The volume-activated chloride current in human endothelial cells depends on intracellular ATP

We have studied the effect of intracellular ATP on volume-activated Cl^–-currents in endothelial cells from human umbilical veins by means of the whole-cell patch clamp technique. The run-down of this current in ruptured patches during repetitive applications of hypotonic solutions (HTS) could be significantly reduced if the cells were internally perfused with a pipette solution that contained 4 mmol/l ATP. This run-down was much less pronounced if currents were recorded using nystatin-perforated patches. The amplitude of the current was drastically reduced and its activation became slower if the cells were superfused with a glucose-free medium with 1 mmol/l KCN. Adding 4 mmol/l ATPS, a poorly hydrolyzable ATP-analogue, to the patch pipette prevented run-down of the current during repetitive activations by HTS, even if the cells were superfused with glucose-free solution with 1 mmol/l KCN. It is concluded that activation of the mechanosensitive Cl^– conductance in human endothelial cells requires the presence of intracellular ATP, but not its hydrolysis.     

Properties of inactivation of calcium channel currents in smooth muscle cells of rabbit portal vein

With 10 mM Ba²⁺ as the charge carrier, inactivation of Ca²⁺ channel currents could be subdivided into at least two exponentials in smooth muscle cells dispersed from the rabbit portal vein by use of the wholecell configuration of the patch-clamp technique: fast and slow inactivation. All characteristics of inactivation were independent of the size of the currents. Step changes in the holding potential unveiled an extremely slow recovery and an onset of inactivation of the order of several minutes. Steady-state inactivation critically depended on the duration of the pre-steps. Inactivation curves obtained under steady-state conditions showed as shift by approximately 25 mV towards negative potentials by comparison with curves obtained using 1-s pre-pulses. This shift greatly reduced the window current. Recovery from inactivation studied with double-pulse protocols could be classified into at least two exponentials. The contribution of the slow recovery was accentuated at negative holding potentials. Recovery from inactivation critically depended on the duration of the conditioning voltage step, and was also dependent on the duration of the pre-step: its voltage dependence disappeared when pre-pulses longer than 2 s were applied. Onset of inactivation was composed of at least two exponentials: the fast component was accelerated at less negative pre-step potentials. We propose that several inactivated states are involved in Ca²⁺ channel inactivation. Transitions between these states are voltage dependent and voltage independent.     

Caffeine induces periodic oscillations of Ca2+-activated K+ current in pulmonary arterial smooth muscle cells

The periodic oscillations of outward currents were studied in smooth muscle cells of the rabbit pulmonary artery. The combined stimuli of superfusion with 1 mM caffeine and depolarization of the membrane potential to 0 mV evoked periodic oscillations of outward currents with fairly uniform amplitudes and intervals. The oscillating outward currents induced by caffeine were dependent on intracellular Ca²⁺ concentration ([Ca²⁺]_i) and had a reversal potential near to the equilibrium potential for K⁺. So the oscillating outward currents are carried by K⁺ through Ca²⁺-dependent K⁺ channels (I _K(Ca)), and may reflect the oscillations of [Ca²⁺]_i. The oscillating outward currents were abolished, or their frequency reduced, by lowering external [Ca²⁺], Ca²⁺ channel blockers, or by 1 M ryanodine, indicating that: (1) there is a continuous influx of Ca²⁺ through the plasma membrane at a holding potential of 0 mV; (2) the periodic transient increases of [Ca²⁺]_i are ascribed to the rhythmic release of Ca²⁺ from ryanodinesensitive intracellular store by the mechanism of Ca²⁺-induced Ca²⁺ release (CICR). On the basis of the above results, we simulated the oscillation of [Ca²⁺]_i induced by caffeine, which is known to lower the threshold of CICR. The patterns of peak amplitude histograms of spontaneous transient outward currents (STOC) in the oscillating cells were different from those in non-oscillating cells. The amplitudes of STOC in the latter were more variable than those in the former. The oscillating outward currents were modulated by 1 M forskolin and 1 M sodium nitroprusside, but STOC were little affected. The above differences between STOC and oscillating outward currents suggest that the two currents are activated by the Ca²⁺ originating from different intracellular Ca²⁺ stores which are functionally heterogeneous.     

