Intracellular Na+, K+ and Cl− activities in Ehrlich ascites tumor cells

Ehrlich ascites tumor cell membrane potential (V_m) and intracellular Na⁺, K⁺ and Cl⁻ activities were measured under steady-state conditions in normal saline medium (Na⁺ = 154, K⁺ = 6, Cl⁻ = 150 mequiv./l). Membrane potential was estimated to be −23.3 ± 0.8 mV using glass microelectrodes. Intracellular ion activities were estimated with similar glass electrodes rendered ion-selective by incorporation of ion-specific ionophores. Measurements of V_m and ion-activity differences were made in the same populations of cells. Under these conditions the intracellular Na⁺, K⁺ and Cl⁻ activities are 4.6 ± 0.5; 68.3 ± 8.0; and 43.6 ± 2.1 mequiv./l, respectively. The apparent activity coefficients for Na⁺ and K⁺ are 0.18 ± 0.02 and 0.41 ± 0.05 respectively. These are significantly lower than the activity coefficients expected for the ions in physiological salt solutions (0.71 and 0.73, respectively). The activity coefficient for intracellular Cl⁻ (0.67 ± 0.03), however, is close to that of the medium (0.73), and the transmembrane electrochemical potential difference for Cl⁻ is not different from zero. The results establish that the energy available from the Na⁺ electrochemical gradient is much greater than previously estimated from chemical measurements.     

Regulatory volume increase in Ehrlich ascites tumor cells is mediated by the 1Na ∶ 1K ∶ 2Cl cotransport system

Summary After swelling in hyposmotic solution, Ehrlich ascites tumor cells shrink towards their original volume. Upon restoration of isosmolality (300 mOsm) the cells initially shrink but subsequently recover volume. This regulatory volume increase (RVI) is completely blocked when [Na⁺] _o or [Cl^–] _o is reduced by 50% in the presence of normal [K⁺] _o . With normal [NaCl] _o but less than 2 mm [K⁺] _o , not only is volume recovery blocked but the cells lose KCl and shrink. When [K⁺] _o is increased to 5 mm there is a rapid net uptake of K⁺ and Cl^– which results in volume recovery. This suggests that the reswelling phase requires the simultaneous presence of Na⁺, K⁺, and Cl^–. Although ouabain has no effect on volume recovery, bumetanide completely blocks RVI by inhibiting a cotransport pathway that mediates the net uptake of Na⁺, K⁺ and Cl^– in the ratio of 1Na1K2Cl. Na⁺ that accumulates is then replaced by K⁺ via the Na/K pump.I wish to thank my colleague, Dr. Thomas C. Smith for advice and helpful comments during the course of these studies. The excellent technical assistance provided by Rebecca Corcoran-Merrill is gratefully acknowledged.This investigation was supported by Grant CA 32927 from the National Cancer Institute, U.S. Public Health Service.     

Na+, K+, Cl− cotransport and its regulation in Ehrlich ascites Tumor cells. Ca2+/Calmodulin and protein kinase C dependent pathways

Summary Net Cl^– uptake as well as unidirectional³⁶Cl influx during regulatory volume increase (RVI) require external K⁺. Half-maximal rate of bumetanide-sensitive³⁶Cl uptake is attained at about 3.3mm external K⁺. The bumetanide-sensitive K⁺ influx found during RVI is strongly dependent on both Na⁺ and Cl^–. The bumetanide-sensitive unidirectional Na⁺ influx during RVI is dependent on K⁺ as well as on Cl^–. The cotransporter activated during RVI in Ehrlich cells, therefore, seems to transport Na⁺, K⁺ and Cl^–. In the presence of ouabain and Ba⁺ the stoichiometry of the bumetanide-sensitive net fluxes can be measured at 1.0 Na⁺, 0.8 K⁺, 2.0 Cl^– or approximately 1 : Na, 1 : K, 2 : Cl. Under these circumstances the K⁺ and Cl^– flux ratios (influx/efflux) for the bumetanide-sensitive component were estimated at 1.34 ±0.08 and 1.82 ± 0.15 which should be compared to the gradient for the Na⁺, K⁺, 2Cl^– cotransport system at 1.75 ± 0.24.Addition of sucrose to hypertonicity causes the Ehrlich cells to shrink with no signs of RVI, whereas shrinkage with hypertonic standard medium (all extracellular ion concentrations increased) results in a RVI response towards the original cell volume. Under both conditions a bumetanide-sensitive unidirectional K⁺ influx is activated. During hypotonic conditions a small bumetanide-sensitive K⁺ influx is observed, indicating that the cotransport system is already activated.The cotransport is activated 10–15 fold by bradykinin, an agonist which stimulates phospholipase C resulting in release of internal Ca²⁺ and activation of protein kinase C.The anti-calmodulin drug pimozide inhibits most of the bumetanide-sensitive K⁺ influx during RVI. The cotransporter can be activated by the phorbol ester TPA. These results indicate that the stimulation of the Na⁺, K⁺, Cl^– cotransport involves both Ca²⁺/calmodulin and protein kinase C.     

