Pore collapse underlies irreversible inactivation of TRPM2 cation channel currents

The Ca(2+)-permeable cation channel transient receptor potential melastatin 2 (TRPM2) plays a key role in pathogen-evoked phagocyte activation, postischemic neuronal apoptosis, and glucose-evoked insulin secretion, by linking these cellular responses to oxidative stress. TRPM2 channels are coactivated by binding of intracellular ADP ribose and Ca(2+) to distinct cytosolically accessible sites on the channels. These ligands likely regulate the activation gate, conserved in the voltage-gated cation channel superfamily, that comprises a helix bundle formed by the intracellular ends of transmembrane helix six of each subunit. For several K(+) and TRPM family channels, activation gate opening requires the presence of phosphatidylinositol-bisphosphate (PIP(2)) in the inner membrane leaflet. Most TRPM family channels inactivate upon prolonged stimulation in inside-out patches; this "rundown" is due to PIP(2) depletion. TRPM2 currents also run down within minutes, but the molecular mechanism of this process is unknown. Here we report that high-affinity PIP(2) binding regulates Ca(2+) sensitivity of TRPM2 activation. Nevertheless, TRPM2 inactivation is not due to PIP(2) depletion; rather, it is state dependent, sensitive to permeating ions, and can be completely prevented by mutations in the extracellular selectivity filter. Introduction of two negative charges plus a single-residue insertion, to mimic the filter sequence of TRPM5, results in TRPM2 channels that maintain unabated maximal activity for over 1 h, and display altered permeation properties but intact ADP ribose/Ca(2+)-dependent gating. Thus, upon prolonged stimulation, the TRPM2 selectivity filter undergoes a conformational change reminiscent of that accompanying C-type inactivation of voltage-gated K(+) channels. The noninactivating TRPM2 variant will be invaluable for gating studies.     

Proton and cation transport activity of the M2 proton channel from influenza A virus

The M2 protein is a small, single-span transmembrane (TM) protein from the influenza A virus. This virus enters cells via endosomes; as the endosomes mature and become more acidic M2 facilitates proton transport into the viral interior, thereby disrupting matrix protein/RNA interactions required for infectivity. A mystery has been how protons can accumulate in the viral interior without developing a large electrical potential that impedes further inward proton translocation. Progress in addressing this question has been limited by the availability of robust methods of unidirectional insertion of the protein into virus-like vesicles. Using an optimized procedure for reconstitution, we show that M2 has antiporter-like activity, facilitating K⁺ or Na⁺ efflux when protons flow down a concentration gradient into the vesicles. Cation efflux is very small except under conditions mimicking those encountered by the endosomally entrapped virus, in which protons are flowing through the channel. This proton/cation exchange function is consistent with the known high proton selectivity of the channel. Thus, M2 acts as a proton uniporter that occasionally allows K⁺ to flow to maintain electrical neutrality. Remarkably, as the pH inside M2-containing vesicles (pH_in) decreases, the proton channel activity of M2 is inhibited, but its cation transport activity is activated. This reciprocal inhibition of proton flux and activation of cation flux with decreasing pH_in first allows accumulation of protons in the early stages of acidification, then trapping of protons within the virus when low pH_in is achieved.     

TRPM5 is a transient Ca2+-activated cation channel responding to rapid changes in [Ca2+]i

Transient receptor potential (TRP) proteins are a diverse family of proteins with structural features typical of ion channels. TRPM5, a member of the TRPM subfamily, plays an important role in taste receptors, although its activation mechanism remains controversial and its function in signal transduction is unknown. Here we characterize the functional properties of heterologously expressed human TRPM5 in HEK-293 cells. TRPM5 displays characteristics of a calcium-activated, nonselective cation channel with a unitary conductance of 25 pS. TRPM5 is a monovalent-specific, nonselective cation channel that carries Na+, K+, and Cs+ ions equally well, but not Ca2+ ions. It is directly activated by [Ca2+]i at concentrations of 0.3-1 microM, whereas higher concentrations are inhibitory, resulting in a bell-shaped dose-response curve. It activates and deactivates rapidly even during sustained elevations in [Ca2+]i, thereby inducing a transient membrane depolarization. TRPM5 does not simply mirror levels of [Ca2+]i, but instead responds to the rate of change in [Ca2+]i in that it requires rapid changes in [Ca2+]i to generate significant whole-cell currents, whereas slow elevations in [Ca2+]i to equivalent levels are ineffective. Moreover, we demonstrate that TRPM5 is not limited to taste signal transduction, because we detect the presence of TRPM5 in a variety of tissues and we identify endogenous TRPM5-like currents in a pancreatic beta cell line. TRPM5 can be activated physiologically by inositol 1,4,5-trisphosphate-producing receptor agonists, and it may therefore couple intracellular Ca2+ release to electrical activity and subsequent cellular responses.     