Developmental changes in the actions of phosphatase inhibitors on calcium current of rabbit heart cells

We used whole-cell voltage clamp to compare the modulation of calcium current density (I _Ca, picoampere per picofarad) of freshly isolated, adult and newborn rabbit heart in response to intracellular application of microcystin and okadaic acid, both of which block phosphatase activity of phosphatase types 1 and 2A. Newborn cells showed a much larger response to the intracellular application of either microcystin or okadaic acid than did adult cells. In newborn cells, the application of microcystin produced an increase in I _Ca which appeared to maximize I _Ca, as shown by the rise in I _Ca to levels which could be reached by application of 10 M forskolin or by the intracellular application of 200 M 3,5-cyclic adenosine monophosphate (cAMP). In adult cells, the maximal response to microcystin was considerably less than that obtainable with forskolin or cAMP. After achieving a maximal response with microcystin, the addition of forskolin increased I _Ca further in adult cells but elicited no additional response in newborn cells. The treatment of cells with 0.1 M isoproterenol, a concentration approximately equal to that required for a half-maximal response, strongly potentiated the effect of microcystin in newborn cells, but not in adult cells. We propose that newborn rabbit heart cells compared with adult rabbit heart cells have a greater level of protein phosphatase activity (perhaps combined with a somewhat greater kinase activity), a greater proportion of the protein phosphatase activity in the form of protein phosphatase type 1 (which is inhibited by isoproterenol) and a greater dependence on the inhibition of protein phosphatase as a mechanism of action of isoproterenol, compared with the increase in kinase activity on calcium channels.     

Slow inward current in single cells isolated from adult human ventricles

Characteristics of the slow inward current (I _si) in human ventricular myocytes isolated from septal specimens obtained in patients undergoing corrective cardiac surgery were studied using the whole-cell clamp method. A first series of experiments was performed under normal standard superfusion. Clamping from –60 mV evoked an inward current with a threshold at about –35 mV, a maximum around +10 mV and an apparent reversal potential at about +55 mV. No overlapping transient or background outward currents were detected in the –60 to +30 mV potential range, but time-dependent and steady-state outward currents were elicited at potentials above +30 mV. An overlap of steady-state activation and inactivation curves was present between –30 and +10 mV and a slight relief from inactivation was observed for voltages positive to +10mV. The time course of inactivation consisted of fast and slow phases with time constants differing by a factor of eight. Slow time constants of inactivation were shorter at potentials that elicited larger I _si, and longer at potentials inducing smaller I _si. Recovery from inactivation evolved slowly with 100% reactivation occurring in about 4000 ms. Switching the holding potential from –60 to –40 mV led to a reversible decline of I _si without any change of the decay time constants. I _si was significantly increased by 0.1 M isoproterenol. Total or partial inhibition by inorganic (2 mM Mn²⁺, 3 mM Co²⁺, 1 mM Cd²⁺) and organic (1 M methoxyverapamil, 5 M diltiazem) calcium antagonists did not unmask any transient outward current. However, a consistent increase of I _si was reversibly observed with 3 mM 4-aminopyridine while using standard solutions. A second series of experiments carried out with K⁺- and Na⁺-free solutions did not demonstrate any significant change from data observed with standard solutions except a reduction of outward currents at steps above +30 mV and alteration of inactivation kinetics. In this experimental setting, 4-aminopyridine also increased I _si but to a lesser degree. We conclude that I _si, as compared to the outward currents, is dominant in the diseased human ventricular cells we have studied.     

