Gytis Baranauskas scite author profile

Acute exposure to cocaine transiently induces several Fos family transcription factors in the nucleus accumbens, a region of the brain that is important for addiction. In contrast, chronic exposure to cocaine does not induce these proteins, but instead causes the persistent expression of highly stable isoforms of deltaFosB. deltaFosB is also induced in the nucleus accumbens by repeated exposure to other drugs of abuse, including amphetamine, morphine, nicotine and phencyclidine. The sustained accumulation of deltaFosB in the nucleus accumbens indicates that this transcription factor may mediate some of the persistent neural and behavioural plasticity that accompanies chronic drug exposure. Using transgenic mice in which deltaFosB can be induced in adults in the subset of nucleus accumbens neurons in which cocaine induces the protein, we show that deltaFosB expression increases the responsiveness of an animal to the rewarding and locomotor-activating effects of cocaine. These effects of deltaFosB appear to be mediated partly by induction of the AMPA (alpha-amino-3-hydroxy-5-methyl-4-isoxazole) glutamate receptor subunit GluR2 in the nucleus accumbens. These results support a model in which deltaFosB, by altering gene expression, enhances sensitivity to cocaine and may thereby contribute to cocaine addiction.

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Somatodendritic Depolarization-Activated Potassium Currents in Rat Neostriatal Cholinergic Interneurons Are Predominantly of the A Type and Attributable to Coexpression of Kv4.2 and Kv4.1 Subunits

Song

et al. 1998

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Unlike other neostriatal neurons, cholinergic interneurons exhibit spontaneous, low-frequency, repetitive firing. To gain an understanding of the K+ channels regulating this behavior, acutely isolated adult rat cholinergic interneurons were studied using whole-cell voltage-clamp and single-cell reverse transcription-PCR techniques. Cholinergic interneurons were identified by the presence of choline acetyltransferase (ChAT) mRNA. Depolarization-activated potassium currents in cholinergic interneurons were dominated by a rapidly inactivating, K+-selective A current that became active at subthreshold potentials. Depolarizing prepulses inactivated this component of the current, leaving a delayed, rectifier-like current. Micromolar concentrations of Cd2+ dramatically shifted the voltage dependence of the A current without significantly affecting the delayed rectifier. The A-channel antagonist 4-aminopyridine (4-AP) produced a voltage-dependent block (IC50, approximately 1 mM) with a prominent crossover at millimolar concentrations. On the other hand, TEA preferentially blocked the sustained current component at concentrations <10 mM. Single-cell mRNA profiling of subunits known to give rise to rapidly inactivating K+ currents revealed the coexpression of Kv4.1, Kv4.2, and Kv1.4 mRNAs but low or undetectable levels of Kv4.3 and Kv3.4 mRNAs. Kv1.1, beta1, and beta2 subunit mRNAs, but not beta3, were also commonly detected. The inactivation recovery kinetics of the A-type current were found to match those of Kv4.2 and 4.1 channels and not those of Kv1.4 or Kv1. 1 and beta1 channels. Immunocytochemical analysis confirmed the presence of Kv4.2 but not Kv1.4 subunits in the somatodendritic membrane of ChAT-immunoreactive neurons. These results argue that the depolarization-activated somatodendritic K+ currents in cholinergic interneurons are dominated by Kv4.2- and Kv4. 1-containing channels. The properties of these channels are consistent with their playing a prominent role in governing the slow, repetitive discharge of interneurons seen in vivo.

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Spatial mismatch between the Na ⁺ flux and spike initiation in axon initial segment

Baranauskas

David

Fleidervish

2013

Proc. Natl. Acad. Sci. U.S.A.

105

163

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It is widely believed that, in cortical pyramidal cells, action potentials (APs) initiate in the distal portion of axon initial segment (AIS) because that is where Na + channel density is highest. To investigate the relationship between the density of Na + channels and the spatiotemporal pattern of AP initiation, we simultaneously recorded Na + flux and action currents along the proximal axonal length. We found that functional Na + channel density is approximately four times lower in the AP trigger zone than in the middle of the AIS, where it is highest. Computational analysis of AP initiation revealed a paradoxical mismatch between the AP threshold and Na + channel density, which could be explained by the lopsided capacitive load imposed on the proximal end of the AIS by the somatodendritic compartment. Favorable conditions for AP initiation are therefore achieved in the distal AIS portion, close to the edge of myelin, where the current source-load ratio is highest. Our findings suggest that cable properties play a central role in determining where the AP starts, such that small plastic changes in the local AIS Na + channel density could have a large influence on neuronal excitability as a whole.neocortex | pyramidal neuron | sodium imaging I n cortical pyramidal cells, as in many CNS neurons, action potentials (APs) generally initiate in the axon initial segment (AIS) (refs. 1-4; reviewed in ref. 5), the proximal part of the axon where the neuronal membrane is not covered with a myelin sheath, and which possesses a distinctive, specialized assembly of voltage-gated channels and associated proteins (6). Because of the pivotal role that the AIS plays in transformation of synaptic input into AP output, precise characterization of its excitable properties is essential for a complete understanding of the cellular mechanisms that underlie operation of cortical neurons and networks. Early theoretical studies proposed two mechanisms to explain preferential AIS AP initiation (7, 8): (i) less current is required to depolarize the AIS membrane to threshold because it is electrically isolated from the neighboring neuronal compartments, and (ii) the depolarizing current density is higher in the AIS than in neighboring compartments, allowing the AIS to overcome their electric load. These two mechanisms are not mutually exclusive, but the technical difficulties that hinder precise measurements in thin neuronal processes have made it difficult to elucidate their relative importance for AP initiation.During the past decade, the isolation hypothesis has been addressed by only a few studies (9), and values of the relevant resistances and capacitances are only approximations. By contrast, the findings by many groups that Na + channel density is relatively high in the proximal axon have focused most attention on the higher current hypothesis, although there remains some controversy as to what extent the density of functional Na + channels is greater in the AIS than in the soma (refs. 10-14; reviewed in ref. 15). The role of high ...

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Sensitization of Pain Pathways in the Spinal Cord: Cellular Mechanisms

Baranauskas

Nistri

1998

Progress in Neurobiology

276

141

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Kv4.2 mRNA Abundance and A-Type K⁺Current Amplitude Are Linearly Related in Basal Ganglia and Basal Forebrain Neurons

2000

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A-type K(+) currents are key determinants of repetitive activity and synaptic integration. Although several gene families have been shown to code for A-type channel subunits, recent studies have suggested that Kv4 family channels are the principal contributors to A-type channels in the somatodendritic membrane of mammalian brain neurons. If this hypothesis is correct, there should be a strong correlation between Kv4 family mRNA and A-type channel protein or aggregate channel currents. To test this hypothesis, quantitative single-cell reverse transcription-PCR analysis of Kv4 family mRNA was combined with voltage-clamp analysis of A-type K(+) currents in acutely isolated neurons. These studies revealed that Kv4.2 mRNA abundance was linearly related to A-type K(+) current amplitude in neostriatal medium spiny neurons and cholinergic interneurons, in globus pallidus neurons, and in basal forebrain cholinergic neurons. In contrast, there was not a significant correlation between estimates of Kv4.1 or Kv4.3 mRNA abundance and A-type K(+) current amplitudes. These results argue that Kv4.2 subunits are major constituents of somatodendritic A-type K(+) channels in these four types of neuron. In spite of this common structural feature, there were significant differences in the voltage dependence and kinetics of A-type currents in the cell types studied, suggesting that other determinants may create important functional differences between A-type K(+) currents.

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