Development of a delayed outward-rectifying K+ conductance in cultured mouse peritoneal macrophages

Whole-cell currents in macrophages: I. Human monocyte-derived macrophages

We examined the variability of occurrence and frequency of voltage-dependent whole-cell currents in human peripheral blood monocyte-derived macrophages (HMDM) maintained in culture for up to three weeks. An increase in cell capacitance from an average value of 9 pF on the day of isolation to 117 pF at 14 days accompanied growth and differentiation in culture. The average resting potential was approximately -34 mV for cells beyond two days in culture. Cells exhibited a voltage- and time-dependent outward current upon membrane depolarization above approximately -30 mV, which appeared to be composed of a number of separate currents with variable expression from donor to donor. Three of these currents are carried by K+. The frequency of each outward current type was calculated for 974 cells obtained from 36 donors. The HMDMs in these studies exhibited two 4-aminopyridine (4-AP) sensitive, time-dependent outward currents (IA and IB) that could be differentiated on the basis of the presence or absence of steady-state inactivation in the physiological potential range, time course of inactivation during maintained depolarization, as well as threshold of activation. The 4-AP-insensitive outward current activated at approximately 10 mV. One component of the 4-AP insensitive-outward current (IC) could be blocked by external TEA and by the exchange of internal CS+ or Na+ for K+. The probability of observing IB and IC appeared to be donor dependent. Following total replacement of internal K+ with CS+, two additional currents could be identified (i) a delayed component of outward current (ID) remained which could be blocked by low concentrations of external Zn2+ (4 microM) and was insensitive to anion replacement in the external solution and (ii) a Cl- current with a reversal potential which shifted in the presence of external anion replacement and which was irreversibly inhibited by the stilbene SITS. The activation of a prominent time-independent inward current was often observed with increasing hyperpolarization. This inward current was blocked by external Ba2+ and corresponded to the inwardly rectifying K+ current. Neither inward nor outward current expression appeared dependent on whether cells were differentiated in adherent or suspension culture nor was there demonstrable differential current expression observed upon transition from suspension to adherent form.

Cultured microglial cells have a distinct pattern of membrane channels different from peritoneal macrophages

Microglia are the source of the resident macrophages of the brain and thus belong to one of the most reactive cell types in cerebral tissue. They are attributed to have an important role in a number of pathological conditions, such as multiple sclerosis, viral infections like AIDS, and in lethal or sublethal injuries of neurons where the blood-brain barrier is left intact (Streit et al., 1988; McGeer et al., 1988; Gendelman et al., 1989). Microglia share a number of macrophage characteristics but so far lack a distinguishing positive marker. In this study it is shown that microglia are distinguished from other macrophages by a unique pattern of ion channels. We compared membrane currents of microglial cells with those from peritoneal macrophages cultured under identical conditions. Although in macrophages a delayed outward K+ current was previously described (Randriamampita and Trautmann, 1987), microglial cells lacked any specific outward current. Instead, these cells were characterized by large inwardly rectifying currents, activated by hyperpolarizing voltage steps. The reversal potential in different K+ gradients and the sensitivity of the current to to Ba2+, TEA, and 4-AP indicates that this current is K+ selective. In single-channel recordings, a 30 pS K+ selective channel similar to the classical inward rectifier K+ channel was observed. Thus, the expression of membrane channels served not only to distinguish microglia from other cells inside and outside the brain, e.g., blood macrophages, but also suggests a unique functional state of this cell population.

Whole-cell currents in macrophages: II. Alveolar macrophages

Although an outwardly rectifying K+ conductance has been described in murine peritoneal macrophages and a murine macrophage cell line, the expression of this conductance in human monocyte-derived macrophages (HMDMs) is rare. Whole-cell current recordings in this study were obtained from HMDMs differentiated in adherent culture for varying periods of time following isolation and compared to currents obtained in human alveolar macrophages (HAMs) obtained from bronchoalveolar lavage. These studies were undertaken to compare ionic current expression in the in vitro differentiated macrophage to that of a human tissue macrophage. HAMs are the major population of immune and inflammatory cells in the normal lung and are the most readily available source of human tissue macrophages. Of the 974 HMDMs in the study obtained from a total of 36 donors, we were able to observe the presence of the inactivating outward current (IA) which exhibited voltage-dependent availability in only 49 (or 5%) of the cells. In contrast, whole-cell current recordings from HAMs, revealed a significantly higher frequency of IA expression (50% in a total of 160 cells from 26 donors). In the alveolar cell, there was no correlation observed between cell size and peak IA amplitude, nor was there a relationship between peak IA amplitude and time in culture. The current in both cell types was K+ selective and 4-aminopyridine (4-AP) sensitive. IA in both cell types inactivated with a time course which was weakly voltage-dependent and which exhibited a time constant of recovery from inactivation of approximately 30 sec. The time course of current inactivation was dependent upon the external K+ concentration. An increase in the time constant describing current decay was observed in elevated K+. Current activation was half-maximal at approximately -18 mV in normal bathing solution. Steady-state inactivation was half-maximal at approximately -44 mV. The presence of the outwardly rectifying K+ conductance may alter the potential of the mononuclear phagocyte to respond to extracellular signals mediating chemotaxis, phagocytosis, and tumoricidal functions.

Effect of adherence, cell morphology, and lipopolysaccharide on potassium conductance and passive membrane properties of murine macrophage J774.1 cells

The effects of adherence, cell morphology, and lipopolysaccharide on electrical membrane properties and on the expression of the inwardly rectifying K conductance in J774.1 cells were investigated. Whole-cell inwardly rectifying K currents (Ki), membrane capacitance (Cm), and membrane potential (Vm) were measured using the patch-clamp technique. Specific Ki conductance (GKi, whole-cell Ki conductance corrected for leak and normalized to membrane capacitance) was measured as a function of time after adherence, and was found to increase almost twofold one day after plating. Membrane potential (Vm) also increased from -42 +/- 4 mV (n = 32) to -58 +/- 2 mV (n = 47) over the same time period. GKi and Vm were correlated with each other; GL (leak conductance normalized to membrane capacitance) and Vm were not. The magnitudes of GKi and Vm 15 min to 2 hr after adherence were unaffected by the presence of 100 microM cycloheximide, but the increase in GKi and Vm that normally occurred between 2 and 8 hr after adherence was abolished by cycloheximide treatment. Membrane properties were analyzed as a function of cell morphology, by dividing cells into three categories ranging from small round cells to large, extremely spread cells. The capacitance of spread cells increased more than twofold within one day after adherence, which indicates that spread cells inserted new membrane. Spread cells had more negative resting membrane potentials than round cells, but GKi and GL were not significantly different. Lipopolysaccharide-(LPS; 1 or 10 micrograms/ml) treated cells showed increased Cm compared to control cells plated for comparable times. In contrast to the effect of adherence, LPS-treated cells exhibited a significantly lower GKi than control cells, indicating that the additional membrane did not have as high a density of functional GKi channels. We conclude that both adherence and LPS treatment increase the total surface membrane area of J774 cells and change the density of Ki channels. In addition, this study demonstrates that membrane area and density of Ki channels can vary independently of one another.

