Akira Warashina

Functional expression from cloned cDNAs of glutamate receptor species responsive to kainate and quisqualate

The complete amino acid sequences of two mouse glutamate receptor subunits (GluR1 and GluR2) have been deduced by cloning and sequencing the cDNAs. Xenopus oocytes injected with mRNA derived from the GluR1 cDNA exhibit current responses both to kainate and to quisqualate as well as to glutamate, whereas oocytes injected with mRNA derived from the GluR2 cDNA show little response. Injection of oocytes with both the mRNAs produces current responses larger than those induced by the GluR1‐specific mRNA and the dose‐response relations indicate a positively cooperative interaction between the two subunits. These results suggest that kainate and quisqualate can activate a common glutamate receptor subtype and that glutamate‐gated ionic channels are hetero‐oligomers of different subunits.

Homogeneous Ca2+ stores in rat adrenal chromaffin cells

The localization and function of Ca(2+) stores in isolated chromaffin cells of rat adrenal medulla were investigated using confocal laser microscopy and amperometry. Binding sites for BODIPY-inositol 1,4,5-trisphosphate (IP(3)), -ryanodine (Ry), and -thapsigargin (Thap) were both perinuclear and at the cell periphery. The endoplasmic reticulum (ER), which was identified by ER Tracker dye, took up fluorescent Ry and IP(3), and the majority of BODIPY-Ry-binding area was bound by fluorescent IP(3). Under Ca(2+)-free conditions, the amount of caffeine-induced catecholamine secretion was 33% of that of muscarine-induced secretion, but muscarine induced little or no secretion after exposure to caffeine. Muscarine-induced Ca(2+) increases, as observed with fluo-3, lasted for a few tens of seconds under Ca(2+)-free conditions, whereas a caffeine-induced Ca(2+) transient diminished rapidly with a half decay time of 3s and this spike-like Ca(2+) transient was then followed by a sustained increase with a low level. These results indicate that IP(3) receptors and Ry receptors (RyRs) are present in common ER Ca(2+) storage and the lower potency of caffeine for secretion may be due to a rapid decrease in RyR channel activity to a low level.

DYE‐MEMBRANE INTERACTION AND ITS CHANGES DURING NERVE EXCITATION

Abstract— With a view toward elucidating the physiocochemical properties of the nerve membrane, the behavior of various dye molecules incorporated into the membrane was investigated. By measuring the difference between the absorption spectra of dyes in the membrane at rest and those during nerve excitation, the nature of the conformation changes of the membrane macromolecules were examined. Mathematical expressions were developed describing the absorbance changes of dye molecules during nerve excitation. Experimental evidence was presented indicating that there is, during nerve excitation, rotation of dye molecules in the membrane. The physicochemical bases of the process of production of fluorescence changes during nerve excitation are discussed. Based on the results of measurements of the polarization of the fluorescent light, the existence of a highly ordered macromolecular structure at or near the inner surface of the membrane was inferred.

Inhibition of TASK1‐like channels by muscarinic receptor stimulation in rat adrenal medullary cells

The muscarinic receptor is known to be involved in the acetylcholine‐induced secretion of catecholamines in the adrenal medulla (AM) cells of various mammals. The ionic mechanisms, however, have not been elucidated yet. Thus, we investigated the issue in acutely isolated rat AM cells with the perforated patch clamp method. Bath application of 30 μM muscarine induced depolarization with the consequent generation of action potentials or an inward current at negative membrane potentials. The muscarine‐sensitive current instantaneously changed in amplitude upon application of command pulses without a time‐dependent component, altered the polarity as a K+‐electrode, and showed rectification of the Goldman‐Hodgkin‐Katz (GHK) type. The whole‐cell current at −20 mV was inhibited by external H+ ions with a concentration responsible for half inhibition of pH 7.09 and muscarine failed to induce a further inward current during exposure to a saline in which pH decreased to 6.5. A similar occlusion occurred in secretion when pH in muscarine‐containing saline decreased to 6.6. RT‐PCR, immunoblotting, and immunocytochemistry suggested that rat AM cells mainly express the TASK1 channel. This TASK channel in AM cells may directly sense a decrease in blood pH, which occurs during exercise. The muscarine action was mimicked by oxotremorine–methiodide, but not by oxotremorine. The present results indicate that activation of muscarinic receptors or a decrease in external pH in the rat AM cell induces secretion through the inhibition of TASK1‐like channels.

