Structural Diversity in the Cytoplasmic Region of G Protein-Gated Inward Rectifier K+ Channels

Inward rectifier K+ (Kir) channels can be functionally categorized into two groups: those that are constitutively active and those that are constitutively inactive, with examples such as Kir2.x and Kir3.x, respectively. Their cytoplasmic regions are thought to be critical for control of channel gating, but a structural basis for this hypothesis is not known. In this study, we report a structure for the cytoplasmic region of a G protein-gated Kir channel, Kir3.2, and compare it with those of Kir3.1 and Kir2.1 channels. The isolated cytoplasmic region of Kir3.2 forms a tetrameric assembly in solution and also in the crystal. While the secondary structure arrangement and the subunit interface of the Kir3.2 crystal structure are found to be nearly identical to those of Kir3.1 and Kir2.1, it is quite different at and around loops between βC- and βD-strands and between βH- and βI-strands. These structural elements are located at the interface with the plasma membrane. Therefore, these structural elements could associate with the Kir channel transmembrane helices and be involved in the regulation of Kir channel gating.     

Conformational Changes Underlying Pore Dilation in the Cytoplasmic Domain of Mammalian Inward Rectifier K+ Channels

The cytoplasmic domain of inward rectifier K⁺ (Kir) channels associates with cytoplasmic ligands and undergoes conformational change to control the gate present in its transmembrane domain. Ligand-operated activation appears to cause dilation of the pore at the cytoplasmic domain. However, it is still unclear how the cytoplasmic domain supports pore dilation and how alterations to this domain affect channel activity. In the present study, we focused on 2 spatially adjacent residues, i.e., Glu236 and Met313, of the G protein-gated Kir channel subunit Kir3.2. In the closed state, these pore-facing residues are present on adjacent βD and βH strands, respectively. We mutated both residues, expressed them with the m₂-muscarinic receptor in Xenopus oocytes, and measured the acetylcholine-dependent K⁺ currents. The dose-response curves of the Glu236 mutants tended to be shifted to the right. In comparison, the slopes of the concentration-dependent curves were reduced and the single-channel properties were altered in the Met313 mutants. The introduction of arginine at position 236 conferred constitutive activity and caused a leftward shift in the conductance-voltage relationship. The crystal structure of the cytoplasmic domain of the mutant showed that the arginine contacts the main chains of the βH and βI strands of the adjacent subunit. Because the βH strand forms a β sheet with the βI and βD strands, the immobilization of the pore-forming β sheet appears to confer unique properties to the mutant. These results suggest that the G protein association triggers pore dilation at the cytoplasmic domain in functional channels, and the pore-constituting structural elements contribute differently to these conformational changes.     

平滑肌内向整流钾通道(K_(IR))

平滑肌内向整流钾通道在维持和调节细胞膜电位中发挥重要作用,并可能成为新的治疗靶点.综述了其分子学基础、电生理特性、生理功能和调控机理等研究进展.     

Moving the pH Gate of the Kir1.1 Inward Rectifier Channel

Both structural and functional studies suggest that pH gating of the inward rectifier potassium (K) channel, Kir1.1 (ROMK), is mediated by the convergence of 4 hydrophobic leucines (one from each subunit) near the cytoplasmic bundle-crossing of the inner transmembrane helices. We tested this hypothesis by moving the putative leucine gate from the L160-Kir1.1b to other positions along the inner transmembrane helix, and measuring inward current and conductance as functions of internal pH, using the Xenopus oocyte heterologous expression system. Results of these studies indicated that it was possible to replace the putative inward rectifier pH gate at L160-Kir1.1b by either a leucine or methionine at 157-Kir1.1b (G157L-L160G or G157M-L160G). Although both leucine and methionine gated the channel at 157-Kir1.1b, residues of similar hydrophobicity (tyrosine and valine) did not. Hence, hydrophobicity was a necessary but not a sufficient condition for steric gating at 157. This was in contrast to the 160-Kir1.1b locus, where side-chain hydrophobicity was both a necessary and sufficient property for steric gating. Homology models were constructed for all mutants that expressed significant whole-cell currents, using the closed-state coordinates of the prokaryotic inward rectifier, KirBac1.1. Models of mutants that retained pH gating were too narrow at the bundle crossing to permit hydrated K ion permeation in the closed-state. On the other hand, mutants that lost pH gating had ample space at the bundle crossing for hydrated K permeation in the closed-state. These results support our hypothesis that hydrophobic leucines at the cytoplasmic end of the inner transmembrane helices comprise the principal pH gate of Kir1.1, a gate that can be relocated from 160-Kir1.1b to 157-Kir1.1b.     

