Extrasynaptic action of vasopressin,oxytocin, and vasotocin neuropeptides on electrically operated ionic channels at the mollusk neuronal membrane

Techniques of intracellular dialysis and neuronal perfusion in the visceral ganglion ofLymnaea stagnalis used during voltage-clamping at the neuronal membrane helped to ascertain that a concentration of 1×10^–16–1×10^–6 M neuroactive peptides (vasopressin, oxytocin, and vasotocin) alter the amplitude of electrically-operated transmembrane ionic currents considerably without affecting the kinetics of current activation and inactivation and surface potential at the membrane. The experimental conditions applying made it possible to record incoming sodium and calcium currents separated from each other as well as outward delayed and transient potassium currents. It was found that electrically-operated cerebral currents could either increase or decline in amplitude under the effects of peptides applied at different concentrations to the membrane of the same unit. Receptors of the peptides investigated in this study are thought to be located within the structure of electrically-operated channels at the neuronal membrane.A. I. Gertsen Teaching Institute, Leningrad. Translated from Neirofiziologiya, Vol. 22, No. 4, pp. 526–533, July–August, 1990.     

The early phase of sodium channel gating current in the squid giant axon

A fast component of displacement current which accompanies the sodium channel gating current has been recorded from the membrane of the giant axon of the squid Loligo forbesii. This component is characterized by relaxation time constants typically shorter than 25 µs. The charge displaced accounts for about 10% (or 2 nC/cm²) of the total displacement charge attributed to voltage-dependent sodium channels. Using a low noise, wide-band voltage clamp system and specially designed voltage step protocols we could demonstrate that this component: (i) is not a recording artifact; (ii) is kinetically independent from the sodium channel activation and inactivation processes; (iii) can account for a significant fraction of the initial amplitude of recorded displacement current and (iv) has a steady state charge transfer which saturates for membrane potentials above + 20 mV and below – 100 mV This component can be modelled as a single step transition using the Eyring-Boltzmann formalism with a quantal charge of 1 e^– and an asymmetrical energy barrier. Furthermore, if it were associated with the squid sodium channel, our data would suggest one fast transition per channel. A possible role as a sodium channel activation trigger, which would still be consistent with kinetic independence, is discussed. Despite uncertainties about its origin, the property of kinetic independence allows subtraction of this component from the total displacement current to reveal a rising phase in the early time course of the remaining current. This will have to be taken into account when modelling the voltage-dependent sodium channel.     

Interaction between sea anemone toxin BgTX8 and ionic channels of neurons isolated from mammals

The action of the toxin BgTX₈ separated from the sea actiniaBunodosoma granolifera on transient tetrodotoxin-sensitive sodium and outward potassium currents of units isolated from rat sensory ganglia was investigated using techniques of voltage clamping at the membrane and intracellular perfusion. It was found that BgTX₈ decelerates the inactivation kinetics but has little effect on activation kinetics of sodium current. At the same time, a 5–10% increase in the amplitude of inward current was often observed at holding potentials of about –100 to –120 mV at the membrane. The dissociation constant of the receptor-toxin equals 4×10^–6 M and is adequately described by Langmuir's isotherm. It was also established that intracellular perfusion of neurons with anemone toxin-containing solution leads to a reduction in the amplitude of sodium current and decelerates its inactivation process. Suppression of outward potassium current was also noted.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Institute of Brain Research, Academy of Sciences, Havana, Cuba. Translated from Neirofiziologiya, Vol. 20, No. 1, pp. 32–37, January–February, 1988.     

