Putative ClC-2 Chloride Channel Mediates Inward Rectification in <Emphasis Type="Italic">Drosophila </Emphasis>Retinal Photoreceptors

We report that Drosophila retinal photoreceptors express inwardly rectifying chloride channels that seem to be orthologous to mammalian ClC-2 inward rectifier channels. We measured inwardly rectifying Cl⁻ currents in photoreceptor plasma membranes: Hyperpolarization under whole-cell tight-seal voltage clamp induced inward Cl⁻ currents; and hyperpolarization of voltage-clamped inside-out patches excised from plasma membrane induced Cl⁻ currents that have a unitary channel conductance of ∼3.7 pS. The channel was inhibited by 1 mM Zn²⁺ and by 1 mM 9-anthracene, but was insensitive to DIDS. Its anion permeability sequence is Cl⁻ = SCN⁻> Br⁻>> I⁻, characteristic of ClC-2 channels. Exogenous polyunsaturated fatty acid, linolenic acid, enhanced or activated the inward rectifier Cl⁻ currents in both whole-cell and excised patch-clamp recordings. Using RT-PCR, we found expression in Drosophila retina of a ClC-2 gene orthologous to mammalian ClC-2 channels. Antibodies to rat ClC-2 channels labeled Drosophila photoreceptor plasma membranes and synaptic regions. Our results provide evidence that the inward rectification in Drosophila retinal photoreceptors is mediated by ClC-2-like channels in the non-transducing (extra-rhabdomeral) plasma membrane, and that this inward rectification can be modulated by polyunsaturated fatty acid. G. Ugarte and R. Delgado contributed equally to this work.     

Are Redox Reactions Involved in Regulation of K+ Channels in the Plasma Membrane of Limnobium stoloniferum Root Hairs?

The effects of the impermeant electron acceptor hexacyanoferrate III (HCF III) and the potassium channel blocker tetraethylam-monium (TEA) on the current-voltage relationship and electrical potential across the plasma membrane of Limnobium stoloniferum root hairs was investigated using a modified sucrose gap technique. One millimolar HCF III immediately and reversibly depolarized the membrane by 27 mV, whereas the effect on the trans-membrane current was markedly delayed. After 6 min of treatment with this electron acceptor, outwardly rectifying current was inhibited by 50%, whereas the inwardly rectifying current was activated approximately 3-fold. Ten millimolar TEA blocked both outward (65%) and inward (52%) currents. Differential TEA-sensitive current was shown to be blocked (55%) by HCF III at -20 mV and was shown to be stimulated (230%) by this electron acceptor at -200 mV. The inward current at -200 mV was eliminated in the absence of K+ or after addition of 10 mM Cs+ and was not affected by addition of either 10mM Na+ or Li+, independent of the presence of HCF III. The addition of any alkali cation to the external medium decreased the outward current both in the presence and in the absence of HCF III. The membrane depolarization evoked by HCF III did not correlate with the corresponding modification of the inward current. HCF III is proposed to activate inwardly rectifying potassium channels and to inactivate outwardly rectifying potassium channels. It is concluded that the plasma membrane depolarization did not result from modulation of the potassium channels by HCF III and may originate from trans-plasma membrane electron transfer.     

Inhibition, by an amphiphilic substance, niflumic acid, of the inward rectification of the crustacean muscle fiber

Agents such as TEA+ or CS+ ions, these last ions instead of K+ ions in poor K extracellular solution, known to reduce or abolish the inwardly rectifying channel in many preparations produced no effect in crayfish muscle membrane By contrast, poor Cl extracellular solution (Cl- ions were replaced by CH3OSO3- ions) blocked the inward current activated by hyperpolarizing pulses and produced an increase of the resting potential. Niflumic acid is a agent which inhibited the inward going rectification of the crayfish muscle membrane. Apparent dissociation constant of niflumic acid with membrane sites was equal to about 6 X 10(-8) M; this value corresponds to that given by Cousin & Motais (1979) concerning translocation of Cl- ions in the membrane of red cells. Activation of the inward going rectification in the crayfish membrane is responsible of an inward current carried by Cl- ions.     

