The release of attack and escape behavior by vibratory stimuli in a wandering spider (Cupiennim salei keys.)

Summary The wandering spiderCupiennius salei responds to vibration of the substrate either with predatory behavior (approach) or with a startle reaction or escape behavior (withdrawal) (Fig. 3). The effects of different parameters of the signal in releasing this behavior were studied by applying various artificial stimuli to a spider standing on a vibrating platform with one or more legs. Receptors sensitive to substrate vibration and the trichobothria, which respond to airborne vibration, together determine the response. Spiders without trichobothria: The type of response to vertical vibrations isfrequency-dependent (Fig. 4a), with predatory reactions predominant at low frequencies (3–4 Hz), and withdrawal reactions at high frequencies (350–460 Hz). Whereas approach is most likely to occur at an intermediate, frequency-dependentamplitude, the probability of withdrawal increases continuously with increasing amplitude (Fig. 6). With sine wave stimuli the lowest threshold amplitude for approach is 9 m peak-to-peak (550 Hz, range tested 1–550 Hz) whereas that for withdrawal is 17 m (800 Hz, range tested 1–800 Hz). The threshold for approach is lower by 6–8 dB whenband-limited noise is used, and the probability of an approach response increases as the bandwidth is expanded. The threshold curve for withdrawal, however, is the same in all cases (Fig. 4b and 5). The spider is capable of both frequency and amplitude discrimination.The metatarsal and pretarsal slit sense organs contribute to these responses as is shown by increased thresholds following their destruction (Fig- 7). Intact animals, with functional trichobothria as well as slit sense organs: They have lower thresholds for withdrawal (by ca. 10 dB; Fig. 9) and shorter reaction times than do spiders without trichobothria. Unlike animals without trichobothria the amplitude thresholds of intact animals to bandlimited noise are ca. 7.5 dB lower than those to sine wave stimuli. The approach threshold is the same as that of spiders without trichobothria. According to direct observation the trichobothria are deflected by airborne sound generated by the substrate motion; the deflection angle increases with both amplitude and frequency of substrate vibration (Fig. 10).There is acentral nervous interaction between the signals from the trichobothria and the slit sense organs with the following basic properties: when both of the two receptor systems receive either a prey-like stimulus or a stimulus eliciting withdrawal their effects add, but when the trichobothria receive stimuli unlike prey they inhibit the approach reaction that would otherwise be triggered by substrate vibration.     

Frequency response characteristics of electroreceptors in weakly electric fish (Gymnotoidei) with a pulse discharge

Summary Three species of Gymnotid fish, two species ofHypopomus andRhamphichthys rostratus, each having pulse type electric organ discharges (EOD) of different durations were studied to learn if any correlation exists between the spectral composition of the species specific EOD pulse and the frequency response characteristics of that species' electroreceptors. The receptor population consisted of two major categories (examples in Fig. 3). One category, termed pulse marker receptors, responded to suprathreshold stimulus pulses with a single spike at a short (<2 ms) latency. These receptors were tuned to the higher frequency components of a species' EOD (Fig. 4A) and were always 5 to 10 dB less sensitive than any other electroreceptors within a given species. The second major receptor category, burst duration coders, responded to an electrical stimulus with a burst of spikes at a longer latency, burst length was a function of stimulus amplitude. This second category could be further divided into three sub-categories according to the receptors' frequency response characteristics. The most commonly seen subcategory, wide band receptors (Fig. 4B), responded best to stimuli having frequencies equal to the dominant frequency component of the species' EOD in the two species ofHypopomus studied. A second subcategory, narrow band receptors (Fig. 4 A), had frequency response characteristics similar to those of the pulse marker receptors; however, these had thresholds 10 dB lower than those of the pulse marker. The third subcategory of burst duration coders, low frequency receptors (Fig. 4 C, D), responded best to stimulus frequencies ranging from about 50 to 150 Hz. Mechanisms of coding stimulus amplitude and responses to prolonged sinusoidal electrical stimuli were also studied in the various receptor types.It is suggested that the differences in the major receptor types and the different frequency response characteristics of the electroreceptors within a given species allows the animals to identify and evaluate signals resulting from their own EOD, the EODs of conspecifics and electrical stimuli generated by other species of electric fish.Supported by NIH Grant #1 RO1 NS 12337-01     

