Membrane currents of the tunicate egg under the voltage-clamp condition

Heterologous functional expression of ascidian Nav1 channels and close relationship with the evolutionary ancestor of vertebrate Nav channels

Voltage-gated sodium channels (Nav1s) are responsible for the initiation and propagation of action potentials in neurons, muscle, and endocrine cells. Many clinically used drugs such as local anesthetics and antiarrhythmics inhibit Nav1s, and a variety of inherited human disorders are caused by mutations in Nav1 genes. Nav1s consist of the main α subunit and several auxiliary β subunits. Detailed information on the structure–function relationships of Nav1 subunits has been obtained through heterologous expression experiments and analyses of protein structures. The basic properties of Nav1s, including their gating and ion permeation, were classically described in the squid giant axon and other invertebrates. However, heterologous functional expression of Nav1s from marine invertebrates has been unsuccessful. Ascidians belong to the Urochordata, a sister group of vertebrates, and the larval central nervous system of ascidians shows a similar plan to that of vertebrates. Here, we report the biophysical properties of ascidian Ciona Nav1 (CiNav1a) heterologously expressed in Xenopus oocytes. CiNav1a exhibited tetrodotoxin-insensitive sodium currents with rapid gating kinetics of activation and inactivation. Furthermore, consistent with the fact that the Ciona genome lacks orthologous genes to vertebrate β subunits, the human β1 subunit did not influence the gating properties when coexpressed with CiNav1a. Interestingly, CiNav1a contains an ankyrin-binding motif in the II–III linker, which can be targeted to the axon initial segment of mammalian cortical neurons. Our findings provide a platform to gain insight into the evolutionary and biophysical properties of Nav1s, which are important for the development of targeted therapeutics.

Voltage-dependent calcium influx mediates maturation of myofibril arrangement in ascidian larval muscle

Calcium signaling is important for multiple events during embryonic development. However, roles of calcium influx during embryogenesis have not been fully understood since routes of calcium influx are often redundant. To define roles of voltage-gated calcium channel (Cav) during embryogenesis, we have isolated an ascidian Cav beta subunit gene (TuCavbeta) and performed gene knockdown using the morpholino antisense oligonucleotide (MO). The suppression of Cav activity by TuCavbetaMO remarkably perturbed gastrulation and tail elongation. Further, larvae with normal morphology also failed to exhibit motility. Phalloidin-staining showed that arrangement of myofibrils was uncoordinated in muscle cells of TuCavbetaMO-injected larvae with normal tail. To further understand the roles of Cav activity in myofibrillogenesis, we tested pharmacological inhibitions with ryanodine, curare, and N-benzyl-p-toluensulphonamide (BTS). The treatment with ryanodine, an intracellular calcium release blocker, did not significantly affect the motility and establishment of the myofibril orientation. However, treatment with curare, an acetylcholine receptor blocker, and BTS, an actomyosin ATPase specific inhibitor, led to abnormal motility and irregular orientation of myofibrils that was similar to those of TuCavbetaMO-injected larvae. Our results suggest that contractile activation regulated by voltage-dependent calcium influx but not by intracellular calcium release is required for proper arrangement of myofibrils.

Ion Channel Development, Spontaneous Activity, and Activity-Dependent Development in Nerve and Muscle Cells

At specific stages of development, nerve and muscle cells generate spontaneous electrical activity that is required for normal maturation of intrinsic excitability and synaptic connectivity. The patterns of this spontaneous activity are not simply immature versions of the mature activity, but rather are highly specialized to initiate and control many aspects of neuronal development. The configuration of voltage- and ligand-gated ion channels that are expressed early in development regulate the timing and waveform of this activity. They also regulate Ca2+influx during spontaneous activity, which is the first step in triggering activity-dependent developmental programs. For these reasons, the properties of voltage- and ligand-gated ion channels expressed by developing neurons and muscle cells often differ markedly from those of adult cells. When viewed from this perspective, the reasons for complex patterns of ion channel emergence and regression during development become much clearer.

The maternal transcript for truncated voltage-dependent Ca2+ channels in the ascidian embryo: a potential suppressive role in Ca2+ channel expression

Ca2+ entry during electrical activity plays several critical roles in development. However, the mechanisms that regulate Ca2+ influx during early embryogenesis remain unknown. In ascidians, a primitive chordate, development is rapid and blastomeres of the muscle and neuronal lineages are easily identified, providing a simple model for studying the expression of voltage-dependent Ca2) channels (VDCCs) in cell differentiation. Here we isolate an ascidian cDNA, TuCa1, a homologue of the alpha(1)-subunit of L-type class Ca2+ channels. We unexpectedly found another form of Ca2+ channel cDNA (3-domain-type) potentially encoding a truncated type which lacked the first domain and a part of the second domain. An analysis of genomic sequence suggested that 3-domain-type RNA and the full-length type have alternative transcriptional start sites. The temporal pattern of the amount of 3-domain-type RNA was the reverse of that of the full-length type; the 3-domain type was provided maternally and persisted during early embryogenesis, whereas the full-length type was expressed zygotically in neuronal and muscular lineage cells. Switching of the two forms occurred at a critical stage when VDCC currents appeared in neuronal or muscular blastomeres. To examine the functional roles of the 3-domain type, it was coexpressed with the full-length type in Xenopus oocyte. The 3-domain type did not produce a functional VDCC current, whereas it had a remarkable inhibitory effect on the functional expression of the full-length form. In addition, overexpression of the 3-domain type under the control of the muscle-specific actin promoter in ascidian muscle blastomeres led to a significant decrease in endogenous VDCC currents. These findings raise the possibility that the 3-domain type has some regulatory role in tuning current amplitudes of VDCCs during early development.

Cross-coupling between voltage-dependent Ca2+ channels and ryanodine receptors in developing ascidian muscle blastomeres

1. Ascidian blastomeres of muscle lineage express voltage-dependent calcium channels (VDCCs) despite isolation and cleavage arrest. Taking advantage of these large developing cells, developmental changes in functional relations between VDCC currents and intracellular Ca2+ stores were studied. 2. Inactivation of ascidian VDCCs is Ca2+ dependent, as demonstrated by two pieces of evidence: (1) a bell-shaped relationship between prepulse voltage and amplitude during the test pulse in Ca2+, but not in Ba2+, and (2) the decay kinetics of Ca2+ currents (ICa) obtained as the size of tail currents. 3. During replacement in the external solution of Ca2+ with Ba2+, the inward current appeared biphasic: it showed rapid decay followed by recovery and slow decay. This current profile was most evident in the mixed bath solution (2 % Ca2+ and 98 % Ba2+, abbreviated to '2Ca/98Ba'). 4. The biphasic profile of I2Ca/98Ba was significantly attenuated in caffeine and in ryanodine, indicating that Ca2+ release is involved in shaping the current kinetics of VDCCs. After washing out the caffeine, the biphasic pattern was reproducibly restored by depolarizing the membrane in calcium-rich solution, which is expected to refill the internal Ca2+ stores. 5. The inhibitors of endoplasmic reticulum (ER) Ca2+-ATPase (SERCAs) cyclopiazonic acid (CPA) and thapsigargin facilitated elimination of the biphasic profile with repetitive depolarization. 6. At a stage earlier than 36 h after fertilization, the biphasic profile of I2Ca/98Ba was not observed. However, caffeine induced a remarkable decrease in the amplitude of I2Ca/98Ba and this suppression was blocked by microinjection of the Ca2+ chelator BAPTA, showing the presence of caffeine-sensitive Ca2+ stores at this stage. 7. Electron microscopic observation shows that sarcoplasmic membranes (SR) arrange closer to the sarcolemma with maturation, suggesting that the formation of the ultrastructural machinery underlies development of the cross-coupling between VDCCs and Ca2+ stores.

Ion channels and early development of neural cells

In this review we underscore the merits of using voltage-dependent ion channels as markers for neuronal differentiation from the early stages of uncommitted embryonic blastomeres. Furthermore, a fairly large part of the review is devoted to the descriptions of the establishment of a simple model system for neural induction derived from the cleavage-arrested eight-cell ascidian embryo by pairing a single ectodermal with a single vegetal blastomere as a competent and an inducer cell, respectively. The descriptions are focused particularly on the early developmental processes of various ion channels in neuronal and other excitable membranes observed in this extraordinarily simple system, and we compare these results with those in other significant and definable systems for neural differentiation. It is stressed that this simple system, for which most of the electronic and optical methods and various injection experiments are applicable, may be useful for future molecular physiological studies on the intracellular process of differentiation of the early embryonic cells. We have also highlighted the importance of suppressive mechanisms for cellular differentiation from the experimental results, such as epidermal commitment of the cleavage-arrested one-cell Halocynthia embryos or suppression of epidermal-specific transcription of inward rectifier channels by neural induction signals. It was suggested that reciprocal suppressive mechanisms at the transcriptional level may be one of the key processes for cellular differentiation, by which exclusivity of cell types is maintained.

