Voltage-gated proton channels exist in the plasma membrane of human oocytes.

STUDY QUESTION: Do human oocytes express voltage-gated proton channels? SUMMARY ANSWER: Human oocytes exhibit voltage-gated proton currents. WHAT IS KNOWN ALREADY: Voltage-gated proton currents have been reported in human sperm, where they contribute to capacitation and motility. No such studies of human oocytes exist. STUDY DESIGN, SIZE, DURATION: Voltage-clamp studies were undertaken using entire oocytes and vesicles derived from oocytes and in excised patches of membrane from oocytes. PARTICIPANTS/MATERIALS, SETTING, METHODS: Frozen, thawed human metaphase II oocytes were obtained from material donated to the gamete repository at the Rush Center for Advanced Reproductive Care. Prior to patch clamping, oocytes were warmed and equilibrated. Formation of an electrically tight seal requires exposing bare oolemma. Sections of the zona pellucida (ZP) were removed using a laser, followed by repeated pipetting, to further separate the oocyte from the ZP. Patch-clamp studies were performed using the whole-cell configuration on oocytes or vesicles derived from oocytes, and using inside-out patches of membrane, under conditions optimized to detect voltage-gated proton currents. MAIN RESULTS AND THE ROLE OF CHANCE: Proton currents are present at significant levels in human oocytes where they exhibit properties similar to those reported in other human cells, as well as those in heterologous expression systems transfected with the HVCN1 gene that codes for the voltage-gated proton channel. LARGE SCALE DATA: N/A. LIMITATIONS, REASONS FOR CAUTION: Human oocytes are large cells, which limits our ability to control the intracellular solution. Subtle effects of cryopreservation by vitrification and subsequent warming on properties of HVCN1, the HVCN1 gene product, cannot be ruled out. WIDER IMPLICATIONS OF THE FINDINGS: Possible functions for voltage-gated proton channels in human oocytes may now be contemplated. STUDY FUNDING/COMPETING INTEREST(S): NIH R35GM126902 (TED), Bears Care (DM). No competing interests. TRIAL REGISTRATION NUMBER: N/A.

Detailed comparison of expressed and native voltage-gated proton channel currents.

Two years ago, genes coding for voltage-gated proton channels in humans, mice and Ciona intestinalis were discovered. Transfection of cDNA encoding the human HVCN1 (H(V)1) or mouse (mVSOP) ortholog of HVCN1 into mammalian cells results in currents that are extremely similar to native proton currents, with a subtle, but functionally important, difference. Expressed proton channels exhibit high H(+) selectivity, voltage-dependent gating, strong temperature sensitivity, inhibition by Zn(2+), and gating kinetics similar to native proton currents. Like native channels, expressed proton channels are regulated by pH, with the proton conductance-voltage (g(H)-V) relationship shifting toward more negative voltages when pH(o) is increased or pH(i) is decreased. However, in every (unstimulated) cell studied to date, endogenous proton channels open only positive to the Nernst potential for protons, E(H). Consequently, only outward H(+) currents exist in the steady state. In contrast, when the human or mouse proton channel genes are expressed in HEK-293 or COS-7 cells, sustained inward H(+) currents can be elicited, especially with an inward proton gradient (pH(o) < pH(i)). Inward current is the result of a negative shift in the absolute voltage dependence of gating. The voltage dependence at any given pH(o) and pH(i) is shifted by about -30 mV compared with native H(+) channels. Expressed H(V)1 voltage dependence was insensitive to interventions that promote phosphorylation or dephosphorylation of native phagocyte proton channels, suggesting distinct regulation of expressed channels. Finally, we present additional evidence that speaks against a number of possible mechanisms for the anomalous voltage dependence of expressed H(+) channels.

Interactions between NADPH oxidase-related proton and electron currents in human eosinophils.