Chloride and potassium channels in U937 human monocytes

Ionic channels in a human monocyte cell line (U937) were studied with the inside-out patch-clamp technique. A Ca2(+)-activated K+ channel and three Cl- -selective channels were observed. The Ca2(+)-activated K+ channel had an inward-rectifying current-voltage relationship with slope conductance of 28 pS, and was not dependent on membrane potential. Among the three Cl- channels, an outward-rectifying 28-pS channel was most frequently observed. The permeability ratio (Cl-/Na+) was 4-5 and CH3SO4- was also permeant. The channel became less active with increasing polarizations in either direction, and was inactive beyond +/- 120 mV. The channel, observed as bursts, occasionally had rapid events within the bursts, suggesting the presence of another mode of kinetics. Diisothiocyanatostilbene-disulfonic acid (DIDS) blocked the channel reversibly in a dose-dependent manner. The second 328-pS Cl- channel had a linear current-voltage relationship and permeability ratio (Cl-/Na+) of 5-6. This channel became less active with increasing polarizations and inactive beyond +/- 50 mV. DIDS blocked the channel irreversibly. The channel had multiple subconductance states. The third 15-pS Cl- channel was least frequently observed and least voltage sensitive among the Cl- channels. Intracellular Ca2+ or pH affected none of the three Cl- channels. All three Cl- channels had a latent period before being observed, suggesting inhibitory factor(s) present in situ. Activation of the cells with interferon-gamma, interferon-alpha A or 12-O-tetradecanoylphorbol-13-acetate (TPA) caused no change in the properties of any of the channels.

State-dependent inactivation of K+ currents in rat type II alveolar epithelial cells

Inactivation of K+ channels responsible for delayed rectification in rat type II alveolar epithelial cells was studied in Ringer, 160 mM K-Ringer, and 20 mM Ca-Ringer. Inactivation is slower and less complete when the extracellular K+ concentration is increased from 4.5 to 160 mM. Inactivation is faster and more complete when the extracellular Ca2+ concentration is increased from 2 to 20 mM. Several observations suggest that inactivation is state-dependent. In each of these solutions depolarization to potentials near threshold results in slow and partial inactivation, whereas depolarization to potentials at which the K+ conductance, gK, is fully activated results in maximal inactivation, suggesting that open channels inactivate more readily than closed channels. The time constant of current inactivation during depolarizing pulses is clearly voltage-dependent only at potentials where activation is incomplete, a result consistent with coupling of inactivation to activation. Additional evidence for state-dependent inactivation includes cumulative inactivation and nonmonotonic from inactivation. A model like that proposed by C.M. Armstrong (1969. J. Gen. Physiol. 54: 553-575) for K+ channel block by internal quaternary ammonium ions accounts for most of these properties. The fundamental assumptions are: (a) inactivation is strictly coupled to activation (channels must open before inactivating, and recovery from inactivation requires passage through the open state); (b) the rate of inactivation is voltage-independent. Experimental data support this coupled model over models in which inactivation of closed channels is more rapid than that of open channels (e.g., Aldrich, R.W. 1981. Biophys. J. 36:519-532). No inactivation results from repeated depolarizing pulses that are too brief to open K+ channels. Inactivation is proportional to the total time that channels are open during both a depolarizing pulse and the tail current upon repolarization; repolarizing to more negative potentials at which the tail current decays faster results in less inactivation. Implications of the coupled model are discussed, as well as additional states needed to explain some details of inactivation kinetics.

Macrophage-colony-stimulating factor (CSF-1) modulates a differentiation-specific inward-rectifying potassium current in human leukemic (HL-60) cells

A voltage-activated inward-rectifying K+ conductance (lKi) appears in human promyelocytic leukemia (HL-60) cells during phorbol ester-induced differentiation into macrophages. This conductance was detected in the cells 24 hours after exposure to phorbol-12-myristate-13-acetate (PMA), as the cells began to express the macrophage phenotype, and continued to increase for 4 days after PMA exposure. The magnitude of inward current was a function of external K+; current was blocked by extracellular or intracellular Cs+ and by extracellular Ba++. Hyperpolarization produced activation at membrane potentials more negative than -80 mV, and a slower, partial inactivation also occurred at potentials more negative than -100 mV. This conductance was not detected in proliferating cells nor in granulocytes derived from HL-60 cells which were induced to differentiate with retinoic acid (RA). Exposure of differentiated macrophages to recombinant human CSF-1 produced inhibition of the lKi beginning within 1 minute after exposure. CSF-1 inhibition of lKi channels in cell-attached patches indicated that channel modulation was via intracellular mediators. The rapid inhibition of the inward rectifier by the macrophage-specific CSF-1 appears to be one of the earliest cellular responses to this factor.

Voltage-dependent and Ca2(+)-activated ion channels in human neutrophils

To investigate the regulation of membrane voltage and transmembrane ion fluxes in human neutrophils, we studied plasma membrane currents using the whole-cell patch-clamp method. We observed three distinct ion channel currents: (a) a voltage-dependent K+ current, (b) a Ca2(+)-activated K+ current, and (c) a Ca2(+)-activated Cl- current. The voltage-dependent K+ current was found in cells at rest. Its conductive properties suggested an inwardly rectifying channel. The channel was activated at membrane potentials more positive than -60 mV, suggesting that it may determine the resting membrane potential of neutrophils. Activation of neutrophils by the Ca2+ ionophore ionomycin led to an increase in whole-cell K+ and Cl- currents. The Ca2(+)-activated K+ channel differed from the voltage-dependent K+ channel because it was insensitive to voltage, because it rectified outwardly, and because the voltage-sensitive K+ channel was Ca2(+)-independent. The Ca2(+)-activated Cl- channel showed outward rectification and no apparent voltage dependency. The Ca2(+)-activated K+ and Cl- channels may play a role in cell volume homeostasis and/or cellular activation.