High-throughput Screening for Small-molecule Modulators of Inward Rectifier Potassium Channels

Specific members of the inward rectifier potassium (Kir) channel family are postulated drug targets for a variety of disorders, including hypertension, atrial fibrillation, and pain^1,2. For the most part, however, progress toward understanding their therapeutic potential or even basic physiological functions has been slowed by the lack of good pharmacological tools. Indeed, the molecular pharmacology of the inward rectifier family has lagged far behind that of the S4 superfamily of voltage-gated potassium (Kv) channels, for which a number of nanomolar-affinity and highly selective peptide toxin modulators have been discovered³. The bee venom toxin tertiapin and its derivatives are potent inhibitors of Kir1.1 and Kir3 channels^4,5, but peptides are of limited use therapeutically as well as experimentally due to their antigenic properties and poor bioavailability, metabolic stability and tissue penetrance. The development of potent and selective small-molecule probes with improved pharmacological properties will be a key to fully understanding the physiology and therapeutic potential of Kir channels.The Molecular Libraries Probes Production Center Network (MLPCN) supported by the National Institutes of Health (NIH) Common Fund has created opportunities for academic scientists to initiate probe discovery campaigns for molecular targets and signaling pathways in need of better pharmacology⁶. The MLPCN provides researchers access to industry-scale screening centers and medicinal chemistry and informatics support to develop small-molecule probes to elucidate the function of genes and gene networks. The critical step in gaining entry to the MLPCN is the development of a robust target- or pathway-specific assay that is amenable for high-throughput screening (HTS).Here, we describe how to develop a fluorescence-based thallium (Tl⁺) flux assay of Kir channel function for high-throughput compound screening^7,8,9,10.The assay is based on the permeability of the K⁺ channel pore to the K⁺ congener Tl⁺. A commercially available fluorescent Tl⁺ reporter dye is used to detect transmembrane flux of Tl⁺ through the pore. There are at least three commercially available dyes that are suitable for Tl⁺ flux assays: BTC, FluoZin-2, and FluxOR^7,8. This protocol describes assay development using FluoZin-2. Although originally developed and marketed as a zinc indicator, FluoZin-2 exhibits a robust and dose-dependent increase in fluorescence emission upon Tl⁺ binding. We began working with FluoZin-2 before FluxOR was available^7,8 and have continued to do so^9,10. However, the steps in assay development are essentially identical for all three dyes, and users should determine which dye is most appropriate for their specific needs. We also discuss the assay''s performance benchmarks that must be reached to be considered for entry to the MLPCN. Since Tl⁺ readily permeates most K⁺ channels, the assay should be adaptable to most K⁺ channel targets.     

Kir2.1 Interactome Mapping Uncovers PKP4 as a Modulator of the Kir2.1-Regulated Inward Rectifier Potassium Currents

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Highlights

• •Generation using BioID of a map of the Kir2.1 interactome with 218 interactions.
• •Identification of Kir2.1^WT- versus Kir2.1^Δ314-315-preferred interactors.
• •Identification of the desmosome protein PKP4 as a new modulator of I_Kir2.1 currents.

