Decrease in excitability of LG following habituation of the crayfish escape reaction

Crayfish escapes from threatening stimuli to the abdomen by tailflipping upwards and forwards. This lateral giant (LG)-mediated escape reaction habituates readily upon repetitive sensory stimulation. Using an isolated abdominal nerve cord preparation, we have analyzed the change in LG activity by applying additional sensory stimulation after different periods following habituation to characterize the retention of LG habituation. Results show that the LG mediated response habituates more quickly, but the retention time is shorter, as repetitive sensory stimulation is applied at progressively shorter inter-stimulus time intervals. The spike response of LG recovers quickly, within several minutes after habituation, but they fail to spike when an additional stimulus is applied after specific long periods following habituation. The critical period of the delay for this decrease in excitability of LG is dependent on the inter-stimulus time interval of the initial repetitive stimulus. As the inter-stimulus interval became longer, the delay needed for decrease in excitability became shorter. Furthermore, the local injection of 10^–6 mol l^–1 octopamine into the neuropil just following habituation promotes the achievement of decrease in excitability. No effects were observed when 10^–6 mol l^–1 serotonin and tyramine were injected. These results suggested octopamine promotes decrease in excitability of LG following habituation.     

On the Generalization of Habituation: How Discrete Biological Systems Respond to Repetitive Stimuli

Habituation, a form of non‐associative learning, isno longer studied exclusively within the fields of psychology and neuroscience. Indeed, the same stimulus–response pattern is observed at the molecular, cellular, and organismal scales and is not dependent upon the presence of neurons. Hence, a more inclusive theory is required to accommodate aneural forms of habituation. Here an abstraction of the habituation process that does not rely upon particular biological pathways or substrates is presented. Instead, five generalizable elements that define the habituation process are operationalized. The formulation can be applied to interrogate systems as they respond to several stimulation paradigms, providing new insights and supporting existing behavioral data. The model can be used to deduce the relative contribution of elements that contribute to the measurable output of the system. The results suggest that habituation serves as a general biological strategy that any system can implement to adaptively respond to harmless, repetitive stimuli.     

Transfer of habituation between stimulation sites of the siphon withdrawal reflex in Aplysia californica

Habituation of the siphon withdrawal reflex (SWR) can be evoked by iterative tactile stimuli presented to one of several sites, including the siphon and gill. The SWR evoked at an arbitrary "test" site did not habituate when stimuli were presented at 20-min intervals. However, there was a large decrease in the reflex evoked at the test site when the trial was preceded by 10 repetitive stimuli (interstimuli interval = 30 s) presented to the opposite "habituation" site. Transfer of habituation occurred from gill to siphon stimulation sites, and vice versa. There was a concomitant decrease in the excitatory input evoked in the central siphon motor neurons LDS1 and LDS3. Moreover, transfer of habituation occurred after the abdominal ganglion (central nervous system) was removed. There was little change in the magnitude of the control responses or transfer of habituation after deganglionation. Since transfer of habituation between stimulation sites of the SWR was similar to that reported previously for the gill withdrawal reflex, it was suggested that a common mechanism may underlie the two behaviors.     

The neuronal reactivity and interaction of the rat cerebral cortex during the microiontophoretic action of acetylcholine in a model negative learning situation]

Unit activity of 46 pairs of neurons of sensorimotor cortex of rats was studied in a model situation of habituation to repetitive microiontophoretic applications of acetylcholine (ACh). The difference between the types of reactions to ACh of two neighbouring neurons recorded by the same microelectrode was observed on 37% of cases. The difference between the dynamics of activity of neurons with similar patterns of reactions during repetitive action of stimuli was also shown. Stability of the excitatory connections between two neighbouring neurons under the conditions when one of them demonstrated the habituation to repetitive action of ACh were indicated by analysis of cross-correlation histograms.     

Role of cAMP in providing for the plastic properties of the electro-excitable membrane of neurons

In isolated snail brain, the role was studied of cyclic adenosine monophosphate (cAMP) in providing plastic properties of electro-excitable neuronal membranes of two types, habituating and non-habituating to rhythmic intracellular stimulation with depolarizing electric pulses. It has been shown that at high level of cAMP in the cell maintained with administration of dibutyryl-cAMP and (or) blockaders of phosphodiesterase in incubation medium, habituating cells lose their ability of habituation to stimulation. There is also no habituation in the presence of serotonin: serotonin effect is removed by imidazol, activator of phosphodiesterase. Imidazol promotes the development of habituation of cells, initially non-habituating to stimulation. Data are obtained on connection of Ca2+ effects and cAMP metabolism in habituating cells. On the basis of the obtained data it is suggested that the cyclase system controls plastic properties of neurones of both types, and reduction of cAMP content in the cell apparently mediates the above mentioned Ca-K-mechanism of habituation.     

