Electrical activities of a type of electroretinogram recorded from the ocellus of a jellyfish, Polyorchis penicillatus (Hydromedusae)

An electroretinogram (ERG), evoked by light stimuli, was recorded from ocelli of Polyorchis penicillatus (Hydromedusae). The ERG is a polyphasic response with a positive potential change at the onset of illumination followed by a slower biphasic pulse, and a positive deflection at the cessation of illumination which is followed by a series of high-frequency pulses. The most striking features of the initial pulse are its latency-log intensity relation and the gradation of pulse amplitude with respect to the intensity of the light stimulus and to different wavelengths. Maximum spectral sensitivity lies around 530 nm. Response patterns induced by shadowing and repeated stimulation of light- and dark-adapted ocelli are described. Morphological structures which could give rise to the mass response of the ocellus are discussed.     

棉铃虫蛾复眼光反应特性

用视网膜电位图(electroretinogram,ERG)技术研究了棉铃虫Helicoverpa armigera蛾暗适应过程中对单色光和白光刺激的光感受性变化。结果显示：(1)依ERG振幅大小(峰-峰值),在340～605 nm波谱内有3个大小不等的峰-主峰位于绿 黄光区562 nm,次峰在蓝光区483 nm,第3个峰在近紫外区400 nm,显示其至少有3种感受器;(2)性别、日龄及暗适应时间长短对其光谱敏感性有影响,低龄时雄蛾对单色光刺激较雌蛾敏感,高日龄时相反;1～5日龄内, 3日龄蛾的视网膜电位(ERP)值最高;随暗适应时间延长,其复眼对近紫外区400 nm敏感性明显增加;(3)一定光强度范围内,随单色光和白光光强度增强该蛾复眼的ERP值增大,初期增加较缓,中期较快,呈近似S型曲线,显示其复眼具有较强的光强度自调节和适应机制。     

中华通草蛉复眼光感受性

运用视网膜电位（Electroretinogram,ERG）技术,对中华通草蛉Chrysopa sinica Tjedar成虫复眼在暗适应过程中对单色光和白光刺激的光感受变化进行了测定。结果表明：（1）在340～605 nm光谱范围内该草蛉的光反应表现3个峰,其中最高峰位于562 nm,次峰在524 nm,第3峰在460 nm;（2）一定光强度（LogI=4.5～0）范围内,其复眼ERG值随光强度的增强而增大,呈近线性增长式样;（3）暗适应时间影响其复眼的ERG值大小,在暗适应100 min时其ERG值达到稳定;（4）中华通草蛉复眼ERG的波形由4个部分组成：开光反应、正相电位、持续负电位和闭光反应。     

不同光波及光强度下棉铃虫(Helicoverpa armigera)成虫的行为反应

运用室内行为实验方法研究了不同波长单色光和白光刺激刺激的棉铃虫「Ｈｅｌｉｃｏｖｅｒｐａ ａｒｍｉｇｅｒａ（Ｈｕｂｎｅｒ）」成虫趋光、避光反应及其与光强度之间的相互关系,结果显示：（１）一定时间暗适应的棉铃虫蛾对单光和白光刺激均具有趋光行为反应,依其趋光反应率大小,其光谱反应曲线在３４０－６０５ｎｍ波谱范围内,表现为大小较复杂上峰,其中两个峰分别在蓝光区４８３ｎｍ、紫外３４０ｎｍ,另外近紫外的４０ｎ     

The Spectral Sensitivities of Single Cells in the Median Ocellus of Limulus

The spectral sensitivities of single Limulus median ocellus photoreceptors have been determined from records of receptor potentials obtained using intracellular microelectrodes. One class of receptors, called UV cells (ultraviolet cells), depolarizes to near-UV light and is maximally sensitive at 360 nm; a Dartnall template fits the spectral sensitivity curve. A second class of receptors, called visible cells, depolarizes to visible light; the spectral sensitivity curve is fit by a Dartnall template with λ_max at 530 nm. Dark-adapted UV cells are about 2 log units more sensitive than dark-adapted visible cells. UV cells respond with a small hyperpolarization to visible light and the spectral sensitivity curve for this hyperpolarization peaks at 525–550 nm. Visible cells respond with a small hyperpolarization to UV light, and the spectral sensitivity curve for this response peaks at 350–375 nm. Rarely, a double-peaked (360 and 530 nm) spectral sensitivity curve is obtained; two photopigments are involved, as revealed by chromatic adaptation experiments. Thus there may be a small third class of receptor cells containing two photopigments.     

