Identification of a Cholesterol-Binding Pocket in Inward Rectifier K+ (Kir) Channels

Cholesterol is the major sterol component of all mammalian plasma membranes. Recent studies have shown that cholesterol inhibits both bacterial (KirBac1.1 and KirBac3.1) and eukaryotic (Kir2.1) inward rectifier K⁺ (Kir) channels. Lipid-sterol interactions are not enantioselective, and the enantiomer of cholesterol (ent-cholesterol) does not inhibit Kir channel activity, suggesting that inhibition results from direct enantiospecific binding to the channel, and not indirect effects of changes to the bilayer. Furthermore, conservation of the effect of cholesterol among prokaryotic and eukaryotic Kir channels suggests an evolutionary conserved cholesterol-binding pocket, which we aimed to identify. Computational experiments were performed by docking cholesterol to the atomic structures of Kir2.2 (PDB: 3SPI) and KirBac1.1 (PDB: 2WLL) using Autodock 4.2. Poses were assessed to ensure biologically relevant orientation and then clustered according to location and orientation. The stability of cholesterol in each of these poses was then confirmed by molecular dynamics simulations. Finally, mutation of key residues (S95H and I171L) in this putative binding pocket found within the transmembrane domain of Kir2.1 channels were shown to lead to a loss of inhibition by cholesterol. Together, these data provide support for this location as a biologically relevant pocket.     

Filter flexibility and distortion in a bacterial inward rectifier K+ channel: simulation studies of KirBac1.1

The bacterial channel KirBac1.1 provides a structural homolog of mammalian inward rectifier potassium (Kir) channels. The conformational dynamics of the selectivity filter of Kir channels are of some interest in the context of possible permeation and gating mechanisms for this channel. Molecular dynamics simulations of KirBac have been performed on a 10-ns timescale, i.e., comparable to that of ion permeation. The results of five simulations (total simulation time 50 ns) based on three different initial ion configurations and two different model membranes are reported. These simulation data provide evidence for limited (<0.1 nm) filter flexibility during the concerted motion of ions and water molecules within the filter, such local changes in conformation occurring on an approximately 1-ns timescale. In the absence of K(+) ions, the KirBac selectivity filter undergoes more substantial distortions. These resemble those seen in comparable simulations of other channels (e.g., KcsA and KcsA-based homology models) and are likely to lead to functional closure of the channel. This suggests filter distortions may provide a mechanism of K-channel gating in addition to changes in the hydrophobic gate formed at the intracellular crossing point of the M2 helices. The simulation data also provide evidence for interactions of the "slide" (pre-M1) helix of KirBac with phospholipid headgroups.     

Molecular dynamics simulations of inwardly rectifying (Kir) potassium channels: a comparative study

Inward rectifier potassium (Kir) channels regulate cell excitability and transport K+ ions across membranes. Homotetrameric models of three mammalian Kir channels (Kir1.1, Kir3.1, and Kir6.2) have been generated, using the KirBac3.1 transmembrane and rat Kir3.1 intracellular domain structures as templates. All three models have been explored by 10 ns molecular dynamics simulations in phospholipid bilayers. Analysis of the initial structures revealed conservation of potential lipid interaction residues (Trp/Tyr and Arg/Lys side chains near the lipid headgroup-water interfaces). Examination of the intracellular domains revealed key structural differences between Kir1.1 and Kir6.2 which may explain the difference in channel inhibition by ATP. The behavior of all three models in the MD simulations revealed that they have conformational stability similar to that seen for comparable simulations of, for example, structures derived from cryoelectron microscopy data. Local distortions of the selectivity filter were seen during the simulations, as observed in previous simulations of KirBac and in simulations and structures of KcsA. These may be related to filter gating of the channel. The intracellular hydrophobic gate does not undergo any substantial changes during the simulations and thus remains functionally closed. Analysis of lipid-protein interactions of the Kir models emphasizes the key role of the M0 (or "slide") helix which lies approximately parallel to the bilayer-water interface and forms a link between the transmembrane and intracellular domains of the channel.     