1. Proton and electron currents in human eosinophils were studied using the permeabilized-patch voltage-clamp technique, with an applied NH4+ gradient to control pH(i). 2. Voltage-gated proton channels in unstimulated human eosinophils studied with the permeabilized-patch approach had properties similar to those reported in whole-cell studies. 3. Superoxide anion (O2-) release assessed by cytochrome c reduction was compared in human eosinophils and neutrophils stimulated by phorbol myristate acetate (PMA). PMA-stimulated O2 release was more transient and the maximum rate was three times greater in eosinophils. 4. In PMA-activated eosinophils, the H+ current amplitude (I(H)) at +60 mV increased 4.7-fold, activation was 4.0 times faster, deactivation (tail current decay) was 5.4 times slower, the H+ conductance-voltage (g(H)-V) relationship was shifted -43 mV, and diphenylene iodinium (DPI)-inhibitable inward current reflecting electron flow through NADPH oxidase was activated. The data reveal that PMA activates the H+ efflux during the respiratory burst by modulating the properties of H+ channels, not simply as a result of NADPH oxidase activity. 5. The electrophysiological response of eosinophils to PMA resembled that reported in human neutrophils, but PMA activated larger proton and electron currents in eosinophils and the response was more transient. 6. ZnCl2 slowed the activation of H+ currents and shifted the g(H)-V relationship to more positive voltages. These effects occurred at similar ZnCl2 concentrations in eosinophils before and after PMA stimulation. These data are compatible with the existence of a single type of H+ channel in eosinophils that is modulated during the respiratory burst.

Activation of NADPH oxidase-related proton and electron currents in human eosinophils by arachidonic acid.

1. Effects of arachidonic acid (AA) on proton and electron currents in human eosinophils were studied using the permeabilized-patch voltage-clamp technique, using an applied NH4+ gradient to control pH(i). 2. Superoxide anion (O2-) release was assessed by cytochrome c reduction in human eosinophils. Significant O2- release was stimulated by 5-10 microM AA. 3. AA activated diphenylene iodinium (DPI)-inhibitable inward current reflecting electron efflux through NADPH oxidase. These electron currents (I(e)) were elicited in human eosinophils at AA concentrations (3-10 microM) similar to those that induced O2- release. 4. The voltage-gated proton conductance (g(H)) in eosinophils stimulated with AA was profoundly enhanced: H+ current amplitude (I(H)) increased 4.6 times, activation was 4 times faster, and the H+ conductance-voltage (g(H)-V) relationship was shifted to substantially more negative voltages. The electrophysiological effects of AA resembled those reported for PMA, except that AA did not consistently slow tau(tail) (deactivation of H+ currents). 5. The stimulation of both proton and electron currents by AA was reversible upon washout. Repeated exposure elicited repeated responses. The activation of H+ currents by AA was dissociable from its activation of NADPH oxidase; H+ currents were enhanced at low concentrations of AA that did not elicit detectable I(e) or when NADPH oxidase was inhibited by DPI. 6. Most of the effects of AA on H+ currents qualitatively resemble those reported in whole-cell studies, reflecting a more direct action than PMA. The results are compatible with AA being an immediate activator of both NADPH oxidase and proton channels in human eosinophils.

The gp91phox component of NADPH oxidase is not the voltage-gated proton channel in phagocytes, but it helps.

During the "respiratory burst," the NADPH oxidase complex of phagocytes produces reactive oxygen species that kill bacteria and other invaders (Babior, B. M. (1999) Blood 93, 1464-1476). Electron efflux through NADPH oxidase is electrogenic (Henderson, L. M., Chappell, J. B., and Jones, O. T. G. (1987) Biochem. J. 246, 325-329) and is compensated by H(+) efflux through proton channels that reportedly are contained within the gp91(phox) subunit of NADPH oxidase. To test whether gp91(phox) functions as a proton channel, we studied H(+) currents in granulocytes from X-linked chronic granulomatous disease patients lacking gp91(phox) (X-CGD), the human myelocytic PLB-985 cell line, PLB-985 cells in which gp91(phox) was knocked out by gene targeting (PLB(KO)), and PLB-985 knockout cells re-transfected with gp91(phox) (PLB(91)). H(+) currents in unstimulated PLB(KO) cells had amplitude and gating kinetics similar to PLB(91) cells. Furthermore, stimulation with the phorbol ester phorbol 12-myristate 13-acetate increased H(+) currents to a similar extent in X-CGD, PLB(KO), and PLB(91) cells. Thus, gp91(phox) is not the proton channel in unstimulated phagocytes and does not directly mediate the increase of proton conductance during the respiratory burst. Changes in H(+) channel gating kinetics during NADPH oxidase activity are likely crucial to the activation of H(+) flux during the respiratory burst.

