A Kv1.5 to Kv1.3 switch in endogenous hippocampal microglia and a role in proliferation.

The proliferation of microglia is a normal process in CNS development and in the defense against pathological insults, although, paradoxically, it contributes to several brain diseases. We have examined the types of voltage-activated K(+) currents (Kv) and their roles in microglial proliferation. Microglia were tissue-printed directly from the hippocampal region using brain slices from 5- to 14-d-old rats. Immediately after tissue prints were prepared, unipolar and bipolar microglia expressed a large Kv current, and the cells were not proliferating. Surprisingly, this current was biophysically and pharmacologically distinct from Kv1.3, which has been found in dissociated, cultured microglia, but it was very similar to Kv1.5. After several days in culture the microglia became highly proliferative, and although the Kv prevalence and current density decreased, many cells exhibited a prominent Kv that was indistinguishable from Kv1.3. The Kv1.5-like current was present in nonproliferating cells, whereas proliferating cells expressed the Kv1.3-like current. Immunocytochemical staining showed a dramatic shift in expression and localization of Kv1.3 and Kv1.5 proteins in microglia: Kv1.5 moving away from the surface and Kv1.3 moving to the surface as the cells were cultured. K(+) channel blockers inhibited proliferation, and the pharmacology of this inhibition correlated with the type of Kv current expressed. Our study, which introduces a method for the physiological examination of microglia from identified brain regions, demonstrates the differential expression of two functional Kv subunits and shows that a functional delayed rectifier current is necessary for microglia proliferation.

HERG-like K+ channels in microglia.

A voltage-gated K+ conductance resembling that of the human ether-à-go-go-related gene product (HERG) was studied using whole-cell voltage-clamp recording, and found to be the predominant conductance at hyperpolarized potentials in a cell line (MLS-9) derived from primary cultures of rat microglia. Its behavior differed markedly from the classical inward rectifier K+ currents described previously in microglia, but closely resembled HERG currents in cardiac muscle and neuronal tissue. The HERG-like channels opened rapidly on hyperpolarization from 0 mV, and then decayed slowly into an absorbing closed state. The peak K+ conductance-voltage relation was half maximal at -59 mV with a slope factor of 18.6 mV. Availability, assessed by a hyperpolarizing test pulse from different holding potentials, was more steeply voltage dependent, and the midpoint was more positive (-14 vs. -39 mV) when determined by making the holding potential progressively more positive than more negative. The origin of this hysteresis is explored in a companion paper (Pennefather, P.S., W. Zhou, and T.E. DeCoursey. 1998. J. Gen. Physiol. 111:795-805). The pharmacological profile of the current differed from classical inward rectifier but closely resembled HERG. Block by Cs+ or Ba2+ occurred only at millimolar concentrations, La3+ blocked with Ki = approximately 40 microM, and the HERG-selective blocker, E-4031, blocked with Ki = 37 nM. Implications of the presence of HERG-like K+ channels for the ontogeny of microglia are discussed.

Chloride-channel block inhibits T lymphocyte activation and signalling.

Both large- and small-conductance chloride (Cl-) channels have been found in human T lymphocytes; however, apart from possible roles in mediating regulatory volume decrease, their functions are not understood. We have used patch-clamp electrophysiology, Ca2+ spectrofluorometry, and Western blot assay for phosphotyrosine to investigate the effects of blocking Cl- channels on proliferation and on specific events in the activation of normal human T cells. Four chemically distinct Cl- channel blockers inhibited both the small-conductance Cl- channels and phytohemagglutinin (PHA)-induced lymphocyte proliferation in a similar dose-dependent manner; their order of potency was 5-nitro-2(3-phenylpropylamino)-benzoic acid (NPPB) > 4,4'-diisothiocyano-2,2'-disulfonic acid (DIDS) > flufenamic acid >> IAA-94. The Cl- channel blockers inhibited both the PHA-induced mobilization of Ca2+ and the rapid tyrosine phosphorylation of several polypeptides. Cell proliferation was not rescued by the Ca+ ionophore ionomycin or by addition of exogenous interleukin-2 (IL-2). Moreover, the blockers also inhibited phosphotyrosine expression in IL-2-treated, activated lymphoblasts. Thus, our results support a role for Cl- channels in early, PHA-evoked signalling and in later, II-2-dependent stages of lymphocyte activation and proliferation.

