The Effect of an Extracellular Mucilage on the Response to Osmotic Shock in the Charophyte Alga Lamprothamnium papulosum

We have used current/voltage (I/V) analysis to investigate the role played by extracellular mucilage in the cellular response to osmotic shock in Lamprothamnium papulosum. Cells lacking extracellular mucilage originated in a brackish environment (1/3 seawater). These were compared, first with cells coated with thick (∼50 μm) extracellular mucilage, collected from a marine lake, and second, with equivalent mucilaginous marine cells, treated with heparinase enzyme to disrupt the mucilage layer. Histochemical stains Toluidine Blue and Alcian Blue at low pH identified the major component of the extracellular mucilage as sulfated polysaccharides. Treating mucilage with heparinase removed the capacity for staining with cationic dyes at low pH, although the mucilage was not removed, and remained as a substantial unstirred layer. Cells lacking mucilage responded to hypotonic shock with depolarization (by ∼95 mV), cessation of cyclosis, due to transient opening of Ca²⁺ channels, and opening of Ca²⁺-activated Cl⁻ channels and K⁺ channels. Cell conductance transiently increased tenfold, but after 60 min was restored to the conductance prior to hypotonic shock. Mucilaginous cells depolarized by a small amount (∼18 mV), but Ca²⁺ channels failed to open in large enough numbers for cyclosis to cease. Likewise most Ca²⁺-activated Cl⁻ channels failed to open and conductance increased only ∼1.2-fold above the prehypotonic level. After 60 min conductance was less than the conductance prior to hypotonic shock. Heparinased mucilaginous cells recovered several aspects of the hypotonic response in cells lacking mucilage. These cells depolarized (by ∼103 mV); cyclosis ceased, indicating that Ca²⁺ channels had opened, and conductance increased to ∼4 times the value prior to hypotonic shock, indicating that Ca²⁺-activated Cl⁻ channels opened. However, after 60 min, these cells had neither restored membrane potential (and remained at positive values), nor decreased their conductance. It was not possible to determine whether K⁺ channels had opened. The heparinased cells recovered the normal hypotonic response of mucilaginous cells when heparinase was washed out. Apical seawater cells, which lacked mucilage, were unaffected by heparinase treatment. The results demonstrate that the presence of extracellular sulfated polysaccharide mucilage impacts upon the electrophysiology of the response to osmotic shock in Lamprothamnium cells. The role of such sulfated mucilages in marine algae and animal cells is compared and discussed. Received: 24 March 1998/Revised: 28 April 1999     

Dual turgor regulation response to hypotonic stress in Lamprothamnium papulosum

Cells of the salt-tolerant charophyte Lamprothamnium respond differently to hypotonic challenge according to their position on the plant (i.e. cell age). Differences in electrophysiological response are coupled with differences in cell fine structure, and the presence or absence of extracellular mucilage. (1) Young, apical (fast-regulating, FR) cells respond with sudden cessation of cyclosis, depolarization to –50 mV (in some cells by more than 100 mV) and increase in membrane conductance by up to an order of magnitude. Intracellular [K⁺]_v, [Na⁺]_v and [Cl^–]_v decrease 1 h after hypotonic challenge. Patch-clamping cytoplasmic droplets reveals two types of K⁺ channel, 150 pS and 35 pS, and a small conductance Cl^– channel, 35 pS (conductances at estimated tonoplast resting potential between zero and 20 mV). Extracellular mucilage is thin (< 5 μm thick) or lacking, similar to freshwater Chara. Unlike freshwater charophytes these cells have a canalicular vacuolar system of large surface area and compartment the fluorochrome 6 carboxyfluorescein in the cytoplasm rather than the vacuolar system. (2) Older basal (slow-regulating, SR) cells do not cease streaming on hypotonic challenge and depolarize only slightly (by approximately 20 mV) with small or no change in membrane conductance. After 1 h the intracellular [K⁺]_v, [Na⁺]_v and [Cl^–]_v scarcely change. Patch-clamping cytoplasmic droplets reveals two types of K⁺ channel, medium conductance 90 pS and low conductance (as in FR cells). The large conductance K⁺ channel was not observed. The Cl^– channel was more active in SR cells. The cells were coated with extracellular mucilage more than 10 μm thick. In a similar manner to freshwater Chara, these cells compartment 6 carboxyfluorescein in a large central vacuole. In the older cells, making up the bulk of any given plant, the simultaneous development of extracellular mucilage and a large central vacuole which compartments 6 carboxyfluorescein is associated with a minimal electrophysiological response to hypotonic challenge. The significance of these findings for salt-tolerance is discussed.     