Volume-induced increase of K+ and Cl− permeabilities in Ehrlich ascites tumor cells. Role of internal Ca2+

Summary Ehrlich ascites tumor cells resuspended in hypotonic medium initially swell as nearly perfect osmometers, but subsequently recover their volume within 5 to 10 min with an associated KCl loss. 1. The regulatory volume decrease was unaffected when nitrate was substituted for Cl^–, and was insensitive to bumetanide and DIDS. 2. Quinine, an inhibitor of the Ca²⁺-activated K⁺ pathway, blocked the volume recovery. 3. The hypotonic response was augmented by addition of the Ca²⁺ ionophore A23187 in the presence of external Ca²⁺, and also by a sudden increase in external Ca²⁺. The volume response was accelerated at alkaline pH. 4. The anti-calmodulin drugs trifluoperazine, pimozide, flupentixol, and chlorpromazine blocked the volume response. 5. Depletion of intracellular Ca²⁺ stores inhibited the regulatory volume decrease. 6. Consistent with the low conductive Cl^– permeability of the cell membrane there was no change in cell volume or Cl^– content when the K⁺ permeability was increased with valinomycin in isotonic medium. In contrast, addition of the Ca²⁺ ionophore A23187 in isotonic medium promoted Cl^– loss and cell shrinkage. During regulatory volume decrease valinomycin accelerated the net loss of KCl, indicating that the conductive Cl^– permeability was increased in parallel with and even more than the K⁺ permeability. It is proposed that separate conductive K⁺ and Cl^– channels are activated during regulatory volume decrease by release of Ca²⁺ from internal stores, and that the effect is mediated by calmodulin.     

Intracellular compartmentation of Na+, K+ and Cl− in the Ehrlich ascites tumor cell: Correlation with the membrane potential

Summary The intracellular distribution of Na⁺, K⁺, Cl^– and water has been studied in the Ehrlich ascites tumor cell. Comparison of the ion and water contents of whole cells with those of cells exposed to La³⁺ and mechanical stress indicated that La³⁺ treatment results in selective damage to the cell membrane and permits evaluation of cytoplasmic and nuclear ion concentrations. The results show that Na⁺ is sequestered within the nucleus, while K⁺ and Cl^– are more highly concentrated in the cell cytoplasm. Reduction of the [Na⁺] of the incubation medium by replacement with K⁺ results in reduced cytoplasmic [Na⁺], increased [Cl^–] and no change in [K⁺]. Nuclear concentrations of these ions are virtually insensitive to the cation composition of the medium. Concomitant measurements of the membrane potential were made. The potential in control cells was –13.7 mV. Reduction of [Na⁺] in the medium caused significant depolarization. The measured potential is describable by the Cl^– equilibrium potential and can be accounted for in terms of cation distributions and permeabilities. The energetic implications of the intracellular compartmentation of ions are discussed.     

