Sensitization and habituation of the swimming behavior in ascidian larvae to light

Ascidian larvae of Ciona intestinalis change their photic behavior during the course of development. Newly hatched larvae show no response to a light stimulus at any intensity. At 4 hr after hatching, larvae were induced to start to swimming upon the cessation of illumination, and to stop swimming upon the onset of illumination. At a weaker light intensity (5.0 x 10(-3) J/m (2).s), the larvae showed similar responses to either a single stimulus or repeated stimuli of onset and cessation of light until 10 hr after hatching. At a stronger light intensity (3.2 x 10(-1) J/m(2).s), when the stimulus was repeated, they showed sensitization and habituation of the swimming response. At 3 hr after hatching the larvae failed to show any response to an initial stimulus at any intensity of light, but after several repeated stimuli (sensitization) they showed a swimming response at light intensities above 4.0 x 10(-2) J/m (2).s. At 5 hr and with intensity above 1.0 x 10 (-2) J/m(2).s, the larvae showed photoresponses to the first stimulus, but after several repetitions the larvae failed to stop swimming upon the onset of light (habituation). A repeated series of stimuli at stronger intensities of light caused greater habituation; this habituation was retained for about 1 min. Since the larval central nervous system in Ciona is comprised of only about 100 neurons, learning behavior in ascidian larvae should provide insights for a minimal mechanism of memory in vertebrates.     

Morphological Alterations in Euglena gracilis Induced by Treatment with CTAB (Cetyltrimethylammonium Bromide) and Triton X-100: Correlations with Effects on Photophobic Behavioral Responses*

SYNOPSIS. Treatment of Euglena gracilis with the cationic detergent CTAB at concentrations of 0.05 mM or higher selectively inhibited the ability of the cells to respond with flagellar reorientation to a sudden decrease of light intensity (step-down photophobic response). The ability to respond similarly to an increase in light intensity (step-up photophobic response) was unaffected even at detergent concentrations at which the step-down response was completely inhibited. Electron microscopy of cells treated with 1.0 mM CTAB revealed selective destruction of the membrane of the reservoir and flagellum. No selective effects upon the step-down or step-up photophobic responses were found upon treatment of the cells with Triton X-100.     

Effect of pronase treatment on step-down and step-up photophobic responses in Euglena gracilis

Pronase-treated cells of Euglena gracilis Z show no discernible ultrastructural effects on the photoreceptor apparatus; however, there are physiological effects on swimming speed and on step-up and step-down photophobic responses, especially the latter. Pronase acts differently on the two photophobic responses: the step-down response is completely inhibited after 2 hr., whereas inhibition of the step-up response occurs in only 50% of the cells even after 24 hr. The effects are fully reversible, with step-up recovery quite rapid and step-down recovery considerably slower.     

Effects of sequential stimuli on Halobacterium salinarium photobehavior.

We analyzed the motor photoresponses of Halobacterium salinarium to different test stimuli applied after a first photophobic response produced by a step-down of red-orange light (prestimulus). We observed that pulses given with a suitable delay after the prestimulus produced unusual responses. Pulses of blue, green, or red-orange light, each eliciting no response when applied alone, produced a secondary photophobic response when applied several seconds after the prestimulus; the same occurred with a negative blue pulse (rapid shut-off and turning on of a blue light). Conversely, no secondary photophobic response was observed when the test stimulus was a step (a step-up for red-orange light, a step-down for blue light) of the same wavelength and intensity. When the delay was varied, different results were obtained with different wavelengths; red-orange pulses were typically effective in producing a secondary photophobic response, even with a delay of 2 s, whereas the response to a blue pulse was suppressed when the test stimulus was applied within 5 s after the prestimulus. The secondary photophobic response to pulses was abolished by reducing the intensity of the prestimulus without affecting the primary photophobic response. These results, some of which were previously reported in the literature as inverse effects, must be produced by a facilitating mechanism depending on the prestimulus itself, the occurrence of reversals being per se ineffective. The fact that red-orange test stimuli are facilitated even at the shortest delay, whereas those of different wavelengths become effective only after several seconds, suggests that the putative mechanism of the facilitating effect is specific for different signaling pathways.     

