Effects of extracellular nucleotides on electrical properties of subconfluent Madin Darby canine kidney cells

Purinergic signalling in the kidney in health and disease

The involvement of purinergic signalling in kidney physiology and pathophysiology is rapidly gaining recognition and this is a comprehensive review of early and recent publications in the field. Purinergic signalling involvement is described in several important intrarenal regulatory mechanisms, including tuboglomerular feedback, the autoregulatory response of the glomerular and extraglomerular microcirculation and the control of renin release. Furthermore, purinergic signalling influences water and electrolyte transport in all segments of the renal tubule. Reports about purine- and pyrimidine-mediated actions in diseases of the kidney, including polycystic kidney disease, nephritis, diabetes, hypertension and nephrotoxicant injury are covered and possible purinergic therapeutic strategies discussed.

ATP directly enhances calcium channels in the luminal membrane of the distal nephron

Calcium (Ca(2+)) transport by the distal tubule (DT) luminal membrane is regulated by the parathyroid hormone (PTH) and calcitonin (CT) through the action of messengers, protein kinases, and ATP as the phosphate donor. In this study, we questioned whether ATP itself, when directly applied to the cytosolic surface of the membrane could influence the Ca(2+) channels previously detected in this membrane. We purified the luminal membranes of rabbit proximal (PT) and DT separately and measured Ca(2+) uptake by these vesicles loaded with ATP or the carrier. The presence of 100 microM ATP in the DT membrane vesicles significantly enhanced 0.5 mM Ca(2+) uptake from 0.57 +/- 0.02 to 0.71 +/- 0.02 pmol/microg per 10 sec (P < 0. 01) in the absence of Na(+) and from 0.36 +/- 0.03 to 0.59 +/- 0.01 pmol/microg per 10 sec (P < 0.01) in the presence of 100 mM Na(+). This effect was dose dependent with an EC(50) value of approximately 40 microM. ATP action involved the high-affinity component of Ca(2+) transport, decreasing the Km from 0.08 +/- 0.01 to 0.04 +/- 0.01 mM (P< 0.02). Replacement of the nucleotide by the nonhydrolyzable ATPgammas abolished this action. Because ATP has been reported to be necessary for cytoskeleton integrity, we also investigated the effect of intravesicular cytochalasin on Ca(2+) transport. Inclusion of 20 microM cytochalasin B decreased 0.5 mM Ca(2+) uptake from 0.33 +/- 0.01 to 0.15 +/- 0.01 pmol/microg per 10 sec (P< 0.01). However, when both 100 microM ATP and 20 microM cytochalasin were present in the vesicles, the uptake was not different from that observed with ATP alone. Neither ATP nor cytochalasin had any influence on Ca(2+) uptake by the PT luminal membrane. We conclude that the high-affinity Ca(2+) channel of the DT luminal membrane is regulated by ATP and that ATP plays a crucial role in the integrity of the cytoskeleton which is also involved in the control of Ca(2+) channels within this membrane.

Mechanism of lanthanum inhibition of extracellular ATP-evoked calcium mobilization in MDCK cells

We have studied the effects of La3+ on ATP-evoked rises in intracellular calcium levels ([Ca2+]i) measured by fura-2 fluorimetry in Madin Darby canine kidney (MDCK) cells. ATP evoked [Ca2+]i rises dose-dependently with an EC50 of 2.5 microM. The trigger for the Ca2+ signal was a release of Ca2+ from the inositol-1,4,5-trisphosphate (IP3)-sensitive stores because the signal was completely blocked by pretreatment with the endoplasmic reticulum (ER) Ca2+ pump inhibitor thapsigargin (TG) or the phospholipase C (PLC) inhibitor U73122. Both the peak height and area under the curve of 10 microM ATP-evoked Ca2+ signal was reduced by approximately 50% by extracellular Ca2+ removal, suggesting that ATP induced capacitative Ca2+ entry. La3+ inhibited the ATP-evoked Ca2+ signal dose-dependently when added before or after ATP. Pretreatment of 0.1 mM La3+ inhibited approximately 90% of the Ca2+ signal induced by 10 microM ATP. The mechanisms underlying the La3+ inhibition appear to involve not only block of capacitative Ca2+ entry but also interference with ATP binding to the ATP receptors.

Properties and regulation of ion channels in MDCK cells

The MDCK cell has proven to be a useful model cell line for the study of properties and regulation of renal epithelial ion channels. Patch clamp studies disclosed the existence of several K+ channels and of a Cl- channel, and their regulation by hormones, cell volume, trace elements and drugs. Most hormones affect K+ channels at least in part by increasing cytosolic Ca2+. However, indirect evidence points to additional mechanisms contributing to K+ channel activation. Cell swelling activates both K+ channels and unselective anion channels. ICln, a protein cloned from MDCK cells, is either a Cl- channel or a regulator of thereof. ICln is up-regulated by cellular acidification and is crucial for rapid regulatory cell volume decrease.

