Effects of diadenosine polyphosphates,ATP and angiotensin II on membrane voltage and membrane conductances of rat mesangial cells

Diadenosine polyphosphates have been shown to influence renal perfusion pressure. As mesangial cells may contribute to these effects we investigated the effects of diadenosine triphosphate (Ap₃A), diadenosine tetraphosphate (Ap₄A), diadenosine pentaphosphate (Ap₅A) and diadenosine hexaphosphate (Ap₆A) on membrane voltage (V _m) and membrane conductance (g _m) in mesangial cells (MC) of normotensive Wistar-Kyoto (WKY) and spontaneously hypertensive (SHR) rats in primary and long-term culture. We applied the patch-clamp technique in the fast-whole-cell configuration to measure V _m and g _m. To compare the effects of diadenosine polyphosphates with hitherto known agonists we also tested adenosine 5-triphosphate (ATP) and angiotensin II (Ang II). As there was no significant difference in the V _m values in MC of WKY (–42±1 mV, n=70) and SHR rats (–45±2 mV, n=99) as well as in the agonist-induced changes of V _m, all data were pooled. The V _m of all the cells was –44±1 mV (n=169) and g _m was 15.9±1.8 nS (n=141). Ion-exchange experiments showed the presence of a K⁺ and a non-selective cation conductance in resting MC whereas a Cl^– conductance or a Na⁺selective conductance could not be observed. Ap₃A, Ap₄A, Ap₅A, AP₆A and ATP each at a concentration of 5 mol/l, led to a significant depolarization of V _m by 5±2 mV (n=14), 7±1 mV (n=25), 3±1 mV (n=23), 2±1 mV (n=16), and 14±2 mV (n=23), respectively. For Ap₄A, the most potent diadenosine polyphosphate, we determined the half-maximally effective concentration (EC ₅₀) as 6 mol/l (n=5–25), for ATP as 2 mol/l (n=9–37), and for Ang II as 8 nmol/l (n=6–18). Ap₄A 100 mol/l increased g _m significantly by 55±20% (n=16), 100 mol/l ATP by 135±60% (n=18). The diadenosine polyphosphates examined were able to depolarize V _m (Ang II >ATP> Ap₄A>Ap₃A>Ap₅A>Ap₆A) by activation of a Cl^– conductance and a non-selective cation conductance, as do ATP or Ang II.     

Effect of bradykinin and histamine on the membrane voltage,ion conductances and ion channels of human glomerular epithelial cells (hGEC) in culture

The effects of bradykinin (BK) and histamine (Hist) on the membrane voltage (V _m), ion conductances and ion channels of cultured human glomerular epithelial cells (hGEC) were examined with the nystatin patch clamp technique. Cells were studied between passage 3 and 20 in a bath rinsed with Ringer-like solution at 37°C. The mean value of V _m was –41±0.5 mV (n=189). BK (10^–6 mol/l, n=29) and Hist (10^–5 mol/l, n= 55) induced a rapid transient hyperpolarization by 15±1 mV and 18±1 mV, respectively. The hyperpolarization was followed by a long lasting depolarization by 6±1 mV (BK 10^–6 mol/l) and 7±1 mV (Hist 10^–5 mol/l). The ED₅₀ was about 5×10^–8 mol/l for BK and 5×10^–7 mol/l for Hist. In the presence of both agonists, increases of outward and inward currents were observed. A change in the extracellular K⁺ concentration from 3.6 to 30 mmol/l depolarized V _m by 8±1 mV and completely inhibited the hyperpolarizing effect of both agents (n=11). Reduction of extracellular Cl^– concentration from 145 to 30 mmol/l led to a depolarization by 2 ±1 mV (n=25). In 30 mmol/l Cl^– the depolarizations induced by BK (10^–7 mol/l) and Hist (10^–6 mol/l) were augmented to 9±2 mV (n=14) and to 10±2 mV (n=11), respectively. Ba²⁺ (5 mmol/l) depolarized V _m by 19±5 mV (n=6) and completely inhibited the hyperpolarization induced by BK (10^–6 mol/l, n=3) and reduced that of Hist (10^–5 mol/l) markedly (n=3). Preincubation with the K⁺ channel blocker charybdotoxin (1–10 nmol/l) for 3 min had no significant effect on V _m, but reduced markedly the BK(10^–6 mol/l, n=11) and Hist-(10^–5 mol/l, n=6) induced hyperpolarizations. In 10 out of 31 experiments in the cell attached nystatin patch configuration big K⁺ channels with a conductance of 247±17 pS were found. The open probability of these K⁺ channels was increased 3- to 5-fold during the hyperpolarization induced by BK (10^–7 mol/l) or Hist (10^–5 mol/l, both n= 4). In excised inside/out patches this K⁺ channel had a mean conductance of 136±8.5 pS (n=10, clamp voltage 0 mV). The channel was outwardly rectifying and its open probability was increased when Ca²⁺ on the cytosolic side was greater than 0.1 mol/l. The data indicate that BK and Hist activate a and a in hGEC. The hyperpolarization is induced by the activation of a Ca²⁺-dependent maxi K⁺ channel.     

