Increased intracellular sodium mimics some but not all aspects of photoreceptor adaptation in the ventral eye of Limulus

The effects of the intracellular iontophoretic injection of Na+ ions have been quantitatively compared with adaptation in ventral photoreceptors of Limulus. We find that: (a) both light adaptation and sodium injection are associated with a decrease in the variability of the threshold response amplitued; (b) both light adaptation and sodium injection are associated with a decrease in the absolute value of the temporal dispersion of the threshold response time delay; (c) the same template curve adequately fits the intensity response relationships measured under light adaptation and Na+ injection; (d) both light adaptation and Na+ injection produce a fourfold decrease in response time delay for a desensitization of 3 log units; (e) the time coures of light adaptation and dark adaptation is significantly faster than the onset of and recovery from desensitization produced by Na+ injection; (f) unlike local illumination, Na+ injection does not produce localized desensitization of the photoreceptor. These findings suggest that a rise in intracellular Na+ concentration makes at most only a minor contribution (probably less than 5%) to the total adaptation of these receptors in the intensity range we have examined (up to 3 log units above absolute threshold). However, changes in intracellular Na+ concentration may contribute to certain components of light and dark adaptation in these receptors.     

The role of retinula cell types in fixation behaviour of walkingDrosophila melanogaster

Summary Fixation behaviour of free walking wild typeDrosophila and various retinal mutants was tested in a circular arena. Optomotor response was also measured as a test of the function of R1-6.ora andsev,ora do not fixate a narrow stripe (10° or 20°, Fig. 1) but are able to orient towards broad stripes (110° or 180°, Fig. 1). The behaviour ofsev is not different from wild type. Fixation behaviour ofw rdgB is similar toora (Figs. 5, 6). The mutantora has a maximum optomotor response at low contrast frequencies (Fig. 2), but the threshold for this response is at least one log unit higher than in wild type orsev (Fig. 8). The light intensity threshold at 550 nm of fixation to a broad stripe (110°) is 1–2 log units higher inora than in wildtype, and 4 log units higher insev,ora and the structural brain mutantVam (Fig. 7).The conclusions are that retinula cells R1-6 mediate fixation to a narrow stripe at high and low ambient light intensities, and to a broad stripe at low ambient light levels. R8, possibly in conjunction with R1-6, contributes to orientation towards broad stripes at high light intensities. This hypothesis is supported by evidence that blue-adapted white-eyed flies are able to orient towards a broad stripe at high blue light intensities (Figs. 9 and 12). Blue adaptation totally eliminates the optomotor response (Figs. 10, 11) and so the optomotor response observed inora at low contrast frequencies (Figs. 2 and 8) is most likely due to the small remnants of the rhabdomeres of R1-6 that remain.Abbreviations PDA prolonged depolarising afterpotential - ERG electroretinogram     

Comparative studies of crustacean spectral sensitivity

Summary Spectral sensitivity of the lateral eyes of the isopodPorcellio scaber (wood louse) and the decapodsCallinectes sapidus (blue crab),Palaemonetes paludosus (Everglades prawn),Orconectes virilis, andO. immunis (crayfish) have been measured between 300 and 660 nm by determining the reciprocal number of photons required to evoke a constant size retinal action potential. Porcellio is maximally sensitive at 515 nm andCallinectes at 505 nm. Both species have a single pigment system, as spectral sensitivity is unchanged by red light adaptation. Palaemonetes appears to have a dichromatic color vision. Sensitivity of the dark-adapted eye is dominated by a receptor maximally sensitive at 550–555 nm, but red or yellow adaptation discloses a uv pigment with _max at about 380 nm. Present evidence suggests the 555 and 380 nm pigments are located in different receptor cells. Orconectes has peak sensitivity at 565 nm, but under red light adaptation and close to the electroretinographic threshold a second sensitivity maximum appears at 425 nm. As in the prawn, these peaks seem to indicate the presence of a two-receptor color vision system.The corneas ofOrconectes, Callinectes, andHomarus (lobster) are relatively thick, and microspectrophotometric measurements show near ultraviolet absorption as well as the protein peak at 280 nm. By contrast,Palaemonetes andMusca (housefly), species with near ultraviolet receptors, have thinner corneas which are transparent through the near ultraviolet. The crystalline cone ofPalaemonetes likewise shows no near ultraviolet absorption but a strong protein band at 280 nm.The scarcity of ultraviolet receptors in the compound eyes of crustacea, in contrast to their common occurrence in insects, is thought to be related to the relative absence of ultraviolet wavelengths in most aquatic environments.This work was supported in part by USPHS research grant NB 03333 to Yale University and postdoctoral fellowship NB 22,547 to H.R.F.     

