channels are distinguished by exclusively neuronal tissue distribution, sensitivity to ω-conotoxins, prominent inhibition by G-proteins, and a unique role in nociception. Most investigated modulatory pathway regulating the CaV2.2 channels is G-protein-coupled receptor-activated pathway leading to current inhibition by Gßγ subunit of G-protein. Binding of Gßγ dimer to α1 subunit of the CaV2.2 channel transfers the channel form "willing" to "reluctant" gating state. Channel phosphorylation by protein kinase C potentiates N-type calcium current. CaV2.2 channels could be functionally regulated also by a number of protein-protein interactions. Ca V2.2 null mice are hyposensitive to inflammatory and neuropathic pain, otherwise they have a mild phenotype. Consistent with the mild phenotype of the CaV2.2-/- mice, reports on mutations linked to a disease phenotype are scarce. Only one mutation related to human heritable diseases was identified until now. Pharmaceutical inhibition of CaV2.2 channels either by direct inhibition of the channel, by an activation of G-protein coupled receptors, or by inhibition of membrane targeting of the channel protein are promising strategies for treatment of severe chronic and/or neuropathic pain.

SNC80 and naltrindole modulate voltage-dependent sodium, potassium and calcium channels via a putatively delta opioid receptor-independent mechanism.

SNC80 was designed as a highly selective nonpeptide delta opioid receptor (DOR) agonist. Antidepressant-like and antinociceptive effects of this compound were demonstrated in animal models. Naltrindole was synthetized as a highly selective DOR antagonist. Its antitussive and antinociceptive effects were reported. Observed effects of SNC80 and naltrindole may be accompanied by changes in neuronal excitability including modulation of voltage-dependent ion channels. We investigated possible DOR-independent modulation of neuronal sodium, calcium and potassium currents by both agents. NG108-15 cells lacking expression of DOR protein were used as model of neuronal cells. Cells were differentiated into neuronal phenotype by exposure to dibutyryl cyclic-AMP (dbcAMP). Lack of DORs expression in NG108-15 cells and the presence of DOR expression in brain and neuronal cultures were demonstrated by Western blot analysis. Both SNC80 and naltrindole exerted low to moderate modulatory effects on voltage-dependent ion currents. SNC80 weakly inhibited sodium current, potentiated calcium current, and did not act on potassium channels. Naltrindole inhibited sodium current, did not act on calcium current and inhibited potassium current at a high concentration. Such effects should be taken into account when these compounds are used for investigation of DOR-mediated signaling pathways.

DNA-DOPE-gemini surfactants complexes at low surface charge density: from structure to transfection efficiency.

DNA condensation, structure and transfection efficiency of complexes formed by gemini surfactants alkane-α,ω-diyl-bis(dodecyldimethylammonium bromide)s (CnGS12, n = 3, 6 and 12 is the number of alkane spacer carbons), dioleoylphosphatidylethanolamine (CnGS12/DOPE = 0.3 mol/mol) and DNA at low surface charge density were investigated through different techniques. Small angle X-ray diffraction showed a condensed lamellar phase with marked dependence of DNA-DNA distance on (+/-) charge ratio. High ionic strength of hydrating medium screens the interaction DNA - CnGS12/DOPE and complexed DNA represented maximally ~ 45-60% of total DNA in the solution as derived from fluorescence and UV-VIS spectroscopy. The in vitro transfection efficiency of CnGS12/DOPE liposomes on mammalian HEK 293 cell line was spacer length-dependent. C12GS12/DOPE/DNA complexes exhibited the best transfection efficiency (~ 18% GFP-expressing cells relative to all viable cells) accompanied by ~ 89% cell viability.

Fibrotic scar model and TGF-ß1 differently modulate action potential firing and voltage-dependent ion currents in hippocampal neurons in primary culture.

Traumatic injury of the central nervous system is accompanied by various functional and morphological changes. Animal models of traumatic brain injury are commonly used to investigate changes in behaviour, morphology, in the expression of various proteins around the site of the injury, or the expression of diagnostically important biomarkers. Excitability of a single neuron at, or close to, the site of injury was rarely investigated. Several in vitro models were developed which allow such investigation. In the present work, we employed a fibrotic scar model according to Kimura-Kuroda and coauthors to analyse altered excitability of rat hippocampal neurons under the conditions mimicking traumatic brain injury. Hippocampal neurons from newborn rats were cultured either on a fibrotic scar model or in the presence of TGF-ß1, a cytokine secreted at a brain injury site that may have both neuroprotective and neurodegenerative function. Fibrotic scar facilitated ability of neonatal hippocampal neurons to fire action potential series by increasing the density of voltage activated sodium and potassium currents. Chondroitin sulphate proteoglycans played substantial role in these effects, as proven by their full reversion after administration of Chondroitinase ABC. In contrast, TGF-ß1 did not contribute to them. An application of TGF-ß1 itself attenuated generation of action potentials, inhibited sodium current and potentiated potassium currents. Main alteration of electrophysiological parameters of neonatal hippocampal neurons caused by a fibrotic scar model is enhanced excitability. TGF-ß1 may have predominantly neuroprotective role in injured rat hippocampus.