Voltage-dependent potassium channels in mouse Schwann cells

1. Ionic currents in Schwann cells cultured from enzymatically dissociated sciatic nerves of newborn mice were recorded by the whole-cell variation of the patch-clamp technique. 2. In these cells only the voltage-dependent K+ currents were recorded. The K+ current was suppressed by quinine, 4-aminopyridine (4-AP) or tetraethylammonium (TEA), their half-suppression concentrations being 22 microM, 0.3 mM and 15 mM, respectively. 3. The peak amplitudes and density of the K+ currents in these Schwann cells increased rapidly during the first 2 days of the culture. 4. In an investigation of the linkage between K+ channels and Schwann cell proliferation, three different K+ channel blockers (quinine, 4-AP and TEA) were added to the medium at different stages of the culture. In media containing sublethal doses of quinine or 4-AP, the start of cell proliferation was delayed when these drugs were added at 12 h or on day 3. The same doses of these drugs applied on day 6, when the Schwann cells were proliferating, did not affect cell proliferation. TEA showed a discrepancy between the dose-dependent blocking of K+ channels and cell proliferation because of its additional cytotoxic effects. 5. It is concluded that voltage-dependent K+ channels in mouse Schwann cells are similar to those observed in human and murine T lymphocytes. These K+ channels are suggested to be involved in Schwann cell proliferation at early stages of development.

The role of potassium channels in Schwann cell proliferation in Wallerian degeneration of explant rabbit sciatic nerves

1. Patch clamp studies of whole-cell ionic currents and biochemical studies of proliferation were carried out on Schwann cells of myelinated axons in explant segments of sciatic nerves of adult rabbit maintained in culture for 0-10 days. 2. Schwann cell proliferation, as assayed by [3H]thymidine incorporation and by electron microscopic autoradiography, showed an increase following nerve explant. Proliferation proceeded in parallel with a gradual hyperpolarization of the resting potential and an increase in K+ currents in Schwann cells of myelinated axons. 3. The relation between K+ channels and proliferation was studied by incubating explant nerves in the presence of various K+ channel blockers. Quinine, TEA and 4-aminopyridine (4-AP), which blocked K+ currents in Schwann cells, were found also to block Schwann cell proliferation in a dose-dependent fashion and over similar concentrations. Electron microscopy showed that TEA did not retard myelin and axonal break-down which is thought to be the source of mitogens for Schwann cell proliferation. 4. The relation between resting potential and proliferation was studied by incubating explant nerves in depolarizing culture media. Depolarizing monovalent cations (K+ and Rb+) led to a marked inhibition of Schwann cell proliferation. However, Cs+ and NH4+, which did not depolarize Schwann cells in patch clamp studies, also inhibited proliferation. Gramicidin and veratridine also inhibited proliferation. 5. The results suggest that the expression of K+ channels is functionally important for Schwann cell proliferation in Wallerian degeneration. A possible link between K+ channel and proliferation might be via a hyperpolarization of the resting membrane potential which occurs when Schwann cells proliferate.

Voltage-activated ionic channels and conductances in embryonic chick osteoblast cultures

Patch-clamp measurements were made on osteoblast-like cells isolated from embryonic chick calvaria. Cell-attached-patch measurements revealed two types of high conductance (100-250 pS) channels, which rapidly activated upon 50-100 mV depolarization. One type showed sustained and the other transient activation over a 10-sec period of depolarization. The single-channel conductances of these channel types were about 100 or 250 pS, depending on whether the pipettes were filled with a low K+ (3 mM) or high K+ (143 mM) saline, respectively. The different reversal potentials under these conditions were consistent with at least K+ conduction. Whole-cell measurements revealed the existence of two types of outward rectifying conductances. The first type conducts K+ ions and activates within 20-200 msec (depending on the stimulus) upon depolarizing voltage steps from less than -60 mV to greater than -30 mV. It inactivates almost completely with a time constant of 2-3 sec. Recovery from inactivation is biphasic with an initial rapid phase (1-2 sec) followed by a slow phase (greater than 20 sec). The second whole-cell conductance activates at positive membrane potentials of greater than +50 mV. It also rapidly turns on upon depolarizing voltage steps. Activation may partly disappear at the higher voltages. Its single channels of 140 pS conductance were identified in the whole cell and did conduct K+ ions but were not highly Cl- or Na+ selective. The results show that osteoblasts may express various types of voltage controlled ionic channels. We predict a role for such channels in mineral metabolism of bone tissue and its control by osteoblasts.

Extracellular ATP induces a large nonselective conductance in macrophage plasma membranes

Extracellular ATP in its tetra-anionic form (ATP4-) induces ion fluxes and membrane depolarization in the mouse macrophage-like cell line J774.2 and in resident mouse macrophages. We analyzed the effects of extracellular ATP4- by both patch-clamp and intracellular microelectrode techniques. Whole-cell patch-configuration membrane potential measurements on J774.2 cells revealed that ATP4- -induced depolarization occurred within 40 ms of pulsed application of ATP and was completely reversible. The depolarizations were accompanied by a dramatic increase in membrane conductance and showed no sign of adaptation to ATP over a period of 30 min. At 5 mM total ATP (ATPt) the whole-cell conductance was approximately 10 nS, and an upper limit of 20 pS for a single-channel conductance has been established. The reversal potential associated with the ATP-induced depolarization at asymmetric K+, Na+, Ca2+, and Cl- concentrations across the membrane was 0 mV. In patch-clamped cells depolarization was complete at 20 microM ATP4-, and repolarization from full depolarization occurred in approximately 5 s. In contrast, in intact cells measured by microelectrode impalement, complete depolarization occurred at approximately 2 mM ATP4- and repolarization was much slower (approximately 100 min). These findings indicate that the changes in intracellular ionic composition that occur after ATP treatment affect the rate of cell repolarization. At lower concentrations of ATP, potassium conductances modulated the depolarizing effect of ATP. ATP also depolarized mouse peritoneal macrophages, but a variant cell line (ATPR B2), derived from J774.2 cells by prolonged exposure to ATP, was insensitive to ATP. Our results provide a membrane electrophysiological description and analysis of a large nonselective plasma membrane conductance of macrophages induced by extracellular ATP.