Vision in the edible snail: the spectral sensitivity of the dark-adapted eye]

The spectral sensitivity of the dark-adapted eye of Helix lucorum L. was investigated using a semi-intact preparation "ball of the eye--optic nerve--cerebral ganglion". The amplitudes of responses of the electroretinogram to monochromatic stimuli of different intensities were used for a reconstruction of the spectral sensitivity. The averaged curve of the spectral sensitivity coincided well with the Dartnall's nomogram for a pigment having the maximum of spectral sensitivity near 496 nm.     

The comparative photobehavior of laboratory-hatched and plankton-caught Balanus improvisus (Darwin) nauplii and the effects of 24-hour starvation

Stage II nauplii of Balanus improvisus (Darwin) were obtained from laboratory-maintained adult barnacles. The immediate phototactic and photokinetic response of laboratory nauplii to light stimuli of known wavelength (460–540 nm) and quantal intensity was determined through use of closed-circuit videotape recordings quantified for computer analysis. Spectral and light intensity responses were compared with previous results using nauplii collected from the plankton. In both cases, nauplii exhibit a primary peak response to light near 480 nm and a secondary peak near 520 nm. Although the spectral response and basic patterns of photobehavior remain similar in field and laboratory nauplii, sensitivity to light intensity is significantly reduced in laboratory nauplii. Responses of fed and 24-h starved laboratory nauplii were also compared at three salinities (15, 20, 30‰). Starvation for 24 h, although inducing no major change in photopositive and photokinetic response of nauplii, can slightly depress spontaneous swimming speed and raise the threshold of intensity response for phototaxis.     

The localisation of lead in the skin of light- and dark-adapted Xenopus laevis

Toads pretreated for 2 months on either a dark or a light background were then exposed to lead nitrate at 50 ppm lead for 21 days, the illumination regimes being maintained. Metal analysis of dorsal skin showed significantly higher lead levels (p less than 0.01) in dark-adapted toads. No precipitated lead deposits were observed at the ultrastructural level, necessitating X-ray microanalysis of sections containing melanophores, gland cells and general (non-melanophore) cytoplasm. Analysis showed the lead to be concentrated within the melanosomes of the melanophores, and to be significantly higher (p less than 0.01) in individual melanosomes of dark-adapted toads than in light adapted ones. Copper was also found to be concentrated in the melanosomes and was higher (p less than 0.01) in the melanosomes of the dark-adapted toads. The results are consistent with the known affinity of melanin for heavy metals and the documented increase in melanophore number under prolonged dark background regimes. Since all toads received the same lead exposure, the melanosome results give rise to speculation that higher melanin levels might occur in individual melanosomes of dark-adapted skin.     

The localisation of lead in the skin of light- and dark-adapted Xenopus laevis

Summary Toads pretreated for 2 months on either a dark or a light background were then exposed to lead nitrate at 50 ppm lead for 21 days, the illumination regimes being maintained. Metal analysis of dorsal skin showed significantly higher lead levels (p<0.01) in dark-adapted toads. No precipitated lead deposits were observed at the ultrastructural level, necessitating X-ray microanalysis of sections containing melanophores, gland cells and general (non-melanophore) cytoplasm. Analysis showed the lead to be concentrated within the melanosomes of the melanophores, and to be significantly higher (p<0.01) in individual melanosomes of dark-adapted toads than in light-adapted ones. Copper was also found to be concentrated in the melanosomes and was higher (p<0.01) in the melanosomes of the dark-adapted toads.The results are consistent with the known affinity of melanin for heavy metals and the documented increase in melanophore number under prolonged dark background regimes. Since all toads received the same lead exposure, the melanosome results give rise to speculation that higher melanin levels might occur in individual melanosomes of dark-adapted skin.     