Association between cerebrospinal fluid interleukin-6 concentrations and outcome after severe human traumatic brain injury.

Acute inflammation plays a significant role in the pathophysiology of traumatic brain injury (TBI). However, the specific relationships between inflammatory mediators and patient outcome following TBI have not been fully established. In this study, we measured plasma and cerebrospinal fluid interleukin-1 (IL-1) and interleukin-6 (IL-6) concentrations in 36 patients, following severe TBI. Patients were monitored with continuous measurements of somatosensory-evoked potentials (SSEP) to derive an established surrogate outcome measurement, the 96-h evoked potential (SSEP96). Clinical outcomes were assessed at 3 months using the Glasgow Outcome Scale (GOS). Peak cerebrospinal fluid (CSF) IL-1 and IL-6 concentrations were significantly higher than those observed in the plasma [median 6.5 pg/mL (range 1.4-25.0) vs. 3.0 (0.8-7.6) for IL-1, and 650 (130-7,214) vs. 253 (52-1,506) for IL-6, p < 0.001 for both]. Peak CSF IL-6 levels correlated with SSEP96 (r = 0.42; p = 0.0133), and peak CSF IL-6 levels were higher with improved GOS (p = 0.024). Multiple regression analysis identified that age (p = 0.0072), pupillary abnormality (p = 0.021), the presence of mass lesion (p = 0.023), and peak CSF IL-6 concentrations (p = 0.026) were all statistically significant predictors of clinical outcome following TBI. These results suggest that peak CSF IL-6 concentrations correlate with improved outcome following TBI. This finding helps to characterize the inflammatory reaction associated with TBI and may help to develop improved treatment strategies for patients with TBI.

Microglial SK3 and SK4 currents and activation state are modulated by the neuroprotective drug, riluzole.

Microglia monitor the CNS for 'danger' signals after acute injury, such as stroke and trauma, and then undergo complex activation processes. Classical activation of microglia can produce neurotoxic levels of glutamate and immune mediators (e.g., pro-inflammatory cytokines, reactive oxygen and nitrogen species), while alternative activation up-regulates anti-inflammatory molecules and is thought to resolve inflammation and protect the brain. Thus, pharmacological strategies to decrease classical- and/or promote alternative activation are of interest. Here, we assessed actions of the neuroprotective drug, riluzole, on two Ca(2+)- activated K channels in microglia - SK3 (KCa2.3, KCNN3) and SK4 (KCa3.1, KCNN4) - and on classical versus alternative microglial activation. Riluzole is used to treat amyotrophic lateral sclerosis, and is in clinical trials for several other CNS disorders, where it has been presumed to target neurons and reduce glutamate-mediated toxicity. We show that simply elevating intracellular Ca(2+) to micromolar levels in whole-cell recordings does not activate SK channels in a cell line derived from primary rat microglia (MLS-9). In intact cells, riluzole raised cytoplasmic Ca(2+), but it was marginal (~200 nM) and transient (2 min). Surprisingly then, in whole cell recordings, riluzole rapidly activated SK3 and SK4 channels for as long as it was present, and did not require elevated intracellular Ca(2+). We then used primary rat microglia to analyze expression of several activation markers and inflammatory mediators. Riluzole decreased classical LPS-induced activation, and increased some aspects of IL-4-induced alternative activation. These actions on microglia suggest an additional mechanism underlying the neuroprotective actions of riluzole.

Kv1.1 and Kv1.3 channels contribute to the degeneration of retinal ganglion cells after optic nerve transection in vivo.