Upregulation of Kv1.3 K(+) channels in microglia deactivated by TGF-beta.

Microglial activation is accompanied by changes in K(+) channel expression. Here we demonstrate that a deactivating cytokine changes the electrophysiological properties of microglial cells. Upregulation of delayed rectifier (DR) K(+) channels was observed in microglia after exposure to transforming growth factor-beta (TGF-beta) for 24 h. In contrast, inward rectifier K(+) channel expression was unchanged by TGF-beta. DR current density was more than sixfold larger in TGF-beta-treated microglia than in untreated microglia. DR currents of TGF-beta-treated cells exhibited the following properties: activation at potentials more positive than -40 mV, half-maximal activation at -27 mV, half-maximal inactivation at -38 mV, time dependent and strongly use-dependent inactivation, and a single channel conductance of 13 pS in Ringer solution. DR channels were highly sensitive to charybdotoxin (CTX) and kaliotoxin (KTX), whereas alpha-dendrotoxin had little effect. With RT-PCR, mRNA for Kv1.3 and Kir2.1 was detected in microglia. In accordance with the observed changes in DR current density, the mRNA level for Kv1.3 (assessed by competitive RT-PCR) increased fivefold after treatment of microglia with TGF-beta.

Simultaneous activation of NADPH oxidase-related proton and electron currents in human neutrophils.

Generation of reactive oxygen species by the NADPH oxidase complex is an important bactericidal weapon of phagocytes. Phorbol myristate acetate (PMA) is a potent agonist for this "respiratory burst" in human neutrophils. Although stoichiometric H(+) efflux occurs during the respiratory burst, efforts to stimulate voltage-gated H(+) channels by PMA in whole-cell patch-clamped phagocytes have been unsuccessful. We have used a modification of the permeabilized-patch configuration that allows control of intracellular pH and preserves second-messenger pathways. Using this method, we show that PMA dramatically enhances and alters voltage-gated proton currents in human neutrophils. PMA produced four alterations in H(+) current properties, each of which increases the H(+) current at any given voltage: (i) a 40-mV negative shift in the H(+) conductance-voltage (g(H)-V) relationship; (ii) faster activation [smaller activation time constant (tau(act))] during depolarizing pulses; (iii) slower deactivation [larger deactivation time constant (tau(tail))] on repolarization; and (iv) a larger maximum H(+) conductance (g(H, max)). Inward current that directly reflects electron transport by NADPH oxidase was also activated by PMA stimulation. The identity of this electron current was confirmed by its sensitivity to diphenylene iodinium, an inhibitor of NADPH oxidase. Diphenylene iodinium also reversed the slowing of tau(tail) with a time course paralleling the inhibition of electron current. However, the amplitudes of H(+) and electron currents activated by PMA were not correlated. A complex interaction between NADPH oxidase and voltage-gated proton channels is indicated. The data suggest that PMA stimulation modulates preexisting H(+) channels rather than inducing a new H(+) channel.

Common themes and problems of bioenergetics and voltage-gated proton channels.

The existence of a proton-selective pathway through a protein is a common feature of voltage-gated proton channels and a number of molecules that play pivotal roles in bioenergetics. Although the functions and structures of these molecules are quite diverse, the proton conducting pathways share a number of fundamental properties. Conceptual parallels include the translocation by hydrogen-bonded chain mechanisms, problems of supply and demand, equivalence of chemical and electrical proton gradients, proton wells, alternating access sites, pK(a) changes induced by protein conformational change, and heavy metal participation in proton transfer processes. An archetypal mechanism involves input and output proton pathways (hydrogen-bonded chains) joined by a regulatory site that switches the accessibility of the bound proton from one 'channel' to the other, by means of a pK(a) change, molecular movement, or both. Although little is known about the structure of voltage-gated proton channels, they appear to share many of these features. Evidently, nature has devised a limited number of mechanisms to accomplish various design strategies, and these fundamental mechanisms are repeated with minor variation in many superficially disparate molecules.

pH-dependent inhibition of voltage-gated H(+) currents in rat alveolar epithelial cells by Zn(2+) and other divalent cations.

