Control of passive permeability of chinese hamster ovary cells by external and intracellular ATP

External ATP causes passive permeability change in several transformed cells, but not in untransformed cells. We studied the effect of external ATP on the passive permeability of CHO-K1 cells, a transformed clone of Chinese hamster ovary cells. Treatment of the cells with external ATP alone did not produce a permeability change, and this was observed only when a mitochondrial inhibitor, such as rotenone or oligomycin, was present together with ATP. These inhibitors reduced the concentration of intracellular ATP and a permeability change by external ATP was observed when intracellular ATP was decreased more than 70%. This requirement for permeability change of CHO-K1 cells was quite unique, since passive permeability change of other transformed cells so far tested was induced by ATP alone. Treatment of CHO-K1 cells with cyclic AMP analogues increased their sensitivity to external ATP about 2-fold. The roles of external and intracellular ATP in controlling passive permeability are discussed.     

Control of membrane permeability by external ATP in mammalian cells: isolation of an ATP-resistant variant from Chinese hamster ovary cells

External ATP causes a great increase in the passive permeability of the plasma membrane for phosphorylated metabolites and other small molecules in cultured mammalian cells. We previously demonstrated that in CHO-K1 cells an ATP-dependent permeability change was induced in the presence of a mitochondrial inhibitor (KCN or rotenone), a cytoskeleton-attacking agent (vinblastine) and a calmodulin antagonist (trifluoperazine). These permeability changes were reversible but long exposure, for 30-60 min, to ATP together with a mitochondrial inhibitor significantly reduced the cell viability of the treated cells. Since this cell lysis was shown to be due to the ATP-dependent permeability change, we could isolate several clones resistant to the action of the external ATP from CHO-K1 cells after repeated treatment with ATP and rotenone. In 9.1 cells, one of the isolated clones, little or no ATP-dependent permeability change was observed in the presence of either a mitochondrial inhibitor, vinblastine or trifluoperazine. This CHO variant could be specifically resistant as to the change in membrane permeability induced by external ATP, since the permeabilities for the 2-deoxyglucose and drugs used in the present studies were similar to those in the case of the parent cells. These results suggest that a specific defect or alteration in the plasma membrane is involved in the ATP-dependent permeability change. It is also reported that Mg2+-dependent ATPase activity was found on the cell surface of both CHO-K1 and 9.1 cells, and this activity was shown to be not involved in the permeability change controlled by external ATP.     

The role of calcium ions in the permeability changes produced by external ATP in transformed 3T3 cells

External ATP causes a rapid increase in passive permeability to nucleotides and phosphate esters in transformed cell lines, such as 3T6 mouse fibroblasts. However, untransformed lines, such as 3T3, do not show a similar sensitivity to external ATP. Ca²⁺ inhibits permeabilization, but only at concentrations approaching those of external ATP. In contrast, La³⁺ and Tb³⁺ inhibit ATP-dependent permeabilization at one-fifth the concentration of external ATP. Considering reports that lanthanides can substitute for calcium ion in many enzymatic reactions, often with a higher affinity, it would appear that Ca²⁺ plays a specific role in the maintenance of a passive membrane permeability barrier and in opposing the effects of external ATP.Other data suggest a regulatory role for the Ca²⁺-calmodulin complex in the permeabilization process. Trifluoperazine, chlorpromazine and W-7, compounds which inhibit cellular functions dependent on the Ca²⁺-calmodulin complex, are able to enhance the effect of external ATP. Thus, a dramatic stimulation of nucleotide permeability occurs with concentrations of external ATP and inhibitor that are ineffective when added alone. Calmodulin antagonists and low concentrations of external ATP increased membrane permeability to Na⁺ and K⁺ as was previously shown for permeabilization with ATP alone. Earlier studies have shown that energy inhibitors which reduce intracellular ATP levels greatly increase the sensitivity of transformed cells to external ATP. However, the Ca²⁺-calmodulin antagonists used in the present study exert their effects at concentrations which do not alter intracellular ATP levels.     