Filtering of behaviourally relevant temporal parameters of a grasshopper's song by an auditory interneuron

Summary In females of the acridid grasshopperChorthippus biguttulus, thoracic auditory interneurons were investigated with respect to their selectivity for temporal parameters of the conspecific song. Special attention was given to the detection of small gaps in the syllables of the song, since behavioural experiments have shown that the presence or absence of gaps is critical for the female's Innate Releasing Mechanism (cf. Fig. 1).The spiking response of one ascending interneuron, the AN4, shows filtering properties which closely resemble the behavioural reactions (cf. Figs. 1, 3 and 5b). The difference in the AN4's reaction to stimuli with gaps and uninterrupted stimuli is maintained over the behaviourally relevant intensity range (Fig. 4). This reaction is reliable enough that the stimulus type could be inferred by higher centres even from single stimulus presentations. Hence, this neuron is likely to participate in the task of gap detection and probably is a part of the neuronal filter network which determines the characteristics of the Innate Releasing Mechanism of this species. However, this interneuron is not species-specific: A homologue exists in other acridids as well and, inLocusta migratoria, has similar response characteristics (Fig. 6). The inferences of this observation for the evolution of an Innate Releasing Mechanism are discussed.Abbreviations CNS central nervous system - PST-histogram post-stimulus-time-histogram - SPL sound pressure level - IRM Innate Releasing Mechanism     

Facilitation at crayfish neuromuscular junctions

Electrophysical recordings from opener muscle fibers in the crayfishProcambarus clarkii (Fig. 1) show that pre-synaptic facilitation at terminals of the single excitatory axon usually decays in a dual-exponential fashion after a single pulse or after a train of pulses (Figs. 2, 3, 7, 9), as has been reported for frog neuromuscular junctions (Mallart and Martin, 1967) and squid giant synapses (Charlton and Bittner, 1974, 1976). Furthermore, the second component of decay at crayfish synapses is associated with a break in the monotonic decay of the first component, a result which suggests that the decay of facilitation is not due to the simple diffusion of some substance (such as calcium) from specialized release sites.The growth of facilitation at all opener synapses during trains of equalinterval stimuli could not be predicted by assuming that each pulse contributed an equal amount of facilitation which summed linearly with that remaining from all previous stimuli (Figs. 4, 6; Table 2), as reported for synapses in frog and squid. During high frequency stimulation (>40 Hz), those terminals which facilitate dramatically (highF _e synapses) show much greater amounts of facilitation than that predicted by the linear summation model (Figs. 4, 8), whereas other terminals (lowF _e synapses) show much less facilitation than predicted (Fig. 6). The rate of growth of facilitation was often very constant at various stimulus rates in highF _e or mixed type synapses (Figs. 4, 8, 10)-a result not predicted by the linear summation model. Finally, when highF _e synapses were stimulated at different frequencies, the rate of growth of facilitation changed dramatically in a fashion not predictable using linear summation (Mallert and Martin, 1967) or power law (Linder, 1974) models.     

Effects of background structure on the discrimination of configurational moving prey dummies by toadsBufo bufo (L.)