Cholesterol regulates prokaryotic Kir channel by direct binding to channel protein

Cholesterol is a major regulator of a variety of ion channels but the mechanisms underlying cholesterol sensitivity of ion channels are still poorly understood. The key question is whether cholesterol regulates ion channels by direct binding to the channel protein or by altering the physical environment of lipid bilayer. In this study, we provide the first direct evidence that cholesterol binds to prokaryotic Kir channels, KirBac1.1, and that cholesterol binding is essential for its regulatory effect. Specifically, we show that cholesterol is eluted together with the KirBac1.1 protein when separated on an affinity column and that the amount of bound cholesterol is proportional to the amount of the protein. We also show that cholesterol binding to KirBac1.1 is saturable with a K(D) of 390μM. Moreover, there is clear competition between radioactive and non-radioactive cholesterol for the binding site. There is no competition, however, between cholesterol and 5-Androsten 3β-17 β-diol, a sterol that we showed previously to have no effect on KirBac1.1 function. Finally, we show that cholesterol-KirBac1.1 binding is significantly inhibited by trifluoperazine, known to inhibit cholesterol binding to other proteins, and that inhibition of cholesterol-KirBac1.1 binding results in full recovery of the channel activity. Collectively, results from this study indicate that cholesterol-induced suppression of KirBac1.1 activity is mediated by direct interaction between cholesterol and the channel protein.     

Short variable sequence acquired in evolution enables selective inhibition of various inward-rectifier K+ channels

Tertiapin (TPN), a small protein toxin originally isolated from honey bee venom, inhibits only certain eukaryotic inward-rectifier K(+) (Kir) channels with high affinity. We found that a short ( approximately 10 residues) sequence in Kir channels, located in the N-terminal part of the linker between the two transmembrane segments, is essential for high-affinity inhibition by TPN and that variability in the region underlies the great variation of TPN affinities among eukaryotic Kir channels. This short variable region is however not present in a bacterial Kir channel (KirBac1.1) or in many other types of prokaryotic and eukaryotic K(+) channels. Thus, the acquisition in evolution of the variable region in eukaryotic Kir channels has created the opportunity to selectively target the numerous types of Kir channel that play important physiological roles. We also show that TPN sensitivity can be readily conferred onto some Kir channels that currently have no known inhibitors by replacing their variable region with that from a TPN-sensitive channel. In heterologous expression systems, such acquired toxin sensitivity will allow currents carried by mutant channels to be readily isolated from interfering background currents. Finally we show that, in the heteromeric GIRK1/4 channels, the GIRK4 and not GIRK1 subunit confers the high affinity for TPN.     

Direct modulation of Kir channel gating by membrane phosphatidylinositol 4,5-bisphosphate

Multiple ion channels have now been shown to be regulated by phosphatidylinositol 4,5-bisphosphate (PIP2) at the cytoplasmic face of the membrane. However, direct evidence for a specific interaction between phosphoinositides and ion channels is critically lacking. We reconstituted pure KirBac1.1 and KcsA protein into liposomes of defined composition (3:1 phosphatidylethanolamine:phosphatidylglycerol) and examined channel activity using a 86Rb+ uptake assay. We demonstrate direct modulation by PIP2 of KirBac1.1 but not KcsA activity. In marked contrast to activation of eukaryotic Kir channels by PIP2, KirBac1.1 is inhibited by PIP2 incorporated in the membrane (K(1/2) = 0.3 mol %). The dependence of inhibition on the number of phosphate groups and requirement for a lipid tail matches that for activation of eukaryotic Kir channels, suggesting a fundamentally similar interaction mechanism. The data exclude the possibility of indirect modulation via cytoskeletal or other intermediary elements and establish a direct interaction of the channel with PIP2 in the membrane.     

