Monosynaptic pathway responsible for generation of bursting activity in theHelix pomatia RPal neuron

The connection between a visceral ganglia interneuron initiating bursting pacemaker activity in the RPal neuron and the RPal neuron itself was investigated inHelix pomatia. Stimulating the interneuron either initiated or intensified bursting activity in the RPal neuron, depending on initial electrical activity in this cell. Replacing calcium with magnesium ions in the extracellular fluid and adding CdCl₂ to this fluid reversibly inhibited the effect of interneuronal stimulation on the RPal neuron. The latter effect was unaffected by increasing the concentration of extracellular Ca²⁺ 10 to 70 mM. Intracellular injection of both Cs⁺ and TEA into the interneuron produced an increase in the duration of its action potentials and rendered the link connecting the neurons more effective. It is deduced that a monosynaptic chemical connection exists between the interneuron and the RPal neuron for which a peptide compound serves as transmitter.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 19, No. 1, pp. 20–28, January–February, 1987.     

A study of the connection between the interneuron initiating pacemaker activity in a bursting neuron and the bursting neuron of the snailHelix pomatia

The connection between an interneuron initiating pacemaker activity in the bursting RPa1 neuron and the bursting neuron itself (Pin and Gola, 1983) has been analyzed in the snail Helix pomatia. Prolonged depolarization of the interneuronal membrane produced in it a series of action potentials as well as a parallel initiation or enhancement of bursting activity in the RPa1 neuron. If the discharge in the interneuron was evoked by short current pulses of threshold amplitude, no bursting activity was seen in the RPa1 neuron. However, short stimuli delivered on the background of subthreshold depolarization of the interneuronal membrane produced bursting activity in the RPa1 neuron. Under voltage-clamp conditions a slow inward current could be recorded in the RPa1 neuronal membrane after stimulation of the interneuron with a latency of about 2 sec. Short shifts of the holding potential in the hyperpolarizing direction at the maximum of this current produced a transient outward current. Replacement of extracellular Ca2+ by Mg2+ ions, as well as addition of 1 mM CdCl2 to the external solution, prevented the response to the interneuronal stimulation in the RPa1 neuron. Electron microscopic investigation of the interneuron has shown the abundance of Golgi complexes in its cytoplasm with electron-dense granules in their vicinity. It is concluded that the connection between the interneuron and the bursting neuron is of chemical origin, based on secretion by the former of some substances which activate at least two types of ionic channels in the membrane of the RPa1 neuron.     

Isolation of a peptide initiating bursting activity in an identifiedHelix pomatia neuron

A peptide initiating bursting activity when applied to the soma of identified neuron RPal ofHelix pomatia (if such activity was absent) or increasing the amplitude of waves of membrane potential (if it was low), was isolated from the water-soluble fraction of brain homogenate. Application of the peptide and of the original material for its isolation (the water-soluble fraction of snail brain homogenate) evoked identical changes in the character of electrical activity of neuron RPal. It is concluded from the experimental results that the isolated protein possesses a specific action, qualitatively different from that of other known peptides, on this neuron and is the active principle of the modulating factor described previously. It is postulated that under natural conditions the modulating factor is secreted by an unidentified peptidergic interneuron in the region of axo-somatic synapses, evoking bursting activity in neuron RPal.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 16, No. 4, pp. 488–492, July–August, 1984.     

Modulation of electrical activity of neuron RPal ofHelix pomatia

Changes in the types of electrical activity of bursting neuron RPal ofHelix pomatia were studied. Neuron RPal may either be "silent" or may exhibit bursting activity with waves of membrane potential of low and high amplitude. Changes in activity of this neuron took place spontaneously over a period of tens or hundreds of seconds. Changes in electrical activity in neuron RPal were synchronized with changes in membrane potential in other neurons. Similar changes in electrical activity of neuron RPal can be produced by application of the water-soluble fraction from snail ganglion homogenate, containing "modulating factor," to the soma. It is suggested that the prolonged changes in electrical activity of neuron RPal described above are connected with the action of compounds resembling neurotransmitters or neurohormones, and secreted by other neurons, on it. These compounds reach the neuron continuously or they are bound with the receptors of the neuron for a long enough period of time to produce stationary changes in its membrane conductance.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 13, No. 4, pp. 398–405, July–August, 1981.     