     

Charges in the Cytoplasmic Pore Control Intrinsic Inward Rectification and Single-Channel Properties in Kir1.1 and Kir2.1 Channels

An E224G mutation of the Kir2.1 channel generates intrinsic inward rectification and single-channel fluctuations in the absence of intracellular blockers. In this study, we showed that positively charged residues H226, R228 and R260, near site 224, regulated the intrinsic inward rectification and single-channel properties of the E224G mutant. By carrying out systematic mutations, we found that the charge effect on the intrinsic inward rectification and single-channel conductance is consistent with a long-range electrostatic mechanism. A Kir1.1 channel where the site equivalent to E224 in the Kir2.1 channel is a glycine residue does not show inward rectification or single-channel fluctuations. The G223K and N259R mutations of the Kir1.1 channel induced intrinsic inward rectification and reduced the single-channel conductance but did not generate large open-channel fluctuations. Substituting the cytoplasmic pore of the E224G mutant into the Kir1.1 channel induced open-channel fluctuations and intrinsic inward rectification. The single-channel conductance of the E224G mutant showed inward rectification. Also, a voltage-dependent gating mechanism decreased open probability during depolarization and contributed to the intrinsic inward rectification in the E224G mutant. In addition to an electrostatic effect, a close interaction of K⁺ with channel pore may be required for generating open-channel fluctuations in the E224G mutant.     

Inward rectifier K+ channel Kir2.3 is localized at the postsynaptic membrane of excitatory synapses

Classical inwardly rectifyingK⁺ channels (Kir2.0) are responsible for maintaining theresting membrane potential near the K⁺ equilibriumpotential in various cells, including neurons. Although Kir2.3 is knownto be expressed abundantly in the forebrain, its precise localizationhas not been identified. Using an antibody specific to Kir2.3, weexamined the subcellular localization of Kir2.3 in mouse brain. Kir2.3immunoreactivity was detected in a granular pattern in restricted areasof the brain, including the olfactory bulb (OB). Immunoelectronmicroscopy of the OB revealed that Kir2.3 immunoreactivity wasspecifically clustered on the postsynaptic membrane of asymmetricsynapses between granule cells and mitral/tufted cells. Theimmunoprecipitants for Kir2.3 obtained from brain contained PSD-95 andchapsyn-110, PDZ domain-containing anchoring proteins. In vitro bindingassay further revealed that the COOH-terminal end of Kir2.3 isresponsible for the association with these anchoring proteins.Therefore, the Kir channel may be involved in formation of the restingmembrane potential of the spines and, thus, would affect the responseof N-methyl-D-aspartic acid receptor channels atthe excitatory postsynaptic membrane.

     

Characterization of Single Inward Rectifier Potassium Channels from Embryonic Xenopus laevis Myocytes

Single inward rectifier K⁺ channels were studied in Xenopus laevis embryonic myocytes. We have characterized in detail the channel which is most frequently observed (Kir) although we routinely observe three other smaller current levels with the properties of inward rectifier K⁺ channels (Kir_(0.3), Kir_(0.5) and Kir_(0.7)). For Kir, slope conductances of inward currents were 10.3, 20.3, and 27.9 pS, in 60, 120 and 200 mM [K⁺] _o respectively. Extracellular Ba²⁺ blocked the normally high channel activity in a concentration-dependent manner (K _A = 7.8 μm, −90 mV). In whole-cell recordings of inward rectifier K⁺ current, marked voltage dependence of Ba²⁺ block over the physiological range of potentials was observed. We also examined current rectification. Following step depolarizations to voltages positive to E _K , outward currents through Kir channels were not observed even when the cytoplasmic face of excised patches were exposed to Mg²⁺-free solution at pH 9.1. This was probably also true for Kir_(0.3), Kir_(0.5) and Kir_(0.7) channels. We then examined the possibility of modulation of Kir channel activity and found neither ATP nor GTP-γS had any effect on Kir channel activity when added to the solution perfusing the cytoplasmic face of a patch. Kinetic analysis revealed Kir channels with a single open state (mean dwell time 72 msec) and two closed states (time constants 1.4, 79 msec). These results suggest that the native Kir channels of Xenopus myocytes have similar properties to the cloned strong inward rectifier K⁺ channels, in terms of conductance, kinetics and barium block but does show some differences in the effects of modulators of channel activity. Furthermore, skeletal muscle may contain either different inward rectifier channels or a single-channel type which can exist in stable subconductance states. Received: 16 September 1996/Revised: 14 March 1997     