Chara buckellii, a Euryhaline Charophyte from an Unusual Saline Environment : III. Time Course of Turgor Regulation

The time course of turgor regulation of the euryhaline giant-celled alga, Chara buckellii, is presented. Isolated intermodal cells were challenged by increasing or decreasing the external osmotic pressure by 150 milliosmoles per kilogram with all ions in the media or by dilution, respectively. Regulation following hypotonic stress was complete within 48 hours whereas regulation following hypertonic stress required between 96 and 144 hours. The change in internal osmotic pressure could be entirely accounted for by changes in vacuolar KCl in response to hypotonic stress, but this ion pair only accounted for 45% of the change in response to hypertonic stress. The membrane potential of C. buckellii is normally hyperpolarized with respect to the equilibrium potential for K⁺ (E_K). The membrane depolarized to a level close to E_K in response to hypotonic treatment and this was accompanied by a transient increase in membrane conductance. In response to hypertonic stress, the membrane hyperpolarized transiently, then repolarized to a level close to the control. This was accompanied by a temporary decrease in membrane conductance. The data are discussed with respect to the ecological significance of the time course and ion transport mechanisms during turgor regulation.     

Neuronal membrane potential is mildly depolarized in the anoxic turtle cortex

Neuronal membrane potential (E_m) regulates the activity of excitatory voltage-sensitive channels. Anoxic insults lead to a severe loss of E_m and excitotoxic cell death (ECD) in mammalian neurons. Conversely, anoxia-tolerant freshwater turtle neurons depress energy usage during anoxia by altering ionic conductance to reduce neuronal excitability and ECD is avoided. This wholesale alteration of ion channel and pump activity likely has a significant effect on E_m. Using the whole-cell patch clamp technique we recorded changes in E_m from turtle cortical neurons during a normoxic to anoxic transition in the presence of various ion channel/pump modulators. E_m did not change with normoxic perfusion but underwent a reversible, mild depolarization of 8.1 ± 0.2 mV following anoxic perfusion. This mild anoxic depolarization (MAD) was not prevented by the manipulation of any single ionic conductance, but was partially reduced by pre-treatment with antagonists of GABA_A receptors (5.7 ± 0.5 mV), cellular bicarbonate production (5.3 ± 0.2 mV) or K⁺ channels (6.0 ± 0.2 mV), or by perfusion of reactive oxygen species scavengers (5.2 ± 0.3 mV). Furthermore, all of these treatments induced depolarization in normoxic neurons. Together these data suggest that the MAD may be due to the summation of numerous altered ion conductance states during anoxia.     

Ion channels activated by osmotic and mechanical stress in membranes of opossum kidney cells

Summary For patch-clamp measurements cultured kidney (OK) cells were exposed to osmotic and mechanical stress. Superfusion of a cell in whole cell configuration with hypotonic media (190 mOsm) evokes strong depolarization, which is reversible by returning to the isotonic bath medium. In the cell-attached configuration the exposure to hypotonic media evokes up to six ion channels of homogeneous single-channel properties in the membrane patch. Subsequently, the channels became activated after a time lag of a few seconds. At an applied membrane potential of 0 mV, the corresponding membrane current is directed inward and shows a transient behavior in the time range of minutes. In the same membrane patch these ion channels can be activated by application of negative hydrostatic pressure. The channel has a single-channel conductance of about 22 pS and is permeable to Na⁺ and K⁺ as well as to Cl^–. It is suggested that volume regulation involves mechanoreceptor-operated ion channels.     