Degeneration of retinal ganglion cells (RGCs) - an important cause of visual impairment - is often modeled by optic nerve transection, which leads to apoptotic death of these central nervous system neurons. With this model, we show that specific voltage-gated K(+) channels (Kv1 family) contribute to the degeneration of rat RGCs and expression of apoptosis-related molecules in vivo. Retinal expression of Kv1.1, Kv1.2, Kv1.3 and Kv1.5 was examined by quantitative real-time reverse transcriptase-PCR and immunohistochemistry. Kv channel blockers and channel-specific short-interfering RNAs (siRNAs) were used to assess their roles in RGC degeneration. We found that (i) rat RGCs express Kv1.1, Kv1.2 and Kv1.3 (but not Kv1.5); (ii) intraocular injection of agitoxin-2 or margatoxin, potent blockers of Kv1.1, Kv1.2 and Kv1.3 channels, dose-dependently reduced the RGC degeneration; (iii) siRNAs applied to the cut optic nerve were rapidly transported throughout RGCs only, in which they reduced the expression of the cognate channel only. Our results show differential roles of the channels; siRNAs directed against Kv1.1 or Kv1.3 channels greatly reduced RGC death, whereas Kv1.2-targeted siRNAs had only a small effect, and siRNAs against Kv1.5 were without effect. (iv) Kv1.1 and Kv1.3 channels apparently contribute to cell-autonomous death of RGCs through different components of the apoptotic machinery. Kv1.1 depletion increased the antiapoptotic gene, Bcl-X(L), whereas Kv1.3 depletion reduced the proapoptotic genes, caspase-3, caspase-9 and Bad.

The repulsive guidance molecule, RGMa, promotes retinal ganglion cell survival in vitro and in vivo.

The repulsive guidance molecule, RGMa, and its receptor Neogenin, regulate neuronal cell death during development, but little is known about their expression and roles in the adult CNS. Here, we show that Neogenin is expressed in the adult rodent retina, particularly on retinal ganglion cells. To determine whether the Neogenin/RGMa pathway is important in the fully developed retina, we examined its contribution to damage-induced neurodegeneration. The effects of RGMa on survival of retinal ganglion cells (RGCs) were examined in vitro and in vivo. Using cultured whole-mount retinal explants, we showed that the addition of RGMa increased RGC survival and that this effect was mediated by the Neogenin receptor. Immunohistochemical analysis indicated that the inhibition of cell death by RGMa resulted from reduced caspase-3 activation. Then, using an in vivo model of RGC apoptosis after optic nerve transection, we demonstrated that intraocular injection of RGMa at 3 and 7 days after axotomy greatly reduced RGC death 14 days postaxotomy. This study provides the first evidence that RGMa is a molecular target for neuroprotection in retinal pathologies, and suggests that targeting "dependence receptors" such as Neogenin has therapeutic potential for the treatment of neuropathologies in the adult CNS.

Acute exposure to human interferon-alpha affects ion currents in human natural killer cells.

Interferon-alpha (IFN-alpha) is a particularly potent stimulator of human natural killer (NK) cell activity. The initial trigger for IFN action is not known, but there is indirect evidence from a number of cell types that changes in ion channel activity are among the earliest responses. Previous evidence includes changes in Ca2+ fluxes and intracellular activity, membrane potential changes, and effects of ion-channel blockers. Killing by human NK cells is dependent on external Ca2+ and on K+ channel activity. In the present study we have confirmed this dependence and the augmentation by human IFN-alpha. Then we directly studied the effects of IFN-alpha on ion currents in human NK cells using the patch-clamp electrophysiological techniques. We find that IFN-alpha can increase the predominant K+ current near the resting potential but suppresses it at higher voltages. Within 1 min after acute IFN-alpha treatment a new current is induced. This small current appears to be through nonselective cation channels that allow monovalent and divalent cations, including Ca2+ to permeate. This current presents a possible early triggering mechanism whereby acute exposure to IFN-alpha augments NK cytotoxicity.