LRET Determination of Molecular Distances during pH Gating of the Mammalian Inward Rectifier Kir1.1b

Gating of the mammalian inward rectifier Kir1.1 at the helix bundle crossing (HBC) by intracellular pH is believed to be mediated by conformational changes in the C-terminal domain (CTD). However, the exact motion of the CTD during Kir gating remains controversial. Crystal structures and single-molecule fluorescence resonance energy transfer of KirBac channels have implied a rigid body rotation and/or a contraction of the CTD as possible triggers for opening of the HBC gate. In our study, we used lanthanide-based resonance energy transfer on single-Cys dimeric constructs of the mammalian renal inward rectifier, Kir1.1b, incorporated into anionic liposomes plus PIP₂, to determine unambiguous, state-dependent distances between paired Cys residues on diagonally opposite subunits. Functionality and pH dependence of our proteoliposome channels were verified in separate electrophysiological experiments. The lanthanide-based resonance energy transfer distances measured in closed (pH 6) and open (pH 8) conditions indicated neither expansion nor contraction of the CTD during gating, whereas the HBC gate widened by 8.8 ± 4 Å, from 6.3 ± 2 to 15.1 ± 6 Å, during opening. These results are consistent with a Kir gating model in which rigid body rotation of the large CTD around the permeation axis is correlated with opening of the HBC hydrophobic gate, allowing permeation of a 7 Å hydrated K ion.     

Discovery and Characterization of a Potent and Selective Inhibitor of Aedes aegypti Inward Rectifier Potassium Channels

Vector-borne diseases such as dengue fever and malaria, which are transmitted by infected female mosquitoes, affect nearly half of the world''s population. The emergence of insecticide-resistant mosquito populations is reducing the effectiveness of conventional insecticides and threatening current vector control strategies, which has created an urgent need to identify new molecular targets against which novel classes of insecticides can be developed. We previously demonstrated that small molecule inhibitors of mammalian Kir channels represent promising chemicals for new mosquitocide development. In this study, high-throughput screening of approximately 30,000 chemically diverse small-molecules was employed to discover potent and selective inhibitors of Aedes aegypti Kir1 (AeKir1) channels heterologously expressed in HEK293 cells. Of 283 confirmed screening ‘hits’, the small-molecule inhibitor VU625 was selected for lead optimization and in vivo studies based on its potency and selectivity toward AeKir1, and tractability for medicinal chemistry. In patch clamp electrophysiology experiments of HEK293 cells, VU625 inhibits AeKir1 with an IC₅₀ value of 96.8 nM, making VU625 the most potent inhibitor of AeKir1 described to date. Furthermore, electrophysiology experiments in Xenopus oocytes revealed that VU625 is a weak inhibitor of AeKir2B. Surprisingly, injection of VU625 failed to elicit significant effects on mosquito behavior, urine excretion, or survival. However, when co-injected with probenecid, VU625 inhibited the excretory capacity of mosquitoes and was toxic, suggesting that the compound is a substrate of organic anion and/or ATP-binding cassette (ABC) transporters. The dose-toxicity relationship of VU625 (when co-injected with probenecid) is biphasic, which is consistent with the molecule inhibiting both AeKir1 and AeKir2B with different potencies. This study demonstrates proof-of-concept that potent and highly selective inhibitors of mosquito Kir channels can be developed using conventional drug discovery approaches. Furthermore, it reinforces the notion that the physical and chemical properties that determine a compound''s bioavailability in vivo will be critical in determining the efficacy of Kir channel inhibitors as insecticides.     