Inhibition by polyvalent cations is a defining characteristic of voltage-gated proton channels. The mechanism of this inhibition was studied in rat alveolar epithelial cells using tight-seal voltage clamp techniques. Metal concentrations were corrected for measured binding to buffers. Externally applied ZnCl(2) reduced the H(+) current, shifted the voltage-activation curve toward positive potentials, and slowed the turn-on of H(+) current upon depolarization more than could be accounted for by a simple voltage shift, with minimal effects on the closing rate. The effects of Zn(2+) were inconsistent with classical voltage-dependent block in which Zn(2+) binds within the membrane voltage field. Instead, Zn(2+) binds to superficial sites on the channel and modulates gating. The effects of extracellular Zn(2+) were strongly pH(o) dependent but were insensitive to pH(i), suggesting that protons and Zn(2+) compete for external sites on H(+) channels. The apparent potency of Zn(2+) in slowing activation was approximately 10x greater at pH(o) 7 than at pH(o) 6, and approximately 100x greater at pH(o) 6 than at pH(o) 5. The pH(o) dependence suggests that Zn(2+), not ZnOH(+), is the active species. Evidently, the Zn(2+) receptor is formed by multiple groups, protonation of any of which inhibits Zn(2+) binding. The external receptor bound H(+) and Zn(2+) with pK(a) 6.2-6.6 and pK(M) 6.5, as described by several models. Zn(2+) effects on the proton chord conductance-voltage (g(H)-V) relationship indicated higher affinities, pK(a) 7 and pK(M) 8. CdCl(2) had similar effects as ZnCl(2) and competed with H(+), but had lower affinity. Zn(2+) applied internally via the pipette solution or to inside-out patches had comparatively small effects, but at high concentrations reduced H(+) currents and slowed channel closing. Thus, external and internal zinc-binding sites are different. The external Zn(2+) receptor may be the same modulatory protonation site(s) at which pH(o) regulates H(+) channel gating.

Temperature dependence of voltage-gated H+ currents in human neutrophils, rat alveolar epithelial cells, and mammalian phagocytes.

H+ currents in human neutrophils, rat alveolar epithelial cells, and several mammalian phagocyte cell lines were studied using whole-cell and excised-patch tight-seal voltage clamp techniques at temperatures between 6 and 42 degrees C. Effects of temperature on gating kinetics were distinguished from effects on the H+ current amplitude. The activation and deactivation of H+ currents were both highly temperature sensitive, with a Q10 of 6-9 (activation energy, Ea, approximately 30-38 kcal/mol), greater than for most other ion channels. The similarity of Ea for channel opening and closing suggests that the same step may be rate determining. In addition, when the turn-on of H+ currents with depolarization was fitted by a delay and single exponential, both the delay and the time constant (tauact) had similarly high Q10. These results could be explained if H+ channels were composed of several subunits, each of which undergoes a single rate-determining gating transition. H+ current gating in all mammalian cells studied had similarly strong temperature dependences. The H+ conductance increased markedly with temperature, with Q10 >/= 2 in whole-cell experiments. In excised patches where depletion would affect the measurement less, the Q10 was 2.8 at >20 degrees C and 5.3 at <20 degrees C. This temperature sensitivity is much greater than for most other ion channels and for H+ conduction in aqueous solution, but is in the range reported for H+ transport mechanisms other than channels; e.g., carriers and pumps. Evidently, under the conditions employed, the rate-determining step in H+ permeation occurs not in the diffusional approach but during permeation through the channel itself. The large Ea of permeation intrinsically limits the conductance of this channel, and appears inconsistent with the channel being a water-filled pore. At physiological temperature, H+ channels provide mammalian cells with an enormous capacity for proton extrusion.

Deuterium isotope effects on permeation and gating of proton channels in rat alveolar epithelium.