Spontaneous action potentials produced by Na and Cl channels in maturing Rana pipiens oocytes.

The electrical excitability of maturing Rana pipiens oocytes was studied using intracellular recording and voltage-clamp techniques. Naturally ovulated oocytes, removed from the body cavity within a few hours after ovulation, possess voltage-sensitive Na and Cl channels that can produce action potentials (ap's). Young oocytes (sometime during metaphase I to first polar body stage) can generate trains of spontaneous action potentials: no chemical treatment or current injection is required. This is the first report of spontaneous repetitive firing in an egg cell membrane. As the oocyte matures, the duration of each ap increases because the outward Cl- current decreases. Middle-aged oocytes (about first polar body stage to metaphase II) have continuously positive membrane potentials (Vm's). Mature, activatable (metaphase II) oocytes have negative Vm's when impaled but can produce a long-lived ap when depolarizing current is injected. The ap's differ fundamentally from ap's in other excitable cells, including eggs: the Na+ current develops slowly and does not inactivate; most of the outward current is carried by Cl-, not by K+; the Cl channel is lost or is rendered insensitive to voltage as the oocyte matures.

A role for action potentials in maturing Rana pipiens oocytes.

Intracellular electrical recording and voltage-clamp techniques were used to investigate possible roles for the action potentials (ap's) of Rana pipiens oocytes. The peak of each spontaneous or evoked ap is at or near the equilibrium potential for Na; therefore, the internal Na+ activity (aiNa) can be calculated from the Nernst equation. During maturation from metaphase I to metaphase II, aiNa increases from about 5 to 23 mM. By using three methods to prevent ap's from firing (voltage clamping, increasing the mechanical damage, adding 5 mM CoCl2 to the Ringer's) it was shown that the increase in aiNa required the existence of ap's. External Co2+ appeared to prevent the ap's by blocking only the Na+ current. Calculations showed that the Na+ influx during an ap could account for the observed increase in aiNa if a gradient or nonuniform distribution of Na+ exists within the oocyte. Preventing the ap's also delayed the onset of shock activatibility, a criterion of maturity. I propose that ap's load the oocyte with Na+ which may regulate the rate of maturation either directly or indirectly.

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.

Nonselective cation channels in intact human T lymphocytes.

Nonselective cation channels were found in single channel recordings from cell-attached patches on human T lymphocytes. These channels were active under conditions that should lead to cell swelling (hypotonic bath solutions with NaCl or KCl); however, a definite dependence of activity on cell swelling has not been proven. Under these conditions similar channels were found in 20 of 23 patches from 11 different blood donors. The current-voltage relation was approximately linear for outward current (11-14 pS) and inwardly rectifying (to 23 pS) when the intact cells were depolarized with high KCl in the bath. The voltage dependence of channel activity is consistent with closing at hyperpolarized membrane potentials (Vm less than or equal to -50 mV) and block of open channels at strongly depolarized membrane potentials (Vm greater than 0 mV). Reversal potentials under all ionic gradients tested are consistent with a channel that is poorly selective between Na+ and K+ ions. Active channels in cell-attached patches were rapidly blocked by bath addition of the membrane-permeant inhibitor quinine. Channels that were active in cell-attached became quiescent after patch excision; however, two patches remained active long enough to obtain current-voltage relations. These were linear with a slope conductance for outward current of 8-11 pS. Because of the clustering of single-channel openings, detailed voltage dependence of kinetics and probability of opening were not studied.

Criteria for perforated-patch recordings: ion currents versus dye permeation in human T lymphocytes.

Nystatin-perforated patches are now frequently used to help preserve cytoplasmic integrity during patch-clamp recordings. We used voltage-dependent K+ currents in human T lymphocytes to compare conventional whole-cell recordings with perforated-patch recordings (PPR). Although there were pronounced differences in the inactivation kinetics, we discovered that our PPR recordings were not "intact". In every case, coinciding with the gradual capacitance transient increase and decrease in access resistance, we observed that large (> MW 800) fluorescent dyes enter the cell from the pipette. These results suggest that caution is required when using differences in the properties of the currents to confirm that the nystatin-containing patch is intact.

