Effect of serotonin and noradrenaline on the magnitude of the response of the command neurons for defensive behavior in Helix lucorum L

Changes in synaptic responses of identified command neurones of avoidance behaviour to the electric nerve stimulation were investigated in the isolated nervous system of the snail during bath application of serotonin or noradrenaline. Serotonin (10(-5) M) elicited an increase of summary EPSP amplitude in the cells without changes of input resistance and resting potential. Noradrenaline (10(-5) M) application evoked an increase of EPSP amplitude, accompanied by an increase of the input resistance. Mechanisms of serotonin and noradrenaline influence on synaptic responses are discussed.     

Elementary and compound postsynaptic potentials in the defensive command neurons of Helix lucorum

The present communication concerns with the analysis of elementary and the compound excitatory postsynaptic potentials (eEPSPs and cEPSPs) recorded by intracellular microelectrode from an identified defensive command neuron of the snail Helix lucorum. The eEPSPs were evoked by single presynaptic action potentials (APs) elicited by cationic current injection into one of the identified sensory neurons synapsing on the respective command neuron. The cEPSPs were elicited by local brief tactile stimuli on the skin or internal organs. It was shown that the cEPSPs amplitudes depend mainly on the number of activated sensory neurons. Compound EPSPs depend also on frequency and the number of APs in the bursts occurring in a single neuron. Presynaptic APs having frequency 2-10 Hz evoke high frequency depression of that eEPSPs after an interval is followed by post-tetanic potentiation of single eEPSPs. Preceding stimulation of a pneumostom area facilitates the cEPSPs elicited by repeated stimulation of viscera. The eEPSPs from the same visceral area demonstrate no heterosynaptic facilitation in experiments with double parallel intracellular recording from responsive sensory and command neurons. The different types of the eEPSPs plasticity are discussed according to their contribution cEPSPs plastic changes.     

Involvement of intracellular calcium in sensitization of command neurons of defensive behavior in the edible snail (Helix lucorum)

Examinations carried out on command neurons of defensive behavior in the edible snail using electrophysiological methods and a chlortetracycline fluorescent probe revealed that a single sensitizing action alters electrical neuronal activity and the amount of bound calcium in the cells. An initial increase in the amount of bound calcium (the first 15–20 min after the sensitizing action) coincides in time with depolarization, enhancement of plasma membrane excitability, and a decrease of amplitude and duration of the excitatory postsynaptic potentials (EPSP) induced by sensory stimulations. Repeated pronounced increase in the bound calcium level develops 50–60 min after the sensitizing action and correlates with facilitation of neuronal responses to sensory stimuli. Alterations in the bound calcium level in command neurons of defensive behavior in the course of sensitization development differed in dynamics and direction from the previously described bound calcium shifts in the same cells in the course of habituation development.P. K. Anokhin Institute of Normal Physiology, Academy of Medical Sciences of the USSR Moscow. I. P. Pavlov Institute of Physiology, Academy of Sciences of the USSR Leningrad. Translated from Neirofiziologiya, Vol. 23, No. 4, pp. 418–427, July–August, 1991.     

The participation of GFAD-synthesizing neurons in behavior regulation in the snail (Helix lucorum L.)

It was shown earlier that some neurons in Helix CNS express the mRNA of the precursor of neuropeptide GFAD. Using the data obtained with the help of the whole-mount in situ hybridization, we tried to identify a group of such neurons, namely, the pedal caudo-ventral group and to determine their possible functions. The local extracellular stimulation of the pedal caudo-ventral group resulted in movements of reproductive organs in the semi-intact preparation and suppressed the activity of the modulatory neurons controlling feeding and defensive behavior. Application of synthetic peptide GFAD (10(-8) mol/l) also activated movements of the reproductive organs and suppressed the activity of the modulatory neuron controlling feeding behavior. Stimulation of the labial nerves resulted in suppression of caudo-ventral neurons with simultaneous activation of the modulatory neuron controlling feeding behavior. The obtained evidence suggests that the caudo-ventral neurons can regulate movements of the reproductive organs and also coordinate different functions in realization of the integral sexual behavior. This group of neurons inhibits the modulatory neurons controlling the forms of behavior incompatible with courtship, i.e., feeding and defensive forms.     