Selectivity of edta-modified calcium channels to monovalent cations

The characteristics of slow inward sodium currents arising in response to membrane depolarization were studied in experiments on isolated dialyzed neurons of the snailHelix pomatia when the calcium-chelating agent EDTA was added to the calcium-free external solution. Values of the relative permeability of the corresponding ionic channels, determined from the shift of the equilibrium potential, were: P_Na+:P_Li+: +=1.00:0.80:0.55:0.21. The ratio between these values for "fast" sodium channels was 1.00:1.04:0.44:0.19. The induced sodium current was blocked by D-600 and nifedipine, which block calcium channels, more effectively than the calcium current of the same membrane (the corresponding dissociation constants were 10^–5 and 0.8·10^–5 mole/liter for the induced sodium current compared with 2.6·10^–5 and 2.3·10^–5 mole/liter for the calcium current). It is postulated on the basis of these data that the calcium channels have a principal selective filter similar to that of sodium channels, but also an additional binding site for bivalent cations, which prevents entry of monovalent cations into the channel. The addition of calcium-chelating agents to the calcium-free external solution liberates this site and thereby modifies the calcium channel into a sodium channel.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 14, No. 5, pp. 491–498, September–October, 1982.     

Voltage-gated ion channels of inflowing current expressed in Xenopus oocytes after injection of rat brain mRNA

The expression of two types of voltage-gated ion channels of the inflowing current ("fast" sodium channels, sensitive to tetrodotoxin, and high-threshold calcium channels) was detected by electrophysiological methods in the membrane ofXenopus oocytes, after injection of poly(A)⁺-mRNA from the brains of 18- to 20-day-old rats. When Cd²⁺ (200 µmoles/liter) was added to the extracellular solution, the barium current through the expressed calcium channels was completely suppressed, but no sensitivity to D-600 (20 µmoles/liter) and nitrendipine (50 µmoles/liter) was exhibited. A peptide blocker of the high-threshold calcium channels of the neuron membrane, -conotoxin GVIA, in a concentration of 1 µmole/liter led to 20–40 min suppression of the barium current expressed in the oocyte. Steady-state inactivation of this current could be described by the Boltzman formula, using the values of the half-inactivation potential V_1/2=–50 mV and the steepness factor k=14 mV. It is concluded that in potential-dependent and pharmacological properties, the calcium channels expressed in the oocyte, despite the absence of any appreciable time-dependent inactivation, most resemble the high-threshold inactivatable (HTI- or N-type) calcium channels of the neuron membrane.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 23, No. 3, pp. 344–353, May–June, 1991.     

Two calcium currents in the somatic membrane of mollusc neurons

Two new types of calcium channels were discovered during research in ionic currents in the somatic membrane ofHelix pomatia neurons, using an intracellular perfusion technique. Apart from the principal calcium current described in the literature with a holding potential of about –110 mV, an additional calcium current was observed activated at depolarizations of –40 to –80 mV and was not reduced when the cell was perfused with solutions containing fluoride anions. The kinetics of this current were well described in the context of the Hodgkin and Huxley model with a time constant of activation of 6–8 msec and of inactivation of 300–600 msec. It increased in amplitude as the Ca⁺⁺ rose in the cellular environment but was reduced by extracellular addition of the Ca⁺⁺ antagonists Co⁺⁺, Ni⁺⁺, and Cd⁺⁺, and the organic blockers nifedipine and verapamil. The association constants of these substances with corresponding channels determined from the maximum of the current-voltage relationship were 2 (Ca⁺⁺), 3 (Co⁺⁺), 0.06 (nifedipine), and 0.2 mM (verapamil). The properties detected in this component of calcium conductance are compared with those of calcium channels in other excitatory formations and its possible functional role is discussed.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 17, No. 5, pp. 627–633, September–October, 1985.     

Action of calcium on the somatic membrane of mollusk giant neurons

Early membrane currents of the isolated neuron soma of the mollusksHelix pomatia,Limnaea stagnalis, andPlanorbis corneus in normal and sodium-free solutions differing in their calcium ion concentration were investigated by the voltage clamp method. The early inward current was shown to continue when the sodium ions in the external solution were replaced by an equivalent number of calcium ions and to be increased with an increase in the concentration of those ions in all neurons of these mollusks investigated. A change in the calcium concentration in the external solution shifted the inactivation curves and also the curves of conductance for the inward current along the potential axis. It is concluded that a system of calcium channels exists in the somatic membrane of neurons in these species of mollusks.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 5, No. 6, pp. 621–627, November–December, 1973.     

