The relative body fat and anthropometric prediction of body density of South Australian females aged 17—35 years

Summary One hundred and thirty-five females were tested in order to: produce some normative percentage body fat (% BF) data on an Australian sample which represented a cross-section of physical activity patterns, cross-validate existing multiple regression equations which predict body density (BD) from anthropometric measurements, and if necessary develop population specific equations.Measurements were taken of 10 girths, 3 widths and 7 skinfolds. Body density was measured by underwater weighing with the residual volume (RV) being determined by helium dilution. The Siri equation was then used to convert BD to % BF. The % BF scores had an overall mean of 23.4 (range 10.8–49.2). The very active group (n=45) had a significantly lower (p<0.05) relative body fat (X=20.6% BF) than either the active (n=45; 23.5% BF) or sedentary groups (n=45; 26.2% BF). Previously published equations were found to have limited applicability to Australian subjects. A stepwise multiple regression was therefore used to develop the following equation (R = 0.893): BD(g·cm^–3) = 1.16957-0.06447 (log₁₀ triceps, subscapular, supraspinale, front thigh, abdominal and calf skinfolds in mm)-0.00081 (gluteal girth in cm)+ 0.0017 (forearm girth in cm) + 0.00606 (biepicondylar humerus breadth in cm). Only those predictors which resulted in a statistically significant increase inr (p0.05) were included. The standard error of estimate of 0.00568 g · cm^–3 was equivalent to 2.6% BF at the mean.This study was supported by a grant from the Menzies Foundation     

Assessment of exercise-induced alterations in body composition of patients with coronary heart disease

Summary The porpose of this study was to determine the effects of exercise habituation on body composition and anthropometric characteristics in cardiac patients. The subjects, comprising 20 patients with coronary heart disease, aged 43–69, participated in our supervised exercise programme for 38.0 (SD 12.5) weeks while in hospital. The intensity of most exercise was set at the lactate threshold. Analyses of the data indicated that small but significant reductions were observed in body mass (m _b) [–1.4 (SD 1.8) kg], abdominal girth [–1.4 (SD 2.6) cm], chest girth [–1.3 (SD 1.8) cm], body mass index [–0.6 (SD 0.7)], and skinfold thicknesses at all the sites measured. As expected, fat-free mass, derived from either bio-electrical impedance (BI) or a skinfold technique with commonly used regression equations, remained essentially unchanged, while there were significant decreases in body fat (BF) and %BF. The absolute amount of change in m _b (i.e. m _b) was significantly associated with abdominal girth (r=0.506), BF estimated by the BI technique (r=0.476), and BF estimated by the skinfold technique (r=0.451). Although the period of the exercise programme [38.0 (SD 12.5) weeks] varied greatly among subjects, it was found not to be associated with m _b and alterations in body composition. We concluded that aerobic exercise induced significant decreases in BF and many anthropometric variables, independent of the duration of exercise, and that a combination of abdominal girth, BI and/or skinfold measurements would be advantageous in estimating primarily exercise-induced alterations in BF in cardiac patients.Data were collected at the Cardiac Rehabilitation Laboratory, Higashi Toride Hospital     

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     

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.     