Direct Regulation of Prokaryotic Kir Channel by Cholesterol

Our earlier studies have shown that channel activity of Kir2 subfamily of inward rectifiers is strongly suppressed by the elevation of cellular cholesterol. The goal of this study is to determine whether cholesterol suppresses Kir channels directly. To achieve this goal, purified prokaryotic Kir (KirBac1.1) channels were incorporated into liposomes of defined lipid composition, and channel activity was assayed by ⁸⁶Rb⁺ uptake. Our results show that ⁸⁶Rb⁺ flux through KirBac1.1 is strongly inhibited by cholesterol. Incorporation of 5% (mass cholesterol/phospholipid) cholesterol into the liposome suppresses ⁸⁶Rb⁺ flux by >50%, and activity is completely inhibited at 12–15%. However, epicholesterol, a stereoisomer of cholesterol with similar physical properties, has significantly less effect on KirBac-mediated ⁸⁶Rb⁺ uptake than cholesterol. Furthermore, analysis of multiple sterols suggests that cholesterol-induced inhibition of KirBac1.1 channels is mediated by specific interactions rather than by changes in the physical properties of the lipid bilayer. In contrast to the inhibition of KirBac1.1 activity, cholesterol had no effect on the activity of reconstituted KscA channels (at up to 250 μg/mg of phospholipid). Taken together, these observations demonstrate that cholesterol suppresses Kir channels in a pure protein-lipid environment and suggest that the interaction is direct and specific.Inwardly rectifying potassium channels (Kir) are known to play critical roles in the regulation of multiple cellular functions including membrane excitability, heart rate, and vascular tone (1–3). Kir channels are classified into seven subfamilies (Kir1–7) identified by distinct biophysical properties and sensitivities to different regulators (2). Our earlier studies have shown that Kir2 channels, one of the major subfamilies of Kir that are responsible for maintaining membrane potential in a variety of cell types, are strongly suppressed by the elevation of membrane cholesterol (4, 5). Cholesterol-induced suppression of Kir2 was first observed in aortic endothelial cells (4), in which resting K⁺ conductance is dominated by Kir2.1 and Kir2.2 channels (6), and then when channels were heterologously expressed in Chinese hamster ovary cells (5, 7). Furthermore, the same effect was observed ex vivo in endothelial cells and bone marrow-derived progenitor cells isolated from hypercholesterolemic pigs (8, 9).In terms of the mechanism, the first insights came from comparing the effects of cholesterol and of its chiral analogue, epicholesterol. Although the two sterols are known to have almost identical effects on the biophysical properties of the lipid bilayer (10, 11), their impact on Kir activity is completely different; partial substitution of endogenous cholesterol with epicholesterol resulted in significant increase in Kir current in endothelial cells (4). These observations suggest that specific sterol-protein interactions may be involved in the cholesterol sensitivity of Kir2 channels. However, in the complex environment of the plasma membrane, cholesterol may interact not only with the channels themselves but also with other proteins, which in turn may regulate the activity of the channels. In the cellular environment, therefore, it is impossible to discriminate between direct channel-cholesterol interactions and indirect effects. Moreover, it is impossible to define the actual concentrations of cholesterol in any given membrane compartment. To quantitatively test direct cholesterol-protein interactions, it is necessary to examine sensitivity of pure Kir channels to membrane cholesterol in a membrane of defined lipid composition. To date, only the cytoplasmic domains of several mammalian Kir channels have been purified (Kir2.1, Kir3.1, and Kir3.2) (12–15). We therefore concentrate in this study on the effect of cholesterol on two bacterial K⁺ channels that differ in the level of their homology to mammalian Kir channels, KirBac1.1 and KcsA. KirBac channels have high sequence homology with mammalian Kirs (e.g. 52% homology between KirBac1.1 and Kir2.1; see Fig. 7A) and have now been extensively used as structural models of mammalian Kir channels (3, 16, 17). The sequence similarity between KcsA and mammalian K channels lies mainly in the transmembrane domain (18). The overall sequence homology of KcsA to mammalian Kir channels is relatively low (e.g. 22% homology between KcsA and Kir2.1; see Fig. 7A), with an entirely different cytoplasmic domain structure.Open in a separate windowFIGURE 7.Cholesterol has no effect on KcsA-mediated ⁸⁶Rb⁺ uptake. A, time courses of ⁸⁶Rb⁺ uptake into liposomes reconstituted with 50 μg of cholesterol/mg of PL and as compared with liposomes containing no cholesterol (control). Both batches of liposomes contained 5 μg of KcsA/mg of PL. Blank liposomes contain no protein. The points represent averages of three independent experiments (means ± S.D.). B, normalized time courses of ⁸⁶Rb⁺ uptake in liposomes incorporating 50, 150, and 250 μg of cholesterol/mg of PL. C, maximal uptake of ⁸⁶Rb⁺ after 240 s in liposomes containing 10, 25, 50, 100, 150, 200, and 250 μg of cholesterol/mg of PL normalized to control (means ± S.D. of 3–5 independent experiments; *, p < 0.05). DPM, disintegrations per minute.Here we show that, similarly to Kir2 channels, prokaryotic Kir channels incorporated into liposomes are strongly suppressed by an increase in membrane cholesterol. Furthermore, the sensitivity of prokaryotic Kir to cholesterol is stereo-selective to cholesterol optical analogues. In contrast, KscA channels are insensitive to membrane cholesterol. These observations suggest that cholesterol directly suppresses Kir channels.     