Turgor regulation in a brackish water charophyte,Lamprothamnium succinctum

Internodal cells of a brackish water charophyte,Lamprothamnium succinctum (A. Br. in Ash.) R.D.W. regulate the turgor pressure in response to changes in both the cellular and the external osmotic pressures. During turgor regulation upon hypotonic treatment, net effluxes of K⁺ and Cl⁻ from the vacuole, membrane depolarization, a transient increase in the electrical membrane conductance and a transient increase in concentration of cytoplasmic Ca²⁺ are induced. Activation of the plasmalemma Ca²⁺ channels and the Ca²⁺-controlled passive effluxes of K⁺ and Cl⁻ through the plasmalemma ion channels are postulated.     

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

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

Effect of external K+, Ca2+, and Ba2+ on membrane potential and ionic conductance in rat astrocytes

Summary 1. The purpose of this study was (a) to identify if astrocytes show a similar non-Nernstian depolarization in low K⁺ or low Ca²⁺ solutions as previously found in human glial and glioma cells, and (b) to analyze the influence of the K⁺ conductance on the membrane potential of astrocytes.2. The membrane potential (E_m) and the ionic conductance were studied with whole-cell patch-clamp technique in neonatal rat astrocytes (5–9 days in culture) and in human glioma cells (U-251MG).3. In 3.0 mM K⁺, E_m was –75 ± 1.0 mV (mean ± SEM,n=39) in rat astrocytes and –79 ± 0.7 mV (n=5) in U-251MG cells. In both cell types E_m changed linearly to the logarithm of [K⁺]₀ between 3.0 and 160 mM K⁺. K⁺ free medium caused astrocytes to hyperpolarize to –93 ± 2.7 mV (n=21) and U-251MG cells to depolarize to –27 ± 2.1 mV (n=3).4. The I-E curve did not show inward rectification in astrocytes at this developmental stage. The slope conductance (g) exhibited only a small decrease (–19%) in K⁺ free solution and no significant change in 160 mM K⁺.5. Ba²⁺ (1.0 mM) depolarized astrocytes to –45 ± 2.9 mV (n=11), decreasing the slope conductance (g) by 42.4 ± 8.3% (n=11). Ca²⁺ free solution depolarized astrocytes to –53 ± 3.4 mV (n=12) and resulted in a positive shift of the I-E curve, increasing g by 15.3 ± 8.2% (n=8).6. Calculations indicated that a block of K⁺ channels explains the depolarizing effect of Ba²⁺. The effects of K⁺ free or Ca²⁺ free solutions on E_m can be explained by a transformation of K⁺ channels to non-specific leakage channels. That astrocytes show a different reaction to low K⁺ than glioma cells can be related to the lack of inwardly rectifying K⁺ channels in astrocytes at this developmental stage.     

Electrophysiology of Turgor Regulation in Marine Siphonous Green Algae

We review electrophysiological measures of turgor regulation in some siphonous green algae, primarily the giant-celled marine algae, Valonia and Ventricaria, with particular comparison to the well studied charophyte algae Chara and Lamprothamnium. The siphonous green algae have a less negative plasma membrane potential, and are unlikely to have a proton-based chemiosmotic transport system, dominated by active electrogenic K⁺ uptake. We also make note of the unusual cellular structure of the siphonous green algae. Hypertonic stress, due to increased external osmotic pressure, is accompanied by positive-going potential difference (PD), increase in conductance, and slow turgor regulation. The relationship between these is not yet resolved, but may involve changes in K⁺ conductance (G _K) or active K⁺ transport at both membranes. Hypotonic turgor regulation, in response to decreased external osmotic pressure, is ∼3 times faster than hypertonic turgor regulation. It is accompanied by a negative-going PD, although conductance also increases. The conductance increase and the magnitude of the PD change are strongly correlated with the magnitude of hypotonic stress.     