Effect of Physical Exercise and Acute Escitalopram on the Excitability of Brain Monoamine Neurons: In Vivo Electrophysiological Study in Rats.

Background: The antidepressant effect of physical exercise has been reported in several clinical and animal studies. Since serotonin, norepinephrine, and dopamine play a central role in depression, it is possible that the beneficial effects of physical exercise are mediated via monoamine pathways. This study investigates the effects of voluntary wheel running on the excitability of monoamine neurons. Materials and Methods: Male Sprague-Dawley rats were used in the study. Voluntary wheel running (VWR) rats were housed in individual cages with free access to a running wheel, while control animals were housed in standard laboratory cages. After three weeks, the rats were anesthetized, and in vivo electrophysiological recordings were taken from dorsal raphe nucleus serotonin neurons, locus coeruleus norepinephrine neurons, and ventral tegmental dopamine neurons. Results: VWR stimulated activity in serotonin, but not in norepinephrine or dopamine neurons. Subsequently, acute administration of the selective serotonin reuptake inhibitor escitalopram in control rats led to complete suppression of serotonin neurons; this suppression was reversed by subsequent administration of selective antagonist of serotonin-1A receptors, WAY100135. Escitalopram induced only partial inhibition of serotonin neurons in the VWR rats while WAY100135 increased the firing activity of serotonin neurons above the baseline value. Conclusions: The beneficial effect of physical exercise on mood is mediated, at least in part, via activation of serotonin neurons. Physical exercise can potentiate the response to selective serotonin reuptake inhibitors by increasing the basal firing activity and diminishing selective serotonin reuptake inhibitor-induced inhibition of serotonin neurons.

Altered Sodium and Potassium, but not Calcium Currents in Cerebellar Granule Cells in an In Vitro Model of Neuronal Injury.

Acute injury of central nervous system (CNS) starts a cascade of morphological, molecular, and functional changes including formation of a fibrotic scar, expression of transforming growth factor beta 1 (TGF-ß1), and expression of extracellular matrix proteins leading to arrested neurite outgrowth and failed regeneration. We assessed alteration of electrophysiological properties of cerebellar granule cells (CGCs) in two in vitro models of neuronal injury: (i) model of fibrotic scar created from coculture of meningeal fibroblasts and cerebral astrocytes with addition of TGF-ß1; (ii) a simplified model based on administration of TGF-ß1 to CGCs culture. Both models reproduced suppression of neurite outgrowth caused by neuronal injury, which was equally restored by chondroitinase ABC (ChABC), a key disruptor of fibrotic scar formation. Voltage-dependent calcium current was not affected in either injury model. However, intracellular calcium concentration could be altered as an expression of inositol trisphosphate receptor type 1 was suppressed by TGF-ß1 and restored by ChABC. Voltage-dependent sodium current was significantly suppressed in CGCs cultured on a model of fibrotic scar and was only partly restored by ChABC. Administration of TGF-ß1 significantly shifted current-voltage relation of sodium current toward more positive membrane potential without change to maximal current amplitude. Both transient and sustained potassium currents were significantly suppressed on a fibrotic scar and restored by ChABC to their control amplitudes. In contrast, TGF-ß1 itself significantly upregulated transient and did not change sustained potassium current. Observed changes of voltage-dependent ion currents may contribute to known morphological and functional changes in injured CNS.

Purinergic regulation of brain catecholamine neurotransmission: In vivo electrophysiology and microdialysis study in rats.

It was previously reported that adenosine-2A (A2A) receptors interact with dopamine-2 (D2) receptors on a molecular level. The aim of the current study was to investigate the functional output of this interaction. In vivo microdialysis was used to assess the effects of an antagonist of A2A receptors, ZM 241385, and an antagonist of D2 receptors haloperidol, either alone or in combination, on brain catecholamine levels. It was found that ZM 241385 did not alter catecholamine levels by its own, but potentiated haloperidol-induced dopamine and norepinephrine release in the nucleus accumbens and prefrontal cortex, respectively. In vivo electrophysiology was used to assess the effect of an agonist (CGS 216820) and an antagonist (ZM 241385) of A2A receptors on the excitability of dopamine and norepinephrine neurons. It was found that CGS 216820 dose-dependently inhibited dopamine and norepinephrine neurons and ZM 241385 reversed this inhibition. In conclusion, those A2A receptors modulate brain catecholamine transmission, and this modulation is mediated, at least in part, via the regulation of excitability of norepinephrine and dopamine neurons. The ability of antagonists of A2A receptors to potentiate the effect of haloperidol on brain norepinephrine and dopamine levels may enhance its clinical efficacy as an antipsychotic drug.