Separate,Ca2+-activated K+ and Cl− transport pathways in Ehrlich ascites tumor cells

Summary The net loss of KCl observed in Ehrlich ascites cells during regulatory volume decrease (RVD) following hypotonic exposure involves activation of separate conductive K⁺ and Cl^– transport pathways. RVD is accelerated when a parallel K⁺ transport pathway is provided by addition of gramicidin, indicating that the K⁺ conductance is rate limiting. Addition of ionophore A23187 plus Ca²⁺ also activates separate K⁺ and Cl^– transport pathways, resulting in a hyperpolarization of the cell membrane. A calculation shows that the K⁺ and Cl^– conductance is increased 14-and 10-fold, respectively. Gramicidin fails to accelerate the A23187-induced cell shrinkage, indicating that the Cl^– conductance is rate limiting. An A23187-induced activation of⁴²K and³⁶Cl tracer fluxes is directly demonstrated. RVD and the A23187-induced cell shrinkage both are: (i) inhibited by quinine which blocks the Ca²⁺-activated K⁺ channel. (ii) unaffected by substitution of NO ₃ ^– or SCN^– for Cl^–, and (iii) inhibited by the anti-calmodulin drug pimozide. When the K⁺ channel is blocked by quinine but bypassed by addition of gramicidin, the rate of cell shrinkage can be used to monitor the Cl^– conductance. The Cl^– conductance is increased about 60-fold during RVD. The volume-induced activation of the Cl^– transport pathway is transient, with inactivation within about 10 min. The activation induced by ionophore A23187 in Ca²⁺-free media (probably by release of Ca²⁺ from internal stores) is also transient, whereas the activation is persistent in Ca²⁺-containing media. In the latter case, addition of excess EGTA is followed by inactivation of the Cl^– transport pathway. These findings suggest that a transient increase in free cytosolic Ca²⁺ may account for the transient activation of the Cl^– transport pathway. The activated anion transport pathway is unselective, carrying both Cl^–, Br^–, NO ₃ ^– , and SCN^–. The anti-calmodulin drug pimozide blocks the volume- or A23187-induced Cl^– transport pathway and also blocks the activation of the K⁺ transport pathway. This is demonstrated directly by⁴²K flux experiments and indirectly in media where the dominating anion (SCN^–) has a high ground permeability. A comparison of the A23187-induced K⁺ conductance estimated from⁴²K flux measurements at high external K⁺, and from net K^– flux measurements suggests single-file behavior of the Ca²⁺-activated K⁺ channel. The number of Ca²⁺-activated K⁺ channels is estimated at about 100 per cell.     

Purinergic inhibition of Na+,K+,Cl− cotransport in C11-MDCK cells: Role of stress-activated protein kinases

Previously, we observed that sustained activation of P2Y₁ leads to inhibition of Na⁺,K⁺,Cl⁻ cotransport (NKCC) in C11 cells resembling intercalated cells from collecting ducts of the Madin-Darby canine kidney. This study examined the role of stress-activated protein kinases (SAPK) in NKCC inhibition triggered by purinergic receptors. Treatment of C11 cells with ATP led to sustained phosphorylation of SAPK such as JNK and p38. Activation of these kinases also occurred in anisomycin-treated cells. Surprisingly, we observed that compounds SP600125 and SB202190, known as potent inhibitors of JNK and p38 in cell-free systems, activated rather than inhibited phosphorylation of the kinases in C11 cells. Importantly, similarly to ATP, all the above-listed activators of JNK and p38 phosphorylation inhibited NKCC. Thus, our results suggest that activation of JNK and/or p38 contributes to NKCC suppression detected in intercalated-like cells from distal tubules after their exposure to P2Y₁ agonists.     

Loop diuretics may fail to inhibit (Na+, K+, Cl−) ‘cotransport’ in human red cells

The inhibition of passive K+ influx into human red blood cells (RBC) by loop diuretics was found to be dependent on the external Na+ concentration. In the absence of external Na+, there was minimal inhibition but the influx remained dependent on Cl- ions. Thus, raising the external Na+ concentration increased the affinity of the putative (Na+, K+, Cl-) cotransport system in human RBC for loop diuretics.     