Inward Rectifier K+ Currents Are Regulated by CaMKII in Endothelial Cells of Primarily Cultured Bovine Pulmonary Arteries

Endothelium lines the interior surface of vascular walls and regulates vascular tones. The endothelial cells sense and respond to chemical and mechanical stimuli in the circulation, and couple the stimulus signals to vascular smooth muscles, in which inward rectifier K⁺ currents (Kir) play an important role. Here we applied several complementary strategies to determine the Kir subunit in primarily cultured pulmonary arterial endothelial cells (PAECs) that was regulated by the Ca²⁺/calmodulin (CaM)-dependent protein kinase II (CaMKII). In whole-cell voltage clamp, the Kir currents were sensitive to micromolar concentrations of extracellular Ba²⁺. In excised inside-out patches, an inward rectifier K⁺ current was observed with single-channel conductance 32.43 ± 0.45 pS and P_open 0.27 ± 0.04, which were consistent with known unitary conductance of Kir 2.1. RT-PCR and western blot results showed that expression of Kir 2.1 was significantly stronger than that of other subtypes in PAECs. Pharmacological analysis of the Kir currents demonstrated that insensitivity to intracellular ATP, pinacidil, glibenclamide, pH, GDP-β-S and choleratoxin suggested that currents weren’t determined by K_ATP, Kir2.3, Kir2.4 and Kir3.x. The currents were strongly suppressed by exposure to CaMKII inhibitor W-7 and KN-62. The expression of Kir2.1 was inhibited by knocking down CaMKII. Consistently, vasodilation was suppressed by Ba²⁺, W-7 and KN-62 in isolated and perfused pulmonary arterial rings. These results suggest that the PAECs express an inward rectifier K⁺ current that is carried dominantly by Kir2.1, and this K⁺ channel appears to be targeted by CaMKII-dependent intracellular signaling systems.     

Inward Rectifying K Channels in the Plasma Membrane of Arabidopsis thaliana

Ion channels in the plasma membrane of protoplasts isolated from cultured cells of Arabidopsis thaliana were studied by means of the patch-clamp technique applied in the whole-cell configuration. In some protoplasts, depolarizing pulses and, in other protoplasts, hyperpolarizing pulses elicited time-dependent currents; both kinds of current were only rarely observed in the same protoplast. The hyperpolarization-activated inward rectifying currents, the focus of this paper, appeared to be due to the relatively slow opening of channels (activation time constant = 150 to 300 milliseconds), which closed at positive potentials. The reversal potential of this current, measured in the presence of different ion concentrations (symmetrical or asymmetrical K⁺ and Cl⁻ or gluconate), was always close to the electrochemical equilibrium potential of K⁺. The currents were inhibited by 10 millimolar tetraethylammonium, a K⁺ channel blocker. These data show that the hyperpolarization-activated currents flow through K⁺ channels, which can provide a pathway for the passive diffusion of K⁺ down its electrochemical gradient.     

Small Inward Rectifying K+ Channels in Coleoptiles: Inhibition by External Ca2+ and Function in Cell Elongation

