Arachidonic acid-sensitive A-currents and multiple Kv4 transcripts are expressed in chick ciliary ganglion neurons

Homeostatic Recovery of Embryonic Spinal Activity Initiated by Compensatory Changes in Resting Membrane Potential

When baseline activity in a neuronal network is modified by external challenges, a set of mechanisms is prompted to homeostatically restore activity levels. These homeostatic mechanisms are thought to be profoundly important in the maturation of the network. It has been shown that blockade of either excitatory GABAergic or glutamatergic transmission in the living chick embryo transiently blocks the movements generated by spontaneous network activity (SNA) in the spinal cord. However, the embryonic movements then begin to recover by 2 h and are completely restored by 12 h of persistent receptor blockade. It remains unclear what mechanisms mediate this early recovery (first hours) after neurotransmitter blockade, or even if the same mechanisms are triggered following GABAergic and glutamatergic antagonists. Here we find two distinct mechanisms that could underlie this homeostatic recovery. First, we see a highly robust compensatory mechanism observed shortly after neurotransmitter receptor blockade. In the first 2 h of GABAergic or glutamatergic blockade in vitro, there was a clear depolarization of resting membrane potential (RMP) in both motoneurons and interneurons. These changes reduced threshold current and were observed in the continued presence of the antagonist. Therefore, it appears that fast changes in RMP represent a key fast homeostatic mechanism for the maintenance of network activity. Second, we see a less consistent compensatory change in the absolute threshold voltage in the first several hours of in vitro and in vivo neurotransmitter blockade. These mechanisms likely contribute to the homeostatic recovery of embryonic movements following neurotransmitter blockade.

Actions and Mechanisms of Polyunsaturated Fatty Acids on Voltage-Gated Ion Channels

Polyunsaturated fatty acids (PUFAs) act on most ion channels, thereby having significant physiological and pharmacological effects. In this review we summarize data from numerous PUFAs on voltage-gated ion channels containing one or several voltage-sensor domains, such as voltage-gated sodium (Na_V), potassium (K_V), calcium (Ca_V), and proton (H_V) channels, as well as calcium-activated potassium (K_Ca), and transient receptor potential (TRP) channels. Some effects of fatty acids appear to be channel specific, whereas others seem to be more general. Common features for the fatty acids to act on the ion channels are at least two double bonds in cis geometry and a charged carboxyl group. In total we identify and label five different sites for the PUFAs. PUFA site 1: The intracellular cavity. Binding of PUFA reduces the current, sometimes as a time-dependent block, inducing an apparent inactivation. PUFA site 2: The extracellular entrance to the pore. Binding leads to a block of the channel. PUFA site 3: The intracellular gate. Binding to this site can bend the gate open and increase the current. PUFA site 4: The interface between the extracellular leaflet of the lipid bilayer and the voltage-sensor domain. Binding to this site leads to an opening of the channel via an electrostatic attraction between the negatively charged PUFA and the positively charged voltage sensor. PUFA site 5: The interface between the extracellular leaflet of the lipid bilayer and the pore domain. Binding to this site affects slow inactivation. This mapping of functional PUFA sites can form the basis for physiological and pharmacological modifications of voltage-gated ion channels.

Inhibitory effects of polyunsaturated fatty acids on Kv4/KChIP potassium channels

Kv4/K channel interacting protein (KChIP) potassium channels are a major class of rapidly inactivating K(+) channels in neurons and cardiac muscle. Modulation of Kv4/KChIP channels by polyunsaturated fatty acids (PUFAs) is important in the regulation of cellular excitability and the induction of activity-dependent synaptic plasticity. Using the Xenopus laevis oocyte expression system, we studied the inhibition by PUFAs of the peak outward K(+) current and the accompanying increase in the rate of current inactivation of rKv4.2/rKChIP1b. Inhibitory effects do not depend on KChIP coexpression since Kv4.2 channels lacking an NH(2)-terminal KChIP association region were substantially inhibited by PUFAs and showed strong kinetic modulation. PUFAs accelerated both the fast and slow time constants that describe the kinetics of Kv4/KChIP inactivation. The time course of entry into closed inactivated states was facilitated by PUFAs, but steady-state inactivation and recovery from inactivation were unaltered. PUFA inhibition of Kv4/KChIP current was not use dependent. The concentration-response relationship for arachidonic acid (AA) inhibition of Kv4/KChIP channels mimicked that for activation of TRAAK channels. Internal serum albumin largely prevents the inhibitory effects of externally applied AA, and the membrane-impermeant AA-CoA is inactive when applied externally. Overall, our data suggest that PUFAs inhibit Kv4/KChIP channels by facilitating inactivation from open and closed gating states and that access of the fatty acid to the internal leaflet of the membrane is important. These results improve our understanding of the mechanisms for the inhibitory effects of PUFAs on Kv4/KChIP channel function.