Preferential use of unobstructed lateral portals as the access route to the pore of human ATP-gated ion channels (P2X receptors)

P2X receptors are trimeric cation channels with widespread roles in health and disease. The recent crystal structure of a P2X4 receptor provides a 3D view of their topology and architecture. A key unresolved issue is how ions gain access to the pore, because the structure reveals two different pathways within the extracellular domain. One of these is the central pathway spanning the entire length of the extracellular domain and covering a distance of ≈70 Å. The second consists of three lateral portals, adjacent to the membrane and connected to the transmembrane pore by short tunnels. Here, we demonstrate the preferential use of the lateral portals. Owing to their favorable diameters and equivalent spacing, the lateral portals split the task of ion supply threefold and minimize an ion''s diffusive path before it succumbs to transmembrane electrochemical gradients.     

Normal gating of CFTR requires ATP binding to both nucleotide-binding domains and hydrolysis at the second nucleotide-binding domain

ATP interacts with the two nucleotide-binding domains (NBDs) of CFTR to control gating. However, it is unclear whether gating involves ATP binding alone, or also involves hydrolysis at each NBD. We introduced phenylalanine residues into nonconserved positions of each NBD Walker A motif to sterically prevent ATP binding. These mutations blocked [alpha-(32)P]8-N(3)-ATP labeling of the mutated NBD and reduced channel opening rate without changing burst duration. Introducing cysteine residues at these positions and modifying with N-ethylmaleimide produced the same gating behavior. These results indicate that normal gating requires ATP binding to both NBDs, but ATP interaction with one NBD is sufficient to support some activity. We also studied mutations of the conserved Walker A lysine residues (K464A and K1250A) that prevent hydrolysis. By combining substitutions that block ATP binding with Walker A lysine mutations, we could differentiate the role of ATP binding vs. hydrolysis at each NBD. The K1250A mutation prolonged burst duration; however, blocking ATP binding prevented the long bursts. These data indicate that ATP binding to NBD2 allowed channel opening and that closing was delayed in the absence of hydrolysis. The corresponding NBD1 mutations showed relatively little effect of preventing ATP hydrolysis but a large inhibition of blocking ATP binding. These data suggest that ATP binding to NBD1 is required for normal activity but that hydrolysis has little effect. Our results suggest that both NBDs contribute to channel gating, NBD1 binds ATP but supports little hydrolysis, and ATP binding and hydrolysis at NBD2 are key for normal gating.     

Expression and regulation of transient receptor potential cation channel,subfamily M,member 2 (TRPM2) in human endometrium

To identify estrogen-responsive genes, we previously isolated estrogen receptor (ER)-binding DNA fragments from human genomic DNA using a recombinant ER protein. Six DNA fragments, each including a perfect palindromic estrogen response element (ERE), were obtained. The nucleotide sequence of one of the six fragments (E1 fragment) showed that the ERE of the E1 fragment is located in the 3′-untranslated region (UTR) of transient receptor potential cation channel, subfamily M, member 2 (TRPM2). Here, we confirmed the estrogen-dependent enhancer activity of the ERE of the E1 fragment by chloramphenicol acetyltransferase assay. TRPM2 mRNA expression was investigated in human endometrium, cultured human endometrial stromal cells (ESCs), and cultured human endometrial epithelial cells (EECs) using RT-PCR. Quantitative RT-PCR revealed that TRPM2 mRNA expression in ESCs increased after 17β-estradiol (E2) treatment. This study demonstrated for the first time that TRPM2 is an estrogen-responsive gene expressed in human endometrial cells.     

Cytoplasmic cAMP-sensing domain of hyperpolarization-activated cation (HCN) channels uses two structurally distinct mechanisms to regulate voltage gating

Voltage gating of hyperpolarization-activated cation (HCN) channels is potentiated by direct binding of cAMP to a cytoplasmic cAMP-sensing domain (CSD). When unliganded, the CSD inhibits hyperpolarization-dependent opening of the HCN channel gate; cAMP binding relieves this autoinhibition so that opening becomes more favorable thermodynamically. This autoinhibition-relief mechanism is conserved with that of several other cyclic nucleotide receptors using the same ligand-binding fold. Besides its thermodynamic effect, cAMP also modulates the depolarization-dependent deactivation rate by kinetically trapping channels in an open state. Here we report studies of strong open-state trapping in an HCN channel showing that the well-established autoinhibition-relief model is insufficient. Whereas deletion of the CSD mimics the thermodynamic open-state stabilization usually associated with cAMP binding, CSD deletion removes rather than mimics the kinetic effect of strong open-state trapping. Substitution of different CSD sequences leads to variation of the degree of open-state trapping in the liganded channel but not in the unliganded channel. CSD-dependent open-state trapping is observed during a voltage-dependent deactivation pathway, specific to the secondary open state that is formed by mode shift after prolonged hyperpolarization activation. This hysteretic activation-deactivation cycle is preserved by CSD substitution, but the change in deactivation kinetics of the liganded channel resulting from CSD substitution is not correlated with the change in autoinhibition properties. Thus the liganded and the unliganded forms of the CSD respectively provide the structural determinants for open-state trapping and autoinhibition, such that two distinct mechanisms for cAMP regulation can operate in one receptor.     