Simulation of mechanisms responsible for initiation and modulation of bursting activity in RPa1 neuron of theHelix snail

A mathematical model of bursting activity in the RPa1 neuron of theHelix snail has been developed. The model allowed us to describe the processes of initiation and augmentation of the bursting activity related to transient secretion of a modulatory factor. Based on the analysis of computer simulations of various mechanisms underlying the effect of a modulating factor on the ionic membrane conductances in the bursting neuron, we suggested that modulating factor evokes a transition of non-voltage-dependent sodium channels and hyperpolarization-activated outward current channels to an active state and influences the gating of voltage-dependent sodium channels.Neirofiziologiya/Neurophysiology, Vol. 27, No. 1, pp. 11–17, January–February, 1995.     

Simulation of bursting activity in theHelix RPa1 neuron: Role of calcium ions

A model of bursting activity in the RPal neuron of the snailHelix pomatia has been developed. In this model, calcium conductances do not play a key role in generation of slow oscillations of membrane potential (MP). The possibility of simulating the maintenance of bursting in the presence of cadmium ions is shown. Inclusion in the model of the calcium-inactivated calcium conductance makes it possible to reproduce both adaptation of the neuron to constant polarizing current, which modifies bursting, and the development of slow inward current when MP is clamped at different phases at the slow wave. In our simulations, the characteristic properties of bursts (such as an increase in the frequency of action potentials and a decrease in spike undershoot at the beginning of a burst) are due to the cumulative inactivation of potassium current. The advantages of the presented mathematical model of bursting compared with other models are discussed.Neirofiziologiya/Neurophysiology, Vol. 26, No. 5, pp. 373–381, September–October, 1994.     

Modulation of endogenous bursting pacemaker activity in a Helix pomatia neuron

Considerable membrane depolarization was shown to arise periodically, at intervals of up to a few minutes, in the PPa1 bursting neuron ofHelix pomatia. Pulses of slow depolarizing current were found by the voltage clamping method. The frequency of the pulses was independent of the holding potential. The equilibrium potential for the slow depolarizing current was about 45 mV. During development of the depolarizing current a region of negative conductivity was observed on the steady-state voltage-current characteristic curve of the membrane. It is suggested that the pulses of slow depolarizing current are associated with the presence of secretory connections between the molluscan neurons.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 9, No. 6, pp. 606–612, November–December, 1977.     

Effect of theophylline on electrical activity of bursting type in an identified Helix pomatia neuron

The effect of theophylline, an inhibitor of cyclic nucleotide phosphodiesterase, on electrical activity of bursting neuron RPa1 ofHelix pomatia was investigated. In a concentration of 1 mM theophylline, when added to the external solution, increases the frequency and number of action potentials in the burst and also the duration of the inter-burst interval and the amplitude of membrane potential waves. In concentrations of 2.5 and 5.0 mM theophylline leads to reversible inhibition of bursting activity. During rinsing this activity rises to a higher level and then returns to the original value. The action of theophylline develops and disappears (as a result of rinsing) in the course of 1–5 min, depending on concentration of the inhibitor. It is suggested that electrical activity of the molluscan bursting neuron is controlled through the cyclic nucleotide system.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 13, No. 1, pp. 75–79, January–February, 1981.     