Hyperpolarizing photoreceptors in the eyes of the giant clamTridacna: physiological evidence for both spiking and nonspiking cell types

Summary Intracellular studies on photoreceptors in the eyes of the giant clamTridacna give evidence for two types of light-sensitive cells, both of which are hyperpolarized by light. These cells are distinguished by the presence or absence of spikes and corresponding characteristics of the receptor potential. In non-spiking (NS) receptors, the average resting potential in the dark is low (-15 mV) and peak receptor potentials are large (to 100 mV) and adapt rapidly to light. Spiking (S) receptors have higher average resting potentials (-45 mV), but receptor potentials do not exceed 20 mV and also do not adapt to light. The spikes in S-receptors are small (3–8 mV), occur spontaneously at low levels of illumination and are inhibited by light. Bursts of spikes arise on the repolarizing off-component of the receptor potential. Light adaptation increases the excitability of S-receptors in terms of a higher frequency and shorter latency of the off response burst. The receptor potential in both cells is due to a light-activated increase in membrane conductance to potassium ions. Membrane conductance decreases in NS-receptors in relation to light adaptation. Unlike the scallop eye, no depolarizing photoreceptors are present.Abbreviations NS non-spiking photoreceptors - S spiking photoreceptors - SW seawater     

A morphometric study of limb proportions in leaping prosimians

Study of individual limb proportions—most notably, for instance, of the intermembral index—distinguishes from most other primates those various prosimians capable of leaping. The present investigation analyzes 24 measures of limb proportions (taken by F.-K. Jouffroy and J. Lessertisseur) from 161 specimens representing 12 species of prosimians, using the multivariate statistical method of multiple discriminant analysis (carried out by R. German and C.E. Oxnard). The results indicate that there are three major gradients: (1) indriids, (2) cheirogaleines, and (3) galagines plus Tarsius, radiating from a fourth centrally located group of species, Lemur, Lepilemur, and Hapalemur. It is likely that the morphometric relationships displayed here can be associated with behavioral (locomotor) parallels among these various forms. Though leaping is a most important adaptation among prosimians, it seems clear that it has evolved separately a number of times, and it seems at least likely that the biomechanical nature of the adaptation differs in different groups. The results, therefore, present certain new hypotheses about prosimian locomotion that can only be tested with further field and laboratory studies. This study also emphasizes the fact that anatomical adaptation is complex. Though the analysis of each anatomical region separately provides a similar qualitative picture of the variation among genera, it is only in the analysis of all measures taken together that the complete pattern described above appears. Though no new variables have been added in that analysis, new information is obviously contained within the results. Since this information stems from the interactions of the variables, it must be due to associations between these anatomical areas.     

Colour receptors in the eye of the digger wasp,Sphex cognatus Smith: Evaluation by selective adaptation

Summary Pigment granule migration in pigment cells and retinula cells of the digger wasp Sphex cognatus Smith was analysed morphologically after light adaptation to natural light, dark adaptation and after four selective chromatic adaptations in the range between 358 nm and 580 nm and used as the index of receptor cell sensitivity. The receptor region of each ommatidium consists of nine retinula cells which form a centrally located rhabdom. Two morphologically and physiologically different visual units can be described, defined by the arrangement of the rhabdomeric microvilli, the topographical relationship of the receptor cells with respect to the eye axes and the unique retinula cell screening pigmentation. These two different sets of ommatidia (type A and B) are randomly distributed in a ratio of 13 throughout the eye (Ribi, 1978b). Chromatic adaptation experiments with wavelengths of 358 nm, 443 nm, 523 nm and 580 nm and subsequent histological examination reveal two UV receptors, two blue receptors and four yellow-green receptors in type A ommatidia and two UV receptors and six green to yellow-green receptors in type B ommatidia. The pigments in cells surrounding each ommatidium (two primary pigment cells, 20 secondary pigment cells and four pigmented cone extensions) were not affected significantly by the adaptation experiments.     