Postembryonic neuronogenesis in the procerebrum of the terrestrial snail,Helix lucorum L.

Neuronogenesis during posthatching development of the procerebrum of the terrestrial snail Helix lucorum was analyzed using bromodeoxyuridine immunohistochemistry to label proliferating cells. Comparison of the distribution of labeled cells in a series of animals which differed in age at the time of incubation with bromodeoxyuridine, in survival time after incubation, and in age at sacrifice reveals a clear pattern and developmental sequence in neuron origin. First, the proliferating cells are located only at the apical portion of the procerebrum. Second, cells which are produced at any particular age remain, for the most part, confined to a single layer in the procerebrum. Third, as development proceeds, each layer of previously produced neurons is displaced toward the basal part of the procerebrum by the production of additional neurons. Our results suggest that the vast majority of the neurons (probably about 70–80%) of the snail procerebrum are produced during the first 1–2 months of posthatching development. © 1998 John Wiley & Sons, Inc. J Neurobiol 35: 271–276, 1998     

Neurophysiological changes and dynamics of bound calcium during the development of associative learning in Helix lucorum

Neurophysiological effects and the dynamics of the content of bound calcium (Ca-b) in command neurons (LP1 and RP1) of defensive behavior during food aversion conditioning are studied inHelix lucorum. In the case of associative learning, there arises in these cells both a response to the conditioned stimulus and a nonspecific facilitation of the reactions to sensory stimuli that is characteristic for the state of sensitization. A response to the presentation of a conditioned stimulus is detected approximately 30 min after the development of long-term sensitization. The use of three or more paired stimuli reveals the characteristic dynamics of the level of Ca-b, which correlates with the neurophysiological effects and differs from the changes in Ca-b content during the development of "pure" sensitization. It is thought that the command neuron of defense behavior exhibits inHelix differences of the molecular-cellular mechanisms lying at the basis of the development of associative learning and sensitization.P. K. Anokhin Institute of Normal Physiology, Russian Academy of Sciences, Moscow. I. P. Pavlov Institute of Physiology, Russian Academy of Sciences, St. Petersburg. Translated from Neirofiziologiya, Vol. 24, No. 6, pp. 691–701, November–December, 1992.     

Role of the giant cerebral ganglion neuron in control of defensive behavior ofHelix lucorum

Neurons participating in contraction of the ommatophore retractor ofHelix lucorum were studied by morphological and electrophysiological methods. Staining by the cobalt filling method revealed a giant cerebral ganglion neuron which sends a fiber into the motor branch of the ipsilateral optic nerve. Both spontaneous and evoked contraction of the retractor was shown to be preceded by a volley of action potentials in the giant neuron. The high-frequency volley of impulses evoked by intracellular stimulation of this neuron leads to contraction of the ipsilateral ommatophore retractor; the intensity of this contraction depends on the discharge frequency. The composition of the sensory inputs of the neuron is discussed. A conclusion is drawn on the motor function of this cerebral ganglion neuron in the escape reflex ofH. lucorum.Research Institute for Biological Testing of Chemical Compounds, Ministry of the Medical Industry, Staraya Kupavna, Moscow Province. Institute of Higher Nervous Activity and Neurophysiology, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 14, No. 4, pp. 353–358, July–August, 1982.     

Effect of vibrissae removal on the defensive behavior of rats in early ontogeny

Influence of restricted sensory afferentation in rats forming of defensive reactions was studied by vibrissectomy from 9 to 20 day of postnatal ontogeny. Defensive withdrawal reaction in response to touch from 10 to 18 day, duration of freezing on 20 day, "open field" behavior on 25 day were measured. Intensity of withdrawal reactions, freezing duration, flight reaction and emotionality in "open field" were lower in vibrissectomized rats with comparison to control.     

The nervous system and the mapping of the neurons in the gastropod Helix lucorum L.]

Summarized literature and experimental author's data are presented concerning the structure of the nervous system and identification of individual neurons in the snail Helix lucorum. Information about especially well-known neurons is given in a table, maps of the ganglia are presented altogether with the results of retrograde staining of different cerebral and suboesophageal nerves. Are given the references concerning morphology of the central nervous system of the snail and identifiable neurons.     