Roles of inositol trisphosphate and protein kinase C in the spontaneous outward current modulated by calcium release in rabbit portal vein

We examined the effects of heparin, guanosine nucleotides, protein kinase C (PKC) modulators, such as phorbol 12,13-dibutylate (PDBu) and H-7 on Ca²⁺-dependent K⁺ currents in smooth muscle cells of the rabbit portal vein using the whole-cell patch-clamp technique, to explore the effects of PKC on the oscillatory outward current (I _oo). Neomycin (30 M), an inhibitor of phospholipase C, and intracellular applications of heparin (10 g/ml) and guanosine 5-O-(2-thiodiphosphate) (GDP[S]; 1 mM) partly but consistently inhibited the generation of I _oo, whereas a higher concentration of heparin (100 g/ml) transiently enhanced then suppressed the generation of I _oo. Inhibition of I _oo generation by heparin was more powerful at the holding potential of + 20 mV than at –20 mV. Inositol 1,4,5-trisphosphate (InsP ₃; 30 M) continuously generated I _oo at holding potentials more positive than –60 mV. Noradrenaline (10 M) and caffeine (3–20 mM) transiently augmented, then reduced the generation of I _oo. Heparin (10 g/ml) completely inhibited responses induced by InsP ₃ and noradrenaline, but not those induced by caffeine. Intracellular application of guanosine 5-triphosphate (GTP; 200 M) or low concentrations of guanosine 5-O-(3-thiotriphosphate) (GTP[S]; 3 M) continuously augmented the generation of I _oo. High concentrations of GTP[S] (10 M) transiently augmented, then inhibited I _oo. Neither GTP[S] nor noradrenaline induced the transient augmentation or the subsequent inhibition of I _oo when applied in the presence of GDP[S] (1 mM), neomycin (30 M) or heparin (10 g/ml). PDBu (0.1 M) reduced the generation of I _oo but failed to produce an outward current following application of caffeine (3–5 mM). This action of PDBu was inhibited by pretreatment with H-7 (20 M). In the presence of H-7, GTP[S] continuously enhanced the generation of I _oo. The suppression of the generation of I _oo during application of noradrenaline (10 M) was reduced by pretreatment with H-7. Thus both InsP₃ and protein kinase C contribute to the generation of I _oo in smooth muscle cells of the rabbit portal vein and heparin is not a specific InsP ₃ antagonist on the InsP ₃-induced Ca²⁺-release channel (PIRC). InsP ₃ opens PIRC and protein kinase C may deplete the stored Ca²⁺ by either inhibiting the reuptake of Ca²⁺ or by enhancement of the releasing actions of InsP ₃.     

GABA-mediated synaptic transmission in neuroendocrine cells: a patch-clamp study in a pituitary slice preparation

Patch-clamp recording techniques were applied to thin slices of the rat pituitary gland in order to study synaptic transmission between hypothalamic nerve terminals and neuroendocrine cells of the intermediate lobe. Inhibitory postsynaptic currents (IPSCs) could be evoked by electrical stimulation of afferent neuronal fibres in the surrounding tissue of the slice. The IPSCs could be evoked in an all-or-nothing mode depending on the stimulus intensity, suggesting that single afferent fibres were stimulated. They had a chloride-dependent reversal potential and were blocked by bicuculline (K _d=0.1 M), indicating that they were mediated by -aminobutyric acid A (GABA_A) receptors. In symmetrical chloride solutions the current/voltage relation of the IPSC peak amplitudes was linear. The IPSCs were characterized by a fast (1–2 ms) rise time and a biexponential decay, with time constants of 21±4 ms and 58±14 ms at a holding potential of –60 mV (n=6 cells). Both decay time constants increased with depolarization in an exponential manner. Spontaneously occurring IPSCs had a time course that was similar to that of evoked IPSCs. These miniature IPSCs, recorded in 1 M tetrodotoxin, displayed an amplitude distribution that was well fitted by single Gaussian functions, with a mean value of its maxima of 18.1±2.3 pA (n=4 cells). Amplitude histograms of evoked IPSCs were characterized by multiple peaks with a modal amplitude of about 18 pA (n=6 cells). These findings indicate the quantal nature of GABAergic synaptic transmission in this system, with a quantal conductance step of about 280 pS. Single-channel currents underlying the IPSCs were studied by bath application of GABA to outside-out patches excised from intermediate lobe cells. Such GABA-induced currents revealed two conductance levels of 14 pS and 26 pS. In conclusion, GABAergic synaptic transmission in neuroendocrine cells of the pituitary has properties that are quite similar to those observed in neurones of the central nervous system.     