A stretch-activated K+ channel in the basolateral membrane ofXenopus kidney proximal tubule cells

The present study examined whether a basolateral potassium ion (K⁺) channel is activated by membrane-stretching in the cell-attached patch. A K⁺ channel of conductance of 27.5 pS was most commonly observed in the basolateral membrane ofXenopus kidney proximal tubule cells. Channel activity increased with hyperpolarizing membrane potentials [at more positive pipette potentials (V _p)]. Open probability (P _o) was 0.03, 0.13, and 0.21 atV _p values of 0, 40, and 80 mV, respectively. Barium (0.1 mM) in the pipette reducedP _o by 79% at aV _p of 40 mV. Application of negative hydraulic pressure (−16 to −32 cm H₂O) to the pipette markedly activated outward currents (fromP _o=0.01 to 0.75) at aV _p of −80 mV, but not inward currents at aV _p of 80 mV. The size of the activated outward currents (from cell to pipette) did not change by replacing chloride with gluconate in the pipette. These results indicate that a stretch-activated K⁺ channel exists in the basolateral membrane of proximal tubule cells. It may play an important role as a K⁺ exit pathway when the cell membrane is stretched (for example, by cell swelling).     

Effects of ouabain and temperature on cell membrane potentials in isolated perfused straight proximal tubules of the mouse kidney

In isolated perfused segments of the mouse proximal tubule, the potential difference across the basolateral cell membrane (PDbl) was determined with conventional microelectrodes. Under control conditions with symmetrical solutions it amounted to –62±1 mV (n=118). The potential difference across the epithelium (PDte) was –1.7±0.1 mV (n=45). Transepithelial resistance amounted to 1.82±0.09 k cm (n=28), corresponding to 11.4±0.6 cm². Increasing bath potassium concentration from 5 to 20 mmol/l depolarized PDbl by +24±1 mV (n=103), and PDte by +1.6±0.1 mV (n=19). Thus, the basolateral cell membrane is preferably conductive to potassium. Rapid cooling of the bath perfusate from 38°C to 10°C led to a transient hyperpolarization of PDbl from –60±1 to –65±1 mV (n=21) within 40 s followed by gradual depolarization by +18±1% (n=14) within 5 min. The transepithelial resistance increased significantly from 1.78±0.11 k cm to 2.20±0.21 k cm (n=15). Rapid rewarming of the bath to 38°C caused a depolarization from –61±2 mV (n=17) to –43±2 mV (n=16) within 15 s followed by a repolarization to –59±2 mV (n=10) within 40 s. Ouabain invariably depolarized PDbl. During both, sustained cooling or application of ouabain, the sensitivity of PDbl to bath potassium concentration decreased in parallel to PDbl pointing to a gradual decrease of potassium conductance. Phlorizin hyperpolarized the cell membrane from –59±2 to –66±1 mV (n=13), virtually abolished the transient hyperpolarization under cooling, and significantly reduced the depolarization after rewarming from +17±2 mV (n=16) to +9±3 mV (n=9).The present data indicate that the contribution of peritubular potassium conductance to the cell membrane conductance decreases following inhibition of basolateral (Na⁺+K⁺)-ATPase. Apparently, cooling from 37° to 10°C does not only reduce (Na^–+K⁺)-ATPase activity but in addition luminal sodium uptake mechanisms such as the sodium glucose cotransporter. As a result, cooling leads to an initial hyperpolarization of the cell followed by depolarization only after some delay.Parts of this study have been presented at the 60th and 61th Meeting of the Deutsche Physiologische Gesellschaft, Dortmund 1984 and Berlin 1985     

