花生四烯酸对钾离子通道的调节作用

花生四烯酸是一个重要的炎症介质,它可以对广泛存在于各种细胞膜表面的外离子通道进行直接的或间接的调节。花生四烯酸与通道的直接作用,改变了通道蛋白的构象;直接学可与通道周围的细胞膜作用,影响钾离子通道的功能。花生四烯酸还可以通过其环氧酶和脂氧酶的代谢产物、蛋白激酶Ｃ（ＰＫＣ）及「Ｃａ＾２＋」间接影响了子通道。这些环节为药理学研究提供了新的可能的靶点。     

Modulation of neuronal survival and excitability by an astroglia-derived factor.

We summarize here currently available data related to an astroglia-secreted factor that induces neuronal apoptosis and behaves as an inhibitor of ionotropic inhibitory GABA(A) and glycine receptors.     

Modulation of MthK potassium channel activity at the intracellular entrance to the pore

We used a bacterial complementation screen with the LB2003 K(+) uptake-deficient strain of Escherichia coli to analyze residues that are critical to Methanobacterium thermoautotrophicum potassium channel (MthK) function. Channel expression and relative structural integrity of mutants were analyzed by SDS-PAGE and Western blot, and mechanisms underlying altered mutant channel function were analyzed using single-channel recording. We observed that wild-type MthK expression complements K(+) uptake deficiency. Although MthK function was previously thought to require Ca(2+) in the millimolar range, we demonstrate that at elevated temperatures the requirement for Ca(2+) becomes much lower. Mutations at the cytoplasmic mouth of the MthK pore can blunt complementation, indicating that those mutant channels cannot support K(+) uptake. In contrast, substitutions at the Ca(2+)-binding site in the MthK RCK domain did not decrease complementation compared with wild-type MthK. We focused on mutations to residues Glu-92 and Glu-96, which may form the narrowest part of the pore in the channel's closed state. Mutations at these residues can yield slight changes in single-channel conductance that do not necessarily correlate with effects on bacterial complementation. However, mutations at Glu-92 could also change channel open probability, and these changes correlated with complementation effects. The most striking of these mutations was E92A, which nearly eliminated bacterial complementation by decreasing the open probability of MthK. Our results suggest that the small, hydrophobic alanine side chain at the K(+) channel bundle crossing may generate an intrinsically stable structure, which in turn shifts the closed-to-open-state equilibrium toward the closed state.     

Modulation of potassium channel gating by external divalent cations

We have examined the actions of Zn2+ ions on Shaker K channels. We found that low (100 microM) concentrations of Zn2+ produced a substantial (approximately three-fold) slowing of the kinetics of macroscopic activation and inactivation. Channel deactivation was much less affected. These results were obtained in the presence of 5 mM Mg2+ and 4 mM Ca2+ in the external solution and so are unlikely to be due to modification of membrane surface charges. Furthermore, the action of 100 microM Zn2+ on activation was equivalent to a 70-mV reduction of a negative surface potential whereas the effects on deactivation would require a 15-mV increase in surface potential. External H+ ions reduced the Zn-induced slowing of macroscopic activation with an apparent pK of 7.3. Treatment of Shaker K channels with the amino group reagent, trinitrobenzene sulfonic acid (TNBS), substantially reduced the effects of Zn2+. All these results are qualitatively similar to the actions of Zn2+ on squid K channels, indicating that the binding site may be a common motif in potassium channels. Studies of single Shaker channel properties showed that Zn2+ ions had little or no effect on the open channel current level or on the open channel lifetime. Rather, Zn2+ substantially delayed the time to first channel opening. Thus, K channels appear to contain a site to which divalent cations bind and in so doing act to slow one or more of the rate constants controlling transitions among closed conformational states of the channel.     

Changes in GIRK1/GIRK2 deactivation kinetics and basal activity in the presence and absence of RGS4