A TEST OF TWO POSSIBLE MECHANISMS FOR PHOTOTACTIC STEERING IN VOLVOX CARTERI (CHLOROPHYCEAE)

We tested two competing models that could explain how differential flagellar activity leads to phototactic turning in spheroids of Volvox carteri f. weismannia (Powers) Iyengar. In one model, turning results from the flagella of anterior cells in the lighted and shadowed hemispheres beating at different frequencies. In a competing model, turning results from a change in beat direction in these flagella. Both models successfully explain phototactic steering under constant illumination, but they make different predictions when colonies are exposed to abrupt changes in light intensity. If turning is due to control of flagellar beat frequency, both progression and rotation rates will change in the same direction and with similar magnitudes. If spheroid turning is due to a change in flagellar beat direction, a decreased rate of progression will accompany an increased rate of rotation and vice versa. We used video-microscopy to observe the behavior of positively phototactic V. carteri spheroids exposed to 10× step-up and step-down stimuli. After a step-up stimulus, spheroids slow their progression and rotation by equal amounts. No significant changes are reported in these parameters after the reciprocal step-down response. These observations are consistent with the variable flagellar frequency model and inconsistent with the variable flagellar direction model for phototactic turning. Switching the direction of light stimulus by 180° results in reorientation of positively phototactic spheroids. The kinetics of this reorientation did not precisely match the predictions of either model.     

Auditory pre-experience modulates classification of affect intensity: evidence for the evaluation of call salience by a non-human mammal,the bat <Emphasis Type="Italic">Megaderma lyra</Emphasis>

Introduction

Immediate responses towards emotional utterances in humans are determined by the acoustic structure and perceived relevance, i.e. salience, of the stimuli, and are controlled via a central feedback taking into account acoustic pre-experience. The present study explores whether the evaluation of stimulus salience in the acoustic communication of emotions is specifically human or has precursors in mammals. We created different pre-experiences by habituating bats (Megaderma lyra) to stimuli based on aggression, and response, calls from high or low intensity level agonistic interactions, respectively. Then we presented a test stimulus of opposite affect intensity of the same call type. We compared the modulation of response behaviour by affect intensity between the reciprocal experiments.

Results

For aggression call stimuli, the bats responded to the dishabituation stimuli independent of affect intensity, emphasising the attention-grabbing function of this call type. For response call stimuli, the bats responded to a high affect intensity test stimulus after experiencing stimuli of low affect intensity, but transferred habituation to a low affect intensity test stimulus after experiencing stimuli of high affect intensity. This transfer of habituation was not due to over-habituation as the bats responded to a frequency-shifted control stimulus. A direct comparison confirmed the asymmetric response behaviour in the reciprocal experiments.

Conclusions

Thus, the present study provides not only evidence for a discrimination of affect intensity, but also for an evaluation of stimulus salience, suggesting that basic assessment mechanisms involved in the perception of emotion are an ancestral trait in mammals.

     

Giant clams discriminate threats along a risk gradient and display varying habituation rates to different stimuli

It is often beneficial for animals to discriminate between different threats and to habituate to repeated exposures of benign stimuli. While much is known about risk perception in vertebrates and some invertebrates, risk perception in marine invertebrates is less extensively studied. One method to study risk perception is to habituate animals to a series of exposures to one stimulus, and then present a novel stimulus to test if it transfers habituation. Transfer of habituation is seen as a continued decrease in response while lack of transfer is seen either by having a similar or greater magnitude response. We asked whether giant clams (Tridacna maxima) discriminate between biologically relevant types of threats along a risk gradient. Giant clams retract their mantle and close their shell upon detecting a threat. While closed, they neither feed nor photosynthesize, and prior work has shown that the cost of being closed increases as the duration of their response increases. We recorded a clam's latency to emerge after simulated threats chosen to represent a risk gradient: exposure to a small shading event, a medium shading event, a large shading event (chosen to simulate fish swimming above them), tapping on their shell and touching their mantle (chosen to simulate different degrees of direct attack). Although these stimuli are initially perceived as threatening, we expected clams to habituate to them because they are ultimately non‐damaging and it would be costly for clams to remain closed for extended periods of time when there is no threat present. Clams had different initial latencies to emerge and different habituation rates to these treatments, and they did not transfer habituation to higher risk stimuli and to some lower risk stimuli. These results suggest that clams discriminated between these stimuli along a risk gradient and the lack of habituation transfer shows that the new stimulus was perceived as a potential threat. This study demonstrates that sessile bivalves can discern between levels of predatory threat. These photosynthetic clams may benefit from being able to categorize predator cues for efficient energy allocation.     

