Sujit Sikdar

Hippocampal neurons are affected by chronic stress and have a high density of cytoplasmic mineralocorticoid and glucocorticoid receptors (MR and GR). Detailed studies on the genomic effects of the stress hormone corticosterone at physiologically relevant concentrations on different steps in synaptic transmission are limited. In this study, we tried to delineate how activation of MR and GR by different concentrations of corticosterone affects synaptic transmission at various levels. The effect of 3-h corticosterone (25, 50, and 100 nM) treatment on depolarization-mediated calcium influx, vesicular release and properties of miniature excitatory post-synaptic currents (mEPSCs) were studied in cultured hippocampal neurons. Activation of MR with 25 nM corticosterone treatment resulted in enhanced depolarization-mediated calcium influx via a transcription-dependent process and increased frequency of mEPSCs with larger amplitude. On the other hand, activation of GR upon 100 nM corticosterone treatment resulted in increase in the rate of vesicular release via the genomic actions of GR. Furthermore, GR activation led to significant increase in the frequency of mEPSCs with larger amplitude and faster decay. Our studies indicate that differential activation of the dual receptor system of MR and GR by corticosterone targets the steps in synaptic transmission differently.

The local fast-spiking interneurons (FSINs) are considered to be crucial for the generation, maintenance, and modulation of neuronal network oscillations especially in the gamma frequency band. Gamma frequency oscillations have been associated with different aspects of behavior. But the prolonged effects of gamma frequency synaptic activity on the FSINs remain elusive. Using whole cell current clamp patch recordings, we observed a sustained decrease of intrinsic excitability in the FSINs of the dentate gyrus (DG) following repetitive stimulations of the mossy fibers at 30 Hz (gamma bursts). Surprisingly, the granule cells (GCs) did not express intrinsic plastic changes upon similar synaptic excitation of their apical dendritic inputs. Interestingly, pairing the gamma bursts with membrane hyperpolarization accentuated the plasticity in FSINs following the induction protocol, while the plasticity attenuated following gamma bursts paired with membrane depolarization. Paired pulse ratio measurement of the synaptic responses did not show significant changes during the experiments. However, the induction protocols were accompanied with postsynaptic calcium rise in FSINs. Interestingly, the maximum and the minimum increase occurred during gamma bursts with membrane hyperpolarization and depolarization respectively. Including a selective blocker of calcium-permeable AMPA receptors (CP-AMPARs) in the bath; significantly attenuated the calcium rise and blocked the membrane potential dependence of the calcium rise in the FSINs, suggesting their involvement in the observed phenomenon. Chelation of intracellular calcium, blocking HCN channel conductance or blocking CP-AMPARs during the experiment forbade the long lasting expression of the plasticity. Simultaneous dual patch recordings from FSINs and synaptically connected putative GCs confirmed the decreased inhibition in the GCs accompanying the decreased intrinsic excitability in the FSINs. Experimentally constrained network simulations using NEURON predicted increased spiking in the GC owing to decreased input resistance in the FSIN. We hypothesize that the selective plasticity in the FSINs induced by local network activity may serve to increase information throughput into the downstream hippocampal subfields besides providing neuroprotection to the FSINs.

ObjectiveMuch evidence suggests that the subiculum plays a significant role in the regulation of epileptic activity. Lactate acts as a neuroprotective agent against many conditions that cause brain damage. During epileptic seizures, lactate formation reaches up to ~6 mmol/L in the brain. We investigated the effect of lactate on subicular pyramidal neurons after induction of epileptiform activity using 4‐aminopyridine (4‐AP‐0Mg2+) in an in vitro epilepsy model in rats. The signaling mechanism associated with the suppression of epileptiform discharges by lactate was also investigated.MethodsWe used patch clamp electrophysiology recordings on rat subicular neurons of acute hippocampal slices. Immunohistochemistry was used for demonstrating the expression of hydroxycarboxylic acid receptor 1 (HCA1) in the subiculum.ResultsOur study showed that application of 6 mmol/L lactate after induction of epileptiform activity reduced spike frequency (control 2.5 ± 1.23 Hz vs lactate 1.01 ± 0.91 Hz, P = .049) and hyperpolarized the subicular neurons (control −51.8 ± 1.9 mV vs lactate −57.2 ± 3.56 mV, P = .002) in whole cell patch‐clamp experiments. After confirming the expression of HCA1 in subicular neurons, we demonstrated that lactate‐mediated effect occurs via HCA1 by using its specific agonist. All values are mean ±SD. Electrophysiological recordings revealed the involvement of Gβγ and intracellular cAMP in the lactate‐induced effect. Furthermore, current‐clamp and voltage‐clamp experiments showed that the G protein–coupled inwardly rectifying potassium (GIRK) channel blocker tertiapin‐Q, negated the lactate‐induced inhibitory effect, which confirmed that lactate application results in outward GIRK current.SignificanceOur finding points toward the potential role of lactate as an anticonvulsant by showing lactate‐induced suppression of epileptiform activity in subicular neurons. The study gives a different insight by suggesting importance of endogenous metabolite and associated signaling factors, which can aid in improving the present therapeutic approach for treating epilepsy.