Patch-clamp studies in human macrophages: single-channel and whole-cell characterization of two K+ conductances

Human peripheral blood monocytes cultured for varying periods of time were studied using whole-cell and single-channel patch-clamp recording techniques. Whole-cell recordings revealed both an outward K current activating at potentials greater than 20 mV and an inwardly rectifying K current present at potentials negative to -60 mV. Tail currents elicited by voltage steps that activated outward current reversed near EK, indicating that the outward current was due to a K conductance. The I-V curve for the macroscopic outward current was similar to the mean single-channel I-V curve for the large conductance (240 pS in symmetrical K) calcium-activated K channel present in these cells. TEA and charybdotoxin blocked the whole-cell outward current and the single-channel current. Excised and cell-attached single-channel data showed that calcium-activated K channels were absent in freshly isolated monocytes but were present in greater than 85% of patches from macrophages cultured for greater than 7 days. Only 35% of the human macrophages cultured for greater than 7 days exhibited whole-cell inward currents. The inward current was blocked by external barium and increased when [K]o increased. Inward-rectifying single-channel currents with a conductance of 28 pS were present in cells exhibiting inward whole-cell currents. These single-channel currents are similar to those described in detail in J774.1 cells (L.C. McKinney & E.K. Gallin, J. Membrane Biol. 103:41-53, 1988).

Phagocytosis by human macrophages is accompanied by changes in ionic channel currents

The present study has shown that changes in ionic channel currents accompany the phagocytosis of particles by mononuclear phagocytes. The patch-clamp technique in the cell-attached configuration was applied to human monocyte-derived macrophages to measure the activity of single transmembrane ionic channels in intact cells. During such measurements, IgG-opsonized and non-opsonized latex particles were offered for phagocytosis under continuous video-microscopical observation. Single particles were presented to the phagocytes at a membrane location some distance from that of the patch electrode. After a lag period following particle attachment, enhanced inward and outward time-variant single channel currents coinciding with particle engulfment were observed. On the basis of current-voltage characteristics and membrane potential measurements, the outward-directed channels were identified as K+ channels. Phagocytosis was also accompanied by slow transient changes in background membrane currents, probably due to changes in the membrane potential of the phagocytosing cell. Phagocytosis of IgG-coated latex particles differed from phagocytosis of uncoated or albumin-coated particles by a shorter lag time between particle attachment and the onset of enhanced ionic channel activity.

Macroscopic Ca2+ -Na+ and K+ currents in single heart and aortic cells

The whole-cell voltage clamp technique was used to study the slow inward currents and K+ outward currents in single heart cells of embryonic chick and in rabbit aortic cells. In single heart cells of 3-day-old chick embryo three types of slow inward Na+ currents were found. The kinetics and the pharmacology of the slow INa were different from those of the slow ICa in older embryos. Two types of slow inward currents were found in aortic single cells of rabbit; angiotensin II increased the sustained type and d-cAMP and d-cGMP decreased the slow transient component. Two types of outward K+ currents were found in both aortic and heart cells. Single channel analysis demonstrated the presence of a high single K+ channel conductance in aortic cells. In cardiac and vascular smooth muscles, slow inward currents do share some pharmacological properties, although the regulation of these channels by cyclic nucleotides and several drugs seems to be different.

A whole-cell and single-channel study of the voltage-dependent outward potassium current in avian hepatocytes

Voltage-dependent membrane currents were studied in dissociated hepatocytes from chick, using the patch-clamp technique. All cells had voltage-dependent outward K+ currents; in 10% of the cells, a fast, transient, tetrodotoxin-sensitive Na+ current was identified. None of the cells had voltage-dependent inward Ca2+ currents. The K+ current activated at a membrane potential of about -10 mV, had a sigmoidal time course, and did not inactivate in 500 ms. The maximum outward conductance was 6.6 +/- 2.4 nS in 18 cells. The reversal potential, estimated from tail current measurements, shifted by 50 mV per 10-fold increase in the external K+ concentration. The current traces were fitted by n2 kinetics with voltage-dependent time constants. Omitting Ca2+ from the external bath or buffering the internal Ca2+ with EGTA did not alter the outward current, which shows that Ca2+-activated K+ currents were not present. 1-5 mM 4-aminopyridine, 0.5-2 mM BaCl2, and 0.1-1 mM CdCl2 reversibly inhibited the current. The block caused by Ba was voltage dependent. Single-channel currents were recorded in cell-attached and outside-out patches. The mean unitary conductance was 7 pS, and the channels displayed bursting kinetics. Thus, avian hepatocytes have a single type of K+ channel belonging to the delayed rectifier class of K+ channels.

Voltage-dependent K+ currents and underlying single K+ channels in pheochromocytoma cells

Properties of the whole-cell K+ currents and voltage-dependent activation and inactivation properties of single K+ channels in clonal pheochromocytoma (PC-12) cells were studied using the patch-clamp recording technique. Depolarizing pulses elicited slowly inactivating whole-cell K+ currents, which were blocked by external application of tetraethylammonium+, 4-aminopyridine, and quinidine. The amplitudes and time courses of these K+ currents were largely independent of the prepulse voltage. Although pharmacological agents and manipulation of the voltage-clamp pulse protocol failed to reveal any additional separable whole-cell currents in a majority of the cells examined, single-channel recordings showed that, in addition to the large Ca++-dependent K+ channels described previously in many other preparations, PC-12 cells had at least four distinct types of K+ channels activated by depolarization. These four types of K+ channels differed in the open-channel current-voltage relation, time course of activation and inactivation, and voltage dependence of activation and inactivation. These K+ channels were designated the Kw, Kz, Ky, and Kx channels. The typical chord conductances of these channels were 18, 12, 7, and 7 pS in the excised configuration using Na+-free saline solutions. These four types of K+ channels opened in the presence of low concentrations of internal Ca++ (1 nM). Their voltage-dependent gating properties can account for the properties of the whole-cell K+ currents in PC-12 cells.