Gating of a G protein-sensitive mammalian Kir3.1 prokaryotic Kir channel chimera in planar lipid bilayers

Kir3 channels control heart rate and neuronal excitability through GTP-binding (G) protein and phosphoinositide signaling pathways. These channels were the first characterized effectors of the βγ subunits of G proteins. Because we currently lack structures of complexes between G proteins and Kir3 channels, their interactions leading to modulation of channel function are not well understood. The recent crystal structure of a chimera between the cytosolic domain of a mammalian Kir3.1 and the transmembrane region of a prokaryotic KirBac1.3 (Kir3.1 chimera) has provided invaluable structural insight. However, it was not known whether this chimera could form functional K(+) channels. Here, we achieved the functional reconstitution of purified Kir3.1 chimera in planar lipid bilayers. The chimera behaved like a bona fide Kir channel displaying an absolute requirement for PIP(2) and Mg(2+)-dependent inward rectification. The channel could also be blocked by external tertiapin Q. The three-dimensional reconstruction of the chimera by single particle electron microscopy revealed a structure consistent with the crystal structure. Channel activity could be stimulated by ethanol and activated G proteins. Remarkably, the presence of both activated Gα and Gβγ subunits was required for gating of the channel. These results confirm the Kir3.1 chimera as a valid structural and functional model of Kir3 channels.     

Functional characterization of a prokaryotic Kir channel

The Kir gene family encodes inward rectifying K+ (Kir) channels that are widespread and critical regulators of excitability in eukaryotic cells. A related gene family (KirBac) has recently been identified in prokaryotes. While a crystal structure of one member, Kir-Bac1.1, has been solved, there has been no functional characterization of any KirBac gene products. Here we present functional characterization of KirBac1.1 reconstituted in liposomes. Utilizing a 86Rb+ uptake assay, we demonstrate that KirBac1.1 generates a K+ -selective permeation path that is inhibited by extraliposomal Ba2+ and Ca2+ ions. In contrast to KcsA (an acid-activated bacterial potassium channel), KirBac1.1 is inhibited by extraliposomal acid (pKa approximately 6). This characterization of KirBac1.1 activity now paves the way for further correlation of structure and function in this model Kir channel.     