Octopamine potentiates intracellular Na+ and Cl− reductions during cell volume regulation inLimulus exposed to hypoosmotic stress

Summary The biogenic amine octopamine (OCT) appears to be involved in cell volume regulation in the horseshoe crab,Limulus polyphemus, during hypoosmotic stress. OCT is present in relatively large amounts (160 nmoles/g dry wt) in the cardiac ganglion. Furthermore, OCT is released from the isolated ganglion during exposure to hypoosmotic media. This release is reflected in the elevation of blood OCT concentrations from basal levels of 4×10^–9 M reaching 1.2×10^–8 M within 72 h of exposure of animals to hypoosmotic media. The circulating OCT potentiates the hypoosmotically-induced reductions of intracellular Na⁺ and Cl^– by a ouabain-sensitive mechanism which complements the main ion regulating (ouabain-insensitive) mechanisms utilized during cell volume recovery.Abbreviations ASW artificial seawater - ECS extracellular space - LS Limulus saline - MOPS morpholinopropanesulfonic acid - OCT octopamine - PNMT phenylethanolamine-N-methyl transferase     

Regulation by cell volume of Na+-K+-2Cl− cotransport in vascular endothelial cells: role of protein phosphorylation

Summary Na⁺-K⁺-2Cl^– cotransport in aortic endothelial cells is activated by cell shrinkage, inhibited by cell swelling, and is responsible for recovery of cell volume. The role of protein phosphorylation in the regulation of cotransport was examined with two inhibitors of protein phosphatases, okadaic acid and calyculin, and a protein kinase inhibitor, K252a. Both phosphatase inhibitors stimulated cotransport in isotonic medium, with calyculin, a more potent inhibitor of protein phosphatase I, being 50-fold more potent. Neither agent stimulated cotransport in hypertonic medium. Stimulation by calyculin was immediate and was complete by 5 min, with no change in cell Na + K content, indicating that the stimulation of cotransport was not secondary to cell shrinkage. The time required for calyculin to activate cotransport was longer in swollen cells than in normal cells, indicating that the phosphorylation step is affected by cell volume. Activation of cotransport when cells in isotonic medium were placed in hypertonic medium was more rapid than the inactivation of cotransport when cells in hypertonic medium were placed in isotonic medium, which is consistent with a shrinkage-activated kinase rather than a shrinkage-inhibited phosphatase. K252a, a nonspecific protein kinase inhibitor, reduced cotransport in both isotonic and hypertonic media. The rate of inactivation was the same in either medium, indicating that dephosphorylation is not regulated by cell volume. These results demonstrate that Na⁺-K⁺-2Cl^– cotransport is activated by protein phosphorylation and is inactivated by a Type I protein phosphatase. The regulation of cotransport by cell volume is due to changes in the rate of phosphorylation rather than dephosphorylation, suggesting the existence of a volume-sensitive protein kinase. Both the kinase and the phosphatase are constitutively active, perhaps to allow for rapid changes in cotransport activity.This work was supported by a Clinical Investigator Award DK01643 (to W.C.O) and a Grant-in-Aid from the American Heart Association of Georgia.     

Reduced growth of Ehrlich ascites tumor cells in creatine depleted mice fed β-guanidinopropionic acid

The effect of implantation of Ehrlich ascites tumor (EAT) cells of creatine distribution was investigated. It was also studied how depletion of creatine by feeding creatine-analogue β-guanidinopropionic acid (β-GPA) affects the growth of EAT cells in mice. Enhanced mobilization of creatine from host tissues to EAT cells against a greater concentration gradient was observed. The creatine (but not creatinine) level in blood plasma was lowered to 22% of the normal value by β-GPA feeding alone and assimilation of ¹⁴C-creatine into EAT cells was inhibited. The growth of EAT cells was significantly reduced and the duration of survival of mice after implantation of EAT cells was extended when the creatine concentration was decreased. A decrease in daily food consumption and the degree of muscle atrophy after implantation of EAT cells was less in β-GPA than control groups. In the creatine-depleted mice, the rate of increase in total EAT cell number and the volume of abdominal ascites were approximately half of the control values, and more dead EAT cells were observed. These results suggest that supplementation of β-GPA inhibits creatine transfer to EAT cells and reduces the growth of cancer cells.     

Phosphate transport and its relationship to cation movements in Ehrlich Lettré ascites tumor cells.

