Hv1 Proton Channel Opening Is Preceded by a Voltage-independent Transition

The voltage sensing domain (VSD) of the voltage-gated proton channel Hv1 mediates a H⁺-selective conductance that is coordinately controlled by the membrane potential (V) and the transmembrane pH gradient (ΔpH). Allosteric control of Hv1 channel opening by ΔpH (V-ΔpH coupling) is manifested by a characteristic shift of approximately 40 mV per ΔpH unit in the activation. To further understand the mechanism for V-ΔpH coupling in Hv1, H⁺ current kinetics of activation and deactivation in excised membrane patches were analyzed as a function of the membrane potential and the pH in the intracellular side of the membrane (pH_I). In this study, it is shown for the first time to our knowledge that the opening of Hv1 is preceded by a voltage-independent transition. A similar process has been proposed to constitute the step involving coupling between the voltage-sensing and pore domains in tetrameric voltage-gated channels. However, for Hv1, the VSD functions as both the voltage sensor and the conduction pathway, suggesting that the voltage independent transition is intrinsic to the voltage-sensing domain. Therefore, this article proposes that the underlying mechanism for the activation of Hv1 involves a process similar to VSD relaxation, a process previously described for voltage-gated channels and voltage-controlled enzymes. Finally, deactivation seemingly occurs as a strictly voltage dependent process, implying that the kinetic event leading to opening of the proton conductance are different than those involved in the closing. Thus, from this work it is proposed that Hv1 activity displays hysteresis.     

Gating Currents in the Hv1 Proton Channel

The Hv1 proton channel shares striking structural homology with fourth transmembrane helical segment-type voltage-sensor (VS) domains but manifests distinctive functional properties, including a proton-selective “aqueous” conductance and allosteric control of voltage-dependent gating by changes in the transmembrane pH gradient. The mechanisms responsible for Hv1’s functional properties remain poorly understood, in part because methods for measuring gating currents that directly report VS activation have not yet been described. Here, we describe an approach that allows robust and reproducible measurement of gating-associated charge movements in Hv1. Gating currents reveal that VS activation and proton-selective aqueous conductance opening are thermodynamically distinct steps in the Hv1 activation pathway and show that pH changes directly alter VS activation. The availability of an assay for gating currents in Hv1 may aid future efforts to elucidate the molecular mechanisms of gating cooperativity, pH-dependent modulation, and H⁺ selectivity in a model VS domain protein.     

Evidence for Functional Diversity between the Voltage-Gated Proton Channel Hv1 and Its Closest Related Protein HVRP1

The Hv1 channel and voltage-sensitive phosphatases share with voltage-gated sodium, potassium, and calcium channels the ability to detect changes in membrane potential through voltage-sensing domains (VSDs). However, they lack the pore domain typical of these other channels. Na_V, K_V, and Ca_V proteins can be found in neurons and muscles, where they play important roles in electrical excitability. In contrast, VSD-containing proteins lacking a pore domain are found in non-excitable cells and are not involved in neuronal signaling. Here, we report the identification of HVRP1, a protein related to the Hv1 channel (from which the name Hv1 Related Protein 1 is derived), which we find to be expressed primarily in the central nervous system, and particularly in the cerebellum. Within the cerebellar tissue, HVRP1 is specifically expressed in granule neurons, as determined by in situ hybridization and immunohistochemistry. Analysis of subcellular distribution via electron microscopy and immunogold labeling reveals that the protein localizes on the post-synaptic side of contacts between glutamatergic mossy fibers and the granule cells. We also find that, despite the similarities in amino acid sequence and structural organization between Hv1 and HVRP1, the two proteins have distinct functional properties. The high conservation of HVRP1 in vertebrates and its cellular and subcellular localizations suggest an important function in the nervous system.     