Effects of inhibitors for intracellular signal transduction systems on the inward current produced by GABA in a snail neuron

1. An inward current (I[in]) was produced by gamma-aminobutyric acid (GABA) and muscimol, but not by baclofen, in an identifiable giant neuron type, v-LCDN (ventral-left cerebral distinct neuron), of an African giant snail (Achatina fulica Ferussac) under voltage clamp. 2. The pharmacological features of the excitatory GABA receptors in this Achatina neuron type, termed the Achatina muscimol II type GABA receptors, were mainly comparable to those of the mammalian GABA(C) receptors. 3. It was demonstrated in the present study that the following inhibitors for intracellular signal transduction systems showed no significant effect on the I(in) produced by GABA in this Achatina neuron type: H-7 [1-(5-isoquinolinyl sulfonyl)-2-methylpiperazine], an inhibitor of cyclic AMP-dependent protein kinase (PKA), cyclic GMP-dependent protein kinase (PKG) and protein kinase C (PKC); H-8 (N-[2-(methylamino)-ethyl]-5-isoquinolinesulfonamide), a PKA and PKG inhibitor; H-9 [N-(2-aminoethyl)-5-isoquinolinesulfonamide], a PKA inhibitor; staurosporine ((9alpha,10beta,11beta,13alpha)-(+)-2,3,10,11,12 ,13-hexahydro-10-methoxy-9-methyl-11-(methylamino)-9,13-epoxy-1H,9H-d iindolo[1,2,3-gh: 3',2',1'-1m]pyrrolo[3,4-j] [1,7]benzodiazonin-1-one), a PKA and PKC inhibitor; KT5823 ((8R,9S, 11S)-9-methoxy-9-methoxycarbonyl-2N,8-dimethyl-2,3,9,10-tetrahydro-8,11- epoxy-1H,8H,11H-2,7b,11a-triazadibenzo[a,g]cycloocta[c,d,e]- trinden-1-one), a PKG inhibitor; W-7 [N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide], a calmodulin inhibitor; ML-9 [1-(5-chloronaphthalene-1-sulfonyl-1H-hexahydro-1,4-diazepine hydrochloride], a myosin light-chain kinase inhibitor; genistein [5,7-dihydroxy-3-(4-hydroxyphenyl)-4H-1-benzopyran-4-one], a tyrosine protein kinase inhibitor; IBMX (3-isobutyl-1-methylxanthine), a cyclic nucleotide phosphodiesterase (PDE) inhibitor; fluphenazine nitrogen-mustard (2-chloroethyl)-4[3-(2-trifluoromethyl-10-phenothiazinyl)-propyl]p iperazine dihydrochloride), a calmodulin-dependent PDE inhibitor; calyculin A, a type 1 protein phosphatase inhibitor; and okadaic acid (9,10-deepithio-9,10-didehydroacanthifolicin), a type 1, 2A and 2B protein phosphatase inhibitor. 4. With these results, it was proposed that the excitatory Achatina muscimol II type GABA receptors in v-LCDN are not metabotropic but ionotropic.

Distinct neuronal lineages of the ascidian embryo revealed by expression of a sodium channel gene

The ascidian larva contains tubular neural tissue, one of the prominent anatomical features of the chordates. The cell-cleavage pattern and cell maps of the nervous system have been described in the ascidian larva in great detail. Cell types in the neural tube, however, have not yet been defined due to the lack of a suitable molecular marker. In the present work, we identified neuronal cells in the caudal neural tube of the Halocynthia embryo by utilizing a voltage-gated Na+ channel gene, TuNa I, as a molecular marker. Microinjection of a lineage tracer revealed that TuNa I-positive neurons in the brain and in the trunk epidermis are derived from the a-line of the eight-cell embryo, which includes cell fates to epidermal and neural tissue. On the other hand, TuNa I-positive cells in the more caudal part of the neural tissue were not stained by microinjection into the a-line. These neurons are derived from the A-line, which contains fates of notochord and muscle, but not of epidermis. Electron microscopic observation confirmed that A-line-derived neurons consist of motor neurons innervating the dorsal and ventral muscle cells. Isolated A-line blastomeres have active membrane excitability distinct from those of the a-line-derived neuronal cells after culture under cleavage arrest, suggesting that the A-line gives rise to a neuronal cell distinct from that of the a-lineage. TuNa I expression in the a-line requires signals from another cell lineage, whereas that in the A-line occurs without tight cell contact. Thus, there are at least two distinct neuronal lineages with distinct cellular behaviors in the ascidian larva: the a-line gives rise to numerous neuronal cells, including sensory cells, controlled by a mechanism similar to vertebrate neural induction, whereas A-line cells give rise to motor neurons and ependymal cells in the caudal neural tube that develop in close association with the notochord or muscle lineage, but not with the epidermal lineage.

Modulation by APGW-amide, an Achatina endogenous inhibitory tetrapeptide, of currents induced by neuroactive compounds on Achatina neurons: peptides

1. Modulatory effects of APGW-amide (Ala-Pro-Gly-Trp-NH2), proposed as an inhibitory neurotransmitter of Achatina neurons, perfused at 3 x 10(-6) M on the currents induced by neuroactive peptides, ejected by brief pressure, were examined by using Achatina giant neuron types, v-RCDN (ventral-right cerebral distinct neuron) and PON (periodically oscillating neuron), under voltage clamp. 2. Outward current (Iout) caused by FMRFamide (Phe-Met-Arg-Phe-NH2) on v-RCDN, which was probably K+ dependent, was inhibited with membrane conductance (g) increase by APGW-amide. From the dose (pressure duration)-response curves of FMRFamide and a Lineweaver-Burk plot of these data, the inhibition caused by APGW-amide was mainly in an uncompetitive manner. 3. Iout caused by APGW-amide on v-RCDN, which was probably K+ dependent, was inhibited with g increase by APGW-amide. The inhibition caused by APGW-amide was partly in a competitive manner and partly in a noncompetitive manner. 4. Iout caused by [Ser2]-Mytilus inhibitory peptide, [Ser2]-MIP (Gly-Ser-Pro-Met-Phe-Val-NH2) on v-RCDN, which was probably K+ dependent, was inhibited with g increase by APGW-amide. Because the modulation of this current was not so marked, a dose-response study of this compound was not carried out. Iin induced by oxytocin on PON was not affected by APGW-amide. 5. From the dose-response curves of APGW-amide, perfused consecutively, the inhibitory effects of APGW-amide on the Iout caused by APGW-amide were stronger than those on the Iout caused by FMRFamide. 6. The inhibition of the APGW-amide-induced Iout on v-RCDN by APGW-amide was partly due to the competition in the receptor sites and partly to the g increase. The inhibition by APGW-amide on the Iout induced by FMRFamide and [Ser2]-MIP would be partly due to the g increase. In addition, we consider that APGW-amide affects intracellular signal transduction systems or ionic channels, thus modulating these currents. 7. The currents modulated by APGW-amide were different from those modulated by achatin-1, another Achatina endogenous neuroexcitatory peptide. We consider that the mechanisms underlying the modulatory effects of APGW-amide are different from those of achatin-I.

Ouabain-sensitive K(+)-dependent outward current caused by threo-beta-hydroxy-L-glutamic acid on a snail neuron

1. An analog of L-glutamic acid, threo-beta-hydroxy-L-glutamic acid (threo-L-BHGA), was applied locally to the giant neuron of an Achatina snail by pneumatic brief pressure ejection and induced an outward current (Iout) on the ventral-left cerebral distinct neurone (v-LCDN). The present study aimed to elucidate the ionic mechanisms of the Iout caused by threo-L-BHGA (ItL-BHGA) of v-LCDN and the effects of ouabain on this current under voltage clamp. 2. The reversal potentials of ItL-BHGA (EtL-BHGA) of v-LCDN in varied K+o were fitted to the Nernst equation as ItL-BHGA = IK (K+ current) and were almost unchanged in Cl-o-free and Na+o-reduced (20% of normal) states. The ItL-BHGA is due to the increase in permeability of the neuromembrane to K+(K(+)-dependent) and is neither Na(+)- nor Cl-(-)-dependent. K(+)-channel blockers, a mixture of tetraethyl-ammonium (TEA) and 4-amino-pyridine (4-AP), blocked ItL-BHGA mainly in a noncompetitive and partly in an uncompetitive manner. 3. Unexpectedly, ItL-BHGA of v-LCDN was almost abolished in the Na+o-free state and significantly reduced in the Cl-o-free state. However, an Na(+)-channel blocker, tetrodotoxin, showed a tendency to enhance ItL-BHGA. On the other hand, ItL-BHGA was enhanced in K+o-free state. 4. Ouabain markedly inhibited ItL-BHGA in both noncompetitive and uncompetitive manners. Benzamil, an inhibitor of the Na(+)-Ca2+ exchange applied simultaneously with ouabain could not prevent ouabain inhibition on ItL-BHGA. The currents induced by other putative neurotransmitters, including a K(+)-dependent Iout caused by dopamine on v-LCDN, were not affected by ouabain. 5. According to our previous study, the threo-L-BHGA receptors are not linked with protein kinases or calmodulin. Then, ItL-BHGA could be produced by the receptor K+ channel complex or the receptor-G-protein-K+ channel combination. The present results indicate that the ATPase activity inhibited by ouabain and the presence of extracellular Na+ and Cl- are needed for threo-L-BHGA to activate the K(+)-dependent structure. Furthermore, the K+o-free state, which inactivates the Na(+)-K+ pump, and tetrodotoxin, which suppresses the Na+ channel at least partly, did not affect the structure to be activated.

Modulation by APGW-amide, an Achatina endogenous inhibitory tetrapeptide, of currents induced by neuroactive compounds on Achatina neurons: amines and amino acids

1. Modulatory effects of APGW-amide (Ala-Pro-Gly-Trp-NH2), proposed as an inhibitory neurotransmitter of Achatina neurons, perfused at 3 x 10(-6) M on the currents induced by small-molecule putative neurotransmitters were examined by using Achatina giant neuron types, v-RCDN (ventral-right cerebral distinct neuron), TAN (tonically autoactive neuron) and RAPN (right anterior pallial nerve neuron), under voltage clamp. These putative neurotransmitters were ejected locally to the neuron by brief pneumatic pressure. 2. Outward current (Iout) induced by erythro-beta-hydroxy-L-glutamic acid (erythro-L-BHGA) on v-RCDN, which was probably K+ dependent, was enhanced with membrane conductance (g) increase under APGW-amide. From dose (pressure duration)-response curves of erythro-L-BHGA measured in physiological solution (control curve) and with APGW-amide (drug curve), ED50 values of the two curves were nearly comparable, whereas Emax of the drug curve was significantly larger than that of the other. From a Lineweaver-Burk plot of these data, the cross point of the control line and the drug line was on the abscissa. 3. K(+)-dependent Iout caused by dopamine (DA) on v-RCDN was inhibited with a g increase by APGW-amide. The inhibition of this current caused by APGW-amide was mainly in a noncompetitive and partly uncompetitive manner. 4. 5-Hydroxytryptamine (5-HT) produced an inward current (Iin) with two (fast and slow) components on TAN, which was probably Na+ dependent. The fast component of the Iin was inhibited by APGW-amide. The inhibition was mainly in a noncompetitive manner. 5. The currents induced by acetylcholine, gamma-aminobutyric acid and L-glutamic acid on Achatina neuron types were not affected by APGW-amide. 6. The inhibitory effects of APGW-amide on the Iin (fast component) induced by 5-HT were nearly equipotent or a bit stronger than those on the Iout caused by DA. 7. The g increase produced by APGW-amide would be a cause for inhibiting the Iout induced by DA. In addition, we consider that APGW-amide affects intracellular signal transduction systems or ionic channels, thus modulating these currents.