Neural modification by paired sensory stimuli

With repetitive stimulation of two sensory pathways which are intact within the isolated nervous system of Hermissenda, features of a cellular conditioning paradigm were identified. Type A photoreceptors, unlike type B photoreceptors, produce fewer impulses in response to light following temporally specific pairing of light stimuli with rotation stimuli. Type A photoreceptor impulse wave-forms are also specifically changed by such stimulus regimens. These findings can be explained, at least in part, by increased inhibition of type A cells by type B cells after stimulus pairing.     

Two types of plasticity in the tentacle withdrawal reflex of Helix aspersa are dissociated by tissue location and response measure

The tentacle withdrawal reflex of the terrestrial snail Helix aspersa was studied in vitro. The reflex is evoked by mechanical stimulation of the nose. Lesion experiments showed that 45% to 75% of the response amplitude is attributable to peripheral pathways alone. The central contribution increases with increasing stimulus intensity.Repeated stimulation produced pure habituation at low stimulus strengths, and habituation mixed with intrinsic sensitization (warm-up effect) at high stimulus strengths. The simultaneous occurrence of habituation and sensitization is consistent with the dual process theory of plasticity. Additional results differentiate the two processes. Habituation can occur without the CNS, whereas intrinsic sensitization requires the CNS. Also, the two processes are differentially effective in their influences on response amplitude and duration: habituation is more effective in determining response amplitude, while sensitization is more effective in determining response duration.Although the establishment of sensitization requires the CNS, 81% of the memory for intrinsic sensitization was localized to the periphery, by lesion experiments. Extrinsic sensitization, caused by stimulation of the medial lip nerve, had similar behavioural effects and a similar memory locus. Both types of sensitization appear to be caused by neuromuscular facilitation mediated by a central pathway.Abbreviations CNS central nervous system - PNS peripheral nervous system - S-R stimulus-response - TRM tentacle retractor muscle     

Neural correlates of habituation of the proleg withdrawal reflex in larvae of the hawk moth, Manduca sexta

The larval proleg withdrawal reflex of the hawk moth, Manduca sexta, exhibits robust habituation. This reflex is evoked by deflecting one or more mechanosensory planta hairs on a proleg tip. We examined neural correlates of habituation in an isolated proleg preparation consisting of one proleg and its segmental ganglion. Repeated deflection of a single planta hair caused a significant decrease in the number of action potentials evoked in the proleg motor nerve (which carries the axons of proleg retractor motor neurons). Significant response decrement was seen for interstimulus intervals of 10 s, 60 s and 5 min. Response decrement failed to occur in the absence of repetitive stimulation, the decremented response recovered spontaneously following a rest, and electrical stimulation of a body wall nerve facilitated the decremented response (a neural correlate of dishabituation). Adaptation of sensory neuron responses occurred during repeated hair deflections. However, when adaptation was eliminated by direct electrical stimulation of sensory neurons, the response in the proleg motor nerve still decreased significantly. Muscle recordings indicated that the response of an identified proleg retractor motor neuron decreased significantly during habituation training. Thus, habituation of the proleg withdrawal reflex includes a central component that is apparent at the level of a single motor neuron. Accepted: 20 December 1996     

Intracellular stimulation of sensory cells elicits swimming activity in the medicinal leech