Three Types of Single Voltage-Dependent Potassium Channels in the Sarcolemma of Frog Skeletal Muscle

Patch-clamp experiments in the sarcolemma of frog skeletal muscle evidenced the presence of three types of voltage-dependent single-channel K⁺ currents. According to their unitary conductance at a membrane voltage of +40 mV, we classified them as 16-, 13-, and 7-pS K⁺ channels. The 16-pS K⁺ channels are active close to a membrane voltage of −80 mV and they do not become inactivated during voltage pulses of 100 ms. Within 10 min after beginning the recording, these channels developed rundown with an exponential time course. The 13-pS K⁺ channels are active near −60 mV; upon a 100-ms depolarization, they exhibited inactivation with an approximate exponential time course. The 7-pS K⁺ channels were recorded at voltages positive to 0 mV. In patches containing all three types of K⁺ channels, the ensemble average currents resemble the kinetic properties of the macroscopic delayed rectifier K⁺ currents recorded in skeletal muscle and other tissues. In conclusion, the biophysical properties of unitary K⁺ currents suggest that these single-channel K⁺ currents may underlie the macroscopic delayed K⁺ currents in frog skeletal muscle fibers. In addition, since the 16- and 13-pS channels were more frequently recorded, both are the main contributors to the delayed K⁺ currents.     

The effect of divalent cations on Na+ tolerance in Charophytes. II: Chara corallina

Abstract The freshwater Charophyte Chora corallina dies when subjected to 70 molm^?3 NaCl if the Ca²⁺ concentration is 0.1 mol m ^?3. This stress is accompanied by a depolarization of the cell to a membrane potential more positive than E_K, a net influx of Na⁺ into the vacuole, and a net loss of K⁺ from the vacuole. Raising the Ca²⁺ concentration to 7 mol m ^?3 in the presence of elevated Na⁺ restores the Na⁺ to Ca²⁺ ratio to 10: 1 as in the control solution, and results in enhanced survival even though turgor is not regulated. Mg²⁺ is not a good substitute for Ca²⁺. It is suggested that the main reason that C. corallina fails to occupy saline habitats is its failure to regulate turgor, not sensitivity to Na ⁺, since the latter is similar to that seen in C. buckellii, which is found in saline habitats.     

I. Ion Channels in Human THP-1 Monocytes

The THP-1 human monocytic leukemia cell line is a useful model of macrophage differentiation. Patch clamp methods were used to identify five types of ion channels in undifferentiated THP-1 monocytes. (i) Delayed rectifier K⁺ current, I _DR, was activated by depolarization to potentials positive to −50 mV, inactivated with a time constant of several hundred msec, and recovered from inactivation with a time constant ∼21 sec. I _DR was inhibited by 4-aminopyridine (4-AP), tetraethylammonium (TEA⁺), and potently by charybdotoxin (ChTX). (ii) Ca-activated K⁺ current (I _SK) dominated whole-cell currents in cells studied with 3–10 μm [Ca²⁺] _i . I _SK was at most weakly voltage-dependent, with reduced conductance at large positive potentials, and was inhibited by ChTX and weakly by TEA⁺, Cs⁺, and Ba²⁺, but not 4-AP or apamin. Block by Cs⁺ and Ba²⁺ was enhanced by hyperpolarization. (iii) Nonselective cation current, I _cat, appeared at voltages above +20 mV. Little time-dependence was observed, and a panel of channel blockers was without effect. (iv) Chloride current, I _Cl, was present early in experiments, but disappeared with time. (v) Voltage-activated H⁺ selective current is described in detail in a companion paper (DeCoursey & Cherny, 1996. J. Membrane Biol. 152:2). The ion channels in THP-1 cells are compared with channels described in other macrophage-related cells. Profound changes in ion channel expression that occur during differentiation of THP-1 cells are described in a companion paper (DeCoursey et al., 1996. J. Membrane Biol. 152:2). Received: 19 September 1995/Revised: 14 March 1996     

Involvement of calcium ion in turgor regulation upon hypotonic treatment in Lamprothamnium succinctum