In view of the importance of P_i in the control of cell metabolism, it was of interest to study the mechanism and regulation of P_i uptake by ascites tumor cells. For this purpose, the incorporation of ³²P_i into Ehrlich Lettré cells was compared when competitive anions and inhibitors which alter cation movements were present. Anions such as sulfanilate (35 mm) and succinate (30 mm) decrease ³²P_i uptake by ca. 35%, suggesting that transport is mediated by a protein similar to the 100,000 M_r anion carrier isolated from erythrocyte membranes. Furosemide, a diuretic which bears a structural analogy to sulfanilate inhibitors of anion transport, also decreases ³²P_i incorporation at concentrations as low as 2 × 10^?5m. This inhibitor blocks cation exchange in ascites tumor cells, and from the present data, it is suggested that a possible function of the furosemidesensitive cation exchange protein is to facilitate anion transport. Ouabain, known to inhibit (Na⁺ + K⁺)-ATPase and its dephosphorylation, stimulates the rate of incorporation of ³²P_i into cells and also raises the net inorganic phosphate level. The stimulation of ³²P_i incorporation is decreased by sulfanilate or succinate. In contrast to the effects of ouabain, addition of 10 mm K⁺, which is known to stimulate (Na⁺ + K⁺)-ATPase and its dephosphorylation, decreases ³²P_i incorporation. These observations suggest that anion transport and energy-dependent Na⁺ and K⁺ movements may be closely coupled to the intact cell.     

Measurement and stoichiometry of bumetanide-sensitive (2Na∶1K∶3Cl) cotransport in ferret red cells

Summary The bumetanide-sensitive uptake of Na⁺, K^–(Rb^–) and Cl^– has been measured at 21°C in ferrent red cells treated with (SITS+DIDS) to minimize anion flux via capnophorin (Band 3). During the time course of the influx experiments tracer uptake was a first-order rate process. At normal levels of external Na⁺ (150mm) the bumetanide-sensitive uptake of K⁺ was dependent on Cl^– and represented almost all of the K⁺ uptake, the residual flux demonstrating linear concentration dependence. The uptake of Na⁺ and Cl^– was only partially inhibited by bumetanide indicating that pathways other than (Na+K+Cl) cotransport participate in these fluxes. The diuretic-sensitive uptake of Na⁺ or Cl^– was, however, abolished by the removal of K⁺ or the complementary ion indicating that bumetanide-sensitive fluxes of Na⁺, K⁺ and Cl^– are closely coupled. At very low levels of [Na] _o (<5mm) K⁺ influx demonstrated complex kinetics, and there was evidence of the unmasking of a bumetanide-sensitive Na⁺-independent K⁺ transport pathway. The stoichiometry of bumetanide-sensitive tracer uptake was 2Na1K3Cl both in cells suspended in a low and a high K⁺-containing medium. The bumetanide-sensitive flux was markedly reduced by ATP depletion. We conclude that a bumetanide-sensitive cotransport of (2Na1K3Cl) occurs as an electroneutral complex across the ferret red cell membrane.     

Stoichiometry and ion affinities of the Na−K−Cl cotransport system in the intestine of the winter flounder (Pseudopleuronectes americanus)

Summary Na–K–Cl cotransport stoichiometry and affinities for Na, K and Cl were determined in flounder intestine. Measurement of simultaneous NaCl and RbCl influxes resulted in ratios of 2.2 for Cl/Na and 1.8 for Cl/Rb. The effect of Na and Rb on Rb influx showed first order kinetics withK _1/2 values of 5 and 4.5mm and Hill coefficients of 0.9 and 1.2, respectively. The effect of Cl on rubidium influx showed a sigmoidal relationship withK _1/2 of 20mm and a Hill coefficient of 2.0. The effects of variations in Na and Cl concentration on short-circuit current (I _sc) were also determined. TheK _1/2 for Na was 7mm with a Hill coefficient of 0.9 and theK _1/2 for Cl was 46mm with a Hill coefficient of 1.9. Based on the simultaneous influx measurements, a cotransport stoichiometry of 1Na1K2Cl is concluded. The Hill coefficients for Cl suggest a high degree of cooperativity between Cl binding sites. Measurements of the ratio of net Na and Cl transepithelial fluxes under short-circuit conditions (using a low Na Ringer solution to minimize the passive Na flux) indicate that the Cl/Na flux ratio is approximately 21. Therefore Na recycling from serosa to mucosa does not significantly contribute to theI _sc. Addition of serosal ouabain (100 m) inhibited Rb influx, indicating that Na–K–Cl cotransport is inhibited by ouabain. This finding suggests that a feedback mechanism exists between the Na–K-ATPase on the basolateral membrane and the apical Na–K–2Cl cotransporter.     