Summary The prey-catching activity of the toadBufo b. bufo was measured in response to various configurational moving two-dimensional black or white stimuli contrasting with various homogeneous or structured backgrounds (Figs. 1 to 5).Area discrimination was tested with squares of different sizes,configurational discrimination with stripes of equal size and different configuration (worm or antiworm), andlength discrimination with worm-like stripes of different length. Signal Extraction. A 2×5 mm² wormlike stripe of a luminanceL _s36 cd×m^–2, for example, was practically not resolved from a homogeneous background of almost the same luminanceL _b = 36. But it could be well detected if the background was structured ( ); at a given luminance ( ) the releasing value of the grey stimulus (L _s= 36) increased to some extent with structure width of the background (Fig. 1 c-e). Configurational Discrimination. The basic stimulus response relationships were maintained, if Configurational stimuli were moved against black, white, grey or structured backgrounds. However, in the range of short stripes (xl= 5 mm) the worm/antiworm discrimination was significantly better withblack stimuli moving against white background than forwhite against black (curvesa andc in Figs. 2A and 3A). The Configurational selectivity in response to white wormlike and antiwormlike stripes increased if stimuli were moved against a grey or a structured background (curvesa andc in Figs. 2 and 3B-E forxl5 mm). Length Discrimination. Relatively short stripes (close to the square configuration) and relatively long ones were discriminated less well than those in a medium size range. The optimal discrimination range was different for black stimuli (range: 3xl ₁6.5 mm) and white stimuli (range: 5xl ₁ 10 mm) (Fig. 4A, B). Discrimination in this range could be enhanced to some extent if the background was structured. These results were consistent for artificially (Fig. 4A) and naturally structured backgrounds (Fig. 5A-C).The results show that stimulus discrimination in toads depends largely on the values of Configurational parameters. The background structure may have distinct effects on stimulus perception, i.e., either masking or facilitation.     

A behavioral study of vibrational sensitivity in the pigeon (Columba livia)

Summary The pigeon (Columba livia) has a well-developed ability to detect weak vibrations. Using the method of heart-rate conditioning the vibrational sensitivity was determined for four pigeons at an error probability of P<0.025. The threshold-frequency relationships indicate that the greatest sensitivity to vibrational stimuli is found in the frequency range from 300 to 1,000 Hz with thresholds of about 0.1 m; lowest threshold is 0.04 m at 500 Hz (Fig. 4). Pigeons can respond not only to the frequency of a stimulus, but also to its intensity. The interval decrement (in %) of ECG is a positive correlative function of the stimulus intensity, the calculated values being approximately 4–5% per order of magnitude of the stimulus amplitude (in m) at best frequencies (Fig. 5). The value of vibration detection for birds is discussed.Abbreviation ECG electrocardiogram     

Response characteristics of wide-field non-habituating non-directional motion detecting neurons in the optic lobe of the locust,Locusta migratoria

1. Extracellular recordings from wide-field nonhabituating non-directional (ND) motion detecting neurons in the second optic chiasma of the locust Locusta migratoria are presented. The responses to various types of stepwise moving spot and bar stimuli were monitored (Fig. 1)
2. Stepwise motion in all directions elicited bursts of spikes. The response is inhibited at stimulus velocities above 5°/s. At velocities above 10°/s the ND neurons are slightly more sensitive to motion in the horizontal direction than to motion in the vertical direction (Fig. 2). The ND cells have a preference for small moving stimuli (Fig. 3).
3. The motion response has two peaks. The latency of the second peak depends on stimulus size and stimulus velocity. Increasing the height from 0.1 to 23.5° of a 5°/s moving bar results in a lowering of this latency time from 176 to 130 ms (Fig. 4). When the velocity from a single 0.1° spot is increased from 1 to 16°/s, the latency decreases from 282 to 180 ms (Figs. 5–6).
4. A change-of-direction sensitivity is displayed. Stepwise motion in one particular direction produces a continuous burst of spike discharges. Reversal or change in direction leads to an inhibition of the response (Fig. 7).
5. It shows that non-directional motion perception of the wide-field ND cells can simply be explained by combining self-and lateral inhibition.

     

Neuronal responses in the tectum opticum ofSalamandra to visual prey stimuli

Summary In the tectum opticum ofSalamandra salamandra neurons were recorded that showed different selectivity to visual prey stimulus parameters. 21 of 80 neurons responded stronger to rectangles oriented horizontally (wormlike configuration) than to the same patterns oriented vertically. With increasing stimulus velocity, however, these neurons showed non-uniform response characteristics. Although there are partial similarities between behavior and neuronal activity, no response curve of tectal neurons corresponds strictly to response curves of salamander preycapture behavior. So none of the neuron types can be called a prey detector.Supported by the Deutsche Forschungsgemeinschaft     

Spectral mechanisms of the compound eye in the fireflyPhotinus pyralis (Coleoptera: Lampyridae)