Circadian phase resetting in response to light-dark and dark-light transitions

Phase shifting of circadian systems by light has been attributed both to parametric effects on angular velocity elicited by a tonic response to the luminance level and to nonparametric instantaneous shifts induced by a phasic response to the dark-light (D>L) and light-dark (L>D) transitions. Claims of nonparametric responses are partly based on "step-PRCs," that is, phase response curves derived from such transitions. Step-PRCs in nocturnal mammals show mostly delays after lights-on and advances after lights-off, and therefore appear incompatible with phase delays generated by light around dusk and advances by light around dawn. We have pursued this paradox with 2 experimental protocols in mice. We first use the classic step-PRC protocol on wheel running activity, using the center of gravity as a phase marker to minimize the masking effects of light. The experiment was done for 3 different light intensities (1, 10, and 100 lux). D>L transitions evoke mostly delays and L>D transitions show no clear tendency to either delay or advance. Overall there is little or no circadian modulation. A 2nd protocol aimed to avoid the problem of masking by assessing phase before and after the light stimuli, both in DD. Light stimuli consisted of either a slow light intensity increase over 48 h followed by abruptly switching off the light, or an abrupt switch on followed by a slow decrease toward total darkness during 48 h. If the abrupt transitions were responsible for phase shifting, we expected large differences between the 2 stimuli. Both light stimuli yielded similar PRCs characterized by delays only with circadian modulation. The results can be adequately explained by a model in which all PRCs evoked by steps result in fact from tonic responses to the light following a step-up or preceding a step-down. In this model only the response reduction of tonic velocity change after the 1st hour is taken into account. The data obtained in both experiments are thus compatible with tonic velocity responses. Contrary to standard interpretation of step-PRCs, nonparametric responses to the transitions are unlikely since they would predict delays in response to lights-off, advances in response to lights-on, while the opposite was found. Although such responses cannot be fully excluded, parsimony does not require invocation of a role for transitions, since all the data can readily be explained by tonic velocity (parametric) effects, which must exist because of the dependence of tau on light intensity.     

Amplitude,latency, and habituation of the electrodermal response to acoustic stimuli in the frog

The electrodermal response (EDR) of frogs to various acoustic stimuli was measured in the form of the skin potential response (SPR). There was no correlation between the polarity of the SPR and the intensity of the stimuli. When different frequencies were presented at the same intensity, the amplitude of the SPR to each was inversely proportional to the sound pressure at which that frequency just elicited an SPR. The amplitude of the sound-induced SPR increased monotonically with increasing sound pressure. The latency of the SPR decreased with increasing intensity of the acoustic stimulus. Acoustic stimuli repeated at intervals of 1 and 2 min elicited responses with progressively decreased amplitude and increased latency; with 4 min intervals there was little habituation. Fatigue participates to only a very slight extent in reducing the amplitude of the SPR and increasing its latency. The results are compared with the published data on frogs and mammals, including humans.     