Ionic mechanisms underlying modulating effects of serotonin on acetylcholine-induced responses in Helix pomatia neurons

The ionic mechanisms underlying modulatory effects of serotonin on acetylcholine-response in identified and nonidentifiedHelix pomatia neurons were investigated using voltage-clamping techniques at the neuronal membrane. External application of 10^–5–10^–4 M serotonin to the membrane of neurons responding to application of acetylcholine depending on Na⁺ depolarization (D_Na response) reduced membrane conductivity during response to acetylcholine without changing reversal potential of acetylcholine-induced current. Acetylcholine (10^–6–10^–4 M) administration took place 1–3 min later. Neurons with response to acetylcholine application dependent on Cl⁺ depolarization (D_Cl response) or hyperpolarization (H_Cl response) behaved similarly. Analogous effects could be produced by external application of theophylline which, together with the latency and residual effect characteristic of serotonin action points to the participation of intracellular processes associated with the cellular cyclase system in the changes produced by serotonin in acetylcholineinduced response. Serotonin brought about a shift in reversal potential and an increase in the acetylcholine-induced current in those neurons where this response was associated with changed permeability at the membrane to certain types of ions. During two-stage acetylcholine-induced response of the D_Na-H_K type, serotonin inhibited the inward current stage. Mechanisms underlying modulatory serotonin action on acetylcholine-induced response in test neurons are discussed in the light of our findings.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 20, No. 1, pp. 57–64, January–February, 1988.     

Mechanisms of generation of long action potentials in barium solutions

Under voltage clamp conditions ionic currents of neurons of the molluskHelix were studied in solutions containing barium ions. Replacement of the calcium ions in the normal external solution by barium ions led to displacement of the potassium conductivity versus membrane potential curve along the voltage axis toward more positive potentials and also to a decrease in the limiting value of the potassium conductance of the membrane. In sodium- and calcium-free solutions containing barium ions two fractions of the inward current are recorded: quickly (I) and slowly (II) inactivated. The rates of activation of these fractions are comparable. Barium ions are regarded as carriers of both fractions of the inward current. It is postulated that both fractions of the barium current are carried along the calcium channels of the membrane.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 9, No. 4, pp. 408–414, July–August, 1977.     

Influence of magnetic fields on the P-870 triplet state in Rps. sphaeroides reaction centers

Magnetic fields influence two properties of the P-870 triplet state observed in Rps. sphaeroides reaction centers: the yield of formation and the kinetics of decay. These effects have been studied in reaction centers which were prepared in three different states: state Q_A ^–, state Q_A ^2– and state (– Q_A) (Q_A depleted). The triplet yields decrease with increasing magnetic fields, with B1/2's of about 140, 41 and 57 Gauss, respectively. The half-time of ³P-870 decay is not influenced by the field in state Q_A ^–; it increases at increasing fields, in state Q_A ^2– and state (– Q_A), with the same B1/2 as the triplet yield. These results are discussed in the framework of current theories of the radical-pair dynamics and of the mechanism of triplet decay.Abbreviations I primary electron acceptor - LDAO lauryldimethylamine oxide - P-870 primary electron donor - Q_A first quinone acceptor - SDS sodium dodecylsulfate - YAG Yttrium Aluminum Garnet     

Blocking action of calmidazolium and chlorpromazine on outward potassium current dependent on extra-cellular calcium ions

The effects of the calmodulin antagonists, calmidazolium (R 24571) and chlorpromazine on delayed outward potassium current at the somatic membrane were investigated in non-identified intracellularly perfused neurons isolated fromHelix pomatia. Voltage was clamped at the membrane. Extracellular application of these substances produced effective depression of the outward current. This effect even occurred at test substance concentrations of 10^–9–10^–8 M. Block-ade of delayed outward current was produced mainly as a result of suppressing the potassium current component dependent on intracellular potassium ions (I_k(Ca/in)). The possibility that the receptor for intracellular calcium responsible for modulating this current may be of a calmodulin-like nature is discussed.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 19, No. 3, pp. 356–361, May–June, 1987.     