External ATP-induced passive permeability change and cell lysis of cultured transformed cells: action in serum-containing growth media

External ATP causes a marked increase in the passive permeability to phosphorylated metabolites in several types of transformed cells in alkaline medium containing low concentrations of Ca2+, but not in untransformed cells. Such increased membrane permeability with external ATP was also observed in B16 melanoma cells at pH 7.4-7.5 in both Tris-buffered saline and a growth medium containing 10% calf serum and divalent ions at normal concentrations, although a higher concentration of ATP was required. The permeability change in the growth medium was significantly enhanced by calmodulin-interacting drugs, such as trifluoperazine (TFP), N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide (W7) and chlorpromazine (CPZ). As expected, prolonged exposure of the cells to ATP in the serum-containing medium led to cell lysis. This ATP-dependent cell lysis was observed only in several transformed cell lines, and not in untransformed mouse fibroblasts. These results indicate that the effect of ATP on the membrane permeability in transformed cells is elicited under the physiological conditions and this would be useful in some limited way for cancer chemotherapy management.     

Role of cytoplasmic ATP in the restoration and maintenance of a membrane permeability barrier in transformed mammalian cells

Addition of ATP to medium surrounding intact, transformed 3T3 cells activates the formation of aqueous channels in the plasma membrane. This results in efflux of nucleotide pools and ions and entry into the cytosol of charged, phosphorylated species. In such permeabilized cells, glycolysis is totally dependent on the external addition of glucose, inorganic phosphate, ADP, K+, Mg2+ and NAD+ which restore lactic acid formation to levels found in untreated cells. As expected, such reconstitution of glycolytic activity is found to restore intracellular ATP levels. This is accompanied by sealing of the membrane channels so that efflux of nucleotide pools ceases. Pyruvate, a substrate for mitochondrial ATP synthesis, when provided along with ADP and inorganic phosphate also produces sealing of the membrane channels. On the other hand, reactivation of pentose phosphate shunt activity, which does not lead to ATP synthesis, does not induce restoration of the membrane permeability barrier. Furthermore, compounds which lower the internal ATP pool prevent sealing, and also render the plasma membrane more sensitive to external ATP (Rozengurt and Heppel, '79). Sealing of aqueous channels following restoration of the internal ATP pool is associated with phosphorylation of the inner membrane surface, and is unaffected by inhibitors of protein synthesis, microfilament or microtubular assembly. These results indicate the probable role of intracellular ATP in the restoration and/or maintenance of an active membrane barrier against efflux of small molecules and ions in transformed 3T3 cells.     

Inhibitory effects of newly synthesized sulfonamide derivatives on calmodulin-dependent phosphodiesterase activity and their modulation of the external ATP-dependent permeability change in mammalian cultured cells

External ATP causes a passive permeability change in several types of transformed cells and this change is further enhanced by calmodulin antagonists, such as trifluoperazine. However, such drugs also have nonspecific effects on membrane permeability. We have synthesized several new sulfonamide derivatives, which were found to inhibit calmodulin-dependent phosphodiesterase. The drugs also enhanced the ATP-dependent permeability change in CHO-K1 cells, but their effective concentration ranges were wider than those of previously known antagonists, and thus they would be useful for pharmacological use.     

Cellular responses to external ATP which precede an increase in nucleotide permeability in transformed cells

Transformed mouse fibroblasts, such as 3T6, exhibit an increase in plasma membrane permeability to nucleotides and other normally impermeant molecules when incubated with external ATP in an alkaline medium low in divalent cations. Increased nucleotide permeability, induced by external ATP, occurs after a 3- to 5-min lag period. Prior to this event, there is a dramatic Na+ influx and K+ efflux, a significant reduction in the levels of intracellular ATP and organic phosphates, and a reduction in the plasma membrane potential. Accordingly, we postulate that these cellular responses to external ATP play a role in the efflux of nucleotides. Ouabain, a specific inhibitor of the plasma membrane (Na+,K+)-ATPase, acts together with low concentrations of external ATP to increase nucleotide permeability in 3T6 cells. This effect occurs at concentrations of ouabain and ATP which alone do not increase nucleotide permeability. In addition, ouabain and low concentrations of ATP alone have little effect on the level of intracellular ATP. This is in contrast to energy inhibitors and uncouplers which appear to enhance nucleotide permeability by lowering the intracellular ATP concentration. Ouabain alone causes a threefold increase in intracellular Na+ levels and a similar reduction in intracellular K+ levels under our experimental conditions, supporting the idea that ion fluxes are involved in the mechanism of permeabilization.     