Abstract When internodal cells of Lamprothamnium succinetum were exposed to a hypotonic medium containing more than 1 mol m^?3 Ca²⁺, the elevated turgor pressure decreased and reached a steady state within 30–60 min. The hypotonic treatment caused the membrane potential to depolarize, with a time lag of ca. 1 min. The membrane conductance increased transiently with the same time lag and reached a peak value within 2–3 min. When the external Ca²⁺ concentration was lowered to 0.01 mol m^?3, both turgor regulation and change in the membrane conductance were strongly inhibited, although the membrane depolarization was not affected. When the Ca2+ level was returned to the normal level, the cells recovered their ability for turgor regulation and the membrane conductance attained a peak value after ca. 15–30 s. This response time is definitely shorter than that needed for the conductance change in cells exposed to a hypotonic medium having a normal level of Ca²⁺ from the beginning. We thus conclude that at least two sequential processes are involved in turgor regulation: a Ca²⁺ -independent process, followed by a Ca²⁺-dependent process.     

Diversity of K+ channels in the basolateral membrane of restingnecturus oxyntic cells

Summary Patch-clamp techniques have been applied to characterize the channels in the basolateral membrane of resting (cimetidine-treated, nonacid secreting) oxyntic cells isolated from the gastric mucosa ofNecturus maculosa. In cell-attached patches with pipette solution containing 100mm KCl, four major classes of K⁺ channels can be distinguished on the basis of their kinetic behavior and conductance: (1) 40% of the patches contained either voltage-independent (a) or hyperpolarization-activated (b), inward-rectifying channels with short mean open times (16 msec fora, and 8 msec forb). Some channels showed subconductance levels. The maximal inward conductanceg _max was 31±5 pS (n=13) and the reversal potentialE _rev was atV _p=–34±6 mV (n=9). (2) 10% of the patches contained depolarization-activated and inward-rectifying channels withg _max=40 ±18 pS (n=3) andE _rev was atV _p=–31±5 mV (n=3). With hyperpolarization, the channels open in bursts with rapid flickerings within bursts. Addition of carbachol (1mm) to the bath solution in cell-attached patches increased the open probabilityP _o of these channels. (3) 10% of the patches contained voltage-independent inward-rectifying channels withg _max=21±3 pS (n=4) andE _rev was atV _p=–24±9 mV (n=4). These channels exhibited very high open probability (P _o=0.9) and long mean open time (1.6 sec) at the resting potential. (4) 20% of the patches contained voltage-independent channels with limiting inward conductance of 26±2 pS (n=3) andE _rev atV _p=–33±3 mV (n=3). The channels opened in bursts consisting of sequential activation of multiple channels with very brief mean open times (10 msec). In addition, channels with conductances less than 6 pS were observed in 20% of the patches. In all nine experiments with K⁺ in the pipette solution replaced by Na⁺, unitary currents were outward, and inward currents were observed only for large hyperpolarizing potentials. This indicates that the channels are more selective for K⁺ over Na⁺ and Cl^–. A variety of K⁺ channels contributes to the basolateral K⁺ conductance of resting oxyntic cells.     

Neutral Red as a Redox Dye Induces K+ Efflux and Current-Voltage Changes in Eremosphaera,Lemna, and Guard Cells*

Membrane effects of the redox and pH indicator neutral red were studied with the chlorococcal alga Eremosphaera viridis, with Lemna gibba, and with “isolated” guard cells in epidermal peels of Valerianella locusta. Neutral red was extracellularly reduced and caused transmembrane current-voltage changes, an increase in membrane conductance by about 14 nS, an apparent K⁺ net efflux of up to 120 μmol g^?1 FW in 5 min, and an intracellular acidification by up to 0.7 pH units. Neutral red-triggered K⁺ net efflux was most pronounced at low pH, at an E_o more positive than ?200 mV, and without extracellular Ca²⁺. From the experimental data it is concluded that, due to the redox function of the phenazine molecule, extracellular neutral red triggers a trans-plasmalemma e^? transfer, leading to strong membrane depolarization and charge compensating K⁺ net efflux, in addition to some unspecific ion release. As a consequence the intracellular concentration of strong cations relative to strong anions (SID) decreases, resulting in intracellular acidification.     