Summary Electroretinograms (ERG) were recorded from dark- and chromatic-adapted compound eyes in the dusk-active firefly,Photinus pyralis , at different wavelengths ranging from 320 to 700 run and over 4.5 log units change in stimulus intensity. ERG waveforms differed in the short (near-UV and violet) and long (yellow) wavelengths (Fig. 1). Waveform differences were quantitated by analysis of rise and fall times as a function of the amplitude of the response. Rise times were found to be relatively constant for all stimulus wavelengths. However, variations in the fall times were detected and followed characteristically different functions for short and long wavelengths (Fig. 2).No significant differences in the slopes of the Vlog-I curves at different stimulus wavelengths were observed (Fig. 3).Spectral sensitivity curves obtained from the ventral sector in dark- and chromatic-adapted conditions revealed peaks in the short ( max 400 nm: Fig. 4; max 430 nm: Fig. 5 A; and max 380 nm; Fig. 5B) and long ( max 570 nm: Figs. 4, 5) wavelengths, suggesting the presence of two spectral mechanisms. The long wavelength (yellow) mechanism was in close tune with the species bioluminescence emission spectrum (Fig. 4B).This investigation was supported in part by NIH Research Grant # EY-00490 (to R.M.C.); Research Grant # 01794N from the Research Foundation of the City University of New York (to A.B.L.); NIGMS Training Grant #1 TO 2 GM 05010-01 MARC (to J.A.H.); and NSF Grant # HES-75-09824 (to C.O.T.). We thank Tom Jensen for technical assistance, Barry Schuttler for his courtesy in allowing us to collect fireflies at his farm, Jean Lall for editorial assistance, and the two anonymous referees whose comments added considerably to the quality of this paper.     

Discrimination of objects through electrolocation in the weakly electric fish,Gnathonemus petersii

Summary Three weakly electric fish (Gnathonemus petersii) were force-choice trained in a two-alternative procedure to discriminate between objects differing in their electrical characteristics. The objects were carbon dipoles in plexiglass tubing (length 2.5 cm, diameter 0.6 cm). Their electrical characteristics could be changed by varying the impedance of an external circuit to which they were connected (Fig. 1). In one (the capacitance dipole) the resistance was very low(< 3 ) and the capcitance variable. In the other (the resistance dipole) the resistance was variable and the capacitance low (<50 pF).Capacitances from several hundred pF (lower thresholds, Fig. 2) to several hundred nF (upper thresholds, Fig. 3) could be discriminated from both insulators and good conductors. In all cases the reward-negative stimulus was the capacitance dipole, which was avoided by all fish spontaneously. Thresholds were defined at 70% correct choices.The fish were then tested for their ability to discriminate between one object with a given capacitance and another with resistances varying from 3 to 200 k. The capacitance dipole continued to be the negative stimulus throughout. All 3 fish avoided it in at least 80% of the trials at each stimulus combination (Fig. 4). This result suggests that Gnathonemus perceives the capacitance and the resistance of objects differentially.The effect of the dipole-objects as well as some natural objects on the local EOD was recorded differentially very close to the fish's skin (Fig. 5). The amplitude of the local EODs was affected by all types of objects as they approached the skin. However, the waveform was changed only by capacitance dipoles and some natural objects (Figs. 6 and 7). It appears that the fish perceive not only intensity changes in the local EOD but wave-form deformations as well and can thus distinguish objects of different complex impedances.Abbreviations EOD electric organ discharge - f _max maximal spectral frequency - GP Gnathonemus petersii - LFS local filtered signal - PMA probing motor act - S+ positive stimulus - S negative stimulus     

Simultaneous Detection of P300 and Steady-State Visually Evoked Potentials for Hybrid Brain-Computer Interface

Objective

We study the feasibility of a hybrid Brain-Computer Interface (BCI) combining simultaneous visual oddball and Steady-State Visually Evoked Potential (SSVEP) paradigms, where both types of stimuli are superimposed on a computer screen. Potentially, such a combination could result in a system being able to operate faster than a purely P300-based BCI and encode more targets than a purely SSVEP-based BCI.