Photoresponse ontogeny and its relation to development of pineal organ and eye in larval bagrid catfish Mystus nemurus (Valenciennes)

The artificially reared bagrid catfish Mystus nemurus was observed for the histological development of the pineal organ and retina and photoresponse in a test tank at hatching to 14?d after hatching. The pineal organ was functional at hatching, and the lens-like tissue was partly ossified forming a pineal window at 6?d. The retina became morphologically functional when the outer segments of single cones were formed, and the eyes were innervated with the optic tectum at 18?h and rods were formed at 36?h. Long and thin single cones were not observed. The larvae exhibited undirected kinetic movement at hatching to 12?h and directed tactic swimming away from a torch after 18?h in response to a torch light. The photoresponse of the larvae was negative at hatching to 30?h and at 6?d to the end of the observation at 14?d, but neutral during a period at 36?h to 5?d. It was evident that the kinetic movement was mediated by light perception with the pineal organ, which was not capable of detecting directed signal information, and that the larvae were capable of directed tactic movement only when vision was involved. The vigorous negative phototaxis at 6–14?d was attributed to the improvement of photosensitivity of the retina and the pineal organ.     

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     

Control by Ammonium Ion of the Change from Step-Up to Step-Down Photophobically Responding Cells in the Flagellate Alga Euglena gracilis

The regulation between step-down and step-up photophobic responses,resulting in photoaccumulation of the cells in an actinic lighttrap or cells' avoidance from an excessive illumination, iscrucially important for the survival of phototrophic organismssuch as Euglena gracilis. As for the factors involved in thisregulation in Euglena gracilis, we for the first time reporthere that ammonium ion specifically enhances step-down photophobicresponse, together with the effects of L-methionine-DL-sulfoximine(L-MSO), an inhibitor of ammonium assimilation, to specificallyenhance step-up photophobic response. The apparent positivecorrelation between the degree of greening and the step-downphotophobic response did not seem to reflect real causal relationshipin view of the results with effects of gabaculine, an inhibitorof -aminolaevulinic acid (-ALA) formation. The transmissionof stigma and step-down appearance did not show any correlationeither, in contrast to a previous assumption by other authors.Cycloheximide (CHX), an inhibitor of eukaryotic protein synthesis,suppressed step-down appearance and enhanced step-up appearance,probably suggesting an involvement of some (newly synthesized)protein(s) specifically in the step-down photosignal detectionand/or signal transduction process(es). (Received August 18, 1998; Accepted December 3, 1998)     

光照强度与光周期对虎斑乌贼胚胎发育的影响

为探究光照对虎斑乌贼受精卵孵化的影响,确定其胚胎发育的最佳光照条件,本研究采用单因子试验方法,分析了不同光照强度(10、30、50、70、90 μmol·m^-2·s^-1)和光周期L∶D(24 h∶0 h、18 h∶6 h、12 h∶12 h、6 h∶18 h、0 h∶24 h)对虎斑乌贼胚胎发育的影响.结果表明: 不同光照强度对虎斑乌贼胚胎发育的孵化率、卵黄囊断裂率、培育周期、初孵幼体体质量与胴长均影响显著;而对孵化周期和幼体出膜7 d后存活率无显著影响.其中孵化率、培育周期、初孵幼体体质量与胴长随着光照强度的增强先增大后减小,而卵黄囊断裂率则逐渐增大.最适光照强度为30 μmol·m^-2·s^-1,此光照强度下孵化率为(90.0±4.1)%,卵黄囊断裂率为(7.3±1.5)%,培育周期为(25.50±0.35) d,孵化周期为(8.10±0.89) d,初孵幼体体质量为(0.213±0.011) g,胴长为(1.013±0.022) cm,出膜7 d后存活率为(97.1±4.0)%.不同光周期对虎斑乌贼胚胎发育的孵化率、培育周期、孵化周期均影响显著,而对卵黄囊断裂率、初孵幼体体质量、胴长和幼体出膜7 d后存活率无显著影响.其中孵化率和孵化周期随着光照时间的增加呈现先增大后减小的变化.最适光周期为LD(12 h12 h),此光周期下孵化率达(88.7±1.8)%,卵黄囊断裂率为(8.7±1.8)%,培育周期为(25.00±0.50) d,孵化周期为(7.00±3.20) d,初孵幼体体质量为(0.209±0.005) g,胴长为(0.998±0.026) cm,出膜7 d后存活率为(96.8±7.1)%.说明弱光照强度30 μmol·m^-2·s^-1和半日光照强度L∶D(12 h∶12 h)更有利于虎斑乌贼的胚胎孵化.在实际生产中,应避免阳光直射,采取适当的遮光措施.     