Ionic channels and membrane hyperpolarization in human macrophages

Microelectrode impalement of human macrophages evokes a transient hyperpolarizing response (HR) of the membrane potential. This HR was found to be dependent on the extracellular concentration of K+ but not on that of Na+ or Cl-. It was not influenced by low temperature (12 degrees C) or by 0.2 mM ouabain, but was blocked by 0.2 mM quinine or 0.2 mM Mg2+-EGTA. These findings indicate that the HR in human macrophages is caused by the activation of a K+ (Ca2+) conductance. Two types of ionic channels were identified in intact cells by use of the patch-clamp technique in the cell-attached-patch configuration, low and high-conductance voltage-dependent K+ channels. The low-conductance channels had a mean conductance of 38 pS with Na+-saline and 32 pS with K+-saline in the pipette. The high-conductance channels had a conductance of 101 and 114 pS with Na+- and K+-saline in the pipette, respectively. Cell-attached patch measurements made during evocation of an HR by microelectrode penetration showed enhanced channel activity associated with the development of the HR. These channels were also high-conductance channels (171 pS with Na+- and 165 pS K+-saline in the pipette) and were voltage dependent. They were, however, active at less positive potentials than the high-conductance K+ channels seen prior to the microelectrode-evoked HR. It is concluded that the high-conductance voltage-dependent ionic channels active during the HR in human macrophages contribute to the development of the HR.

A patch-clamp study of mammalian platelets and their voltage-gated potassium current

1. Mammalian platelets were freshly isolated from human, rabbit, or rat blood. The whole-cell and cell-attached voltage-clamp variations of the patch-clamp technique were employed to study the passive electrical properties and ion channels of unstimulated platelets. 2. The input capacitance of a platelet measured by the phase-sensitive detection method was about 128 fF, the input resistance of a platelet was about 59 G omega and the resting membrane potential was about -50 mV which was directly measured by a whole-cell recording in the current-clamp mode. 3. The predominant ion channel was a voltage-gated K+ channel resembling the delayed rectifier K+ channel of nerve, muscle and T-lymphocyte. There was no indication of any inward current in the platelet membrane. The activation of the K+ current could be fitted by n4 kinetics, and was half-maximal at about -35 mV. 4. The time constant of K+ current inactivation was virtually independent of voltage and varied from cell to cell. Recovery from inactivation was slow and dependent on the size and duration of the preceding conditional voltage step. Steady-state inactivation was half-maximal at about -50 mV and was complete at positive potentials. 5. The predominant single-K+-channel conductance was 9 pS and the estimated number of K+ channels per platelet was about 325, corresponding to a density of 25/micron2 apparent membrane area.

Single-channel activity in sea urchin sperm revealed by the patch-clamp technique

Ionic fluxes are deeply involved in the response of spermatozoa to the egg. Using the patch-clamp technique, we show for the first time single ion channel activity in sea urchin spermatozoa and spermatozoa heads. Due to their small size gigaseals were obtained in suspended cells by applying suction through the pipette. The rate of gigaseal formation was very low and improved to 6% (n = 1145) when flagella were detached from sperm. Current-voltage curves created from single-channel events showed conductances of approx. 65 and 170 pS, suggesting the presence of two types of channels. At least one appears to be a K+ channel.

Elevation of a potassium current in differentiating human leukemic (HL-60) cells

Human promyelocytic leukemia (HL-60) cells display a novel voltage-dependent outward current under voltage clamp. This current is present at low levels in the proliferative state and in granulocytes derived from HL-60 cells which were induced to differentiate with retinoic acid. It is elevated in macrophages derived from HL-60 cells after exposure to phorbol-12-myristate-13-acetate (PMA). The current is carried primarily by K+, is blocked by Cs+ and by increased intracellular concentrations of Cl-. From a holding potential of -80 mV, significant activation required depolarization to +20 mV membrane potential. Activation was not influenced by intracellular Ca2+ (1-2 X 10(-6) M). These properties appear to differ significantly from the Ca2+-activated K+ channel and the delayed rectifier. The increase of this voltage-activated current in differentiation toward the macrophage, but not the granulocyte, suggests that this current is correlated specifically with macrophage differentiation.

Ionic channels in murine macrophages

In this paper we examine the different voltage or calcium-dependent currents present in murine peritoneal macrophages, and in a macrophage-like cell line, J774. Three of these are K currents while the fourth is carried by Cl. One K current, activated by hyperpolarization, has all the characteristics of the inward rectifier found in egg or muscle cells. It appears in peritoneal macrophages only after several days in culture. A second K current, activated by depolarization, is a typical delayed rectifier. The amplitude of these currents and, as a consequence, the membrane potential of the cells, can be markedly changed by the movement of fluid around the cells. A third K current is activated by internal calcium levels in the micromolar range. It presents a low-voltage sensitivity and is blocked by 0.1-1 mM quinine. The Cl current flows through large-size channels (180-390 pS) that are active mainly in excised patches. These channels are unlikely to be half gap junctional channels, as suggested in former studies. The second goal of this paper is to examine if the activation of receptors for the Fc fragment of IgGs (Fc receptors) is associated with a change in the electrical properties of the membrane of macrophages. We have observed that the binding of multivalent ligands (the monoclonal antibody 2.4G2, aggregated IgGs, or sheep red blood cells coated with IgGs) to their Fc receptors on adherent macrophages did not trigger any change in resting potential. This is a surprising difference with former results obtained on non-adherent J774 cells (Young, J. D.-E., J. C. Unkeless, H. R. Kaback, and Z. A. Cohn, 1983, Proc. Natl. Acad. Sci. USA., 80:1357-1361) and on human alveolar macrophages (Nelson, D. J., E. R. Jacobs, J. M. Tang, J. M. Zeller and R. C. Bone, 1985, J. Clin. Invest., 76:500-507).