Approach

We analyse the interactions between the brain responses of the two paradigms, and assess the possibility to detect simultaneously the brain activity evoked by both paradigms, in a series of 3 experiments where EEG data are analysed offline.

Main Results

Despite differences in the shape of the P300 response between pure oddball and hybrid condition, we observe that the classification accuracy of this P300 response is not affected by the SSVEP stimulation. We do not observe either any effect of the oddball stimulation on the power of the SSVEP response in the frequency of stimulation. Finally results from the last experiment show the possibility of detecting both types of brain responses simultaneously and suggest not only the feasibility of such hybrid BCI but also a gain over pure oddball- and pure SSVEP-based BCIs in terms of communication rate.     

Behavioral detection of electric signal waveform distortion in the weakly electric fish,Gnathonemus petersii

The novelty response of weakly electric mormyrids is a transient acceleration of the rate of electric organ discharges (EOD) elicited by a change in stimulus input. In this study, we used it as a tool to test whether Gnathonemus petersii can perceive minute waveform distortions of its EOD that are caused by capacitive objects, as would occur during electrolocation. Four predictions of a hypothesis concerning the mechanism of capacitance detection were tested and confirmed: (1) G. petersii exhibited a strong novelty response to computer-generated (synthetic) electric stimuli that mimic both the waveform and frequency shifts of the EOD caused by natural capacitive objects (Fig. 3). (2) Similar responses were elicited by synthetic stimuli in which only the waveform distortion due to phase shifting the EOD frequency components was present (Fig. 4). (3) Novelty responses could reliably be evoked by a constant amplitude phase shifted EOD that effects the entire body of the fish evenly, i.e., a phase difference across the body surface was lacking (Figs. 3, 4). (4) Local presentation of a phase-shifted EOD mimic that stimulated only a small number of electroreceptor organs at a single location was also effective in eliciting a behavioral response (Fig. 5).Our results indicate that waveform distortions due to phase shifts alone, i.e. independent of amplitude or frequency cues, are sufficient for the detection of capacitive, animate objects. Mormyrids perceive even minute waveform changes of their own EODs by centrally comparing the input of the two types of receptor cells within a single mormyromast electroreceptor organ. Thus, no comparison of differentially affected body regions is necessary. This shows that G. petersii indeed uses a unique mechanism for signal analysis, which is different from the one employed by gymnotiform wavefish.Abbreviations EOD electric organ discharge - p-p-amplitude peak-to-peak amplitude     

Unusual discharge patterns of single fibers in the pigeon's auditory nerve

Summary Extracellular recording from single auditory nerve fibers in the pigeon,Columba livia, revealed some unusual discharge patterns of spontaneous and evoked activity.Time interval histograms (TIHs) of spontaneous activity showed a random interval distribution in 73% of the auditory fibers (Fig. 1a). The remaining 27% revealed periodicity in the TIHs (Fig. 1b–e), determined by the characteristic frequency (CF) of a given fiber. Normally, those fibers had a CF<2.2 kHz. In both cases spontaneous activity was irregular.The time pattern of quasiperiodic spontaneous firing in different auditory fibers is described by three main types of autocorrelation histograms (ACHs; decaying, nondecaying, and modulated), reflecting the spontaneous oscillations of the hair cell membrane potential (Fig. 1b–d).Single-tone suppression in auditory fibers with quasi-periodic spontaneous activity was found (Figs. 2, 10) and it could be observed if the eighth nerve was cut. There was no suppressive effect in fibres with random spontaneous firing.The frequency selectivity properties of auditory fibers were studied by means of an automatic method. Both simple (Fig. 4) and complex (Figs. 7, 8) response maps were found. Apart from the usual excitatory area, complex response maps were characterized by suppressive areas lying either above (Fig. 7), below (Fig. 8e), or on both sides of the CF (Fig. 8a–c). Generally, complex response maps were observed for fibers showing quasiperiodic spontaneous activity (Figs. 7, 8).Input-output functions at frequencies evoking single-tone suppression were nonmonotonic, while they were always monotonic at frequencies near the CF (Fig. 12).No difference in sharpness was observed between normal frequency threshold curves (FTCs) and exitatory areas of complex response maps (Fig. 9).On-off responses evoked by suppressive stimuli were found (Figs. 2, 3). They had a periodic pattern determined by the CF and did not depend on the stimulus frequency (Fig. 3).Low-CF fibers were observed which changed their time discharge structure to tone levels about 45 dB lower than their thresholds at the CF (Fig. 6).The observed features of the discharge patterns of the pigeon's auditory fibers reflect the distinctive nature of the fundamental mechanisms of auditory analysis in birds that are connected with electrical tuning of the hair cells and probably with the micromechanics of the bird's cochlea.Abbreviations ACH autocorrelation histogram - BP base period - CF characteristic frequency - FTC frequency threshold curve - IHC inner hair cell - OHC outer hair cell - PSTH peristimulus time histogram - TIH time interval histogram     