Voltage-dependent potassium channels in the molluscan neuron somatic membrane

Under voltage clamp conditions proof of the presence of two populations of potassium current channels was obtained on the molluscan neuron somatic membrane: inactivated and uninactivated. They differ from each other in their physicochemical characteristics, the property of their gating mechanisms, and the molecular structure of their current-conducting part. The inactivated potassium current is largely and selectively inhibited by cooling. Channels of the fast potassium current also are highly sensitive to temperature changes. By using parameters of gating mechanisms of the "fast" potassium channels included in the Hodgkin-Huxley model, the physicochemical properties of channels of this type were described. The density of fixd negative surface charges on the somatic membrane in the region of localization of fast potassium channels was estimated with the aid of the Gouy-Chapman theory. It is 0.3 electron charge/nm². Data on the character of interaction of potassium channels with intracellular sodium ions revealed differences in the structure of the current-conducting part of different types of potassium channels. Experiments on intracellularly perfused molluscan neurons demonstrated the particular features of interaction between intracellular calcium ions and calcium-activated channels under conditions of strictly controlled changes in the intracellular calcium concentration.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 16, No. 3, pp. 296–307, May–June, 1984.     

Action of neurotoxin from the sea anemoneHomostichanthus duerdemi on inward sodium current in mammalian neurons

The action of purified toxin from the sea anemoneHomostichanthus duerdemi (HTX-1) on the inward sodium current was studied in experiments on isolated neurons from rat spinal ganglia and neuroblastoma cells of clone N-18F1, by an intracellular perfusion and voltage clamp method. HTX-1 was found to delay inactivation of the tetrodotoxin-(TTX-)sensitive inward sodium current and to make it incomplete, but virtually without affecting its activation. The relationship between the fraction of sodium channels modified by the toxin and the HTX-1 concentration is described by a Langmuir isotherm with association constant of (1.1 ± 0.1)·10^–7 M (holding potential –100 mV). Under the influence of the toxin the peak inward sodium current was increased by about 80%. Binding of HTX-1 with TTX-sensitive sodium channels is distinguished by strong potential-dependence: at a holding membrane potential of 0 mV the binding constant was an order of magnitude less than at a potential of –100 mV. In the case of brief action of HTX-1 on the nerve cell membrane (under 5 min) the effect of the toxin was completely reversible, but if the time of action of HTX-1 exceeded 30 min, subsequent washing with normal solution for 90 min did not abolish the effect completely.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Pacific Institute of Bioorganic Chemistry, Far Eastern Scientific Center, Academy of Sciences of the USSR, Vladivostok. Translated from Neirofiziologiya, Vol. 14, No. 4, pp. 402–409, July–August, 1982.     

Separation of sodium and calcium channels in the surface membrane of molluscan nerve cells

By intracellular dialysis of isolated neurons of the mollusksHelix pomatia andLimnaea stagnalis and by a voltage clamp technique the characteristics of transmembrane ionic currents were studied during controlled changes in the ionic composition of the extracellular and intracellular medium. By replacing the intracellular potassium ions by Tris ions, functional blocking of the outward potassium currents was achieved and the inward current distinguished in a pure form. Replacement of Ringer's solution in the extracellular medium with sodium-free or calcium-free solution enabled the inward current to be separated into two additive components, one carried by sodium ions, the other by calcium ions. Sodium and calcium inward currents were found to have different kinetics and different potential-dependence: _mNa=1±0.5 msec, _mCa=3±1 msec, _hNa=8±2 msec, _hCa=115±10 msec (V_m=0), G_Na=0.5 (V_m=–21±2 mV), G_Ca=0.5 (V_m=–8±2 mV). Both currents remained unchanged by tetrodotoxin, but the calcium current was specifically blocked by cadmium ions (2·10^–3 M), verapamil, and D=600, and also by fluorine ions if injected intracellularly. All these results are regarded as evidence that the soma membrane of the neurons tested possesses separate systems of sodium and calcium ion-conducting channels. Quantitative differences are observed in the relative importance of the systems of sodium and calcium channels in different species of mollusks.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 8, No. 2, pp. 183–191, March–April, 1976.     