The effect of RGS4, a GTPase-activating protein, on the deactivation kinetics and basal activity of GIRK1/GIRK2 channels activated by the human kappa-opioid receptor (hKOR) was investigated. Co-expression in Xenopus oocytes of RGS4 reduces the basal GIRK1/GIRK2 current and strongly increases the percentage agonist-evoked K+ conductance. RGS4 reconstitutes the native gating kinetics by accelerating GIRK1/GIRK2 channel deactivation, a phenomenon also seen after activation with other 7 TM receptors (e.g. muscarine type). In the absence of RGS4, the GIRK1/GIRK2 conductance was increased by approx. 50% after hKOR stimulation with the kappa-selective opioid receptor ligand, U69593; however more importantly, at the end of the washout period it was dramatically reduced to about 60% of the basal conductance as measured before receptor stimulation. Furthermore, we found that repeated receptor stimulation causes an increase of the agonist-gated deactivation kinetics, without affecting the maximal and minimal conductance levels of GIRK1/GIRK2 channels during and after agonist application. Unlike in the absence of RGS4, coexpression with RGS4 completely abolished the reduction of basal conductance after agonist washout and the deactivation kinetics remained unaffected upon repeated agonist application. The results presented here clearly indicate that previous stimulation by agonists activating G protein-coupled receptors may have long-lasting, strong consequences on the following responses. Therefore, our study provides evidence for a novel modulation of deactivation kinetics of GIRK1/GIRK2 currents in the absence of RGS4.     

Modulation of the Kir7.1 potassium channel by extracellular and intracellular pH

Inwardly rectifying K(+) (K(ir)) channels in the apical membrane of the retinal pigment epithelium (RPE) contribute to extracellular K(+) homeostasis in the distal retina by mediating K(+) secretion. Multiple lines of evidence suggest that these channels are composed of Kir7.1. Previously, we showed that native K(ir) channels in bovine RPE are modulated by changes in intracellular pH in the physiological range. In the present study, we used the Xenopus laevis oocyte expression system to investigate the pH dependence of cloned human Kir7.1 channels and several point mutants involving histidine residues in the NH(2) and COOH termini. Kir7.1 channels were inhibited by strong extracellular acidification and modulated by intracellular pH in a biphasic manner, with maximal activity at about intracellular pH (pH(i)) 7.0 and inhibition by acidification or alkalinization. Replacement of histidine 26 (H26) in the NH(2) terminus with alanine eliminated the requirement of protons for channel activity and increased sensitivity to proton-induced inhibition, resulting in maximal channel activity at alkaline pH(i) and smaller whole cell currents at resting pH(i) compared with wild-type Kir7.1. When H26 was replaced with arginine, the pH(i) sensitivity profile was similar to that of the H26A mutant but with the pK(a) shifted to a more acidic value, giving rise to whole cell current amplitude at resting pH(i) that was comparable to that of wild-type Kir7.1. These results indicate that Kir7.1 channels are modulated by intracellular protons by diverse mechanisms and suggest that H26 is important for channel activation at physiological pH(i) and that it influences an unidentified proton-induced inhibitory mechanism.     

Modulation of neuronal excitability by intracellular calcium buffering: from spiking to bursting

We have investigated the detailed regulation of neuronal firing pattern by the cytosolic calcium buffering capacity using a combination of mathematical modeling and patch-clamp recording in acute slice. Theoretical results show that a high calcium buffer concentration alters the characteristic regular firing of cerebellar granule cells and that a transition to various modes of oscillations occurs, including bursting. Using bifurcation analysis, we show that this transition from spiking to bursting is a consequence of the major slowdown of calcium dynamics. Patch-clamp recordings on cerebellar granule cells loaded with a high concentration of the fast calcium buffer BAPTA (15 mM) reveal dramatic alterations in their excitability as compared to cells loaded with 0.15 mM BAPTA. In high calcium buffering conditions, granule cells exhibit all bursting behaviors predicted by the model whereas bursting is never observed in low buffering. These results suggest that cytosolic calcium buffering capacity can tightly modulate neuronal firing patterns leading to generation of complex patterns and therefore that calcium-binding proteins may play a critical role in the non-synaptic plasticity and information processing in the central nervous system.     

Modulation of the mitochondrial large-conductance calcium-regulated potassium channel by polyunsaturated fatty acids

Polyunsaturated fatty acids (PUFAs) and their metabolites can modulate several biochemical processes in the cell and thus prevent various diseases. PUFAs have a number of cellular targets, including membrane proteins. They can interact with plasma membrane and intracellular potassium channels. The goal of this work was to verify the interaction between PUFAs and the most common and intensively studied mitochondrial large conductance Ca²⁺-regulated potassium channel (mitoBK_Ca). For this purpose human astrocytoma U87 MG cell lines were investigated using a patch-clamp technique. We analyzed the effects of arachidonic acid (AA); eicosatetraynoic acid (ETYA), which is a non-metabolizable analog of AA; docosahexaenoic acid (DHA); and eicosapentaenoic acid (EPA). The open probability (P_o) of the channel did not change significantly after application of 10 μM ETYA. P_o increased, however, after adding 10 μM AA. The application of 30 μM DHA or 10 μM EPA also increased the P_o of the channel. Additionally, the number of open channels in the patch increased in the presence of 30 μM EPA. Collectively, our results indicate that PUFAs regulate the BK_Ca channel from the inner mitochondrial membrane.     