Protein synthesis in transformed 3T3 cells permeabilized by exogenous ATP

Exogenous ATP has been shown to cause a rapid and reversible increase in permeability in transformed 3T3 cells (3T6 and SV3T3) but not in untransformed 3T3 cells. The cells remain viable, but lose intracellular acid-soluble pools. Treatment of transformed cells with ATP greatly reduces incorporation of ¹⁴C-leucine into protein, which is restored by the incubation of the cells with Dulbecco's modified Eagle's medium or by the external additions of certain ions and energy sources. tRNA is not required for the restoration of protein synthesis. In the permeabilized cells the energy for protein synthesis can be provided by glycolysis, oxidative phosphorylation, or direct addition of ATP. These studies demonstrate the usefulness of this method for studying the control of metabolism and macromolecular synthesis in monolayer cultures of transformed mammalian cells.     

ATP-driven,Na(+)-independent inward Cl- pumping in neuroblastoma cells

In immature neurones, the steady-state intracellular Cl- concentration [Cl-](i) is generally higher than expected for passive distribution, and this is believed to be due to Na(+)-K(+)-2Cl(-) co-transport. Here, we show that N2a neuroblastoma cells, incubated in HEPES-buffered NaCl medium maintain a [Cl-](i) around 60 mm, two- to threefold higher than expected for passive distribution at a membrane potential of - 49 mV. When the cells were transferred to a Cl(-) -free medium, [Cl-](i) decreased quickly (t(1/2) < 5 min), suggesting a high Cl- permeability. When the intracellular ATP concentration was reduced to less than 1 mm by metabolic inhibitors, the initial rate of (36) Cl- uptake was strongly inhibited (60-65%) while steady-state [Cl-](i) decreased to 24 mm, close to the value predicted from the Nernst equilibrium. Moreover, after reduction of [ATP](i) and [Cl-](i) by rotenone, the subsequent addition of glucose led to a reaccumulation of Cl-, in parallel with ATP recovery. Internal bicarbonate did not affect Cl- pumping, suggesting that Cl-/HCO(3)(-) exchange does not significantly contribute to active transport. Likewise, Na(+) -K(+) -2Cl(-) co-transport also appeared to play a minor role: although mRNA for the NKCC1 form of the co-transporter was detected in N2a cells, neither the initial rate of (36)Cl- uptake nor steady-state [Cl-](i) were appreciably decreased by 10 microm bumetanide or replacement of external Na(+) by choline. These results suggest that a highly active ATP-dependent mechanism, distinct from Na(+) -K(+) -2Cl(-) co-transport, is responsible for most of the inward Cl- pumping in N2a cells.     

Agents which reverse multidrug-resistance are inhibitors of [3H]vinblastine transport by isolated vesicles.

Resistance of human cancer cells to multiple cytotoxic hydrophobic agents (multidrug resistance) is due to overexpression of the MDR1 gene whose product is the ATP-dependent multidrug transporter, P-glycoprotein. We have previously reported that plasma membrane vesicles partially purified from multidrug-resistant human KB carcinoma cells, but not from drug-sensitive cells, accumulated [3H]vinblastine in an ATP-dependent manner (Horio, M., Gottesman, M.M. and Pastan, I. (1988) Proc. Natl. Acad. Sci. USA 85, 3580-3584). Certain calcium-channel blockers, quinidine, and phenothiazines are able to overcome multidrug resistance in cultured cells. In this work, the effect of these reversing agents on ATP-dependent vinblastine (VBL) transport by vesicles from drug-resistant KB cells has been characterized. Azidopine was the most potent inhibitor of ATP-dependent VBL uptake tested (ID50: concentration of inhibitor such that the transport of vinblastine is inhibited by 50%, less than 1 microM). Verapamil, quinidine, and the tiapamil analogue RO-11-2933 were potent but less effective inhibitors (ID50 less than 5 microM). Diltiazem, nifedipine and trifluoperazine were even less effective. These agents had no effect on Na(+)-dependent and Na(+)-independent L-leucine uptake by the vesicles, indicating that the inhibition of ATP dependent VBL transport by these agents is not a non-specific effect, as might result from leaks in the vesicle membrane. Verapamil, quinidine, azidopine and trifluoperazine increased the apparent Km value of vinblastine transport, suggesting that these agents may be competitive inhibitors of vinblastine transport.     