Changes in the ionic mechanisms of electrical excitability in the somatic membrane of rat dorsal root ganglion neurons during ontogenesis. Correlations between inward current densities

Correlations between densities of various types of inward currents in the somatic membrane of dorsal root ganglion neurons were studied in three different rat age groups: 5–9 days, 45 days, and 90 days. A linear relationship was found in neurons with "slow" tetrodotoxin-sensitive sodium current between the densities of high-threshold calcium current and "slow" sodium current (Bravias-Pearson's correlation coefficient: r=0.84 and 0.70 for n₁=16 and n₂=28, respectively). No such correlation was observed in neurons with low-threshold calcium inward current. Cells with only two types of channel — "fast" sodium and high-threshold calcium — present in their somatic membrane manifested an inverse correlation (r=–0.48, where n₄=95) between the densities of transmembrane currents passing through these channels. No inverse relationship was observed in the density of "fast" sodium and high-threshold calcium currents in neurons with tetradotoxinresistant "slow" sodium and/or low threshold calcium channels.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 18, No. 6, pp. 820–827, November–December, 1986.     

Argiopine,argiopinines, and pseudoargiopinines as glutamate receptor blockers in hippocampal neurons

A homologous set of low-molecular weight compounds selectively blocking ionic currents were purified from venom from the spiderArgiope lobata with a selective blocking action on ionic currents activated by applying glutamate and its agonist kainic acid (KA) to the membrane of neurons isolated from the rat hippocampus. Three groups of these compounds — argiopine, argiopinines, and pseudoargiopinines, produced voltage-dependent glutamate- and KA-activated ionic currents at concentrations of 10^–6-10^–4 M, interacting primarily with agonist-activated ionic channels without affecting K_d values of the agonist. The blocking action could be partially reversed by argiopine application but only slightly when argiopinines and pseudoargiopinines were used. Kinetics of toxin effects on Ka-activated ionic currents showed at least two exponential components with different time constants. Simple and reversed rate constants of interaction between toxins and ionic channels were estimated from the plot of the kinetics of ionic current blockade and recovery against toxin concentration. Argiopine, argiopinines, and pseudoargiopinines lend themselves to further research into glutamate receptors of the mammalian CNS employing electrophysiological and biochemical techniques.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev, M. M. Shemyakin Institute of Bioorganic Chemistry, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 21, No. 6, pp. 748–756, November–December, 1989.     

Single potassium channel of anomalous (inward) rectification in mollusk neurons

Currents passing through individual potassium channels with anomalous (inward) rectification were recorded at the neuronal membrane ofPlanorbarius corneus using the patch clamp technique. These currents could be detected, whether in "right side out" or "inside out" configurations in the presence of 50 mM potassium ions or one of the potassium channel blockers: tetraethylammonium (TEA), barium, or cesium (2–20 mM) on the external side of the membrane. Inward currents were observed in individual channels at potentials more negative than level of potassium equilibrium potential (E_k); conductance of these measured 81±12 pS (n=11). At more positive potentials than E_k, conductance fell to zero. Potassium channels with anomalous (inward) rectification inPlanorbarius corneus resemble equivalent channels in other cells in their kinetics: time scale of the open state may be described by a single exponential function. This would imply that the ionic channel has a single open state. Time scale of the closed state was biexponential, thus indicating the possible existence of two kinetically different nonconducting states of the potassium channel with anomalous (inward) rectification at the neuronal membrane ofPlanorbarius corneus.I. M. Sechenov Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 21, No. 1, pp. 31–38, January–February, 1989.     

