Phototaxis and membrane potential in the photosynthetic bacterium Rhodospirillum rubrum.

Cells of the photosynthetic bacterium Rhodospirillum rubrum cultivated anaerobically in light show phototaxis. The behavior of individual cells in response to the phenomenon is reversal(s) of the swimming direction when the intensity of the light available to them abruptly decreases. The tactic response was inhibited by antimycin, an inhibitor of the photosynthetic electron transfer system. The inhibitory effect of antimycin was overcome by phenazine methosulfate. Motility of the cells was not impaired by antimycin under aerobic conditions. Valinomycin plus potassium also inhibited their phototactic response; however, valinomycin or potassium alone had no effect. A change in membrane potential of the cells was measured as an absorbance change of carotenoid. Changes in the membrane potential caused by "on-off" light were prevented by antimycin and by valinomycin plus potassium, but not by antimycin plus phenazine methosulfate nor valinomycin or potassium alone. The results indicated that the phototactic response of R. rubrum is mediated by a sudden change in electron flow in the photosynthetic electron transfer system, and that the membrane potential plays an important role in manifestation of the response.     

Sudden reversal of phototaxis during the development of nestling birds

Starling, Sturnus vulgaris, nestlings from about 10 days of age moved away from light, i.e. they were negatively phototactic. However, several days before fledging, they changed to move towards light, probably a necessary prerequisite for fledging. The phototactic reversal was correlated with physical development and the ability to fly. In contrast to most studies or newly acquired behaviour, there was no change in response time associated with the reversal. However, hunger reduced the response time of hand-reared nestlings. It is suggested that a positive phototaxis for strong fliers or negative phototaxis for flightless young is an adaptive escape response. The reversal of phototaxis is probably a general feature of avian development.     

Effects of sodium azide on phototaxis of the blue-green alga Anabaena variabilis and consequences to the two-photoreceptor systems-hypothesis

Experiments with sodium azide support the earlier report that two different photoreceptor systems participate in the absorption of the phototactically active light in Anabaena variabilis. The one of them, represented by the phycobiliproteins and chlorophyll a, is responsible for positive and negative phototaxis around 440 nm and between 580 and 700 nm. This system is sensitive to sodium azide which is able to reverse the negative reaction at high fluence rates to a positive one. The second one which absorbs light between 500 and 560 nm and above 700 nm is insensitive to azide. It triggers only negative responses in absence and presence of azide as well. P750 is obviously not a photoreceptor pigment of this system, since there is no indication for its occurrence in Anabaena. Even photobleaching of the photosynthetic pigments at high fluence rates is prevented by azide. The noncyclic photosynthetic electron transport is not severely inhibited by azide because photokinesis is only in part impaired. Therefore, the hypothesis is suggested that the phototactic reaction-sign reversal generator of Anabaena is controlled by the level of an active oxygen species, probably singlet oxygen, which is quenched by azide.     

Effects of Calcium and Potassium Ions on Phototaxis in Cryptomonas

Effects on positive phototaxis and the cell motility of 7 cationsin 5mM MOPS (morpholinopropane sulfonic acid) buffer (pH 7.0)containing 0.16 mM NaCl, 0.68 mM KCl, 0.5 mM CaCl₂ and 0.16mM MgCl₂ were studied in the unicellular flagellate Cryptomonaswith a photoelectrical measuring apparatus and photomicrography.When calcium ion was removed from the medium by adding 1 mMEGTA (ethylene glycol-bis-(ß-amino-ethylether)-N,N'-tetraaceticacid), the phototactic response was totally inhibited, but theswimming rate was not much affected. The effect of EGTA waspartially reversed by the addition of 1 mM CaCl₂. When 15mMKCl or RbCl was added to the medium, phototaxis was greatlyinhibited, but there was no significant influence on the swimmingrate. Similar but less inhibitory effects were induced in thepresence of NaCl, LiCl and CsCl. KCl-induced inhibition waspartially removed by the addition of 15 mM CaCl₂ or MgCl₂. (Received June 25, 1982; Accepted September 27, 1982)     

Relationships between geotaxis/phototaxis and diel vertical migration in autotrophic dinoflagellates

Marine dinoflagellate diel vertical migrations are often conceptuallyexplained by a species' geotactic and phototactic preferences,but actual simultaneous measurements are rare. Newly collectedsimultaneous measurements on Heterocapsa (Cachonina) illdefina(Herman and Sweeney) and Gymnodinium breve (Davis) are combinedwith similar literature information on Amphidinium carterae(Hulbert), Peridinium faeroense (Paulsen) and Prorocentrum micans(Ehrenberg) to explore several examples of the actual relationshipsbetween diel vertical migration and geotaxis/phototaxis. Amphidiniumcarterae does not migrate, but it exhibits a negative geotaxisthat may counter a small sinking velocity. The four other speciesall exhibit diel vertical migrations that yield surface aggregationsduring daylight, but the associated combinations of geotaxisand phototaxis precision (which is strongest when every cellin a population exhibits the same response to a stimulus andweakest when the response is random) and sign [which is positive(negative) when motion is toward (away from) the stimulus] aredifferent in each case. These different taxis combinations maybe related to species-specific sensor structure and/or placement.Furthermore, variations in the different biochemical pools overa species' cell cycle may contribute to structural/mechanicalchanges that influence how a given sensory array functions ata given time. If so, this coupling may be an important linkin the growth optimization mechanisms and occasional bloom successesof different autotrophic dinoflagellate species under varyingenvironmental conditions.     