Spectral sensitivities of photoreceptors and lamina monopolar cells in the dragonfly,Hemicordulia tau

Summary Five spectral types of photoreceptors with peak sensitivities at 330 nm, 410 nm, 460 nm, 525 nm and 630 nm were recorded from the ventral eye of the dragonfly, Hemicordulia tau. Often the 525 nm photoreceptors presented broader, and the 630 nm photoreceptors narrower, spectral sensitivities than would be excepted of a photopigment with the same peak sensitivity. Four types of lamina monopolar cells (cell types 1–4) were recognised from their dark-adapted spectral sensitivities and their anatomy. The anatomical identification allows tentative assignation to the monopolar cell classification from Sympetrum rubicundulum obtained using Golgi staining (Meinertzhagen and Armett-Kibel 1982). When dark-adapted, the monopolar cells had peak spectral sensitivities that were similar to single photoreceptors or appeared to pool receptor outputs, but in some cases spectral sensitivity changed markedly upon adaptation to white and to chromatic light, in one case (cell type 2) apparently switching off a UV-sensitive input.     

光谱和光强度对西花蓟马雌虫趋光行为的影响

利用行为学方法研究了光谱、光强对西花蓟马Frankliniella occidentalis (Pergande)雌成虫的趋、避光行为的影响。结果显示：（1）在340~605nm波谱内14个波长其光谱趋光行为反应为多峰型,峰间主次较明显。趋光行为反应中,蓝绿区498~524nm有一较宽峰,趋光率20.31%;其它各峰依大小次序分别位于紫光380nm、蓝光440nm;（２）避光行为反应中,蓝光440nm处略高,避光率17.19%;紫外340nm处亦有一峰,避光率15.63%;（３）随光强增强其趋光反应率增大,白光、380nm和524nm刺激时其光强趋光行为反应呈一倒“L”型式样,498nm为峰型,440nm时为一较缓的平直线型;光强最弱时仍均有一定趋光率 ,最强时均未出现高端平台;（４）随光强增强其避光反应率增大,440nm为较平缓直线;340nm刺激时为较缓波动线。结果表明：光谱对其趋光行为有很大影响,光强度的影响较大且影响大小与波长因素有关。     

Intracellular optical physiology of the bee's eye

Summary Intracellular optical physiology is a newly developed, non-invasive technique for recording from single types of insect photoreceptor cells. An intact animal is mounted on the goniometer stage of a double-beam, incident-light microspectrophotometer. The stimulating beam delivers monochromatic flashes that evoke pupillary responses from photoreceptor cells in a localized region of the eye. The measuring beam delivers red or infrared illumination that continuously measures the changes in reflectance that accompany the pupillary response. In this paper on the worker bee we demonstrate two experimental conditions under which only one of the three spectral types of photoreceptor dominates the measured response.When the eye is dark-adapted, and increases in reflectance are measured with an infrared beam, threshold responses evoked by long flashes (40 s or more) are dominated by that cell type which is most sensitive to the stimulus. The following data were taken from the dorsal (ventral) poles of the bee's eye: At 350 nm, a quantum flux of 0.1 (0.05)×10 ¹² photons/cm ²/s/numerical aperture of 0.2 produces a threshold response that originates only from the UV-receptors. At 430 nm, a quantum flux of 0.6 (0.2) units produces a threshold response that is dominated by the blue-receptors. At 530 nm, a flux of 1.0 (0.1) units produces a threshold response that originates only from the green-receptors.When the eye is red-adapted, the pupillary responses to short flashes (10 s or less) are dominated by the green-receptors. Under this condition the pupillary action-spectrum for sensitized green-receptors is the same as the electrophysiological spectral sensitivity function of the minimally coupled green-receptor. This is true throughout the spectral range 350 nm–650 nm (Fig. 3).If the duration of stimulating flashes is increased to 40 s, the shape of the action spectrum is unchanged for wavelengths greater than 470 nm, but is significantly elevated, by as much as 1.8 log-units, for wave-lengths less than 420 nm (Fig. 4). In this case the UV-receptors dominate the pupillary response at short wavelengths, while the green-receptors dominate it at long wavelengths.We used these effects to determine that all three spectral types of receptor are present in the regions of both dorsal and ventral poles, as well as in the frontal region of the eye.This work was supported by grants EY01140 and EY00785 from the National Eye Institute, U.S.P.H.S. (to GDB), by the Connecticut Lions Eye Research Foundation (to GDB), and by a grant from the University of Zurich (to RW), and by grant 3.529.075 from the Swiss National Science Foundation (to RW) including a Senior Research Fellowship awarded to GDB. We thank Dr. Thomas Labhart for many helpful discussions and for allowing us to refer to his unpublished data, and Dr. Doekele Stavenga for his critical, constructive comments.     

