Modulation of the inhibitory action of ATP on acetylcholine-activated current by protein phosphorylation in rat sympathetic neurons

Modulation by protein phosphorylation of the relation between acetylcholine (ACh)-activated current (I _ACh) and adenosine triphosphate-(ATP)-activated current (I _ATP) was investigated with the whole-cell voltage-clamp technique in rat sympathetic neurons. During simultaneous activation by 100 M ATP of an inward current, the current evoked by 100 M ACh was reduced to 60–70% of that in the absence of ATP. Effects of compounds that are known to modulate protein phosphorylation were tested by including them in the intracellular solution. The reduction ofI _ACh by ATP was not observed when K252a (1 M), a non-selective protein kinase inhibitor, adenosine 5-O-(3-thiotriphosphate) (ATP[S], 1 mM) or,-methylene ATP (1 mM) were included in the intracellular solution. Activators of protein kinases, adenosine 3,5-cyclic monophosphate (cAMP, 100 M), guanosine 3,5-cyclic monophosphate (cGMP, 100 M), phorbol 12-myristate 13-acetate (PMA, 1 M), also abolished the reduction by ATP ofI _ACh. The effects of okadaic acid, a protein phosphatase inhibitor, were paradoxical: okadaic acid (2 M) itself abolished the reduction by ATP ofI _ACh but it antagonized the abolishment by cAMP or cGMP of the reduction ofI _ACh. Okadaic acid did not affect the disappearance of the reduction ofI _ACh by ATP in the presence of intracellular PMA. The results suggest that the interaction betweenI _ACh andI _ATP is regulated by protein phosphorylation/dephosphorylation. Possible mechanisms underlying the effects of these modulators of protein phosphorylation are discussed.     

Dihydropyridine inhibition of neuronal calcium current and substance P release

Dihydropyridine (DHP) calcium channel antagonists, which inhibit the slowly inactivating or L-type cardiac calcium (Ca) current, have been shown to be ineffective in blocking⁴⁵Ca influx and Ca-dependent secretion in a number of neuronal preparations. In the studies reported here, however, the antagonist DHP nifedipine inhibited both the L-type Ca current and potassium-evoked substance P (SP) release from embryonic chick dorsal root ganglion (DRG) neurons. These results suggest that, in DRG neurons. Ca entry through L-type channels is critical to the control of secretion. The inhibition of Ca current by nifedipine was both voltage and time-dependent, significant effects being observed only on currents evoked from relatively positive holding potentials maintained for several seconds. As expected from these results, nifedipine failed to inhibit L-type Ca current underlying the brief plateau phase of the action potential generated from the cell's normal resting potential; likewise, no significant effect of the drug was observed on action potential-stimulated SP release evoked by electrical field stimulation. The results of this work are discussed in terms of an assessment of the role of L-type Ca channels in neurosecretion.This work was supported by United States Public Health Service Grant NS16483 (KD) and by a USPHS Postdoctoral Fellowship (SGR)     

Influence of extracellur Ca2+ on endogenous Cl− channels in Xenopus oocytes

Removal of Ca²⁺ from the external bath solution evoked marked depolarization and large currents (up to several microamperes) in voltage-clamped defolliculated oocytes of Xenopus laevis. The resulting current was not carried by a cation influx but was due to a huge Cl^– efflux, which could be strongly inhibited by the Cl^– channel blockers flufenamic acid and niflumic acid. Removal of Mg²⁺ or Ba²⁺ from the solutions had the same effects as removing Ca²⁺. The reversal potential of –12 mV also indicated that Cl^– channels were responsible for the large currents. Patch-clamp studies revealed a single-channel slope conductance of 90 pS. During oocyte maturation these channels remained active. The half-maximal Ca²⁺ concentration of about 20 M showed that quite low doses of extracellular Ca²⁺ profoundly influence the electrical properties of the oocyte membrane.     

Nitric oxide: a local signalling molecule controlling the activity of pre‐autonomic neurones in the paraventricular nucleus of the hypothalamus

Abstract Aim: The gas molecule nitric oxide (NO) has been shown to modulate autonomic function by acting both peripherally and centrally. Accumulating evidence indicates that the paraventricular nucleus (PVN) of the hypothalamus is an important locus mediating central NO actions on autonomic function, under both physiological and pathological conditions. However, the cellular targets and mechanisms mediating NO actions within the PVN are still poorly understood. Results: By combining in vitro patch‐clamp recordings with neuronal tract tracing techniques, we show that neuronal excitability of autonomic‐related neurones in the PVN is tonically inhibited by an endogenous NO input. Furthermore, immunohistochemical studies show that ～25% of autonomic‐related PVN neurones express neuronal nitric oxide synthase, suggesting that at least a proportion of them contribute to the cellular sources of NO within the PVN. Conclusion: In summary, this work suggests that NO modulation of the firing activity of autonomic‐related PVN neurones constitutes an efficient mechanism mediated central NO regulation of autonomic function.     