Characteristics of Schwann-cell miniature end-plate currents in denervated frog muscle

End-plates in denervated frog sartorius muscles were investigated, under voltage clamp, to determine the characteristics of miniature endplate currents (mepc) caused by the release of acetylcholine (ACh)-quanta from Schwanncells. Staining for acetylcholinesterase ascertained that in most cases Schwann-cell mepc had been recorded focally from the end-plate. The mean amplitude of Schwann-cell mepc (about 1 nA) was smaller than the amplitude (3–4 nA) of normal nerve evoked mepc. The amplitude distribution of Schwann-cell mepc was skewed, as were also the distributions of decay time constants and of rise times. Some Schwann-cell mepc appeared to be of composite nature, as shown by an inflexion on either the rising or falling phase. The decay time constant of both fast and slowly decaying Schwann-cell mepc increased with membrane hyperpolarization suggesting an exponential correlation. The potential dependence was 118±37 mV (means±SD from 6 experiments) for ane-fold change of , which does not differ significantly from that for neural mepc (98 mV). The cholinesterase inhibitor neostigmine increased the amplitude and prolonged the time course of Schwann-cell mepc to a similar degree after short and long term denervation, which indicates that cholinesterase was still functional after 3–4 months of denervation. The results show that the characteristics of Schwann-cell mepc resemble in many respects those of neural mepc but are more variable in shape and amplitude.     

Noise analysis of cAMP-stimulated Na current in frog colon

The effects of oxytocin and cAMP on the electrogenic Na⁺-transport in the short-circuited epithelium of the frog colon (Rana esculenta, Rana temporaria) were investigated. Oxytocin (100 mU · ml^–1) elevated the shortcircuit current (I _sc) transiently by 70% whereas cAMP (1 mmol · l^–1) elicited a comparable sustained response. The mechanism of the natriferic action of cAMP was studied by analysing current fluctuations through apical Na⁺-channels induced by amiloride or CDPC (6-chloro-3,5-diaminopyrazine-2-carboxamid). The noise data were used to calculate Na⁺-channel density (M) and single apical Na⁺-current (i _Na).i _Na-Values obtained with amiloride and CDPC were 1.0±0.1 pA (n=5) and 1.1±0.2 pA (n=6) respectively and unaffected by cAMP. On the other hand, cAMP caused a significant increase in M from 0.23±0.08 m^–2 (n=5) to 0.49±0.17 m^–2 (n=5) in the amiloride experiments. In our studies with CDPC we obtained smaller values for M in control (0.12±0.04 m^–2;n=6) as well as during cAMP treatment (0.19±0.06 m^–2;n=6). However, the cAMP-induced increase in M was also significant. We conclude that cAMP stimulates Na⁺-transport across the frog colon by activating silent apical Na⁺-channels. Thus, the mechanism of regulation of colonic Na-transport in frogs differs considerably from that in other vertebrates as mammals and birds.     

Calcium-dependent slow outward current in visceral primary afferent neurones of the rabbit

Slow outward currents were recorded from voltage-clamped neurones in nodose ganglia excised from rabbits. In the majority of Type C neurones, a short depolarizing command pulse evoked a slow outward tail current (I _SAH) with a decay time constant ranging from 0.5 to 2 s. TheI _SAH was due to an increase in membrane conductance to K⁺ because its reversal potential was approximately equal to the Nernst potential for K⁺. TheI _SAH was reversibly blocked by removal of external Ca²⁺ or by Ca²⁺ antagonists. A Ca²⁺ ionophore, A23187, produced an outward current which was similar to theI _SAH. TheI _SAH was resistant to tetraethylammonium and depressed by Ba²⁺, whereas it was not affected by Cs⁺ and 4-aminopyridine. TheI _SAH was initially augmented and subsequently depressed by apamin (1–10 nM) and (+)-tubocurarine (100–600 M). It is concluded that theI _SAH in visceral primary neurones may be due to a long-lasting increase in K⁺ conductance caused by an increase in the concentration of intracellular Ca²⁺, resulting from Ca²⁺ entry during the depolarizing command pulse.