The superoxide-generating NADPH oxidase of human neutrophils is electrogenic and associated with an H+ channel

Henderson, L. M.; Chappell, Joseph; Jones, Owen

doi:10.1042/bj2460325

Cited by 320 publications

(377 citation statements)

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“…As a compensating mechanism, the operation of a H ÷-transporting pathway has been suggested in the plasma membrane that could allow the efflux of protons in the direction of their electrochemical gradient [3,4]. The existence of an electrogenic H+-transporting pathway has been demonstrated in the plasma membrane of neutrophil granulocytes [3][4][5][6][7], macrophages [8] and HL-60 granulocytes [9], on the basis of intracellular pH-determinations by fluorescent dyes [3 6] and by whole cell patch clamp measurements [7][8][9].…”

Section: Introductionmentioning

confidence: 99%

Ligands of purinergic receptors stimulate electrogenic H⁺‐transport of neutrophils

et al. 1995

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Section: Introductionmentioning

confidence: 99%

Ligands of purinergic receptors stimulate electrogenic H⁺‐transport of neutrophils

et al. 1995

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“…HVCN1 has multiple functions in different cell types. For example, in neutrophils it mediates the positive charge compensation associated with oxidative bursts during phagocytosis [51,52] , while in tracheal epithelium it mediates acid secretion [49] . In addition, activation of HVCN1…”

Section: Hydrogen Voltage-gated Channel 1 (Hvcn1)mentioning

confidence: 99%

Proton production, regulation and pathophysiological roles in the mammalian brain

Zeng

2012

Neurosci. Bull.

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Abstract:The recent demonstration of proton signaling in C. elegans muscle contraction suggests a novel mechanism for proton-based intercellular communication and has stimulated enthusiasm for exploring proton signaling in higher organisms. Emerging evidence indicates that protons are produced and regulated in localized space and time. Furthermore, identification of proton regulators and sensors in the brain leads to the speculation that proton production and regulation may be of major importance for both physiological and pathological functions ranging from nociception to learning and memory. Extracellular protons may play a role in signal transmission by not only acting on adjacent cells but also affecting the cell from which they were released. In this review, we summarize the upstream and downstream pathways of proton production and regulation in the mammalian brain, with special emphasis on the proton extruders and sensors that are critical in the homeostatic regulation of pH, and discuss their potential roles in proton signaling under normal and pathophysiological conditions.

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“…Defects in any one of the enzyme subunits cause chronic granulomatous disease (CGD), a genetic disease characterized by severe and recurrent bacterial infections that were fatal in childhood before the advent of antibiotics (Stasia and Li, 2008). The oxidase is electrogenic (Henderson et al, 1987) as it translocates electrons across the plasma membrane in order to produce superoxide, and the electron currents can be measured with patch-clamp electrodes in cells with high plasma membrane oxidase activity, such as neutrophils and eosinophils (Schrenzel et al, 1998;DeCoursey et al, 2000). Unless compensated, the extrusion of the negatively charged electron will depolarize the phagocyte plasma membrane to extremely high voltages, and values of +60 mV and of up to +180 mV have been reported in intact cells (Jankowski and Grinstein, 1999) and in excised patches, respectively Petheo and Demaurex, 2005).…”

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confidence: 99%

“…The activity of the oxidase was shown early on to require a compensating charge , which was immediately postulated to be provided by voltage-gated proton channels (Henderson et al, 1987) whose activity was then recorded electrically in phagocytes (Demaurex et al, 1993a,b;DeCoursey and Cherny, 1993). An alternative mechanism was postulated in 2004 by Tony Segal, who proposed that the large-conductance Ca 2+ -activated K + channel (BKCa) was responsible for charge compensation during respiratory burst and thus essential for innate immunity (Ahluwalia et al, 2004).…”

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confidence: 99%

“…Recent studies from mice bearing a targeted disruption within the HVCN1 gene (Hv1 -/-) confirmed that Hv1 is the only proton channel expressed in phagocytes and invalidated definitively a longstanding hypothesis postulating that the oxidase is itself a proton channel (Henderson et al, 1987Henderson and Meech, 2002;Banfi et al, 2000;DeCoursey et al, 2002;Maturana et al, 2002). All attempts to record proton currents in Hv1-deficient phagocytes yielded absolutely flat traces, even after activation of cells with PMA (Ramsey et al, 2009;Morgan et al, 2009;El Chemaly et al, 2010;Okochi et al, 2009), a procedure that evoked electron currents of similar amplitude in Hv1 -/-and in wild-type (WT) Fig.…”

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Do Hv1 proton channels regulate the ionic and redox homeostasis of phagosomes?

Chemaly

Demaurex

2012

Molecular and Cellular Endocrinology

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a b s t r a c tRecent work on animal models has revealed the important role played by the voltage-gated proton channel Hv1 during bacterial killing by innate immune cells. Studies from mice lacking Hv1 channels showed that Hv1 proton channels are required for high-level production of reactive oxygen species (ROS) by the NADPH oxidase of phagocytes (NOX2) in two ways. First, Hv1 channels maintain a physiological membrane potential during the respiratory burst of neutrophils by providing a compensating charge for the electrons transferred by NOX2 from NADPH to superoxide. Second, Hv1 channels maintain a physiological cytosolic pH by extruding the acid generated by the NOX2-dependent consumption of NADPH. The two mechanisms directly sustain the activity of the NOX2 enzyme and indirectly sustain other neutrophil functions by enhancing the driving force for the entry of calcium into cells, thereby boosting cellular calcium signals. The increased depolarization of Hv1-deficient neutrophils aborted calcium responses to chemoattractants and revealed adhesion and migration defects that were associated with an impaired depolymerization of the cortical actin cytoskeleton. Current research aims to transpose these findings to phagosomes, the phagocytic vacuoles where bacterial killing takes place. However, the mechanisms that control the phagosomal pH appear to vary greatly between phagocytes: phagosomes rapidly acidify in macrophages but remain neutral for several minutes in neutrophils following ingestion of solid particles, whereas in dendritic cells phagosomes alkalinize, a mechanism thought to promote antigen crosspresentation. In this review, we discuss how the knowledge gained on the role of Hv1 channels at the plasma membrane of neutrophils can be used to study the regulation of the phagosomal pH, ROS, membrane potential, and calcium fluxes in different phagocytic cells.

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The superoxide-generating NADPH oxidase of human neutrophils is electrogenic and associated with an H+ channel

Cited by 320 publications

References 28 publications

Ligands of purinergic receptors stimulate electrogenic H⁺‐transport of neutrophils

Ligands of purinergic receptors stimulate electrogenic H⁺‐transport of neutrophils

Proton production, regulation and pathophysiological roles in the mammalian brain

Do Hv1 proton channels regulate the ionic and redox homeostasis of phagosomes?

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The superoxide-generating NADPH oxidase of human neutrophils is electrogenic and associated with an H+ channel

Cited by 320 publications

References 28 publications

Ligands of purinergic receptors stimulate electrogenic H+‐transport of neutrophils

Ligands of purinergic receptors stimulate electrogenic H+‐transport of neutrophils

Proton production, regulation and pathophysiological roles in the mammalian brain

Do Hv1 proton channels regulate the ionic and redox homeostasis of phagosomes?

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Ligands of purinergic receptors stimulate electrogenic H⁺‐transport of neutrophils

Ligands of purinergic receptors stimulate electrogenic H⁺‐transport of neutrophils