Polyunsaturated fatty acid modulation of voltage-gated ion channels

Arachidonic acid (AA) was found to inhibit the function of whole-cell voltage-gated (VG) calcium currents nearly 16 years ago. There are now numerous examples demonstrating that AA and other polyunsaturated fatty acids (PUFAs) modulate the function of VG ion channels, primarily in neurons and muscle cells. We will review and extract some common features about the modulation by PUFAs of VG calcium, sodium, and potassium channels and discuss the impact of this modulation on the excitability of neurons and cardiac myocytes. We will describe the fatty acid nature of the membrane, how fatty acids become available to function as modulators of VG channels, and the physiologic importance of this type of modulation. We will review the evidence for molecular mechanisms and assess our current understanding of the structural basis for modulation. With guidance from research on the structure of fatty acid binding proteins, the role of lipids in gating mechanosensitive (MS) channels, and the impact of membrane lipid composition on membrane-embedded proteins, we will highlight some avenues for future investigations.

Molecular physiology and modulation of somatodendritic A-type potassium channels

The somatodendritic subthreshold A-type K+ current (ISA) in nerve cells is a critical component of the ensemble of voltage-gated ionic currents that determine somatodendritic signal integration. The underlying K+ channel belongs to the Shal subfamily of voltage-gated K+ channels. Most Shal channels across the animal kingdom share a high degree of structural conservation, operate in the subthreshold range of membrane potentials, and exhibit relatively fast inactivation and recovery from inactivation. Mammalian Shal K+ channels (Kv4) undergo preferential closed-state inactivation with features that are generally inconsistent with the classical mechanisms of inactivation typical of Shaker K+ channels. Here, we review (1) the physiological and genetic properties of ISA, 2 the molecular mechanisms of Kv4 inactivation and its remodeling by a family of soluble calcium-binding proteins (KChIPs) and a membrane-bound dipeptidase-like protein (DPPX), and (3) the modulation of Kv4 channels by protein phosphorylation.

A-current expression is regulated by activity but not by target tissues in developing lumbar motoneurons of the chick embryo

The functional expression of A-type K+ channels (IA) was examined in chick lumbar motoneurons (LMNs) at embryonic days 6 and 11 (E6 and E11). We observed a threefold increase in IA density between E6 and E11 in spinal cord slices and acutely dissociated LMNs. There was no change in current density, kinetics, or voltage dependence of IA in E11 homozygous limbless mutants or in E11 embryos in which hindlimbs were surgically removed at E6. Moreover, chronic in ovo administration of D-tubocurarine, which causes an increase in motoneuron branching on the surface of target muscles, had no effect on IA. Electrical activity played an important role in IA regulation in LMNs in vitro and in ovo. Blocking spontaneous electrical activity of LMNs by chronic in ovo application of mecamylamine or muscimol reduced IA by 80%. LMNs cultured in the presence of TTX also failed to express normal densities of IA, even when the cultures also contained target tissues. The portion of IA that remained after in ovo or in vitro blockade of activity inactivated more quickly than the IA of LMNs that were allowed to discharge spikes. The developmental expression of LMN IA increases significantly during development, and this increase is activity dependent but does not require interactions with target tissues. Ongoing activity also seems to regulate the kinetics of IA inactivation.

Eicosatetraynoic acid (ETYA), a non-metabolizable analogue of arachidonic acid, blocks the fast-inactivating potassium current of rat pituitary melanotrophs