Vasopressin alters the mechanism of apical Cl− entry from Na+:Cl− to Na+:K+:2Cl− cotransport in mouse medullary thick ascending limb

Summary Experiments were performed usingin vitro perfused medullary thick ascending limbs of Henle (MTAL) and in suspensions of MTAL tubules isolated from mouse kidney to evaluate the effects of arginine vasopressin (AVP) on the K⁺ dependence of the apical, furosemide-sensitive Na⁺:Cl^– cotransporter and on transport-related oxygen consumption (QO₂). In isolated perfused MTAL segments, the rate of cell swelling induced by removing K⁺ from, and adding onemm ouabain to, the basolateral solution [ouabain(zero-K⁺)] provided an index to apical cotransporter activity and was used to evaluated the ionic requirements of the apical cotransporter in the presence and absence of AVP. In the absence of AVP cotransporter activity required Na⁺ and Cl^–, but not K⁺, while in the presence of AVP the apical cotransporter required all three ions.⁸⁶Rb⁺ uptake into MTAL tubules in suspension was significant only after exposure of tubules to AVP. Moreover,²²Na⁺ uptake was unaffected by extracellular K⁺ in the absence of AVP while after AVP exposure²²Na⁺ uptake was strictly K⁺-dependent. The AVP-induced coupling of K⁺ to the Na⁺:Cl^– cotransporter resulted in a doubling in the rate of NaCl absorption without a parallel increase in the rate of cellular²²Na⁺ uptake or transport-related oxygen consumption. These results indicate that arginine vasopressin alters the mode of a loop diuretic-sensitive transporter from Na⁺:Cl^– cotransport to Na⁺:K⁺:2Cl^– cotransport in the mouse MTAL with the latter providing a distinct metabolic advantage for sodium transport. A model for AVP action on NaCl absorption by the MTAL is presented and the physiological significance of the coupling of K⁺ to the apical Na⁺:Cl^– cotransporter in the MTAL and of the enhanced metabolic efficiency are discussed.     

Thiol-Dependent passive K/Cl transport in sheep red cells: IV. Furosemide inhibition as a function of external Rb+, Na+, and Cl−

Summary The effect of the loop diuretic furosemide (4-chloro-N-furfuryl-5-sulfamoyl-anthranilic acid) on the thiol-dependent, ouabain-insensitive K(Rb)/Cl transport in low K⁺ sheep red cells was studied at various concentrations of extracellular Rb⁺, Na⁺ and Cl^–. In Rb⁺-free NaCl media, 2×10^–3 m furosemide inhibited only one-half of thiol-dependent K⁺ efflux. In the presence of 23mm RbCl, however, the concentration of furosemide to produce 50% K⁺ efflux inhibition (IC₅₀) was 5×10^–5 m. In Rb⁺ containing NaCl media, the inhibitory effect of 10^–3 m furosemide was equal to that caused by NO ₃ ^– replacement of Cl^– in the medium. The apparent synergistic action of furosemide and external Rb⁺ on K⁺ efflux was also seen in the ouabain-insensitive Rb⁺ influx. A preliminary kinetic analysis suggests that furosemide binding alters both maximal K⁺(Rb⁺) transport and apparent external Rb⁺ affinity. In the presence of external Rb⁺, Na⁺ (as compared to choline) exerted a small but significant augmentation of the furosemide inhibition of K⁺(Rb⁺) fluxes. There was no effect of Cl^– on the IC₅₀ value of furosemide. As there is no evidence for coupled Na⁺K⁺ cotransport in low K⁺ sheep red cells, furosemide may modify thiol-dependent K⁺(Rb⁺/Cl flux or Rb⁺ (and to a slight degree Na⁺) modulate the effect of furosemide.     