Voltage-dependent conductances of solitary ganglion cells dissociated from the rat retina

1. Ganglion cells were dissociated from the enzyme-treated rat retina, identified with specific fluorescent labels, and maintained in vitro. Electrophysiological properties of solitary retinal ganglion cells were investigated with both conventional intracellular and patch-clamp recordings. Although comparable results were obtained for most measurements some important differences were noted. 2. The input resistance of solitary retinal ganglion cells was considerably higher when measured with 'giga-seal' suction pipettes than with conventional intracellular electrodes. Under current-clamp conditions with both intracellular and patch pipettes, these central mammalian neurones maintained resting potentials of about -60 mV and displayed action potentials followed by an after-hyperpolarization in response to small depolarizations. The membrane currents during this activity, analysed under voltage clamp with patch pipettes, consisted of five components: Na+ current (INa), Ca2+ current (ICa), and currents with properties similar to the delayed outward, the transient (A-type), and the Ca2+-activated K+ currents (IK, IA and IK(Ca), respectively). 3. Ionic substitution, pharmacological agents, and voltage-clamp experiments revealed that the regenerative currents were carried by both Na+ and Ca2+. 100 nM-1 microM-tetradotoxin (TTX) reversibly blocked the fast spikes carried by the presumptive INa, which under voltage-clamp analysis had classical Hodgkin-Huxley-type activation and inactivation. 4. Single-channel recordings of the Na+ current (iNa) permitted comparison of these 'microscopic' events with the 'macroscopic' whole-cell current (INa). The inactivation time constant (tau h) fitted to the averaged single-channel recordings of iNa in outside-out patches was slower than the tau h obtained during whole-cell recordings of INa. 5. In the presence of 1-40 microM-TTX and 20 mM-TEA, slow action potentials appeared in intracellular recordings and were probably mediated by Ca2+. The potentials were abrogated by 3 mM-Co2+ or 200 microM-Cd2+; conversely, increasing the extracellular Ca2+ concentration from 2.5 to 10-25 mM or substitution of 1 mM-Ba2+ for 2.5 mM-Ca2+ enhanced their amplitude. ICa was measured directly in whole-cell recordings with patch pipettes after blocking INa with extracellular 1 microM-TTX and K+ currents with intracellular 120-mM Cs+ and 20 mM-TEA. 6. During whole-cell recordings with patch electrodes, extracellular 20 mM-TEA suppressed IK and, to a lesser extent, IA. Extracellular 5 mM-4-AP or a pre-pulse of the membrane potential to -40 mV prior to stronger depolarization completely blocked IA.(ABSTRACT TRUNCATED AT 400 WORDS)

Two types of potassium channels in murine T lymphocytes

The properties of two types of K+ channels in murine T lymphocytes are described on the basis of whole-cell and isolated-patch recordings using the gigohm-seal technique. Type l (standing for "lpr gene locus" or "large") channels were characterized mainly in T cells from mutant MRL/MpJ-lpr/lpr mice, in which they are present in large numbers. Type n ("normal") K+ channels are abundant and therefore most readily studied in concanavalin A-activated T cells from four strains of mice, MRL-+/+, CBA/J, C57BL/6J, and BALB/c. Type l channels, compared with type n, are activated at potentials approximately 30 mV more positive, and close much more rapidly upon repolarization. Type l channels inactivate more slowly and less completely than type n during maintained depolarization, but recover from inactivation more rapidly, so that little inactivation accumulates during repetitive pulses. Type l channels have a higher unitary conductance (21 pS) than type n (12 pS) and are less sensitive to block by external Co++, but are 100-fold more sensitive to block by external tetraethylammonium (TEA), with half-block of type l channels at 50-100 microM TEA compared with 8-16 mM for type n. TEA blocks both types of channels by reducing the apparent single channel current amplitude, with a dose-response relation similar to that for blocking macroscopic currents. Murine type n K+ channels resemble K+ channels in human T cells.

Mitogen induction of ion channels in murine T lymphocytes

Using gigohm-seal recording, we studied ion channel expression in resting and activated T lymphocytes from mice. Both the number of channels per cell and the predominant type of K+ channel depend upon the state of activation of the cell. Unstimulated T cells express small numbers of K+ channels, typically a dozen per cell, and are heterogeneous, usually expressing either type n or type l K+ channels (see DeCoursey, T. E., K. G. Chandy, S. Gupta, and M. D. Cahalan. 1987. Journal of General Physiology. 89:379-404). 1 d after stimulation by the murine T cell mitogen concanavalin A, large numbers of type n K+ channels appear in enlarged, activated cells. Type n channels appear in activated cells with a time course consistent with that reported for mitogen-induced enhancement of protein synthesis. Voltage-gated tetrodotoxin-sensitive Na+ channels present in about one-third of unstimulated cells from the MRL-n strain are increased approximately 10-fold after activation.

Ion channels in human macrophages compared with the U-937 cell line

The human cell line U-937 has been used extensively to model many macrophage functions. We have examined the cell membranes of human monocyte-derived macrophages (HMDM) and U-937 cells to compare membrane properties as expressed by single ion channel currents. The patch-clamp technique was applied to isolated, nonactivated, inside-out patches of cell membranes obtained from HMDM and from the U-937 cell line. Voltage-gated potassium channels of similar conductance but different kinetics are present in both types of cells, and a calcium-activated potassium channel is present only in the HMDM. These differences in ion channel properties suggest fundamentally different behavior between these two cell types at the level of the cell membrane.

Changes in the expression of potassium channels during mouse T cell development

In this report we have combined the whole-cell electrophysiological recording technique with flow microfluorometry to isolate phenotypically defined thymocytes and T lymphocytes. Results obtained showed that J11d-/Lyt-2-/L3T4- cells express none or very few delayed rectifier K+ channels, whereas most other Lyt-2-/L3T4- cells, as well as typical cortical thymocytes (Lyt-2+/L3T4+), do express K+ channels. Mature (Lyt-2+/L3T4- or Lyt-2-/L3T4+) thymocytes, which are heterogeneous for J11d expression, were also found to be heterogeneous for K+ channel expression. Consistent with this finding was the observation that the cortisone-resistant subpopulation of thymocytes, which express low levels of J11d, were enriched for cells expressing low levels of K+ channels. Mature phenotype peripheral T lymphocytes expressed very low levels of K+ channels, but upon activation with Con A were found to express high levels of K+ channels. The results suggest that K+ channel expression in T cells is developmentally regulated. Increased expression of the channel is induced in response to mitogenic signals throughout the T cell lineage. Expression of the channel, therefore, serves as a useful marker in defining steps in the T cell differentiation pathway.