Intracellular stimulation of each of three different types of mechanoreceptors, the T, P and N cells, evokes swimming behavior in leech preparations. Stimulation of an individual N cell or P cell evoked swimming in 75% and 53% respectively, of the preparations tested. Stimulation of an individual T cell was ineffective in eliciting swimming; however, simultaneous stimulation of two T cells evoked swimming in 59% of our preparations. Stimulation of mechanosensory neurons elicited swimming activity for a limited number of trials; i.e. the response habituated. The number of swim episodes evoked before habituation to criterion did not differ significantly for the different types of mechanoreceptors. The duration of swim episodes declined significantly over the course of N cell stimulation. The tendency for swim length to decline with repeated stimulation was present as well for swim episodes elicited by P or T cell stimulation. Swim initiation recovered spontaneously following habituation resulting from T cell stimulation. Spontaneous recovery following N cell stimulation was not demonstrated. However, N cell stimulation evoked swimming again after DP nerve shock or to a limited extent, after cell 204 stimulation. Spontaneous recovery of swim initiation to P cell stimulation was not investigated. A previous study detailed habituation of swimming activity to mechanical stimulation of the body wall (Debski and Friesen 1985). Only the T cells are activated significantly by this stimulus. Stimulation of sensory receptors other than mechanoreceptors was not effective in eliciting swimming in our preparation. We conclude that T cells mediate swim initiation elicited by stroking of the body wall and that the cessation of swimming to this stimulus is not due to sensory adaptation.     

Transfer of habituation in Aplysia: contribution of heterosynaptic pathways in habituation of the gill-withdrawal reflex

Habituation of the Aplysia gill-withdrawal reflex (and siphon-withdrawal reflex) has been attributed to low-frequency homosynaptic depression at central sensory-motor synapses. The recent demonstration that transfer of habituation between stimulation sites occurs in this model system has prompted the hypothesis that heterosynaptic inhibitory pathways also play a role in the mediation of habituation behavior. To test this hypothesis, the sites and mechanisms of neural plasticity which underlie transfer of habituation in Aplysia were examined. Transfer of habituation is a reduction in the reflex evoked at one stimulation site (siphon) due to repeated presentation of a stimulus to a second site (gill). Centrally mediated transfer of habituation, measured in a preparation lacking the siphon-gill peripheral nervous system (PNS), was associated with a reduced excitatory response in central motor neurons. Repeated tactile stimulation of the gill did not attenuate the gill response evoked by electrical stimulation of the branchial nerve nor the mechanoreceptor response recorded in LE sensory neurons. In contrast, repeated stimulation of siphon or gill at a site which was "off" the sensory field of a specific mechanoreceptor led to a diminution in synaptic transmission between that sensory neuron and its followers (motor neurons and inter-neurons). These data demonstrate that centrally mediated transfer of habituation results from heterosynaptic modulation of synaptic transmission at the sensory-motor (and sensory-interneuron) synapses. Therefore, habituation behavior in Aplysia is mediated through the conjoint action of homosynaptic and heterosynaptic inhibitory processes.     

Factors affecting habituation of PC12 cells to ATP.

Extracellular ATP triggers catecholamine secretion from PC12 cells by activating ionotropic purine receptors. Repeated stimulation by ATP leads to habituation of the secretory response. In this paper, we use amperometric detection to monitor the habituation of PC12 cells to multiple stimulations of ATP or its agonist. Cells habituate to 30 microm ATP slower than they do to 300 or 600 microm ATP. Modifying external Mg2+ affects the response of cells to 30 microm ATP, but does not affect habituation, suggesting that habituation does not necessarily correspond to either stimulus intensity or cellular response. Mg2+ affects the initial response of PC12 cells to 2MeSATP in a manner similar to ATP. Increasing external [Mg2+] to 3.0 mm, however, eliminates habituation to 2MeSATP. This habituation can be partially restored by costimulation with 100 microm UTP. Background application of UTP increases habituation to both ATP and 2MeSATP. This suggests that ATP-sensitive metabotropic (P2Y) receptors play a role in the habituation process. Finally, although Ca2+ influx through voltage-operated calcium channels does not appear to contribute to secretion during ATP stimulation, blocking these channels with nicardipine increases habituation. This suggests a role for voltage-operated calcium channels in the habituation process.     

Effect of FMRFamide on the electrical and plastic properties of identified Helix pomatia neurons

Effect of the neuropeptide FMRFamide on two types of nerve cells differing in plastic properties: habituating and non-habituating to rhythmic intracellular stimulation, has been studied. FMRFamide causes a slow developing, continuously growing depolarisation and an increase of input resistance of the most part of habituating cells resulting in inhibition of their habituation to intracellular stimulation. No desensitisation of cells to the action of FMRFamide was observed. The data obtained by using Ca-ionophore, imidazole and caffeine show that the effect of the peptide may be caused by inhibition of Ca-dependent K-conductance and depends on cAMP metabolism. FMRFamide exerts a less pronounced action on non-habituating cells and does not change their plastic properties. Inhibition by FMRFamide of the habituation at the level of electroexcitable membrane may play a significant part in regulation of neuronal plasticity.     