Analysis of potassium channel functions in mammalian axons by gene knockouts

Mammalian axons express a rich repertoire of various K channel subtypes whose distribution is profoundly affected by myelination. In the past two decades, functional analysis of axonal K channels has been approached primarily through pharmacology. Recently, gene knockout techniques have been used to specifically delete a particular K channel subtype from axons. This is significant since the bulk of K channels in a myelinated nerve are covered by the myelin, making functional analysis of specific K channel subtypes by traditional means difficult. This review summarizes the first mutational analysis of this sort performed on an axonal fast K channel termed Kv1.1. This K channel is concealed by the myelin loops in the paranodes of all major myelinated fiber tracts, and exhibits highly heterogeneous distribution even in certain non-myelinated CNS axons. Physiological analysis of Kv1.1 null mutants suggest novel functions for this axonal K channel subtype, including modulation of conduction failures at branch points and stabilization of transition zones in myelinated nerves.     

Modulation of Kv1.5 potassium channel gating by extracellular zinc.

Zinc ions are known to induce a variable depolarizing shift of the ionic current half-activation potential and substantially slow the activation kinetics of most K(+) channels. In Kv1.5, Zn(2+) also reduces ionic current, and this is relieved by increasing the external K(+) or Cs(+) concentration. Here we have investigated the actions of Zn(2+) on the gating currents of Kv1.5 channels expressed in HEK cells. Zn(2+) shifted the midpoint of the charge-voltage (Q-V) curve substantially more (approximately 2 times) than it shifted the V(1/2) of the g-V curve, and this amounted to +60 mV at 1 mM Zn(2+). Both Q1 and Q2 activation charge components were similarly affected by Zn(2+), which indicated free access of Zn(2+) to channel closed states. The maximal charge movement was also reduced by 1 mM Zn(2+) by approximately 15%, from 1.6 +/- 0.5 to 1.4 +/- 0.47 pC (n = 4). Addition of external K(+) or Cs(+), which relieved the Zn(2+)-induced ionic current reduction, decreased the extent of the Zn(2+)-induced Q-V shift. In 135 mM extracellular Cs(+), 200 microM Zn(2+) reduced ionic current by only 8 +/- 1%, compared with 71% reduction in 0 mM extracellular Cs(+), and caused a comparable shift in both the g-V and Q-V relations (17.9 +/- 0.6 mV vs. 20.8 +/- 2.1 mV, n = 6). Our results confirm the presence of two independent binding sites involved in the Zn(2+) actions. Whereas binding to one site accounts for reduction of current and binding to the other site accounts for the gating shift in ionic current recordings, both sites contribute to the Zn(2+)-induced Q-V shift.     

Regulation of a mammalian Shaker-related potassium channel, hKv1.5, by extracellular potassium and pH

Using the whole-cell recording mode of the patch-clamp technique we studied the effects of removal of extracellular potassium, [K(+)](o), on a mammalian Shaker-related K(+) channel, hKv1.5. In the absence of [K(+)](o), current through hKv1.5 was similar to currents obtained in the presence of 4.5 mM [K(+)](o). This observation was not expected as earlier results had suggested that either positively charged residues or the presence of a nitrogen-containing residue at the external TEA(+) binding site (R487 in hKv1.5) caused current loss upon removal of [K(+)](o). However, the current loss in hKv1.5 was observed when the extracellular pH, pH(o), was reduced from 7.4 to 6.0, a behavior similar to that observed previously for current through mKv1.3 with a histidine at the equivalent position (H404). These observations suggested that the charge at R487 in hKv1.5 channels was influenced by other amino acids in the vicinity. Replacement of a histidine at position 463 in hKv1.5 by glycine confirmed this hypothesis making this H463G mutant channel sensitive to removal of [K(+)](o) even at pH(o) 7.4. We conclude that the protonation of H463 at pH 7.4 might induce a pK(a) shift of R487 that influences the effective charge at this position leading to a not fully protonated arginine. Furthermore, we assume that the charge at position 487 in hKv1.5 can directly or indirectly disturb the occupation of a K(+) binding site within the channel pore possibly by electrostatic interaction. This in turn might interfere with the concerted transition of K(+) ions resulting in a loss of K(+) conduction.     