Effect of bradykinin, ATP and adrenaline on cell membrane resistances of Madin-Darby canine kidney cells

1. Previous studies have shown that bradykinin, ATP and adrenaline hyperpolarize the cell membrane of Madin-Darby canine kidney (MDCK) cells by activation of calcium-sensitive K+ channels. The present study has been performed to determine the effect of these hormones on the resistance of the cell membrane and the cellular coupling. To this end, cellular cable analysis has been performed. 2. As a result, all three hormones lead to the expected, marked decrease of cell membrane resistance. 3. However, the bradykinin-induced reduction of cell membrane resistance was sustained, contrasting with only transient hyperpolarization induced by bradykinin and only transient activation of the K+ channels. Thus, the cable analysis reveals the sustained activation of an additional conductance. 4. ATP, but not the other two hormones, leads to a delayed increase of the intercellular coupling resistances. 5. Prolonged exposure of the cells to adrenaline leads to oscillations of the cell membrane potential, apparently by oscillatory activation of the K+ channels.

Inhibition of ion conductances by osmotic shrinkage of Madin-Darby canine kidney cells

Osmotic swelling of Madin-Darby canine kidney (MDCK) cells enhances the ion conductances of the cell membrane, which allows release of cellular ions and subsequent regulatory cell volume decrease. The present study has been performed to test whether cell shrinkage similarly affects the ion conductances of MDCK cell membranes. Increase of extracellular osmolarity by addition of 50 mM NaCl or 100 mM mannitol leads within 3 min to a hyperpolarization of the cell membrane, a marked increase of cell membrane resistance [by 223 +/- 38% (n = 8) and 228 +/- 21% (n = 5), respectively], as well as a moderate increase of the K+ selectivity of the cell membrane (by 37 +/- 13%, n = 9). Thus exposure to hypertonic extracellular fluid decreases the cell membrane conductances including the K+ conductance. Cell volume measurements reveal a regulatory cell volume increase, which is sensitive to both furosemide and dimethylamiloride. Extracellular ATP (10 microM), which activates calcium-sensitive K+ channels, hyperpolarizes the cell membrane close to the K+ equilibrium potential. The respective values are -69.9 +/- 3.1 mV (n = 9) in isotonic fluid, -79.4 +/- 1.8 mV (n = 9) within 3 min, and -76.4 +/- 1.8 mV (n = 7) within 16-h exposure to hypertonic extracellular fluid. This observation points to a sustained increase of intracellular K+ activity after exposure to hypertonic extracellular fluid.

Effect of trifluoperazine on renal epithelioid Madin-Darby canine kidney cells

Following exposure to a number of hormones, the cell membrane in Madin-Darby Canine Kidney (MDCK) cells is hyperpolarized by increase of intracellular calcium activity. The present study has been performed to elucidate the possible role of calmodulin in the regulation of intracellular calcium activity and cell membrane potential. To this end trifluoperazine has been added during continuous recording of cell membrane potential or intracellular calcium. Trifluoperazine leads to a transient increase of intracellular calcium as well as a sustained hyperpolarization of the cell membrane by activation of calcium sensitive K+ channels. Half-maximal effects are observed between 1 and 10 mumol/L trifluoperazine. A further calmodulin antagonist, chlorpromazine, (50 mumol/L), similarly hyperpolarizes the cell membrane. The effects of trifluoperazine are virtually abolished in the absence of extracellular calcium. Pretreatment of the cells with either pertussis toxin or phorbol-ester TPA does not interfere with the hyperpolarizing effect of trifluoperazine. In conclusion, calmodulin is apparently involved in the regulation of calcium transfer across the cell membrane but not in the stimulation of K+ channels by intracellular calcium.

Further analysis of ATP-mediated activation of K+ channels in renal epithelioid Madin Darby canine kidney (MDCK) cells

ATP activates K+ channels by increasing intracellular calcium activity in Madin Darby canine kidney (MDCK) cells. The present study has been performed to test for the involvement of G-proteins and of protein kinase C in the intracellular transmission of these effects. To this end, the effect of ATP on intracellular calcium and K+ channel activity has been studied in cells pretreated with the phorbol ester 12-O-tetradecanoyl-phorbol 13-acetate (TPA) and/or pertussis toxin. The ATP-induced increase of intracellular calcium is not significantly affected by pretreatment with pertussis toxin, is significantly blunted by pretreatment with TPA and is abolished by pretreatment with both pertussis toxin and the phorbol ester. The ATP activation of K+ channels is similarly blunted by pretreatment with TPA, but is not abolished by pretreatment with both the phorbol ester and pertussis toxin. Furthermore, the ATP-induced hyperpolarization is not abolished in cells pretreated with both pertussis toxin and TPA. In those cells, ATP may activate K+ channels by calcium-dependent mechanisms or lead to localized increases of intracellular calcium sufficient to activate the K+ channels but escaping detection with fura-2 fluorescence.

