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      The Voltage–gated Proton Channel, Hv1, Enhances Brain Damage from Ischemic Stroke

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          SUMMARY

          Phagocytic cell NADPH oxidase (NOX) generates reactive oxygen species (ROS) as part of innate immunity. Unfortunately, ischemia can also induce this pathway and inflict damage on native cells. Here we show that NOX–mediated damage can be inhibited by suppression of the voltage-gated proton channel, Hv1. Hv1 is required for full NOX activity since it compensates for loss of NOX–exported charge. We show that Hv1 is required for NOX–dependent ROS generation in brain microglia in situ and in vivo. Mouse and human brain microglia, but not neurons or astrocytes, express large Hv1-mediated currents. Mice lacking Hv1 were protected from NOX–mediated neuronal death and brain damage 24 hours after stroke. These results demonstrate that Hv1–dependent ROS production is responsible for a significant fraction of brain damage at early time points after ischemic stroke and provide a rationale for Hv1 as a therapeutic target for the treatment of ischemic stroke.

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          Most cited references35

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          Temporal and spatial dynamics of cerebral immune cell accumulation in stroke.

          Ischemic stroke leads to significant morbidity and mortality in the Western world. Early reperfusion strategies remain the treatment of choice but can initiate and augment an inflammatory response causing secondary brain damage. The understanding of postischemic inflammation is very limited. The objectives of this study were to define the temporal and spatial infiltration of immune cell populations and their activation patterns in a murine cerebral ischemia-reperfusion injury model. Transient middle cerebral artery occlusion was induced for 1 hour followed by 12-hour to 7-day reperfusion in C57/BL6 mice. Immunohistochemistry and flow cytometry were used to quantify the infiltrating immune cell subsets. Accumulation of microglia and infiltration of the ischemic hemisphere by macrophages, lymphocytes, and dendritic cells (DCs) preceded the neutrophilic influx. DCs were found to increase 20-fold and constituted a substantial proportion of infiltrating cells. DCs exhibited a significant upregulation of major histocompatibility complex II and major histocompatibility complex II high-expressing DCs were found 100 times more abundant than in sham conditions. Upregulation of the costimulatory molecule CD80 was observed in DCs and microglial cells but did not further increase in major histocompatibility complex II high-expressing DCs. No lymphocyte activation was observed. Additionally, regulatory immune cells (natural killer T-cells, CD4(-)/CD8(-)T lymphocytes) cumulated in the ischemic hemisphere. This study provides a detailed analysis of the temporal dynamics of immune cell accumulation in a rodent stroke model. The peculiar activation pattern and massive increase of antigen-presenting cells in temporal conjunction with regulatory cells might provide additional insight into poststroke immune regulation.
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            A voltage-gated proton-selective channel lacking the pore domain.

            Voltage changes across the cell membrane control the gating of many cation-selective ion channels. Conserved from bacteria to humans, the voltage-gated-ligand superfamily of ion channels are encoded as polypeptide chains of six transmembrane-spanning segments (S1-S6). S1-S4 functions as a self-contained voltage-sensing domain (VSD), in essence a positively charged lever that moves in response to voltage changes. The VSD 'ligand' transmits force via a linker to the S5-S6 pore domain 'receptor', thereby opening or closing the channel. The ascidian VSD protein Ci-VSP gates a phosphatase activity rather than a channel pore, indicating that VSDs function independently of ion channels. Here we describe a mammalian VSD protein (H(V)1) that lacks a discernible pore domain but is sufficient for expression of a voltage-sensitive proton-selective ion channel activity. H(v)1 currents are activated at depolarizing voltages, sensitive to the transmembrane pH gradient, H+-selective, and Zn2+-sensitive. Mutagenesis of H(v)1 identified three arginine residues in S4 that regulate channel gating and two histidine residues that are required for extracellular inhibition of H(v)1 by Zn2+. H(v)1 is expressed in immune tissues and manifests the characteristic properties of native proton conductances (G(vH+)). In phagocytic leukocytes, G(vH+) are required to support the oxidative burst that underlies microbial killing by the innate immune system. The data presented here identify H(v)1 as a long-sought voltage-gated H+ channel and establish H(v)1 as the founding member of a family of mammalian VSD proteins.
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              A voltage sensor-domain protein is a voltage-gated proton channel.

              Voltage-gated proton channels have been widely observed but have not been identified at a molecular level. Here we report that a four-transmembrane protein similar to the voltage-sensor domain of voltage-gated ion channels is a voltage-gated proton channel. Cells overexpressing this protein showed depolarization-induced outward currents accompanied by tail currents. Current reversal occured at equilibrium potentials for protons. The currents exhibited pH-dependent gating and zinc ion sensitivity, two features which are characteristic of voltage-gated proton channels. Responses of voltage dependence to sequence changes suggest that mouse voltage-sensor domain-only protein is itself a channel, rather than a regulator of another channel protein.
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                Author and article information

                Journal
                9809671
                21092
                Nat Neurosci
                Nat. Neurosci.
                Nature neuroscience
                1097-6256
                1546-1726
                6 February 2012
                04 March 2012
                01 October 2012
                : 15
                : 4
                : 565-573
                Affiliations
                [1 ]Howard Hughes Medical Institute, Children’s Hospital Boston and Department of Neurobiology, Harvard Medical School, Boston, MA 02115, USA
                [2 ]Research Division, Joslin Diabetes Center, Harvard Medical School, Boston, MA 02215, USA
                [3 ]Department of Radiology, Beth Israel Deaconess Medical Center, Boston, MA, 02115, USA
                [4 ]Department of Radiology, Children’s Hospital Boston, Boston, MA, 02115, USA
                [5 ]Department of Lab Medicine, Children’s Hospital Boston, and Department of Pathology, Harvard Medical School, Boston, MA, 02115, USA
                Author notes
                [* ] Correspondence: David E. Clapham MD, PhD., Howard Hughes Medical Institute, Children’s Hospital Boston, 1309 Enders Research Building, 320 Longwood Avenue, Boston, MA 02115, Phone: 617-919-2680, Fax: 617-731-0787, dclapham@ 123456enders.tch.harvard.edu
                [+]

                Equal Contribution

                Article
                HHMIMS354343
                10.1038/nn.3059
                3314139
                22388960
                0538ef52-0910-405b-b271-1eb0a41b8864

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                History
                Funding
                Funded by: Howard Hughes Medical Institute :
                Award ID: || HHMI_
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                Neurosciences
                Neurosciences

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