Synthesis of achatin-I (Gly-D-Phe-L-Ala-L-Asp) analogs having dehydrophenylalanine or aminoisobutyric acid residue at position 2, and their effects on Achatina giant neurons

1. Achatin-I (Gly-D-Phe-L-Ala-L-Asp), a neuroactive tetrapeptide having a D-phenylalanine residue, has been proposed to be an excitatory neurotransmitter of Achatina giant neurons. It was revealed that the D-Phe2 residue is essential for bioactivity of achatin-I, which seems to adopt beta-turn conformation. In the present study, in order to investigate the structure-activity relationships of achatin-I and its derivatives, the two highly constrained analogs of achatin-I, [delta ZPhe2]achatin-I (Gly-delta ZPhe-L-Ala-L-Asp) (delta ZPhe: (Z)-alpha,beta-dehydrophenylalanine) and [Aib2]achatin-I (Gly-Aib-L-Ala-L-Asp) (Aib: alpha-aminoisobutyric acid), were synthesized, and their effects on the two identifiable Achatina giant neuron types, PON (periodically oscillating neuron) and v-RCDN (ventral-right cerebral distinct neuron), were examined in comparison with those of achatin-I under voltage clamp. 2. Achatin-I (n = 6), ejected onto the neurone by brief pneumatic pressure (2 kg/cm2, 400 ms, 10(-3) M, at 10-min intervals), produced an inward current (Im) on PON. The Iin value (mean +/- SEM) was 0.44 +/- 0.03 nA. The interval between the achatin-I ejection and the Iin peak was 14.74 +/- 3.15 s (n = 6). [delta ZPhe2]achatin-I (n = 6) and [Aib2]achatin-I (n = 6) had no effect on this neuron type. 3. On the other hand, achatin-I (n = 10) and [delta ZPhe2]-achatin-I (n = 10), ejected by brief pressure, produced an Iin on v-RCDN. The Iin values were 0.85 +/- 0.07 nA for achatin-I and 0.48 +/- 0.05 nA (p < 0.01, compared with that of achatin-I by Student's t-test for paired data) for [delta ZPhe2]achatin-I. The intervals between the compound ejection and the Iin peak were 5.95 +/- 0.33 s for achatin-I and 8.70 +/- 0.81 s (p < 0.05, compared with that of achatin-I) for [delta ZPhe2]achatin-I. [Aib2]achatin-I (n = 10) had no effect on this neuron type.

Pharmacologic characteristics of excitatory gamma-amino-butyric acid (GABA) receptors in a snail neuron

1. The pharmacologic characteristics of excitatory gamma-aminobutyric acid (GABA) receptors, termed muscimol II type GABA receptors, found in a giant neuron type, v-LCDN (ventral-left cerebral distinct neuron), of an African giant snail (Achatina fulica Férussac), were studied using the mammalian GABA receptor agonists, antagonists and synergists and GABA uptake inhibitor using the voltage clamp technique. 2. GABA and its agonists, ejected by brief pressure, produced an inward current (Iin) of the following order of potency: trans-t-aminocrotonic acid (TACA) > GABA > muscimol > isoguvacine > 5-aminopentanoic acid and cis-4-aminocrotonic acid (CACA). (+/-)-Baclofen and 3-aminopropylphosphonic acid (APPA) were ineffective. The Iin values produced by GABA, TACA, isoguvacine and CACA were stable for at least 60 min, whereas the Iin induced by muscimol was not. 3. According to the dose-response curves of GABA, TACA, isoguvacine and CACA, measured by the varied pressure duration method, the ED50 value of CACA was larger than those of the other compounds, and Emax of TACA was larger than that of GABA, whereas Emax values of isoguvacine and CACA were smaller. 4. The perfusion of beta-alanine, pentobarbital and 5-aminopentanoic acid inhibited the Iin induced by GABA, whereas (-)-bicuculline, pitrazepin, diazepam and 2-hydroxysaclofen had no effect. 5. From the effects of beta-alanine on the dose-response curves of GABA, measured by the varied pressure duration method, beta-alanine competitively inhibited the Iin caused by GABA. According to the effects of pentobarbital on the dose-response curves of GABA, this drug noncompetitively inhibited the Iin using the varied pressure duration method, and partly competitively and partly noncompetitively using the Y-tube method. The effects of 5-aminopentanoic acid on the dose-response curves of GABA indicated that this drug noncompetitively inhibited the Iin using the varied pressure duration method, and partly noncompetitively and partly uncompetitively using the Y-tube method. 6. The pharmacologic features of the Achatina muscimol II type GABA receptors were similar to those of mammalian GABAC (GABAp1) receptors, except for the effects of pentobarbital.

Lineweaver-Burk analysis for the blocking effects of mammalian dopamine receptor antagonists on dopamine-induced currents in Achatina giant neurones

1. We had demonstrated (Emaduddin et al., 1995) the blocking effects of the three mammalian dopamine receptor antagonists, (+/-)-SKF83566 (mammalian dopamine D1-like receptor antagonist), (+)-UH232 (D2 and D3-like receptor antagonist) and (+/-)-sulpiride (D2-like receptor antagonist) on the dose (pressure duration)-response curves of dopamine in the three giant neurone types, LVMN (left visceral multiple spike neurone), d-RPeAN (dorsal-right pedal anterior neurone) and v-LCDN (ventral-left cerebral distinct neurone), of Achatina fulica Férussac under voltage clamp. In the present study, we analyzed these data by Lineweaver-Burk plot. 2. Dopamine-induced inward currents (Iin) of the two neurone types, LVMN and d-RPeAN, were blocked by (+/-)-SKF83566 and (+)-UH232 in partly noncompetitive and partly uncompetitive manners. (+/-)-Sulpiride had no effect on these currents. 3. In contrast, dopamine-induced outward current (Iout) of v-LCDN was inhibited competitively by (+/-)-sulpiride and noncompetitively by (+)-UH232. (+/-)-SKF83566 had no effect on this current. 4. Therefore, we consider that the pharmacological features of the dopamine receptors of Achatina neurones are not identical in detail to those of the mammalian dopamine receptors.

A weakly inward rectifying potassium channel of the salmon brain. Glutamate 179 in the second transmembrane domain is insufficient for strong rectification

A cDNA encoding for a weakly inward rectifying K+ channel (sWIRK: salmon weakly inward rectifying K+ channel) was isolated from the masu salmon brain by expression cloning. The sWIRK channel exhibited the highest similarity with members of the ROMK1 subfamily, BIR10/KAB-2 (70% amino acid identity) and ROMK1 (46%). An ATP binding motif which is characteristic of this subfamily was also conserved. The sWIRK RNA was detected in the brain, but not in the heart, kidney, skeletal muscle, liver, testis, and ovary. In the brain, the expression was observed in the ependymoglial cells on the surface of the ventricles as well as in the small perineuronal glia-like cells in the midbrain and the medulla. When compared with the strong inward rectifier IRK1 channel, the sWIRK channel showed a much weaker inward rectification property, and the activation kinetics upon hyperpolarization was slower and less voltage-dependent. The slope conductance of the single channel inward current was 37 pS (140 mM K+o), and outward current channel events were also observed. The weak rectification of sWIRK is significant in that it has a negatively charged residue (glutamate) in the M2 region which is reported to cause strong inward rectification. By introducing a point mutation to remove this negative charge (glutamine), the sWIRK E179Q mutant channel lost its inward rectification property completely, and the single channel property (45 pS; 140 mM K+o) was ohmic up to highly depolarized potential, even in the presence of the physiological cytoplasmic blockers such as Mg2+ and polyamines.

Kinetic mechanism of Na+ channel depression by taurine in guinea pig ventricular myocytes

To examine effects of taurine on the kinetics of the Na+ channel current (I(Na)), action potentials and whole-cell Na+ currents were recorded from single ventricular myocytes of guinea pigs. Kinetic parameters for the activation and inactivation of I(Na) were determined in accordance with the first-order kinetic model. Changes in the kinetic parameters were assessed before and after taurine exposure (5-50 mM). While taurine at concentrations higher than 10 mM decreased the peak I(Na) by ca. 15%, the agent did not alter the reversal potential and the maximum Na+ conductance (GNa). Taurine shifted the steady-state inactivation (h(infinity)) curve toward the negative potential direction and decreased the slope of h(infinity). Concomitantly, the slope of the steady-state activation (m(infinity)) was also slightly decreased and the rate of inactivation in the large potential region (-40 to -30 mV) slightly increased, whereas the rate of the activation appeared to remain unchanged. It is suggested that taurine alters the surface charge of the membrane and reduces the number of charges moving upon activation and inactivation of channels, thereby reducing I(Na).

Blocking effects of promethazine, triprolidine and their analogues on the excitation caused by the peptide, achatin-I

An Achatina endogenous tetrapeptide, achatin-I (Gly-D-Phe-Ala-Asp), applied by brief pressure, produced an inward current (Iin) on an Achatina giant neurone type, PON (periodically oscillating neurone). Promethazine, triprolidine and their analogues tested, applied by perfusion, showed a tendency to inhibit the Iin, suggesting that the effective structures vary to a wide extent. With respect to promethazine and its analogues, the presence of 2-bromo, 5-oxo, 3-dimethylsulfamido and 2-methoxy weakened the effects. 10-(2-methylamino-2-methylethyl) instead of 10-(2-dimethylamino-2-methylethyl) of promethazine and the azepine ring instead of phenothiazine ring potentiated the effects. From the dose (pressure duration)-response study of achatin-I, the two promethazine analogues, RP 6497 and RP 6549 (the structures are shown in Fig. 1), inhibited the Iin in partly competitive and partly noncompetitive manners. Regarding triprolidine and its analogues, the compounds in Z-configuration seemed to be more effective than those in E-configuration. The presence of 4-methyl in 1-phenyl, and 1-(4-pyridyl) instead of 1-(2-pyridyl) potentiated the effects. 3-Dimethylamino instead of 3-pyrrolidino weakened the effects. The two triprolidine analogues, Trip Der 3 and Trip Der 6 (the structures in Fig. 2), inhibited the Iin in an uncompetitive manner.