Activation of the Ca(2+)-activated nonselective cation channel by diacylglycerol analogues in rat cardiomyocytes

INTRODUCTION: Cardiac hypertrophy is associated with changes in electrophysiologic properties due to ionic channel modifications and increases in protein kinase C (PKC) activity and diacylglycerol (DAG) content. These changes may contribute to an increased propensity for arrhythmia. Similar electrophysiologic modifications have been reported in adult rat cardiomyocytes undergoing dedifferentiation in primary culture. METHODS AND RESULTS: Single-channel measurements on such cells identified the appearance of a Ca(2+)-activated nonselective cation channel (NSC(Ca)) during the dedifferentiation process. The current study investigated the sensitivity of this channel to PKC and DAG analogues. In the cell-attached configuration, channel conductance was 20.2 pS under physiologic conditions. Perfusion with the DAG analogue 1-oleoyl-2-acetyl-sn-glycerol (OAG, 0.1 mM) or the PKC activator phorbol 12-myristate 13-acetate (PMA, 0.5 microM) increased the channel normalized open probability (nPo), whereas in the presence of the PKC inhibitor calphostin C (1 microM), only OAG retained this effect. In the inside-out configuration, perfusion of both DAG analogues OAG (0.1 mM) and 1-stearoyl-2-arachidonoyl-sn-glycerol (SAG, 10 microM) on the inside of the membrane increased nPo. These results indicate that DAG regulates the NSC(Ca) channel via both the PKC pathway and by a direct interaction. CONCLUSION: DAG content, PKC activity, and channel expression increased during hypertrophy. This indicates that the NSC(Ca) channel exhibits high activity in this condition and, therefore, is a candidate for the genesis of arrhythmias in ventricular cardiomyocytes. In addition, regulation of the channel by DAG and PKC contributes to current understanding of the physiologic role of this channel, which shares properties with the cloned TRPM4b channel.     

Regulation of cardiac calcium channel current and contractile activity by the dihydropyridine Bay K 8644 is voltage-dependent

Pharmacological studies have provided considerable information about the molecular structure of ion channels in the membranes of excitable cells. Two classes of drugs, the local anesthetics and the biotoxins, have been used to study sodium channels in nerve, skeletal muscle, and cardiac cells, and tetraethylammonium ion and many of its derivatives have provided structural information about potassium channels in nerve. More recently, organic compounds that block calcium channels (calcium channel antagonists) have begun to be used to probe calcium channels in cardiac and smooth muscle cells (see). One group of calcium channel blockers, the dihydropyridines, has provided considerable information on the structure and function of these channels on the basis of electrophysiological and binding studies. Slight modification of the structure of one of these dihydropyridines, nifedipine, has led to the discovery of a group of compounds that are presumed to act by increasing the influx of Ca2+ into cardiac and smooth muscle cells. One of these novel compounds, Bay K 8644 (methyl 1,4-dihydro-2,6-dimethyl-3-nitro-4-(2-trifluoromethylphenyl)-pyridine-5 carboxylate) has been reported to act at the same receptor site as the calcium channel antagonist nifedipine, but enhances contractile activity of the perfused heart and aortic strips. Because activation of contraction in cardiac muscle is closely linked to calcium entry via voltage-dependent calcium channels (see for review) these results suggested that Bay K 8644 might act on these channels.     

From the Cover: An uncoupling channel within the c-subunit ring of the F1FO ATP synthase is the mitochondrial permeability transition pore