Inward and outward K+-selective currents in the plasma membrane of protoplasts from maize root cortex and stele

In an attempt to understand the processes mediating ion transport within the root, the patch clamp technique was applied to protoplasts isolated from the cortex and stele of maize roots and their plasma membrane conductances investigated. In the whole-cell configuration, membrane hyperpolarization induced a slowly activating inwardly rectifying conductance in most protoplasts isolated from the root cortex. In contrast, most protoplasts isolated from the stele contained a slowly activating outwardly rectifying conductance upon plasma membrane depolarization. The reversal potential of the inward current indicated that it was primarily due to the movement of K⁺; the outwardly rectifying conductance was comparatively less selective for K⁺. Membrane hyperpolarization beyond a threshold of about ?70 mV induced inward currents. When E_K was set negative of this threshold, inward currents activated negative of E_K and no outward currents were observed positive of E_K. Outward currents in the stelar protoplasts activated at potentials positive of ?85 mV. However, when E_K was set positive of ?85 mV a small inward current was also observed at potentials negative (and slightly positive) of the equilibrium potential for K⁺. Inwardly and outwardly rectifying K⁺ channels were observed in outside-out patches from the plasma membrane of cortical and stelar cells, respectively. Characterization of these channels showed that they were likely to be responsible for the macroscopic ‘whole-cell’ currents. Inward and outward currents were affected differently by various K⁺ channel blockers (TEA⁺, Ba²⁺ and Cs⁺). In addition, Ca²⁺ above 1 mM partially blocked the inward current in a voltage-dependent manner but had little effect on the outward current. It is suggested that the inwardly rectifying conductance identified in protoplasts isolated from the cortex probably represents an important component of the low-affinity K⁺ uptake mechanism (mechanism II) identified in intact roots. The outwardly rectifying conductance identified in protoplasts isolated from the stele could play a role in the release of cations into the xylem vessels for transport to the shoot.     

An inwardly rectifying potassium channel in the basolateral membrane of sheep parotid secretory cells

Summary Using whole-cell patch-clamp techniques, we demonstrate that sheep parotid secretory cells have both inwardly and outwardly rectifying currents. The outwardly rectifying current, which is blocked by 10 mmol/liter tetraethylammonium (TEA) applied extracellularly, is probably carried by the 250 pS Ca²⁺-and voltage-activated K⁺ (BK) channel which has been described in previous studies. In contrast, the inwardly rectifying current, which is also carried by K⁺ ions, is not sensitive to TEA. It is similar to the inwardly rectifying currents observed in many excitable tissues in that (i) its conductance is dependent on the square root of the extracellular K⁺, (ii) the voltage range over which it is activated is influenced by the extracellular K⁺ concentration and (iii) it is blocked by the addition of Cs⁺ ions (670 µmol/liter) to the bathing solution. Our previously published cell-attached patch studies have shown that the channel type most commonly observed in the basolateral membrane of unstimulated sheep parotid secretory cells is a K⁺ channel with a conductance of 30 pS and, in this study, we find that its conductance also depends on the square root of the extracellular K⁺ concentration. It thus seems likely that it carries the inwardly rectifying K⁺ current seen in the whole-cell studies.     

Inward rectification of the minK potassium channel

The minK protein induces a slowly activating voltage-dependent potassium current when expressed in Xenopus oocytes. We have used macroscopic minK currents to determine the open channel current-voltage relationship for the channel, and have found that the minK current is inwardly rectifying. The channel passes inward current at least 20fold more readily than outward current. Both rat and human minK exhibit this property. The rectification of minK is similar to that reported for a slow component of the cardiac delayed rectifier, strengthening the hypothesis that minK is responsible for that current.We would like to thank Drs. Steve Goldstein and Chris Miller for the artificial rat minK gene, and Dr. Rick Swanson for the human minK construct. This work was supported by NIH grant GM-48851 to L.K.K.     

Calcium-dependent sodium current in the marine ciliateEuplotes vannus

Summary Ca and Na inward currents were recorded upon depolarizations inEuplotes after the blockage of K outward currents with intracellular Cs ions. The Na current was analyzed under voltage clamp and had the following properties: it activated to a maximum within 150 msec and partly inactivated during sustained voltage steps. It had a positive equilibrium potential between 25 and 30 mV and could be carried by Na or Li ions but not by K, choline or Tris ions. The current revealed a prominent associated inward tail current which deactivated with a single-exponential time constant of 118 msec. Both the current and its tail were strongly reduced after reduction of the extracellular Na concentration. Externally applied K channel blocker tetraethylammonium chloride did not block the current. Either EGTA injection into the cell or nonlethal deciliation with ethanol eliminated the current and its tail. These results indicate the existence of a Na conductance within the membrane ofEuplotes which is activated by the intracellular level of free Ca²⁺.     