Effect of ionophore A23187 on the membrane permeability in mouse fibroblasts.

Addition of the divalent cation ionophore A23187 to transformed mouse fibroblasts (3T6) resulted in an increase in the cell membrane permeability to normally impermeant solutes (e.g., nucleotides). The membrane permeability was assessed by following the efflux of prelabeled adenine nucleotides, the influx of p-nitrophenyl phosphate in cells attached to plastic dishes and reconstitution of intracellular protein synthesis in the presence of exogenously added normally impermeant factors required for macromolecular synthesis. The permeability change of 3T6 cells was found to be dependent on the specific presence of external calcium ion. The permeabilization was found to occur preferably in alkaline pH and specific to certain transformed cells. It is preceded by rapid efflux of K+, influx of Na+ and partial hydrolysis of cellular nucleotides in 3T6 cells. Similar ion fluxes were previously found to precede cell permeabilization by electrogenic ionophores for monovalent ions and by exogenous ATP. Our data suggest that a calcium dependent process caused the K+ release and excess Na+ entry, causing dissipation of the membrane potential and subsequent formation of aqueous channels.     

On the role of protein phosphorylation in the ATP-dependent permeabilization of transformed cells

Incubation of transformed mouse fibroblasts with external ATP in alkaline medium low in divalent cations causes an increase in the permeability of the plasma membrane to nucleotides and other small molecules. Previous suggestions that the phosphorylation of a 44,000 dalton membrane protein is involved in this permeabilization process have been pursued. Fractionation of cells that had been incubated with [γ-³²P] ATP revealed that the labeled 44K phosphoprotein was found in both the membrane and mitochondrial fractions. Incubation of fractions isolated from unlabeled cells with [γ-³²P] ATP resulted in substantial formation of ³²P-44K in the mitochondrial fraction and less incorporation in the membrane fraction. The 44,000 dalton protein was identified as the α-subunit of mitochondrial pyruvate dehydrogenase by partial proteolytic mapping and immunological cross-reactivity with antibodies prepared against bovine pyruvate dehydrogenase. The phosphorylation of this protein in whole cells by externally added ATP is suppressed by inclusion in the incubation medium of carboxyatractyloside (CAT) and EDTA. These substances have no effect on ATP-dependent permeabilization, indicating that the phosphorylation of pyruvate dehydrogenase is not involved in this process.     

Regulation of a calcium-sensitive K+ channel (cIK1) by protein kinase C

Ca2+-sensitive K+ channels (IK1 channels) are required for many physiological functions such as cell proliferation, epithelial transport or cell migration. They are regulated by the intracellular Ca2+ concentration and by phosphorylation-dependent reactions. Here, we investigate by means of the patch-clamp technique mechanisms by which protein kinase C (PKC) regulates the canine isoform, cIK1, cloned from transformed renal epithelial (MDCK-F) cells. cIK1 elicits a K+-selective, inwardly rectifying, and Ca2+-dependent current when expressed in HEK293 or CHO cells. It is inhibited by charybdotoxin, clotrimazole, and activated by 1-ethyl-2-benzimidazolone. cIK1 is activated by intracellular application of ATP or ATP[gS]. ATP-dependent activation is reversed by PKC inhibitors (bisindolylmaleimide, calphostin C), while stimulation with ATP[gS] resists PKC inhibition. Stimulation of protein kinase C with phorbol 12-myristate 13-acetate (PMA) leads to the acute activation of cIK1 currents, which are blocked by PKC inhibitors. In contrast, PKC depletion by overnight incubation with PMA prevents ATP-dependent cIK1 activation. Neither single mutations nor the simultaneous mutation of all PKC sites (T101, S178, T329) to alanine alter the acute regulation of cIK1 channels by PKC. However, current amplitudes of CIK1-T329A and the triple mutant are dramatically increased upon long-term treatment with PMA. These mutations thereby disclose an inhibitory effect on cIKl current of the PKC site at T329. Our results indicate that cIK1 channel activity is regulated in two ways. PKC-dependent activation of cIK1 channels occurs indirectly, while the inhibitory effect probably requires a direct interaction with the channel protein.     