Selectivity of opioid peptide effects on excitability and various sensory inputs in LPl1 and PPl1 command neurons participating in defensive behavior of the snail Helix lucorum

Opioid peptides effects on neural membrane as well as neural responses evoked by sensory stimuli with different modality and site of application, were investigated in L-RPII command neurones of defensive behaviour of semi-intact preparation in the land snail Helix lucorum. Met-enkephalin (10 uM) application onto the snail CNS increases membrane excitability and produces facilitation of neural responses evoked by quinine solution (0.5%) application onto snail head and depression of reactions evoked by tactile stimulation of the head. Met-enkephalin in dose of 0.1 uM initiates only a depression of neural responses evoked by tactile stimulation of the head. Leu-enkephalin (10 uM) application suppresses neural reactions evoked by tactile stimulation of the head. Membrane excitability and neural responses evoked by quinine application onto the snail head do not change after leu-enkephalin administration. Effects appear 10-20 min after initiation of the peptide application. Initial neural responses were observed 15-30 min after CNS washing with Ringer solution. In addition, facilitation of neural responses evoked by chemical stimulation of the snail head was found 30-50 min after leu-enkephalin washing. Peptides do not change neural responses evoked by tactile stimulation of the snail foot. Neural effects of peptides were prevented by simultaneous naloxon administration (50 uM). Experimental results show selective opioid peptides' effects on excitability and plasticity of L-RPII neural inputs with site- and modality-specifics.     

Mechanisms of achromatic vision in snail Helix lucorum L.: intracellular study of light-sensitive cells in retina

Intracellular study of the eye of land snail Helix lucorum L. demonstrated two types of visual cells responding to flashes of white light by slow sustained depolarization (D - type) and by slow sustained hyperpolarization (H - type). Peaks of spectral sensitivity of both types at 465-500 nm coincide with the peak of spectral sensitivity of photopigment 'rhodopsin'. The revealed D- and H - cells in the snail retina are considered as analogous of B- and D - cells, respectively, in the vertebrate visual system.     

Dynamics of changes in the excitability of Helix lucorum neurons in response to an analog of vasopressin

Application of desglycine-arginine-vasopressin to spontaneously nonactive command neurones of the snail's defensive reflex in the process of low-frequency (2-4 min intervals) intracellular stimulation led under certain conditions to an increase of excitability that was expressed in the shortening of latency of action potential generation, increase of the number of action potentials in response to a stimulus of fixed value, increase of membrane resistance, lowering of critical level of membrane depolarization and amplifying of pacemaker activity. However in spite of unidirectional changes of all the recorded parameters, the increases of values, opposite to the latency, did not correlate with the increases of membrane resistance and correlated well with the changes of depolarization critical level. If desglycine arginine-vasopressin was added to the medium during worsening of the neurones' excitability was probably caused by the influence of desglycine-arginine-vasopressin on the membrane active properties.     

Neuronal responses in area 7 of the cat cortex during defensive conditioning

Responses of neurons in area 7 of the parietal association cortex during and after formation of a defensive conditioned reflex to sound were recorded in waking cats. Changes in spike responses of the neurons as a result of the onset of conditioned reflex limb movements were observed in 68% of neurons. Spike responses of neurons formed as a result of learning appeared only if conditioned-reflex limb movements appeared, and they were not observed if, for some reason or other, movements were absent after presentation of the positive conditioned stimulus or on extinction of the reflex. Responses of 46% neurons to conditioned stimulation preceded the conditioned-reflex motor responses by 50–450 msec. The remaining responding neurons were recruited into the response after the beginning of movement. Characteristic spike responses of neurons to the conditioned stimulus appeared 500–900 msec before the beginning of movement and, in the case of appearance of special, "prolonged" motor responses of limb withdrawal, evoked by subsequent reinforcing stimulation.     