Investigations of the ionic mechanisms of bursting activity in Helix pomatia neurons

Steady-state current-voltage characteristics of the membrane and ionic currents arising during changes in membrane potential in bursting neurons ofHelix pomatia were studied by the voltage clamp method. The steady-state current-voltage characteristics of the membrane were shown to have a nonlinear region. Replacement of sodium ions by Tris-HC1 ions in the external solution completely abolishes this nonlinearity. Hyperpolarization of the membrane under voltage clamp conditions leads to the development of an outward current which reaches a maximum and then is inactivated. This current has a reversal potential in the region of the potassium equilibrium potential. Depolarization of the membrane to the threshold value for excitation of uncontrollable regions of the axon hillock causes the appearance of a slow inward current. After reaching a maximum, the inward current falls to zero. A model of generation of waves in a bursting neuron is suggested.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 10, No. 2, pp. 193–202, March–April, 1978.     

Possible interaction between synaptic and pacemaker mechanisms of electrical activity in bursting neurons of Helix pomatia

Membrane hyperpolarization induced by short pulses of inward current, by stimulation of the anal nerve, which leads to the appearance of a long IPSP in the neuron, and developing during the appearance of spontaneous IPSPs in the neuron was investigated in neuron RPa1 ofHelix pomatia. Short-term hyperpolarization of the neuron membrane by an inward current (10 msec) led to the development of self-maintained (regenerative) membrane hyperpolarization lasting several seconds. The amplitude and duration of regenerative hyperpolarization increased with an increase in amplitude and duration of the pulse of inward current. The time course of IPSPs arising spontaneously in the neuron and in response to stimulation of the anal nerve was similar to that of regenerative hyperpolarization evoked by a pulse of inward current. It is suggested that regenerative hyperpolarization associated with activation of endogenous mechanisms of regulation of the bursting activity of the neuron may be due not only to short-term membrane hyperpolarization of the test neuron by the electric current, but also to hyperpolarization occurring during IPSP generation.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 13, No. 1, pp. 67–74, January–February, 1981.     

Effect of cadmium ions on bursting electrical activity of an identified snail neuron

The effect of cadmium ions, a specific blocker of the inward calcium current in molluscan neurons, on electrical activity of identified neuron RPal ofHelix pomatia was studied. Cadmium ions in a concentration of 1 mM were shown to block bursting activity of the neuron completely. The membrane potential increased under these circumstances to about ?65 mV. After rinsing out the cadmium ions electrical activity in the neuron was fully restored. If a modulating factor (a peptide fraction obtained from the water-soluble part of snail brain homogenate) was added to the solution containing cadmium ions, however, not only was bursting activity not blocked, but it was actually intensified. Addition of modulating factor to the solution after blocking induced by cadmium ions led to the reappearance of bursting activity if not more than a few tens of seconds had elapsed after blocking developed. As the time after the beginning of blocking increased, addition of the modulating factor became less effective and caused only rhythmic activity to develop. It was concluded from the results of these experiments that bursting activity of neuron RPal is not endogenous but is induced in it by a modulating factor secreted by an unidentified peptidergic interneuron. Calcium ions do not play an essential role in the generation of slow depolarization waves in the neuron under these circumstances but they are essential for secretion of the modulating factor.     

Modulation of electrical activity of neuron RPa2 ofHelix pomatia

Neuron RPa2 ofHelix pomatia can generate rhythmic (beating) or periodic (bursting) activity. A spontaneous switch from beating to bursting activity takes place in the course of tens of minutes. Similar changes in electrical activity can be induced by the addition of the water-soluble fraction obtained from a homogenate of snail ganglia to the experimental chamber. Artificial polarization of the membrane of neuron RPa2 by asteady inward current leads to an increase in the duration of intervals between bursts and to a decrease in the number of action potentials in the burst. With an increase in amplitude of the polarizing current, action potential generation ceases completely, but generation of waves of membrane potential persists. If the voltage on the neuron membrane is clamped, periodic fluctuations of membrane current disappear. It is suggested that action potential generation by neurons RPa2 is determined by the properties of the potential-dependent conductance of its membrane, i.e., that it is endogenous in origin and can be regulated by compounds acting on the membrane. These compounds, secreted by other neurons, resemble neurotransmitters or neurohormones.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 13, No. 4, pp. 406–412, July–August, 1981.     