Membrane properties of isolated mudpuppy taste cells

The voltage-dependent currents of isolated Necturus lingual cells were studied using the whole-cell configuration of the patch-clamp technique. Nongustatory surface epithelial cells had only passive membrane properties. Small, spherical cells resembling basal cells responded to depolarizing voltage steps with predominantly outward K+ currents. Taste receptor cells generated both outward and inward currents in response to depolarizing voltage steps. Outward K+ currents activated at approximately 0 mV and increased almost linearly with increasing depolarization. The K+ current did not inactivate and was partially Ca++ dependent. One inward current activated at -40 mV, reached a peak at -20 mV, and rapidly inactivated. This transient inward current was blocked by tetrodotoxin (TTX), which indicates that it is an Na+ current. The other inward current activated at 0 mV, peaked at 30 mV, and slowly inactivated. This more sustained inward current had the kinetic and pharmacological properties of a slow Ca++ current. In addition, most taste cells had inwardly rectifying K+ currents. Sour taste stimuli (weak acids) decreased outward K+ currents and slightly reduced inward currents; bitter taste stimuli (quinine) reduced inward currents to a greater extent than outward currents. It is concluded that sour and bitter taste stimuli produce depolarizing receptor potentials, at least in part, by reducing the voltage-dependent K+ conductance.     

Block of inward rectification by intracellular H+ in immature oocytes of the starfish Mediaster aequalis

Intracellular pH was recorded in immature starfish oocytes using pH- sensitive microelectrodes, and inwardly rectifying potassium currents were measured under voltage clamp. When the intracellular pH was lowered using acetate-buffered artificial sea water from the normal value of 7.09 to 5.9, inward rectification was completely blocked. The relationship between inward rectification and internal pH between 7.09 and 5.9 could be fit by a titration curve for the binding of three H ions to a site with a pK of 6.26 to block the channel. The H+ block showed no voltage dependence, and the activation kinetics of the inwardly rectifying currents were not affected by the changes in internal pH.     

Inwardly rectifying potassium current in rabbit osteoclasts: A whole-cell and single-channel study

Summary Ionic conductances of rabbit osteoclasts were investigated using both whole-cell and cell-attached configurations of the patch-clamp recording technique. The predominant conductance found in these cells was an inwardly rectifying K⁺ conductance. Whole-cell currents showed an N-shaped current-voltage (I–13;V) relation with inward current activated at potentials negative to E_K. When external K⁺ was varied, I-V curves shifted 53 mV/10-fold change in [K⁺]_out, as predicted for a K⁺-selective channel. Inward current was blocked by Ba²⁺ and showed a time-dependent decline at negative potentials, which was reduced in Na⁺-free external solution. Inward single-channel currents were recorded in the cell-attached configuration. Single-channel currents were identified as inward-rectifier K⁺ channels based on the following observations: (i) Unitary I-V relations rectified, with only inward current resolved. (ii) Unitary conductance () was 31 pS when recorded in the cell-attached configuration with 140 mm K⁺ in the pipette and was found to be dependent on [K⁺]. (iii) Addition of Ba²⁺ to the pipette solution abolished single-channel events. We conclude that rabbit osteoclasts possess inwardly rectifying K⁺ channels which give rise to the inward current recorded at negative potentials in the whole-cell configuration. This inwardly rectifying K⁺ current may be responsible for setting the resting membrane potential and for dissipating electrical potential differences which arise from electrogenic transport of protons across the osteoclast ruffled border.This work was supported by The Arthritis Society and the Medical Research Council of Canada. M.E.M.K. was supported by a fellowship, S.J.D. a development Grant and S.M.S. a scholarship from the Medical Research Council. We thank Dr. Zu Gang Zheng for help with scanning microscopy.     