Cell-type specific depression of neuronal excitability in rat hippocampus by activation of ATP-sensitive potassium channels

The contribution of ATP-sensitive potassium (K(ATP)) channels to neuronal excitability was studied in different types of pyramidal cells and interneurones in hippocampal slices prepared from 9- to 15-day-old rats. The presence of functional K(ATP) channels in the neurones was detected through the sensitivity of whole-cell currents to diazoxide, a K(ATP) channel opener, and to tolbutamide, a K(ATP) channel inhibitor. The percentages of neurones with K(ATP) channels increase in the sequence: CA1 pyramidal cells (37%)相似文献   

Regulation of intrinsic excitability in hippocampal neurons by activity-dependent modulation of the KV2.1 potassium channel

K_V2.1 is the prominent somatodendritic sustained or delayed rectifier voltage-gated potassium (Kv) channel in mammalian central neurons, and is a target for activity-dependent modulation via calcineurin-dependent dephosphorylation. Using hanatoxin-mediated block of K_V2.1 we show that, in cultured rat hippocampal neurons, glutamate stimulation leads to significant hyperpolarizing shifts in the voltage-dependent activation and inactivation gating properties of the K_V2.1-component of delayed rectifier K⁺ (IK) currents. In computer models of hippocampal neurons, these glutamate-stimulated shifts in the gating of the K_V2.1-component of IK lead to a dramatic suppression of action potential firing frequency. Current-clamp experiments in cultured rat hippocampal neurons showed glutamate-stimulation induced a similar suppression of neuronal firing frequency. Membrane depolarization also resulted in similar hyperpolarizing shifts in the voltage-dependent gating properties of neuronal IK currents, and suppression of neuronal firing. The glutamate-induced effects on neuronal firing were eliminated by hanatoxin, but not by dendrotoxin-K, a blocker of K_V1.1-containing channels. These studies together demonstrate a specific contribution of modulation of K_V2.1 channels in the activity-dependent regulation of intrinsic neuronal excitability.     

Critical determinants of the G protein gamma subunits in the Gbetagamma stimulation of G protein-activated inwardly rectifying potassium (GIRK) channel activity

The betagamma subunits of G proteins modulate inwardly rectifying potassium (GIRK) channels through direct interactions. Although GIRK currents are stimulated by mammalian Gbetagamma subunits, we show that they were inhibited by the yeast Gbetagamma (Ste4/Ste18) subunits. A chimera between the yeast and the mammalian Gbeta1 subunits (ymbeta) stimulated or inhibited GIRK currents, depending on whether it was co-expressed with mammalian or yeast Ggamma subunits, respectively. This result underscores the critical functional influence of the Ggamma subunits on the effectiveness of the Gbetagamma complex. A series of chimeras between Ggamma2 and the yeast Ggamma revealed that the C-terminal half of the Ggamma2 subunit is required for channel activation by the Gbetagamma complex. Point mutations of Ggamma2 to the corresponding yeast Ggamma residues identified several amino acids that reduced significantly the ability of Gbetagamma to stimulate channel activity, an effect that was not due to improper association with Gbeta. Most of the identified critical Ggamma residues clustered together, forming an intricate network of interactions with the Gbeta subunit, defining an interaction surface of the Gbetagamma complex with GIRK channels. These results show for the first time a functional role for Ggamma in the effector role of Gbetagamma.     

SK2 channel regulation of neuronal excitability,synaptic transmission,and brain rhythmic activity in health and diseases

Small conductance calcium-activated potassium channels (SKs) are solely activated by intracellular Ca²⁺ and their activation leads to potassium efflux, thereby repolarizing/hyperpolarizing membrane potential. Thus, these channels play a critical role in synaptic transmission, and consequently in information transmission along the neuronal circuits expressing them. SKs are widely but not homogeneously distributed in the central nervous system (CNS). Activation of SKs requires submicromolar cytoplasmic Ca²⁺ concentrations, which are reached following either Ca²⁺ release from intracellular Ca²⁺ stores or influx through Ca²⁺ permeable membrane channels. Both Ca²⁺ sensitivity and synaptic levels of SKs are regulated by protein kinases and phosphatases, and degradation pathways. SKs in turn control the activity of multiple Ca²⁺ channels. They are therefore critically involved in coordinating diverse Ca²⁺ signaling pathways and controlling Ca²⁺ signal amplitude and duration. This review highlights recent advances in our understanding of the regulation of SK2 channels and of their roles in normal brain functions, including synaptic plasticity, learning and memory, and rhythmic activities. It will also discuss how alterations in their expression and regulation might contribute to various brain disorders such as Angelman Syndrome, Alzheimer's disease and Parkinson's disease.     