Multiple intracellular signal transduction pathways mediating inward current produced by the neuropeptide, achatin-I

The effects of intracellular signal transduction system inhibitors on the inward current (Iin) caused by achatin-I (Gly-D-Phe-Ala-Asp), an Achatina endogenous tetrapeptide having a D-phenylalanine residue, applied locally onto the neurone tested, were examined under voltage clamp using two identifiable Achatina giant neurone types, v-RCDN (ventral-right cerebral distinct neurone) and PON (periodically oscillating neurone). H-89 (N-[2-(p-bromocinnamylamino)-ethyl]-5-isoquinolinesulfonamide) (adenosine-3',5'-cyclic monophosphate (cyclic AMP)-dependent protein kinase inhibitor) markedly suppressed the achatin-I-induced Iin on PON, whereas this drug was ineffective on the Iin of v-RCDN. Dose (pressure duration)-response study of achatin-I on PON in a physiological solution and in the presence of H-89, and Lineweaver-Burk plot of these data, indicated that H-89 inhibited the Iin in a noncompetitive manner. KT5823 (N-methyl-(8R*,9S*,11S*)-(-)-9-methoxy-9-methoxycarbonyl-8-methyl-2,3,9, 10-tetrahydro-8,11-epoxy-1H,8H,11H-2, 7b,11a-triazadibenzo[a,g]cycloocta[c,d,e]-trinden-1-on e) (guanosine-3',5'-cyclic monophosphate (cyclic GMP)-dependent protein kinase inhibitor) suppressed the achatin-I-induced Iin of v-RCDN in mainly noncompetitive and partly uncompetitive manners, but this drug had no effect on the Iin of PON. W-7 (N-(6-aminohexyl)-5-chloro-1-naphthalene-sulfonamide) (calmodulin inhibitor) suppressed noncompetitively the Iin of PON, but this drug had no effect on the Iin of v-RCDN. IBMX (3-isobutyl-1-methylxanthine) (cyclic nucleotide phosphodiesterase inhibitor) enhanced the achatin-I-induced Iin of v-RCDN, but this drug was ineffective on the Iin of PON. However, IBMX might have effects on the achatin-I receptor sites on v-RCDN. These findings suggest multiple intracellular signal transduction pathways mediating the achatin-I-induced Iin: the Iin of PON is via cyclic AMP-dependent and probably Ca2+/calmodulin-dependent protein kinases, and that of v-RCDN via cyclic GMP-dependent protein kinase. Other signal transduction system inhibitors including calphostin C (2-[12-[2-(benzyloxy)-propyl]-3, 10-dihydro-4,9-dihydroxy-2,6,7,11-tetramethoxy-3,10-dioxo-1-per yleny]-1 -methylethyl carbonic acid 4-hydroxyphenyl ester) (protein kinase C inhibitor) did not significantly affect the Iin of both v-RCDN and PON.

Effects of L-glutamic acid and its agonists on snail neurones

The sensitivities of 22 giant neurone types of an African giant snail (Achatina fulica Férussac) to threo-beta-hydroxy-L-glutamic acid (threo-L-BHGA), a derivative of L-glutamic acid (L-Glu), applied by brief pneumatic pressure ejection, were examined under current clamp. The 5 neurone types were depolarized by this compound, whereas 2 were hyperpolarized. The 4 neurone types, PON (periodically oscillating neurone), RAPN (right anterior pallial nerve neurone), d-RPLN (dorsal-right parietal large neurone) and RPeNLN (right pedal nerve large neurone) that are excited by threo-L-BHGA and one type, v-LCDN (ventral-left cerebral distinct neurone), inhibited by this compound, were selected to study their pharmacological features in detail. Effects of the stereoisomers of L-Glu and threo-L-BHGA, and mammalian L-Glu receptor agonists, ejected by brief pressure, on the 5 Achatina neurone types were examined under voltage clamp. d-RPLN produced an inward current (Iin) by L-Glu and threo-L-BHGA, whereas this neurone type was insensitive to D-Glu and erythro-L-, threo-D- and erythro-D-BHGA. This was also excited by AMPA, indicating that the pharmacological features of the L-Glu receptors in this neurone type were similar to those of the mammalian ionotropic AMPA type L-Glu receptors. RAPN produced Iin by L-Glu and threo-L-BHGA. This neurone type was also excited by quisqualic acid and ibotenic acid, indicating that the features of the L-Glu receptors were similar to those of the mammalian metabotropic L-Glu receptors. PON and RPeNLN produced Iin by L-Glu and threo-L-BHGA. These neurone types were also excited by quisqualic acid, AMPA and ibotenic acid, indicating that their L-Glu receptors seemed to be in the mixed type, of the two types mentioned. On the other hand, v-LCDN produced an outward current (Iout) by threo-L- and erythro-L-BHGA, but was insensitive to L-Glu, indicating that the receptors activated by L-BHGA were not L-Glu receptors. This neurone type was also inhibited by quisqualic acid.

Pharmacological characteristics of an outward current produced by beta-hydroxy-L-glutamic acid on a snail neurone

An outward current (Iout) was produced by stereoisomers of beta-hydroxy-L-glutamic acid (L-BHGA), an L-glutamic acid (L-Glu) derivative, applied by brief pneumatic pressure ejection on an identifiable neurone type, v-LCDN (ventral-left cerebral distinct neurone), of Achatina fulica Férussac. However, L- and D-Glu were almost ineffective on this neurone type. The pharmacological features of this Iout caused by L-BHGA were elucidated in the present study. According to the dose (pressure duration)-response studies on the L-BHGA stereoisomers that produced the Iout, the effective potency of threo-L-BHGA was approximately similar to that of erythro-L-BHGA. The dose (pressure duration)-response curve of quisqualic acid was shifted towards the left direction from those of threo-and erythro-L-BHGA, suggesting that the binding activity of quisqualic acid to the receptors would be stronger than those of the L-BHGA stereoisomers. GABA, glycine and L-homocysteic acid showed an inward current (Iin) on this neurone type, in contrast to the Iout caused by L-BHGA. beta-Alanine and taurine had absolutely no effect. Therefore, no amino acid inhibitory neurotransmitter candidate was found for this neurone type except for L-BHGA. It was assumed that L-BHGA, in either threo-or erythro-configuration, would be an inhibitory neurotransmitter for this neurone type. Mammalian L-Glu receptor antagonists. D(-)-AP-5, (+/-)-CPP, CNQX and L(+)-AP-3, applied by perfusion, showed no effect on the Iout of v-LCDN caused by threo-L-BHGA, indicating that the features of the inhibitory receptor activated by L-BHGA were much different from those of any type of the mammalian L-Glu receptors. Among the inhibitors of ATP-sensitive K+ channel, glipizide significantly inhibited the Iout caused by threo-L-BHGA, whereas tolbutamide did not. Inhibitors of intracellular signal transduction systems, H-7, H-8, H-9, staurosporine, calphostin C, KT5823 and W-7, had no effect on the Iout caused by threo-L-BHGA, suggesting that the receptors activated by threo-L-BHGA would be ionotropic.

Identifiable Achatina giant neurones: their localizations in ganglia, axonal pathways and pharmacological features

1. An African giant snail (Achatina fulica Férussac), originally from East Africa, is now found abundantly in tropical and subtropical regions of Asia, including Okinawa in Japan. This is one of the largest land snail species in the world. The Achatina central nervous system is composed of the buccal, cerebral and suboesophageal ganglia. The 37 giant neurones were identified in these ganglia by the series of studies conducted over about 20 years. The identifications were made by the localization of these neurones in the ganglia, their axonal pathways and their pharmacological features. 2. In the left buccal ganglion, the four giant neurones, d-LBAN, d-LBMB, d-LBCN and d-LBPN, were identified. In the left and right cerebral ganglia, d-LCDN, d-RCDN, v-LCDN and v-RCDN were identified. The suboesophageal ganglia are further composed of the left and right parietal, the visceral, the left and right pleural, and the left and right pedal ganglia. In the right parietal ganglion, PON, TAN, TAN-2, TAN-3, RAPN, d-RPLN, BAPN, LPPN, LBPN, LAPN and v-RPLN were identified. In the visceral ganglion, VIN, FAN, INN, d-VLN, v-VLN, v-VAN, LVMN, RVMN and v-VNAN were identified. In the left parietal ganglion, v-LPSN was identified. In the left and right pedal ganglia, LPeNLN, RPeNLN, d-LPeLN, d-LPeCN, d-RPeAN, d-LPeDN, d-LPeMN and d-LPeEN were identified. 3. Of the small molecule compounds tested, dopamine, 5-hydroxytryptamine, GABA, L-glutamic acid, threo- or erythro-beta-hydroxy-L-glutamic acid were effective on the Achatina giant neurones. We suppose that these compounds act as the neurotransmitters for these neurones. 4. Of the neuroactive peptides, achatin-I(Gly-D-Phe-Ala-Asp). APGW-amide(Ala-Pro-Gly-Trp-NH2) and Achatina cardioexcitatory peptide (ACEP-1)(Ser-Gly-Gln-Ser-Trp-Arg-Pro-Gln-Gly-Arg-Phe-NH2) were proposed as neurotransmitters, because these were effective on the Achatina giant neurones and their presence was demonstrated in the Achatina ganglia. Further, myomodulin (Pro-Met-Ser-Met-Leu-Arg-Leu-NH2), buccalin (Gly-Met-Asp-Ser-Leu-Ala-Phe-Ser-Gly-Gly-Leu-NH2), FMRFamide (Phe-Met-Arg-Phe-NH2). [Ser2]-Mytilus inhibitory peptide ([Ser2]-MIP) (Gly-Ser-Pro-Met-Phe-Val-NH2), catch-relaxing peptide (CARP) (Ala-Met-Pro-Met-Leu-Arg-Leu-NH2), oxytocin (Cys-Tyr-Ile-Gln-Asn-Cys-Pro-Leu-Gly-NH2) and small cardioactive peptideB (SCPB) (Met-Asn-Tyr-Leu-Ala-Phe-Pro-Arg-Met-NH2) could also be neurotransmitters because these peptides were also effective on the Achatina giant neurones, though their presence in the ganglia of this animal has not yet been demonstrated. 5. Calcium current (ICa) was recorded from Achatina giant neurones in the Na(+)-free solution containing K(+)-channel blockers under voltage clamp. The Ca2+ antagonistic effects of brovincamine, verapamil, eperisone, diltiazem, monatepil, etc., were compared using the ICa of the Achatina neurones. 6. Almost all of the mammalian small molecule neurotransmitters were effective on the Achatina giant neurones, suggesting that these compounds are acting on the neurones of a wide variety of animal species. However, the pharmacological features of the Achatina neurone receptors to these compounds were not fully comparable to those of the mammalian receptors. For example, we proposed that beta-hydroxy-L-glutamic acid (either threo- or erythro-) could be an inhibitory neurotransmitter for an Achatina neurone. 7. In contrast, the Achatina giant neurones appear to have no receptor for the mammalian neuroactive peptides, except for oxytocin and Arg-vasotocin. On the other hand, many neuroactive peptides were isolated from invertebrate nervous tissues, including achatin-I, a neuroexcitatory tetrapeptide having a D-phenylalanine residue.