Vacuolar ion currents in the primitive green algaEremosphaera viridis: The electrical properties are suggestive of both the Characeae and higher plants

Summary The electrical properties of the vacuolar membrane of the primitive green algaEremosphaera virdis were investigated using the patch-clamp technique. In whole vacuole measurements two types of transport systems with long activation time-constants were identified. The first, showing marked outward rectification, was activated by an increase in the cytosolic calcium concentration. Furthermore, it displayed sensitivity to micromolar concentrations of the anion channel blocker Zn²⁺ and to acidification of the cytosol. In contrast, the second time-activated current component was almost insensitive to changes in cytosolic pH and was blocked by the potassium channel inhibitor TEA. In addition to these slowly activating current components, the vacuolar membrane contained at least two further transport systems, responsible for an instantaneous current. These two current components were distinguished by their different sensitivity to protons, cytosolic calcium, and TEA. Comparing these electrical properties to those observed in vacuoles of higher plants or in cytoplasmic droplets from characean algae, respectively, it seems thatEremosphaera is intermediate, corresponding to the systematic position of this simple green alga.Abbreviations [Ca²⁺]_cyt cytosolic free calcium concentration - EGTA ethyleneglycol-bis(-aminoethylether)N,N,N,N-tetraacetic acid - HEPES N-[2-hydroxyethyl]piperazine-N-[2-ethanesulfonic acid] - I electric current - IRC inward rectifying current - MES 2-[N-morpholino]ethanesulfonic acid - ORC outward rectifying current - pH_cyt cytosolic pH - pH_vac vacuolar pH - P_o open probability - P_x permeability coefficient of ion species X - TEA tetraethylammonium chloride - Tris tris[hydroxymethyl]aminomethane - V voltage     

Internal Na+ and Mg2+ blockade of DRK1 (Kv2.1) potassium channels expressed in Xenopus oocytes. Inward rectification of a delayed rectifier

Delayed rectifier potassium channels were expressed in the membrane of Xenopus oocytes by injection of rat brain DRK1 (Kv2.1) cRNA, and currents were measured in cell-attached and inside-out patch configurations. In intact cells the current-voltage relationship displayed inward going rectification at potentials > +100 mV. Rectification was abolished by excision of membrane patches into solutions containing no Mg2+ or Na+ ions, but was restored by introducing Mg2+ or Na+ ions into the bath solution. At +50 mV, half- maximum blocking concentrations for Mg2+ and Na+ were 4.8 +/- 2.5 mM (n = 6) and 26 +/- 4 mM (n = 3) respectively. Increasing extracellular potassium concentration reduced the degree of rectification of intact cells. It is concluded that inward going rectification resulting from voltage-dependent block by internal cations can be observed with normally outwardly rectifying DRK1 channels.     

On the mechanism of cesium-induced voltage and current tails in single ventricular myocytes

The mechanisms by which different concentrations of cesium modify membrane potentials and currents were investigated in guinea pig single ventricular myocytes. In a dose-dependent manner, cesium reversibly decreases the resting potential and action potential amplitude and duration, and induces a diastolic decaying voltage tail (V_ex), which increases at more negative and reverses at less negative potentials. In voltage-clamped myocytes, Cs⁺ increases the holding current, increases the outward current at plateau levels while decreasing it at potentials closer to resting potential, induces an inward tail current (I_ex) on return to resting potential and causes a negative shift of the threshold for the inward current. During depolarizing ramps, Cs⁺ decreases the outward current negative to inward rectification range, whereas it increases the current past that range. During repolarizing ramps, Cs⁺ shifts the threshold for removal of inward rectification negative slope to less negative values. Cs⁺-induced voltage and current tails are increased by repetitive activity, caffeine (5 mM) and high [Ca²⁺]_o (8.1 mM), and are reduced by low Ca²⁺ (0.45 mM), Cd²⁺ (0.2 mM) and Ni²⁺ (2 mM). Ni²⁺ also abolishes the tail current that follows steps more positive than E_Ca. We conclude that Cs⁺ (1) decreases the resting potential by decreasing the outward current at more negative potentials, (2) shortens the action potential by increasing the outward current at potentials positive to the negative slope of inward rectification, and (3) induces diastolic tails through a Ca²⁺-dependent mechanism, which apparently is an enhanced electrogenic Na-Ca exchange.     