Mitochondria maintain tight regulation of inner mitochondrial membrane (IMM) permeability to sustain ATP production. Stressful events cause cellular calcium (Ca²⁺) dysregulation followed by rapid loss of IMM potential known as permeability transition (PT), which produces osmotic shifts, metabolic dysfunction, and cell death. The molecular identity of the mitochondrial PT pore (mPTP) was previously unknown. We show that the purified reconstituted c-subunit ring of the F_O of the F₁F_O ATP synthase forms a voltage-sensitive channel, the persistent opening of which leads to rapid and uncontrolled depolarization of the IMM in cells. Prolonged high matrix Ca²⁺ enlarges the c-subunit ring and unhooks it from cyclophilin D/cyclosporine A binding sites in the ATP synthase F₁, providing a mechanism for mPTP opening. In contrast, recombinant F₁ beta-subunit applied exogenously to the purified c-subunit enhances the probability of pore closure. Depletion of the c-subunit attenuates Ca²⁺-induced IMM depolarization and inhibits Ca²⁺ and reactive oxygen species-induced cell death whereas increasing the expression or single-channel conductance of the c-subunit sensitizes to death. We conclude that a highly regulated c-subunit leak channel is a candidate for the mPTP. Beyond cell death, these findings also imply that increasing the probability of c-subunit channel closure in a healthy cell will enhance IMM coupling and increase cellular metabolic efficiency.Mitochondria produce ATP by oxidative phosphorylation (OXPHOS). Leak currents in the inner mitochondrial membrane (IMM) reduce the efficiency of this process by uncoupling the electron transport system from ATP synthase activity. Many studies have described the biophysical and pharmacological features of an IMM pore [the mitochondrial permeability transition pore (mPTP)] that is responsible for a rapid IMM uncoupling, causing osmotic shifts within the mitochondrial matrix in the setting of cellular Ca²⁺ dysregulation and adenine nucleotide depletion (1–4). Some studies suggest that such uncoupling also functions during physiological events and that the mPTP may transiently operate as a Ca²⁺-release channel (5–7). Although models for the molecular identity of the mPTP have been proposed (8), deletions of putative components, such as adenine nucleotide translocase (ANT) and the voltage-dependent anion channel (VDAC), have failed to prevent rapid depolarizations (9). In the meantime, nonpore forming regulatory components of the mPTP, such as cyclophilin D (CypD), have been extensively investigated (10, 11).We recently reported a leak conductance sensitive to ATP/ADP and the Bcl-2 family member B-cell lymphoma-extra large (Bcl-x_L) within the membrane of isolated submitochondrial vesicles (SMVs) enriched in ATP synthase (12, 13). We demonstrated binding of Bcl-x_L within F₁ to the beta-subunit of the ATP synthase, suggesting that the channel responsible for the leak conductance lies within the membrane portion (ATP synthase F_O) and that Bcl-x_L binding to F₁ might close the leak. Recent studies also support the idea that the mPTP is located within the multiprotein–lipid complex of the ATP synthase (10, 14, 15); however, a review of these articles confirms that the specific protein responsible for pore formation remains undetermined (16). We now describe that the purified c-subunit of the mammalian ATP synthase, when reconstituted into liposomes, forms a voltage-dependent channel sensitive to adenine nucleotides, recombinant F₁ beta-subunit protein, and anti–c-subunit antibodies. In cells, fluorescent labeling of the c-subunit detects ring opening and closing in response to Ca²⁺ and the mPTP inhibitor cyclosporine A (CsA). C-subunit single-channel conductance is increased by permanent loosening of the c-subunit ring structure by specific mutagenesis, promoting cell death. In contrast, depletion of the c-subunit in cells inhibits Ca²⁺-induced IMM depolarization and cell death. Finally, we show that high matrix Ca²⁺ dissociates the c-subunit ring from the ATP synthase enzyme in F₁, providing a mechanism for PT.     