Inhibition of a Gi-activated potassium channel (GIRK1/4) by the Gq-coupled m1 muscarinic acetylcholine receptor

The G protein-coupled inwardly rectifying K+ channel, GIRK1/GIRK4, can be activated by receptors coupled to the Galpha(i) subunit. An opposing role for Galpha(q) receptor signaling in GIRK regulation has only recently begun to be established. We have studied the effects of m1 muscarinic acetylcholine receptor (mAChR) stimulation, which is known to mobilize calcium and activate protein kinase C (PKC) by a Galpha(q)-dependent mechanism, on whole cell GIRK1/4 currents in Xenopus oocytes. We found that stimulation of the m1 mAChR suppresses both basal and dopamine 2 receptor-activated GIRK 1/4 currents. Overexpression of Gbetagamma subunits attenuates this effect, suggesting that increased binding of Gbetagamma to the GIRK channel can effectively compete with the G(q)-mediated inhibitory signal. This G(q) signal requires the use of second messenger molecules; pharmacology implicates a role for PKC and Ca2+ responses as m1 mAChR-mediated inhibition of GIRK channels is mimicked by PMA and Ca2+ ionophore. We have analyzed a series of mutant and chimeric channels suggesting that the GIRK4 subunit is capable of responding to G(q) signals and that the resulting current inhibition does not occur via phosphorylation of a canonical PKC site on the channel itself.     

Modulation of caffeine contractures in mammalian skeletal muscles by variation of extracellular potassium

Caffeine contractures were induced after K⁺ -conditioning of skeletal muscles from pigs and mice. K⁺ -conditioning is defined as the partial depolarization caused by increasing external potassium (K) with [K⁺]×[Cl^?] constant. Conditioning depolarizations that rendered muscles refractory to brief electrical stimulation still enhanced the contracture tension elicited by subsequent direct caffeine stimulation of sarcoplasmic reticulum (SR) calcium release. The effects of K⁺ -conditioning on caffeine-induced contractures of intact cell bundles reached a maximum at 15–30 mM K and then progressively declined at higher [K⁺]₀. Conditioning with 30 mM K⁺ for 5 min, which inactivates excitation-contraction (EC) coupling in response to action potentials, both increased the magnitude of caffeine contractures 2–10-fold and shifted the contracture threshold toward lower caffeine concentrations. Enhanced sensitivity to caffeine was inhibited by dantrolene (20 μM) and its watersoluble analogue azumolene (150 μM). These drugs decreased caffeine-induced contractures following depolarization with 4–15 mM K⁺ to 25–50% of control tension. The inorganic anion perchlorate (CIO), which like caffeine potentiates twitches, increased caffeine-induced contractures ～? twofold after K⁺ -conditioning (>4 mM). The results suggest that CIO and dantrolene, in addition to caffeine, also influence SR calcium release either directly or by mechanism(s) subsequent to depolarization of the sarcolemma. Moreover, since CIO is known to shift the voltage-dependence of intramembrane charge movement, CIO may exert effects on the transverse-tubule voltage sensors as well as the SR. © 1995 Wiley-Liss, Inc.     

Crystal structure of the mammalian GIRK2 K+ channel and gating regulation by G proteins, PIP2, and sodium

G protein-gated K(+) channels (Kir3.1-Kir3.4) control electrical excitability in many different cells. Among their functions relevant to human physiology and disease, they regulate the heart rate and govern a wide range of neuronal activities. Here, we present the first crystal structures of a G protein-gated K(+) channel. By comparing the wild-type structure to that of a constitutively active mutant, we identify a global conformational change through which G proteins could open a G loop gate in the cytoplasmic domain. The structures of both channels in the absence and presence of PIP(2) suggest that G proteins open only the G loop gate in the absence of PIP(2), but in the presence of PIP(2) the G loop gate and a second inner helix gate become coupled, so that both gates open. We also identify a strategically located Na(+) ion-binding site, which would allow intracellular Na(+) to modulate GIRK channel activity. These data provide a structural basis for understanding multiligand regulation of GIRK channel gating.