ATP-resistant variants of transformed mouse fibroblasts

Addition of ATP to cultures of transformed mouse fibroblasts, 3T6 cells, resulted in cell growth inhibition, whereas the growth of the non-transformed counterparts, 3T3 cells, was only slightly affected. The inhibition was found to be specific for adenine nucleotides, and concentration dependent. At relatively low concentrations (e.g., 1.0 mM) the effect of ATP was cytostatic, whereas at higher concentrations (e.g., 1.0 mM) a cytotoxic effect was exerted. ATP-resistant variants of 3T6 cells were selected by exposure of cultures to gradually elevated concentrations of ATP. The variants were found to resemble the non-transformed counterparts, 3T3 cells, more than the 3T6 parent cells, by the following criteria: ATP-induced alterations in the membrane potential, changes in membrane permeability, cell growth inhibition, and colony formation on soft agar. The data indicate that long exposure of the transformed cells to external ATP results in redifferentiation and reduction in their tumorigenicity.     

Calcium metabolism and enzyme secretion in guinea pig pancreas. Uptake, storage and release of calcium in whole cells and mitochondrial and microsomal fractions

In isolated pancreatic acinar cells from the guinea pig stimulation of enzyme secretion by carbamoylcholine is slightly diminished in the absence of extracellular Ca. LaCl3 in a concentration, which does not influence the secretory response to carbamoylcholine, nearly completely abolishes 45Ca uptake by cells, indicating that Ca uptake is not necessary for secretion. In cells preloaded with 45CaCl2, addition of carbamoylcholine leads to an immediate release of 45Ca, which can be blocked by atropine or 8-(N,N-diethylamino)-octyl 3,4,5-trimethoxybenzoate and is not influences by LaCl3 in concentrations, which do not inhibit secretion. A similar release of 45CaCl2 from preloaded cells is obtained by addition of the mitochondrial inhibitors antimycin A, carbonylcyanide p trifluoromethoxyphenylhydrazone (FCCP), and oligomycin. Possibly due to markedly diminished ATP levels, neither antimycin A nor FCCP act as secretagogues, both compounds being inhibitors of secretion. Oligomycin, which decreases ATP levels only to 20%, stimulates secretion. Mitochondria and microsomes from pancreatic tissue are able to accumulate 45Ca. Mitochondrial 45Ca uptake can be driven by ATP or active respiration and is inhibited by NaN3, oligomycin, antimycin A or FCCP. Microsomal 45Ca uptake is ATP-dependent. NaN3 and mitochondrial inhibitors have no influence on microsomal 45Ca uptake, which is stimulated several-fold by oxalate. The results support the assumption, that in the guinea pig pancreas Ca mobilization from intracellular stores is necessary to initiate secretion. Due to their ability for an active accumulation of45Ca both mitochondria and microsomes could serve as intracellular calcium stores.     

Induction of permeability change and restoration of membrane permeability barrier in transformed cell cultures

Transformed 3T3 cells incubated with ATP at an alkaline pH become permeable to phosphorylated compounds. The increase in membrane permeability can be induced by incubation with ATP at a neutral pH but only if sodium fluoride is present. Fluoride is not necessary for activation of the permeability change in these cultures at the alkaline pH. The effect of fluoride is very rapid, and sodium fluoride by itself does not alter membrane permeability. The alteration of membrane permeability by ATP in 3T6 cells is reversible; the permeability barrier is restored by switching to neutral buffer in the presence or absence of divalent cations. The restoration of the membrane permeability barrier is prevented by fluoride, and by ATP itself; this action of ATP is specific and no other nucleoside triphosphates or chelating agents produce this effect. Untransformed 3T3 cells do not exhibit any appreciable change in permeability as a result of ATP treatment either in the presence or absence of fluoride. These results are consistent with the presence on the transformed cell surface of an ATP-requiring protein kinase and a fluoride-inhibitable protein phosphatase, which would be involved in the control of membrane permeability.     