Non‐Selective and Time‐Dependent Behavioural Responses of Common Toads (Bufo bufo) to Predator Acoustic Cues

Acoustic predator recognition has rarely been studied in anurans, in spite of the fact that hearing is widespread in these animals and that it has been demonstrated to play an important role in both arthropods and other vertebrates. Using field playback experiments, we tested the hypothesis that adult common toads (Bufo bufo) are capable of recognizing natural vocalizations of a common predator, the Eurasian otter (Lutra lutra), and show antipredator responses. We found that toads exposed to both natural (two types of otter sounds) and synthetic stimuli [white noise (WN) and otter sound‐based amplitude modulated WN] increased time allocated to locomotion and escape behaviour. These responses were correlated with time elapsed from sunset to the onset of testing and were independent from the type of acoustic signal, toad features and other environmental factors monitored. We conclude that B. bufo has not developed a selective recognition of predator vocalizations, suggesting that low‐frequency or seismic sounds associated with predator movements may provide anurans with better cues about an approaching risk. We propose that the time‐dependent response to acoustic stimuli of common toads represents a case of threat‐sensitivity and demonstrates that it can occur even when the response to the threat is not predator specific.     

Photoresponses of the copepod Mesocyclops edax

The predatory copepod Mesocyclops edax is an important componentof many zooplankton communities where it typically makes extensivedid vertical migrations. To describe the effect of light onadults we measured their photoresponses in the laboratory. Theresponse spectrum is characterized by a wide plateau of greatestsensitivity from about 480 – 580 nm. These animals areadapted to perceive light during the day since their regionof maximum sensitivity overlaps the spectral region of highestquantal intensity underwater (575 – 700 nm). The thresholdintensity for positive phototaxis by dark adapted animals wasabout 5 x 10^–1 Wm^–2 at 540 nm, and they were positivelyphototactic up to an intensity of 5 x 10^–1 Wm^–2.Above this intensity phototaxis is no longer observed. Light-adaptedanimals were less sensitive than dark-adapted, but their generalpattern of response to light intensity did not differ. Thereis no rhythm in phototaxis. Their photoresponses may providea mechanism for controlling vertical migration so as to minimizeexposure to planktivorous fish. ¹Contribution No. 1375-AEL from UM-CEES, Appalachian EnvironmentalLaboratory.     

Physiological studies on pea tendrils

When tendrils which have been dark adapted for 3 days are mechanically stimulated, they will only coil appreciably if they are irradiated with light. A spectral response curve suggests that this is a blue light effect. Red or far red light do not modulate this response, but a high intensity flash of blue white light given before the actinic blue light blocks coiling for 30 min. The dark-adapted tendril, which has not been previously rubbed, has the ability to store the tactile sensory information for about 60 min, but loses it if it is not irradiated within 120 min after mechanical perturbation.     

Proximate control of diel vertical migration in Phyllosoma larvae of the Caribbean spiny lobster Panulirus argus

Phyllosoma larvae of the spiny lobster Panulirus argus undergo diel vertical migration (DVM), in which they are at depth during the day and nearer the surface at night. This study determined the visual spectral sensitivity of Stage I larvae and investigated whether light plays a proximate role in DVM as an exogenous cue and as an entrainment cue for an endogenous rhythm in vertical migration. Under constant conditions, larvae have a circadian rhythm (24.5-h period) in vertical swimming that resulted in a twilight DVM pattern. The behavioral response spectrum and electroretinogram recording indicated two photoreceptor spectral classes with maxima at 360 and 486 nm. When stimulated in an apparatus that simulated the underwater angular light distribution, dark-adapted larvae showed only positive phototaxis, with a threshold intensity of 1.8 × 10(13) photons m(-2) s(-1) (3.0 × 10(-5) μmoles photons m(-2) s(-1)). They have an avoidance response to predator shadows in which they descend upon sudden decreases in light intensity of more than 69%. When stimulated with relative rates of decrease in light intensity as occur at sunset they ascended, whereas they descended upon relative rates of light intensity increase as occur at sunrise. Thus, the DVM pattern is controlled by both an endogenous circadian rhythm in swimming and behavioral responses to light at sunrise and sunset.     