Neuronal responses in the limbic cortex of awake cats during defensive conditioning

Spike activity was investigated in limbic cortex neurons during defensive conditioning to acoustic stimulation in chronic experiments on cats. A relationship was found between the numbers of neurons responding, their contribution to formation of a temporal connection, and the duration of the acoustic stimulus. Phasic responses of 50–500 msec duration with latencies of 15–50 msec were observed for the most part. Intensive spike response with a minimum latency of 15 msec and a duration of between 200 msec and 2.5 sec evolved in most cells (95.1% in field 24 and 83% in field 32) in response to electrical stimulation. Response to acoustic stimulation rose during defensive conditioning in 33.3% cells and declined and finally disappeared in 13.3%, but response at the site where reinforcement was abolished was reproduced in all these cells. It was thus found that the numbers of limbic cortex neurons responding to sound not only fails to increase but actually decreases after training. The limbic cortex is thought to play its most active part in conditioning response to a recognized signal during the period preceding the awaited painful reinforcement.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 18, No. 5, pp. 660–669, September–October, 1986.     

Synapses identifiable in the parietal ganglia of the snail Helix lucorum

The synaptic plasticity is a background for learning and memory. Identifiable synapses that are the synapses between individually identifiable neurons are a very convenient model for studying plasticity. Synapses between the interoceptive mechanosensory neurons and the command neurons of the withdrawal behavior were identified in the Helix lucorum brain. It was shown that synaptic plasticity estimated by the dynamics of the elementary postsynaptic potentials elicited by single presynaptic spikes differed from the synaptic plasticity estimated by the dynamics of compound synaptic responses of the same neurons to sensory stimulation. Habituation and heterosynaptic facilitation phenomena are discussed in terms of the dynamics of the elementary postsynaptic potentials.     

明亮熊蜂和意大利蜜蜂在温室桃园的访花行为和传粉生态学比较

2004—2006年连续3年应用明亮熊蜂和意大利蜜蜂在北京为温室桃园传粉,对其访花行为和传粉生态学进行研究.结果表明：两种蜂都可以替代人工掸花为温室桃园提供有效的传粉服务.两种蜂的访花行为和传粉效果不同,明亮熊蜂偏爱于采集花粉,主要以震动翅膀的方式来使花粉释放和传播,而意大利蜜蜂偏爱于采集花蜜,主要以身体接触的方式来粘附和传播花粉;明亮熊蜂的活动起点温度低、日工作时间长、访花速度快,在低温条件下比意大利蜜蜂的传粉效果好;意大利蜜蜂的趋光性强,飞撞温室塑料薄膜的现象严重,受温度和光照条件的影响较大,对温室环境的适应性较差.     

Relation between fast and slow elemental synaptic potentials in command neurons in Helix lucorum taurica L

In experiments on a semi-intact snail preparation and a preparation of the snail isolated CNS, after spikes (Sp) evoked in presynaptic neurones by depolarizing current, not only rapid (R) EPSPs emerged in the command neurones of the defensive reaction of closing the pneumostome, but they were also followed by slow (S) EPSPs lasting over 2 min. For each single synaptic contact, the R and S EPSP amplitudes were in a good linear correspondence. In different synapses no direct connection was observed between R EPSP and S EPSP. It is suggested that R and S EPSPs may set in as a result of the action of different substances on the command neurones. Functional significance of S EPSPs with different amplitudes in different command neurones may consist in a prolonged specific preparation of the neurones for the action of stimuli.     

Selective involvement of opioids in mechanisms of synapse-specific plasticity in Helix lucorum snail during sensitization acquisition

Effects of met-enkephalin (opioid peptide) and naloxone (opioid antagonist) on nociceptive sensitization were studied in L-RP11 Helix neurons. In control snails sensitizing stimulation produced reversible membrane depolarization and depression of neural responses evoked by sensory stimuli during the short-term stage of sensitization and facilitation of these responses at the long-term stage. Met-enkephalin (10 but not 0.1 microM) suppressed the neural responses evoked by nociceptive stimuli. Sensitizing stimulation during metenkephalin application prevented the facilitation of neural responses evoked by tactile stimulation of snail head, whereas facilitation of neural responses evoked by chemical stimulation of head or tactile stimulation of foot were similar to that in control sensitized snails. Sensitizing stimulation during met-enkephalin and/or naloxone application prevented the facilitation of neural responses evoked by chemical stimulation of snail head, whereas responses evoked by tactile stimulation of snail head or foot were facilitated (as in neurons of control sensitized snails). Opioids are suggested to be involved in regulation of nociceptive mechanisms and selective induction of long-term plasticity in L-RP11 neural inputs activated by tactile of chemical stimulation of snail head.