Actin-dependent activation of ion conductances in bronchial epithelial cells

Activation of Cl^– and K⁺ channels is necessary to drive ion secretion in epithelia. There is substantial evidence from previous reports that vesicular transport and exocytosis are involved in the regulation of ion channels. In the present study we examined the role of cytoskeletal elements and components of intracellular vesicle transport on ion channel activation in bronchial epithelial cells. To this end, cells were incubated with a number of different compounds which interact with either microtubules or actin microfilaments, or which interfere with vesicle transport in the Golgi apparatus. The effectiveness of these agents was verified by fluorescence staining of cellular microtubules and actin. The function was examined in ³⁶Cl^– efflux studies as well as in whole-cell (WC) patch-clamp and cell-attached studies. The cells were studied under control conditions and after exposure to (in mmol/l) ATP (0.1), forskolin (0.01), histamine (0.01) and hypotonic bath solution (HBS, NaCl 72.5). In untreated control cells, ATP primarily activated a K⁺ conductance whilst histamine and forskolin induced mainly a Cl^– conductance. HBS activated both K⁺ and Cl^– conductances. Incubation of the cells with brefeldin A (up to 100 mol/l) did not inhibit WC current activation and ³⁶Cl^– efflux. Nocodazole (up to 170 mol/l) reduced the ATP-induced WC current, and mevastatin (up to 100 mol/l) the cell-swelling-induced WC current. Neither had any effect on the WC current induced by forskolin and histamine. Also ³⁶Cl^– efflux induced by HBS, ATP, forskolin and histamine was unaltered by these compounds. Similarly, colchicine (10 mol/l) and taxol (6 mol/l) affected neither ³⁶Cl^– efflux nor WC current induced by ATP, forskolin, histamine or HBS. In contrast, depolymerisation of actin by cytochalasin D (10 mol/l) significantly attenuated ³⁶Cl^– effluxes and WC current activation by the above-mentioned agonists. Incubation with a C2 clostridial toxin (5 nmol/l) showed similar effects on WC currents. Moreover, when cytochalasin D (10 mol/l), C2 clostridial toxins (5 nmol/l), or phalloidin (10 mol/l) were added to the pipette filling solution current activation was markedly reduced. However, in excised inside-out membrane patches, cytochalasin D (10 mol/l), G-actin (10 mol/l) and phalloidin (10 mol/l) had no effect. These data suggest that actin participates in the activation of ion channels in 16HBE14o- epithelial cells and support the concept that exocytosis is a crucial step in the regulation of Cl^– and K⁺ channels in these cells.     

Patch-clamp study of rubidium and potassium conductances in single cation channels from mammalian exocrine acini

Single-channel current recordings were carried out on excised inside-out patches of baso-lateral plasma membrane from exocrine acinar cells. The mouse pancreas and submandibular gland as well as the pig pancreas were investigated.In the mouse pancreas the voltage-insensitive Ca²⁺-activated cation channel was studied. Single-channel current-voltage (i/v) relationships were studied in symmetrical Rb⁺-rich solutions and in asymmetrical Rb⁺/Na⁺ and Na⁺/Rb⁺ solutions. In all cases the i/v relations were linear and had the same slope representing a single-channel conductance of about 33 pS which is identical to that previously obtained with symmetrical Na⁺ solutions or asymmetrical Na⁺/K⁺ solutions.In the mouse submandibular gland and the pig pancreas the voltage and Ca²⁺-activated K⁺ channel was studied. The outward currents observed after depolarization in the presence of quasi-physiological Na⁺/K⁺ gradients were immediately abolished when all the K⁺ in the bath fluid was replaced by Rb⁺ (bath fluid in contact with inside of plasma membrane). This effect was immediately and fully reversible upon return to the high K⁺ solution.The voltage and Ca²⁺-activated K⁺ channel was also studied in asymmetrical K⁺/Rb⁺ and Rb⁺/K⁺ solutions. In the first case inward (K⁺) currents could be observed but not outward (Rb⁺) currents, while in the other case inward (Rb⁺) currents could not be seen whereas outward (K⁺) currents were measured. The current-voltage relationships were approximately linear and the null potential was close to 0 mV in both situations. In contrast the null potential for current through the K⁺ channel in the presence of asymmetrical Na⁺/K⁺ or Li⁺/K⁺ solutions was about –70 mV and with reversed gradients about +60 mV.Outward K⁺ currents of reduced size (through the voltage and Ca²⁺-activated K⁺ channel) could be observed when the bath fluid contained 75 mM K⁺ and 75 mM Rb⁺, but not (in the same membrane patches) when 150 mM Rb⁺ and no K⁺ was present.It is concluded that the large voltage- and Ca²⁺-activated K⁺ channel has an extremely low Rb⁺ conductance. It is possible, however, that the permeability for Rb⁺ may be about the same as for K⁺. The voltage-insensitive Ca²⁺-activated cation channel does not discriminate between K⁺ and Rb⁺.     

Ca2+- and swelling-induced activation of ion conductances in bronchial epithelial cells

