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.     

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.     

Electrical connection between two bursting neurons inHelix pomatia

In some preparations of the CNS ofHelix pomatia, two neurons with bursting activity may be present in the right parietal ganglion, where usually there is only one bursting neuron RPal. If electrical activity of these neurons is recorded simultaneously, fluctuations of membrane potential are almost completely synchronized. Artificial depolarization and hyperpolarization of the membrane of one neuron caused depolarization or hyperpolarization of the other neuron. During long-term recording of the activity of both neurons synchronous modulation of their bursting activity was observed. Modulating factor (a peptide fraction obtained from the water-soluble part of snail brain homogenate) led to potentiation of the bursting activity of both neurons. It is concluded from the results of these experiments that two bursting RPal neurons, connected electrically with one another, may exist in the snail nervous system. In cases when the parameters of pacemaker activity of these two neurons are closely similar, electrical connection guarantees synchronization of their bursting activity and ensures a common frequency of changes in their membrane potential.     

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.     

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.     

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.     

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.     

Postsynaptic mechanisms initiating bursting activity in theHelix pomatia RPal neuron under the influence of an interneuron

Postsynaptic mechanisms of the connection between the interneuron in the visceral ganglion initiating bursting activity in RPal and B7 neurons and these neurons themselves were investigated in the snail (Helix pomatia). Using voltage clamping at the membrane of these cells, stimulation of the interneuron gave rise to a slow inward current with a 2 sec latency; it rose in amplitude as stimulation increased in duration. Reducing the temperature from 25 to 5°C diminished the rise and decay rate of this current with a temperature coefficient of about 10. The current-voltage relationship of the slow inward current was nonlinear, with a maximum of –65 mV. Reducing the concentration of sodium ions in the extracellular fluid increased the amplitude of the current. While hyperpolarization of the burster neuron membrane produced a burst of inward current prior to stimulation, this same hyperpolarization induced a pulse of outward current at the peak of the slow inward current. Stimulating the interneuron is thus thought to activate at least two types of ionic channel in the cell body of the burster neurons: a steady sodium and a voltage- and time-dependent channel for outward current. This process could well be mediated by a biochemical cytoplasmic chain reaction.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 19, No. 1, pp. 28–36, January–February, 1987.     

Mechanisms of Generation of Pacemaker Activity by Identified Helix Neurons

We studied the mechanisms of generation of pacemaker activity in identified neurons of Helix pomatia. For this purpose, we isolated the PPa2 and PPa7 neurons generating spontaneous rhythmic monomodal activity and PPa1 neuron with bursting activity. It was demonstrated that isolated PPa2 and PPa7 cells produce endogenous rhythmic activity that was not considerably modified by external application of 1 mM CdCl₂. Sometimes, only low-amplitude dendritic action potentials (AP) were observed instead of generation of full-amplitude somatic AP. In contrast, isolation of the PPa1 neuron eliminated its bursting activity, but subsequent application of oxytocin on this neuron recovered such activity. This finding shows that the bursting activity of the PPa1 neuron is of an exogenous nature. Application of 1 mM CdCl₂ suppressed this bursting activity, but when Cd²⁺ was applied against the background of superfusion of the neuron with Ringer solution containing a bursting activity-initiating neuropeptide obtained from the molluscan CNS, this blocker was incapable of suppressing the bursting activity. A blocker of the hyperpolarization-activated current (I _h , H current), Cs⁺ (10 mM) exerted no noticeable effect on the activity of the studied neurons. Our findings allow us to conclude that the pacemaker activity is initiated within the dendritic tree of a cell and is then electrotonically spread to the soma, where full-amplitude AP are generated. It seems probable that Ca²⁺ ions and H current are not directly involved in generation of the pacemaker activity in the studied snail neurons.     

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.     