Electrophysiological effects of extracellular ATP on Necturus gallbladder epithelium

The effects of addition of ATP to the mucosal bathing solution on transepithelial, apical, and basolateral membrane voltages and resistances in Necturus gallbladder epithelium were determined. Mucosal ATP (100 microM) caused a rapid hyperpolarization of both apical (Vmc) and basolateral (Vcs) cell membrane voltages (delta Vm = 18 +/- 1 mV), a fall in transepithelial resistance (Rt) from 142 +/- 8 to 122 +/- 7 omega.cm2, and a decrease in fractional apical membrane resistance (fRa) from 0.93 +/- 0.02 to 0.83 +/- 0.03. The rapid initial hyperpolarization of Vmc and Vcs was followed by a slower depolarization of cell membrane voltages and a lumen-negative change in transepithelial voltage (Vms). This phase also included an additional decrease in fRa. Removal of the ATP caused a further depolarization of membrane voltages followed by a hyperpolarization and then a return to control values. fRa fell to a minimum after removal of ATP and then returned to control values as the cell membrane voltages repolarized. Similar responses could be elicited by ADP but not by adenosine. The results of two-point cable experiments revealed that ATP induced an initial increase in cell membrane conductance followed by a decrease. Transient elevations of mucosal solution [K+] induced a larger depolarization of Vmc and Vcs during exposure to ATP than under control conditions. Reduction of mucosal solution [Cl-] induced a slow hyperpolarization of Vmc and Vcs before exposure to ATP and a rapid depolarization during exposure to ATP. We conclude that ATP4- is the active agent and that it causes a concentration-dependent increase in apical and basolateral membrane K+ permeability. In addition, an apical membrane electrodiffusive Cl- permeability is activated by ATP4-.

Cellular mechanisms of ATP-induced hyperpolarization in renal epitheloid MDCK-cells

Previous studies have shown that ATP enhances intracellular calcium concentration and activates potassium channels in Madin Darby canine kidney (MDCK)-cells, thus leading to hyperpolarization of the cell membrane. The present study has been performed to elucidate the intracellular mechanisms involved. To this end, the effects of ATP on the potential difference across the cell membrane (PD), on formation of inositol phosphates, and on intracellular calcium concentration (Cai) have been analyzed in cells without or with pretreatment with pertussis toxin or 12-O-tetradecanoyl phorbol 13-acetate diester (TPA). In untreated cells, ATP leads to a sustained hyperpolarization and an increase of inositol 1,4,5-trisphosphate (IP3), inositol 1,3,4,5-tetrakisphosphate (IP4), and Cai. In the absence of extracellular calcium, the effect of ATP on PD and Cai is only transient. In cells pretreated with pertussis toxin, the effect of ATP on inositol trisphosphate is almost abolished, but ATP still leads to an increase of PD and Cai, which is sustained in the presence, and transient in the absence, of extracellular calcium. In cells pretreated with TPA, the effect of ATP on inositol trisphosphate is reduced and the effect on Cai blunted; but ATP still leads to a hyperpolarization of the cell membrane, which is sustained in the presence, and transient in the absence, of extracellular calcium. The observations indicate that ATP activates phospholipase C by a phorbol ester and pertussis toxin sensitive mechanism. In addition, ATP enhances Cai by pertussis toxin insensitive mechanisms allowing recruitment of calcium from both, extracellular fluid and intracellular stores. Calcium then activates the potassium channels and thus leads to the hyperpolarization of the cell membrane.

Determination of cell membrane resistance in cultured renal epithelioid (MDCK) cells: effects of cadmium and mercury ions

Previous studies have indicated that the cell membrane of Madin Darby Canine Kidney (MDCK) cells is hyperpolarized by a number of hormones and trace elements, in parallel with an enhancement of potassium selectivity. Without knowledge of the cell membrane resistance (Rm), however, any translation of potassium selectivity into potassium conductance remains equivocal. The present study was performed to determine the Rm of MDCK cells by cellular cable analysis. To this end, three microelectrodes were impaled into three different cells of a cell cluster; current was injected via one microelectrode and the corresponding voltage deflections measured by the other two microelectrodes. In order to extract the required specific resistances, the experimental data were analysed mathematically in terms of an electrodynamical model derived from Maxwell's equations. As a result, a mean Rm of 2.0 +/- 0.2 k omega cm2 and an intercellular coupling resistance (Rc) of 6.1 +/- 0.8 M omega were obtained at a mean potential difference across the cell membrane of -47.0 +/- 0.6 mV. An increase of the extracellular K+ concentration from 5.4 to 20 mmol/l depolarized the cell membrane by 16.2 +/- 0.5 mV and decreased Rm by 30.6 +/- 3.0%; 1 mmol/l barium depolarized the cell membrane by 20.1 +/- 1.1 mV and increased Rm by 75.9 +/- 14.3%. Omission of extracellular bicarbonate and carbon dioxide at constant extracellular pH caused a transient hyperpolarization (up to -60.4 +/- 1.4 mV), a decrease of Rm (by 75 +/- 4.5%) and a decrease of Rc (by 23.1 +/- 8.4%).(ABSTRACT TRUNCATED AT 250 WORDS)