黄皮酰胺促钾通道开放

一种新发现的具有促智作用的药物——黄皮酰胺能抑制去甲肾上腺素(NE)或KCl引起的血管平滑肌收缩。本研究旨在应用膜片钳(patch clamp)技术探讨黄皮酰胺对Wistar大鼠尾动脉平滑肌细胞膜钾离子通道的作用。单个平滑肌细胞用酶法分离,以细胞封接方式记录离子通道活动。在细胞池内注入2μM黄皮酰胺后,钾离子通道活动明显增强。用本实验室开发的计算机软件(patch clamp analysis system,Version 1.0)计算分析通道活动的特征参数。     

Kinetics and distribution of voltage-gated Ca,Na and K channels on the somata of rat cerebellar Purkinje cells

Voltage gated ion channels on the somatic membrane of rat cerebellar Purkinje cells were studied in dissociated cell culture with the combination of cell-attached and whole-cell variation of patch clamp technique. The method enables us to record local somatic membrane current under an improved space clamp condition. Transient (fast-inactivating) and steady (slow inactivating) Ca channel currents, Na current, transient (fast-inactivating) and steady (slow-inactivating) K currents, were observed. Transient and steady Ca channel currents were activated at test potentials more positive than –40 mV and –20 mV, respectively (in 50 mM external Ba). The transient current inactivated with a half-decay time of 10–30 ms during maintained depolarizing pulses, while the steady current showed relatively little inactivation. Na current was activated at more positive potentials than –60 mV, and inactivated with a half-decay time of less than 5 ms. Transient and steady K outward currents were recorded at more positive potential than –20 mV and –40 mV, respectively. The transient current inactivated with a half-decay time of 2–8 ms. Ca, Na and K channels showed different patterns of distribution on the somatic membrane. Steady Ca channels tended to cluster compared with Na or K channels.     

Effects of acetylcholine on time-dependent currents in sheep cardiac Purkinje fibers

Voltage clamp experiments were carried out on sheep Purkinje fibers to determine the effect of Ach on the time-dependent currents.On the pacemaker current (i _{K 2}) Ach 10^–6 mol·l^–1 had the following effects: shift of the activation curve by a few mV in the depolarizing direction, without change in the rectifier ratio. The potential dependence of the time constants for activation and deactivation was influenced in a similar way as the activation curve.Ach had no effect on the positive dynamic current (i _qr ) or the late plateau outward current (i _x ).The slow inward current (i _si ) as well as the transient inward current (T.I.) were reduced in amplitude and slowed in time course by Ach.The changes in pacemaker current are important in explaining the increased rate of diastolic depolarization in the presence of Ach. The decrease of slow inward current by Ach cannot be made responsible for the plateau shift or the prolongation of the action potential.Supported by F.G.W.O. Belgium 3.0087.74     

Mechanisms of the inhibition of Shaker potassium channels by protons

Potassium channels are regulated by protons in various ways and, in most cases, acidification results in potassium current reduction. To elucidate the mechanisms of proton-channel interactions we investigated N-terminally truncated Shaker potassium channels (K_v1 channels) expressed in Xenopus oocytes, varying pH at the intracellular and the extracellular face of the membrane. Intracellular acidification resulted in rapid and reversible channel block. The block was half-maximal at pH 6.48, thus even physiological excursions of intracellular pH will have an impact on K⁺ current. The block displayed only very weak voltage dependence and C-type inactivation and activation were not affected. Extracellular acidification (up to pH 4) did not block the channel, indicating that protons are effectively excluded from the selectivity filter. Channel current, however, was reduced greatly due to marked acceleration of C-type inactivation at low pH. In contrast, inactivation was not affected in the T449V mutant channel, in which C-type inactivation is impaired. The pH effect on inactivation of the wild-type channel had an apparent pK of 4.7, suggesting that protonation of extracellular acidic residues in Kv channels makes them subject to pH regulation.     

Cytoskeletal modulation of the response to mechanical stimulation in human vascular endothelial cells

Possible interactions of cytoskeletal elements with mechanically induced membrane currents and Ca²⁺ signals were studied in human endothelial cells by using a combined patch-clamp and Fura II technique. For mechanical stimulation, cells were exposed to hypotonic solution (HTS). The concomitant cell swelling activates a Cl^– current, releases Ca²⁺ from intracellular stores and activates Ca²⁺ influx. To interfere with the cytoskeleton, cells were loaded either with the F-actin-stabilizing agent phalloidin (10 mol/l), or the F-actin-depolymerizing substance cytochalasin B (50 mol/l). These were administered either in the bath or the pipette solutions. The tubulin structure of the endothelial cells was modulated by taxol (50 mol/l), which supports polymerization of tubulin, or by the depolymerizing agent colcemid (10 mol/l) both applied to the bath. Immunofluorescence experiments show that under the chosen experimental conditions the cytoskeletal modifiers employed disintegrate the F-actin and microtubuli cytoskeleton. Neither of these cytoskeletal modifiers influenced the HTS-induced Cl^– current. Ca²⁺ release was not affected by cytochalasin B, taxol or colcemid, but was suppressed if the cells were loaded with phalloidin. Depletion of intracellular Ca²⁺ stores by thapsigargin renders the intracellular [Ca²⁺] sensitive to the extracellular [Ca²⁺], which is indicative of a Ca²⁺ entry pathway activated by store depletion. Neither cytochalasin B nor phalloidin affected this Ca²⁺ entry. We conclude that F-actin turnover or depolymerization is necessary for Ca²⁺ release by mechanical activation. The tubulin network is not involved. The Ca²⁺ release-activated Ca²⁺ entry is not modulated by the F-actin cytoskeleton.     

Identification of single transiently opening (“A-type”) K channels in guinea-pig colonic myocytes

Two K⁺ channel populations were identified in depolarized cell-attached membrane patches of myocytes freshly dispersed from the circular smooth muscle of guinea-pig proximal colon. First, a large-conductance (150 pS) Ca²⁺-activated K⁺ channel which was non-inactivating and sensitive to blockade by tetraethylammonium (TEA, 0.5–5 mM); and second, a smaller conductance K⁺ channel which opened and closed within 100 ms, was insensitive to TEA (0.5–5 mM), but was blocked by 5 mM 4-aminopyridine (4-AP) or maintained depolarization, and which had a unitary conductance of 12–13 pS. The averaged time course of these smaller conductance K⁺ channels closely resembled the time course of the 4-AP-sensitive, Ca²⁺-insensitive transient outward K⁺ current recorded in the whole-cell recording mode.