The voltage-activated H+ selective conductance of rat alveolar epithelial cells was studied using whole-cell and excised-patch voltage-clamp techniques. The effects of substituting deuterium oxide, D2O, for water, H2O, on both the conductance and the pH dependence of gating were explored. D+ was able to permeate proton channels, but with a conductance only about 50% that of H+. The conductance in D2O was reduced more than could be accounted for by bulk solvent isotope effects (i.e., the lower mobility of D+ than H+), suggesting that D+ interacts specifically with the channel during permeation. Evidently the H+ or D+ current is not diffusion limited, and the H+ channel does not behave like a water-filled pore. This result indirectly strengthens the hypothesis that H+ (or D+) and not OH- is the ionic species carrying current. The voltage dependence of H- channel gating characteristically is sensitive to pH0 and pHi and was regulated by pD0 and pDi in an analogous manner. shifting 40 mV/U change in the pD gradient. The time constant of H+ current activation was about three times slower (T(act) was larger) in D2O than in H2O. The size of the isotope effect is consistent with deuterium isotope effects for proton abstraction reactions, suggesting that H+ channel activation requires deprotonation of the channel. In contrast, deactivation (T(tail)) was slowed only by a factor < or = 1.5 in D2O. The results are interpreted within the context of a model for the regulation of H+ channel gating by mutually exclusive protonation at internal and external sites (Cherny, V.V., V.S. Markin, and T.E. DeCoursey. 1995. J. Gen. Physiol. 105:861-896). Most of the kinetic effects of D2O can be explained if the pKa of the external regulatory site is approximately 0.5 pH U higher in D2O.

Proton and chloride currents in Chinese hamster ovary cells.

Proton and anion conductances were studied in Chinese hamster ovary (CHO) cells using tight-seal whole-cell recording. The pipette solution contained tetramethylammonium, TMA+, methanesulfonate, MeSO3-, highly buffered to pH 5.5. An outwardly rectifying anion conductance was observed in nearly all cells, with a relative permeability of MeSO3- < or = 0.5 that of Cl-. The anion conductance was small immediately after establishing whole-cell configuration, increased rapidly to a maximum at approximately 5 min, and then decreased more slowly to a small value over tens of minutes. A small voltage-activated H+ selective conductance was observed in most cells. H+ currents were studied after the Cl- conductance has subsided. The average H+ current at +40 mV at pHo 7.0 was 1.6 pA/pF. This H+ conductance was activated by membrane depolarization and enhanced at high pHo, and exhibited activation and deactivation kinetics comparable with H+ currents in other mammalian cells.

Adsorption of haematoporphyrins on the planar bilayer membrane.

Adsorption of haematoporphyrin derivatives with different hydrophobicities of peripheral groups on a planar bilayer lipid membrane (BLM) was studied in the dark and upon illumination by the visible light. Haematoporphyrin molecules were shown to adsorb on the BLM as anions. The adsorption changed the boundary potential at the membrane/water interface, in particular, it altered the potential in the diffuse part of the double layer outside the membrane and increased an additional unscreenable potential drop inside it. Illumination decreased the value of the negative potential drop due probably to the appearance of a positive charge in the haematoporphyrin macrocycle. The adsorption of haematoporphyrins affected the BLM conductivity induced by different ionophores, which can be explained by changes in membrane structure. Haematoporphyrin derivatives with higher hydrophobicities adsorbed deeper inside the membrane, caused greater changes in its structure and displayed a stronger photodynamic effect.

Effects of buffer concentration on voltage-gated H+ currents: does diffusion limit the conductance?

The single-channel proton conductance of the voltage-gated H(+)-selective channel, like that of the F0 component of the H(+)-ATPase, is nearly constant over a wide range of pH encompassing the physiological range. To examine the possible contributions of buffer diffusion and buffer-channel proton transfer reactions to this phenomenon, the effects of buffer concentration on voltage-activated H+ currents were explored in voltage-clamped rat alveolar epithelial cells. Changes in the external buffer concentration ([B]o), evaluated using the whole-cell configuration, had only small effects on H+ currents (IH). Lowering [B]o from 100 to 1 mM did not alter the voltage-activation curve or reversal potential (Vrev) but reduced IH, typically by 10-30%. Changes in internal buffer concentration ([B]i), examined in inside-out patches, usually altered IH more distinctly and subtly changed the kinetics. Overall, the effects of changing buffer concentration were small and subtle. The maximum attenuation of the single-channel H+ current at 1 mM buffer was estimated to be approximately 20% at either mouth of the H+ channel. Therefore, the rate-determining step in H+ permeation is neither deprotonation of buffer at the inner mouth of the channel nor protonation of buffer at the external surface. Evidently the rate of H+ permeation through the channel is itself small enough that diffusion of buffer in bulk solution does not directly limit the conductance significantly.