The present study was performed to examine Ca²⁺-dependent and cell-swelling-induced ion conductances in a polarized bronchial epithelial cell line (16HBE14o-). Whole-cell currents were measured in fast and slow whole-cell patch-clamp experiments in cells grown either on filters or on coated plastic dishes. In addition the transepithelial voltage (V _te) and resistance (R _te) were measured in confluent monolayers. Resting cells had a membrane voltage (V _m) of –36±1.1 mV (n=137) which was mainly caused by K⁺ and Cl^– conductances and to a lesser extent by a Na⁺ conductance. V _te was apical-side-negative after stimulation. Equivalent short-circuit current (I _sc = V _te/R _te) was increased by the secretagogues histamine (0.1 mmol/l), bradykinin (0.1–10 mol/l) and ATP (0.1–100 mol/l). The histamine-induced I _sc was blocked by either basolateral diphenhydramine (0.1 mmol/l, n=4) or apical cimetidine (0.1 mmol/l, n=4). In fast and slow whole-cell recordings ATP and bradykinin primarily activated a transient K⁺ conductance and hyperpolarized V _m. This effect was mimicked by the Ca²⁺ ionophore ionomycin (1 mol/l, n=11). Inhibition of the bradykinin-induced I _sc by the blocker HOE140 (1 mol/l, n=3) suggested the presence of a BK₂ receptor. The potency sequence of different nucleotide agonists on the purinergic receptor was UTP ATP > ITP > GTP CTP [,-methylene] ATP 2-methylthio-ATP = 0 and was obtained in I _sc measurements and patch-clamp recordings. This suggests the presence of a P_2u receptor. Hypotonic cell swelling activated both Cl^– and K⁺ conductances. The Cl^– conductance was only slightly inhibited by 4,4-diisothiocyanatostilbene-2,2-disulphonic acid (0.5 mmol/ l, n=3). These data indicate that 16HBE140- bronchial epithelial cells, which are known to express high levels of cystic fibrosis transmembrane conductance regulator protein, form a secretory epithelium. While hypotonic cell swelling activates both K⁺ and Cl^– channels, the Ca²⁺-induced Cl^– secretion is due mainly to activation of basolateral K⁺ channels.     

High-conductance K+ channel in apical membranes of principal cells cultured from rabbit renal cortical collecting duct anlagen

Using the patch clamp technique, one type of K⁺ channel was identified in the apical cell membrane of cultured principal cells of rabbit renal collecting ducts in the cell-attached or excised-patch configuration. The channel was highly selective for K⁺ over Na⁺ (typically 30-70-fold) and had a conductance of 180, SD±39 pS (n=6), referred to a situation of 140 mmolar K⁺-Ringer solution present on either surface of the patch membrane. Channel activity was completely blocked by Ba²⁺ (5 mmol/l) and partially inhibited by Na⁺. The latter was evidenced by a deviation from Goldman rectification at high cytoplasm-positive membrane potentials, which was observed when Na⁺ competed with K⁺ for channel entrace from the cytoplasmic surface. Channel open probability depended strongly on membrane voltage and cytoplasmic Ca²⁺ concentration. Open-close kinetics exhibited double exponential behaviour, with a strong voltage dependence of the slow open time constant. Infrequently also a substate conductance level was identified. The voltage and calcium dependence suggest that the channel plays a role in adjusting K⁺ secretion to Na⁺ absorption in the fine regulation of cation excretion in renal collecting ducts.     

Effects of inhibitors and ion substitutions on oscillations of cell membrane potential in cells expressing the RAS oncogene

Previous studies revealed that in NIH fibroblasts expressing the ras oncogene but not in other NIH fibroblasts, bradykinin leads to sustained, calcium dependent oscillations of cell membrane potential by repetitive activation of calcium-sensitive K⁺ channels. The present study has been performed to test for ion and inhibitor sensitivity of these oscillations. Both, Lys-bradykinin (kallidin) and bradykinin, but not any shorter peptide tested, maintained the oscillations. The oscillations are abolished in the presence of the K⁺ channel blocker barium (10 nmol/l). The amplitude but not the frequency of the oscillations is dependent on the extracellular potassium concentration. The oscillations are not dependent on the presence of extracellular sodium, bicarbonate or chloride. The oscillations are abolished in the absence of extracellular calcium and their frequency is significantly decreased at reduced extracellular calcium (to 0.2 mmol/l). The oscillations are not inhibited by acute administration of ouabain (0.1 mmol/l), by dimethylamiloride (100 mol/l), furosemide (1 mmol/l) and hydrochlorothiazide (100 mol/l), by cobalt (100 mol/l), zinc (100 mol/l), gadolinium (100 mol/l), verapamil (10 mol/l) and diltiazem (10 mol/l), but are abolished in the presence of 100 mol/l lanthanum, 1 mmol/l cadmium, 10 mol/l nifedipine, 25 mol/l SK & F 96365 and 200 mol/l TMB-8. Stimulation of calcium entry by 10 mol/l ionomycin is frequently followed by oscillations of cell membrane potential even in the absence of bradykinin. In conclusion, in cells expressing the ras oncogene bradykinin leads to sustained activation of calcium channels at the cell membrane, which cause oscillations of the cell membrane potential by triggering intracellular calcium release.     

Hyperpolarizing membrane potential changes in a cloned monkey kidney cell line

Electrophysiological properties of a cloned monkey kidney cell line, JTC-12, were studied. The mean resting potential and input resistance were –15.3 mV and 78 M, respectively. Spontaneous hyperpolarizations with increased membrane conductance were observed. Similar hyperpolarization could be elicited by mechanical and electrical stimulations. The mean reversal potential of these hyperpolarizations was –72.7 mV. Hyperpolarization could be also elicited in a chloride-free solution. These data indicate that: (1) JTC-12 cells exhibit spontaneous and induced hyperpolarizations, and (2) occurrence of hyperpolarization is related to an increase in membrane permeability to potassium ions.     