Chloride and potassium conductances of cultured human sweat ducts

The purpose of this study was to characterize the ion conductances, in particular those for Cl^– and K⁺, of human sweat duct cells grown in primary culture. Sweat duct cells from healthy individuals were grown to confluence on a dialysis membrane, which was then mounted in a mini-Ussing chamber and transepithelial and intracellular potentials were measured under open-circuit conditions. Under control conditions the epithelia developed mucosa-negative transepithelial potentials, V _te, of about –10mV. The apical membrane potential, V _a, was –25 mV to –30 mV (n=97) in most cells, but several cells had a higher potential of about –55 mV (n=29). Mucosal amiloride (10 mol/l) hyperpolarized V _a from –31±1 mV to a new sustained level of –46±2 mV (n=36). These changes were accompanied by increase in the fractional resistance of the apical membrane, fR _a, and decreases of V _te and the equivalent short-circuit current, I _sc. In amiloride-treated tissues an increase in mucosal K⁺ concentration (5 mmol/l to 25 mmol/l) depolarized V _a by 5±1 mV (n=8), while the same step on the serosal side depolarized V _a by 20±2 mV (n=8). A Cl^– channel blocker 3,5-dichloro-diphenylamine-2-carboxylate DCl-DPC; 10 mol/l) depolarized V _a by 5±1 mV (n=6), an effect that was lost after amiloride application. The blocker had no effect from the serosal side. Reduction of mucosal Cl^– (from 120 to 30 or 10 mmol/l) depolarized V _a by 9–11 mV (n=35), an effect that was often followed by a secondary hyperpolarization of 10–30 mV (n=27). Isoproterenol (5 mol/l) increased the V _a responses to low Cl^– such that the depolarizing response was increased from 10±1 mV to 19±2 mV (n=8); the hyperpolarizing response seemed to be reduced. With changes in Cl^– concentration on the serosal side, V _a remained relatively constant at –25 mV, while V _te decreased from –8 mV to–3 mV; hence, V _bl depolarized by about 5 mV. Taken together, our results show that the human sweat duct epithelium possesses Na⁺, K⁺ and Cl^– conductances on the luminal membrane and Cl^– and K⁺ conductances on the basolateral membrane. The Cl^– conductances on the luminal membrane is sensitive to DCl-DPC, and can be activated by isoproterenol. The small K⁺ conductance on the luminal membrane could account for some K⁺ secretion in sweat glands.     

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]     

CAMP-dependent activation of ion conductances in bronchial epithelial cells

The cAMP-dependent activation of Cl^– channels was studied in a bronchial epithelial cell line (16HBE14o-) in fast and slow whole-cell, and cell-attached patch-clamp experiments. The cells are known to express high levels of cystic fibrosis transmembrane conductance regulator mRNA and protein. Isoproterenol, forskolin and histamine (all 10 mol/l) reversibly and significantly depolarized the membrane voltage (V _m) and increased the whole-cell Cl^– conductance significantly by 34.0±0.9 (n=3), 18.1±2.7 (n=50), and 25±4.5 (n=37) nS respectively. The effect of histamine was blocked by cimetidine (10 mol, n=5) but not by diphenhydramine (10 mol/l, n=4), which suggests binding of histamine to H₂ receptors. The forskolin-induced current was not inhibited significantly by 4,4-diisothiocyanatostilbene-2,2-disulphonic acid (0.5 mmol/l, n=9) nor glibenclamide (10 mol/l, n=3) and had an anion-permeability sequence of Cl^–= Br^–>I^– (n=9). In cell-attached recordings forskolin (10 mol/l) increased the conductance of the patched membrane from 65.5±13.6 pS to 150.8±33.2 pS (n=30). Although the conductance was increased significantly, clear ion-channel events occurring in parallel with the current activation were not detected in the cell attached membrane. In 4 out of 30 cell-attached recordings single-channel currents were observed. These channels, with a single-channel conductance of about 6 pS, were already active before forskolin was added. No effect of forskolin on the channel amplitude, open probability or kinetics of these channels was observed. From these data we conclude that the cAMP-induced conductance increase in 16HBE14o-cells can be correlated with the activation of very small and not resolvable (probably less than 2 pS) Cl^– channels rather than with the activation of channels with a conductance of 6–10 pS.     