Control of KirBac3.1 Potassium Channel Gating at the Interface between Cytoplasmic Domains

KirBac channels are prokaryotic homologs of mammalian inwardly rectifying potassium (Kir) channels, and recent structures of KirBac3.1 have provided important insights into the structural basis of gating in Kir channels. In this study, we demonstrate that KirBac3.1 channel activity is strongly pH-dependent, and we used x-ray crystallography to determine the structural changes that arise from an activatory mutation (S205L) located in the cytoplasmic domain (CTD). This mutation stabilizes a novel energetically favorable open conformation in which changes at the intersubunit interface in the CTD also alter the electrostatic potential of the inner cytoplasmic cavity. These results provide a structural explanation for the activatory effect of this mutation and provide a greater insight into the role of the CTD in Kir channel gating.     

Control of inward rectifier K channel activity by lipid tethering of cytoplasmic domains

Interactions between nontransmembrane domains and the lipid membrane are proposed to modulate activity of many ion channels. In Kir channels, the so-called "slide-helix" is proposed to interact with the lipid headgroups and control channel gating. We examined this possibility directly in a cell-free system consisting of KirBac1.1 reconstituted into pure lipid vesicles. Cysteine substitution of positively charged slide-helix residues (R49C and K57C) leads to loss of channel activity that is rescued by in situ restoration of charge following modification by MTSET(+) or MTSEA(+), but not MTSES(-) or neutral MMTS. Strikingly, activity is also rescued by modification with long-chain alkyl-MTS reagents. Such reagents are expected to partition into, and hence tether the side chain to, the membrane. Systematic scanning reveals additional slide-helix residues that are activated or inhibited following alkyl-MTS modification. A pattern emerges whereby lipid tethering of the N terminus, or C terminus, of the slide-helix, respectively inhibits, or activates, channel activity. This study establishes a critical role of the slide-helix in Kir channel gating, and directly demonstrates that physical interaction of soluble domains with the membrane can control ion channel activity.     

Modulation of endothelial inward-rectifier K+ current by optical isomers of cholesterol

Membrane potential of aortic endothelial cells under resting conditions is dominated by inward-rectifier K(+) channels belonging to the Kir 2 family. Regulation of endothelial Kir by membrane cholesterol was studied in bovine aortic endothelial cells by altering the sterol composition of the cell membrane. Our results show that enriching the cells with cholesterol decreases the Kir current density, whereas depleting the cells of cholesterol increases the density of the current. The dependence of the Kir current density on the level of cellular cholesterol fits a sigmoid curve with the highest sensitivity of the Kir current at normal physiological levels of cholesterol. To investigate the mechanism of Kir regulation by cholesterol, endogenous cholesterol was substituted by its optical isomer, epicholesterol. Substitution of approximately 50% of cholesterol by epicholesterol results in an early and significant increase in the Kir current density. Furthermore, substitution of cholesterol by epicholesterol has a stronger facilitative effect on the current than cholesterol depletion. Neither single channel properties nor membrane capacitance were significantly affected by the changes in the membrane sterol composition. These results suggest that 1) cholesterol modulates cellular K(+) conductance by changing the number of the active channels and 2) that specific cholesterol-protein interactions are critical for the regulation of endothelial Kir.     

Two different conformational states of the KirBac3.1 potassium channel revealed by electron crystallography

Potassium channels allow the selective flow of K(+) ions across membranes. In response to external gating signals, the potassium channel can move reversibly through a series of structural conformations from a closed to an open state. 2D crystals of the inwardly rectifying K(+) channel KirBac3.1 from Magnetospirillum magnetotacticum have been captured in two distinct conformations, providing "snap shots" of the gating process. Analysis by electron cryomicroscopy of these KirBac3.1 crystals has resulted in reconstructed images in projection at 9 A resolution. Kir channels are tetramers of four subunits arranged as dimers of dimers. Each subunit has two transmembrane helices (inner and outer). In one crystal form, the pore is blocked; in the other crystal form, the pore appears open. Modeling based on the KirBac1.1 (closed) crystal structure shows that opening of the ion conduction pathway could be achieved by bending of the inner helices and significant movements of the outer helices.     