Contrasting the roles of the I-II loop gating brake in CaV3.1 and CaV3.3 calcium channels.

Low-voltage-activated CaV3 channels are distinguished among other voltage-activated calcium channels by the most negative voltage activation threshold. The voltage dependence of current activation is virtually identical in all three CaV3 channels while the current kinetics of the CaV3.3 current is one order slower than that of the CaV3.1 and CaV3.2 channels. We have analyzed the voltage dependence and kinetics of charge (Q) movement in human recombinant CaV3.3 and CaV3.1 channels. The voltage dependence of voltage sensor activation (Qon-V) of the CaV3.3 channel was significantly shifted with respect to that of the CaV3.1 channel by +18.6 mV and the kinetic of Qon activation in the CaV3.3 channel was significantly slower than that of the CaV3.1 channel. Removal of the gating brake in the intracellular loop connecting repeats I and II in the CaV3.3 channel in the ID12 mutant channel shifted the Qon-V relation to a value even more negative than that for the CaV3.1 channel. The kinetic of Qon activation was not significantly different between ID12 and CaV3.1 channels. Deletion of the gating brake in the CaV3.1 channel resulted in a GD12 channel with the voltage dependence of the gating current activation significantly shifted toward more negative potentials. The Qon kinetic was not significantly altered. ID12 and GD12 mutants did not differ significantly in voltage dependence nor in the kinetic of voltage sensor activation. In conclusion, the putative gating brake in the intracellular loop connecting repeats I and II controls the gating current of the CaV3 channels. We suggest that activation of the voltage sensor in domain I is limiting both the voltage dependence and the kinetics of CaV3 channel activation.

Effects of AP39, a novel triphenylphosphonium derivatised anethole dithiolethione hydrogen sulfide donor, on rat haemodynamic parameters and chloride and calcium Cav3 and RyR2 channels.

H2S donor molecules have the potential to be viable therapeutic agents. The aim of this current study was (i) to investigate the effects of a novel triphenylphosphonium derivatised dithiolethione (AP39), in the presence and absence of reduced nitric oxide bioavailability and (ii) to determine the effects of AP39 on myocardial membrane channels; CaV3, RyR2 and Cl(-). Normotensive, L-NAME- or phenylephrine-treated rats were administered Na2S, AP39 or control compounds (AP219 and ADT-OH) (0.25-1 µmol kg(-1)i.v.) and haemodynamic parameters measured. The involvement of membrane channels T-type Ca(2+) channels CaV3.1, CaV3.2 and CaV3.3 as well as Ca(2+) ryanodine (RyR2) and Cl(-) single channels derived from rat heart sarcoplasmic reticulum were also investigated. In anaesthetised Wistar rats, AP39 (0.25-1 µmol kg(-1) i.v) transiently decreased blood pressure, heart rate and pulse wave velocity, whereas AP219 and ADT-OH and Na2S had no significant effect. In L-NAME treated rats, AP39 significantly lowered systolic blood pressure for a prolonged period, decreased heart rate and arterial stiffness. In electrophysiological studies, AP39 significantly inhibited Ca(2+) current through all three CaV3 channels. AP39 decreased RyR2 channels activity and increased conductance and mean open time of Cl(-) channels. This study suggests that AP39 may offer a novel therapeutic opportunity in conditions whereby (•)NO and H2S bioavailability are deficient such as hypertension, and that CaV3, RyR2 and Cl(-) cardiac membrane channels might be involved in its biological actions.

Ca(V)1.2 and Ca(V)1.3 L-type calcium channels regulate the resting membrane potential but not the expression of calcium transporters in differentiated PC12 cells.

PC12 cells differentiated under the influence of the neuronal growth factor (NGF) serve as a model of both sympathetic neurons and chromaffin cells. NGF-induced differentiation critically depends on elevated intracellular calcium concentration. Main pathway for Ca²âº entry in excitable cells is represented by voltage-dependent calcium channels including L-type calcium channels (LTCC). We investigated role of Ca(V)1.2 and Ca(V)1.3 LTCC subtypes in NGF-differentiated PC12 cells. The expression of LTCC subtypes was downregulated by transfection of NGF-differentiated PC12 cells with siRNA for either CACNA1C or CACNA1D gene. Efficiency of gene silencing was verified by RT-PCR and by functional essay. The dominant LTCC subtype in PC12 cells was Ca(V)1.2. Downregulation of either LTCC significantly hyperpolarized the resting membrane potential. Expression of mRNA for intracellular calcium transporters inositol trisphosphate receptor type 1, 2 and 3, ryanodine receptor type 1 and 2 and sarco/endoplasmic reticulum Ca²âº ATPase type 2 as well as plasma membrane transporters Na⁺-Ca²âº exchanger type 1 and 2 was not altered in the absence of either LTCC subtype. In conclusion, Ca²âº influx through Ca(V)1.2 or to Ca(V)1.3 channel subtypes contributes to maintenance of the resting membrane potentials of NGF-differentiated PC12 cells but is not required for regulation of expression of genes for calcium-transporting proteins.