Ba2+ and amiloride uncover or induce a pH-sensitive and a Na+ or non-selective cation conductance in transitional cells of the inner ear

The membrane potential V _m the cytosolic pH (pH_i), the transference numbers (t) for K⁺, Cl^– and Na⁺/ non-selective cation (NSC) and the pH-sensitivity of V _m were investigated in transitional cells from the vestibular labyrinth of the gerbil. V _m, pH_i, , and the pH_i sensitivity of V _m were under control conditions were –92±1 mV (n=89 cells), pH_i 7.13±0.07 (n=11 epithelia), 0.87±0.02 (n=22), 0.02±0.01 (n=19), 0.01±0.01 (n=24) and –5 mV/pH unit (n=13 cells/n=11 epithelia), respectively. In the presence of 100 mol/l Ba²⁺ the corresponding values were: –70±1 mV (n=32), pH_i 7.16±0.08 (n=6), 0.31±0.05 (n=4), 0.06±0.01 (n=6), 0.20±0.03 (n=10) and -16 mV/pH-unit (n=15/n=6). In the presence of 500 mol/l amiloride the corresponding values were: –72±2mV (n=34), pH_i 7.00±0.07 (n=5), 0.50±0.04 (n=6), 0.04±0.01 (n=11), 0.28±0.04 (n=9) and –26 mV/pH-unit (n=20/n=5). In the presence of 20 mmol/l propionate plus amiloride the corresponding values were: –61±2 mV (n=27), pH_i 6.72±0.06 (n=5), 0.30±0.02 (n=6), 0.06±0.01 (n=5) and 0.40±0.02 (n=8), respectively. V _m was depolarized and and pH_i decreased due to (a) addition of 1 mmol/l amiloride in 150 mmol/l Na⁺ by 38±1 mV (n=8), from 0.82±0.02 to 0.17±0.02 (n=8) and by 0.13±0.01 pH unit (n=6), respectively; (b) reduction of [Na⁺] from 150 to 1.5 mmol/l by 3.3±0.5 mV (n=30), from 0.83±0.02 to 0.75±0.04 (n=9) and by 0.33±0.07 pH unit (n=4), respectively and (c) addition of 1 mmol/l amiloride in 1.5 mmol/l Na⁺ by 20±1 mV (n=11) and from 0.83±0.03 to 0.53±0.02 (n=5), respectively. These data suggest that the K⁺ conductance is directly inhibited by amiloride and Ba²⁺ and that Ba²⁺ and amiloride uncover or induce a pH-sensitive and a Na⁺/NSC conductance which may or may not be the same entity.Some of the data have been presented at various meetings and appear in abstract form in [31, 35, 37]     

Ca2+-and voltage activated K+ channel in apical cell membrane of gallbladder epithelium fromTriturus

The presence of Ca²⁺- and voltage-activated K⁺ channels was directly demonstrated in the apical cell membrane of gallbladder epithelium by patch-clamp single-channel current recording. In K⁺-depolarized epithelial cells, negative pipette potentials induced outward current steps when the patch-pipette was filled with Na⁺-rich solution and these current steps were not affected by the presence or absence of Cl^–. When K⁺-rich solution was in the pipette and K⁺-depolarized cells were examined, the current-voltage relations were linear with a single-channel conductance of 140 pS and polarity was reversed at 0 mV. In excised inside-out membrane patches, raising the free Ca²⁺ concentration of the medium facing the inner side of the membrane from 10^–7 to 10^–6 M evoked a marked increase in open state probability of the channels without affecting the elementary current steps. This suggests that intracellular Ca²⁺ as a second messenger plays a crucial role in the regulatory mechanism of the membrane potential by modulating the high-conductance apical K⁺ channels.     

Ion conductances of isolated cortical collecting duct cells

The study of ion conductances in the intact cortical collecting duct (CCD) with the patch-clamp method is rather difficult. An optimized method to isolate CCD cells from rat kidneys using an in vivo followed by an in vitro enzyme digestion is described. Individual CCD segments were collected after this digestion and incubated in EGTA-buffered medium. This procedure resulted in single cells or cell clusters. These freshly isolated CCD cells were studied with different modifications of the patch-clamp method. Membrane voltages measured in the cell-attached-nystatin configuration were –74 ±1mV (n=13) and –68±3 mV (n=22) in cells isolated from normal and mineralocorticoid-treated rats respectively. These values and those measured with the nystatin-perforated slow-whole-cell configuration (–79 ±1mV, n=23) are comparable to those measured in principal cells of isolated CCD segments. The cells hyperpolarized after the addition of amiloride and depolarized with the addition of adiuretin to the bath. The amiloride effect was enhanced when cells were isolated from deoxycorticosterone-acetate-treated rats. The cells were strongly depolarized upon elevation of the extracellular K⁺-concentration and did not demonstrate a measurable Cl^– conductance. A large-conductance K⁺ channel (174 pS, n=5, cell-attached, 145 mmol/l K⁺ in the pipette; 140 pS, n=12, cell-free, 3.6 mmol/l K⁺ in the bath) was seen. It had a very low activity on the cell, but a high open probability when excised into a solution with 1 mmol/l Ca²⁺ on the cytosolic side. More often a small-conductance K⁺ channel (36–52 pS, n=19, cell-attached; 30 pS, n=5, cell-free) with a high open probability was found on the cell. These freshly isolated cells seem to be a powerful preparation to study the properties and regulation of ion conductances of rat CCD with several electrophysiological methods. These freshly isolated CCD cells maintain the conductance properties known from principal cells of the intact CCD.     