Cholesterol sensitivity and lipid raft targeting of Kir2.1 channels

This study investigates how changes in the level of cellular cholesterol affect inwardly rectifying K+ channels belonging to a family of strong rectifiers (Kir2). In an earlier study we showed that an increase in cellular cholesterol suppresses endogenous K+ current in vascular endothelial cells, presumably due to effects on underlying Kir2.1 channels. Here we show that, indeed, cholesterol increase strongly suppressed whole-cell Kir2.1 current when the channels were expressed in a null cell line. However, cholesterol level had no effect on the unitary conductance and only little effect on the open probability of the channels. Moreover, no cholesterol effect was observed either on the total level of Kir2.1 protein or on its surface expression. We suggest, therefore, that cholesterol modulates not the total number of Kir2.1 channels in the plasma membrane but rather the transition of the channels between active and silent states. Comparing the effects of cholesterol on members of the Kir2.x family shows that Kir2.1 and Kir2.2 have similar high sensitivity to cholesterol, Kir2.3 is much less sensitive, and Kir2.4 has an intermediate sensitivity. Finally, we show that Kir2.x channels partition virtually exclusively into Triton-insoluble membrane fractions indicating that the channels are targeted into cholesterol-rich lipid rafts.     

Comparative analysis of cholesterol sensitivity of Kir channels: Role of the CD loop

Kir channels are important in setting the resting membrane potential and modulating membrane excitability. A common feature of Kir2 channels and several other ion channels that has emerged in recent years is that they are regulated by cholesterol, a major lipid component of the plasma membrane whose excess is associated with multiple pathological conditions. Yet, the mechanism by which cholesterol affects channel function is not clear. We have recently shown that the sensitivity of Kir2 channels to cholesterol depends on residues in the CD loop of the cytosolic domain of the channels with one of the mutations, L222I, abrogating cholesterol sensitivity of the channels completely. Here we show that in addition to Kir2 channels, members of other Kir subfamilies are also regulated by cholesterol. Interestingly, while similarly to Kir2 channels, several Kir channels, Kir1.1, Kir4.1 and Kir6.2Delta36 were suppressed by an increase in membrane cholesterol, the function of Kir3.4* and Kir7.1 was enhanced following cholesterol enrichment. Furthermore, we show that independent of the impact of cholesterol on channel function, mutating residues in the corresponding positions of the CD loop in Kir2.1 and Kir3.4*, inhibits cholesterol sensitivity of Kir channels, thus extending the critical role of the CD loop beyond Kir2 channels.     

Relationship between Kir2.1/Kir2.3 activity and their distributions between cholesterol-rich and cholesterol-poor membrane domains

Our earlier studies have shown that Kir2.x channels are suppressed by an increase in the level of cellular cholesterol, whereas cholesterol depletion enhances the activity of the channels. In this study, we show that Kir2.1 and Kir2.3 channels have double-peak distributions between cholesterol-rich (raft) and cholesterol-poor (non-raft) membrane fractions, indicating that the channels exist in two different types of lipid environment. We also show that whereas methyl--cyclodextrin-induced cholesterol depletion removes cholesterol from both raft and non-raft membrane fractions, cholesterol enrichment results in cholesterol increase exclusively in the raft fractions. Kinetics of both depletion-induced Kir2.1 enhancement and enrichment-induced Kir2.1 suppression correlate with the changes in the level of raft cholesterol. Furthermore, we show not only that cholesterol depletion shifts the distribution of the channels from cholesterol-rich to cholesterol-poor membrane fractions but also that cholesterol enrichment has the opposite effect. These observations suggest that change in the level of raft cholesterol alone is sufficient to suppress Kir2 activity and to facilitate partitioning of the channels to cholesterol-rich domains. Therefore, we suggest that partitioning to membrane rafts plays an important role in the sensitivity of Kir2 channels to cholesterol. ion channels; inward rectifiers; inwardly rectifying potassium channels     

Alterations in conserved Kir channel-PIP2 interactions underlie channelopathies

Inwardly rectifying K(+) (Kir) channels are important regulators of resting membrane potential and cell excitability. The activity of Kir channels is critically dependent on the integrity of channel interactions with phosphatidylinositol 4,5-bisphosphate (PIP(2)). Here we identify and characterize channel-PIP(2) interactions that are conserved among Kir family members. We find basic residues that interact with PIP(2), two of which have been associated with Andersen's and Bartter's syndromes. We show that several naturally occurring mutants decrease channel-PIP(2) interactions, leading to disease.     