Voltage-activated proton currents in human THP-1 monocytes.

Depolarization-activated H+-selective currents were studied using whole-cell and excised-patch voltage clamp methods in human monocytic leukemia THP-1 cells, before and after being induced by phorbol ester to differentiate into macrophage-like cells. The H+ conductance, gH, activated slowly during depolarizing pulses, with a sigmoidal time course. Fitted by a single exponential following a delay, the activation time constant, tauact was roughly 10 sec at threshold potentials, decreasing at more positive potentials. Tail currents upon repolarization decayed mono-exponentially at all potentials. The tail current time constant, tautail, was voltage dependent, decreasing with hyperpolarization from 2-3 sec at 0 mV to approximately 200 msec at -100 mV. Surprisingly, although tauact depended strongly on pHo, tautail was completely independent of pHo. H+ currents were inhibited by Zn2+. Increasing pHo or decreasing pHi shifted the voltage-activation relationship to more negative potentials, tending to activate the gH at any given voltage. Studied in excised, inside-out membrane patches, H+ currents were larger and activated much more rapidly at lower bath pH (i.e., pHi). In THP-1 cells differentiated into macrophages, the H+ current density was reduced by one-half, and tauact was slower by about twofold. The properties of H+ channels in THP-1 cells and in other macrophage-related cells are compared.

Voltage-activated proton currents in membrane patches of rat alveolar epithelial cells.

1. Voltage-activated H(+)-selective currents were studied in cell-attached and excised, inside-out patches of membrane from rat alveolar epithelial cells in primary culture. The pH was varied from 5.5 to 7.5 in the pipette (pHo) and in the bath (pHi). 2. H+ currents in cell-attached patches exhibited activation kinetics and voltage dependence intermediate between their behaviour after excision into pH 6.5 and pH 7.5 solutions, consistent with reported pHi values for alveolar epithelial cells. 3. In inside-out patches, increasing pHo shifted the threshold voltage for activating H+ currents and the relationship between the time constant of activation of H+ currents (tau act) and voltage (V) negatively along the voltage axis by 40-50 mV (unit pH)-1. 4. Decreasing pHi shifted the activation threshold and the tau act-V relationship negatively along the voltage axis by 40-50 mV (unit pH)-1. In addition, at lower pHi the activation of H+ currents upon patch depolarization was markedly faster, with tau act increasing approximately 4- to 5-fold per unit pHi. 5. The limiting slope H+ conductance increased only by a factor of 1.7 per unit pH when pHi was lowered in the range 7.5-5.5 (at constant pHo 7.5). This result suggests that H+ permeation through voltage-activated H+ 'channels' occurs by a mechanism distinct from H+ permeation through water-filled ion channels, in which the conductance might be expected to increase in direct proportion to [H+].

The voltage-activated hydrogen ion conductance in rat alveolar epithelial cells is determined by the pH gradient.