Molecular mechanisms supporting a paracrine role of GABA in rat adrenal medullary cells

GABA is known to produce membrane depolarization and secretion in adrenal medullary (AM) cells in various species. However, whether the GABAergic system is intrinsic or extrinsic or both in the adrenal medulla and the role that GABA plays are controversial. Therefore, these issues were addressed by combining a biochemical and functional analysis. Glutamic acid decarboxylase (GAD), a GABA synthesizing enzyme, and vesicular GABA transporter (VGAT) were expressed in rat AM cells at the mRNA and protein levels, and the adrenal medulla had no nerve fibre‐like structures immunoreactive to an anti‐GAD Ab. The double staining for VGAT and chromogranin A indicates that GABA was stored in chromaffin granules. The α1, α3, β2/3, γ2 and δ subunits of GABAA receptors were identified in AM cells at the mRNA and protein levels. Pharmacological properties of GABA‐induced Cl− currents, immunoprecipitation experiments and immunocytochemistry indicated the expression of not only γ2‐, but also δ‐containing GABAA receptors, which have higher affinities for GABA and neurosteroids. Expression of GATs, which are involved in the clearance of GABA at GABAergic synapses, were conspicuously suppressed in the adrenal medulla, compared with expression levels of GABAA receptors. Increases in Ca2+ signal in AM cells evoked trans‐synaptically by nerve stimulation were suppressed during the response to GABA, and this suppression was attributed to the shunt effect of the GABA‐induced increase in conductance. Overall Ca2+ responses to electrical stimulation and GABA in AM cells were larger or smaller than those to electrical stimulation alone, depending on the frequency of stimulation. The results indicate that GABA functions as a paracrine in rat AM cells and this function may be supported by the suppression of GAT expression and the expression of not only γ2‐, but also δ‐GABAA receptors.

Potential-dependent effects of sea anemone toxins and scorpion venom on crayfish giant axon

Effects of two kinds of sea anemone toxin (Parasicyonis actinostoloides andAnemonia sulcata) and scorpion venom (Leiurus quinquestriatus) on crayfish giant axons were examined electrophysiologically. All toxins acted on the axon in a similar manner to prolong the falling phase of the action potential. In all cases the development of toxicity was reduced when the nerve membrane was depolarized by a current injection. However, the ranges of membrane potential where the significant reduction in toxicity took place were different for each toxin. The action of Parasicyonis toxin was also suppressed by depolarization resulting from treatment of the axon with a neurotoxic alkaloid, veratridine. The mechanism of the potential-dependent toxin action is discussed with reference to the present data and relevant works by other investigators.

Characterization of Low pH-induced Catecholamine Secretion in the Rat Adrenal Medulla

Abstract: Catecholamine (CA) secretion was evoked when the isolated rat adrenal gland was perfused with HEPES‐buffered Krebs solution acidified by the addition of HCI or by gassing with 95% O2/5% CO2. The secretion was detectable at pH 7.0 and increased with decreasing pH until at ∼6.4. The low pH‐induced CA secretion consisted of two phases, an initial transient response followed by a sustained phase. An intracellular Ca2+ antagonist, 3,4,5‐trimethoxybenzoic acid 8‐(N,N‐diethylamino)octyl ester, selectively inhibited the initial phase of secretion. Both of the responses were resistant to nifedipine, a blocker of voltage‐gated Ca2+ channel, but were completely inhibited in Ca2+‐free (1 mM EGTA containing) solution. Adrenaline was an exclusive component in CAs released by low pH. The time course and extent of intracellular acidification caused either by low pH in the external medium or by the offset of a transitory NH4CI application had no correlation with those of the secretory responses in the corresponding period. These results suggest that extracellular acidification preferentially activates adrenaline secretive cells to evoke CA secretion and that this low pH‐induced CA secretion may be mediated by dihydropyridine‐insensitive Ca2+ influx. Furthermore, the initial transient phase of the low pH‐induced CA secretion might be caused by a Ca2+ release from intracellular stores, which is also induced by the Ca2+ influx.