Differentiation of the membrane system in cells of Rhodopseudomonas capsulata after transition from chemotrophic to phototrophic growth conditions

Aerobically in the dark grown cultures of Rhodopseudomonas capsulata were shifted to low oxygen partial pressure for 30 min and afterwards to phototrophic conditions (anaerobic, light). During 210 min of adaptation to a phototrophic mode of life the bacteriochlorophyll (BChl) concentration increased 53-fold (doubling time 40 min) and the carotenoid content six fold. Growth was delayed. The light membrane fraction from chemotrophic and induced phototrophic cells contained low concentrations of small photosynthetic units (reaction center+light harvesting BChl B870), and low respiratory activities, especially of succinatecytochrome c oxidase. The heavy membrane fraction, i.e. the intracytoplasmic chromatophore fraction, increased during adaptation approximately 9-fold in surface area per cell, 42-fold in BChl content, 7-fold in reaction center content and 6-fold in the size of the photosynthetic unit.Phospholipid and fatty acid content and patterns changed slightly during adaptation.Non-standard Abbreviations BChl bacteriochlorphyll - R. Rhodopseudomonas     

Different ionic conductances are modulated during the late receptor potential and the prolonged depolarizing afterpotential in Hermissenda type A photoreceptors

Wavelength-dependent, bistable phenomena were found in the receptor potential of Hermissenda crassicornis type A photoreceptors. Short exposure to blue light induced a prolonged depolarizing afterpotential (PDA) following the cessation of the light stimulus. Stronger adaptation to blue light, as caused by prolonged exposure and/or high intensity stimulation, effected a reduction in the early depolarizing transient of the late receptor potential (LRP) as elicited by subsequent stimuli. Vast separation of LRP emergence and PDA emergence could be obtained in photoreceptors in which a strong cancellation of the LRP was accomplished but a PDA still emerged after cessation of the light stimulus. Short exposure to yellow light cancelled the PDA, and stronger adaptation restored the LRP (opposite effect to blue light). The initial depolarizing part of the LRP had earlier been demonstrated to be mediated by the lightdependent increase of an inward conductance. In contrast, in this study the PDA was found to be accompanied by the reduction of an outward conductance, most likely a K⁺ conductance. A bistable photopigment system is thought to control the bistable receptor potential phenomenology by regulating the different membrane conductances during the LRP and the PDA.Abbreviations LRP late receptor potential - PDA prolonged depolarizing afterpotential - PHA prolonged hyperpolarizing afterpotential     

Spectral responses of sustaining fibers in the optic tracts of crayfish (Procambarus)

Summary Spectral response curves were recorded for 60–70 individual sustaining fibers in the optic nerve of the crayfish Procambarus. These cells belong to at least 8 of the 14 classes of sustaining fibers described by Wiersma and Yamaguchi (1966) on the basis of receptive fields. About 90 percent of the cells receive predominant input from yellow-green receptors and are maximally sensitive at 560 to 570 nm; a much smaller number receive principal input from blue receptors and are maximally sensitive near 460 nm.The wavelength sensitivity of optic fibers receiving their major input from yellow-green receptors depends on the state of dark adaptation of the animal and the intensity of illumination. Early in dark adaptation and at high intensities of stimulation the spectral response curve is distorted by light which has been filtered through the sleeves of red-brown shielding pigment. During dark adaptation a shift in maximum spectral response to shorter wavelengths parallels the retraction of the migratory pigment to the dark position and the development of retinal glow. The effects are reversed by injecting into a dark-adapted animal an extract of eyestalks containing the hormone controlling pigment migration: the pigment sleeves lengthen, retinal glow disappears, and shoulders or peaks of sensitivity appear in the red region of the spectrum.This work was supported by USPHS research grant EY 00222 to Yale University. A. E. R. W. was aided by a Fulbright-Hays travel grant. We are grateful to Prof. C. A. G. Wiersma and Dr. R. M. Glantz for a helpful demonstration of the recording technique.     

The effect of light adaptation on the dynamic properties of phototransduction in the fly,Phormia regina

The static and dynamic characteristics of phototransduction were studied in photoreceptors of the compound eye of the fly Phormia regina (Calliphoridae) using a green light emitting diode driven by a controlled current source. The LED provides sufficiently intense light to investigate the behaviour of the receptors over about half of the dark adapted range of the response versus log intensity curve. The effects of constant adapting light intensities upon the step response and upon the frequency response and coherence functions were examined. Using both methods the effect of light adaptation upon receptor sensitivity can be closely approximated by a similar linear dependence of log sensitivity upon log adapting intensity. However, there was no reliably detectable effect of light adaptation upon the time constant of the response over the range of adapting intensities used.Abbreviation LED Light Emitting Diode     

Influence of long-term spaceflight on neuromechanical properties of muscles in humans.