Electrical properties of cultured renal tubular cells (OK) grown in confluent monolayers

OK cells grown to confluent monolayers were investigated by microelectrode techniques and microinjection. Cell membrane potential difference (PD_m) in bi-carbonate-free solution is –61.8±0.6 mV (n=208), cell membrane resistance (R_m) amounts to 1.4±0.2k · cm² (n=8). The apparent transference number for potassium (t_K ⁺) is 71±3% (n=28) and can be reduced by 3 mmol/l BaCl₂ to 7.5±4.0%; (n=8). In the presence of extracellular CO₂ and HCO ₃ ^– (pH 7.4) the cells acidify by 0.34±0.05 pH units (n=12). This leads to a depolarization of PD_m by 8.4±1.8 mV (n=8), an increase in R_m by 49±10% (n= 10), and a reduction of K⁺-conductance to 63±5% (n= 13). Intracellular acidification by the NH₄Cl-prepulse technique also inhibits K⁺-conductance and depolarizes the membrane. Recovery from an intracellular acid load is reflected by cell membrane repolarization. This recovery can be inhibited by amiloride (10^–3 mol/l). Na⁺- and Cl^–-conductances could not be detected.The transepithelial resistance (R _te) of OK cell monolayers 1 day after plating is 41±6 ·cm² and decreases with time after plating. Intercellular communication (electrical or dye coupling) was not observed.Conclusions: 1. The membrane potential of OK cells is largely determined by a pH-sensitive, barium-blockable K⁺-conductance. 2. Amiloride-blockable Na⁺/H⁺-exchange is reflected by membrane potential changes via this K⁺-conductance. 3. Monolayers of OK cells are electrically leaky.Parts of this study were presented at the 66th meeting of the Deutsche Physiologische Gesellschaft, Würzburg, September 1988 [Pflügers Arch 412 (Suppl 1):R55].     

A calcium-activated nonselective cationic channel in the basolateral membrane of outer hair cells of the guinea-pig cochlea

The patch-clamp technique was used to investigate ion channels in the basolateral perilymph-facing membrane of freshly isolated outer hair cells (OHCs) from the guinea-pig cochlea. These sensory cells probably determine, via their motile activity, the fine tuning of sound frequencies and the high sensitivity of the inner ear. A Ca²⁺-activated nonselective cationic channel was found in excised inside-out membrane patches. The current/voltage relationship was linear with a unit conductance of 26.3±0.3 pS (n=15) under symmetrical inger conditions. The channel excluded anions (P _Na/P _Cl=18 whereP _Na/P _Cl denotes the relative permeability of Na to Cl); it was equally permeant to the Na⁺ and K⁺ ions and exhibited a low permeability toN-methyl-D-glucamine and Ba²⁺ or Ca²⁺. Channel opening required a free Ca²⁺ concentration of about 10^–6 mol/l on the internal side of the membrane and the open probability (P _o) was maximal at 10^–3 mol/l (P _o=0.72±0.06,n=12). Adenosine 5mono-, tri- and di-phosphate reducedP _o to 29±14 (n=5), 42±10 (n=8) and 51±12 (n=5) % of controlP _o, respectively, when they were added at a concentration of 10^–3 mol/l to the internal side. The channel was partially blocked by flufenamic acid (10^–4 mol/l) and 3,5-dichlorodiphenylamine-2-carboxylic acid (DCDPC, 10^–5 mol/l). This type of channel, together with Ca²⁺-activated K⁺ channels, might participate in the control of membrane potential and modulate the motility of OHCs.     

A new class of inhibitors of cAMP-mediated Cl− secretion in rabbit colon,acting by the reduction of cAMP-activated K+ conductance