Destabilization of ATP-sensitive potassium channel activity by novel KCNJ11 mutations identified in congenital hyperinsulinism

The inwardly rectifying potassium channel Kir6.2 is the pore-forming subunit of the ATP-sensitive potassium (K(ATP)) channel, which controls insulin secretion by coupling glucose metabolism to membrane potential in beta-cells. Loss of channel function because of mutations in Kir6.2 or its associated regulatory subunit, sulfonylurea receptor 1, causes congenital hyperinsulinism (CHI), a neonatal disease characterized by persistent insulin secretion despite severe hypoglycemia. Here, we report a novel K(ATP) channel gating defect caused by CHI-associated Kir6.2 mutations at arginine 301 (to cysteine, glycine, histidine, or proline). These mutations in addition to reducing channel expression at the cell surface also cause rapid, spontaneous current decay, a gating defect we refer to as inactivation. Based on the crystal structures of Kir3.1 and KirBac1.1, Arg-301 interacts with several residues in the neighboring Kir6.2 subunit. Mutation of a subset of these residues also induces channel inactivation, suggesting that the disease mutations may cause inactivation by disrupting subunit-subunit interactions. To evaluate the effect of channel inactivation on beta-cell function, we expressed an alternative inactivation mutant R301A, which has equivalent surface expression efficiency as wild type channels, in the insulin-secreting cell line INS-1. Mutant expression resulted in more depolarized membrane potential and elevated insulin secretion at basal glucose concentration (3 mm) compared with cells expressing wild type channels, demonstrating that the inactivation gating defect itself is sufficient to cause loss of channel function and hyperinsulinism. Our studies suggest the importance of Kir6.2 subunit-subunit interactions in K(ATP) channel gating and function and reveal a novel gating defect underlying CHI.     

Direct visualization of KirBac3.1 potassium channel gating by atomic force microscopy

KirBac3.1 belongs to a family of transmembrane potassium (K⁺) channels that permit the selective flow of K-ions across biological membranes and thereby regulate cell excitability. They are crucial for a wide range of biological processes and mutations in their genes cause multiple human diseases. Opening and closing (gating) of Kir channels may occur spontaneously but is modulated by numerous intracellular ligands that bind to the channel itself. These include lipids (such as PIP₂), G-proteins, nucleotides (such as ATP) and ions (e.g. H⁺, Mg²⁺, Ca²⁺). We have used high-resolution atomic force microscopy (AFM) to examine KirBac3.1 in two different configurations. AFM imaging of the cytoplasmic surface of KirBac3.1 embedded in a lipid bilayer has allowed visualization of the tetrameric assembly of the ligand-binding domain. In the absence of Mg²⁺, the four subunits appeared as four protrusions surrounding a central depression corresponding to the cytoplasmic pore. They did not display 4-fold symmetry, but formed a dimer-of-dimers with 2-fold symmetry. Upon addition of Mg²⁺, a marked rearrangement of the intracellular ligand-binding domains was observed: the four protrusions condensed into a single protrusion per tetramer, and there was an accompanying increase in protrusion height. The central cavity within the four intracellular domains also disappeared on addition of Mg²⁺, indicating constriction of the cytoplasmic pore. These structural changes are likely transduced to the transmembrane helices, which gate the K⁺ channel. This is the first time AFM has been used as an interactive tool to study K⁺ channels. It has enabled us to directly measure the conformational changes in the protein surface produced by ligand binding.