Neurochemical mechanisms of burst activity regulation in isolated snail endogenous oscillators: Role of monoamines in opoid peptides

The electrical activity of three identified bursting neurons (including one "plateau-generating" neuron) is studied in the brain ofHelix lucorum under conditions of complete isolation. A method for isolating the identified neurons is worked out (mechanical extraction by means of microelectrodes). All three neurons are shown to be endogenous oscillators. In the isolated state in the absence of any stimulation they exhibit spontaneous changes in activity: from an inactive state to nongrouped regular activity, from regular activity to burst activity, and vice versa. It is also found that the burst activity of all three isolated neurons can be regulated (initiated, discontinued, parameters altered) using the same neurochemical agents: serotonin, opioid enkephalins. Burst activity can be generated by the combined action of dopamine and enkephalin and discontinued just with dopamine. The possible significance of the described neurochemical mechanism of regulating burst activity in neurons that are endogenous oscillators is discussed with regard to the generation of the rhythm of various cyclic functions.N. K. Kol'tsov Institute of Developmental Biology, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 23, No. 4, pp. 472–480, July–August, 1991.     

Modification of bursting in a Helix neuron by drugs influencing intracellular regulation of calcium level

The effect of ruthenium red, caffein and EGTA (ethyleneglycol tetraacetic acid) influencing intracellular Ca2+ level as well as that of pH-lowering was investigated on identified RPal neuron of Helix pomatia characterized by bimodal pacemaker (bursting) activity. Drugs were applied both extracellularly and intracellularly. Intracellular injection was performed from micropipettes by pressure. It was found that intracellular injection of ruthenium red, caffein, EGTA and pH-lowering caused immediate short hyperpolarization and suspension of bursting. The effect of caffein and lowering of pH was biphasic, hyperpolarization was followed by an increase of spiking. Following EGTA injection the amplitudes of interburst hyperpolarizing waves decreased, and prolongation of spikes occurred. Extracellular application of ruthenium red caused slight depolarization, while caffein produced mainly effects that were similar to those of the intracellular injection. Adding EGTA into the bath resulted in cessation of bursting, and later on also spike generation was blocked. All these effects could be eliminated by washing. It is concluded that Ca-influx during spiking cannot be considered as a single factor in maintaining bursting activity, nevertheless, intracellular binding and liberation of Ca depending on the cell metabolism should also be taken into consideration as a possible mechanism of burst regulation.     

Ganglioside sialidase activity in bovine neuronal perikarya

Neuronal perikarya were isolated, using bulk preparative procedures, from bovine brains. Synaptosomes, neuronal perikarya, and brain homogenates had similar ganglioside patterns, with the synaptosomes containing at least four times more total ganglioside per mg protein than the neuronal perikarya and twice that of the homogenate. Synaptosomes had 26–33 nmol total sialic acid/mg protein, while the neurons had only 15–17 nmol. Determination of ganglioside sialidase activity showed that neuronal perikarya had very low levels (negligible), in comparison with synaptosomes or whole-brain homogenates. Trypsin treatment during the isolation procedure enhanced sialidase activity two-to threefold in the particulate fraction of the whole-brain homogenate. Determination of the distribution of sialidase activity in the fractions obtained during the isolation of the neuronal perikarya showed that the sialidase activity was associated with the myelin, broken-off dendritic processes, and glial-cell fractions that banded in the less dense sucrose.     

Effect of intracellular injection of cyclic amp on electrical characteristics of identified neurons in Helix pomatia

The effect of intracellular iontophoretic injection of cyclic AMP on electrical activity of neurons RPa1, RPa3, LPa2, LPa3, and LPl1 in the corresponding ganglia ofHelix pomatia was investigated. Injection of cyclic AMP into neuron LPl1 was found to cause the appearance of rhythmic activity (if the neuron was originally "silent"), an increase in the frequency of spike generation (if the neuron had rhythmic activity), and a decrease in amplitude of waves of membrane potential, in the duration of the interval between bursts, and in the number of action potentials in the burst (if the neuron demonstrated bursting activity). In the remaining "silent" neurons injection of cyclic AMP led to membrane depolarization. Injection of cyclic AMP into neurons whose membrane potential was clamped at the resting potential level evoked the development of an inward transmembrane current (cyclic AMP current), the rate of rise and duration of which increased proportionally to the size and duration of the injection. Theophylline in a concentration of 1 mM led to an increase in the amplitude and duration of the cyclic AMP current by about 50%. It is concluded that a change in the cyclic AMP concentration within the nerve cell may modify the ionic permeability of its membrane and, correspondingly, its electrical activity.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 12, No. 5, pp. 517–525, September–October, 1980.     

