Interaction of chemotactic factors with human macrophages. Induction of transmembrane potential changes.

The electrophysiology of chemotactic factor interaction with cultured human macrophages was investigated with standard intracellular recording techniques. In initial studies, E. coli endotoxin-activated serum, added to cell cultures during intracellular recordings, caused membrane hyperpolarizations which were greater than 30 s in duration, 10-50 mV in amplitude, and associated with decreased membrane resistance. Control serum produced smaller hyperpolarizations lasting 10-20 s and 5-30 m V in amplitude. Endotoxin-activated human serum deficient in the third complement component (C3) did not produce hyperpolarizations unless the serum was reconstituted with C3 before activation. Fractionation of normal activated serum by molecular seive chromatography (G-75 Sephadex) indicated that only fractions that eluted with an estimated molecular weight of 12,500 produced membrane potential changes. The active material that was chemotactic for the macrophages was identified as the small molecular weight cleavage product of C5, C5a, by heat stability (30 min at 56 degrees C) and inactivation by goat antisera to human C5 but not C3. 17 percent of macrophages stimulated with C5a exhibited a biphasic response characterized by a small (2-6 mV), brief (1-10 s) depolarization associated with a decreased membrane resistance preceding the larger and prolonged hyperpolarizations. Magnesium-ethylene glycol bis[beta-aminoethyl ether]N,N'-tetraacetic acid (Mg [2.5 mM]-EGTA [5.0 mM]) blocked the C5a-evoked potential changes, whereas colchine (10(- 6)M) and cytochalasin B (3.0 mug/ml did not. Hydrocortisone sodium succinate (0.5 mg/ml) decreased the percentage of cells responding to C5a. In related studies, synthetic N-formyl methionyl peptide (f-met-leu-phe), which had chemotactic activity for cultured macrophages, produced similar membrane potential changes. Repeated exposure of macrophages to C5a or f- met-leu-phe resulted in desensitization to the same stimulus. Simultaneous photomicroscope and intracellular recording studies during macrophage stimulation with chemotactic factor demonstrated that the membrane potential changes preceded membrane spreading, ruffling, and pseudopod formation. These observations demonstrate that ion fluxes associated with membrane potential changes are early events in macrophage activation by chemotactic factors

Nonlinear current-voltage relationships in cultured macrophages.

Intracellular recordings of cultured mouse thioglycolate-induced peritoneal exudate macrophages reveal that these cells can exhibit two different types of electrophysiological properties characterized by differences in their current-voltage relationships and their resting membrane potentials. The majority of cells had low resting membrane potentials (-20 to -40 mV) and displayed current-voltage relationships that were linear for inward-going current pulses and rectifying for outward-going pulses. Small depolarizing transients, occurring either spontaneously or induced by current pulses, were seen in some cells with low resting membrane potentials. A second smaller group of cells exhibited more hyperpolarized resting membrane potentials (-60 to -90 mV) and S-shaped current-voltage relationships associated with a high-resistance transitional region. Cells with S-shaped current-voltage relationships sometimes exhibited two stable states of membrane potential on either side of the high-resistance transitional region. These data indicate that macrophages exhibit complex electrophysiological properties often associated with excitable cells.

Voltage clamp studies in macrophages from mouse spleen cultures.

Voltage clamp studies of macrophages from cultures of mouse spleen macrophages produced N-shaped steady-state current-voltage curves containing a region of negative slope resistance. Some macrophages exhibit two stable states of membrane potential, having current-voltage relationships that cross the voltage axis at three points. Outward currents that turn on at voltages of +15 millivolts or greater were noted in several cells. The addition of barium chloride to the bathing medium abolished the negative slope resistance and reduced the inward currents in response to hyperpolarizing voltage steps. These data provide direct evidence that macrophages exhibit at least tow different voltage-dependent conductances and demonstrate that voltage clamp techniques can be useful in studying the membrane properties of leukocytes.

Ionic channels in leukocytes.