The RCK2 domain of the human BKCa channel is a calcium sensor

Large conductance voltage and Ca(2+)-dependent K(+) channels (BK(Ca)) are activated by both membrane depolarization and intracellular Ca(2+). Recent studies on bacterial channels have proposed that a Ca(2+)-induced conformational change within specialized regulators of K(+) conductance (RCK) domains is responsible for channel gating. Each pore-forming alpha subunit of the homotetrameric BK(Ca) channel is expected to contain two intracellular RCK domains. The first RCK domain in BK(Ca) channels (RCK1) has been shown to contain residues critical for Ca(2+) sensitivity, possibly participating in the formation of a Ca(2+)-binding site. The location and structure of the second RCK domain in the BK(Ca) channel (RCK2) is still being examined, and the presence of a high-affinity Ca(2+)-binding site within this region is not yet established. Here, we present a structure-based alignment of the C terminus of BK(Ca) and prokaryotic RCK domains that reveal the location of a second RCK domain in human BK(Ca) channels (hSloRCK2). hSloRCK2 includes a high-affinity Ca(2+)-binding site (Ca bowl) and contains similar secondary structural elements as the bacterial RCK domains. Using CD spectroscopy, we provide evidence that hSloRCK2 undergoes a Ca(2+)-induced change in conformation, associated with an alpha-to-beta structural transition. We also show that the Ca bowl is an essential element for the Ca(2+)-induced rearrangement of hSloRCK2. We speculate that the molecular rearrangements of RCK2 likely underlie the Ca(2+)-dependent gating mechanism of BK(Ca) channels. A structural model of the heterodimeric complex of hSloRCK1 and hSloRCK2 domains is discussed.     

Structure of the EF-hand domain of polycystin-2 suggests a mechanism for Ca2+-dependent regulation of polycystin-2 channel activity

The C-terminal cytoplasmic tail of polycystin-2 (PC2/TRPP2), a Ca²⁺-permeable channel, is frequently mutated or truncated in autosomal dominant polycystic kidney disease. We have previously shown that this tail consists of three functional regions: an EF-hand domain (PC2-EF, 720–797), a flexible linker (798–827), and an oligomeric coiled coil domain (828–895). We found that PC2-EF binds Ca²⁺ at a single site and undergoes Ca²⁺-dependent conformational changes, suggesting it is an essential element of Ca²⁺-sensitive regulation of PC2 activity. Here we describe the NMR structure and dynamics of Ca²⁺-bound PC2-EF. Human PC2-EF contains a divergent non-Ca²⁺-binding helix-loop-helix (HLH) motif packed against a canonical Ca²⁺-binding EF-hand motif. This HLH motif may have evolved from a canonical EF-hand found in invertebrate PC2 homologs. Temperature-dependent steady-state NOE experiments and NMR R₁ and R₂ relaxation rates correlate with increased molecular motion in the EF-hand, possibly due to exchange between apo and Ca²⁺-bound states, consistent with a role for PC2-EF as a Ca²⁺-sensitive regulator. Structure-based sequence conservation analysis reveals a conserved hydrophobic surface in the same region, which may mediate Ca²⁺-dependent protein interactions. We propose that Ca²⁺-sensing by PC2-EF is responsible for the cooperative nature of PC2 channel activation and inhibition. Based on our results, we present a mechanism of regulation of the Ca²⁺ dependence of PC2 channel activity by PC2-EF.     