In vitro metabolism of opioid tetrapeptide agonists in various tissues and subcellular fractions from rats

The metabolism of three mu-selective opioid tetrapeptide agonists, Tyr-D-Arg-Phe-Nva-NH(2) (TArPN), Tyr-D-Arg-Phe-Phe-NH(2) (TArPP), and Tyr-D-Ala-Phe-Phe-NH(2) (TAPP), was investigated in different rat tissues. High metabolic activity (<20% peptide remaining after 30 min) was found against the three peptides in the kidney homogenate and against TArPN in spleen homogenate. Low metabolic activity (>80% peptide remaining after 30 min) was found for all peptides in brain homogenate and plasma, and for TArPN and TArPP in blood. The other tissue homogenates, prepared from the small and large intestine, liver and lung, all exhibited intermediate metabolic activity (20-80% peptide remaining after 30 min) against the peptides. In all tissues investigated, the tetrapeptides were metabolized at the C-terminal amide by deamidation.A further in depth metabolic investigation was performed in subcellular fractions isolated from three tissues (small intestine, liver and kidney). In the liver, the deamidation was predominantly localized to the mitochondrial/lysosomal fraction, while hydrolysis at the N-terminal Tyr residue was the major metabolic pathway in the microsomal/brush-border membrane fraction from the kidney and small intestine.     

Travelling wave patterns in a model of the spinal pattern generator using spiking neurons

The aim of this study is to produce travelling waves in a planar net of artificial spiking neurons. Provided that the parameters of the waves – frequency, wavelength and orientation – can be sufficiently controlled, such a network can serve as a model of the spinal pattern generator for swimming and terrestrial quadruped locomotion. A previous implementation using non-spiking, sigmoid neurons lacked the physiological plausibility that can only be attained using more realistic spiking neurons. Simulations were conducted using three types of spiking neuronal models. First, leaky integrate-and-fire neurons were used. Second, we introduced a phenomenological bursting neuron. And third, a canonical model neuron was implemented which could reproduce the full dynamics of the Hodgkin–Huxley neuron. The conditions necessary to produce appropriate travelling waves corresponded largely to the known anatomy and physiology of the spinal cord. Especially important features for the generation of travelling waves were the topology of the local connections – so-called off-centre connectivity – the availability of dynamic synapses and, to some extent, the availability of bursting cell types. The latter were necessary to produce stable waves at the low frequencies observed in quadruped locomotion. In general, the phenomenon of travelling waves was very robust and largely independent of the network parameters and emulated cell types.     

Relative stability of α-melanotropin and related analogues to rat brain homogenates

α-Melanotropin (α-MSH) retains less than 1% of its original activity after a 60 min incubation with 10% rat brain homogenate. [Nle⁴, D-Phe⁷]-α-MSH is nonbiodegradable in rat serum (240 min incubation) and still maintains 10% of its original activity in 10% rat brain homogenate (240 min incubation). The related fragment analogue, Ac-[Nle⁴, D-Phe⁷]-α-MSH_4–10-NH₂, retains 50% of its activity after a 240 min incubation in rat brain homogenate, whereas Ac-[Nle⁴, D-Phe⁷]-α-MSH_4–11-NH₂ is totally resistant to inactivation by rat brain homogenate. Both [Nle⁴, D-Phe⁷]-fragments are resistant to degradation by rat serum, but [Nle⁴]-α-MSH, Ac-[Nle⁴]-α-MSH_4–10-NH₂ and Ac-[Nle⁴]-α-MSH_4–11-NH₂ are rapidly inactivated under both conditions. The cyclic melanotropin, [ ]-α-MSH, is inactivated in rat brain homogenate as is the shorter Ac-[ ]-α-MSH_4–10-NH₂ analogue, but neither cyclic melanotropin is inactivated upon incubation in serum from rats. Ac-[ ]-α-MSH_4–10-NH₂ is resistant to inactivation by either rat serum or a brain homogenate. Some of these melanotropin analogues may provide useful probes for the localization and characterization of putative melanotropin receptors in both the central nervous system and peripheral tissues.     