In the past several years, with the advent of the patch clamp technique, the field of leukocyte electrophysiology has grown considerably. With the exceptions of the neutrophil and the eosinophil, electrophysiological and biochemical techniques have been used to characterize a number of types of voltage- or ligand-gated ionic channels in the different classes of leukocytes. This article reviews each of the ionic channels described in leukocytes and their functional relevance. It should be emphasized that this is by no means a final listing of the ionic channels in leukocytes, but merely a summary of the studies to date. It is highly likely that there are many other ionic channels in leukocytes with important functional implications that have not yet been discovered.

Enhanced activity of the macrophage-like cell line J774.1 following exposure to gamma radiation.

Exposure of the macrophage-like cell line J774.1 to 20 gray of cobalt-60 gamma radiation resulted in a block of tritiated thymidine incorporation, along with an increase in cell "activation," as assessed by increases in lysosomal enzyme and ectoenzyme content, PMA-induced H2O2 production, and NBT staining, ingestion of E(IgG), spreading, and membrane ruffling. These changes are evident within 1 day postradiation and peak at 4 days postradiation.

The formyl peptide chemoattractant receptor is encoded by a 2 kilobase messenger RNA. Expression in Xenopus oocytes.

Activation of the formyl peptide chemoattractant receptor (FPCR) of phagocytic cells mobilizes intracellular calcium stores and affects the plasma membrane potential. Affinity crosslinking of FPCR has demonstrated a 60-80 kDa glycoprotein, with core peptide of 32 kDa. It is not known whether functional FPCR is this single peptide or requires multiple subunits. We used Xenopus oocyte expression system to determine the size of mRNA required for synthesis of functional FPCR. Injection of oocytes with poly(A)+ RNA from HL60 cells differentiated to the granulocyte phenotype resulted in acquisition of formyl peptide-specific responses (inward transmembrane current with a reversal potential consistent with a chloride conductance, and calcium efflux). FPCR activity expressed in oocytes had a ligand concentration dependence, ligand structure dependence and pertussis toxin sensitivity similar to those reported in phagocytic cells. When RNA was size fractionated, a single peak of FPCR activity at 2 kilobases was observed after injection of mRNA into oocytes. Our data strongly suggest that FPCR is composed of a single-sized polypeptide.

Calcium- and voltage-activated potassium channels in human macrophages.

Single calcium-activated potassium channel currents were recorded in intact and excised membrane patches from cultured human macrophages. Channel conductance was 240 pS in symmetrical 145 mM K+ and 130 pS in 5 mM external K+. Lower conductance current fluctuations (40% of the larger channels) with the same reversal potential as the higher conductance channels were noted in some patches. Ion substitution experiments indicated that the channel is permeable to potassium and relatively impermeable to sodium. The frequency of channel opening increased with depolarization and intracellular calcium concentration. At 10(-7) M (Ca++)i, channel activity was evident only at potentials of +40 mV or more depolarized, while at 10(-5) M, channels were open at all voltages tested (-40 to +60 mV). In intact patches, channels were seen at depolarized patch potentials of +50 mV or greater, indicating that the ionized calcium concentration in the macrophage is probably less than 10(-7) M.

Electrophysiological properties of macrophages.

Electrophysiological studies indicate that the macrophage can display at least two different K conductances, a Ca-mediated K conductance and an inward rectifying K conductance, as well as an electrogenic Na+-K+ pump. Spontaneous hyperpolarizations associated with a Ca-mediated K permeability have been noted in all types of macrophages studied. Similar membrane hyperpolarizations can be elicited by a variety of stimuli that presumably increase intracellular calcium. These include mechanical and electrical stimulation as well as exposure to endotoxin-activated serum, chemotactic peptides, and the Ca ionophore A23187. Recent patch clamp studies on macrophages demonstrated channel activity that probably corresponds to currents through the inward rectifying K conductance previously described with current clamp techniques. With the advent of the patch clamp, this and other conductances can be effectively examined by using both whole-cell voltage clamp and patch recordings in a variety of different macrophages, including small freshly isolated cells.

Evidence for a Ca-activated inwardly rectifying K channel in human macrophages.