Intracellular Ca2+ signaling induced by osmotic shock in human T lymphocytes.

After exposure to hypo-osmotic medium most vertebrate cells are able to reregulate their volume by losing electrolytes (K, Cl) and water, a process called regulatory volume decrease (RVD). The whole process of RVD requires a sensor(s) to detect swelling, a transducer(s) to translate the signal, and effectors that cause electrolyte loss. In many cell types an increase in cytoplasmic calcium (Cai) is the transducer and T lymphocytes were formerly thought to fit this pattern. However, this model was thrown into doubt by experiments on Cai-depleted T cells and by the previous failure to detect Cai changes. In the present study we used Ca fluorescence measurements of fluo-3-loaded normal human T lymphocytes exposed to 60% hypo-osmotic saline in a perfused cuvette. We show that hypo-osmotic shock causes a rapid rise in Cai (averaged over approximately 10(4) cells) due to both release of Ca from internal stores and influx. Ca2+ influx occurred at room temperature as well as at 37 degrees C and at a variety of external Ca2+ concentrations (1, 1.5, 2.5 mM). Following hypo-osmotic shock, reexposure to normal osmolarity restored Cai to resting levels. Cell viability and biological responsiveness were not impaired by these osmotic treatments and the subsequent biphasic Cai rise in response to a mitogenic lectin was normal. Using the whole-cell, patch-clamp technique we have isolated an inward cation current that can be carried by Ca2+. Both this current and the Cai rise were blocked by micromolar gadolinium; hence, this current may provide the Ca2+ influx pathway during a hypo-osmotic shock. Finally, these results and recent information on K, Cl, and cation channels in human T cells are incorporated into a model for RVD in these cells.

Regulation of native Kv1.3 channels by cAMP-dependent protein phosphorylation.

We present evidence that activity of native Kv1.3 channels in human T lymphocytes can be increased by inhibiting phosphatases [using okadaic acid (OA)] or by activating protein kinase A (PKA). OA increased the maximal conductance (Gmax) by 40% and shifted the voltage dependence of activation and inactivation, resulting in a significant increase in window current around the normal membrane potential. PKA inhibition [using the PKA inhibitor peptide PKI-(5-24)] decreased Gmax by 43%, whereas PKA activation [by the Sp diastereomer of adenosine 3',5'-cyclic monophosphothioate (Sp-cAMPS)] increased Gmax by 60% and shifted the inactivation curve, producing an increase in the window current. These results are consistent with our previously published work using cell-attached patches but differ from some studies of Kv1.3. Because we previously reported a similar upregulation by protein kinase C (PKC) activation in these cells, we tested whether the PKA and PKC effects were additive. Our results suggest that PKC-dependent phosphorylation acts as a master switch, inasmuch as calphostin C greatly inhibited the current even after Sp-cAMPS, OA, or PKC activation was used to increase protein phosphorylation. Inasmuch as phosphorylation by both kinases (phorbol ester followed by Sp-cAMPS) abrogated the effects of either kinase alone, our results support the view that Kv1.3 is regulated in a complex manner by serine/threonine phosphorylation.

Modulation of potassium channels in human T lymphocytes: effects of temperature.