Human Voltage-Gated Proton Channel Hv1: A New Potential Biomarker for Diagnosis and Prognosis of Colorectal Cancer

Solid tumors exist in a hypoxic microenvironment, and possess high-glycolytic metabolites. To avoid the acidosis, tumor cells must exhibit a dynamic cytosolic pH regulation mechanism(s). The voltage-gated proton channel Hv1 mediates NADPH oxidase function by compensating cellular loss of electrons with protons. Here, we showed for the first time, that Hv1 expression is increased in colorectal tumor tissues and cell lines, associated with poor prognosis. Immunohistochemistry showed that Hv1 is strongly expressed in adenocarcinomas but not or lowly expressed in normal colorectal or hyperplastic polyps. Hv1 expression in colorectal cancer is significantly associated with the tumor size, tumor classification, lymph node status, clinical stage and p53 status. High Hv1 expression is associated significantly with shorter overall and recurrence-free survival. Furthermore, real-time RT-PCR and immunocytochemistry showed that Hv1 is highly expressed in colorectal cancer cell lines, SW620, HT29, LS174T and Colo205, but not in SW480. Inhibitions of Hv1 expression and activity in the highly metastatic SW620 cells by small interfering RNA (siRNA) and Zn²⁺ respectively, markedly decrease the cell invasion and migration, restraint proton extrusion and the intracellular pH recovery. Our results suggest that Hv1 may be used as a potential biomarker for diagnosis and prognosis of colorectal carcinoma, and a potential target for anticancer drugs in colorectal cancer therapy.     

Reovirus-Induced Apoptosis Is Preceded by Increased Cellular Calpain Activity and Is Blocked by Calpain Inhibitors

The cellular pathways of apoptosis have not been fully characterized; however, calpain, a cytosolic calcium-activated cysteine protease, has been implicated in several forms of programmed cell death. Reoviruses induce apoptosis both in vitro and in vivo and serve as a model for studying virus-induced cell death. We investigated the potential role of calpain in reovirus-induced apoptosis in vitro by measuring calpain activity as well as evaluating the effects of calpain inhibitors. L929 cells were infected with reovirus type 3 Abney (T3A), and calpain activity, measured as cleavage of the fluorogenic calpain substrate Suc-Leu-Leu-Val-Tyr-AMC, was monitored. There was a 1.6-fold increase in calpain activity in T3A-infected cells compared to mock-infected cells; this increase was completely inhibited by preincubation with calpain inhibitor I (N-acetyl-leucyl-leucyl-norleucinal [aLLN]), an active-site inhibitor. Both aLLN and PD150606, a specific calpain inhibitor that interacts with the calcium-binding site, inhibited reovirus-induced apoptosis in L929 cells by 54 to 93%. Apoptosis induced by UV-inactivated reovirus was also reduced 65 to 69% by aLLN, indicating that inhibition of apoptosis by calpain inhibitors is independent of effects on viral replication. We conclude that calpain activation is a component of the regulatory cascade in reovirus-induced apoptosis.     

Pseudomonas Exotoxin A-Mediated Apoptosis Is Bak Dependent and Preceded by the Degradation of Mcl-1