Organic acids and water-soluble phenolics produced by Paxillus sp. 60/92 together show antifungal activity against Pythium vexans under acidic culture conditions

Ectomycorrhizal fungi can produce antifungal compounds in vitro as well as in symbiosis with the host plant that can reduce root diseases. The objective of this study was to isolate antifungal compounds from culture filtrate of Paxillus sp. 60/92, which can form mycorrhizas with Picea glehnii seedlings. Culture filtrate of Paxillus sp. 60/92 showed antifungal activity against Pythium vexans at pH 3–4 but not at pH 5–10, although sterile MMN-b liquid medium (pH 3–10) did not show antifungal activity. Upon separation of antifungal compounds in the culture filtrate, antifungal activity was detected in the organic acid and water-soluble phenolics fractions adjusted to pH 3. Although antifungal activity of individual fractions was lower than that of the culture filtrate, a mixture of these fractions showed antifungal activity similar to that of the culture filtrate. Furthermore, antifungal activity of oxalic acid, which is known to be produced by Paxillus involutus, was increased by mixing with the water-soluble phenolic fraction. Our findings indicate that Paxillus sp. 60/92 produces organic acids and water-soluble phenolics that together show antifungal activity at pH 3–4 against P. vexans.     

β-d-glucosidase in fractions from rat brain

-Glucosidase activity has been determined in homogenate and in centrifugation fractions of 7-day-old and adult rat brain; maximum activity was found at pH 4 and pH 5. Of the adult brain, more than 50% of the activity was concentrated in the 800-g sediment fraction (P₁), while in the brain of 7-day-old rat about 20% was found in the corresponding fraction. The activity maximum in all fractions after a 2% Triton X-100 treatment occurs at pH 5. Addition of Triton to adult brain homogenate enhances the activity, but this stimulation is less than the sum of the activities observed at pH 4 and pH 5 in the absence of Triton. Triton addition to brain homogenate of 7-day-old rat results in a fall in activity at pH 4 and in a maximum at pH 5. In rat brain homogenate subjected to sonication, a loss of activity is observed at pH 4, scarcely at pH 5; the activity loss is completely abolished and turned into an increase under the influence of Triton. This increase equals the level obtained when Triton is added to an untreated brain homogenate. Sonication of rat brain homogenate leads to changes in the distribution pattern; about 25% of the activity of the adult brain is found in the P₁ fraction compared to 50% in the corresponding fraction of the untreated brain. Fractionation of a sonicated brain homogenate from adult rat reveals that at pH 4 most activity (52%) is concentrated in the 20,000-g pellet (P₂), 23% in supernatant fluid (S₂); at pH 5 the opposite is observed: most activity (49%) is found in the 20,000-g supernatant (S₂) and 23% in the 20,000-g pellet (P₂). In the presence of Triton the activity of the sonicated brain homogenate of adult rat increases; this stimulation roughly equals the sum of the corresponding activities measured at pH 4 and pH 5 in the absence of Triton.     

Determination of the topical organization of outputs of identified molluscan neurons

In experiments on mollusks (Planorbis corneus) the topical organization of outputs of neurons RPal and RPa2 of the right parietal ganglion was investigated. Outputs were identified by coherence analysis of accumulated electrical activity in dissected nerves during activation of the above neurons. The analysis was based on a number of features described in this paper. Axons of the test neurons were found to be present in the left and right pallial nerves; polysynaptic pathways activated by these neurons also were discovered. The topical organization of outputs of the test neurons was shown to be invariant for different preparations.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 16, No. 4, pp. 458–463, July–August, 1984.