1. The predominant channels found in lymphocytes with patch-clamp whole-cell recordings are voltage-gated K+ channels. Several lines of evidence suggest that these channels are involved in lymphocyte function. Most lymphocyte functions are temperature sensitive and have not been correlated with electrophysiology at different temperatures. We have examined the effect of temperature on the voltage-dependent K+ channel in normal human T lymphocytes. Both macroscopic current and single-channel events were studied with whole-cell recordings at temperatures from 5 to 42 degrees C. 2. Peak conductance, activation rate, inactivation rate and rate of recovery from inactivation all increased progressively as the temperature increased. The effect of temperature on channel opening processes was greater at low temperatures. In contrast, the inactivation process was most sensitive to temperature changes above room temperature. Arrhenius plots of conductance and kinetic parameters were curvilinear with no obvious break-points. 3. The increase in whole-cell conductance at 37 degrees C was due to both an increase in the single-channel conductance and in the probability that each channel is open at any time. 4. K+ currents were fitted by Hodgkin-Huxley equations with n4j kinetics providing the best description of the currents at all temperatures tested. 5. Steady-state activation- and inactivation-voltage curves shifted in opposite directions with warming, resulting in a greater area of overlap of the curves ('window' current). The increase in resting K+ channel activity predicted by a greater window current was confirmed with single-channel measurements. 6. The present study has shown that the behaviour of K+ channels in human T lymphocytes is temperature dependent.

Cl- channels in intact human T lymphocytes.

We recently described a large, multiple-conductance Cl- channel in excised patches from normal T lymphocytes. The properties of this channel in excised patches are similar to maxi-Cl- channels found in a number of cell types. The voltage dependence in excised patches permitted opening only at nonphysiological voltages, and channel activity was rarely seen in cell-attached patches. In the present study, we show that Cl- channels can be activated in intact cells at physiological temperatures and voltages and that channel properties change after patch excision. Maxi-Cl- channels were reversibly activated in 69% of cell-attached patches when the temperature was above 32 degrees C, whereas fewer than 2% of patches showed activity at room temperature. Upon excision, the same patches displayed large, multiple-conductance Cl- channels with characteristics like those we previously reported for excised patches. After patch excision, warm temperatures were not essential to allow channel activity; 37% (114/308) of inside-out patches had active channels at room temperature. The voltage dependence of the channels was markedly different in cell-attached recordings compared with excised patches. In cell-attached patches, Cl- channels could be open at cell resting potentials in the normal range. Channel activation was not related to changes in intracellular Ca2+ since neither ionomycin nor mitogens activated the channels in cell-attached patches, Ca2+ did not rise in response to warming and the Cl- channel was independent of Ca2+ in inside-out patches. Single-channel currents were blocked by internal or external Zn2+ (100-200 microM), 4-acetamido-4' isothiocyanostilbene-2,2'-disulfonate (SITS, 100-500 microM) and 4,4'-diisothiocyanostilbene 2,2'-disulfonate (DIDS, 100 microM). NPPB (5-nitro-2-(3-phenylpropylamino)-benzoate) reversibly blocked the channels in inside-out patches.

Native Kv1.3 channels are upregulated by protein kinase C.

The voltage-gated potassium channel, Kv1.3, which is highly expressed in a number of immune cells, contains concensus sites for phosphorylation by protein kinase C (PKC). In lymphocytes, this channel is involved in proliferation-through effects on membrane potential, Ca2+ signalling, and interleukin-2 secretion-and in cytotoxic killing and volume regulation. Because PKC activation (as well as increased intracellular Ca2+) is required for T-cell proliferation, we have studied the regulation of Kv1.3 current by PKC in normal (nontransformed) human T lymphocytes. Adding intracellular ATP to support phosphorylation, shifted the voltage dependence of activation by +8 mV and inactivation by +17 mV, resulting in a 230% increase in the window current. Inhibiting ATP production and action with "death brew" (2-deoxyglucose, adenylylimidodiphosphate, carbonyl cyanide-m-chlorophenyl hydrazone) reduced the K+ conductance (GK) by 41 +/- 2%. PKC activation by 4 beta-phorbol 12,13-dibutyrate, increased GK by 69 +/- 6%, and caused a positive shift in activation (+9 mV) and inactivation (+9 mV), which resulted in a 270% increase in window current. Conversely, several PKC inhibitors reduced the current. Diffusion into the cell of inhibitory pseudosubstrate or substrate peptides reduced GK by 43 +/- 5% and 38 +/- 8%, respectively. The specific PKC inhibitor, calphostin C, potently inhibited Kv1.3 current in a dose- and light-dependent manner (IC50 approximately 250 nM). We conclude that phosphorylation by PKC upregulates Kv1.3 channel activity in human lymphocytes and, as a result of shifts in voltage dependence, this enhancement is especially prevalent at physiologically relevant membrane potentials. This increased Kv1.3 current may help maintain a negative membrane potential and a high driving force for Ca2+ entry in the presence of activating stimuli.

