Similar to growth factors aldosterone stimulates Na+/H+ exchange in renal target cells leading to cytoplasmic alkalinization. An alkaline intracellular pH reduces the H+ bonds between repressor proteins and DNA leading to the destabilization of the nuclear chromatin. We observed that sustained alkaline stress "per se" can lead to malignant transformation of Madin-Darby canine kidney (MDCK) cells. Cells grown for two weeks in alkaline culture medium (pH 7.8) developed multiple "foci" composed of spindle-shaped pleomorphic cells lacking contact inhibition and exhibiting poor adhesion to the culture support, typical characteristics of dedifferentiated tumor cells. "Focus" cells were cloned and grown in standard medium (pH 7.4). Cells maintained their abnormal growth pattern, indicating stable pH-induced genetic transformation. Cells were fused with polyethylene glycol to giant cells and impaled with microelectrodes. In contrast to non-transformed giant MDCK cells the plasma membrane potential showed spontaneous oscillations that could be virtually abolished by the omission of extracellular Ca2+ or by the addition of the K+ channel blocker Ba2+. We conclude that sustained alkaline stress can induce malignant transformation in MDCK cells indicated by an abnormal growth pattern and by membrane potential oscillations most likely due to Ca2+ activated K+ channels in the plasma membrane.
Intracellular alkalinization is known to be associated with tumorigenic transformation. Besides phenotypical alterations alkali-transformed Madin-Darby canine kidney (MDCK) cells exhibit a spontaneously oscillating cell membrane potential (PD). Using single-channel patch clamp techniques, it was the aim of this study to identify the ion channel underlying the rhythmic hyperpolarizations of the PD. In the cell-attached patch configuration, we found that channel activity was oscillating. The frequency of channel oscillations is 1.1+±0.1 min'.At the peak of oscillatory channel activity, single-channel current was -2.7±0.05 pA, and in the resting state it was -1.95±0.05 pA. Given the single-channel conductance of 53±3 pS for inward (and of 27±5 pS for outward) current the difference of single-channel current amplitude corresponded to a hyperpolarization of -14 mV. The channel is selective for K+ over Na'. Channel kinetics are characterized by one open and by three closed time constants. The channel is Ca2" sensitive.Half maximal activation in the inside-out patch mode is achieved at a Ca2+ concentration of 10 ,umol/ liter. In addition, we also found a 13-pS K+ channel that shows no oscillatory activity in the cell-attached patch configuration and that was not Ca2" sensitive. We conclude that the Ca2 -sensitive 53-pS K+ channel is underlying spontaneous oscillations of the PD. It has virtually identical biophysical properties as a Ca2`-sensitive K+ channel in nontransformed parent MDCK cells. Hence, alkali-induced transformation of MDCK cells did not affect the channel protein itself but its regulators thereby causing spontaneous fluctuations of the PD. (J. Clin. Invest. 1993. 91:218-223.)
High pH is known to be associated with normal cell growth and neoplastic transformation. We observed that Madin-Darby canine kidney (MDCK) cells grown under sustained alkaline stress (pH 7.7) develop "foci" composed of spindle-shaped cells lacking contact inhibition and exhibiting only poor adhesion to the culture support. Foci-developing (F) cells were cloned and grown in control medium (pH 7.4), where they maintained their neoplastic features indicating a stable pH-induced genetic transformation. After F cells had been fused to giant cells with polyethylene glycol, the cell membrane potential (Vm) was measured by means of microelectrodes. In contrast to non-transformed MDCK cells, Vm of F cells showed spontaneous biorhythmicity caused by periodic opening of Ca2(+)-activated K+ channels. Spiking activity was blunted by the Ca2+ channel blocker nifedipine, by the K+ channel blocker Ba2+, by the Na+/H+ exchange blocker amiloride and its analogue ethylisopropylamiloride, and by an extracellular pH of 7.6 and 6.8. We conclude that MDCK cells transformed by sustained alkaline stress have lost their stable plasma membrane potential but, instead, exhibit endogenous Ca2(+)- and pH-sensitive oscillations.
Alkaline stress transforms Madin-Darby canine kidney (MDCK) cells as indicated by loss of epithelial structure, multilayer cell growth and formation of foci. In the present study we report that transformed MDCK cells (MDCK-F cells) exhibit spontaneous and lasting oscillations of intracellular Ca2+ concentration ([Ca2+]i), which are absent in non-transformed cells. Oscillations, as revealed by Fura-2 video imaging, were due to the activity of an inositol 1,4,5-trisphosphate-(InsP3)-sensitive Ca2+ store since their frequency was dependent on bradykinin concentration and they were abolished by the phosphoinositidase C inhibitor U73122. Moreover, blockers of the cytoplasmic Ca(2+)-ATPase, thapsigargin and 2,5-di-(tetr-butyl)-1,4-benzohydroquinone inhibited oscillatory activity. In contrast, neither injection of ruthenium red, ryanodine nor caffeine had any effect on oscillations. Analysis of the spatial distribution of [Ca2+]i showed that Ca2+ transients originated from an initiation site constant for a given cell and spread through the cell as an advancing Ca2+ wave. Oscillations started in a random manner from single cells and spread over neighbouring cells, suggesting a kind of intercellular communication. We conclude that MDCK-F cells have acquired the ability for endogenous Ca2+ release through transformation. Oscillations are primarily due to the activity of an InsP3-sensitive cytosolic Ca2+ oscillator.
Distal tubules were harvested from frog kidney and placed on the membrane of a K+-selective macroelectrode. Then the renal tissue was covered with a dialysis membrane to produce a closed extracellular compartment with a constant volume (40 microliter). K+ fluxes in and out of the cells could be determined, since the steady-state K+ activity during constant perfusion changed to a new steady state when perfusion was stopped. Inhibition of passive K+ permeability by the addition of Ba2+ resulted in K+ uptake by the cells because of the function of the Na+-K+ pump. Inhibition of the pump by the addition of ouabain led to K+ efflux from cells reflecting the passive K+ permeability. Because K+ net movement under control conditions (no Ba2+ or ouabain) results from both uptake and efflux, subtraction of K+ uptake (in the presence of Ba2+) from control K+ net flux reveals the passive K+ efflux. This value agrees well with that obtained with ouabain. Furosemide led to a significant K+ shift from the extracellular compartment into the intracellular compartment. Reduction of extracellular pH from 7.8 to 6.0 decreased the rate of K+ uptake by 39 +/- 7% and the K+ leak by 51 +/- 11%. We conclude that K+ uptake and K+ release can be functionally separated. This so-called "electrode sandwich technique" permits evaluation of pump and leak independently in the same cell population.
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