Plant growth requires a continuous supply of intracellular solutes in order to drive cell elongation. Ion fluxes through the plasma membrane provide a substantial portion of the required solutes. Here, patch clamp techniques have been used to investigate the electrical properties of the plasma membrane in protoplasts from the rapid growing tip of maize coleoptiles. Inward currents have been measured in the whole cell configuration from protoplasts of the outer epidermis and from the cortex. These currents are essentially mediated by K⁺ channels with a unitary conductance of about 12 pS. The activity of these channels was stimulated by negative membrane voltage and inhibited by extracellular Ca²⁺ and/or tetraethylammonium-CI (TEA). The kinetics of voltage- and Ca²⁺-gating of these channels have been determined experimentally in some detail (steady-state and relaxation kinetics). Various models have been tested for their ability to describe these experimental data in straightforward terms of mass action. As a first approach, the most appropriate model turned out to consist of an active state which can equilibrate with two inactive states via independent first order reactions: a fast inactivation/activation by Ca²⁺-binding and -release, respectively (rate constants >>10³ sec⁻¹) and a slower inactivation/activation by positive/negative voltage, respectively (voltage-dependent rate constants in the range of 10³ sec⁻¹). With 10 mm K⁺ and 1 mm Ca²⁺ in the external solution, intact coleoptile cells have a membrane voltage (V) of −105 ± 7 mV. At this V, the density and open probability of the inward-rectifying channels is sufficient to mediate K⁺ uptake required for cell elongation. Extracellular TEA or Ca²⁺, which inhibit the K⁺ inward conductance, also inhibit elongation of auxin-depleted coleoptile segments in acidic solution. The comparable effects of Ca²⁺ and TEA on both processes and the similar Ca²⁺ concentration required for half maximal inhibition of growth (4.3 mm Ca²⁺) and for conductance (1.2 mm Ca²⁺) suggest that K⁺ uptake through the inward rectifier provides essential amounts of solute for osmotic driven elongation of maize coleoptiles. Received: 6 June 1995/Revised: 12 September 1995     

Identification of gamma-aminobutyric acid receptor-interacting factor 1 (TRAK2) as a trafficking factor for the K+ channel Kir2.1

To identify proteins that regulate potassium channel activity and expression, we performed functional screening of mammalian cDNA libraries in yeast that express the mammalian K(+) channel Kir2.1. Growth of Kir2.1-expressing yeast in media with low K(+) concentration is a function of K(+) uptake via Kir2.1 channels. Therefore, the host strain was transformed with a human cDNA library, and cDNA clones that rescued growth at low K(+) concentration were selected. One of these clones was identical to the protein of unknown function isolated previously as gamma-aminobutyric acid receptor-interacting factor 1 (GRIF-1) (Beck, M., Brickley, K., Wilkinson, H., Sharma, S., Smith, M., Chazot, P., Pollard, S., and Stephenson, F. (2002) J. Biol. Chem. 277, 30079-30090). GRIF-1 specifically enhanced Kir2.1-dependent growth in yeast and Kir2.1-mediated (86)Rb(+) efflux in HEK293 cells. Quantitative microscopy and flow cytometry analysis of immunolabeled surface Kir2.1 channel showed that GRIF-1 significantly increased the number of Kir2.1 channels in the plasma membrane of COS and HEK293 cells. Physical interaction of Kir2.1 channel and GRIF-1 was demonstrated by co-immunoprecipitation from HEK293 lysates and yeast two-hybrid assay. In vivo association of Kir2.1 and GRIF-1 was demonstrated by co-immunoprecipitation from brain lysate. Yeast two-hybrid assays showed that an N-terminal region of GRIF-1 interacts with a C-terminal region of Kir2.1. These results indicate that GRIF-1 binds to Kir2.1 and facilitates trafficking of this channel to the cell surface.     