Fractional contribution of major ions to the membrane potential of Drosophila melanogaster oocytes

In ovarian follicles of Drosophila melanogaster, ion substitution experiments revealed that K⁺ is the greatest contributor (68%) in setting oocyte steady‐state potential (E_m), while Mg²⁺ and a metabolic component account for the rest. Because of the intense use made of Drosophila ovarian follicles in many lines of research, it is important to know how changes in the surrounding medium, particularly in major diffusible ions, may affect the physiology of the cells. The contributions made to the Drosophila oocyte membrane potential (E_m) by [Na⁺]_o, [K⁺]_o, [Mg²⁺]_o, [Ca²⁺]_o, [Cl^?]_o, and pH (protons) were determined by substitutions made to the composition of the incubation medium. Only K⁺ and Mg²⁺ were found to participate in setting the level of E_m. In follicles subjected to changes in external pH from the normal 7.3 to either pH 6 or pH 8, E_m changed rapidly by about 6 mV, but within 8 min had returned to the original E_m. Approximately half of all follicles exposed to reduced [Cl^?]_o showed no change in E_m, and these all had input resistances of 330 kΩ or greater. The remaining follicles had smaller input resistances, and these first depolarized by about 5 mV. Over several minutes, their input resistances increased and they repolarized to a value more electronegative than their value prior to reduction in [Cl^?]_o. Together, K⁺ and Mg²⁺ accounted for up to 87% of measured steady‐state potential. Treatment with sodium azide, ammonium vanadate, or chilling revealed a metabolically driven component that could account for the remaining 13%. © 2009 Wiley Periodicals, Inc.     

III. Ion Channel Expression in PMA-differentiated Human THP-1 Macrophages

Ion channel expression was studied in THP-1 human monocytic leukemia cells induced to differentiate into macrophage-like cells by exposure to the phorbol ester, phorbol 12-myristate 13-acetate (PMA). Inactivating delayed rectifier K⁺ currents, I _DR, present in almost all undifferentiated THP-1 monocytes, were absent from PMA-differentiated macrophages. Two K⁺ channels were observed in THP-1 cells only after differentiation into macrophages, an inwardly rectifying K⁺ channel (I _IR) and a Ca²⁺-activated maxi-K channel (I _BK). I _IR was a classical inward rectifier, conducting large inward currents negative to E _K and very small outward currents. I _IR was blocked in a voltage-dependent manner by Cs⁺, Na⁺, and Ba²⁺, block increasing with hyperpolarization. Block by Na⁺ and Ba²⁺ was time-dependent, whereas Cs⁺ block was too fast to resolve. Rb⁺ was sparingly permeant. In cell-attached patches with high [K⁺] in the pipette, the single I _IR channel conductance was ∼30 pS and no outward current could be detected. I _BK channels were observed in cell-attached or inside-out patches and in whole-cell configuration. In cell-attached patches the conductance was ∼200–250 pS and at potentials positive to ∼100 mV a negative slope conductance of the unitary current was observed, suggesting block by intracellular Na⁺. I _BK was activated at large positive potentials in cell-attached patches; in inside-out patches the voltage-activation relationship was shifted to more negative potentials by increased [Ca²⁺]. Macroscopic I _BK was blocked by external TEA⁺ with half block at 0.35 mm. THP-1 cells were found to contain mRNA for Kv1.3 and IRK1. Levels of mRNA coding for these K⁺ channels were studied by competitive PCR (polymerase chain reaction), and were found to change upon differentiation in the same direction as did channel expression: IRK1 mRNA increased at least 5-fold, and Kv1.3 mRNA decreased on average 7-fold. Possible functional correlates of the changes in ion channel expression during differentiation of THP-1 cells are discussed. Received: 19 September 1995/Revised: 14 March 1996     