Previously we have shown that arylamino-benzoates like 5-nitro-2-(3-phenylpropylamino)-benzoate (NPPB), which are very potent inhibitors of NaCl absorption in the thick ascending limb of the loop of Henle, are only poor inhibitors of the cAMP-mediated secretion of NaCl in rat colon. This has prompted our search for more potent inhibitors of NaCl secretion in the latter system. The chromanole compound 293 B inhibited the equivalent short-circuit current (I _sc) induced by prostaglandin E₂ (n=7), vasoactive intestinal polypeptide (VIP,n=5), adenosine (n=3), cholera toxin (n=4) and cAMP (n=6), but not by ionomycin (n=5) in distal rabbit colon half maximally (IC₅₀) at 2 mol/l from the mucosal and at 0.7 mol/l from the serosal side. The inhibition was reversible and paralleled by a significant increase in transepithelial membrane resistance [e.g. in the VIP series from 116±16 ·cm² to 136±21 ·cm² (n=5)]. A total of 25 derivatives of 293 B were examined and structure activity relations were obtained. It was shown that the racemate 293 B was the most potent compound with-in this group and that its effect was due to the enantiomer 434 B which acted half maximally at 0.25 mol/l. Further studies in isolated in vitro perfused colonic crypts revealed that 10 mol/l 293 B had no effect on the membrane voltage across the basolateral membrane (V _bl) in non-stimulated crypt cells: –69±3 mV versus –67±3 mV (n=10), whilst in the same cells 1 mmol/l Ba²⁺ depolarised (V _bl) significantly. However, 293 B depolarised (V _bl) significantly in the presence of 1 mol/l forskolin: –45±4mV versus –39±5 mV (n=7). Similar results were obtained with 0.1 mmol/l adenosine. 293 B depolarised (V _bl) from –40±5 mV to –30±4 mV (n=19). This was paralleled by an increase in the fractional resistance of the basolateral membrane. VIP had a comparable effect. The hyperpolarisation induced by 0.1 mmol ATP was not influenced by 10 mol/l 293 B: –75±6 mV versus –75±6 mV (n=6). Also 293 B had no effect on basal K⁺ conductance (n=4). Hence, we conclude that 293 B inhibits the K⁺ conductance induced by cAMP. This conductance is apparently relevant for Cl^– secretion and the basal K⁺ conductance is insufficient to support secretion.     

Taurocholate depolarizes rat hepatocytes in primary culture by increasing cell membrane Na+ conductance

Rat hepatocytes in primary culture were impaled with conventional microelectrodes. Addition of 5–100 mol/l taurocholate led to a slowly developing depolarization that was maximal at 50 mol/l (10.5±1.5 mV, n=15) and not reversible. The effect was Na⁺ dependent and decreased in cells preincubated with 1 mol/l taurocholate. Increasing external K⁺ tenfold depolarized the cells by 12.3±2.3 mV under control conditions and by 6.3±1.2 mV with 50 mol/l taurocholate present (n=7). Depolarization by 1 mmol/l Ba²⁺ was 7.6±0.8 mV and 6.0±0.7 mV (n=9) before and after addition of taurocholate, respectively. Cable analysis and Na⁺ substitution experiments reveal that this apparent decrease in K⁺ conductance reflects an actual increase in Na⁺ conductance: in the presence of taurocholate, specific cell membrane resistance decreased from 2.8 to 2.3 k · cm² · Na⁺ substitution by 95% depolarized cell membranes by 8.9±2.9 mV (n=9), probably due to indirect effects on K⁺ conductance via changes in cell pH. With taurocholate present, the same manoeuvre changed membrane voltages by –0.8±2.6 mV. When Na⁺ concentration was restored to 100% from solutions containing 5% Na⁺, cells hyperpolarized by 3.5±3.6 mV (n=7) under control conditions and depolarized by 4.4±2.9 mV in the presence of taurocholate, respectively. In Cl^– substitution experiments, there was no evidence for changes in Cl^– conductance by taurocholate. These results show that taurocholate-induced membrane depolarization is due to an increase in Na⁺ conductance probably via uptake of the bile acid.     