Binding of [3H]muscimol to calf cerebrocortical synaptic membranes and the effects of sulphur-containing convulsant and non-convulsant compounds

Endogenous and xenobiotic sulphur-containing convulsant and non-convulsant compounds containing structural moieties of, or bearing a structural resemblance to, GABA and homocysteine were tested in binding studies for their potency in displacing the GABA-mimetic [³H]muscimol from specific, high-affinity sites (K _d=3.6 nM;B _max=3.94 pmol/mg protein) on freeze-thawed, Triton-treated calf-brain synaptic membranes. The xenobiotic convulsants, 4-mercaptobutyric acid (MBA), 3-mercaptopropionic acid (3-MPA) and 2-mercaptopropionic acid (2-MPA) were found to be two-site competitive inhibitors exhibiting apparent inhibition affinity constants (K _i ^app ) of 5000 M, 3750 M, and 4800 M, respectively; while homocysteic acid (K _i ^app =4800 M) was shown to be a one-site partial competitive inhibitor. Intermediary metabolites of methionine: S-adenosyl-l-homocysteine,l-cysteine, the convulsantl-homocysteine, and its non-convulsant disulphide oxidation product, homocystine, were found to be one-site partial competitive inhibitors exhibitingK _i ^app values of 5750 M, 8350 M, 5000 M, and 510 M, respectively. The endogenous anticonvulsant neuroeffector, taurine, and the tripeptide, reduced glutathione (GSH) were shown to be, respectively, one-site (K _i=20 M) and two-site (K _i ^app =4300 M) competitive inhibitors of [³H]muscimol binding. These findings are discussed with regard to a previously proposed mechanism for the convulsant action of homocysteine.     

Music alters visual perception

Background

Visual perception is not a passive process: in order to efficiently process visual input, the brain actively uses previous knowledge (e.g., memory) and expectations about what the world should look like. However, perception is not only influenced by previous knowledge. Especially the perception of emotional stimuli is influenced by the emotional state of the observer. In other words, how we perceive the world does not only depend on what we know of the world, but also by how we feel. In this study, we further investigated the relation between mood and perception.

Methods and Findings

We let observers do a difficult stimulus detection task, in which they had to detect schematic happy and sad faces embedded in noise. Mood was manipulated by means of music. We found that observers were more accurate in detecting faces congruent with their mood, corroborating earlier research. However, in trials in which no actual face was presented, observers made a significant number of false alarms. The content of these false alarms, or illusory percepts, was strongly influenced by the observers'' mood.

Conclusions

As illusory percepts are believed to reflect the content of internal representations that are employed by the brain during top-down processing of visual input, we conclude that top-down modulation of visual processing is not purely predictive in nature: mood, in this case manipulated by music, may also directly alter the way we perceive the world.     

Changes in the auditory system of locusts (Locusta migratoria and Schistocerca gregaria) after deafferentation

Deafferentation experiments during postembryonic development show morphological and/or physiological changes of receptor fibers and of identified auditory interneurons in the CNS of the locusts Locusta migratoria and Schistocerca gregaria after unilateral ablation of one tympanic organ either in the larva or the adult animal.