Single-channel analysis of two types of Na+ currents in rat dorsal root ganglia

The properties of voltage-gated Na+ channels were studied in neurones isolated from rat dorsal root ganglia using the outside-out configuration of the patch-clamp technique. Two types of single-channel currents were identified from the difference in unit amplitudes. Neither type was evoked in the medium in which extracellular Na+ ions were replaced by an equimolar amount of tetramethylammonium ions. The two types of single-channel currents differed in their sensitivity to tetrodotoxin (TTX). The smaller channel current was insensitive to 1 microM TTX (referred to as TTX-I), while the larger channel current was blocked by 1 nM TTX (TTX-S). The unit amplitudes measured during a step depolarization to -30 mV (1.4 mM internal and 250 mM external Na+ concentrations) were 1.16 pA for TTX-S and 0.57 pA for TTX-I, respectively. The slope conductance measured at -30 mV was 16.3 pS for TTX-S and 8.5 pS for TTX-I. TTX-S could be activated by step depolarizations positive to -60 mV, while TTX-I could be activated at potentials positive to -40 mV. When the test pulse was preceded by a depolarizing prepulse, the prepulse positive to -50 mV preferentially inactivated TTX-S with a minimal effect on TTX-I. Activation and inactivation time courses of the averaged ensemble currents computed from TTX-S showed remarkable resemblances to the time courses of the macroscopic TTX-sensitive Na+ current. Similarly, the ensemble currents of TTX-I mimicked the macroscopic TTX-insensitive Na+ current. It was concluded that the two types of Na+ channels in rat dorsal root ganglia differ not only in their sensitivity to TTX, but also in their single-channel conductances.

Effects of dopamine on snail neurones

The pharmacological features of dopamine receptors in identifiable giant neurone types of a snail (Achatina fulica Férussac) were studied. Under voltage clamp, two neurone types, LVMN (left ventral multiple spike neurone) and d-RPeAN (dorsal-right pedal anterior neurone), produced an inward current (Iin) in response to dopamine, (-)-noradrenaline and epinine, whereas v-LCDN (ventral-left cerebral distinct neurone) produced an outward current (Iout) in response to dopamine and epinine. Mammalian dopamine receptor agonists, fenoldopam (dopamine D1-like receptor agonist), (+/-)-SKF 38393 (1-phenyl-2,3,4,5-tetrahydro-1H-3-benzazepine-7,8- diol) (D1-like), apomorphine (D2-like), (-)-quinpirole (D3 and D4) and methylergometrine showed slight or no effect. (+/-)-SKF 83566 ((+/-)-7-bromo-8-hydroxy-3-methyl-1-phenyl-2,3,4,5-tetrahydro-1H-3-benza zepine) (dopamine D1-like receptor antagonist) and (+)-UH 232 (cis-(+)-5-methoxy-1-methyl-2-(di-n-propylamino)tetralin) (D3 and D2) non-competitively inhibited the Iin of LVMN and d-RPeAN, but (+/-)-sulpiride (D2-like) was without effect. In contrast, (+/-)-sulpiride competitively inhibited Iout of v-LCDN, (+)-UH 232 non-competitively inhibited Iout of v-LCDN but (+/-)-SKF 83566 was without effect. H-7 (1-(5-isoquinolinesulfonyl)-2-methylpiperazine) (non-selective protein kinase inhibitor) inhibited Iin of LVMN and d-RPeAN, but did not affect Iout of v-LCDN. Dopamine-induced Iin was Na(+)-dependent; Iout was K(+)-dependent. Ouabain did not affect these currents. We propose that the pharmacological features of Achatina neuronal dopamine receptors are not fully comparable to those of mammals, although intracellular signal transduction systems linked with dopamine receptors may similarly exist in different animal species.

Suppressing effects of neuroactive peptides on the inward current caused by achatin-I, an Achatina endogenous peptide

1. Modulatory effects of the four molluscan neuroactive peptides. FMRFamide (Phe-Met-Arg-Phe-NH2), APGW-amide (Ala-Pro-Gly-Trp-NH2), oxytocin and [SER2]-Mytilus inhibitory peptide ([SER2]-MIP) (Gly-Ser-Pro-Met-Phe-Val-NH2) were examined on the inward current (Iin) caused by achatin-I (Gly-D-Phe-Ala-Asp), which has been isolated from the Achatina ganglia. 2. Two Achatina giant neurone types, v-RCDN (ventral-right cerebral distinct neurone) and PON (periodically oscillating neurone), were used. Achatin-I was applied locally to the neurone tested by brief pneumatic pressure ejection, and the other molluscan neuroactive peptides were perfused around the ganglia. 3. FMRFamide, perfused at 3 microM, suppressed markedly the Iin elicited by the achatin-I of both v-RCDN and PON. APGW-amide at 3 microM also suppressed the Iin of v-RCDN, but did not affect that of PON. Oxytocin at 1 microM suppressed the Iin of PON, but did not affect that of v-RCDN. [Ser2]-MIP at 3 microM did not affect the Iin of v-RCDN. 4. The dose-response curves of FMRFamide, APGW-amide and oxytocin, indicated that their respective suppressive effects on the Iin of achatin-I were dose-dependent, and that APGW-amide was slightly more potent than the other peptides. The dose (pressure duration)-response curves of achatin-I (1 kg/cm2, 10(-3) M, 5 min interval), obtained by varying the duration of the achatin-I pressure ejection, were measured in the presence and absence of each of the three peptides.(ABSTRACT TRUNCATED AT 250 WORDS)

Blockers for excitatory effects of achatin-I, a tetrapeptide having a D-phenylalanine residue, on a snail neurone

Some histamine H1 receptor antagonists suppressed the inward current (Iin) of an Achatina identifiable neurone type, PON (periodically oscillating neurone), caused by an Achatina endogenous tetrapeptide having a D-phenylalanine residue, achatin-I (Gly-D-Phe-Ala-Asp), under voltage clamp. Achatin-I was applied locally to the neurone by brief pneumatic pressure ejection and antagonists were administered by perfusion. The dose-response curves of the effective histamine H1 antagonists indicated their potency order to suppress the Iin as follows: chlorcyclizine, promethazine, triprolidine and homochlorcyclizine > trimeprazine and clemastine > diphenylpyraline. The potent drugs were mostly piperazine and phenothiazine types. The effects of chlorcyclizine, promethazine and triprolidine on the dose (the duration of the pressure ejection)-response curve of achatin-I indicated that these drugs affected the Iin caused by achatin-I in a non-competitive manner. The antagonists for the receptors of the small-molecule neurotransmitters other than histamine H1, such as histamine H2, acetylcholine, gamma-aminobutyric acid (GABA), L-glutamic acid, dopamine, alpha- and beta-adrenalin and 5-hydroxytryptamine, had no effect on the Iin caused by achatin-I.

Neural expression of a sodium channel gene requires cell-specific interactions

In the protochordate Halocynthia roretzi, voltage-activated sodium current undergoes a change in kinetics within 48 hr of fertilization. Molecular cloning and microinjection of antisense DNA into single cells suggest that the kinetic changes are due to the increased expression of a putative neural-specific sodium channel gene, TuNa I. TuNa I gene transcription is first induced in late stage gastrulae, preceding the appearance of the rapidly inactivating sodium current unique to neural cells. In cleavage-arrested and intact embryos, cell interactions between specific animal and vegetal blastomeres are required for induction of TuNa I gene expression. Our results implicate cell contact, prior to neurulation, as a mechanism for selectively activating the TuNa I gene expressed in cells of the neural lineage.

A region of the muscarinic-gated atrial K+ channel critical for activation by G protein beta gamma subunits

Complementary DNAs encoding two types of inwardly rectifying K+ channels, GIRK1 and IRK1, have been cloned from rat atrium and mouse macrophage, respectively. GIRK1 expressed in Xenopus oocytes was activated by acetylcholine when m2 muscarinic acetylcholine receptor was coexpressed. The acetylcholine-induced activation of GIRK1 was enhanced by coexpression with the G protein beta 1 gamma 2 subunit but not the beta 1 gamma 1 or alpha subunits. Deletion of the C-terminus of GIRK1 impaired the channel activation associated with the beta 1 gamma 2 subunit. Moreover, replacement of the C-terminus of IRK1 with that of GIRK1 produced a chimera channel that was activated by the beta 1 gamma 2 subunit, whereas intact IRK1 was not activated by the beta 1 gamma 2 subunit. These findings define the C-terminus of GIRK1 as a regulatory region for the G protein beta gamma subunit.