Biphasic regulation of InsP3 receptor gating by dual Ca2+ release channel BH3-like domains mediates Bcl-xL control of cell viability

Antiapoptotic Bcl-2 family members interact with inositol trisphosphate receptor (InsP₃R) Ca²⁺ release channels in the endoplasmic reticulum to modulate Ca²⁺ signals that affect cell viability. However, the molecular details and consequences of their interactions are unclear. Here, we found that Bcl-x_L activates single InsP₃R channels with a biphasic concentration dependence. The Bcl-x_L Bcl-2 homology 3 (BH3) domain-binding pocket mediates both high-affinity channel activation and low-affinity inhibition. Bcl-x_L activates channel gating by binding to two BH3 domain-like helices in the channel carboxyl terminus, whereas inhibition requires binding to one of them and to a previously identified Bcl-2 interaction site in the channel-coupling domain. Disruption of these interactions diminishes cell viability and sensitizes cells to apoptotic stimuli. Our results identify BH3-like domains in an ion channel and they provide a unifying model of the effects of antiapoptotic Bcl-2 proteins on the InsP₃R that play critical roles in Ca²⁺ signaling and cell viability.The inositol trisphosphate receptors (InsP₃R) are a family of intracellular cation channels that release Ca²⁺ from the endoplasmic reticulum (ER) in response to a variety of extracellular stimuli (1). Three InsP₃R isoforms are ubiquitously expressed and regulate diverse cell processes, including cell viability (1). Activation of the channels by InsP₃ elicits changes in cytoplasmic Ca²⁺ concentration ([Ca²⁺]_i) that provide versatile signals to regulate molecular processes with high spatial and temporal fidelity (1). Regions of close proximity to mitochondria enable localized Ca²⁺ release events to be transduced to mitochondria (2, 3). Ca²⁺ released from the ER during cell stimulation modulates activities of effector molecules and is taken up by mitochondria to stimulate oxidative phosphorylation and enhance ATP production (4–6) to match energetic supply with enhanced demand. In addition, cells in vivo are constantly exposed to low levels of circulating hormones, transmitters, and growth factors that bind to plasma membrane receptors to provide a background level of cytoplasmic InsP₃ (7) that generates low-level stochastic InsP₃R-mediated localized or propagating [Ca²⁺]_i signals (8–10). Such signals also play an important role in maintenance of cellular bioenergetics (8). Nevertheless, under conditions of cell stress the close proximity of mitochondria to Ca²⁺ release sites may result in mitochondrial Ca²⁺ overload and initiate Ca²⁺-dependent forms of cell death, including necrosis and apoptosis (11–13). It has been suggested that high levels of ER Ca²⁺ (14–16) and enhanced activity of the InsP₃R (17–19) promote cell death by providing a higher quantity of released Ca²⁺ to mitochondria (3, 20, 21).Protein interactions modulate the magnitude and quality of InsP₃R-mediated [Ca²⁺]_i signals that regulate apoptosis and cell viability. Notable in this regard is the Bcl-2 protein family. Proapoptotic Bcl-2–related proteins Bax and Bak initiate cytochrome C release from mitochondria in response to diverse apoptotic stimuli, whereas antiapoptotic Bcl-2–related proteins, including Bcl-2 and Bcl-x_L, antagonize Bax/Bak by forming heterodimers that prevent their oligomerization and apoptosis initiation (22, 23). Heterodimerization is mediated by interactions of proapoptotic Bcl-2 homology 3 (BH3) domains with a hydrophobic groove on the surface of antiapoptotic Bcl-2 proteins (23) that is a therapeutic target in diseases, including cancer (22). Whereas a central feature of molecular models of apoptosis is the control of outer mitochondrial membrane permeability by Bcl-2–related proteins, a substantial body of evidence has demonstrated that these proteins localize to the ER (24, 25), bind to InsP₃Rs (26–32) and, by modulating InsP₃R-mediated Ca²⁺ release, regulate ER-mediated cell death and survival (15, 27, 32–34). Nevertheless, a unified understanding of the detailed molecular mechanisms by which Bcl-2 family proteins interact with and regulate InsP₃R channel activity is lacking. The Bcl-2 family member homolog NrZ interacts with the amino-terminal InsP₃-binding region via its helix 1 BH4 domain and inhibits Ca²⁺ release (28). Bcl-2 also interacts with the InsP₃R (26) via its BH4 domain (35), but in contrast it associates with a region in the central coupling domain (35). Whereas this interaction also inhibits Ca²⁺ release (26), Bok interacts with the channel 500 residues C-terminal to the Bcl-2 binding sequence via its BH4 domain but does not affect Ca²⁺ release (29). Conversely, the Bcl-x_L BH4 domain may lack this interaction (36). Inhibition of the Bcl-2 BH4 domain interaction with the channel enhanced InsP₃R-mediated Ca²⁺ signals and apoptosis sensitivity in white blood cells (18, 35, 37). However, it is unclear if Bcl-2 inhibits Ca²⁺ signaling directly by binding to the channel or if it acts indirectly, as a hub in a protein complex that influences channel phosphorylation (38). Conversely, we demonstrated that Bcl-x_L, Bcl-2, and Mcl-1 bind to the carboxyl (C)-terminus of all three InsP₃R isoforms, and showed that these interactions activated single InsP₃R channels and promoted InsP₃R-mediated Ca²⁺ release and apoptosis resistance (27, 31, 32). Furthermore, Bcl-x_L mediates an interaction of oncogenic K-RAS with the InsP₃R C terminus that regulates its biochemical and functional interaction and cell survival (39). However, the molecular details of the interactions of antiapoptotic protein with the InsP₃R C terminus are unknown. Furthermore, the relationship between Bcl-2 family protein binding in the coupling domain and C terminus is unclear. Thus, the mechanisms whereby Bcl-2 and Bcl-x_L affect InsP₃R activity and the effects of this modulation on cell viability remain to be determined.Here, we used single-channel electrophysiology of native ER membranes to explore the detailed mechanisms of the effects of Bcl-x_L on the InsP₃R, and the role of this interaction on cell viability. Surprisingly, our results reveal that whereas Bcl-x_L activates the channel at low concentrations, it inhibits it at higher concentrations, resulting in a biphasic response of channel activation on [Bcl-x_L]. Remarkably, the Bcl-x_L BH3 domain-binding pocket is required for both effects. Low [Bcl-x_L] activates the channel by simultaneous binding to two BH3 domain-like helices in the channel C terminus, whereas channel inhibition at high [Bcl-x_L] requires binding to only one of them and to a site previously identified as the Bcl-2 binding site in the channel-coupling domain. Disruption of these interactions diminishes cell viability. Our results provide a unifying model of the effects of antiapoptotic Bcl-2 proteins on the InsP₃R that play critical roles in Ca²⁺ signaling and cell viability.     