The effects of pressure on the water permeability of the descending limb of Henle's loops of rabbits

Descending limbs of Henle's loops from rabbits were perfused in vitro. Using techniques where the collecting pipets permitted cannulation of the tubule, we were able to maintain reasonable flow rates at lower perfusion reservoir heights than are required with a conventional Sylgard seal pipet. The bath was either isosmotic to the perfusate, or was made 300 mOsm hyperosmotic using urea. Net water reabsorption did not occur in tubules perfused at low pressure (average reservoir height = 26 cm H₂O) even when the bath was hyperosmotic: J _v =–0.06 ±0.18 nl/min (n=7). Observed increases in sodium concentration and osmolality of collected fluid, when the bath was made hyperosmotic, were 16±8 mM (n=7) and 254±38 mOsm (n=7), respectively. Presumably the large increase in osmolality of the collected fluid was due to entrance of urea.When the Sylgard seal collecting end was utilized higher perfusion reservoir heights had to be used to maintain flow (mean height 66 cm H₂O). These tubules were highly permeable to water as reported by others for this tubule segment. In the presence of a hyperosmotic bath water extrusion resulted in a dramatic increase in the osmolality of the collected fluid (312 ±5 mOsm; 7 tubules) which was almost completely accounted for by an increase in sodium concentration (153±8 mmole/l; 6 tubules).The¹⁴C urea permeability (measured lumen to bath) of descending limbs in a 300 mOsm bath was 0.64 ×10^–7 cm²·s^–1±0.23×10^–7 (11 tubules). When the bath was made hyperosmotic using urea or raffinose the¹⁴C urea permeability increased significantly.     

Evidence for Na+/Ca2+ exchange in isolated smooth muscle cells: a fura-2 study

Isolated smooth muscle cells (SMC) from guinea pig taenia coli were employed. Suspension of cells were externally loaded in saline with the fluorescent calcium indicators quin-2/AM or fura-2/AM at 20–40 M or 4 M respectively, resulting in an estimated intracellular concentration of 100–200 M for quin-2 or 10–20 M fura-2 (free acid). On addition of 100 M carbachol or high K _o ⁺ (80 mM) depolarization, fura-2 loaded cells contracted (104±47 m,n=121 rest: 39±13 m,n=59 contracted) identically to control (103±35 m,n=232 rest: 39±16 m,n=89 contracted) cells, whereas quin-2 loaded cells were unresponsive to these protocols and there was no significant length change. The Ca _i ²⁺ of fura-2 loaded cells was 100±18 nM (mean±SD,n=15) and was not significantly different from quin-2 loaded cells 107±26 nM (n=13). Treatment of fura-2 loaded cells with 100 M ouabain saline for 10–60 min progressively elevated the Ca _i ²⁺ to a mean of 266±83 nM (n=15). Reduction of Na _p ⁺ (96% Li⁺ replaced) significantly increased Ca _i ²⁺ to 317±77 nM (n=8). After pretreatment with ouabain (100 M), Na _o ⁺ replacement (Li⁺) increased Ca _i ²⁺ at a significantly faster rate [3.6 nM min^–1 (control) cf. 19.8 nM min^–1 (ouabain)].     