Tetrodotoxin-resistant sodium channels

1. Tetrodotoxin (TTX) has been widely used as a chemical tool for blocking Na+ channels. However, reports are accumulating that some Na+ channels are resistant to TTX in various tissues and in different animal species. Studying the sensitivity of Na+ channels to TTX may provide us with an insight into the evolution of Na+ channels. 2. Na+ channels present in TTX-carrying animals such as pufferfish and some types of shellfish, frogs, salamanders, octopuses, etc., are resistant to TTX. 3. Denervation converts TTX-sensitive Na+ channels to TTX-resistant ones in skeletal muscle cells, i.e., reverting-back phenomenon. Also, undifferentiated skeletal muscle cells contain TTX-resistant Na+ channels. Cardiac muscle cells and some types of smooth muscle cells are considerably insensitive to TTX. 4. TTX-resistant Na+ channels have been found in cell bodies of many peripheral nervous system (PNS) neurons in both immature and mature animals. However, TTX-resistant Na+ channels have been reported in only a few types of central nervous system (CNS). Axons of PNS and CNS neurons are sensitive to TTX. However, some glial cells have TTX-resistant Na+ channels. 5. Properties of TTX-sensitive and TTX-resistant Na+ channels are different. Like Ca2+ channels, TTX-resistant Na+ channels can be blocked by inorganic (Co2+, Mn2+, Ni2+, Cd2+, Zn2+, La3+) and organic (D-600) Ca2+ channel blockers. Usually, TTX-resistant Na+ channels show smaller single-channel conductance, slower kinetics, and a more positive current-voltage relation than TTX-sensitive ones. 6. Molecular aspects of the TTX-resistant Na+ channel have been described. The structure of the channel has been revealed, and changing its amino acid(s) alters the sensitivity of the Na+ channel to TTX. 7. TTX-sensitive Na+ channels seem to be used preferentially in differentiated cells and in higher animals instead of TTX-resistant Na+ channels for rapid and effective processing of information. 8. Possible evolution courses for Na+ and Ca2+ channels are discussed with regard to ontogenesis and phylogenesis.

Modulation of neuropeptide effects by achatin-I, an Achatina endogenous tetrapeptide

Achatin-I (Gly-D-Phe-L-Ala-L-Asp), an endogenous tetrapeptide in the ganglia of Achatina fulica Férussac, at 3 x 10(-6) M suppressed both the inward current (Iin) of an Achatina giant neurone, PON (periodically oscillating neurone), caused by locally ejected oxytocin, and the outward current (Iout) of v-RCDN (ventral-right cerebral distinct neurone) induced by APGW-amide. Dose (pressure duration)-response studies with oxytocin and APGW-amide showed that their ED50 values were not affected by achatin-I, whereas the Emax values were suppressed. The v-RCDN Iout caused by FMRF-amide was enhanced by achatin-I, but the same current induced by [Ser2]Mytilus inhibitory peptide ([Ser2]MIP) was not affected. Achatin-I suppressed the Iout of TAN (tonically autoactive neurone) caused by acetylcholine, but did not affect the Iin of v-RCDN elicited by acetylcholine. The Iout caused by gamma-aminobutyric acid, threo-beta-hydroxy-L-glutamic acid and dopamine was not affected by achatin-I. It is considered that achatin-I acts as a neuromodulator and has both suppressing and enhancing actions on the effects of various neurotransmitters, including peptides, in Achatina giant neurones.

Influence of the drugs for membrane excitability modification on the excitation caused by achatin-I

1. The pneumatic pressure ejection of achatin-I (Gly-D-Phe-L-Ala-L-Asp), an endogenous tetrapeptide having a D-phenylalanine residue, produced an inward current (Iin) in an identifiable giant neuron, PON (periodically oscillating neuron), of an African giant snail, Achatina fulica Férussac. The influence of the drugs for membrane excitability modification, applied by perfusion, on the PON excitation caused by achatin-I was examined under voltage clamp. 2. The four channel blocking drugs, tetrodotoxin (TTX), tetraethylammonium chloride (TEA), verapamil and picrotoxin, at 10(-4) M did not affect significantly the PON excitation caused by the peptide. 3. N-beta-phenylpropionyl-L-tyrosine (BPLT), a membrane hyperpolarizant, at 10(-6) M and concanavalin A (Con A), which altered the response to L-glutamate, at 100 micrograms/ml-1 were considered to hardly influence the PON excitation caused by achatin-I.

Neural induction suppresses early expression of the inward-rectifier K+ channel in the ascidian blastomere

1. Early expression of ion channels following neural induction was examined in isolated, cleavage-arrested blastomeres from the ascidian embryo using a two-electrode voltage clamp. Currents were recorded from the isolated, cleavage-arrested blastomere, a4-2, after treatment with serine protease, subtilisin, which induces neural differentiation as consistently as cell contact. 2. The inward-rectifier K+ current increased at the late gastrula stage shortly after the sensitive period for neural induction both in the induced (protease-treated) and uninduced cells. Ca2+ channels, characteristic of epidermal-type differentiation, and delayed-rectifier K+ channels and differentiated-type Na+ channels, characteristic of neural-type differentiation appeared much later than the inward-rectifier K+ channels, at a time corresponding to the tail bud stage of the intact embryo. 3. When cells were treated with subtilisin during the critical period for neural induction, the increase in the inward-rectifier K+ current from the late gastrula stage to the neurula stage was about three times smaller (3.67 +/- 1.74 nA, mean +/- S.D., n = 14) than in untreated cells (11.25 +/- 3.10 nA, n = 26). The same changes in the inward-rectifier K+ channel were also observed in a4 2 blastomeres which were induced by cell contact with an A4-1 blastomere. However, when cells were treated with subtilisin after the critical period for neural induction, the amplitude of the inward-rectifier K+ current was the same as in untreated cells. Thus the expressed level of the inward-rectifier K+ channel was linked to the determination of neural or epidermal cell types. 4. There was no significant difference in the input capacitance of induced and uninduced cells, indicating that the difference in the amplitude of the inward-rectifier K+ currents derived from a difference in the channel density rather than a difference in cell surface area. 5. The expression of the inward-rectifier K+ channel at the late gastrula stage was sensitive to alpha-amanitin, a highly specific transcription inhibitor. In both induced and uninduced cells, injection of alpha-amanitin at the 32-cell stage reduced the current density of the inward-rectifier K+ channel to about 2 nA/nF, corresponding to 13% of that recorded from uninjected cells. By contrast, the expression of the fast-inactivating-type Na+ current, which transiently increased along with the inward-rectifier K+ channel, was resistant to alpha-amanitin injection. 6. The dose of alpha-amanitin injected was controlled by monitoring co-injected fluorescent dye, fura-2.(ABSTRACT TRUNCATED AT 400 WORDS)

Primary structure and functional expression of a mouse inward rectifier potassium channel

A complementary DNA encoding an inward rectifier K+ channel (IRK1) was isolated from a mouse macrophage cell line by expression cloning. This channel conducts inward K+ current below the K+ equilibrium potential but passes little outward K+ current. The IRK1 channel contains only two putative transmembrane segments per subunit and corresponds to the inner core structure of voltage-gated K+ channels. The IRK1 channel and an ATP-regulated K+ channel show extensive sequence similarity and constitute a new superfamily.

Modulatory effects of achatin-I, an Achatina endogenous neuroactive peptide, on responses to 5-hydroxytryptamine

Achatin-I (Gly-D-Phe-L-Ala-L-Asp) was found in the ganglia of an African giant snail (Achatina fulica Férussac), and proposed as an excitatory neurotransmitter of Achatina neurones. At 3 x 10(-6) the peptide markedly enhanced the fast inward current (Iin) of an Achatina neurone type, TAN (tonically autoactive neurone), produced by the pneumatic pressure ejection of 5-HT. This Iin was facilitated immediately by the achatin-I perfusion, and the facilitation decreased gradually even with the peptide present. The dose (duration)-response curves of the TAN fast Iin on pressure ejection in the absence (control) and presence of achatin-I at 3 x 10(-6) M (n = 8) were analyzed as follows. The ED50 (95% confidence limit) were 59.3 ms (13.9-95.3 ms) for the control, and 36.5 ms (19.5-52.6 ms) for achatin-I. The Emax were 1.06 +/- 0.11 nA for the control, and 1.74 +/- 0.26 nA for achatin-I (P < 0.01 for paired data). Among achatin-I derivatives, achatin-II (Gly-L-Phe-L-Ala-L-Asp) enhanced the TAN fast response to 5-HT, but was ten times weaker than achatin-I. [L-Glu4]achatin-I (Gly-D-Phe-L-Ala-L-Glu) and achatin-I amide (Gly-D-Phe-Ala-L-Asp-NH2) had no facilitatory effect. We propose that achatin-I is a neuromodulator as well as a neurotransmitter for Achatina giant neurones.

Sensitivities of Achatina giant neurones to putative amino acid neurotransmitters

1. GABA receptors in Achatina identifiable giant neurones were classified into the muscimol I, muscimol II and baclofen types. Muscimol I and II type GABA receptors were sensitive to GABA and muscimol but insensitive to baclofen, whereas baclofen type receptors were sensitive to GABA and baclofen but insensitive to muscimol. Muscimol I and baclofen types were associated with the inhibition caused by GABA, while muscimol II type with the GABA excitation. 2. GABA, muscimol and TACA produced a transient outward current (Iout) with an increase in membrane conductance (g) of an Achatina neurone, TAN, having the muscimol I type GABA receptors. Their relative potency values (RPV) at GABA ED50 (approximately 10(-4) M) were: GABA:muscimol:TACA = 1:0.6:0.3. The GABA effects were potentiated by pentobarbitone, antagonized competitively by pitrazepin and non-competitively by picrotoxin and diazepam, and unaffected by bicuculline. The ionic mechanism of effects of GABA and its two analogues was the increase in membrane Cl- conductance (gCl). 3. GABA and (+/-)-baclofen produced a slow Iout with a g increase of another Achatina neurone, RPeNLN, having the baclofen type GABA receptors. The two compounds were almost equipotent (ED50: approximately 3 x 10(-4) M). The ionic mechanism of their effects was the increase in gk. The two compounds hardly affected the voltage-gated and slowly inactivating calcium current. Iout produced by GABA and (+/-)-baclofen were reduced by TEA, but unaffected by 4-AP, bicuculline, pitrazepin and picrotoxin. 4. Beta-hydroxy-L-glutamic acid (L-BHGA) showed the marked effects on the Achatina giant neurones; the two neurones were excited by the compound, whereas the three inhibited. D-BHGA, L-Glu, D-Glu and NMDA were less effective than L-BHGA or almost ineffective. Erythro-L-BHGA was more or less effective than threo-L-BHGA according to the neurones tested. 5. alpha-Kainic acid and domoic acid excited the two neurones, which were excited by L-BHGA. L-Quisqualic acid showed the similar effects to L-BHGA, which were mostly much stronger than L-BHGA. Erythro-L-tricholomic acid and DL-ibotenic acid showed the effects similar to L-BHGA selectively on some neurones. 6. It was pointed out that the pharmacological features of GABA on the Achatina neurones are simpler than those of L-BHGA, due to the simpler structure of the former compound having less binding sites than the latter.