The glutamate receptor subunit delta2 is capable of gating its intrinsic ion channel as revealed by ligand binding domain transplantation

The family of ionotropic glutamate receptors includes 2 subunits, delta1 and delta2, the physiological relevance of which remains poorly understood. Both are nonfunctional in heterologous expression systems, although the isolated, crystallized ligand binding domain (LBD) of delta2 is capable of binding D-serine. To investigate these seemingly contradictory observations we tested whether delta receptors can be ligand gated at all. We used a strategy that replaced the native LBD of delta2 by a proven glutamate-binding LBD. Test transplantations between α-amino-3-hydroxy-5-methylisoxazole propionate (AMPA) and kainate receptors (GluR1 and GluR6, respectively) showed that this approach can produce functional chimeras even if only one part of the bipartite LBD is swapped. Upon outfitting delta2 with the LBD of GluR6, the chimera formed glutamate-gated ion channels with low Ca²⁺ permeability and unique rectification properties. Ligand-induced conformational changes can thus gate delta2, suggesting that the LBD of this receptor works fundamentally differently from that of other ionotropic glutamate receptors.     

Cyclic nucleotide-gated channel 18 is an essential Ca2+ channel in pollen tube tips for pollen tube guidance to ovules in Arabidopsis

In flowering plants, pollen tubes are guided into ovules by multiple attractants from female gametophytes to release paired sperm cells for double fertilization. It has been well-established that Ca²⁺ gradients in the pollen tube tips are essential for pollen tube guidance and that plasma membrane Ca²⁺ channels in pollen tube tips are core components that regulate Ca²⁺ gradients by mediating and regulating external Ca²⁺ influx. Therefore, Ca²⁺ channels are the core components for pollen tube guidance. However, there is still no genetic evidence for the identification of the putative Ca²⁺ channels essential for pollen tube guidance. Here, we report that the point mutations R491Q or R578K in cyclic nucleotide-gated channel 18 (CNGC18) resulted in abnormal Ca²⁺ gradients and strong pollen tube guidance defects by impairing the activation of CNGC18 in Arabidopsis. The pollen tube guidance defects of cngc18-17 (R491Q) and of the transfer DNA (T-DNA) insertion mutant cngc18-1 (+/−) were completely rescued by CNGC18. Furthermore, domain-swapping experiments showed that CNGC18’s transmembrane domains are indispensable for pollen tube guidance. Additionally, we found that, among eight Ca²⁺ channels (including six CNGCs and two glutamate receptor-like channels), CNGC18 was the only one essential for pollen tube guidance. Thus, CNGC18 is the long-sought essential Ca²⁺ channel for pollen tube guidance in Arabidopsis.Pollen tubes deliver paired sperm cells into ovules for double fertilization, and signaling communication between pollen tubes and female reproductive tissues is required to ensure the delivery of sperm cells into the ovules (1). Pollen tube guidance is governed by both female sporophytic and gametophytic tissues (2, 3) and can be separated into two categories: preovular guidance and ovular guidance (1). For preovular guidance, diverse signaling molecules from female sporophytic tissues have been identified, including the transmitting tissue-specific (TTS) glycoprotein in tobacco (4), γ-amino butyric acid (GABA) in Arabidopsis (5), and chemocyanin and the lipid transfer protein SCA in Lilium longiflorum (6, 7). For ovular pollen tube guidance, female gametophytes secrete small peptides as attractants, including LUREs in Torenia fournieri (8) and Arabidopsis (9) and ZmEA1 in maize (10, 11). Synergid cells, central cells, egg cells, and egg apparatus are all involved in pollen tube guidance, probably by secreting different attractants (9–15). Additionally, nitric oxide (NO) and phytosulfokine peptides have also been implicated in both preovular and ovular pollen tube guidance (16–18). Thus, pollen tubes could be guided by diverse attractants in a single plant species.Ca²⁺ gradients at pollen tube tips are essential for both tip growth and pollen tube guidance (19–27). Spatial modification of the Ca²⁺ gradients leads to the reorientation of pollen tube growth in vitro (28, 29). The Ca²⁺ gradients were significantly increased in pollen tubes attracted to the micropyles by synergid cells in vivo, compared with those not attracted by ovules (30). Therefore, the Ca²⁺ gradients in pollen tube tips are essential for pollen tube guidance. The Ca²⁺ gradients result from external Ca²⁺ influx, which is mainly mediated by plasma membrane Ca²⁺ channels in pollen tube tips. Thus, the Ca²⁺ channels are the key components for regulating the Ca²⁺ gradients and are consequently essential for pollen tube guidance. Using electrophysiological techniques, inward Ca²⁺ currents were observed in both pollen grain and pollen tube protoplasts (31–36), supporting the presence of plasma membrane Ca²⁺ channels in pollen tube tips. Recently, a number of candidate Ca²⁺ channels were identified in pollen tubes, including six cyclic nucleotide-gated channels (CNGCs) and two glutamate receptor-like channels (GLRs) in Arabidopsis (37–40). Three of these eight channels, namely CNGC18, GLR1.2, and GLR3.7, were characterized as Ca²⁺-permeable channels (40, 41) whereas the ion selectivity of the other five CNGCs has not been characterized. We hypothesized that the Ca²⁺ channel essential for pollen tube guidance could be among these eight channels.In this research, we first characterized the remaining five CNGCs as Ca²⁺ channels. We further found that CNGC18, out of the eight Ca²⁺ channels, was the only one essential for pollen tube guidance in Arabidopsis and that its transmembrane domains were indispensable for pollen tube guidance.     

Functional studies indicate amantadine binds to the pore of the influenza A virus M2 proton-selective ion channel

Influenza A and B viruses contain proton-selective ion channels, A/M2 and BM2, respectively, and the A/M2 channel activity is inhibited by the drugs amantadine and its methyl derivative rimantadine. The structure of the pore-transmembrane domain has been determined by both x-ray crystallography [Stouffer et al. (2008) Nature 451:596–599] and by NMR methods [Schnell and Chou (2008) Nature 451:591–595]. Whereas the crystal structure indicates a single amantadine molecule in the pore of the channel, the NMR data show four rimantadine molecules bound on the outside of the helices toward the cytoplasmic side of the membrane. Drug binding includes interactions with residues 40–45 with a polar hydrogen bond between rimantadine and aspartic acid residue 44 (D44) that appears to be important. These two distinct drug-binding sites led to two incompatible drug inhibition mechanisms. We mutagenized D44 and R45 to alanine as these mutations are likely to interfere with rimantadine binding and lead to a drug insensitive channel. However, the D44A channel was found to be sensitive to amantadine when measured by electrophysiological recordings in oocytes of Xenopus laevis and in mammalian cells, and when the D44 and R45 mutations were introduced into the influenza virus genome. Furthermore, transplanting A/M2 pore residues 24–36 into BM2, yielded a pH-activated chimeric ion channel that was partially inhibited by amantadine. Thus, taken together our functional data suggest that amantadine/rimantadine binding outside of the channel pore is not the primary site associated with the pharmacological inhibition of the A/M2 ion channel.     