The effects of arachidonic acid (5,8,11,14-eicosatetraenoic acid, AA) and 5,8,11,14-eicosatetraynoic acid (ETYA), a non-metabolizable analogue of AA, were examined on the transient [IK(f)] and the delayed rectifier-like [IK(s)] voltage-gated potassium currents in rat pituitary melanotrophs. The main questions addressed were whether AA and ETYA blocked IK(f) and if any blocking action was specific. Macroscopic currents were measured using the patch clamp technique. Bath application of 20 µM AA reduced IK(f), however, the degree of the block varied between cells. In contrast, ETYA consistently inhibited IK(f). Fitting of the charge transfer or the peak current amplitude yielded KD estimates for ETYA of 1.2 µM and 3.3 µM, respectively. The reduction by ETYA of peak IK(f) was always associated with an increased rate of current decay, but there was no detectable change of the kinetics of activation. ETYA caused a small left shift of the IK(f) steady-state inactivation curve and significantly slowed recovery from inactivation. At 20 µM, ETYA also reduced IK(s), indicating that it is not specific. The possibility that ETYA acts as an open-channel blocker is discussed.Key words: transient potassium current, melanotroph, eicosatetraynoic acid, ETYA, arachidonic acid.

Cytosolic phospholipase A2 and the distinct transcriptional programs of astrocytoma cells

Astrocytes constitute the most abundant cell type in the nervous system. Under physiological conditions, they respond to the stimuli to which neurons are also responsive. The use of astrocytoma cell lines with well-defined morphological and functional markers has been helpful for addressing the mechanisms of signal transduction that operate in the nervous system. On the basis of the effects produced by agonists of different types of receptor (muscarinic ACh receptors, thrombin receptors, phospholipases A2 receptors and tumor necrosis factor alpha receptors), several different transcriptional programs that involve the MAP kinase-cytosolic phospholipase A2 system and the transcription factor NF-kappaB have been described.

Fatty acid-activated K+ channels in autonomic neurons: activation by an endogenous source of free fatty acids

Application of arachidonic acid evoked robust activation of large-conductance K+ channels in cell-attached and excised inside-out patches from acutely isolated chick ciliary ganglion neurons. A similar effect was produced by 5,8,11,14-eicosatetraynoic acid, a nonmetabolizable analogue of arachidonic acid. The unitary conductance of fatty acid-activated channels was 35-40 pS at +20 mV with physiological gradients of K+ and 165 pS at +20 mV with an extracellular K+ concentration of 37.5 mM and an intracellular K+ concentration of 150 mM. Gating of these channels in cell-attached patches was potentiated by membrane stretch. Channel gating evoked by both lipids was concentration-dependent, with detectable activation apparent at 4 microM in the majority of patches and maximal activation occurring between 32 and 64 microM. Gating was relatively voltage-independent. Large-conductance K+ channels were also activated in inside-out patches by the monounsaturated fatty acid 11-cis-eicosenoic acid but not by the fully saturated fatty acid arachidic acid. Application of 100 microM H2O2, an agent that activates cytosolic phospholipase A2, also caused activation of large-conductance K+ channels in intact neurons. The stimulatory effects of H2O2 were blocked by pretreatment with 20 microM 4-bromophenacyl bromide, an irreversible inhibitor of phospholipase A2. Therefore, mobilization of endogenous fatty acids can cause activation of large-conductance K+ channels in autonomic neurons.

Kv4.2 mRNA abundance and A-type K(+) current amplitude are linearly related in basal ganglia and basal forebrain neurons

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.

Arachidonic acid reciprocally alters the availability of transient and sustained dendritic K(+) channels in hippocampal CA1 pyramidal neurons

The dendrites of hippocampal CA1 pyramidal cell dendrites express a high density of transient A-type K(+) channels, which play a critical role in the back-propagation of action potentials and in the determination of dendritic excitability. Recently, arachidonic acid and its nonmetabolizable analogue 5,8,11,14-eicosatetraynoic acid (ETYA) were shown to block transient K(+) channels in the somata of these cells (), but to have little effect on the somatic action potential. In the present study we have investigated the effects of arachidonic acid and ETYA on the gating of channels and the excitability of the apical dendrites of CA1 pyramidal neurons. We found not only a block of transient K(+) channels, but also an enhancement of sustained outward currents. The sustained currents consisted of at least two distinct channel types. The larger conductance channel (>50 pS) was identified as a K(+) channel. Arachidonic acid greatly enhanced the amplitude of back-propagating dendritic action potentials (>200 micrometer from the soma) but did not result in sustained depolarizations of the dendrites similar to those seen with 4-aminopyridine (4-AP) application. In fact, arachidonic acid reduced dendritic excitability when applied after 4-AP. Thus, arachidonic acid appears to cause a shift of available channels from the fast, transient type to the slower, sustained types. The net effect appears to be an enhancement of dendritic action potential amplitude that occurs without compromising the electrical stability of the dendrites.