Pannexins are single-membrane large-pore ion channels that release ATP upon activation. Three isoforms of pannexins, 1, 2, and 3, perform diverse cellular roles, including inflammation, differentiation, neuropathic pain, and ATP release. In this study, we report the cryoEM structure of pannexin 3 at 3.9 Å and characterize the structural differences with pannexin isoforms 1 and 2. We observe the organization of the Pannexin3 vestibule into two distinct chambers with a wider pore radius in comparison to both PANX1 and 2 isoforms. We further report the structure of pannexin1 congenital mutant R217H in the resolution range of 3.9 Å. The congenital mutant R217H in transmembrane helix3 (TM3), R217H induce structural changes that leads to a partially closed pore and altered ATP interaction propensities. The channel conductance of the congenital mutant displays weakened voltage sensitivity. The results showcase a complete comparison of the three pannexin isoform structures that along with t...

Besides having a role in signal transduction some trimeric G-proteins may be involved in a late stage of exocytosis. Using immunocytochemistry and confocal microscopy we found that Gi3-protein resides mainly in the plasma membrane, whereas Gi1/2-protein is preferentially associated with secretory granules. To study the function of trimeric Gi3- and Gi1/2-proteins, secretory responses in single rat melanotrophs were monitored by patch-clamp membrane capacitance measurements. We report here that mastoparan, an activator of trimeric G-proteins, enhances calcium-induced secretory activity in rat melanotrophs. The introduction of synthetic peptides corresponding to the C-terminal domain of the α-subunit of Gi3- and Gi1/2-proteins indicated that Gi3 peptide specifically blocked the mastoparan-stimulated secretory activity, which indicates an involvement of a trimeric Gi3-protein in mastoparan-stimulated secretory activity. Flash photolysis of caged Ca2+-elicited biphasic capacitance incre...

Neuro-electronic hybrid systems have been gaining interest of researchers as a possible architecture for computing. This aims to exploit the strengths of biological neuronal systems with their immense parallel processing and learning capabilities along with that of VLSI systems. Towards this end, we have set up a system which demonstrates the use of a live neuronal culture to solve a real world problem of controlling a robot doing the task of obstacle avoidance. We show that a neuronal culture can look at the sensor inputs to the robot and generate motor commands to allow it to explore an arena while avoiding obstacles.

Although many proteins essential for regulated neurotransmitter and peptide hormone secretion have been identified, little is understood about their precise roles at specific stages of the multistep pathway of exocytosis. To study the function of CAPS (Ca 2+ -dependent activator protein for secretion), a protein required for Ca 2+ -dependent exocytosis of dense-core vesicles, secretory responses in single rat melanotrophs were monitored by patch-clamp membrane capacitance measurements. Flash photolysis of caged Ca 2+ elicited biphasic capacitance increases consisting of rapid and slow components with distinct Ca 2+ dependencies. A threshold of ≈10 μM Ca 2+ was required to trigger the slow component, while the rapid capacitance increase was recorded already at a intracellular Ca 2+ activity < 10 μM. Both kinetic membrane capacitance components were abolished by botulinum neurotoxin B or E treatment, suggesting involvement of SNARE (soluble N -ethylmaleimide-sensitive factor attach...