Cell swelling activates K+ and Cl− channels as well as nonselective,stretch-activated cation channels in ehrlich ascites tumor cells

Summary Cell-attached patch-clamp recordings from Ehrlich ascites tumor cells reveal nonselective cation channels which are activated by mechanical deformation of the membrane. These channels are seen when suction is applied to the patch pipette or after osmotic cell swelling. The channel activation does not occur instantaneously but within a time delay of 1/2 to 1 min. The channel is permeable to Ba²⁺ and hence presumably to Ca²⁺. It seems likely that the function of the nonselective, stretch-activated channels is correlated with their inferred Ca²⁺ permeability, as part of the volume-activated signal system. In isolated insideout patches a Ca²⁺-dependent, inwardly rectifying K⁺ channel is demonstrated. The single-channel conductance recorded with symmetrical 150 mm K⁺ solutions is for inward current estimated at 40 pS and for outward current at 15 pS. Activation of the K⁺ channel takes place after an increase in Ca²⁺ from 10^–7 to 10^–6 m which is in the physiological range. Patch-clamp studies in cellattached mode show K⁺ channels with spontaneous activity and with characteristics similar to those of the K⁺ channel seen in excised patches. The single-channel conductance for outward current at 5 mm external K⁺ is estimated at about 7 pS. A K⁺ channel with similar properties can be activated in the cellattached mode by addition of Ca²⁺ plus ionophore A23187. The channel is also activated by cell swelling, within 1 min following hypotonic exposure. No evidence was found of channel activation by membrane stretch (suction). The time-averaged number of open K⁺ channels during regulatory volume decrease (RVD) can be estimated at 40 per cell. The number of open K⁺ channels following addition of Ca²⁺ plus ionophore A23187 was estimated at 250 per cell. Concurrent activation in cell-attached patches of stretch-activated, nonselective cation channels and K⁺ channels in the presence of 3 mm Ca²⁺ in the pipette suggests a close spatial relationship between the two channels. In excised inside-out patches (with NMDG chloride on both sides) a small 5-pS chloride channel with low spontaneous activity is observed. The channel activity was not dependent on Ca²⁺ and could not be activated by membrane stretch (suction). In cell-attached mode singlechannel currents with characteristics similar to the channels seen in isolated patches are seen. In contrast to the channels seen in isolated patches, the channels in the cell-attached mode could be activated by addition of Ca²⁺ plus ionophore A23187. The channel is also activated by hypotonic exposure with a single-channel conductance at 7 pS (or less) and with a time delay at about 1 min. The number of open channels during RVD is estimated at 80 per cell. Two other types of Cl^– channels were regularly recorded in excised inside-out patches: a voltage-activated 400-pS channel and a 34-pS Cl^– channel which show properties similar to the Cl^– channel in the apical membrane in human airway epithelial cells. There is no evidence for a role in RVD for either of these two channels.     

2′(3′),5′-ADP inhibits initiation-dependent protein synthesis in a cell-free system from Ehrlich ascites tumor cells

When tested in a poly(U)-dependent polyphenylalanine synthesizing system and in a postnuclear supernatant, both derived from Ehrlich ascites tumor cells, 2(3),5-ADP did not affect chain elongation of polypeptide synthesis. In a cell-free system which was dependent on initiation and programmed by natural mRNA, however, the amino acid incorporating activity was suppressed to about 10% of the control in the presence of 1 mM 2(3),5-ADP. The inhibitor was shown not to interfere with the attachment of poly(U) to the small ribosomal subunit and with the formation of mRNA-80S ribosome complexes in a complete protein synthesizing system. The subsequent attachment of a 40S ribosomal subunit to the mRNA-80S ribosome complex and the formation of polysomes, however, was depressed by the inhibitor. The experimental results suggest that 2(3),5-ADP inhibits initiation-dependent protein synthesis between monosome formation and the formation of the first peptide bond(s).     