Tetrodotoxin-sensitive calcium-conducting channels in the rat hippocampal CA1 region

1. Tetrodotoxin (TTX)-sensitive Ca2+ conducting channels which produce a transient inward current were investigated in pyramidal neurones freshly dissociated from the dorsal part of rat hippocampal CA1 region by the use of the suction-pipette technique, which allows for intracellular perfusion under a single-electrode voltage clamp. 2. In all cells superfused with Na(+)- and K(+)-free external solution containing 10 mM-Ca2+ and 10(-5) M-La3+, a transient inward Ca2+ current was evoked by a step depolarization to potentials more positive than about -50 mV from a holding potential (VH) of -100 mV. This current was inhibited by either removing the extracellular Ca2+ or adding TTX (termed as 'TTX-ICa'). 3. Activation and inactivation processes of the TTX-ICa were highly potential dependent at 20-22 degrees C, and the latter was fitted by a double exponential function. The time to peak of the current decreased from 5.0 to 2.3 ms at a test potential change from -50 to 0 mV. The time constants of the current decay decreased from 2.8 to 2.2 ms for fast component (tau if) and from 16.0 to 8.2 ms for slow component (tau is) at a potential change from -35 to -10 mV. 4. The TTX-ICa was activated at threshold potential of about -55 mV and reached full activation at -30 mV. The steady-state inactivation of TTX-ICa could be fitted by a Boltzmann equation with a slope factor of 6.0 mV and a half-inactivation voltage of -72.5 mV. 5. Biphasic recovery (reactivation) from the complete inactivation of TTX-ICa was observed. The time constant of the major component (78.8 to 91.6% of total) of the reactivation was 13.1 ms, and that of the minor one was 120 to 240 ms. Therefore, TTX-ICa remained fairly constant at a train of stimulation up to 3 Hz. However, the inhibition of current amplitude occurred as the repetitive stimulation increased more than 10 Hz, and considerable tonic inhibition occurred with increasing stimulation frequency. 6. When the peak amplitudes in the individual current-voltage (I-V) relationships of TTX-ICa at various extracellular Ca2+ concentrations ([Ca2+]o) were plotted as a function of [Ca2+]o, the current amplitude increased linearly without showing any saturation. 7. The ratio of peak amplitude in the individual I-V relationships of Ca2+, Sr2+ and Ba2+ currents passing through the TTX-sensitive Ca2+ conducting channel was 1:0.33:0.05, although the current kinetics were much the same.(ABSTRACT TRUNCATED AT 400 WORDS)

APGW-amide as an inhibitory neurotransmitter of Achatina fulica Ferussac

APGWamide (L-Ala-L-Pro-Gly-L-Trp-NH2) was purified from the ganglia of an African giant snail (Achatina fulica Ferussac). This peptide inhibited (hyperpolarized) more than half of the Achatina neurone types tested. This produced an outward current with the membrane conductance increase of RAPN (right anterior pallial neurone) under voltage clamp. The ED50 of the peptide was 6.2 x 10(-6) M (95% confidence limit: 5.0-7.8 x 10(-6) M) and the Emax was 3.9 +/- 0.2 nA. The effects were due to a membrane permeability increase to K+. The peptide is proposed as an inhibitory neurotransmitter of the Achatina neurones.

Slow inward current induced by achatin-I, an endogenous peptide with a D-Phe residue

Following a preliminary report on the isolation of a neuroactive tetrapeptide, achatin-I (Gly-D-Phe-L-Ala-L-Asp) that has a D-phenylalanine residue, from the Achatina fulica ganglia, the pharmacological features of this peptide on Achatina giant neurones were now worked out in detail. Of the eight possible stereoisomers, only achatin-I markedly, and [D-Ala3]achatin-I slightly, induced a slow inward current (Iin) with an increase in membrane conductance (g) of the identifiable neurones, tonically autoactive neurone (TAN), dorsal-right cerebral distinct neurone (d-RCDN) and periodically oscillating neurone (PON) which had been tested previously. Of 23 types of neurones tested, 10 types including the three mentioned were excited by achatin-I, whereas no neurone was inhibited. The ED50 of achatin-I for the neurones tested were 0.2-2.7 x 10(-5) M, and that for PON was the lowest. The Hill coefficients of achatin-1. 0.62-0.80, derived from 1.0 Emax values of achatin-I for producing Iin, 4.2-6.3 nA, were significantly greater than those of [D-Ala3]achatin-I, 1.8-3.4 nA. Iin of TAN and d-RCDN induced by achatin-I was blocked in the Na(+)-free state, but unaffected in the Ca2(+)-free (replaced with Co2+), Cl(-)-free or K(+)-enriched (3.0X) state, indicating that the current was produced by the g increase in response to Na+. However, the Iin was partially blocked by tetrodotoxin 10(-4) M. We propose that achatin-I is an excitatory neurotransmitter on Achatina neurones.

Structure-activity relationship studies on the endogenous neuroactive tetrapeptide achatin-I on giant neurons of Achatina fulica Ferussac

The structure-activity relationships of achatin-I, a neuroactive peptide containing a D-phenylalanine residue, for producing excitatory effects on three different types of Achatina neurons, PON, TAN and d-RCDN, were studied under the voltage clamp method. Of the peptides examined, only Gly-Gly-D-Phe-L-Ala-L-Asp (IV). D-Phe-L-Ala-L-Asp (V) and Gly-D-Phe-L-Ala-L-Asn (XVI) produced an inward current with increased membrane conductance similar to achatin-1 (I). The structure-activity relationship was essentially the same for the three Achatina neuron types. The equiactive molar ratios (EMRs) of the active peptides vs. achatin-I (I) were calculated from their dose-response curves: 8 - 60 for Gly-Gly-DPhe-L-Ala-L-Asp (IV), 200 - greater than 250 for D-Phe-L-Ala-L-Asp (V) and greater than 200 for Gly-D-Phe-L-Ala-L-Asn (XVI). These values indicate that the achatin-I receptor in the Achatina neurons is highly structure-specific.

Changes in sodium channels during neural differentiation in the isolated blastomere of the ascidian embryo

1. The current density and the kinetics of voltage-sensitive sodium channels during neural differentiation were examined in the isolated, cleavage-arrested blastomere of ascidian embryos which contains presumptive neural regions. The macroscopic sodium current were measured with the two-microelectrode voltage-clamp technique and the single sodium channel currents were recorded with the patch-clamp technique under the cell-attached configuration. 2. The entire time course of sodium channel development could be divided into three phases from the current density and channel gating properties. 3. In the first phase, from fertilization to about 40 h, the density of the sodium channel current was from 8 to 50 microA cm-2. The channel gating properties were similar to those of the sodium channel in the egg cell except for a negative shift in the voltage dependence of the peak inward current, the steady-state inactivation, and the decay time constant. The sodium channels in this phase were classified as 'type-I' channels. 4. In the second phase (40-60 h after fertilization), the density of the sodium channel current increased from 20 to 800 microA cm-2. The curves of the I-V relationship and of the steady-state inactivation shifted in the positive direction by 5-10 mV. 5. At 45-55 h, when the rate of increase in the sodium current was greatest, as much as 40 microA cm-2 h-1, the decay time course of the sodium current became slowest. The time for the current to decline from the peak to the one-tenth of the peak (t 1/10) increased to about five times that in the first phase. After 55 h t 1/10 gradually decreased. 6. In this phase, steady-state inactivation curves showed two inflexion points at different levels of membrane potential and were fitted with a sum of two Boltzmann distribution curves with distinct parameters. The relative contribution of the component with its voltage dependence shifted in the positive direction tended to decrease with development. 7. On examining single-channel recordings, two types of sodium channel were identified in this phase. One type (type-II) showed frequent repetitions of open-to-shut states throughout a voltage step. The ensemble current of the type-II channel showed a slow decay, suggesting that this type of channel may underlie the markedly slow decay of the macroscopic current in this phase. The second type (type-III) had more late openings than the type-I channel but fewer than the type-II channel.(ABSTRACT TRUNCATED AT 400 WORDS)

Inactivation kinetics of the sodium channel in the egg and the isolated, neurally differentiated blastomere of the ascidian

1. Inactivation kinetics of the sodium channel was compared between the egg-type channel in the egg cell and the differentiated-type channel in the cleavage-arrested, neurally differentiated blastomere of the ascidian. The techniques of the two-microelectrode voltage clamp and the cell-attached patch clamp were used. 2. In both types of channel, the time course of inactivation development obtained with a two-pulse protocol at potentials from -40 to -60 mV could be fitted with two exponentials with distinctive parameters. 3. The time course of recovery from inactivation at potentials more negative than -70 mV was compared between the two types of channel. At -80 to -120 mV, a delay of recovery was evident in the egg-type channel, whereas no delay was observed in the differentiated type. 4. In both types of channel, the two time constants of the inactivation of the macroscopic current, derived from the measurements of inward current, inactivation development and recovery from inactivation, had a bell-shaped voltage dependency. The fast time constants had a peak at -55 mV in the differentiated type and -70 mV in the egg type. The slow time constants had a peak around -60 mV in both types. 5. At the single-channel level, the averaged current from the differentiated-type channel showed both fast and slow decays. The frequency of late openings was higher in the differentiated-type channel than in the egg type. 6. The voltage dependence of the decay time constant and the carried charge in the summed current of the single-channel events was found to be shifted in the negative direction by 10-30 mV, compared with that of the macroscopic current. 7. The possibility that the higher frequency of late openings in the differentiated-type channel might be derived from delayed activation was excluded, since first-latency histograms of the single channel were not significantly different between the two types of channel.