Inhibition of epithelial chloride channels by cytosol

Chloride channels that have an intermediate conductance and are outwardly rectifying were studied by the patch-clamp technique in cell-excised membrane patches from respiratory epithelial cells in primary culture (REC) of normal and cystic fibrosis tissue, HT₂₉ and T₈₄ human colon carcinoma cells and placenta trophoblast cells (PTC). Chloride channels were immediately activated by the exposure of the cytosolic side of the patch to a Ringer-type solution, which lacked cytosolic components normally inhibiting chloride channels in the on cell configuration. Tentatively, we labelled the cytosolic component (or components) responsible for this inhibition cytosolic inhibitor (CI). The presence of CI in cytosol derived from HT₂₉ cells was shown by assaying crude cytosol extracts from these cells on Cl^– channels from HT₂₉ cells (n=2) and REC from normal subjects and cystic fibrosis patients (n=4). In order to examine CI further, PTC were used as a source of cytosol. The cytosol of PTC inhibited HT₂₉ Cl^– channels in a dosedependent manner with a half-maximal inhibition observed at a 16 dilution (n=11) of the native cytosol. CI from PTC was heat-stable (10 min at 100°C, n=8). When cytosol extract was partitioned into a chloroform phase, Cl^– channel inhibition was shown for the lipophilic extract (n=12) as well as for the aqueous phase (n=10). The inhibitory potency of the lipid extract was slightly larger than that of the aqueous phase. Several separation procedures were used to determine the molecular size of CI. When CI was filtered through 30-kDa filters at 6000 rpm for 45 min, inhibitory potency was observed in the filtrate and the retained fraction (n=3). The same was observed with 10-kDa filters (n=6). When CI was dialysed through a 12-kDa membrane, inhibitory capacity was recovered from the dialysate. Similarly, gel filtration indicated that CI was <5kDa (n=13) and probably <1.5 kDa (n=11), but >700 kDa (n=9). CI was exposed to bead-coupled hydrolysing enzymes (trypsin, non-specific protease, lipase, -amylase, nucleotidase), but none of the enzymes used destroyed the inhibitory potency of CI. These data indicate that CI is present in HT₂₉ as well as in PTC. It inhibits reversibly intermediate-conductance outwardly rectifying Cl^– channels in REC, HT₂₉, and PTC. CI is heat-stable and amphiphilic and has an apparent molecular mass of 0.7–1.5 kDa. Given this nature of CI, several putative ion-channel regulators were examined on Cl^– channels of HT₂₉ cells. It was found that inositol triphosphate, GTP, GTP [-S], ATP, cAMP, cGMP and dioleoylglycerol all had no effect from the cytosolic side. Non-saturated fatty acids (n=23) inhibited the open probability of these Cl^– channels from the cytosolic side after some delay reversibly at concentrations of 5 mol/l for arachidonic acid and more than 1 mmol/l for linoleic acid. Saturated fatty acids had no effect. The present data indicate that this type of Cl^– channel may be inhibited by some cytosolic inhibitor with the above properties. Excision of membrane patches containing this channel leads to instantaneous disinhibition (=excision activation). It is possible that an increased concentration of CI or an increased sensitivity to CI may be responsible for the tonic inhibition of Cl^– channels observed in cystic fibrosis REC.Preliminary accounts of this report have been given at the cystic fibrosis conferences in Sestri Levante (March 1990) and in Arlington (October 1990)     

Small-conductance chloride channels induced by cAMP,Ca2+, and hypotonicity in HT29 cells: ion selectivity,additivity and stilbene sensitivity