A specific effect of external ATP on the permeability of transformed 3T3 cells

Addition of ATP causes a dramatic increase in the rate of p-nitrophenyl phosphate hydrolysis by intact 3T6 and 3T3 cells transformed by polyoma virus and simian virus 40 (SV40). In sharp contrast, untransformed 3T3 cells or secondary mouse embryo fibroblasts, either growing or resting, do not respond to ATP. The activation displays specificity, reversibility and dependence on pH, temperature and ATP concentration. The data suggest that exposure to ATP changes the permeability of transformed cells to p-nitrophenyl phosphate thus revealing an internal, ouabain-insensitive, phosphatase activity.     

Chemical Hypoxia-Induced Cell Death in Human Glioma Cells: Role of Reactive Oxygen Species,ATP Depletion,Mitochondrial Damage and Ca2+

This study was undertaken to evaluate whether chemical hypoxia-induced cell injury is a result of reactive oxygen species (ROS) generation, ATP depletion, mitochondrial permeability transition, and an increase in intracellular Ca²⁺, in A172 cells, a human glioma cell line. Chemical hypoxia was induced by incubating cells with antimycin A, an inhibitor of mitochondrial electron transport, in a glucose-free medium. Exposure of cells to chemical hypoxia resulted in cell death, ROS generation, ATP depletion, and mitochondrial permeability transition. The H₂O₂ scavenger pyruvate prevented cell death, ROS generation, and mitochondrial permeability transition induced by chemical hypoxia. In contrast, changes mediated by chemical hypoxia were not affected by hydroxyl radical scavengers. Antioxidants did not affect cell death and ATP depletion induced by chemical hypoxia, although they prevented ROS production and mitochondrial permeability transition induced by chemical hypoxia. Chemical hypoxia did not increase lipid peroxidation even when antimycin A was increased to 50 M, whereas the oxidant t-butylhydroperoxide caused a significant increase in lipid peroxidation, at a concentration that is less effective than chemical hypoxia in inducing cell death. Fructose protected against cell death and mitochondrial permeability transition induced by chemical hypoxia. However, ROS generation and ATP depletion were not prevented by fructose. Chemical hypoxia caused the early increase in intracellular Ca²⁺. The cell death and ROS generation induced by chemical hypoxia were altered by modulation of intracellular Ca²⁺ concentration with ruthenium red, TMB-8, and BAPTA/AM. However, mitochondrial permeability transition was not affected by these compounds. These results indicate that chemical hypoxia causes cell death, which may be, in part, mediated by H₂O₂ generation via a lipid peroxidation-independent mechanism and elevated intracellular Ca²⁺. In addition, these data suggest that chemical hypoxia-induced cell death is not associated directly with ATP depletion and mitochondrial permeability transition.     

Interaction of adenine nucleotides with the adenine nucleotide translocase regulates the developmental changes in proton conductance of the inner mitochondrial membrane.

2-h-old neonatal liver mitochondria, when depleted of adenine nucleotides, showed an 'ohmic' current-voltage relationship and a higher passive proton permeability of the membrane, resembling fetal mitochondrial behaviors for the proton conductance. Incubation of fetal mitochondria with ATP, GDP or carboxyatractyloside promoted a significant reduction in the passive proton permeability of the membrane and the appearance of the characteristic biphasic behavior for the proton conductance. It is concluded that the postnatal increase in intramitochondrial adenine nucleotide concentration promotes, by the interaction of the nucleotides with the adenine nucleotide translocase, the reduction in the passive proton permeability of the mitochondrial membrane, allowing efficient energy conservation in the neonatal liver.