The three-dimensional (3D) NMR solution structure (MeOH) of the highly hydrophobic delta-conotoxin delta-Am2766 from the molluscivorous snail Conus amadis has been determined. Fifteen converged structures were obtained on the basis of 262 distance constraints, 25 torsion-angle constraints, and ten constraints based on disulfide linkages and H-bonds. The root-mean-square deviations (rmsd) about the averaged coordinates of the backbone (N, C(alpha), C) and (all) heavy atoms were 0.62+/-0.20 and 1.12+/-0.23 A, respectively. The structures determined are of good stereochemical quality, as evidenced by the high percentage (100%) of backbone dihedral angles that occupy favorable and additionally allowed regions of the Ramachandran map. The structure of delta-Am2766 consists of a triple-stranded antiparallel beta-sheet, and of four turns. The three disulfides form the classical 'inhibitory cysteine knot' motif. So far, only one tertiary structure of a delta-conotoxin has been reported; thus, the tertiary structure of delta-Am2766 is the second such example. Another Conus peptide, Am2735 from C. amadis, has also been purified and sequenced. Am2735 shares 96% sequence identity with delta-Am2766. Unlike delta-Am2766, Am2735 does not inhibit the fast inactivation of Na+ currents in rat brain Na(v)1.2 Na+ channels at concentrations up to 200 nM.

The interaction of zwitterionic lipid DMPC and DPPC with cyclic hexapeptide, cyclo (D-Ala-L-Pro-L-Ala)2 was studied using circular dichroism (CD) and differential scanning calorimetry (DSC). Preliminary membrane conductance results showed that the peptide has a tendency to form channels inside the lipid bilayer. CD studies indicated that as the lipid/peptide (L/P) ratio (DMPC/peptide) was increased, the magnitude of the negative CD band having a lambda(max) around 200 nm decreased. At a L/P ratio of 210:1, this band disappeared completely, indicating dramatic conformational changes in the peptide on interaction with the lipid bilayer. Reduction of the phase transition temperature and the maximum heat capacity of the lipid bilayer (DPPC) for gel-to-liquid crystalline phase transition indicates a strong interaction of the peptide with the lipid bilayer.

Tetrapentylammonium (TPeA) block of rat brain type IIA sodium channel α subunit was studied using whole cell patch clamp. Results indicate that TPeA blocks the inactivating brain sodium channel in a potential and use‐dependent manner similar to that of the cardiac sodium channel. Removal of inactivation using chloramine‐T (CT) unmasks a time‐dependent block by TPeA consistent with slow blocking kinetics. On the other hand, no time dependence is observed when inactivation is abolished by modification with veratridine. TPeA does not bind in a potential‐dependent fashion to veratridine‐modified channels and does not significantly affect gating of veratridine‐modified channels suggesting that high affinity binding of TPeA to the brain sodium channel is lost after veratridine modification.British Journal of Pharmacology (2001) 132, 1755–1760; doi:10.1038/sj.bjp.0703973

1. The effects of the Na+ electrochemical potential gradient on gamma‐aminobutyric acid (GABA)‐induced Cl‐ currents (ICl) in frog sensory neurones were studied, using a suction pipette technique with which internal perfusion can be accomplished under current‐ and voltage‐clamp conditions. 2. Under current clamp, the depolarizing response to GABA decreased in the presence of external Na+. A similar external Na+‐dependent reduction in the GABA‐induced inward ICl was observed under voltage clamp. The reversal potential of GABA‐induced ICl (EGABA) was nearly equal to the Cl‐ equilibrium potential (ECl), irrespective of the presence or absence of external Na+. 3. Varying the Na+ influx by changing the holding membrane potential (VH) altered the GABA response: the GABA‐induced ICl decreased progressively as VH became more negative. 4. The effects of changing the external and internal Na+ concentrations ([Na+]o and [Na+]i) on the GABA‐induced ICl were also studied. Increasing [Na+]o at a c...