Interactive effects of Na and K in killing by human natural killer cells.

Contact-mediated lysis by human natural killer cells is inhibited by a number of drugs that block the predominant K channel. In this study we have further examined the role of the K channel and the interactions between passive K and Na transport in killing. Low external Na-inhibited killing and inhibition were not due to reduce inward current through the Na channels in the target cell. A role for the Na/H antiport is suggested since amiloride inhibited killing in a dose-dependent manner that was competitive with external Na. Depolarizing the killer cell with elevated external K did not inhibit killing. On the contrary, high K0 reduced the inhibition caused by low Na0 and by the K-channel blockers quinidine, verapamil, and retinoic acid. Hyperpolarizing the killer cell with low K0 or valinomycin inhibited killing. Valinomycin, which should prevent the depolarization caused by K-channel block, did not reverse the effect of the blockers quinidine, verapamil, and 4-aminopyridine. Hence, the primary role of the K channels during killing is not maintain the negative membrane potential. On the contrary, depolarization may promote killing under conditions where killing is submaximal.

Modulation of potassium channels in intact human T lymphocytes.

1. A voltage-dependent K+ channel called the 'n' type (for 'normal') is the most prevalent ion channel found in whole-cell recordings from T lymphocytes. In whole-cell patch-clamp recordings activity of the n-type channel is affected by mitogenic agents, pH, Ca2+ and temperature but not by cyclic nucleotides. Because channel properties and regulation can depend on cytoplasmic components we sought to reassess the properties of K+ channels in intact, normal human T lymphocytes using cell-attached, patch-clamp recordings. In the present study, we show that the predominant K+ channel in resting, intact cells is the n type and is affected by voltage, temperature and Ca2+ in ways similar to the disrupted cell. Moreover, K+ channels are activated by agents that raise cyclic AMP in intact cells. 2. In cell-attached recordings, we found voltage-activated K+ channels in about 60% of patches at room temperature. The channel was K+ selective as judged from the reversal potential under different Ka(+)-K+ gradients and at different resting membrane potentials. Some patches were subsequently excised and the selectivity further confirmed. The current-voltage relation was inwardly rectifying under symmetrical K+ concentrations and had a slope conductance of 9.4 pS at 50 mV depolarized and 23.8 pS at 50 mV hyperpolarized from the resting potential. From the reversal potentials under various conditions the cell resting potential was -51 +/- 1 mV in normal NaCl saline and about 0 mV when the bath contained 150 mM-KCl saline. Two other types of K+ channel were seen in resting, intact cells, but were much less common (less than 5% and 11% of patches). A large-conductance K+ channel was seen in less than 1% of inside-out patches. 3. The predominant K+ channel in intact, resting T lymphocytes was confirmed as the n type underlying the whole-cell K+ current evoked by voltage steps. In cell-attached patches there was a low, steady-state level of activity at the resting potential but activity was greatly increased by depolarizing voltage jumps. Steady-state inactivation could be removed by a hyperpolarizing pre-pulse. Ensemble currents constructed by summing channel openings during repeated voltage jumps showed sigmoid kinetics of current activation and a monoexponential decay phase. These kinetics were well fitted by a Hodgkin-Huxley-type n4j kinetic model with time constants very similar to the whole-cell current of disrupted cells. Moreover, the kinetics depended on the external K+ concentration as previous research has shown.(ABSTRACT TRUNCATED AT 400 WORDS)