Pharmacological characteristics of two different types of inhibitory GABA receptors on Achatina fulica neurones

GABA (gamma-aminobutyric acid) receptors of Achatina fulica neurones have been classified into two types associated with neuronal inhibition and one type with excitation. The pharmacological features of muscimol I and baclofen types associated with inhibition were investigated in this study. Activation of muscimol I type receptors on TAN (tonically autoactive neurone) by GABA, muscimol and trans-4-aminocrotonic acid (TACA) produced a transient outward current (Iout) with an increase in membrane conductance (g). Their relative potencies at GABA ED50 (approximately 10(-4) M) were: GABA: muscimol: TACA = 1:0.6:0.3. The relation between Iout and g increase (delta g) induced by various concentrations of these compounds was linear. The Hill coefficients for GABA were close to 1.0. The GABA effects were potentiated by pentobarbitone, antagonized competitively by pitrazepin and non-competitively by picrotoxin and diazepam, and unaffected by bicuculline. The reversal potentials of the effects of GABA, muscimol and TACA on TAN changed under various [Cl-]0 according to the Nernst equation for Ec1, but not under various [K+]0 and [Na+]0. Activation of baclofen type GABA receptors on RPeNLN (right pedal nerve large neurone) by GABA and (+/-)-baclofen produced a slow Iout with an increase in g. The two compounds were almost equipotent (ED50: approximately 3 x 10(-4) M). The relation between Iout and delta g produced by various concentrations was linear. The Hill coefficients for GABA were also close to 1.0. The reversal potentials of GABA and (+/-)-baclofen on RPeNLN changed under various [K+]0 according to the Nernst equation for EK, but not under various [Cl-]0 and [Na+]0. The two compounds hardly affected the voltage-gated and slowly inactivating calcium current. The Iout produced by GABA and (+/-)-baclofen was reduced by tetraethylammonium chloride, but was unaffected by 4-aminopyridine, bicuculline, pitrazepin and picrotoxin. In conclusion, the pharmacological features of muscimol I type GABA receptors are partly comparable to those of mammalian GABAA receptors, except for the influences of bicuculline and diazepam: the features of the baclofen type GABA receptor, which did not occur with muscimol I type receptors in the same neurone, were similar to those of GABAB.

Oxytocin-induced sodium current is mediated by cAMP-dependent protein phosphorylation in an identified snail neuron

The intracellular biochemical process underlying oxytocin-induced change of membrane properties was analyzed in an identified neuron of Achatina fulica Férussac, using pressure injection technique and pharmacological tools. Oxytocin dose-dependently enhanced the negative slope resistance (NSR) region on the current-voltage relation. The oxytocin-induced current was attenuated by a reduction of extracellular Na+ and not influenced by the addition of 100 microM tetrodotoxin (TTX) to the medium, suggesting that this current is predominantly due to the activation of TTX-resistant Na+ channels. In the Ca2(+)-free state, substituted by an equivalent amount of Co2+, the amplitude of oxytocin-induced current was somewhat reduced at the NSR region but it was not influenced at less than -60 mV. Application of 100 microM isobutylmethylxanthine, a phosphodiesterase inhibitor, augmented the oxytocin-induced current. Pressure injection of 10 mM adenosine 3',5'-cyclic monophosphate (cAMP) elicited a Na(+)-dependent inward current similar to the oxytocin response. The further role of cAMP linked with the oxytocin-induced current was investigated using two kinds of cAMP-dependent protein kinase inhibitors, isoquinolinesulfonamide (H-8) and protein kinase inhibitor (PKI). Extracellular application of H-8 or pressure injection of PKI, prior to oxytocin application, both blocked the oxytocin-induced current. Based on these results, oxytocin-elicited inward currents may mediate cAMP-dependent protein phosphorylation mainly by activation of Na+ channels.

Comparative study of d-diltiazem and its analogues as calcium antagonists in snail neurones

The blocking effects of d-diltiazem, its metabolites, deacetyl-d-diltiazem (d-M1), deacetyl-N-demethyl-d-diltiazem (d-M2), deacetyl-O-demethyl-d-diltiazem (d-M4) and deacetyl-N, O-demethyl-d-diltiazem (d-M6) and 1-diltiazem were investigated on the voltage-gated calcium current (ICa) of an Achatina neurone. Based on the IC50 values, the order of potency was: d-diltiazem (0.426 mM), d-M2 (0.456), d-M1 (0.491), 1-diltiazem (0.759) greater than d-M4 (1.212) greater than d-M6 (greater than 2.000). Assuming that the IC50 reflects the KD for resting Ca2+ channels (Kr), steady state activation studies gave KD values for the inactivated channels (Ki) and Kr/Ki ratios of 0.122 mM (Ki) and 3.52 (Kr/Ki) (d-diltiazem), 0.112 and 6.98 (1-diltiazem), 0.083 and 6.07 (d-M1) and 0.156 and 2.97 (d-M2). All drugs tested showed a certain degree of voltage-dependence. The further percentage reduction in the normalized ICa after high frequency stimulation demonstrated the use-dependence of: 1-diltiazem (27.5%), d-diltiazem (26.3) greater than d-M2 (19.2) greater than d-M1 (16.7) greater than d-M6 (9.8). The voltage- and use-dependence of these drugs are consistent with their Ca2+ antagonistic properties.

Effects of Mytilus inhibitory peptides on a giant neurone of Achatina fulica Férussac

Among several identifiable neurones of Achatina fulica Férussac, RAPN (right anterior pallial neurone) was sensitive to the two Mytilus inhibitory peptides (MIPs), H-Gly-Ser-Pro-Met-Phe-Val-NH2 ([Ser2]MIP) and H-Gly-Ala-Pro-Met-Phe-Val-NH2 ([Ala2]MIP), and their fragments, H-Pro-Met-Phe-Val-NH2 (MIP-(3-6)) and H-Met-Phe-Val-NH2 (MIP-(4-6)). These peptides, applied either locally by pneumatic pressure or in the bath, produced a slow outward current with an increase in membrane conductance. The other two related peptides, H-Gly-Ala-Pro-Met-Val-Phe-NH2 ([Ala2, Val5, Phe6]MIP-NH2) and H-Gly-Ala-Pro-Met-NH2 ([Ala2]MIP-(1-4)-NH2), were ineffective. The potency order of the four effective peptides was determined from their dose-response relations: [Ser2]MIP greater than [Ala2]MIP greater than MIP-(3-6) greater than MIP-(4-6). The ED50 of [Ser2]MIP was about 3 X 10(-5) M. Relations between the outward current (nA) and the conductance increase (microseconds) produced by the four peptides were quite linear (Y = 0.03416 X-0.01083, r = 0.98677). The reversal potentials for [Ser2]MIP (ES-MIP) measured with various extracellular K+ concentrations ([K+]0) were fitted to the Nernst equation, being identical with EK. ES-MIP was not affected by changing [Na+]0 and [Cl-]0.

Suppression of calcium current in a snail neurone by eperisone and its analogues

The effects of eperisone, tolperisone and isoperisone on the calcium current (ICa) were studied in an identified neurone of Achatina fulica under voltage clamping. At a holding voltage of -50 mV, these drugs inhibited ICa dose dependently without affecting activation time. Eperisone (IC50 = 0.348 mM) and isoperisone (0.226 mM) were significantly more effective than tolperisone (1.089 mM). Eperisone binds competitively with Ca2+ to the Ca2+ channels, based on its effects seen with various extracellular Ca2+ concentrations. The three drugs shifted the steady state inactivation curves in the hyperpolarizing direction. The mean dissociation constants for inactivated Ca2+ channels were calculated to be 0.070 mM (eperisone), 0.162 mM (tolperisone) and 0.014 mM (isoperisone). These values were much lower than their IC50 at Vh of -50 mV, which are reflected as the dissociation constants for resting Ca2+ channels. High frequency stimulation did not potentiate ICa suppression, suggesting that the drugs hardly bind to activated Ca2+ channels. These findings indicate that the selectivities of the Ca2+ channels to the drugs are in the order of their inactivated, resting and open states.

Ionic currents underlying the action potential of Rana pipiens oocytes

Ionic currents in immature, ovulated Rana pipiens oocytes (metaphase I) were studied using the voltage-clamp technique. At this stage of maturity the oocyte can produce action potentials in response to depolarizing current or as an "off response" to hyperpolarizing current. Reducing external Na+ to 1/10 normal (choline substituted) eliminated the action potentials and both the negative-slope region and zero-crossing of the I-V relation. Reducing external Cl- to 1/10 or 1/100 normal (methanesulfonate substituted) lengthened the action potential. The outward current was reduced and a net inward current was revealed. By changing external Na+, Cl-, and K+ concentrations and using blocking agents (SITS, TEA), three voltage- and time-dependent currents were identified, INa, IK and ICl. The Na+ current activated at about 0 mV and reversed at very positive values which decreased during maturation. Inward Na+ current produced the upstroke of the action potential. During each voltage-clamp step the Na+ current activated slowly (seconds) and did not inactivate within many minutes. The Na+ current was not blocked by TTX at micromolar concentrations. The K+ current was present only in the youngest oocytes. Because IK was superimposed on a large leakage current, it appeared to reverse at the resting potential. When leakage currents were subtracted, the reversal potential for IK was more negative than -110 mV in Ringer's solution. IK was outwardly rectifying and strongly activated above -50 mV. The outward K+ current produced an after hyperpolarization at the end of each action potential. IK was blocked completely and reversibly by 20 mM external TEA. The Cl- current activated at about +10 mV and was outwardly rectifying. ICl was blocked completely and reversibly by 400 microM SITS added to the bathing medium. This current helped repolarize the membrane following an action potential in the youngest oocytes and was the only repolarizing current in more mature oocytes that had lost IK. The total leakage current had an apparently linear I-V relation and was separated into two components: a Na+ current (IN) and a smaller component carried by as yet unidentified ions.