Voltage dependent potassium fluxes and the significance of action potentials in Acetabularia

Membrane potential, V_m, and K⁺(⁸⁶Rb⁺) fluxes have been measured simultaneously on individual cells of Acetabularia mediterranea. During resting state (resting potential approx. ?170 mV) the K⁺ influx amounts to 0.24–0.6 pmol · cm^?2 · s^?1 and the K⁺ efflux to 0.2–1.5 pmol · cm^?2 s^?1. According to the K⁺ concentrations inside and outside the cell (40 : 1) the voltage dependent K⁺ flux (zero at V_m = E_K = ?90 mV) is stimulated approx. 40-fold for V_m more positive than E_K.It is calculated that during one action potential (temporary depolarization to V_m more positive than E_K) a cell looses the same amount of K⁺, which leaks in during 10–20 min in the resting state (V_m = ?170 mV). Since action potentials occur spontaneously in Acetabularia, they are therefore suggested to have a significant function for the K⁺ balance of this alga.     

Satellite glial cells In Situ within mammalian prevertebral ganglia express K+ channels active at rest potential

Patch-clamp experiments were performed on satellite glial cells wrapped around sympathetic neurons in the rabbit coeliac ganglion. With the cleaning method used, the glial cells could be kept in place and were directly accessible to the patch-clamp pipettes. Whole-cell recordings showed that glial cells had almost ohmic properties. Their resting potential (–79.1±1.2 mV) was found to be very nearly the same as the K⁺ reversal potential and 20 mV more negative than that of the neurons they encapsulated. Unitary currents from ionic channels present in the glial membrane were recorded in the cell-attached configuration with pipettes filled with various amounts of K⁺, Na⁺ and gluconate. Only K⁺-selective channels with slight inwardly rectifying properties (in the presence of 150 mM [K⁺]₀) were detected. These channels were active (P ₀=0.7–0.8) at the cell resting potential. The channel conductance, but not its opening probability, was dependent on the [K⁺] in the pipette. Cl^–-selective channels (outwardly rectifying and large conductance channels) were detected in excised patches.The properties of the K⁺ channels (increased inward current with [K⁺] and detectable outward current at low [K⁺]) are well suited for siphoning the K⁺ released by active neurons.     

Membrane Potassium Channels and Human Bladder Tumor Cells. I. Electrical Properties

These experiments were conducted to determine the membrane K⁺ currents and channels in human urinary bladder (HTB-9) carcinoma cells in vitro. K⁺ currents and channel activity were assessed by the whole-cell voltage clamp and by either inside-out or outside-out patch clamp recordings. Cell depolarization resulted in activation of a Ca²⁺-dependent outward K⁺ current, 0.57 ± 0.13 nS/pF at −70 mV holding potential and 3.10 ± 0.15 nS/pF at 30 mV holding potential. Corresponding patch clamp measurements demonstrated a Ca²⁺-activated, voltage-dependent K⁺ channel (K_Ca) of 214 ± 3.0 pS. Scorpion venom peptides, charybdotoxin (ChTx) and iberiotoxin (IbTx), inhibited both the activated current and the K_Ca activity. In addition, on-cell patch recordings demonstrated an inwardly rectifying K⁺ channel, 21 ± 1 pS at positive transmembrane potential (V _m ) and 145 ± 13 pS at negative V _m . Glibenclamide (50 μm), Ba²⁺ (1 mm) and quinine (100 μm) each inhibited the corresponding nonactivated, basal whole-cell current. Moreover, glibenclamide inhibited K⁺ channels in inside/out patches in a dose-dependent manner, and the IC₅₀= 46 μm. The identity of this K⁺ channel with an ATP-sensitive K⁺ channel (K_ATP) was confirmed by its inhibition with ATP (2 mm) and by its activation with diazoxide (100 μm). We conclude that plasma membranes of HTB-9 cells contain the K_Ca and a lower conductance K⁺ channel with properties consistent with a sulfonylurea receptor-linked K_ATP. Received: 12 June 1997/Revised: 21 October 1997