The axosomatic contacts on the bursting neuron of the snailHelix pomatia. II. ultrastructural localization of adenylate cyclase

Fluoride and peptide-stimulated adenylate cyclase activity was investigated by electron histochemistry on serial sections of the RPAI neuron of the snail Helix pomatia. Fluoride-stimulated adenylate cyclase was detected in the surface membrane of the RPAI neuron, the postsynaptic membrane of axosomatic contacts, and the surface of glial cells forming a multilayer capsule around the neuron. Peptide-stimulated adenylate cyclase was located in the membrane of glial cells surrounding the neuron, their processes (trophospongia) invaginating deeply in the neuronal soma, and the membrane of somatic protrusions forming the system of lacoons in the region of the axosomatic contact. No peptide-stimulated adenylate cyclase was revealed in the remaining part of the surface of the somatic membrane. The localization of adenylate cyclase activity in the postsynaptic membrane in the region of the axosomatic contact is in accordance with the hypothesis based on electrophysiological experiments that the cyclase system participates in the genesis and regulation of the bursting activity of the RPAI neuron.     

The axosomatic contacts on the bursting neuron of the snailHelix pomatia. I. ultrastructural features of the axosomatic contacts

The analysis of serial ultrathin sections of the RPAI bursting neuron of the snail Helix pomatia reveals the presence of axosomatic contacts on its surface membrane. These contacts have a number of specific features: the presynaptic axon contains synaptic vesicles and electron-dense granules, typical of peptidergic terminals; the terminal part of the axon forms many finger-like processes which invaginate the neuronal soma; the width of the cleft (80 nm) in the area of the contact is larger than that in usual synaptic contacts; and there is a system of lacoons in the region of the axosomatic contact; this system is formed by protrusions of the soma and it accompanies the contact along its extent. It is suggested that the system of lacoons which communicates with the space between the terminal and the soma may serve as a ramified synaptic cleft into which the secretion from the terminal is released. This system may contribute to a considerable prolongation of the time of action of the secretory product on the membrane of the RPAI neuron.     

Possible mechanisms of the anterior limbic cortex influence on the neuron activity of the vago-solitary complex

In ananesthetized cats, neurons of the nucleus of the tractus solitarius (NTS) and the dorsal motor nucleus of the vagus nerve (DMNV) revealed phasic excitatory responses to separate single vagal and cortical stimuli. Stimulation of the anterior limbic cortex combined with vagal stimulation resulted in inhibitory or excitatory modification of the vagal induced responses of the NTS and DMNV neurons. The data obtained suggest that complete inhibitory effects are related to general cortical mechanisms of control of the functional state of the brain stem visceral neurons. Selective inhibition of the vagal induced responses by limbic cortex stimulation is due to particular cortical mechanisms of the visceral sensory transmission control via the NTS neurons.     

Dissociation of Helix pomatia haemocyanin under the influence of alkali salts

The dissociation into halves of the α-component of Helix pomatia haemocyanin was investigated by light scattering and ultracentrifugation. Within the normal pH-stability region, a dissociation into halves can be obtained with alkali chlorides. This dissociation levels off at a salt concentration of 1 m. In contrast with the pH-induced dissociation, this process is both completely reversible and rapid.A study with different alkali halidea and other salts reveala the dissociation to be caused by the anions and not merely by an effect of the ionic strength. For some salts a dissociation into tenths and 20ths is found. The sequence of efficiency of the anions is practically that of the chaotropic ions (anions that favour the transfer of apolar groups to water). The effect of other parameters which influence the process is studied. The dependence on protein concentration is much smaller than expected from the law of mass action. This deviation, together with the unusual dissociation pattern of the protein in the ultracentrifuge, can be explained by the presence of different thermodynamic components.