Pseudomonas exotoxin A (PE) is a bacterial toxin that arrests protein synthesis and induces apoptosis. Here, we utilized mouse embryo fibroblasts (MEFs) deficient in Bak and Bax to determine the roles of these proteins in cell death induced by PE. PE induced a rapid and dose-dependent induction of apoptosis in wild-type (WT) and Bax knockout (Bax^−/−) MEFs but failed in Bak knockout (Bak^−/−) and Bax/Bak double-knockout (DKO) MEFs. Also a loss of mitochondrial membrane potential was observed in WT and Bax^−/− MEFs, but not in Bak^−/− or in DKO MEFs, indicating an effect of PE on mitochondrial permeability. PE-mediated inhibition of protein synthesis was identical in all 4 cell lines, indicating that differences in killing were due to steps after the ADP-ribosylation of EF2. Mcl-1, but not Bcl-x_L, was rapidly degraded after PE treatment, consistent with a role for Mcl-1 in the PE death pathway. Bak was associated with Mcl-1 and Bcl-x_L in MEFs and uncoupled from suppressed complexes after PE treatment. Overexpression of Mcl-1 and Bcl-x_L inhibited PE-induced MEF death. Our data suggest that Bak is the preferential mediator of PE-mediated apoptosis and that the rapid degradation of Mcl-1 unleashes Bak to activate apoptosis.Apoptosis is a mode of cell death utilized by multicellular organisms to remove unwanted cells. Also, many different cancer treatments, including chemotherapy and radiotherapy, induce apoptosis and result in the destruction of tumor cells. In some cases, apoptosis resistance can contribute to the failure of chemotherapy (14, 20, 24). Immunotoxins are a class of antitumor agents in which a powerful protein toxin is brought to the cancer cell by an antibody or an antibody fragment (for reviews, see references 28, 29, and 32). Several immunotoxins are currently in clinical trials, and one of these, BL22, targeting CD22, has shown excellent activity in drug-resistant hairy-cell leukemia (18, 19). Also, a fusion protein in which a fragment of diphtheria toxin is fused to the cytokine interleukin 2 (IL-2) (Ontak) is approved for the treatment of cutaneous T-cell lymphoma (26). Several studies carried out to determine how protein toxins and immunotoxins containing these toxins kill target cells have reported caspase activation (13, 16, 17, 30, 33). However, the steps leading up to caspase activation by these toxins that inhibit protein synthesis have not been elucidated.Bcl-2 family members are essential regulators of the mitochondrial (intrinsic) apoptosis pathway (1, 21). Proteins of this family have been divided into pro- and antiapoptotic proteins. Antiapoptotic proteins include the multi-Bcl-2 homology (BH) domain proteins Bcl-2, Bcl-x_L, Bcl-w, Mcl-1, Bcl-b, and Bcl2a1. Proapoptotic members can be further classified into two subfamilies, the multi-BH domain Bax homologues, including Bax, Bak, and Bok, and the BH3-only proteins, including Nbk/Bik, Noxa, Hrk, Bad, Bim, Puma, and Bmf. Bax and Bak are the most extensively studied central mediators in the mitochondrial apoptosis pathway (4, 6). Various stimuli, including pathogens, toxic drugs, irradiation, and starvation, induce a conformational change and activation of Bak/Bax, usually via BH3-only proapoptosis proteins. This results in the disruption of mitochondrial membranes and the release of apoptotic factors, such as cytochrome c, SMAC, and apoptosis-inducing factor, which lead to the activation of effector caspases (5, 37, 40, 42, 43).The roles of Bax and Bak can be redundant or nonredundant, depending on the apoptotic stimuli. Bak and Bax can compensate for each other in apoptosis induced by staurosporine, etoposide, UV irradiation, serum deprivation, tBid, Bim, Bad, or Noxa (37, 43). Bak plays an essential role for apoptosis induced by Semliki Forest virus, gliotoxin, Bcl-x_S, and vinblastine (22, 27, 34, 35), while Bax is favored for apoptosis induced by Nbk/Nik, a combination of tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) and ionizing irradiation, or TRAIL and 5-fluorouracil (5-FU) (9, 10, 36, 38). Silencing of either Bak or Bax resulted in resistance to apoptosis induced by Neisseria gonorrhoeae and cisplatin (15). Sometimes the same stimulus may result in different outcomes in different cell types. NBK/Bik mediated Bax-dependent cell death in one study (9), while in another study, NBK/Bik activated BAK-mediated apoptosis (31).In the current study, we utilized mutant mouse embryo fibroblasts (MEFs) deficient in Bak, Bax, or both proteins and provided evidence for an essential role of Bak in apoptosis induced by Pseudomonas exotoxin A (PE) and other protein synthesis inhibitors. We found that Bak^−/− cells are resistant to killing by PE and that Mcl-1, which binds to Bak, controls apoptosis induced by PE.     

The Transition from Proliferation to Differentiation in Colorectal Cancer Is Regulated by the Calcium Activated Chloride Channel A1

Breaking the balance between proliferation and differentiation in animal cells can lead to cancer, but the mechanisms maintaining this balance remain largely undefined. The calcium activated chloride channel A1 (CLCA1) is a member of the calcium sensitive chloride conductance family of proteins and is expressed mainly in the colon, small intestine and appendix. We show that CLCA1 plays a functional role in differentiation and proliferation of Caco-2 cells and of intestinal tissue. Caco-2 cells spontaneously differentiate either in confluent culture or when treated with butyrate, a molecule present naturally in the diet. Here, we compared CLCA1 expressional levels between patients with and without colorectal cancer (CRC) and determined the functional role of CLCA1 in differentiation and proliferation of Caco-2 cells. We showed that: 1) CLCA1 and CLCA4 expression were down-regulated significantly in CRC patients; 2) CLCA1 expression was up-regulated in Caco-2 cells induced to differentiate by confluent culture or by treatment with sodium butyrate (NaBT); 3) Knockdown of CLCA1 with siRNA significantly inhibited cell differentiation and promoted cell proliferation in Caco-2 confluent cultures, and 4) In Caco-2 3D culture, suppression of CLCA1 significantly increased cell proliferation and compromised NaBT-induced inhibition of proliferation. In conclusion, CLCA1 may contribute to promoting spontaneous differentiation and reducing proliferation of Caco-2 cells and may be a target of NaBT-induced inhibition of proliferation and therefore a potential diagnostic marker for CRC prognosis.     