Cobalt activates potassium conductance in the plasma membrane of cultured renal epithelioid (MDCK)-cells

Cobalt has been shown to stimulate sodium transport across the distal nephron of the newt kidney. The mechanism of this action remained elusive. The present study has been performed to test for effects of cobalt on electrical properties of cultured subconfluent kidney (MDCK)-cells: cobalt (10 microM) leads to a rapid, sustained and reversible hyperpolarization of the cell membrane, paralleled by an increase of the potassium selectivity and a decrease of the resistance. Thus, cobalt increases the potassium conductance of the cell membrane. The half-maximal effect is elicited by approx. 1 microM. At extracellular calcium concentration reduced to less than 0.1 microM, cobalt (10 microM) leads to a transient hyperpolarization, which can be elicited only once. Thus, cobalt enhances the potassium conductance in a calcium dependent way. At higher concentrations (100 microM) cobalt hyperpolarizes the cell membrane only transiently even in the presence of extracellular calcium. Furthermore 100 microM cobalt interferes with ATP-induced hyperpolarization, which is known to result from calcium mediated activation of K+ channels. Thus, 100 microM cobalt may inhibit ATP-stimulated calcium entry into the cell.

Cadmium enhances potassium conductance in cultured renal epitheloid (MDCK) cells

The kidney is a main target organ for cadmium toxicity. The present study has been performed to test for effects of cadmium on electrical properties of cultured subconfluent kidney (MDCK) cells. Cadmium leads to a rapid, sustained and reversible hyperpolarization of the cell membrane, paralleled by an increase of the potassium selectivity and a decrease of the resistance. Thus, cadmium increases the potassium conductance of the cell membrane. The half maximal effect is elicited congruent to 0.2 microM, a concentration encountered during chronic cadmium intoxication. At extracellular calcium concentration reduced to less than 0.1 microM, 5 microM cadmium leads to a transient hyperpolarization, which can be elicited only once. High concentrations (50 microM) of cadmium lead to a sustained hyperpolarization even at extracellular calcium concentrations of less than 0.1 microM. According to fluorescence measurements cadmium leads to an increase of intracellular calcium activity, which is sustained at 1 mM and transient at less than 1 microM extracellular calcium activity. In conclusion, cadmium at low concentrations enhances the potassium conductance in a calcium dependent way. The observations suggest that cadmium enhances intracellular calcium both by recruitment from intracellular stores and by modification of calcium transport across the cell membrane. At high concentrations cadmium enhances the potassium conductance independently from enhanced intracellular calcium activity.

Activation of potassium channels in renal epithelioid cells (MDCK) by extracellular ATP

Extracellular ATP has been shown to stimulate transepithelial chloride transport in confluent Madin-Darby canine kidney (MDCK) cell layers and to enhance potassium conductance in subconfluent MDCK cells. The present study has been performed to test for the effect of extracellular ATP on channel activity in patches from subconfluent MDCK cells. Within 8 s, addition of extracellular ATP (10 mumol/l) leads to a sustained, but fully reversible, appearance of potassium-selective channels in cell-attached patches [increase of open probability from 0.03 +/- 0.02 (n = 10) to 0.50 +/- 0.07 (n = 6)]. With the use of pipettes filled with 145 mmol/l KCl, inwardly rectifying property of the channels is disclosed with a single-channel conductance of 65.7 +/- 3.1 pS (n = 9) at zero potential difference between pipette and bath and with a reversal potential of 75.4 +/- 2.0 mV (n = 5; pipette negative vs. reference in the bath). The open probability of the channels is not significantly modified by altering pipette potential from -50 mV, pipette positive, to 50 mV, pipette negative. At extracellular calcium activities of less than 10 nmol/l, ATP leads to a transient activation of channels. In conclusion, extracellular ATP activates inwardly rectifying potassium channels in the cell membrane of subconfluent MDCK cells. A sustained activation of the channels requires the presence of extracellular calcium and is probably mediated by increases in intracellular calcium.