Role of Voltage-Gated K+ (KV) Channels in Vascular Function

Voltage-dependent K⁺ (K_V) channels represent the most diverse group of K⁺ channels ubiquitously expressed in vascular smooth muscles. The K_V channels, together with other types of K⁺ conductances, such as Ca²⁺-activated (BK_Ca), ATP-sensitive (K_ATP), and inward rectifier, play an important role in the control of the cell membrane potential and regulation of the vascular contractility. Comparison of the expression of different K_V channel isoforms obtained from RT-PCR studies showed that virtually all K_V genes could be detected in vascular smooth muscle cells (VSMC). Based on the analysis of both mRNA and protein expressions, it is likely that K_V1.1, K_V1.2, K_V1.3, K_V1.5, K_V1.6, K_V2.1, and K_V3.1b channel isoforms are mainly responsible for the delayed rectifier current characterized electrophysiologically in most VSMC types studied to date. It has been recently demonstrated by our research group and by others that functional expression of multiple K_V channel α-subunits is not homogeneous and varies in different vascular beds of small and large arteries. Growing evidence suggests that in some small arteries, e.g., cerebral arteries and arterioles, the K_V channels are activated at more negative membrane voltages than BK_Ca, thus making a greater contribution to the control of vascular tone. Our data also suggest that in some blood vessels, such as the rat aorta and mouse small mesenteric arteries, the K_V channel current (identified mainly as passed through K_V2.1 channels), but not BK_Ca, is the predominant conductance activated even under conditions where intracellular Ca₂₊ concentration is increased up to 200 nM. In addition, our data indicate that the K_V2.1 channel current could also contribute to the regulation of the induced rhythmic activity in the rat aorta in vitro acting as a negative feedback mechanism for membrane depolarization. We and other experimenters also demonstrated that functional expression of K_V channels is a dynamic process, which is altered under normal physiological conditions (e.g., during the development of the vessels), and in various pathological states (e.g., pulmonary hypertension developing during chronic hypoxia). Recent findings also suggest that activation of K_V channels can also play a role in vascular apoptosis (causing loss of intracellular K⁺ and subsequent cell shrinking, one of the essential prerequisites of cellular apoptosis). To summarize, the K^V channels are essential for normal vascular function, and their expression and properties are altered under abnormal conditions. Therefore, understanding of the molecular identity of native K_V channels and their functional significance and elucidation of the mechanisms, which govern and control the expression of the K_V channels in the vasculature, represent an important and challenging task and could also lead to the development of useful therapeutic strategies for the treatment of cardiovascular diseases.     

K+ Channels in Apoptosis

A proper rate of programmed cell death or apoptosis is required to maintain normal tissue homeostasis. In disease states such as cancer and some forms of hypertension, apoptosis is blocked, resulting in hyperplasia. In neurodegenerative diseases, uncontrolled apoptosis leads to loss of brain tissue. The flow of ions in and out of the cell and its intracellular organelles is becoming increasingly linked to the generation of many of these diseased states. This review focuses on the transport of K(+) across the cell membrane and that of the mitochondria via integral K(+)-permeable channels. We describe the different types of K(+) channels that have been identified, and investigate the roles they play in controlling the different phases of apoptosis: early cell shrinkage, cytochrome c release, caspase activation, and DNA fragmentation. Attention is also given to K(+) channels on the inner mitochondrial membrane, whose activity may underlie anti- or pro-apoptotic mechanisms in neurons and cardiomyocytes.     

Voltage-dependent Gating of Single Wild-Type and S4 Mutant KAT1 Inward Rectifier Potassium Channels

The voltage-dependent gating mechanism of KAT1 inward rectifier potassium channels was studied using single channel current recordings from Xenopus oocytes injected with KAT1 mRNA. The inward rectification properties of KAT1 result from an intrinsic gating mechanism in the KAT1 channel protein, not from pore block by an extrinsic cation species. KAT1 channels activate with hyperpolarizing potentials from −110 through −190 mV with a slow voltage-dependent time course. Transitions before first opening are voltage dependent and account for much of the voltage dependence of activation, while transitions after first opening are only slightly voltage dependent. Using burst analysis, transitions near the open state were analyzed in detail. A kinetic model with multiple closed states before first opening, a single open state, a single closed state after first opening, and a closed-state inactivation pathway accurately describes the single channel and macroscopic data. Two mutations neutralizing charged residues in the S4 region (R177Q and R176L) were introduced, and their effects on single channel gating properties were examined. Both mutations resulted in depolarizing shifts in the steady state conductance–voltage relationship, shortened first latencies to opening, decreased probability of terminating bursts, and increased burst durations. These effects on gating were well described by changes in the rate constants in the kinetic model describing KAT1 channel gating. All transitions before the open state were affected by the mutations, while the transitions after the open state were unaffected, implying that the S4 region contributes to the early steps in gating for KAT1 channels.