Bacteriorhodopsin Is a Powerful Light-Driven Proton Pump

The activity of bacteriorhodopsin was investigated with Halobacterium halobium cell envelopes, which lack cytoplasmic constituents. It was found that the physiological concentration of magnesium ion greatly enhanced the light-induced pH change; under optimal conditions, the pH change of the external medium was as large as 3.5 pH units, even though the volume fraction of the envelope vesicles was as low as 0.01. This pH change is about three times larger than the largest change reported thus far. This same effect was observed with transition metal ions, but not with other alkaline divalent cations. That is, divalent cations that formed hydroxides below pH 10 were effective in enhancing the light-induced pH change. This result suggests that some divalent cations acted as buffers against a large increase in the internal pH, and that the internal pH was an important factor in determining the activity of bacteriorhodopsin. It was also shown that a high level of the proton-pump activity was maintained in a wide range of external pHs, at least between 4.5 and 9.4.     

The Permeation of Ammonium through a Voltage-independent K+ Channel in the Plasma Membrane of Rye Roots

Nitrogen is available to the plant in the form of NH⁺ ₄ in the soil solution. Here it is shown that a voltage-independent K⁺ channel in the plasma membrane of rye (Secale cereale L.) roots is permeable to NH⁺ ₄. The channel was studied following its incorporation into planar 1-palmitoyl-2-oleoyl phosphatidyl ethanolamine bilayers. The unitary conductance of the channel was greater when assayed in the presence of 100 mm NH₄Cl than 100 mm KCl. However, the probability of finding the channel open (P _o ) was lower in the presence of 100 mm NH₄Cl (P _o = 0.63) than in 100 mm KCl (P _o = 0.8), suggesting that P _o can be regulated by the (permeant) ions present in solution. When assayed in equimolar concentrations of NH₄Cl (cis) and KCl (trans), the zero-current (reversal) potential for the channel (E _rev) exhibited a complex concentration dependence. At low cation concentrations, the apparent permeability of NH⁺ ₄ relative to K⁺ (P_NH4/P_K) was greater than 1.0. However, as the cation concentration was increased, P_NH4/P_K initially decreased to a minimum of 0.95 at 3 mm before increasing again to a maximum of 1.89 at 300 mm. At cation concentrations above 300 mm, P_NH4/P_K decreased slightly. This implies that the pore of the channel can be occupied by more than one cation simultaneously. Ammonium permeation through the pore was simulated using a model which is composed of three energy barriers and two energy wells (the ion-binding sites). The model (3B2S) allowed for single-file permeation, double cation occupancy, ion-ion repulsion within the pore and surface potential effects. Results indicated that energy peaks and energy wells were situated asymmetrically within the electrical distance of the pore, that cations repel each other within the pore and that the vestibules to the pore contain negligible surface charge. The energy profile obtained for NH⁺ ₄ is compared with ones obtained for K⁺ and Na⁺. This information allows the fluxes through the K⁺ channel of the three major monovalent cations present in the soil solution to be predicted. Received: 16 October 1995/Revised 12 March 1996     

Light-Induced Stomatal Opening Is Affected by the Guard Cell Protein Kinase APK1b

Guard cells allow land plants to survive under restricted or fluctuating water availability. They control the exchange of gases between the external environment and the interior of the plant by regulating the aperture of stomatal pores in response to environmental stimuli such as light intensity, and are important regulators of plant productivity. Their turgor driven movements are under the control of a signalling network that is not yet fully characterised. A reporter gene fusion confirmed that the Arabidopsis APK1b protein kinase gene is predominantly expressed in guard cells. Infrared gas analysis and stomatal aperture measurements indicated that plants lacking APK1b are impaired in their ability to open their stomata on exposure to light, but retain the ability to adjust their stomatal apertures in response to darkness, abscisic acid or lack of carbon dioxide. Stomatal opening was not specifically impaired in response to either red or blue light as both of these stimuli caused some increase in stomatal conductance. Consistent with the reduction in maximum stomatal conductance, the relative water content of plants lacking APK1b was significantly increased under both well-watered and drought conditions. We conclude that APK1b is required for full stomatal opening in the light but is not required for stomatal closure.     