Cellular and molecular mechanisms underlying the treatment of depression: focusing on hippocampal G-protein-coupled receptors and voltage-dependent calcium channels.

Depression is a brain disorder characterized by severe emotional, cognitive, neuroendocrine and somatic dysfunction. Although the latest generation of antidepressant drugs has improved clinical efficacy and safety, the onset of their clinical effect is significantly delayed after treatment commencement, and a large number of patients exhibit inadequate response to these drugs and/or depression relapse even following initially successful treatment. It is therefore essential to develop new antidepressant drugs and/or adjuncts to existing ones. Recent studies suggest that the beneficial effect of antidepressant drugs is mediated, at least in part, via stimulation of adult hippocampal neurogenesis and subsequent increase in hippocampal plasticity. Since the stimulatory effect of antidepressant drugs on hippocampal neurogenesis involves G-protein coupled receptors (GPCR) and voltage-dependent calcium channels (VDCC), greater efficacy may be available if future antidepressant drugs directly target these specific GPCR and VDCC. The potential advantages and limitations of these treatment strategies are discussed in the article.

Maternal treatment with a selective delta-opioid receptor agonist during gestation has a sex-specific pro-cognitive action in offspring: mechanisms involved.

Background: There is growing evidence that the treatment of several mental disorders can potentially benefit from activation of delta-opioid receptors. In the future, delta-agonists with a safe pharmacological profile can be used for the treatment of mood disorders in pregnant women. However, the data on prenatal exposure to delta-opioid agonists are missing. The present study is aimed to test the hypothesis that the activation of delta-opioid receptors during gravidity has positive effects on the behaviour accompanied by changes in glutamate and monoamine neurotransmission. Methods: Gestating Wistar rats were chronically treated with a selective delta-agonist SNC80 or vehicle. Adult male and female offspring underwent novel object recognition (for the assessment of cognition) and open field (for the assessment of anxiety and habituation) tests, followed by in vivo electrophysiological examination of the activity of hippocampal glutamate and midbrain serotonin (5-HT) and dopamine neurons. Results: We found that the maternal treatment with SNC80 did not affect the offspring's anxiety, habituation, and 5-HT neuronal firing activity. Female offspring of SNC80-treated dams exhibited improved novelty recognition associated with decreased firing rate and burst activity of glutamate and dopamine neurons. Conclusion: Maternal treatment with delta-opioid agonists during gestation may have a pro-cognitive effect on offspring without any negative effects on anxiety and habituation. The putative pro-cognitive effect might be mediated via mechanism(s) involving the firing activity of hippocampal glutamate and mesolimbic dopamine neurons.

Effects of pre-gestational exposure to the stressors and perinatal bupropion administration on the firing activity of serotonergic neurons and anxiety-like behavior in rats.

Exposure by women to stressors before pregnancy increases their risk of contracting prenatal depression, a condition which typically may require antidepressant treatment. And even though such perinatal antidepressant treatment is generally considered to be safe. For the mother, its effects on the development and functioning of the offspring`s brain remain unknown. In this study, we aimed to investigate the effects of pregestational chronic unpredictable stress (CUS) and perinatal bupropion on the anxiety behavior and firing activity of the dorsal raphe nucleus (DRN) serotonin (5-HT) neurons. Female rats underwent CUS for three weeks before mating. Bupropion was administered to them from gestation day ten until their offspring were weaned. Behavioral (elevated plus maze or EPM test) and neurophysiological (single-unit in vivo electrophysiology) assessments were performed on offspring who reached the age of 48-56 days. We found that maternal CUS and perinatal bupropion, as separate factors on their own, did not change offspring behavior. There was, however, an interaction between their effects on the number of entries to the open arms and time spent in the intersection: maternal CUS tended to decrease these values, and perinatal bupropion tended to diminish CUS effect. Maternal CUS increased the firing activity of 5-HT neurons in males, but not females. Perinatal bupropion did not alter the firing activity of 5-HT neurons but tended to potentiate the maternal CUS-induced increase in 5-HT neuronal firing activity. The CUS-induced increase in firing activity of 5-HT neurons might be a compensatory mechanism that diminishes the negative effects of maternal stress. Perinatal bupropion does not alter the offspring`s anxiety and firing activity of 5-HT, but it does intervene in the effects of maternal stress.