Calcium sensor regulation of the CaV2.1 Ca2+ channel contributes to short-term synaptic plasticity in hippocampal neurons

Short-term synaptic plasticity is induced by calcium (Ca²⁺) accumulating in presynaptic nerve terminals during repetitive action potentials. Regulation of voltage-gated Ca_V2.1 Ca²⁺ channels by Ca²⁺ sensor proteins induces facilitation of Ca²⁺ currents and synaptic facilitation in cultured neurons expressing exogenous Ca_V2.1 channels. However, it is unknown whether this mechanism contributes to facilitation in native synapses. We introduced the IM-AA mutation into the IQ-like motif (IM) of the Ca²⁺ sensor binding site. This mutation does not alter voltage dependence or kinetics of Ca_V2.1 currents, or frequency or amplitude of spontaneous miniature excitatory postsynaptic currents (mEPSCs); however, synaptic facilitation is completely blocked in excitatory glutamatergic synapses in hippocampal autaptic cultures. In acutely prepared hippocampal slices, frequency and amplitude of mEPSCs and amplitudes of evoked EPSCs are unaltered. In contrast, short-term synaptic facilitation in response to paired stimuli is reduced by ∼50%. In the presence of EGTA-AM to prevent global increases in free Ca²⁺, the IM-AA mutation completely blocks short-term synaptic facilitation, indicating that synaptic facilitation by brief, local increases in Ca²⁺ is dependent upon regulation of Ca_V2.1 channels by Ca²⁺ sensor proteins. In response to trains of action potentials, synaptic facilitation is reduced in IM-AA synapses in initial stimuli, consistent with results of paired-pulse experiments; however, synaptic depression is also delayed, resulting in sustained increases in amplitudes of later EPSCs during trains of 10 stimuli at 10–20 Hz. Evidently, regulation of Ca_V2.1 channels by CaS proteins is required for normal short-term plasticity and normal encoding of information in native hippocampal synapses.Modification of synaptic strength in central synapses is highly dependent upon presynaptic activity. The frequency and pattern of presynaptic action potentials regulates the postsynaptic response through diverse forms of short- and long-term plasticity that are specific to individual synapses and depend upon accumulation of intracellular Ca²⁺ (1–4). Presynaptic plasticity regulates neurotransmission by varying the amount of neurotransmitter released by each presynaptic action potential (1–5). P/Q-type Ca²⁺ currents conducted by voltage-gated Ca_V2.1 Ca²⁺ channels initiate neurotransmitter release at fast excitatory glutamatergic synapses in the brain (6–9) and regulate short-term presynaptic plasticity (3, 10). These channels exhibit Ca²⁺-dependent facilitation and inactivation that is mediated by the Ca²⁺ sensor (CaS) protein calmodulin (CaM) bound to a bipartite site in their C-terminal domain composed of an IQ-like motif (IM) and a CaM binding domain (CBD) (11–14). Ca²⁺-dependent facilitation and inactivation of P/Q-type Ca²⁺ currents correlate with facilitation and rapid depression of synaptic transmission at the Calyx of Held (15–18). Elimination of Ca_V2.1 channels by gene deletion prevents facilitation of synaptic transmission at the Calyx of Held (19, 20). Cultured sympathetic ganglion neurons with presynaptic expression of exogenous Ca_V2.1 channels harboring mutations in their CaS regulatory site have reduced facilitation and slowed depression of postsynaptic responses because of reduced Ca²⁺-dependent facilitation and Ca²⁺-dependent inactivation of Ca_V2.1 currents (21). The CaS proteins Ca²⁺-binding protein 1 (CaBP-1), visinin-like protein-2 (VILIP-2), and neuronal Ca²⁺ sensor-1 (NCS-1) induce different degrees of Ca²⁺-dependent facilitation and inactivation of channel activity (22–26). Expression of these different CaS proteins with Ca_V2.1 channels in cultured sympathetic ganglion neurons results in corresponding bidirectional changes in facilitation and depression of the postsynaptic response (25, 26). Therefore, binding of CaS proteins to Ca_V2.1 channels at specific synapses can change the balance of CaS-dependent facilitation and inactivation of Ca_V2.1 channels, and determine the outcome of synaptic plasticity (27). Currently, it is not known whether such molecular regulation of Ca_V2.1 by CaS proteins induces or modulates synaptic plasticity in native hippocampal synapses.To understand the functional role of regulation of Ca_V2.1 channels by CaS proteins in synaptic plasticity in vivo, we generated knock-in mice with paired alanine substitutions for the isoleucine and methionine residues in the IM motif (IM-AA) in their C-terminal domain. Here we investigated the effects of mutating this CaS regulatory site on hippocampal neurotransmission and synaptic plasticity. This mutation had no effect on basal Ca²⁺ channel function or on basal synaptic transmission. However, we found reduced short-term facilitation in response to paired stimuli in autaptic synapses in hippocampal cultures and in Schaffer collateral (SC)-CA1 synapses in acutely prepared hippocampal slices. Moreover, synaptic facilitation in mutant SC-CA1 synapses developed and decayed more slowly during trains of stimuli. These results identify a critical role for modulation of Ca_V2.1 channels by CaS proteins in short-term synaptic plasticity, which is likely to have important consequences for encoding and transmitting information in the hippocampus.