The effect of secretagogues on ion conductances of in vitro perfused,isolated rabbit colonic crypts

Several secretagogues were used in this study, including those which enhance intracellular cyclic adenosine monophosphate (cAMP) production, as well as others which elevate intracellular Ca²⁺ activity and are known to increase Cl^– secretion in the intact colon and in colonic carcinoma cell lines. They were examined with respect to their effects on electrophysiological properties in isolated rabbit distal colonic crypts. Crypts were dissected manually and perfused in vitro. Transepithelial voltage (V _te), transepithelial resistance (R _te), membrane voltage across the basolateral membrane (V _bl), and fractional basolateral membrane resistance (FR _bl), were estimated. Basolateral prostaglandin E₂ (PGE₂, 0.1 mol/l), vasoactive intestinal peptide (VIP, 1 nmol/l) and adenosine (0.1 mmol/l) induced an initial depolarisation and a secondary partial repolarisation of (V _bl). In the case of adenosine, the initial depolarization of (V _bl) was by 31±2 mV (n=47).R _te fell significantly from 16.4±3.6 to 14.2±3.7 ·cm² (n= 6), andFR _blincreased significantly from 0.11±0.02 to 0.51±0.10 (n=6). In the second phase the repolarisation of (V _bl) amounted 11±2 mV (n=47) and a steadystate (V _bl) of –51±2 mV (n=47) was reached.R _te fell further and significantly to a steady-state value of 12.4±3.8 ·cm² (n=6) andFR _bl fell significantly to 0.42±0.13 (n=6). In 30% of the experiments, a transient hyperpolarisation of (V _bl) by 8±2 mV (n=14) was seen during wash out of adenosine. In the presence of adenosine, but not under control conditions, lowering of luminal Cl^– concentration from 120 to 32 mmol/l depolarised (V _bl) significantly by 8±1 mV (n=9). Basolateral ATP and ADP (0.1 mmol/l) led to a short initial depolarisation followed by a sustained and significant hyperpolarisation by 6±2 mV (n=27) and 5±4 mV (n=8), respectively. Carbachol (CCH) hyperpolarised (V _bl) in a concentration-dependent manner. At 100 mol/l (bath) the hyperpolarisation was by 14±2 mV (n=11) andFR _bl fell slightly. Neurotensin (10 nmol/l), isoproterenol (10 mol/l) and uridine 5-triphosphate (UTP, 0.1 mmol/l) had no effect. It is concluded that PGE₂, VIP and adenosine upregulate sequentially a luminal Cl^– conductance and a basolateral K⁺ conductance by increasing intracellular cAMP concentration. Ca²⁺ mobilising hormones such as ATP, ADP, and CCH increase the basolateral K⁺ conductance, while the effect on luminal Cl^– conductance appears to be very limited.     

Electrophysiology of cell volume regulation in proximal tubules of the mouse kidney

The present study has been designed to test for the influence of cell swelling on the potential difference and conductive properties of the basolateral cell membrane in isolated perfused proximal tubules. During control conditions the potential difference across the basolateral cell membrane (PD_bl) is –65±1 mV (n=74). Decrease of peritubular osmolarity by 80 mosmol/l depolarizes the basolateral cell membrane by +7.8±0.5 mV (n=42). An increase of bath potassium concentration from 5 to 20 mmol/l depolarizes the basolateral cell membrane by +25±1 mV (n=11), an increase of bath bicarbonate concentration from 20 to 60 mmol/l hyperpolarizes the basolateral cell membrane by –3.2±0.5 mV (n=13). A decrease of bath chloride concentration from 79.6 to 27 mmol/l hyperpolarizes the basolateral cell membrane by –1.8±0.7 mV (n=6). During reduced bath osmolarity, the influence of altered bath potassium concentration on PD_bl is decreased ( PD_bl=+16±2 mV,n=11), the influence of altered bicarbonate concentration on PDbl is increased ( PD_bl=–6.0±0.8 mV,n=13), and the influence of altered bath chloride concentration on PD_bl is unaffected ( PD_bl=–1.8±0.6 mV,n=6). Barium depolarizes the basolateral cell membrane to –28±2 mV (n=16). In the presence of 1 mmol/l barium, decrease of peritubular osmolarity by 80 mosmol/l leads to a transient hyperpolarization of the basolateral cell membrane by –5.9±0.5 mV (n=16). This transient hyperpolarization is blunted in the absence of extracellular bicarbonate. In conclusion, cell swelling depolarizes straight proximal tubule cells and increases bicarbonate selectivity of the basolateral cell membrane at the expense of potassium selectivity. The data reflect either incrases of bicarbonate conductance or decrease of potassium conductance during exposure of proximal tubule cells to hypotonic media.Parts of this work were presented at the 18th Congress of the Gesellschaft für Nephrologie, Frankfurt/M. 1986 and at the 8th International Symposium on Biochemical Aspects of Kidney Function, Dubrovnik 1986     