Behavioral experiments on the visual processing of color stimuli inPieris brassicae L. (Lepidoptera)

Summary In spontaneous-choice experiments on the butterflyPieris brassicae L. (Pieridae), spectral-effectiveness and spectral-sensitivity functions were obtained for various behaviors.Pilot experiments with colored PVC films, for which the relative number of reflected quanta with regard to the given illumination had been calculated, showed that the feeding response is distinctly intensity-dependent (Fig. 4). The animals are also capable of color discrimination independent of this intensity discrimination;P. brassicae prefers blue to other colors (e.g., orange, red and purple) with higher relative quantum numbers (Fig. 3) and distinguishes golden yellow and red from gray shades as well as from black and white (Fig. 5a, b).The results of subsequent spontaneous-choice experiments, using as stimuli monochromatic lights with known quantum flux, indicate that the various visually controlled functional categories of behavior can be assigned to the following spectral regions (Figs. 6, 8): 1. The open-space reaction corresponds to the UV and violet region, ca. 320–420 nm; 2. The feeding reaction corresponds to the blue region, ca. 420–500 nm, and the orange-red region, ca. 590–610 nm; 3. Egg-laying and drumming correspond to the green-yellow region, ca. 520–580 or 590 nm, respectively. The intensity dependence of the individual responses is again apparent in these experiments with monochromatic light stimuli (Figs. 7, 11, 12a).Even at very high intensities and when the content of the relevant wavelength is high, white light is practically ineffective for the feeding reaction (Fig. 9), drumming and egg-laying (cf. Results), regardless of its UV content. The open-space reaction, however, can be elicited by white light according to its UV content (Fig. 12 b).P. brassicae cannot be trained to give a feeding response to monochromatic light stimuli (Fig. 10).Experiments with mixtures of wavelengths have shown that the combination of the two maxima in the spectral sensitivity curve for the feeding reaction (=600 plus 447 nm) is just as effective as =447 nm alone (Fig. 13, left). Moreover, the mixture producing the hypothetical Pieris purple (=600 plus 370 nm) is no more or less effective in eliciting the feeding and open-space reactions than the more effective component for each of these reactions when presented alone (Fig. 13, right). With the mixture of =600 plus 558 nm, both the feeding reaction and drumming are distinctly reduced (Fig. 13, middle). This mixed color, unlike the other two mixtures tested, has a color quality different from that of the component colors.That the behavior ofP. brassicae is exclusively wavelength-specific can thus be ruled out. There are indications that wavelength-specific behavior and color vision are both present.Abbreviation RNQ relative number of quanta This publication is dedicated to Professor Dr. Dr.h.c. H. Autrum on the occasion of his 80th birthday     

Phonotactic specificity of the cricketTeleogryllus oceanicus: intensity-dependent selectivity for temporal parameters of the stimulus

Summary We have investigated the effects of alterations of several temporal parameters of auditory stimuli, as well as of stimulus intensity changes, on the attractiveness of these stimuli to femaleTeleogryllus oceanicus, as measured by monitoring sound-elicited flight steering responses. AlthoughT. oceanicus has a rhythmically complex calling song, females are attracted by a simpler model consisting of regularly repeating sound pulses. We have found that the two major temporal features of this model, sound pulse duration and pulse repetition rate, are both important for eliciting phonotactic steering responses.Stimuli with altered temporal features had intensity thresholds indistinguishable from the control stimulus (Fig. 3). The majority of crickets, however, ceased to respond to the altered stimuli when the stimulus intensity was sufficiently increased (Figs. 4–7). In some cases, intensity increases resulted in a reversal of the steering response from positive to negative (Fig. 10). Effects of altered temporal parameters were also apparent at lower stimulus intensities, where the amplitudes of steering responses to stimuli with altered parameters were smaller than those in response to the control stimulus (Figs. 8, 9).We considered the possibility that the cessation of responsiveness to stimuli with altered temporal features was due to a temporal pattern-specific diminution of binaural cues for sound localization at high intensities. Experiments performed with unilaterally deafened crickets (Fig. 11) led us to conclude that this was not the case, and that our findings instead reflect the properties of the song recognition mechanism.Abbreviations UIL upper intensity limit - RAF ratio of abdominal flexion