锯缘青蟹视网膜电图特性的昼夜节律变化

本文系统地分析了锯缘青蟹scylla serrata视网膜电图特性(敏感度、光谱敏感性和波形)的昼夜节律性变化。这种节律性可能主要是由于视网膜屏蔽色素位置的昼夜变化所致,但也可能存在另一种机制。     

Electrophysiological evidence for rod and cone-based vision in the nocturnal flying squirrel

Summary The flying squirrel (Glaucomys volans) is a strongly nocturnal rodent. Previous anatomical observations suggested that the retina of this animal contains some cone-like receptors in addition to large numbers of rods. Evidence for duplicity of function in this visual system was obtained from an examination of three indices of visual activity: the electroretinogram (ERG), the isolated PIII retinal response, and the visually evoked cortical potential (VECP). The spectral sensitivity of the dark-adapted flying squirrel is similar to that of other mammals — it has a 500 nm peak (Figs. 3, 8). Responses of the ERG and isolated PIII to flickering light indicate the operation of two processes (Figs. 4, 7), one of which is unable to follow flickering light at repetition rates above 10–15 Hz. Spectral sensitivity measurements reveal that these two processes have different spectral sensitivities. The photopic mechanism in the flying squirrel visual system has peak sensitivity at about 520 nm (Figs. 5, 7, 9). The effects of steady light adaptation are much more obvious in the cortical potentials than they are in the retinal potentials.We thank David Birch for his advice and assistance. This research was supported by a Grant from the National Eye Institute (EY-00105).     

Photosensitive neurogenic heart of the isopod crustacean Ligia exotica

The heart of animals is regulated through the central nervous system in response to external sensory stimuli. We found, however, that the adult neurogenic heart of the isopod crustacean Ligia exotica has photosensitivity. The beat frequency of the isolated heart decreased in response to a light stimulus. Magnitude of the response was stimulus intensity dependent and the heartbeat frequency decreased to less than 80% of the dark value during illumination of the white light with an intensity of 6.0 mW cm-2. The spectral sensitivity curve of the heart photoresponse peaked at a wavelength around 520 nm. In response to 530 nm monochromatic light, the relationship between light intensity and response magnitude was linear and the threshold intensity was 7.26 x 1012 quanta cm-2 s-1. Bursting activity of the cardiac ganglion, which is located in the heart and acts as the cardiac pacemaker deceased in frequency in response to illumination by white light. This fact suggests that the heart photoresponse of L. exotica results from the photosensitivity of the cardiac ganglion neurons. The photoresponse of the heart therefore contributes to regulation of cardiac output in addition to other regulatory systems.     

Electroretinogram and the spectral sensitivity of the compound eyes in the firefly Photuris versicolor (Coleoptera-Lampyridae): A correspondence between green sensitivity and species bioluminescence emission

ERGs were recorded from the dorsal sector of dark- and chromatic-adapted compound eyes in the dark-active firefly Photuris versicolor ♀ and ♂ at different wavelengths across the spectrum ranging from 320 nm to 700 nm over 4.5 log units of change in the stimulus intensity. ERG elicited by white light stimulus was an on-negative monophasic wave typical of scotopic eyes. ERGs elicited by chromatic stimuli differed in their waveform characteristics in the short (near-u.v. and violet) and long (green-yellow) wavelengths. The slope of the intensity-response curves at different stimulus wavelengths were similar for phasic response and differed for the plateau component of the ERG. The spectral sensitivity curves obtained under dark- and chromatic-adapted conditions revealed peaks in the near-u.v. (λ_max, 380 nm) and in the green (λ_max 550 nm), suggesting the presence of at least two receptor types in the dorsal sector of the compound eyes of P. versicolor. The green (550 nm) peak corresponds with the species bioluminescence emission peak (552 nm).