Cation stimulation of the proton-translocating redox activity at the plasmalemma of Catharanthus roseus cells

Cultured Catharanthus roseus cells exhibit transmembrane ferricyanide reduction through a plasma membrane redox system which may be associated with proton translocation. Evidence shows that endogenous pyridine nucleotides serve as hydrogen donors for the reaction. The proton translocating function of the redox system is confirmed, in intact cells and isolated protoplasts, by the ability of Ca²⁺ and other cations to increase both the redox activity and the efflux of protons. The role of the cations is seen to be not a simple general charge screening phenomenon as already described. By using ionic surfactants (CP⁺, SDS^–) it was shown that the net surface charge of the membrane can interact in the activation process via a cation attraction effect. It is proposed that specific binding of cations to the plasma membrane could alter the conformation of the redox system facilitating its interaction with NADH.Abbreviations CP⁺ cetylpyridinium - EGTA ethylene glycol bis (-aminoethyl)-N,N-tetraacetic acid - FeCN potassium ferricyanide - SDS^– sodium dodecyl sulfate - SHAM salicylhydroxamic acid     

Stimulation of neuronal calcium conductance by parathyroid hormone

The effects of 10^–10–10^–5 M parathyroid hormone (PTH) on voltage-dependent potassium channels at theHelix pomatia neuronal membrane were investigated in voltage-clamped experiments using intracellular perfusion techniques. The hormone was found to produce a 2-stage effect on calcium current (I_Ca). The initial, brief stage of PTH action consisted of a minor (7–10%) increase in I_Ca and was partially reversible. This was followed by the second (slow) stage, developing for 60–70 min, whereupon level of I_Ca doubled. This hormonal action was not easily reversed and did not occur unless the intracellular solution contained ATP or the hormone was applied after perfusing the cell. Introducing 10 mM EDTA into the perfusate induced a considerable decline in PTH effects. Adding concentrations of 100 and 60 µM of exogenous cAMP and cGMP, respectively, did not imitate the action of this hormone. The first-mentioned effect is thought to be produced by indirect PTH action on channel protein or structures closely associated with the channel and the second by metabolic processes, possibly the phosphoinositide pathway of signal transmission.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Medical Institute, Erevan. Translated from Neirofiziologiya, Vol. 22, No. 3, pp. 373–380, May–June, 1990.     

Participation of the adenylate cyclase system in the postsynaptic mechanism of heterosynaptic facilitation

In an analysis of the postsynaptic mechanism of heterosynaptic facilitation, changes in the amplitude of the excitatory postsynaptic current (EPSC) and the current evoked by application of acetylcholine (ACh current), acting on the adenylate cyclase system of the LC-1 and RC-1 neurons of the molluskPlanorbis corneus, were compared. Both responses are n-cholinergic and depend on the membrane conductivity for Na⁺ and K⁺. Application of serotonin led to a 100–300% increase in the amplitude of the EPSC and (in most cases) the ACh current. However, in 30% of the cases, the increase in the EPSC was accompanied by a decrease in the ACh current. This is probably due to the different contributions of Na⁺ and K⁺ to the mechanism of activation of the conductivity of th channel-receptor complex of the nonsynaptic cell membrane. The influence of serotonin on the EPSC and ACh current was simulated by the action of phosphodiesterase blockers and adenylate cyclase activators. Phosphodiesterase activators and protein kinase blockers reversibly inhibited the EPSC and ACh current. Thus, activation of the adenylate cyclase system, mediated by the action of serotonin, promotes the development of a postsynaptic mechanism of formation of heterosynaptic facilitation of the EPSC in the command neurons of the mollusk.A. A. Bogomolets Institute of Physiology, Ukrainian Academy of Sciences, Kiev. Translated from Neirofiziologiya, Vol. 23, No. 6, pp. 676–683, November–December, 1991.