Previous studies in HT₂₉ cells utilizing the cellattached nystatin (CAN) method [Greger R, Kunzelmann K (1991) Pflügers Arch 419:209–211] have revealed that the Cl^– channels induced by cAMP or by increasing cytosolic Ca²⁺, e.g. by addition of ATP, and by hypotonic cell swelling share in common their conductance, which was so small in our studies [Kunzelmann et al. (1992) Pflügers Arch (in press)] that we could not resolve it at the single-channel level. This prompted the question whether these Cl^– conductances can be distinguished in terms of their ion selectivity and sensitivity towards inhibitors. Whether these pathways are additive or not was also examined. The present study utilized the whole-cell patch-clamp and the CAN methods. A total of 160 patches were studied. In whole-cell patches 8-(4-chlorophenylthio)-cAMP (cAMP, 0.1±1 mmol/l) induced a significant depolarization by 5 mV and a twofold increase in conductance (G) from 6.2±1.5 nS to 11.7±3.2 nS (n=15). Total replacement of Cl^– by Br^– and I^– in cAMP-treated cells hyperpolarized the membrane voltage (V) significantly from –35±2.8 to –39±3.4 and –45± 3.3 mV respectively, but had no detectable effect on G, which was 11.9±3.3 nS in the case of Br^– and 11.8± 3.3 nS in the case of I^–. Hence, the permselectivity of the cAMP pathway was I^–>Br^–>Cl^–, but the conductances for these anions were all indistinguishable. For ATP at 10–100 mol/l the depolarization was least with I^–: from –41±1.1 to –36±2.4mV, intermediate for Br^– to –25±1.6 mV, and largest for Cl^– to –20±1.8 mV (n=18). ATP increased G from 3.4±0.3 nS to 12.9±2.8 nS (Cl^–), to 12.9±2.8 nS (Br^–) and to 12.9±2.7 (I^–) (n=18). These data indicate that the ATP-induced anion channel has a permeability sequence of I^–>Br^–>Cl^–. The conductance for all three anions was identical. Hypotonic cell swelling by 160 mosmol/l induced a depolarization that was smallest for I^–, from –42±4 to –32±2.1 mV, intermediate for Br^–: –29±1.8mV, and similar for Cl^–: –28±2 mV (n=20). G was increased from 2.8±0.8 nS to 15±2.5nS in the case of Cl^–, to 15±2.5 nS for Br^– and to 16±2.6 nS for I^– (n=20). Therefore, all three pathways are indistinguishable with respect to their anion selectivity. All three pathways are insensitive towards low concentrations of 4-nitro-2-(3-phenylpropylamino)benzoate, but are all blocked by 4,4-diisothiocyanatostilbene-2,2-disulphonic acid, with a half-maximal inhibition around 0.6 mmol/l. Finally, the possible additivity was examined in three permutations. ATP (0.1 mmol/l) alone (n=14) had a slightly but not significantly larger effect on conductance than the combination of ATP and cAMP (1 mmol/l, n=14) and the combination of ATP and hypotonicity (193 mosmol/l, n=13). Similarly, the effects of hypotonicity and cAMP (n=11) were not additive. These data indicate that all three pathways share common properties. Hence, it is suggested that all three pathways converge on the same small Cl^– channel.Supported by DFG Gr 480/10 and BMFT 01 GA 8816     

cAMP increases the basolateral Cl−-conductance in the isolated perfused medullary thick ascending limb of Henle's loop of the mouse

The effect of cAMP on transepithelial and transmembrane potential differences and resistances was examined in isolated in vitro perfused mouse medullary thick ascending limbs of Henle's loop (mTAL). The effects of furosemide and barium were tested. Stimulation of NaCl transport by ADH 10^–9+dbcAMP 4·10^–4+forskolin 10^–6 mol·l^–1 (paired experiments) resulted in: a) an increase in transepithelial potential difference, referenced to the grounded bath, from +6.7±0.3 mV to +12.0±0.4 mV (n=47); b) a decrease in transepithelial resistance from 25±1 cm² to 20±1 cm² (n=47); c) a depolarization of the basolateral membrane by 12 mV and of the apical membrane by 7 mV (n=36); d) a decrease in the fractional resistance of the basolateral membrane from 0.27±0.005 to 0.15±0.06 (n=12). Furosemide (10^–4 mol·l^–1) abolished the active transepithelial transport potential and hyperpolarized the basolateral membrane potential to values which were similar in both control and cAMP treated mTAL segments. Barium increased the transepithelial resistance and depolarizedPD _bl to similar values in both functional states. An increase in the fractional conductance of the basolateral membrane was also seen, if, prior to the cAMP treatment, the luminal Na⁺2Cl^–K⁺ contransport was inhibited by furosemide. Thus, we propose that stimulation of active NaCl reabsorption in the mTAL segment of the mouse by ADH, mediated via cAMP, increases primarily the basolateral chloride conductance.Supported by Deutsche Forschungsgemeinschaft Gr 480/6-2Parts of this study have been presented at the 59th Meeting of the German Physiological Society in Dortmund 1984 and at the 69th FASEB Meeting in Anaheim 1985     

cAMP-dependent activation of small-conductance Cl− channels in HT29 colon carcinoma cells