K channels are expressed early in human T-cell development

Mature human T lymphocytes proliferate in response to the mitogen phytohemagglutinin (PHA), but immature thymocytes lacking the T3 receptor (T3- thymocytes) do not. Because functioning K channels are required for proliferation of mature T cells, we asked whether immunoincompetent T3- thymocytes lack normal K channels. We report that T3- thymocytes have a K+ current similar to that of mature peripheral T cells--that is, similar voltage dependence, activation and inactivation kinetics, and pharmacology. Moreover, the maximal specific K+ conductance is the same for both cell types, implying a similar density of activable channels in each cell. In assessing the functional responses of the channels to PHA, we found that the K+ current of immature and mature cells responds similarly to the mitogen. Responses near the threshold voltage for activating the K+ current were variable; the K+ conductance and rate of activation were increased, decreased, or unchanged after PHA treatment. For several cells, the voltage dependence of the conductance and activation kinetics was shifted in opposite directions. At more positive voltages, PHA consistently caused a 10-20% suppression of conductance that was not due to the addition of an inward current, to changes in the time course of activation or inactivation, or to changes in the steady-state level of inactivation. The effects of PHA on the K+ current cannot be explained by a simple shift in surface potential, as has been hypothesized to be involved in its triggering of T-cell proliferation. Taken together, our findings show K channels are expressed very early in T-cell differentiation, possibly before thymic processing, differential responses of the K+ current to PHA do not account for the failure of T3- thymocytes to proliferate, and changes in surface potential are probably not a necessary early event in activation of T cells by PHA.

Voltage-gated potassium conductance in human T lymphocytes stimulated with phorbol ester

The whole-cell patch-clamp method was used to study the voltage-gated K+ conductance of human peripheral blood T lymphocytes. After entry into whole-cell recording mode, there are time-dependent changes in some properties of the conductance. Over the first 10-30 min, the threshold for activation shifts about 10 mV more negative, and the rates of activation and inactivation increase. Inactivation is less strongly voltage dependent than activation or deactivation. Lymphocytes were stimulated to proliferate in culture with the tumour promoter 12-O-tetradecanoylphorbol-13-acetate (TPA). No changes in K+ conductance were observed in the first few hours of TPA stimulation. At 24 h after mitogen addition, TPA-treated cells were found to have 1.7-fold greater average voltage-gated K+ conductance than unstimulated control cells. At 48 h, TPA-stimulated cells had the same average K+ conductance as at 24 h, even though the cells were now much increased in size, as measured by cell capacitance. DNA synthesis by cultures stimulated with TPA, phytohaemagglutinin or succinyl concanavalin A was depressed by the addition of 0.1 mM-quinine at any point in the culture period. In the first 20 h after mitogen addition, DNA synthesis was more effectively inhibited by quinine than if the drug were added later. Cell proliferation was equally sensitive to quinine regardless of mitogen.

Potassium channels mediate killing by human natural killer cells

Human natural killer (NK) cells in peripheral blood spontaneously recognize and kill a wide variety of target cells. It has been suggested that ion channels are involved in the killing process because there is a Ca-dependent stage and because killings by presensitized cytotoxic T lymphocytes, which in many respects resembles NK killing, is associated with changes in K and Na transport in the target cell. However, no direct evidence exists for ion channels in NK cells or in their target cells. Using the whole-cell variation of the patch-clamp technique, we found a voltage-dependent potassium (K+) current in NK cells. The K+ current was reduced in a dose-dependent manner by the K-channel blockers 4-aminopyridine and quinidine and by the traditional Ca-channel blockers verapamil and Cd2+. We tested the effects of ion-channel blockers on killing of two commonly used target cell lines: K562, which is derived from a human myeloid leukemia, and U937, which is derived from a human histiocytic leukemia. Killing of K562 target cells, determined in a standard 51Cr-release assay, was inhibited in a dose-dependent manner by verapamil, quinidine, Cd2+, and 4-aminopyridine at concentrations comparable to those that blocked the K+ current in NK cells. In K562 target cells only a voltage-dependent Na+ current was found and it was blocked by concentrations of tetrodotoxin that had no effect on killing. Killing of U937 target cells was also inhibited by the two ion-channel blockers tested, quinidine and verapamil. In this cell line only a small K+ current was found that was similar to the one in NK cells. We could not find any evidence of a Ca2+ current in target cells or in NK cells; therefore, our results cannot explain the Ca dependence of killing. Our findings show that there are K channels in NK cells and that these channels play a necessary role in the killing process. In contrast, the endogenous channel type in the target cell is probably not a factor in determining target cell sensitivity to natural killing.

Differential expression of inward and outward potassium currents in the macrophage-like cell line J774.1

J774.1 cells, a mouse-derived macrophage-like tumour cell line, were voltage clamped using whole-cell patch-clamp techniques. Cells were maintained in suspension cultures and plated at varying times before recording. The average zero-current potential of long-term adherent (greater than 24 h) cells was -77.6 mV. A tenfold increase in [K]o produced a 49 mV shift in zero-current potential. Freshly plated cells (less than 24 h) expressed two voltage-dependent currents: an outward current expressed transiently from 1 to 12 h post-plating and an inward current expressed 2-4 h post-plating which persisted in 100% of long-term adherent cells. Inward current was dependent upon voltage, time and [K]o 1/2, similar to the anomalous rectifier of other tissues. The conductance activated at potentials negative to -50 mV and plateaued at potentials negative to -110 mV. Inactivation was evident at potentials negative to -100 mV. Both the rate and extent of inactivation increased with hyperpolarization. Inward rectification was blocked by external BaCl2 or CsCl. The outward current was time- and voltage-dependent. The instantaneous I/V curves derived from tail experiments reversed at the potassium equilibrium potential (EK). A tenfold change of [K]o shifted the reversal potential 52 mV, indicating that the current was carried by potassium. This conductance activated at potentials positive to -50 mV, plateaued at potentials positive to -10 mV and inactivated completely with an exponential time course at all potentials. At voltages positive to -25 mV the rate of inactivation was independent of voltage. The outward current was blocked by 4-aminopyridine or D600. During the first 10 min after attaining a whole-cell recording, the conductance/voltage relation of the outward current shifted to more negative voltages and peak conductance showed a slight increase; recordings then stabilized. The voltage dependence of the inward current did not shift with time but wash-out of inward current was observed in some cells. The J774.1 cell line can serve as a model for the study of the role of voltage-dependent ionic conductances in macrophages.