Cell-attached patch studies of cultured human macrophages demonstrate that exposure to ionomycin induces inward-rectifying single-channel currents that differ from the voltage-dependent 28 pS inward-rectifying K currents previously described in these cells (J. Membr. Biol. 103: 55-66, 1988). With 150 mM KCl in the electrode and NaCl Hanks' solution in the bath, the ionomycin-induced single-channel conductance for inward currents was 37 pS, and the reversal potential was 57 mV. Channel activity was often associated with a shift in the base-line current level indicating that the cell membrane potential hyperpolarized. The ability of ionomycin to induce channel activity depended on extracellular [Ca] supporting the view that the channels were gated by calcium. Ionomycin-induced channels were permeable to K, relatively impermeable to Cl or Na, exhibited bursting kinetics, and had no apparent voltage dependence. Barium (3 mM in the patch electrode) did not significantly block the ionomycin-induced channel at rest but blocked channel activity when the patch was hyperpolarized beyond the resting membrane potential. Exposure of macrophages to platelet-activating factor, which is known to increase intracellular [Ca] [( Ca]i) (J. Cell Biol. 103: 439-450, 1986), also transiently induced channel activity. In excised patches with 3 microM [Ca]i bursting inward-rectifying channels with a 41 pS conductance were noted that probably correspond to the ionomycin-induced channels present in cell-attached patches. Increasing [Ca]i from 10(-8) to 3 x 10(-6) M induced inward-rectifying channel activity in previously quiescent excised patches.(ABSTRACT TRUNCATED AT 250 WORDS)

Calcium spikes in cultured human reticular cells from peritoneal exudates.

Intracellular recordings of cultured human peritoneal exudate cells reveal that cells within the culture exhibit an active depolarizing response to injected currents which can reach positive potentials and resemble slow spikes. The cells exhibiting spikes are similar to the reticular cells described by Stuart and Davidson (1971a,b) in that they are esterase(+), acid phosphatase(+), and internalize colloidal carbon but not opsonized red blood cells. The active depolarizing response is unaffected by either decreasing the external sodium concentration or by adding tetrodotoxin (3 X 10(-5) M), whereas increasing the external calcium concentration increases both the spike amplitude and rate of rise, and the addition of cobalt (3 mM) blocks the response. Addition of barium increases the duration and amplitude of the spikes but reduces the afterhyperpolarization. The data indicate that cultured human reticular cells from the peritoneal cavity exhibit a calcium spike.

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).

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.

G-protein activators induce a potassium conductance in murine macrophages.

The whole-cell patch clamp technique was used to test whether intracellular application of G-protein activators affect ionic currents in murine macrophages. Both the J774.1 macrophage-like cell line and primary bone marrow derived macrophages were used. Cells were bathed in Na Hanks' solution and intracellularly dialyzed (via the patch pipette) with K Hanks (145 mM KCl, < 100 nM Ca) plus or minus the G-protein activators GTP gamma S (10 microM), GppNHp (10 microM), or AIF4- (200 microM AlCl3 + 5 mM KF). In the absence of G-protein activators, only two K currents, an inwardly rectifying K current (Kir) and an outward, inactivating K current (Ko) were observed. In the presence of protein activators, two effects were observed: (i) the Kir conductance, which is stable for up to 30 min under control conditions, decayed twice as fast and (ii) an outwardly rectifying, noninactivating current appeared. The induced outward current appeared < 2 min after attaining the whole-cell patch clamp configuration. The current could be distinguished from the Kir and Ko currents on the basis of its direction of rectification (outward), barium sensitivity (> 1 mM), and kinetics (no time-dependent inactivation). Intracellular application of GTP (500 microM), GDP (500 microM), cAMP (100 microM + 0.5 mM ATP), or IP3 (20 microM) did not induce the current; 100 microM ATP gamma S activated a half-maximal amount of current. Induction of outward current by 10 microM GTP gamma S could be prevented by pre-exposing cells to pertussis toxin but not cholera toxin. This current is K selective since (i) its induction was accompanied by hyperpolarization of the cell toward EK, even after Kir had "washed out", (ii) it was present after > 90% of both intracellular and extracellular Cl were replaced by isethionate, and (iii) the induced outward conductance was absent when Ki was completely replaced by Cs, and was reduced by approximately 1/3 when [K]i was reduced by 1/3. Quinidine (1 mM) and 4-aminopyridine (10 mM) inhibited the current, but apamin (1 microM) and charybdotoxin (1 microM) did not.