The present study was performed to examine the conductance properties in the colon carcinoma cell line HT₂₉ and the activation of Cl^– channels by cAMP. A modified cell-attached nystatin patch-clamp technique was used, allowing for the simultaneous recording of the cell membrane potential (PD) and the conductance properties of the cell-attached membrane. In resting cells, PD was –56±0.4 mV (n=294). Changing the respective ion concentrations in the bath indicate that these cells possess a dominating K⁺ conductance and a smaller Cl^– conductance. A significant non-selective cation conductance, which could not be inhibited by amiloride, was only observed in cells examined early after plating. The K⁺ conductance was reversibly inhibited by 1–5 mmol/l Ba²⁺. Stimulation of the cells by the secretagogues isoproterenol and vasointestinal polypeptide (VIP) depolarized PD and induced a Cl^– conductance. Similar results were obtained with compounds increasing cytosolic cAMP: forskolin, 3-isobutyl-1-methylxanthine, cholera toxin and 8-bromoadenosine cyclic 3,5-monophosphate (8-Br-cAMP). VIP (1 nmol/l, n=10) and isoproterenol (1 umol/l, n=12) depolarized the cells dose-dependently and reversibly by 12±2 mV and 13±2 mV. The maximal depolarization was reached after some 20 s. The depolarization was due to increases in the fractional Cl^– conductance. Simultaneously the conductance of the cellattached membrane increased from 155±31 pS to 253±40 pS (VIP, n=4) and from 170±43 pS to 268±56 pS (isoproterenol, n=11), reflecting the gating of Cl^– channels in the cell-attached membrane. 5-Nitro-2-(3-phenylpropylamino)-benzoate (1 mol/l) was without significant effects in resting and in forskolin-stimulated HT₂₉ cells. The agonist-induced conductance increase of the cell-attached nystatin patches was not paralleled by the appearance of detectable single-channel events in these membranes. These data suggest activation of small, non-resolvable Cl^– channels by cAMP.Supported by DFG Gr 480/10 and BMFT 01 GA 88/6     

Electrophysiological studies in principal cells of rat cortical collecting tubules ADH increases the apical membrane Na+-conductance

The mechanism of ion transport across principal cells of rat cortical collecting tubules (CCT) and its regulation by vasopressin (ADH) has been studied in the isolated perfused tubule. To amplify the response to ADH rats were treated with 5 mg I. M. desoxycorticosterone 4–9 days prior to the experiments. Addition of 2·10^–10 mol·1^–1 ADH increased the transepithelial voltage from –5.1 ±0.7 mV to –16.1±1.4 mV (n=37) and decreased the transepithelial resistance from 51±4 cm² to 39±2 cm² (n=33). Optical and functional differentiation of impalements of principal and intercalated cells was made and only data of principal cells are presented. ADH depolarized the apical membrane from 79±1 mV to 66±2 mV (n=26) and decreased the fractional resistance of the apical membrane from 0.76±0.04 to 0.70±0.04 (n=13). These ADH effects were prevented by 10^–5 or 10^–4 mol·1^–1 luminal amiloride which hyperpolarized the apical membrane when added in the presence or absence of ADH. Apical and basolateral membranes were dominated by large K⁺ conductances and addition of 3 mmol·1^–1 barium to bath or lumen perfusates increased transepithelial resistance almost two-fold, whereas luminal amiloride increased the transepithelial resistance only by 26–35%. Ouabain (0.5 mmol·1^–1, bath) depolarized the basolateral membrane and decreased its K⁺ conductance. These effects were prevented by the simultaneous presence of apical amiloride suggesting that the only route of Na⁺ entry into the principal cells occurred via the amiloride sensitive Na⁺ conductance. We conclude that ADH stimulates Na⁺ reabsorption and K⁺ secretion in the rat CCT primarily by increasing the Na⁺ conductance in the apical cell membrane.Parts of this study have been presented at the 19th ASN meeting in Washington, DC, USA 1986     

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.