Step-up photophobic response in the ciliate,Stentor coeruleus

The avoidance by Stentor coeruleus of a light trap is caused by a step-up photophobic response. The phobic response invariably consists of a delay of about 200 ms, a stop response, a turn to one side, and resumption of swimming in the new direction. After this the cells enter a refractory period of 1–3 s following a phobic response, during which they will not give a second response. Phobic responses can be elicited by spatial and temporal increases in light intensity. The action spectrum for the step-up photophobic response resembles the absorption spectrum of stentorin, the proposed photoreceptor pigment, and of its chromophore, hypericin.The phobic response is specifically inhibited by the protonophorous uncouplers TPMP⁺ and FCCP but not by the ionophores gramicidin and A23187. Since the uncouplers block light-induced membrane potential changes at the same concentrations, it has been proposed that the primary photoreception causes a light-induced potential change, which in turn, induces a motor response.Abbreviations TPMP⁺ triphenyl methyl phosphonium bromide - FCCP carbonylcyanide p-trifluoromethoxy-phenylhydrazone     

A one-instant mechanism of phototaxis in the cyanobacterium Phormidium uncinatum

Abstract The front portion ('head') of a Phormidium uncinatum trichome responds to a step-down in light intensity [10], whereas the rear end ('tail') responds to step-up stimuli [11]. We studied this phenomenon further and found that: (i) illumination of the head caused a reversal within 1 min in only 6% of the trichomes, whereas illumination of the tail produced a reversal in 56% of trichomes; (ii) if a light spot trained on the head of a trichome was moved together with the trichome, there were no reversals for > 20 min, while the normal rate of spontaneous reversals was once per 3–5 min. Shifting the light spot from the head to the tail caused a reversal within 1–2 min; (iii) both the step-up response of the tail and phototaxis were suppressed by an inhibitor of methylation, ethionine, but not by inhibitors of photosynthesis (DCMU, DBMIB); phototaxis and the step-up response of the tail were absent in red light ( λ > 670 nm). It was concluded that trichomes of P. uncinatum possess a one-instant mechanism of phototaxis, which involves a simultaneous comparison of light intensities between two parts of the organism.     

Neural cell adhesion molecule (NCAM-/-) null mice show impaired sensitization of the startle response

The neural cell adhesion molecule (NCAM) plays important roles in development of the nervous system and in synaptic plasticity and memory formation in the adult. The present study sought to further investigate the role of NCAM in learning by testing habituation and footshock sensitization learning of the startle response (SR) in NCAM null mutant (NCAM-/-) and wildtype littermate (NCAM+/+) mice. Whereas habituation is a form of non-associative learning, footshock sensitization is induced by rapid contextual fear conditioning. Habituation was tested by repetitive presentation of acoustic and tactile startle stimuli. Although NCAM-/- mice showed differences in sensitivity in both stimulus modalities, habituation learning was intact in NCAM-/- mice, suggesting that NCAM does not play a role in the mechanisms underlying synaptic plasticity in the startle pathway. Footshock sensitization was elicited by presentation of electric footshocks between two series of acoustic stimuli. In contrast to habituation, footshock sensitization learning was attenuated in NCAM-/- mice: the acoustic SR increase after the footshocks was lower in the mutant than in wildtype mice, indicating that NCAM plays an important role in the relevant brain areas, such as amygdala and/or the hippocampus.     

Dynamics of the activity of rabbit visual cortex neurons during elaboration of elementary conditioned reflexes to time and association

Elaboration of a reflex to time (with omissions of stimuli) and of association; light--light + electrocutaneous stimulation of the paw was studied on neurones of the rabbit visual cortex. It was shown that by similarity of patterns of the discharge to a conditioned stimulus and to reinforcement, 83% of neurones reveal the formation of a reflex to time, and 57%--elaboration of association. Three ways of coding plastic reorganizations of the neuronal discharges are suggested; by the total number of spikes in the response, by the total sum of inhibitory periods, and by the pattern of the response. It has been found that in the reflex to time the early components of the response to the stimulus are reproduced during omissions; in elaboration of the association the late components of the discharge reaction to reinforcement are mainly repeated. Most cells with plastic reorganizations possessed polysensority and revealed discharge sensitization during habituation.     