1. Voltage‐clamp recordings were obtained from gonadotrophs of the ovine pars tuberalis in dissociated cell culture, utilizing the whole‐cell recording mode of the patch‐clamp technique. 2. The amplitudes of Ca2+ and Ba2+ currents were dependent on the extracellular concentration of divalent cation. 3. Ba2+ tail currents were observed on termination of depolarizing voltage steps. The extrapolated amplitudes of ‘instantaneous’ tail currents increased with membrane depolarization and showed saturation beyond +15 mV. 4. True inactivation of currents occurred in the presence of both external Ca2+ and Ba2+, judged from decrease in tail current amplitudes with progressive increases in duration of the activating voltage pulse. The inactivation process was fitted by a single‐exponential function at membrane potentials below ‐25 mV, while at more depolarized potentials the inactivation was better described by a double‐exponential function. The inactivation time constants decreased with posit...

Tissue acidosis and high lactate concentrations are associated with cerebral ischaemia. The degree of acidosis is dependent on circulating glucose concentration, hyperglycaemia being associated with increased acidosis. Among other agents, lactate and protons have been shown to activate the leak potassium channel; TREK1 (TWIK related potassium channel 1) from the intracellular side and its increased activity is implicated in tolerance towards ischaemic cell damage. In the present study, we show that ischaemic concentrations of lactate (30 mM) at pH 7.0 and 6.5, commonly observed during ischemia, cause robust potentiation of human TREK1 (hTREK1) activity at single-channel level in cell-free inside-out membrane patches, while 30 mM lactate at pH 6.0 to 5.5, commonly observed during hyperglycaemic ischemia, reduces hTREK1 channel activity significantly. The biphasic effect of 30 mM lactate (ischaemic concentrations) on modulation of hTREK1 by varying pH conditions is specific since basal concentrations of lactate (3 mM) and 30 mM pyruvate at pH 7.0 and 5.5 failed to show similar effect as lactate. Experiments with deletion and point mutants of hTREK1 channel suggest that lactate changes the pH modulation of hTREK1 by interacting differently with the histidine residue at 328th position (H328) above and below its pKa (∼6.0) in the intracellular carboxyl-terminal domain of TREK1. This lactate-induced pH modulation of hTREK1 is absent in C-terminal deletion mutant, CTDΔ100, and is similar in E321A-hTREK1 mutant as in wild-type hTREK1 suggesting that it is independent of pH-sensitive glutamate residue at 321st position. Such a differential pH-dependent effect of lactate on an ion channel function has not been reported earlier and has important implications in different stages of ischaemia.

Acetylcholine release is vital in the pacing of theta rhythms in the hippocampus. The subiculum is the output region of the hippocampus with different neuronal subtypes that generate theta oscillations during arousal and rapid eye movement sleep. The combination of intrinsic resonance in the hippocampal neurons and the periodic excitation of hippocampal excitatory and inhibitory neurons by cholinergic pathway drives theta oscillations. However, the acetylcholine mediated effect on intrinsic subthreshold resonance generating hyperpolarization‐activated cyclic nucleotide‐gated current, Ih of subicular neurons is unexplored. We studied the acetylcholine receptor‐independent effect of cholinergic agents on the intrinsic properties of subiculum principal neurons and the underlying mechanism.

The neuronal voltage-gated sodium channels play a vital role in the action potential waveform shaping and propagation. Here, we report the effects of prolonged depolarization (1-160 s) on the detailed kinetics of activation, fast inactivation and recovery from slow inactivation in the rNa(v)1.2a voltage-gated sodium channel alpha-subunit expressed in Chinese hamster ovary (CHO) cells. Wavelet analysis revealed that the duration and amplitude of a prolonged sustained depolarization altered all the steady state and kinetic parameters of the channel in a pseudo-oscillatory fashion with time-variable period and amplitude, often superimposed on a linear trend. The half steady state activation potential showed a reversible depolarizing shift of 5-10 mV with duration of prolonged depolarization, while half steady state inactivation potential showed a hyperpolarizing shift of 43-55 mV. The time periods for most of the parameters relating to activation and fast and slow inactivation, lie close to 28-30 s, suggesting coupling of these kinetic processes through an oscillatory mechanism. Co-expression of the beta1-subunit affected the time periods of oscillation (close to 22 s for alpha + beta1) in steady state activation parameters. Application of a pulse protocol that mimicked paroxysmal depolarizing shift (PDS), a kind of depolarization seen in epileptic discharges, instead of a sustained depolarization, also caused oscillatory behaviour in the rNav1.2a alpha-subunit. This inherent pseudo-oscillatory mechanism may regulate excitability of the neurons, account for the epileptic discharges and subthreshold membrane potential oscillation and offer a molecular memory mechanism intrinsic to the neurons, independent of synaptic plasticity.