Modifications of acoustic habituation by interruption of visual input in quipazine treated cats

The influence of interruption of the visual input on acoustic habituation was studied in cats before and following the administration of quipazine, 3 mg/kg iv. The characteristics of acoustic habituation were analyzed through the magnitude and temporal course of multiunit activity (MUA) responses elicited in the mesencephalic reticular formation (MRF) by repetitive acoustic stimuli (70 db, 50 Hz trains of 2 sec duration) in 6 freely moving cats with cortical electrodes over the parietal cortex and bipolar electrodes chronically implanted in MRF and basolateral amygdala (AMN). The cats were submitted to repetitive acoustic stimulation during one 30 min period before, and three 30 min periods after drug administration in the following conditions: a) with unmasked eyes; b) with masked eyes by means of dark contact lenses. Persistent attentive behavior, catatonic attitudes, hypersynchronous (6 Hz, 100-150 microV) EEG activity and significant increase of spontaneous MUA in FRM and AMN were induced by quipazine both in the cats tested with unmasked and with masked eyes. This increase of MUA was higher immediately following drug administration and progressively decreased, although MUA values remained significantly higher than controls 110 min after quipazine administration. Acoustic habituation, evidenced through the progressive decrease of MUA responses of MRF to acoustic stimuli, was observed before quipazine administration when the cats were tested with unmasked and with masked eyes; as well as in cats tested with unmasked eyes following drug administration. However, the MUA responses to acoustic stimuli did not decrease in cats with masked eyes during acoustic stimulation periods 0-30 min and 40-70 min after quipazine administration.(ABSTRACT TRUNCATED AT 250 WORDS)     

Habituation of direct cortical responses in cats

Gradual diminution of direct responses of various cortical areas was studied in acute experiments on cats under barbiturate anesthesia. During repetitive stimulation of the surface of cortical association areas these responses underwent all changes characteristic of the habituation phenomenon. Direct cortical responses in primary projection areas were distinguished by great stability, and habituation was absent in this case. After neuronal isolation of an island of projection cortex, habituation of responses began to develop there just as in the cortical association areas. The possible causes of differences between changes in direct cortical responses in different areas are discussed. It is suggested that projection areas receive strong activating influences from deep brain structures, which exert a sensitizing effect on the direct responses.I. S. Beritashvili Institute of Physiology, Academy of Sciences of the Georgian SSR, Tbilisi. Translated from Neirofiziologiya, Vol. 13, No. 3, pp. 241–246, May–June, 1981.     

Habituation of postsynaptic unit responses of the cat motor cortex to stimuli of different modalities

Habituation (extinction) of postsynaptic unit responses of the cat motor cortex to repetitive electrodermal, photic, acoustic, and combined bimodal stimulation was investigated by intracellular recording. Habituation was shown by a decrease in the number of spikes per grouped discharge and a decrease in the amplitude and duration of the EPSPs, and sometimes IPSPs, on repetition of the stimulus. The way in which the course of habituation depends on the modality and duration of stimulation (at a constant frequency of 1/sec) is examined. Habituation of postsynaptic responses to sensory stimuli is observed with neurons of different functional groups, namely identified neurons of pyramidal tract and unidentified neurons, some of which were evidently pyramidal neurons and interneurons. The hypothesis is put forward that the habituation of PSPs of the cortical neurons is based on processes taking place mainly at the subcortical level.A. A. Zhdanov Leningrad State University. Translated from Neirofiziologiya, Vol. 4, No. 5, pp. 545–553, September–October, 1972.     

Neurophysiological mechanisms underlying habituation of the tentacle retraction reflex in the land slug Ariolimax

Habituation of the tentacle retraction reflex was studied at the following response levels: (1) Muscle tension elicited in the tentacle retractor muscle by repeated stimulation of a cerebral nerve (at 60-sec intervals) declined in parallel with evoked activity of the largest unit in the tentacle retractor nerve. (2) The largest unit in the tentacle retractor nerve (L₄) showed spontaneous recovery and dishabituation. The rate of response decrement was inversely related to the strength of stimulus, and an optimal interstimulus interval ca. 60 s was found. Retention of habituation for 24 h was exhibited. (3) The major retractor motoneurons (L₂, L₃, L₄) all showed habituation, dishabituation, and spontaneous recovery. The decline of L₄ activity was parallelled by a decline in muscle response. (4) Compound EPSPs elicited in the retractor motoneurons by stimulation of sensory pathways showed habituation and dishabituation. (5) Unitary EPSPs elicited by stimulation of cerebral nerves and connectives with minimal stimulus strengths also showed habituation and were unaffected by spontaneously occurring EPSPs. Dishabituation by another pathway was also shown. (6) Depolarization of L₄ by a constant current produced spike trains of constant firing rate and evoked a constant level of muscle tension in repeated trials, suggesting the absence of habituation in a peripheral nerve net or at the neuromuscular junction.     