Reflex and elastic properties of the triceps surae (TS) were measured on 12 male cosmonauts 28-40 days before a 3- to 6-mo spaceflight, 2 or 3 days after return (R+2/+3) and a few days later (R+5/+6). H reflexes to electrical stimulations and T reflexes to tendon taps gave the reflex excitability at rest. Under voluntary contractions, reflex excitability was assessed by the stretch reflex, elicited by sinusoidal length perturbations. Stiffness measurements concerned the musculoarticular system in passive conditions and the musculotendinous complex in active conditions. Results indicated 1) no changes (P > 0.05) in H reflexes, whatever the day of test, and 2) increase in T reflexes (P < 0.05) by 57%, despite a decrease (P < 0.05) in musculoarticular stiffness (11%) on R+2/+3. T reflexes decreased (P < 0.05) between R+2/+3 and R+5/+6 (-21%); 3) increase in stretch reflexes (P < 0.05) on R+2/+3 by 31%, whereas it decreased (P < 0.05) between R+2/+3 and R+5/+6 (-29%). Musculotendinous stiffness was increased (P < 0.05) whatever the day of test (25%). Links between changes in reflex and stiffness were also studied by considering individual data. At R+2/+3, correlated changes between T reflexes and musculoarticular stiffness suggested that, besides central adaptive phenomena, musculoarticular structures took part in the reflex adaptation. This mechanical contribution was confirmed when data collected at R+2/+3 and R+5/+6 were used because correlations between changes in stretch reflexes and musculotendinous stiffness were improved. In conclusion, the present study shows that peripheral influences take part in reflex changes in gravitational unloaded muscles, but can only be revealed when central influences are reduced.     

The roles ofDrosophila ocelli and compound eyes in phototaxis

Summary Drosophila have three types of photoreceptors in their compound eyes: R1–6, R7, and R8. In addition they have simple eyes, ocelli, with another type of photoreceptor. The role of each type of receptor and the possible interaction of their inputs were examined in an innate visual preference task, fast walking phototaxis. Flies were found to be attracted to light, i.e., positively phototactic. We compared the strength of the photopositive response and the spectral preference of normal fly strains and mutant fly strains lacking functional ocelli, R1–6, or R7, singly or in combination. Electroretinographic measures were used to confirm the specificity of deficits in visual mutant strains and the normal functioning of intact receptors.The strength of the photopositive response was strong, as indicated by the high correlation between increases in the intensity of the variable stimulus and increasing numbers of flies attracted toward it. Nearly all strains with or without intact receptor types showed high correlations whether the constant intensity stimulus offered as the alternative choice was bright 467 nm light (Figs. 1 and 2) or dim 572 nm light (Figs. 3 and 4). These constant stimuli were selected so that data in relevant intensity ranges of receptor function would be obtained. An important exception to the high correlations in the intensityresponse functions occurred with flies lacking function in all receptor types except R8; their positive phototaxis was extremely weak in dim light (Fig. 3).Analyses of the phototactic spectral sensitivities (Figs. 5 and 6), as well as comparisons with known electrophysiological spectral sensitivities, were used to determine the inputs from compound eye receptors and to demonstrate central interaction of these inputs with ocellar input. Several experiments with converging evidence suggest that R7 (when present) and R8 dominate fast phototaxis in the conditions of our experiment. R1–6 is the predominant compound eye receptor type in ERG measures; however, its behavioral input is clearly demonstrated only as enhancing R8 dominance of phototaxis in experiments using a dim constant stimulus and as enhancing R7 dominance of phototaxis in experiments using a bright constant stimulus. Similarly, the presence of ocellar receptors also facilitates R8 input in dim light and R7 input in bright light. The data substantiating these respective conclusions are: (1) a lack of dim light phototaxis in a mutant strain with only R8 functional (Fig. 3); and (2) a lack of an ultraviolet (UV) maximum from R7 in bright light phototaxis in a mutant strain with only R7 and R8 functional (Fig. 5c).Generally, absence of the ocelli and R1–6 had remarkably little effect on fast phototactic behavior except for the interaction with R7 and R8 inputs. This interaction is consistent with a theory that ocelli serve to modulate compound eye sensitivity.Abbreviations ERG electroretinogram - PDA prolonged depolarizing afterpotential - R (1–6, 7, 8) retinular cell(s) - UV ultraviolet We thank K. Frayer, F. Garfinkel, K. Hansen, M. Johnson, R. Srygley, and G. Sullivan for technical assistance; K. Hansen was instrumental in running the experiments at extremely dim conditions. Supported by grants NSF-BNS-76-11921 and NIH-1-RO1-EY-02487-01A1 (to W.S.S.). Experiments reported in this paper were included in a dissertation (Karin G. Hu) submitted in partial fulfillment of the requirements of the Ph.D. degree to the Department of Psychology, The Johns Hopkins University, Baltimore, Maryland 21218. We thank members of the Graduate Board Dissertation Examining Committee for their comments: Drs. E. Blass, R. DeVoe, K. Muller and W. Sofer.     