Oxidative stress due to excessive accumulation of reactive oxygen or nitrogen species in the brain as seen in certain neurodegenerative diseases can have deleterious effects on neurons. Hydrogen peroxide, endogenously generated in neurons under normal physiological conditions, can produce an excess of hydroxyl radical via a Fenton mediated mechanism. This may induce acute oxidative injury if not scavenged or removed effectively by antioxidants. There are several biochemical assay methods to estimate oxidative injury in cells; however, they do not provide information on the biochemical changes as the cells get damaged progressively under oxidative stress. Raman microspectroscopy offers the possibility of real time monitoring of the chemical composition of live cells undergoing oxidative stress under physiological conditions. In the present study, a hippocampal neuron coculture was used to observe the acute impact of hydroxyl radicals generated by hydrogen peroxide in the presence of Fe(2+) (Fenton reaction). Raman peaks related to nucleic acids (725, 782, 1092, 1320, 1340, 1420, and 1576 cm(-1)) showed time-dependent changes over the experimental period (60 min), indicating the breakdown of the phosphodiester backbone as well as nuclear bases. Interestingly, ascorbic acid (a potent antioxidant) when cotreated with Fenton reactants showed protection of cells as inferred from the Raman spectra, presumably by scavenging hydroxyl radicals. Little or no change in the Raman spectra was observed for untreated control cells and for cells exposed to Fe(2+) only, H2O2 only, and ascorbate only. A live-dead assay study also supported the current observations. Hence, Raman microspectroscopy has the potential to be an excellent noninvasive tool for early detection of oxidative stress that is seen in neurodegenerative diseases.

Oxidative stress can induce central and peripheral neurodegenerative diseases like Parkinson’s, Alzheimer’s and peripheral neuropathy. Reactive oxygen or nitrogen species or free radicals play a critical role in oxidative stress. Hydrogen peroxide is a reactive oxygen species and can produce hydroxyl radical in presence of metal ions (by Fenton reaction), which induces per oxidation of major cellular components such as lipids, proteins and nucleic acids [1,2]. Hence, the effects of hydroxyl radical on rat hippocampal neurons were studied to understand the molecular changes related to oxidative stress in neurodegenerative disorders. Hippocampal neuron network culture from Wistar rats was grown on MgF2 cover slips for 7 days. Before Raman experiments, the culture cover slips were washed with HEPES buffer solution. The cells were incubated in the same buffer with 5% CO2 and 95% air humidified, at 37°C. After recording the control spectra (before treatment) for 15 min, the incubation bu...

The subiculum is a structure that forms a bridge between the hippocampus and the entorhinal cortex (EC), and plays a major role in the memory consolidation process. Here, we demonstrate spike-timing-dependent plasticity (STDP) at the proximal excitatory inputs on the subicular pyramidal neurons of juvenile rat. Causal (positive) pairing of a single EPSP with a single back-propagating action potential (bAP) after a time interval of 10 ms (+10 ms) failed to induce plasticity. However, increasing the number of bAPs in a burst to three, at two different frequencies of 50 Hz (bAP burst) and 150 Hz, induced long-term depression (LTD) after a time interval of +10 ms in both the regular-firing (RF), and the weak burst firing (WBF) neurons. The LTD amplitude decreased with increasing time interval between the EPSP and the bAP burst. Reversing the order of the pairing of the EPSP and the bAP burst induced LTP at a time interval of -10 ms. This finding is in contrast with reports at other syna...

The voltage-dependent kinetics of veratridine-modified RIIA Na+ channel alpha subunit expressed heterologously in CHO cells were studied using the whole-cell patch-clamp technique. The activation and deactivation kinetics are well described by double exponential functions but poorly by a monoexponential function. Unlike the slow component, the fast time constant and associated amplitude factor depended steeply on the potential. The steady-state activation of veratridine-modified channels is described by a Boltzmann function with a V1/2 of -131.9 mV and a slope of 9.41 mV. A two-state model is proposed for the fast component that explains the kinetics of veratridine's mechanism of action.