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.

Inositol 1,4,5-trisphosphate concentrations increase after adherence in the macrophage-like cell line J774.1.

Several properties of macrophages change when suspended cells become adherent. To determine the intracellular signals involved in these changes, concentrations of the second messenger inositol 1,4,5-trisphosphate [Ins(1,4,5)P3] were monitored during adherence of J774.1 cells, a macrophage-like cell line. When cells grown in suspension were allowed to adhere to a glass surface, there was a transient increase in InsP3 that reached a peak between 100 and 120 s after plating. Inositol mono- and bis-phosphate concentrations were also elevated 100 and 120 s after plating. Analysis of isomer distribution showed significant 3-fold increases in Ins(1,4,5)P3 and inositol 1,3,4,5-tetrakisphosphate [Ins(1,3,4,5)P4] at 100 s after plating. These values were maintained at 120 s, with the additional appearance of a 4-fold increase in inositol 1,3,4-trisphosphate. The adherence-induced generation of Ins(1,4,5)P3 was decreased, and Ins(1,3,4,5)P4 formation was blocked, in Ca2+-free medium. However, doubling intracellular [Ca2+] by addition of the Ca2+ ionophore ionomycin (1 microM) did not increase Ins(1,4,5)P3 in suspended cells. Adherence of J774.1 cells to fibronectin-coated glass also induced an increase in InsP3.

Modulation of K+ currents in monocytes by VCAM-1 and E-selectin on activated human endothelium.

Resting membrane potential (RMP) and whole cell currents were recorded in human THP-1 monocytes adherent to polystyrene, unstimulated human umbilical vein endothelial cells (HUVECs), lipopolysaccharide (LPS)-treated HUVECs, immobilized E-selectin, or vascular cell adhesion molecule 1 (VCAM-1) using the patch-clamp technique. RMP after 5 h on polystyrene was -24.3 +/- 1.7 mV (n = 42) with delayed rectifier K+ (Idr) and Cl- currents (ICl) present in >75% of the cells. Inwardly rectifying K+ currents (Iir) were present in only 14% of THP-1 cells. Adherence to unstimulated HUVECs or E-selectin for 5 h had no effect on Iir or ICl but decreased Idr. Five hours after adherence to LPS-treated HUVECs, outward currents were unchanged, but Iir was present in 81% of THP-1 cells. A twofold increase in Iir and a hyperpolarization (-41.3 +/- 3.7 mV, n = 16) were abolished by pretreatment of THP-1 cells with cycloheximide, a protein synthesis inhibitor, or herbimycin A, a tyrosine kinase inhibitor, or by pretreatment of the LPS-treated HUVECs with anti-VCAM-1. Only a brief (15-min) interaction between THP-1 cells and LPS-treated HUVECs was required to induce Iir expression 5 h later. THP-1 cells adherent to VCAM-1 exhibited similar conductances to cells adherent to LPS-treated HUVECs. Thus engagement of specific integrins results in selective modulation of different K+ conductances.

Response of Aplysia statocyst receptor cells to physiologic stimulation.

1. The electrical responses of Aplysia statocyst receptor cells were investigated using intracellular micro-electrodes. These ciliated mechanoreceptor cells were stimulated by downward tilting about a horizontal axis. 2. Tilting so that the receptor cell was excited produced a depolarizing receptor potential which, if large enough, could generate action potentials. 3. Large fluctuations in membrane potential were evident during depolarizing receptor potentials and were reduced or sometimes absent when a cell was tilted upward. Power-density spectra of the noise voltage revealed that most of the energy added by downward tilt is contained in frequency components below 3 Hz. 4. Removing synaptic input to the receptor cells by cutting the statocyst nerve or adding excess Mg2+ to the bath did not abolish the increase in fluctuations caused by downward, excitatory tilts. 5. The depolarizing receptor potential was often associated with a decrease in membrane resistance as measured with constant current pulses using a bridge circuit. 6. Replacing most of the Na+ in the bath with either Tris or Mg2+ abolished both potential and resistance changes caused by downward tilt. These results indicate that an increased permeability to Na+ underlies the receptor potential.