Voltage-activated H+ currents were studied in rat alveolar epithelial cells using tight-seal whole-cell voltage clamp recording and highly buffered, EGTA-containing solutions. Under these conditions, the tail current reversal potential, Vrev, was close to the Nernst potential, EH, varying 52 mV/U pH over four delta pH units (delta pH = pHo - pHi). This result indicates that H+ channels are extremely selective, PH/PTMA > 10(7), and that both internal and external pH, pHi, and pHo, were well controlled. The H+ current amplitude was practically constant at any fixed delta pH, in spite of up to 100-fold symmetrical changes in H+ concentration. Thus, the rate-limiting step in H+ permeation is pH independent, must be localized to the channel (entry, permeation, or exit), and is not bulk diffusion limitation. The instantaneous current-voltage relationship exhibited distinct outward rectification at symmetrical pH, suggesting asymmetry in the permeation pathway. Sigmoid activation kinetics and biexponential decay of tail currents near threshold potentials indicate that H+ channels pass through at least two closed states before opening. The steady state H+ conductance, gH, as well as activation and deactivation kinetic parameters were all shifted along the voltage axis by approximately 40 mV/U pH by changes in pHi or pHo, with the exception of the fast component of tail currents which was shifted less if at all. The threshold potential at which H+ currents were detectably activated can be described empirically as approximately 20-40(pHo-pHi) mV. If internal and external protons regulate the voltage dependence of gH gating at separate sites, then they must be equally effective. A simpler interpretation is that gating is controlled by the pH gradient, delta pH. We propose a simple general model to account for the observed delta pH dependence. Protonation at an externally accessible site stabilizes the closed channel conformation. Deprotonation of this site permits a conformational change resulting in the appearance of a protonation site, possibly the same one, which is accessible via the internal solution. Protonation of the internal site stabilizes the open conformation of the channel. In summary, within the physiological range of pH, the voltage dependence of H+ channel gating depends on delta pH and not on the absolute pH.

Na(+)-H+ antiport detected through hydrogen ion currents in rat alveolar epithelial cells and human neutrophils.

Voltage-activated H(+)-selective currents were studied in cultured adult rat alveolar epithelial cells and in human neutrophils using the whole-cell configuration of the patch-clamp technique. The H+ conductance, gH, although highly selective for protons, was modulated by monovalent cations. In Na+ and to a smaller extent in Li+ solutions, H+ currents were depressed substantially and the voltage dependence of activation of the gH shifted to more positive potentials, when compared with the "inert" cation tetramethylammonium (TMA+). The reversal potential of the gH, Vrev, was more positive in Na+ solutions than in inert ion solutions. Amiloride at 100 microM inhibited H+ currents in the presence of all cations studied except Li+ and Na+, in which it increased H+ currents and shifted their voltage-dependence and Vrev to more negative potentials. The more specific Na(+)-H+ exchange inhibitor dimethylamiloride (DMA) at 10 microM similarly reversed most of the suppression of the gH by Na+ and Li+. Neither 500 microM amiloride nor 200 microM DMA added internally via the pipette solution were effective. Distinct inhibition of the gH was observed with 1% [Na+]o, indicating a mechanism with high sensitivity. Finally, the effects of Na+ and their reversal by amiloride were large when the proton gradient was outward (pHo parallel pHi 7 parallel 5.5), smaller when the proton gradient was abolished (pH 7 parallel 7), and absent when the proton gradient was inward (pH 6 parallel 7). We propose that the effects of Na+ and Li+ are due to their transport by the Na(+)-H+ antiporter, which is present in both cell types studied. Electrically silent H+ efflux through the antiporter would increase pHi and possibly decrease local pHo, both of which modulate the gH in a similar manner: reducing the H+ currents at a given potential and shifting their voltage-dependence to more positive potentials. A simple diffusion model suggests that Na(+)-H+ antiport could deplete intracellular protonated buffer to the extent observed. Evidently the Na(+)-H+ antiporter functions in perfused cells, and its operation results in pH changes which can be detected using the gH as a physiological sensor. Thus, the properties of the gH can be exploited to study Na(+)-H+ antiport in single cells under controlled conditions.

Potential, pH, and arachidonate gate hydrogen ion currents in human neutrophils.

Indirect evidence indicates that a proton-selective conductance is activated during the respiratory burst in neutrophils. A voltage- and time-dependent H(+)-selective conductance, gH, in human neutrophils is demonstrated here directly by the whole-cell patch-clamp technique. The gH is extremely low at large negative potentials, increases slowly upon membrane depolarization, and does not inactivate. It is enhanced at high external pH or low internal pH and is inhibited by Cd2+ and Zn2+. Arachidonic acid, which plays a pivotal role in inflammatory reactions, amplifies the gH. The properties of the gH described here are compatible with its activation during the respiratory burst in stimulated neutrophils, in which it may facilitate sustained superoxide anion release by dissipating metabolically generated acid.