Endothelin-1 blunts transepithelial transport and differentiation of Madin-Darby canine kidney cells

We investigated the effects of endothelin-1 (ET-1) on Madin-Darby canine kidney (MDCK) cells, a cell line originating from the renal collecting duct. The activity of transepithelial transport was assessed as the rate of dome formation in monolayers grown on solid support. The pH value of the dome fluid (dome pH) was measured by means of pH-selective microelectrodes. Differentiation of monolayer cells was estimated as the peanut-lectin(PNA)-binding capacity of the apical membrane. Confluent monolayers were incubated for 12–72 h in serum-free medium at various concentrations of ET-1. Exposure to 1 nmol/l ET-1 reduced dome formation by a maximum of 41±8% (n=4; P<0.02) after 24 h. ET-1 (10 nmol/l; 24 h) decreased dome pH from 7.52±0.02 (n=53) to 7.36±0.03 (n=51; P<0.02). Apical application of amiloride (1 mmol/l) reduced dome pH in both ET-1-treated and non-treated domes to essentially the same level, 7.25±0.03 (n=19) and 7.23±0.03 (n=17) respectively. ET-1 (10 nmol/l; 24 h) reduced PNA-binding capacity by 19±3% (n=5; P < 0.02). Moreover, ET-1 prevented the increase in PNA binding (+53±7%; n=5) induced by 0.1 mol/l aldosterone. We conclude that ET-1 inhibits transepithelial transport and PNA binding via inhibition of apical Na⁺/H⁺ exchange, thus antagonizing aldosterone action in MDCK cells.     

The ion conductances of colonic crypts from dexamethasone-treated rats

Whole-cell patch-clamp studies were performed in isolated colonic crypts of rats pretreated with dexamethasone (6 mg/kg subcutaneously on 3 days consecutively prior to the experiment). The cells were divided into three categories according to their position along the crypt axis: surface cells (s.c.); mid-crypt cells (m.c.) and crypt base cells (b.c.). The zero-current membrane voltage (V _m) was –56 ± 2 mV in s.c (n = 34); –76 ± 2 mV in M.C. (n = 47); and –87 ± 1 mV in b.c. (n = 87). The whole-cell conductance (G _m) was similar (8–12 nS) in all three types of cells. A fractional K⁺ conductance accounting for 29–67% ofG _m was present in all cell types. A Na⁺conductance was demonstrable in s.c. by the hyperpolarizing effect onV _m of a low-Na⁺ (5 mmol/1) solution. In m.c. and b.c. the hyperpolarizing effect was much smaller, albeit significant. Amiloride had a concentration-dependent hyperpolarizing effect onV _m in m.c. and even more so in s.c.. It reducedG _m by approximately 12%. The dissociation constant (K _D) was around 0.2 mol/l. Triamterene had a comparable but not additive effect (K _D = 30 mol/l,n = 14). Forskolin (10 mol/l, in order to enhance cytosolic adenosine 3, 5-cyclic monophosphate or CAMP) depolarizedV _m in all three types of cells. The strongest effect was seen in b. c..G _m was enhanced significantly in b.c. by 83% (forskolin) to 121% [8-(4-chlorophenylthio)cAMP]. The depolarization ofV _m and increase inG _m was caused to large extent by an increase in Cl^– conductance as shown by the effect of a reduction in bath Cl^– concentration from 145 to 32 mmol/1. This manocuvre hyperpolarizedV _m under control conditions significantly by 6–9 mV in all three types of cells, whilst it depolarizedV _m in the presence of forskolin in m.c. and in b.c.. These data indicate that s.c. of dexamethasone-treated rats possess mostly a K⁺ conductance and an amiloride- and Tramterene-inhibitable Na⁺ conductance. m.c. and b.c. possess little or no Na⁺ conductance; theirV _m is largely determined by a K⁺ conductance. Forskolin (via cAMP) augments the Cl^– conductance of m.c. and b.c. but has only a slight effect on s.c.     