Whole-cell K+ current activation in response to voltages and carbachol in gastric parietal cells isolated from guinea pig

Summary Patch-clamp studies of whole-cell ionic currents were carried out in parietal cells obtained by collagenase digestion of the gastric fundus of the guinea pig stomach. Applications of positive command pulses induced outward currents. The conductance became progressively augmented with increasing command voltages, exhibiting an outwardly rectifying current-voltage relation. The current displayed a slow time course for activation. In contrast, inward currents were activated upon hyperpolarizing voltage applications at more negative potentials than the equilibrium potential to K⁺ (E _K). The inward currents showed time-dependent inactivation and an inwardly rectifying current-voltage relation. Tail currents elicited by voltage steps which had activated either outward or inward currents reversed at nearE _K, indicating that both time-dependent and voltagegated currents were due to K⁺ conductances. Both outward and inward K⁺ currents were suppressed by extracellular application of Ba²⁺, but little affected by quinine. Tetraethylammonium inhibited the outward current without impairing the inward current, whereas Cs⁺ blocked the inward current but not the outward current. The conductance of inward K⁺ currents, but not outward K⁺ currents, became larger with increasing extracellular K⁺ concentration. A Ca²⁺-mobilizing acid secretagogue, carbachol, and a Ca²⁺ ionophore, ionomycin, brought about activation of another type of outward K⁺ currents and voltage-independent cation currents. Both currents were abolished by cytosolic Ca²⁺ chelation. Quinine preferentially inhibited this K⁺ current. It is concluded that resting parietal cells of the guinea pig have two distinct types of voltage-dependent K⁺ channels, inward rectifier and outward rectifier, and that the cells have Ca²⁺-activated K⁺ channels which might be involved in acid secretion under stimulation by Ca²⁺-mobilizing secretagogues.     

Inwardly rectifying K(+) channels in esophageal smooth muscle

The whole cell patch-clamp technique was used to investigate whether there were inwardly rectifying K(+) (K(ir)) channels in the longitudinal muscle of cat esophagus. Inward currents were observable on membrane hyperpolarization negative to the K(+) equilibrium potential (E(k)) in freshly isolated esophageal longitudinal muscle cells. The current-voltage relationship exhibited strong inward rectification with a reversal potential (E(rev)) of -76.5 mV. Elevation of external K(+) increased the inward current amplitude and positively shifted its E(rev) after the E(k), suggesting that potassium ions carry this current. External Ba(2+) and Cs(+) inhibited this inward current, with hyperpolarization remarkably increasing the inhibition. The IC(50) for Ba(2+) and Cs(+) at -60 mV was 2.9 and 1.6 mM, respectively. Furthermore, external Ba(2+) of 10 microM moderately depolarized the resting membrane potential of the longitudinal muscle cells by 6.3 mV while inhibiting the inward rectification. We conclude that K(ir) channels are present in the longitudinal muscle of cat esophagus, where they contribute to its resting membrane potential.     

Two Distinct K+ Channels in Lamprey (Lampetra fluviatilis) Erythrocyte Membrane Characterized by Single Channel Patch Clamp

Two channels, distinguished by using single-channel patch-clamp, carry out potassium transport across the red cell membrane of lamprey erythrocytes. A small-conductance, inwardly rectifying K⁺-selective channel was observed in both isotonic and hypotonic solutions (osmolarity decreased by 50%). The single-channel conductance was 26 ± 3 pS in isotonic (132 mm K⁺) solutions and 24 ± 2 pS in hypotonic (63 mm K⁺) solutions. No outward conductance was found for this channel, and the channel activity was completely inhibited by barium. Cell swelling activated another inwardly rectifying K⁺ channel with a larger inward conductance of 65 pS and outward conductance of 15 pS in the on-cell configuration. In this channel, rectification was due to the block of outward currents by Mg²⁺ and Ca²⁺ ions, since when both ions were removed from the cytosolic side in inside-out patches the conductance of the channel was nearly ohmic. In contrast to the small-conductance channel, the swelling-activated channel was observed also in the presence of barium in the pipette. Neither type of channel was dependent on the presence of Ca²⁺ ions on the cytosolic side for activity. Received: 18 July 1997/Revised: 30 January 1998     