Interpreting trans-retinal recordings of spectral sensitivity

A quantitative model is developed to describe spectral sensitivity functions recorded extracellularly from heterogeneous populations of receptors in different states of adaptation. This treatment identifies the most important influences and clarifies several general features of experimental results. The shapes of retinal spectral sensitivity curves in different states of chromatic adaptation depend in predictable fashion on whether the primary effect of the adapting light on individual receptors is to decrease Vmax (response compression) or to increase the quantum demand for half-saturation. Some response compression is necessary in order for one or more receptors to drop out of the response at modest levels of adaptation. The apparent ease of adaptation also depends on the criterion voltage, particularly in the presence of response compression. The technique of selective adaptation of the ERG is capable of revealing the presence of receptors that comprise only a few percent of the total population. The short wavelength absorption of all visual pigments normally makes it impossible to use uv or violet light to adapt selectively those receptors with maximal sensitivity in the uv or violet region of the spectrum while sparing receptors with maximal sensitivity at longer wavelengths. The presence of cone oil droplets absorbing at short wavelengths, however, can effectively screen visual pigments in some of the receptors from uv or violet adapting lights.     

The action of spike frequency adaptation in the postural motoneurons of hermit crab abdomen during the first phase of reflex activation

Cuticular strain associated with support of the shell of the hermit crab, Pagurus pollicarus, by its abdomen activates mechanoreceptors that evoke a stereotyped reflex in postural motoneurons. This reflex consists of three phases: a brief high-frequency burst of motoneuron spikes, a pause, and a much longer duration but lower frequency period of spiking. These phases are correlated with a rapid increase in muscle force followed by a slight decline to a level of tone that is greater than that at rest but less than maximal. The present experiments address the mechanisms underlying the transition from the first to second phase of the reflex and their role in force generation. Although centrally generated inhibitory post-synaptic potentials (IPSPS) are present during the pause period of the reflex, intracellular current injection of motoneurons reveals a spike frequency adaptation that rapidly and substantially reduces motoneuron firing frequency and is unchanged in saline that reduces synaptic transmission. The adaptation is voltage sensitive and persists for several hundred milliseconds upon repolarization. Hyperpolarization partially restores the initial response of the motoneuron to depolarizing current. Spike frequency adaptation and synaptic inhibition are important mechanisms in the generation of force that maintains abdominal stiffness at a constant, submaximal level.     

Ultraviolet polarisation sensitivity in the stomatopod crustacean <Emphasis Type="Italic">Odontodactylus scyllarus</Emphasis>

The ommatidia of crustacean eyes typically contain two classes of photoreceptors with orthogonally oriented microvilli. These receptors provide the basis for two-channel polarisation vision in the blue–green spectrum. The retinae of gonodactyloid stomatopod crustaceans possess a great variety of structural specialisations for elaborate polarisation vision. One type of specialisation is found in the small, distally placed R8 cells within the two most ventral rows of the mid-band. These ultraviolet-sensitive photoreceptors produce parallel microvilli, a feature suggestive for polarisation-sensitive photoreceptors. Here, we show by means of intracellular recordings combined with dye-injections that in the gonodactyloid species Odontodactylus scyllarus, the R8 cells of mid-band rows 5 and 6 are sensitive to linear polarised ultraviolet light. We show that mid-band row 5 R8 cells respond maximally to light with an e-vector oriented parallel to the mid-band, whereas mid-band row 6 R8 cells respond maximally to light with an e-vector oriented perpendicular to the mid-band. This orthogonal arrangement of ultraviolet-sensitive receptor cells could support ultraviolet polarisation vision. R8 cells of rows 5 and 6 are known to act as quarter-wave retarders around 500 nm and thus are the first photoreceptor type described with a potential dual role in polarisation vision.     