A Cellular Automata Model of Proton Hopping Down a Channel

Proton hopping is the process where a H‐atom on a hydronium ion forms a H‐bond with the O‐atom of a neighboring H₂O molecule. There is then an exchange of bonding forces when that covalent bond of the H‐atom in the hydronium ion changes to a H‐bond, and the previous H‐bond changes to a covalent bond with the neighboring O‐atom. The neighboring molecule now becomes a hydronium (H₃O⁺) ion. This process repeats itself very rapidly among neighboring hydronium and H₂O molecules. There is a flow of protonic character through bulk H₂O, referred to as proton hopping. This process carries information through living systems where H₂O is present. A cellular automata model of proton hopping down a channel has been created and studied. Variations in the rate of proton entry into the channel and the effects of the polar character of the channel walls was studied using the model. The behavior of the models corresponds to experimental results.     

Designing Inhibitors of M2 Proton Channel against H1N1 Swine Influenza Virus

Background

M2 proton channel of H1N1 influenza A virus is the target protein of anti-flu drugs amantadine and rimantadine. However, the two once powerful adamantane-based drugs lost their 90% bioactivity because of mutations of virus in recent twenty years. The NMR structure of the M2 channel protein determined by Schnell and Chou (Nature, 2008, 451, 591–595) may help people to solve the drug-resistant problem and develop more powerful new drugs against H1N1 influenza virus.

Methodology

Docking calculation is performed to build the complex structure between receptor M2 proton channel and ligands, including existing drugs amantadine and rimantadine, and two newly designed inhibitors. The computer-aided drug design methods are used to calculate the binding free energies, with the computational biology techniques to analyze the interactions between M2 proton channel and adamantine-based inhibitors.

Conclusions

1) The NMR structure of M2 proton channel provides a reliable structural basis for rational drug design against influenza virus. 2) The channel gating mechanism and the inhibiting mechanism of M2 proton channel, revealed by the NMR structure of M2 proton channel, provides the new ideas for channel inhibitor design. 3) The newly designed adamantane-based inhibitors based on the modeled structure of H1N1-M2 proton channel have two pharmacophore groups, which act like a “barrel hoop”, holding two adjacent helices of the H1N1-M2 tetramer through the two pharmacophore groups outside the channel. 4) The inhibitors with such binding mechanism may overcome the drug resistance problem of influenza A virus to the adamantane-based drugs.     

Cellular and Neural Responses to Sour Stimuli Require the Proton Channel Otop1

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A novel Hv1 inhibitor reveals a new mechanism of inhibition of a voltage-sensing domain

Voltage-gated sodium, potassium, and calcium channels consist of four voltage-sensing domains (VSDs) that surround a central pore domain and transition from a down state to an up state in response to membrane depolarization. While many types of drugs bind pore domains, the number of organic molecules known to bind VSDs is limited. The Hv1 voltage-gated proton channel is made of two VSDs and does not contain a pore domain, providing a simplified model for studying how small ligands interact with VSDs. Here, we describe a ligand, named HIF, that interacts with the Hv1 VSD in the up and down states. We find that HIF rapidly inhibits proton conduction in the up state by blocking the open channel, as previously described for 2-guanidinobenzimidazole and its derivatives. HIF, however, interacts with a site slowly accessible in the down state. Functional studies and MD simulations suggest that this interaction traps the compound in a narrow pocket lined with charged residues within the VSD intracellular vestibule, which results in slow recovery from inhibition. Our findings point to a “wrench in gears” mechanism whereby side chains within the binding pocket trap the compound as the teeth of interlocking gears. We propose that the use of screening strategies designed to target binding sites with slow accessibility, similar to the one identified here, could lead to the discovery of new ligands capable of interacting with VSDs of other voltage-gated ion channels in the down state.