Inward rectification in mouse macrophages: evidence for a negative resistance region.

The electrical properties of cultured mouse thioglycollate-induced peritoneal macrophages were investigated using intracellular recording techniques. Thirty-five percent of the cells studied had membrane potentials ranging from -65 to -95 mV and exhibited S-shaped, steady-state current-voltage (I-V) relationships containing a transitional region. Analysis of currents in the transitional region from the rate of rise and fall of the voltage responses to current pulses indicated the presence of a negative resistance region in this area. Tetrodotoxin (3 X 10(-5) M), cobalt chloride (3 mM), 4-aminopyridine (4 mM), and tetraethylammonium chloride (8 mM) did not eliminate the transitional region of the I-V curves, whereas addition of barium chloride (4 mM) and rubidium chloride (3 mM) did. Increasing the external concentration of potassium shifted the I-V relationship horizontally along the current axis but did not eliminate the transitional region. These data indicate that the inward rectification and the negative resistance region probably result from a voltage-dependent potassium conductance.

Demonstration of an electrogenic Na+-K+ pump in mouse spleen macrophages.

The effect of ouabain on the membrane potential of cultured mouse spleen macrophages was examined. Ouabain (10(-3) M) induced a membrane depolarization (6.6 mV) in 18 of 19 cells studied that occurred within several minutes after exposure and was not associated with significant changes in current-voltage relationships. In related studies, cells were placed in K+-free medium in the cold for 2 h to block pump activity. Subsequent exposure to K+ at 37 degrees C resulted in a membrane hyperpolarization. However, addition of K+ also enhanced inward rectification. To differentiate between the effect of K+ on the Na+-K+ pump and its action on inward rectification, two types of experiments were done. Studies performed in the presence of barium, which blocks inward rectification, demonstrated a K+-induced hyperpolarization with no changes in rectification. Additional studies examined the effects of rubidium on Na+-loaded cells. Rubidium, which blocks inward rectification but substitutes for K+ in activating the Na+-K+ pump, induced membrane hyperpolarizations that were reversed by addition of ouabain. These data indicate that macrophages exhibit an electrogenic Na+-K+ pump, which probably contributes to the resting membrane potential under steady-state conditions and can be activated under conditions designed to Na+ load the cells. In addition, they demonstrate that increasing extracellular K+ enhances inward rectification in macrophages.

Exposure to gamma-irradiation increases phorbol myristate acetate-induced H2O2 production in human macrophages.

Cell number, protein, and phorbol myristate acetate (PMA)-induced H2O2 production were measured in cultured human peripheral blood monocytes for six days after exposure to varying doses of gamma-radiation. Both the number of adherent cells and the protein per dish decreased with increasing radiation doses. The dose of radiation decreasing the number of adherent cells by 37% on days 4 and 6 postirradiation was 29 Gy. Four hours postirradiation there was a small decrease in PMA-induced H2O2 production for doses of 7.5 Gy or greater; levels returned to normal by eight hours and increased at 24 hours postirradiation. By day 4 postirradiation significant increases in PMA-induced H2O2 production were noted at all radiation doses (2.5 to 50 Gy). This increase was not due to a shift in the PMA dose-response curve, a change in the time course of the PMA response, or an effect of decreased cell density on the assay system. Superoxide levels were not significantly changed in cells exposed to 20 Gy. Catalase, glutathione peroxidase, and superoxide dismutase levels also were unchanged. Culturing irradiated cells with gamma-interferon increased PMA-induced H2O2 release, which indicated that irradiated cells retained their capacity to respond to gamma-interferon. These data demonstrate that irradiation affects the PMA-induced H2O2 production of human monocytes in a time- and dose-dependent manner. An increase in the release of reactive oxygen intermediates by the macrophage may play a role in enhancing the deleterious effects of radiation in vivo.