Ionic currents underlying the action potential of Rana pipiens oocytes

Ionic currents in immature, ovulated Rana pipiens oocytes (metaphase I) were studied using the voltage-clamp technique. At this stage of maturity the oocyte can produce action potentials in response to depolarizing current or as an "off response" to hyperpolarizing current. Reducing external Na+ to 1/10 normal (choline substituted) eliminated the action potentials and both the negative-slope region and zero-crossing of the I-V relation. Reducing external Cl- to 1/10 or 1/100 normal (methanesulfonate substituted) lengthened the action potential. The outward current was reduced and a net inward current was revealed. By changing external Na+, Cl-, and K+ concentrations and using blocking agents (SITS, TEA), three voltage- and time-dependent currents were identified, INa, IK and ICl. The Na+ current activated at about 0 mV and reversed at very positive values which decreased during maturation. Inward Na+ current produced the upstroke of the action potential. During each voltage-clamp step the Na+ current activated slowly (seconds) and did not inactivate within many minutes. The Na+ current was not blocked by TTX at micromolar concentrations. The K+ current was present only in the youngest oocytes. Because IK was superimposed on a large leakage current, it appeared to reverse at the resting potential. When leakage currents were subtracted, the reversal potential for IK was more negative than -110 mV in Ringer's solution. IK was outwardly rectifying and strongly activated above -50 mV. The outward K+ current produced an after hyperpolarization at the end of each action potential. IK was blocked completely and reversibly by 20 mM external TEA. The Cl- current activated at about +10 mV and was outwardly rectifying. ICl was blocked completely and reversibly by 400 microM SITS added to the bathing medium. This current helped repolarize the membrane following an action potential in the youngest oocytes and was the only repolarizing current in more mature oocytes that had lost IK. The total leakage current had an apparently linear I-V relation and was separated into two components: a Na+ current (IN) and a smaller component carried by as yet unidentified ions.     

Regulation of the inward rectifying properties of G-protein-activated inwardly rectifying K+ (GIRK) channels by Gbeta gamma subunits

Gbetagamma subunits are known to bind to and activate G-protein-activated inwardly rectifying K(+) channels (GIRK) by regulating their open probability and bursting behavior. Studying G-protein regulation of either native GIRK (I(KACh)) channels in feline atrial myocytes or heterologously expressed GIRK1/4 channels in Chinese hamster ovary cells and HEK 293 cells uncovered a novel Gbetagamma subunit mediated regulation of the inwardly rectifying properties of these channels. I(KACh) activated by submaximal concentrations of acetylcholine exhibited a approximately 2.5-fold stronger inward rectification than I(KACh) activated by saturating concentrations of acetylcholine. Similarly, the inward rectification of currents through GIRK1/4 channels expressed in HEK cells was substantially weakened upon maximal stimulation with co-expressed Gbetagamma subunits. Analysis of the outward current block underlying inward rectification demonstrated that the fraction of instantaneously blocked channels was reduced when Gbetagamma was over-expressed. The Gbetagamma induced weakening of inward rectification was associated with reduced potencies for Ba(2+) and Cs(+) to block channels from the extracellular side. Based on these results we propose that saturation of the channel with Gbetagamma leads to a conformational change within the pore of the channel that reduced the potency of extracellular cations to block the pore and increased the fraction of channels inert to a pore block in outward direction.     

Microvascular endothelial cells from human omentum lack an inward rectifier K+ current

In most macrovascular endothelial cell (EC) preparations, resting membrane potential is determined by the inwardly rectifying K+ current (I(K1)), whereas in microvascular EC the presence of I(K1) varies markedly. Cultured microvascular EC from small vessels of human omentum were examined by means of the voltage-clamp technique to elucidate the putative role of I(K1) in maintaining resting membrane potential. Macrovascular EC from human iliac artery and bovine aorta served as reference. Human omentum EC showed an outwardly rectifying current-voltage relation. Inward current was hardly sensitive to variations of extracellular [K+] and Ba2+ block suggesting lack of I(K1). However, substitution of extracellular [Na+] and/or [Cl-] affected the current-voltage relation indicating that Na+ and Cl- contribute to basal current. Furthermore, outward current was reduced by tetraethylammonium (10 mM), and cell-attached recordings suggested the presence of a Ca2+-activated K+ current. In contrast to human omentum EC, EC from human iliac artery and bovine aorta possessed inwardly rectifying currents which were sensitive to variations of extracellular [K+] and blocked by Ba2+. Thus, the lack of I(K1) in human omentum EC suggests that resting membrane potential is determined by Na+ and Cl- currents in addition to K+ outward currents.