Cytological basis of photoresponsive behavior in a sponge larva.

Ontogenetic changes in the photoresponse of larvae from the demosponge Reneira sp. were studied by analyzing the swimming paths of individual larvae exposed to diffuse white light. Larvae swam upward upon release from the adult, but were negatively phototactic until at least 12 hours after release. The larval photoreceptors are presumed to be a posterior ring of columnar monociliated epithelial cells that possess 120-microm-long cilia and pigment-filled protrusions. A sudden increase in light intensity caused these cilia to become rigidly straight. If the light intensity remained high, the cilia gradually bent over the pigmented vesicles in the adjacent cytoplasm, and thus covered one entire pole of the larva. The response was reversed upon a sudden decrease in light intensity. The ciliated cells were sensitive to changes in light intensity in larvae of all ages. This response is similar to the shadow response in tunicate larvae or the shading of the photoreceptor in Euglena and is postulated to allow the larvae to steer away from brighter light to darker areas, such as under coral rubble-the preferred site of the adult sponge on the reef flat. In the absence of a coordinating system in cellular sponges, the spatial organization and autonomous behavior of the pigmented posterior cells control the rapid responses to light shown by these larvae.     

Responses to repeated oral irritation by capsaicin, cinnamaldehyde and ethanol in PROP tasters and non-tasters

Both increases (sensitization) and decreases (desensitization) in oral irritation have been reported in response to repeated short-term stimulation by compounds such as capsaicin, zingerone and menthol. It is unclear why one irritant would show sensitization and another desensitization, and this is further complicated by substantial inter-individual variation in response patterns. These variations may be the result of individual differences such as that represented by sensitivity to 6-n-propylthiouracil (PROP), which has been associated with variation in the overall intensity of irritation. In addition, comparisons between irritants have almost always involved inter-study comparisons, entailing different subject groups and frequently different methods. In the studies reported here, responses to three irritants-capsaicin, cinnamaldehyde and ethanol-were examined as a function of PROP taster status. A common core of subjects also received all three irritants, allowing an assessment of the extent to which different response patterns between irritants seen previously were the result of different properties of the irritants themselves. Over a series of ten stimuli presented at 1 min intervals, PROP taster status differentiated subject responses on the basis of overall intensity, but not the pattern of responses over repeated stimulation. The group response to ethanol and cinnamaldehyde was desensitization, a pattern also shown by most of the individual subjects. In contrast, the group response to capsaicin was neither clear sensitization nor desensitization, reflecting much greater individual variability in response patterns. It is suggested that the time course to a single irritant stimulus largely determines between irritant response variations, while the inter-stimulus interval (ISI) used for a given irritant will have critical values for showing predominantly sensitization or desensitization.     

Habituation and dishabituation mediated by the peripheral and central neural circuits of the siphon of aplysia

The siphon withdrawal response evoked by a weak tactile (water drop) or light stimulus is mediated primarily by neurons in the siphon. Central neurons (abdominal ganglion) contribute very little since the response amplitude and latency are not changed following removal of the abdominal ganglion. Similarly, habituation and dishabituation of this withdrawal response are not different after removal of the abdominal ganglion, indicating that the peripheral neural circuit in the isolated siphon can mediate habituation itself, and thus has many of the properties attributed to central neurons. Responses evoked by electrical stimulation of the siphon nerve habituate, depending upon the stimulus intensity and interval. These habituated responses may be dishabituated by tactile or light stimulation of the siphon. These results show that each neural system, peripheral and central, has an excitatory modulatory influence on the other. Normally adaptive siphon responses must be shaped by the integrated activity of both of these neural systems.