Effects of urea on K+ fluxes and cell volume in perfused rat liver

Exposure of the perfused rat liver to a perfusate made hyperosmotic by the presence of 200 mmol l^–1glucose led, as expected, to marked, transient hepatocellular shrinkage followed by volume-regulatory net K⁺ uptake. However, even after this volume-regulatory K⁺ uptake had ceased, the liver cells are still slightly shrunken. Withdrawal of glucose from the perfusate resulted in marked transient cell swelling, net K⁺ release from the liver and restoration of cell volume. However, when the Krebs-Henseleit perfusate was made hyperosmotic by the presence of urea (20–300 mM), there was no immediate decrease in liver mass, yet a slight and persistent cell shrinkage developing 2 min after the onset of exposure to urea. Surprisingly, urea induced concentration-dependent net K⁺ efflux from the liver and removal of urea net K⁺ reuptake from the inflowing perfusate. The urea (200 mM)-induced net K⁺ release resembled that observed following a lowering of the influent [NaCl]: making the perfusate hypoosmotic (245 mosmol l^–1, by reducing influent [NaCl] by 30 mM) gave roughly the same K⁺ response as hyperosmotic exposure (505 mosmol/l) resulting from the presence of 200 mM urea. The urea-induced K⁺ efflux was not inhibited in the presence of ouabain (1 mM), or in Ca⁺⁺-free perfusion, but was modified in the presence of quinidine (1 mM) or Ba⁺⁺ (1 mM). The direction in which the liver was perfused had no effect on the urea-induced net K⁺ release. Electrophysiological studies showed that urea led to quinidine-sensitive hyperpolarization and increase in K⁺ selectivity of plasma membranes, suggesting opening of K⁺ channels in the hepatocyte plasma membrane in response to urea. The data suggest that urea, but not glucose, enters the hepatocyte as quickly as water. Furthermore, urea at high concentrations apparently leads to K⁺ efflux from the hepatocyte and cell shrinkage, possibly due to opening of K⁺ channels in the hepatocyte plasma membrane.     

Properties of the potassium conductances of principal cells of rat cortical collecting ducts

In this study we examined by impalement techniques properties of the macroscopic K⁺ conductances in the luminal and basolateral membrane of principal cells from isolated perfused cortical collecting ducts (CCD) of the rat. Both membranes possess a dominating K⁺ conductance. Compared to their behaviour with K⁺, both membranes appear much less permeable to NH ₄ ⁺ and Rb⁺, and the K⁺ conductances of both membranes are inhibited by these cations. In light of these findings, it is very unlikely that significant amounts of NH ₄ ⁺ , which is secreted in the CCD, cross the principal cells as NH ₄ ⁺ . Several inhibitors with known effects on K⁺ channels in patch-clamp studies have been examined. Tetraethylammonium, which inhibits the excised K⁺ channels of these cells, has no effect on the macroscopic K⁺ conductances of either membrane. Verapamil, which inhibits the K⁺ channels in the luminal membrane, acts predominantly on the basolateral membrane K⁺ conductance in the intact tubule. Therefore, some of the macroscopic properties of the K⁺ conductances are distinct from those of single channels thus far observed in patchclamp studies.Supported by DFG Schl 277/2-1 and Gr 480/10     

Determination of intracellular K+ activity in rat kidney proximal tubular cells

The intracellular K⁺ activity of rat kidney proximal tubular cells was determined in vivo, using intracellular microelectrodes. In order to minimize damage from the impaling electrodes, separate measurements on separate cells, were performed with single-barrelled KCl-filled non-selective electrodes and single-barrelled, K⁺-sensitive microelectrodes, which were filled with a liquid K⁺-exchanger resin that has also a small sensitivity to Na⁺. Both electrodes had tip diameters of 0.2 m or below. The proper intracellular localization of the electrodes was ascertained by recording the cell potential response to intermittent luminal perfusions with glucose. The membrane potential measured with the non-selective microelectrodes was –76.3±8.1 mV (n=81) and the potential difference measured with the K⁺-sensitive microelectrode was –7.2±5.8 mV (n=32). Based on the activity of K⁺ in the extracellular fluid of 3 mmol/l the intracellular K⁺ activity was estimated to be 82 mmol/l. Assuming equal K⁺-activity coefficients to prevail inside and outside the cell, this figure suggests that the intracellular K⁺ concentration is 113 mmol/l which must be considered as a lower estimate, however. The data indicate that the K⁺-ion distribution between cytoplasm and extracellular fluid is not in equilibrium with the membrane potential, but that K⁺ is actively accumulated inside the cell. This result provides direct evidence for the presence of an active K⁺ pump in the tubular cell membranes, which in view of other observations, must be envisaged as a (not necessarily electroneutral) Na⁺/K⁺-exchange pump which operates in the peritubular cell membrane and is eventually responsible for the major part of the tubular solute and water absorption.