Potassium channels in cultured bovine adrenal chromaffin cells

K channels of bovine adrenal chromaffin cells were studied using patch-clamp techniques. Whole-cell K currents measured near +10 mV were much larger in 1 mM-external Ca than in Ca-free saline. Noise analysis suggested that this Ca-dependent current was carried by a large unitary conductance channel, called BK channel, which was previously described in inside-out patches (Marty, 1981). The Ca-dependent K current near +10 mV declined with time due to 'run-down' of Ca channels. At the same time, a fraction of the outward current observed above +50 mV was also eliminated. This outward current component probably represents K efflux through Ca channels. Whole-cell Ca-dependent K currents were studied using various Ca buffers. EGTA buffers were surprisingly inefficient: in order to block the current entirely, it was necessary to use an isotonic EGTA solution and to increase internal pH. 1,2-bis(o-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid (BAPTA) was at least five times more efficient than EGTA. In isolated patches three types of single-channel K currents were observed. Under normal ionic conditions (140 mM-K inside, 140 mM-Na outside), the unitary conductances measured between -20 and +40 mV were 96 pS, 18 pS and 8 pS. The 96 pS channels are the Ca-dependent BK channels. 18 pS and 8 pS channels were both activated and then inactivated by membrane depolarization. Both displayed complex kinetics; single-channel currents were grouped in bursts. Activation and inactivation kinetics were faster for the 18 pS channel (therefore termed FK channel, for fast K channel) than for the 8 pS channel (SK channel, for slow or small amplitude channel). The voltage dependence of opening probability was steeper for the FK channel as compared to the SK channel.

Immunoglobulin G-induced single ionic channels in human alveolar macrophage membranes

While it is well known that the engagement of IgG Fc receptors on the macrophage surface triggers a number of cellular responses, including particle ingestion, secretion, and respiratory burst activity, the mechanism of signal transmission following ligand binding remains poorly understood. To acquire more data in this area, we studied the electrical properties of the macrophage membrane and its response to oligomeric immunoglobulin G (IgG) using the patch-clamp technique on human alveolar macrophages that were obtained by bronchoalveolar lavage and maintained in short-term tissue culture. The results showed that cell resting potentials, as determined from whole-cell tight seal recordings, increased from -15 mV on the day of plating to -56 mV after the first day in culture and remained stable at this hyperpolarized level. Macrophages revealed an input resistance of 3.3 G omega, independent of age in culture. Extracellular application of heat-aggregated human IgG to cells voltage-clamped at -70 mV resulted in peak inward currents of approximately 470 pA. We identified an IgG-dependent, nonselective channel in both cell-attached and isolated membrane patches, with a unitary conductance of approximately 350 pS and a predominant subconductance level of 235 pS in symmetrical NaCl solutions. Single channel open times were observed to be in the range of seconds and, in addition, were dependent upon membrane voltage. Channel opening involved transitions between a number of kinetic states and subconductance levels. Channel events recorded in cell-attached patches showed characteristic exponential relaxations, which implied a variation in membrane potential as a result of a single ion channel opening. These data suggest that the IgG-dependent nonselective cation channel that we have characterized may provide the link between Fc receptor engagement and subsequent cellular activation.

A voltage-gated potassium channel in human T lymphocytes

Human peripheral T lymphocytes were studied at 20-24 degrees C using the gigaohm seal recording technique in whole-cell or outside-out patch conformations. The predominant ion channel present under the conditions employed was a voltage-gated K+ channel closely resembling delayed rectifier K+ channels of nerve and muscle. The maximum K+ conductance in ninety T lymphocytes ranged from 0.7 to 8.9 nS, with a mean of 4.2 nS. The estimated number of K+ channels per cell is 400, corresponding to a density of about three channels/micron2 apparent membrane area. The activation of K+ currents could be fitted by Hodgkin-Huxley type n4 kinetics. The K+ conductance in Ringer solution was half-maximal at -40 mV. The time constant of K+ current inactivation was practically independent of voltage except near the threshold for activating the K+ conductance. Recovery from inactivation was slow and followed complex kinetics. Steady-state inactivation was half-maximal at -70 mV, and was complete at positive potentials. Permeability ratios, relative to K+, determined from reversal potential measurements were: K+(1.0) greater than Rb+(0.77) greater than NH4+(0.10) greater than Cs+ (0.02) greater than Na+(less than 0.01). Currents through K+ channels display deviations from the independence principle. The limiting outward current increases when external K+ is increased, and Rb+ carries less inward current than expected from its relative permeability. Tail current kinetics were slowed about 2-fold by raising the external K+ concentration from 4.5 to 160 mM, and were 5 times slower in Rb+ Ringer solution than in K+ Ringer solution. Single K+ channel currents had two amplitudes corresponding to about 9 and 16 pS in Ringer solution. Replacing Ringer solution with isotonic K+ Ringer solution increased the unitary conductance and resulted in inward rectification of the unitary current-voltage relation. Comparable effects of external K+ were seen in the whole-cell conductance and instantaneous current-voltage relation. Several changes in the K+ conductance occurred during the first few minutes after achievement of the whole-cell conformation. Most are explainable by dissipation of a 10-20 mV junction potential between pipette solution and the cytoplasm, and by the use of a holding potential more negative than the resting potential. However, inactivation of K+ currents became faster and more complete, changes not accounted for by these mechanisms. K+ efflux through open K+ channels in intact lymphocytes, calculated from measured properties of K+ channels, can account for efflux values reported in resting lymphocytes, and for the increase in K+ efflux upon mitogenic stimulation.(ABSTRACT TRUNCATED AT 400 WORDS)

Ion channels in lymphocytes

The advent of the gigaohm-seal recording technique has enabled the study of the electrical properties of small cells, such as individual lymphocytes. Recent studies using this technique in combination with standard immunological and biochemical techniques indicate that cells of the immune system may utilize ion channels, similar in properties to those described in nerve and muscle, in the process of activation. For example, potassium channels may be required for T-lymphocyte mitogenesis and calcium channels for antibody production. This article summarizes these recent reports.