Central adaptation models of the vestibulo-ocular and optokinetic systems

A theoretical analysis of two models of the vestibulo-ocular and optokinetic systems was performed. Each model contains a filter element in the vestibular periphery to account for peripheral adaptation, and a filter element in the central vestibulooptokinetic circuit to account for central adaptation. Both models account for1 adaptation, i.e. a response decay to a constant angular acceleration input, in both peripheral vestibular afferent and vestibulo-ocular reflex (VOR) responses and2 the reversal phases of optokinetic after-nystagmus (OKAN) and the VOR and3 oscillatory behavior such as periodic alternating nystagmus. The two models differ regarding the order of their VOR transfer function. Also, they predict different OKAN patterns following a prolonged optokinetic stimulus. These models have behavioral implications and suggest future experiments.     

The dynamics of photosynthetic acclimation to changes in light quanlity and quality in three Australian rainforest tree species

Photosynthetic acclimation was studied in seedlings of three subtropical rainforest species representing early (Omalanthus populifolius), middle (Duboisia myoporoides) and late (Acmena ingens) successional stages in forest development. Changes in the photosynthetic characteristics of pre-existing leaves were observed following the transfer of plants between deep shade (1–5% of photosynthetically active radiation (PAR), selectively filtered to produce a red/far-red (R/FR) ratio of 0.1) and open glasshouse (60% PAR and a R/FR ratio of 1.1–1.2), and vice versa. The extent and rate of response of the photosynthetic characteristics of each species to changes in light environment were recorded in this simulation of gap formation and canopy closure/overtopping. The light regimes to which plants were exposed produced significant levels of acclimation in all the photosynthetic parameters examined. Following transfer from high to low light, the light-saturated rate of photosynthesis was maintained near pre-transfer levels for 7 days, after which it decreased to levels which closely approximated those in leaves which had developed in low light. The decrease in photosynthetic capacity was associated with lower apparent quantum yields and stomatal conductances. Dark respiration was the parameter most sensitive to changes in light environment, and responded significantly during the first 4–7 days after transfer. Acclimation of photosynthetic capacity to increases in irradiance was significant in two of the three species studied, but was clearly limited in comparison with that of new leaves produced in the high light conditions. This limitation was most pronounced in the early-successional-stage species, O. populifolius. It is likely that structural characteristics of the leaves, imposed at the time of leaf expansion, are largely responsible for the limitations in photosynthetic acclimation to increases in irradiance.     

Female coital orgasm and male attractiveness

Female coital orgasm may be an adaptation for preferentially retaining the sperm of males with “good genes.” One indicator of good genes may be physical attractiveness. Accordingly, R. Thornhill, S. W. Gangestad, and R. Comer (1995) found that women mated to more attractive men reported an orgasm during a greater proportion of copulations than did women mated to less attractive men. The current research replicates this finding, with several design variations. We collected self-report data from 388 women residing in the United States or in Germany. Results support the hypothesis that women mated to more attractive men are more likely to report an orgasm at the most recent copulation than are women mated to less attractive men, after statistically controlling for several key variables. Discussion addresses (a) the inability of the present research to specify the causal link between female orgasm and male attractiveness and (b) the proactive nature of female sexuality documented in recent research guided by an evolutionary perspective.     

Insect pupil mechanisms

Summary The light-dependent pigment migration system of dragonfly ocelli was studied by optical, non-invasive techniques. The median ocellus is comprised of two lateral halves, as can be demonstrated in the intact animal since illumination of the receptors in one half of the median ocellus only induces a movement of pigment located in that half. Measurable pigment migration can occur within a few seconds, but its speed and extent depends on light intensity. Dispersal of pigment, which occurs upon light adaptation, proceeds faster than retraction, which occurs upon dark adaptation. Action spectra for pigment movement have been determined inSympetrum andAnax. The spectrum forSympetrum has a prominent UV peak, moderate blue sensitivity, and very low green sensitivity. A similar profile is obtained inAnax, but only after intense orange adaptation which suppresses the green sensitivity. The results conform to the known spectral sensitivities of Libellulid and Aeschnid ocellar receptors. It is concluded that the photoreceptors drive pigment movement through an unknown mechanism. The effect of the migration of pigment is the selective reduction of radiant flux on the retina from luminous sources at high elevations relative to the animal's normal flying posture.This work was supported by grants by the Netherlands Organization for the Advancement of Pure Research (Z.W.O.) (to DGS), by National Eye Institute U.S.P.H.S. EY01140 and EY00785 (to GDB) and EY00777 and EY00040 (to RLC).