In the work reported here, we have investigated the changes in the activation and fast inactivation properties of the rat brain voltage-gated sodium channel (rNa(v) 1.2a) alpha subunit, expressed heterologously in the Chinese Hamster Ovary (CHO) cells, by short depolarizing prepulses (10-1000 ms). The time constant of recovery from fast inactivation (tau(fast)) and steady-state parameters for activation and inactivation varied in a pseudo-oscillatory fashion with the duration and amplitude of a sustained prepulse. A consistent oscillation was observed in most of the steady-state and non-inactivating current parameters with a time period close to 225 ms, although a faster oscillation of time period 125 ms was observed in the tau(fast). The studies on the non-inactivating current and steady-state activation indicate that the phase of oscillation varies from cell to cell. Co-expression of the beta1 subunit with the alpha subunit channel suppressed the oscillation in the charge movement per single channel and free energy of steady-state inactivation, although the oscillation in the half steady-state inactivation potential remained unaltered. Incidentally, the frequencies of oscillation in the sodium channel parameters (4-8 Hz) correspond to the theta component of network oscillation. This fast pseudo-oscillatory mechanism, together with the slow pseudo-oscillatory mechanism found in these channels earlier, may contribute to the oscillations in the firing properties observed in various neuronal subtypes and many pathological conditions.

Fenvalerate is a pyrethroid insecticide which interacts with ionic channels. Using circular dichroism technique we have studied the interaction of fenvalerate with gramicidin, a model channel peptide which transports ions. In most organic solvents, gramicidin exists as a double helix except in trifluoroethanol where it exists as a channel forming single stranded beta6.3 helical monomer. In model lipid membranes, under certain experimental conditions, gramicidin exists as a channel forming single stranded beta6.3 helical dimer. Our results show that fenvalerate interacts more with the single stranded beta6.3 helical monomer or dimer than with the double helical form of gramicidin. This was further confirmed by an increase in the rate of gramicidin mediated proton transport in liposomes by fenvalerate, using the pH sensitive fluorophore, pyranine.

Glial cells in the brain are capable of responding to hormonal signals. The ovarian steroid hormone 17beta-estradiol, in addition to its actions on neurons, can directly affect glial cells. Estrogen receptors have been described on both neurons and astrocytes, suggesting a complex interplay between these two in mediating the effects of the hormone. Astrocytes sense and respond to neuronal activity with a rise in intracellular calcium concentration ([Ca(2+)](i)). Using simultaneous electrophysiology and calcium imaging techniques, we monitored neuronal activity evoked astrocyte ([Ca(2+)](i)) changes in mixed hippocampal cultures loaded with fluo-3 AM. Action potential firing in neurons, elicited by injecting depolarizing current pulses, was associated with ([Ca(2+)](i)) elevations in astrocytes, which could be blocked by 200 microM MCPG and also 1 microM TTX. We compared astrocytic ([Ca(2+)](i)) transients in control and 24-hour estradiol treated cultures. The amplitude of the ([Ca(2+)](i)) transient, the number of responsive astrocytes, and the ([Ca(2+)](i)) wave velocity were all significantly reduced in estradiol treated cultures. ([Ca(2+)](i)) rise in astrocytes in response to local application of the metabotropic glutamate receptor (mGluR) agonist t-ACPD was attenuated in estradiol treated cultures, suggesting functional changes in the astrocyte mGluR following 24-h treatment with estradiol. Since astrocytes can modulate synaptic transmission by release of glutamate, the attenuated ([Ca(2+)](i)) response seen following estradiol treatment could have functional consequences on astrocyte-neuron signaling.

Extracellular single neuron activity of the dorsolateral prefrontal cortex (DL) was recorded in the monkey, during bar pressing for reward. The bar press-related neurons which exhibited excitation or inhibition during the bar press period were found to be scattered diffusely in the DL. Activity changes that arose during the bar press period also appeared when the experimenter pressed the bar for the monkey. When delivery of food was delayed for a random time after cue tone on, bar press responses were still confined to the bar press period and did not extend beyond the cue tone. These results, together with the lesion studies, suggest that bar press-related neurons are involved in the animal's concentration during the bar press period.