Potential-dependent action ofAnemonia sulcata toxins III and IV on sodium channels in crayfish giant axons

Effects of toxins III and IV (ATX III and IV) from the sea anemoneAnemonia sulcata on the Na current of crayfish giant axons were studied. Both toxins slowed the inactivation of Na channels, producing a maintained Na current during a depolarizing voltage pulse. Using the intensity of the toxin-induced maintained current as an index for the fraction of Na channels to which toxin is bound, the toxin association and dissociation kinetics were analyzed. The dissociation rate of ATX III was increased by two orders of magnitudes by depolarizing the membrane from −70 to −40mV. This increase of the dissociation rate caused a marked decrease in the binding rate of ATX III to Na channels in the same potential range. ATX IV exhibited association and dissociation kinetics that had a potential dependency quite similar to that of ATX III in spite of different ionic charge distribution in these two toxins. The results support the view that the potential-dependent kinetics of these toxins are not due to an electrostatic interaction between the ionic charges of toxins and the membrane potential but result from a modulation of the binding energy depending on the gate configuration of the Na channel.

InsP3 receptor type 2 and oscillatory and monophasic Ca2+ transients in rat adrenal chromaffin cells

Muscarinic receptor stimulation induced oscillatory and monophasic Ca(2+) transients in rat adrenal chromaffin cells in the absence of external Ca(2+). As this Ca(2+) mobilization may be mediated by InsP(3), we first explored types of InsP(3) receptors and their intracellular distribution in chromaffin cells. The InsP(3) receptor type 1 was not immunodetected in precipitates of adrenal medulla homogenates and in dissociated adrenal chromaffin cells, whereas an anti-type 3 mAb recognized a faint band with about 250 kDa, but no significant immunoreaction was visible in chromaffin cells. The anti-type 2 mAb strongly detected a band with about 220 kDa and the immunoreaction was observed perinuclearly and at the cell periphery. These results indicate that InsP(3) receptor type 2 is predominant in chromaffin cells. The oscillatory and monophasic Ca(2+) transients were reproduced in simulation based on a three-state kinetic model (shut, open, and inactivated states). Ca(2+) ions were found experimentally and theoretically to turn over rapidly between stores and the cytosol during stimulation. The results suggest that InsP(3) receptor type 2 is responsible for both oscillatory and monophasic Ca(2+) transients and that change in mode of Ca(2+) responses may be accounted for by the kinetic property of the type 2 receptor.

Mechanisms and roles of muscarinic activation in guinea-pig adrenal medullary cells

Muscarinic receptors are expressed in the adrenal medullary (AM) cells of various mammals, but their physiological roles are controversial. Therefore, the ionic mechanism for muscarinic receptor-mediated depolarization and the role of muscarinic receptors in neuronal transmission were investigated in dissociated guinea-pig AM cells and in the perfused guinea-pig adrenal gland. Bath application of muscarine induced an inward current at -60 mV. This inward current was partially suppressed by quinine with an IC(50) of 6.1 μM. The quinine-insensitive component of muscarine-induced currents changed the polarity at -78 mV and was inhibited by bupivacaine, a TWIK-related acid-sensitive K(+) (TASK) channel inhibitor. Conversely, the current-voltage relationship for the bupivacaine-insensitive component of muscarine currents showed a reversal potential of -5 mV and a negative slope below -40 mV. External application of La(3+) had a double action on muscarine currents of both enhancement and suppression. Immunoblotting and immunocytochemistry revealed expression of TASK1 channels and cononical transient receptor potential channels 1, 4, 5, and 7 in guinea-pig AM cells. Retrograde application of atropine reversibly suppressed transsynaptically evoked catecholamine secretion from the adrenal gland. The results indicate that muscarinic receptor stimulation in guinea-pig AM cells induces depolarization through inhibition of TASK channels and activation of nonselective cation channels and that muscarinic receptors are involved in neuronal transmission from the splanchnic nerve.