A study of behavioural habituation to a feeding deterrent in nymphs of Schistocerca gregaria

ABSTRACT. Behavioural habituation† of Schistocerca gregaria Forskål fifth instar larvae to a feeding deterrent, nicotine hydrogen tartrate (NHT), is described. An attempt was made to differentiate between various factors possibly involved in the induction of this behavioural habituation. Sensory stimulation (through maxillary palp), cannulation of NHT into the crop, and its administration by gelatine capsules placed into the oesophagus each resulted in behavioural habituation, but in the latter two cases a sole induction via post-ingestional input is not completely proven. Injection of NHT into the haemolymph did not induce habituation. It is concluded that habituation via sensory stimulation is a central phenomenon.     

Modulation of the Aplysia gill withdrawal reflex by dopamine

The ability of dopamine to modulate gill contractions was tested in Aplysia. When dopamine was perfused through the gill vasculature, gill contractions caused by siphon stimulation (gill withdrawal reflex) and by depolarization of the gill motor neuron L7 were increased in amplitude, as compared with those evoked during seawater perfusion. Habituation of gill movements, brought about by repetitive stimulation of the siphon or of L7, was prevented by dopamine. Despite the absence of reflex habituation, the number of action potentials in central gill motor neurons, evoked by siphon stimulation, showed normal decrement. Dopamine's effects were blocked when the ctenidial nerve was cut or when L7 hyperpolarized. These data suggest that dopamine acts peripherally to increase the efficacy of L7's synaptic transmission onto gill muscle or elements of the gill neural plexus.     

The GTPase Rab3a negatively controls calcium-dependent exocytosis in neuroendocrine cells.

There is accumulating evidence that small GTPases of the rab family regulate intracellular vesicle traffic along biosynthetic and endocytotic pathways in eukaryotic cells. It has been suggested that Rab3a, which is associated with synaptic vesicles in neurons and with secretory granules in adrenal chromaffin cells, might regulate exocytosis. We report here that overexpression in PC12 cells of Rab3a mutant proteins defective in either GTP hydrolysis or in guanine nucleotide binding inhibited exocytosis, as measured by a double indirect immunofluorescence assay. Moreover, injection of the purified mutant proteins into bovine adrenal chromaffin cells also inhibited exocytosis, as monitored by membrane capacitance measurements. Finally, the electrophysiological approach showed that bovine chromaffin cells which were intracellularly injected with antisense oligonucleotides targeted to the rab3a messenger exhibited an increasing potential to respond to repetitive stimulations. In contrast, control cells showed a phenomenon of desensitization. These results provide clear evidence that Rab3a is involved in regulated exocytosis and suggest that Rab3a is a regulatory factor that prevents exocytosis from occurring unless secretion is triggered. Furthermore, it is proposed that Rab3a is involved in adaptive processes such as response habituation.     

The biochemistry of the neuron. Neurosecretory habituation to repetitive depolarizations in PC12 cells

Habituation in response to repetitive depolarization of PC12 cells can be used as a model for memory processes at the molecular level. In response to depolarization by high external potassium, a triphasic elevation in internal calcium levels occurred. Calcium elevation was maximal immediately after addition of the stimulus (phase 1), followed by a 2-min period in which the calcium level decreased (phase 2), leading to a new steady-state level which was higher than in the unstimulated cell (phase 3). In response to repetitive depolarizations, the calcium level in phase 1 was reduced by as much as 43%, and phase 3 was reduced by as much as 40%. By measuring the relationship between calcium elevation and secretion, it was shown that measured reductions in calcium levels were correlated with neurosecretory habituation. One of the components responsible for the reductions in calcium levels was a tetraethylammonium-sensitive potassium channel, and the habituation of this channel was reversed by addition of 4 beta-phorbol 12-myristate 13-acetate.