Bumetanide-sensitive Ion Fluxes in Vascular Smooth Muscle Cells: Lack of Functional Na+, K+, 2 Cl− Cotransport

To examine the involvement of Na⁺,K⁺,2Cl⁻ cotransport in monovalent ion fluxes in vascular smooth muscle cells (VSMC), we compared the effect of bumetanide on ⁸⁶Rb, ³⁶Cl and ²²Na uptake by quiescent cultures of VSMC from rat aorta. Under basal conditions, the values of bumetanide-sensitive (BS) inward and outward ⁸⁶Rb fluxes were not different. Bumetanide decreased basal ⁸⁶Rb uptake by 70–75% with a K _i of ∼0.2–0.3 μm. At concentrations ranging up to 1 μm, bumetanide did not affect ³⁶Cl influx and reduced it by 20–30% in the range from 3 to 100 μm. In contrast to ⁸⁶Rb and ³⁶Cl influx, bumetanide did not inhibit ²²Na uptake by VSMC. BS ⁸⁶Rb uptake was completely abolished in Na⁺- or Cl⁻-free media. In contrast to ⁸⁶Rb, basal BS ³⁶Cl influx was not affected by Na⁺ _o and K⁺ _o . Hyperosmotic and isosmotic shrinkage of VSMC increased ⁸⁶Rb and ³⁶Cl influx to the same extent. Shrinkage-induced increments of ⁸⁶Rb and ³⁶Cl uptake were completely abolished by bumetanide with a K _i or ∼0.3 μm. Shrinkage did not induce BS ⁸⁶Rb and ³⁶Cl influx in (Na⁺ or Cl⁻)- and (Na⁺ or K⁺)-depleted media, respectively. In the presence of an inhibitor of Na⁺/H⁺ exchange (EIPA), neither hyperosmotic nor isosmotic shrinkage activated ²²Na influx. Bumetanide (1 μm) did not modify basal VSMC volume and intracellular content of sodium, potassium and chloride but abolished the regulatory volume increase in isosmotically-shrunken VSMC. These data demonstrate the absence of the functional Na⁺,K⁺,2Cl⁻ cotransporter in VSMC and suggest that in these cells basal and shrinkage-induced BS K⁺ influx is mediated by (Na⁺ _o + Cl⁻ _o )-dependent K⁺/K⁺ exchange and Na⁺ _o -dependent K⁺,Cl⁻ cotransport, respectively. Received: 30 January 1996/Revised: 20 May 1996     

Na+-K+-Cl− cotransport system in brain capillary endothelial cells: Response to endothelin and hypoxia

Effect of endothelin-1 and chemically induced hypoxia on Na⁺−K⁺−Cl⁻ cotransport activity in cultured rat brain capillary endothelial cells was examined by using⁸⁶Rb⁺ as a tracer for K⁺; bumetanide-sensitive K⁺ uptake was defined as Na⁺−K⁺−Cl⁻ cotransport activity. Endothelin-1, phorbol 12-myristate 13-acetate (PMA), or thapsigargin increased Na⁺−K⁺−Cl⁻ cotransport activity. A protein kinase C inhibitor, bisindolylmaleimide, inhibited PMA- and endothelin-1- (but not thapsigargin-) induced Na⁺−K⁺−Cl⁻ cotransport activity, indicating the presence of both protein kinase C-dependent regulatory mechanisms and protein kinase C-independent mechanisms which involve intracellular Ca²⁺. Oligomycin, sodium azide, or antimycin A increased Na⁺−K⁺−Cl⁻ cotransport activity by 80–200%. Oligomycin-induced Na⁺−K⁺−Cl⁻ cotransport activity was reduced by an intracellular Ca²⁺ chelator (BAPTA/AM) but not affected by bisindolylmaleimide, suggesting the involvement of intracellular Ca²⁺, and not protein kinase C, in hypoxia-induced Na⁺−K⁺−Cl⁻ cotransport activity. Portions were presented at “27th Annual Meeting, The American Society for Neurochemistry” Philadelphia, Pennsylvania, March 2–6, 1996.