Sublethal effects of cupric ion activity on the phototaxis of three calanoid copepods

Using wavelengths near maximal photosensitivity, phototactic responses of two estuarine calanoid copepods (Acartia tonsa, Acartia hudsonica) and one nearshore, neritic copepod (Temora longicornis) were measured after 24 h exposures to sublethal concentrations of free cupric ions. A nitrilotriacetate-trace metal ion buffer system was used to control the free cupric ion activity (pCu = negative log of the free cupric ion activity), which determines organismic response. All three species exhibited positive phototaxis at pCu 13.0 reported for unpolluted surface sea waters and estuarine waters. As cupric ion activity increased, percent positive phototactic response decreased, indicating a strong sublethal effect of free cupric ions on photobehavior. Changes in photobehavior occurred at cupric ion activities that have been reported for many estuaries and coastal waters near urban and industrialized areas. Temora longicornis was much less phototactically sensitive than the two estuarine species. It also exhibited phototactic sign switching as pCu changed.     

The effect of temperature on phototaxis and geotaxis by larvae of the crab Rhithropanopeus harrisi (Gould)

Investigations of the effect of sudden temperature change on the phototaxis of Stage I and IV zoeae upon stimulation from horizontal and vertical directions with 500-nm light indicate a temperature-induced geotactic response in larvae of the crab Rhithropanopeus harrisi (Gould). For the horizontal tests both zoea stages were reared at 20 °C. Stage I showed positive phototaxis at temperatures between 15 ° and 35 °C, while Stage IV responded over the range of 10–30 °C. For the vertical tests, larvae, reared at 25 °C, were stimulated with overhead lights. Stage I zoeae ascended at 15 °, 20 ° and 25 °C and descended at 5 °, 10 °, 30 ° and 35 °C. Stage IV zoeae ascended at 20 ° and 25 °C and descended at 5 °, 10 °, 15 °, 30 ° and 35 °C. Although the descent at high temperatures could result from a negative phototaxis, a reversal in phototactic sign at high temperatures was not found in the horizontal experiments and the same vertical movement pattern is observed in total darkness. Upon exposure to high temperatures near the water surface, larvae would descend by means of a positive geotaxis rather than a negative phototaxis. This response involves active swimming by Stage IV larvae and passive sinking by Stage I.     

PHOTOTAXIS IN CHLAMYDOMONAS REINHARDTII

Parameters which distinguish phototaxis from random motility in Chlamydomonas reinhardtii have been defined with quantitative assays. The phototactic responses in photosynthetic, mixotrophic, and heterotrophic cultures were highest during exponential growth and declined rapidly as the cultures entered stationary phase. In contrast, random motility was relatively constant throughout growth. Phototaxis and motility also differ in their sensitivity to azide and antimycin A. Both of these drugs inhibited phototaxis within 5 min, but motility was unaffected for at least 30 min. Phototaxis and motility have different ion requirements. Optimum motility was observed in the presence of either Ca⁺⁺ or Mg⁺⁺; phototaxis required Ca⁺⁺ and either K⁺ or NH₄⁺. Photosynthesis is not required for phototaxis, since phototaxis was not inhibited by dichlorophenyldimethyl urea, and a mutant lacking chlorophyll was phototactic.     

Role of flavin quenchers and inhibitors in the sensory transduction of the negative phototaxis in the flagellate,Euglena gracilis

The effect of potential inhibitors of flavin photochemistry on the negative phototaxis ofEuglena gracilis has been studied. Substances that react with the excited states of flavins impair negative phototaxis: at high concentrations, potassium iodide (KI) and manganese chloride (MnCl₂) efficiently abolish phototactic orientation. Potassium cyanide, a general metabolic inhibitor, was ineffective. These results support the hypothesis that a flavin-type chromophore acts as a photoreceptor of this response. The involvement in the sensory transduction of negative phototaxis of hydrogen peroxide, one of the products of flavin photochemistry, is discussed.     

Action of Mono- and Difluorodinitrobenzene on Induced Electrical Modifications by External pH Changes in Nitella

The action of mono- (FNB) or difluorodinitrobenzene (DFNB) onion permeability is mainly attributed to its interactionwithamino groups of the membrane by dinitrophenylation. Nitella cells were dimtrophenylated at pH 7.3 and the membranepotential and electrical resistance were then measured in acidicor basic solutions. No matter what the pH value was, FNB andDFNB induced a depolarization of the membrane potential andcaused a diminution of resistance. However these effects ofFNB and DFNB were more drastic at alkaline pH and in the presenceof a weak concentration of potassium. Neither the addition of0.1 mM calcium nor the substitution of chlorides by nitratesmodified the DFNB effect. These results are compatible withthe assumption that the DFNB binding to the membrane leads toan augmentation of the negative charges of the membrane bringingabout an increased cation conductance and a modification ofthe affinity of a K⁺/H⁺exchange pump. The transient responseof the membrane potential at the time of dinitrophenylationwas used to roughly estimate the total density of amino groupsof the membrane of Nitella.     

Multiple light inputs control phototaxis in Synechocystis sp. strain PCC6803

The phototactic behavior of individual cells of the cyanobacterium Synechocystis sp. strain PCC6803 was studied with a glass slide-based phototaxis assay. Data from fluence rate-response curves and action spectra suggested that there were at least two light input pathways regulating phototaxis. We observed that positive phototaxis in wild-type cells was a low fluence response, with peak spectral sensitivity at 645 and 704 nm. This red-light-induced phototaxis was inhibited or photoreversible by infrared light (760 nm). Previous work demonstrated that a taxD1 mutant (Cyanobase accession no. sll0041; also called pisJ1) lacked positive but maintained negative phototaxis. Therefore, the TaxD1 protein, which has domains that are similar to sequences found in both bacteriophytochrome and the methyl-accepting chemoreceptor protein, is likely to be the photoreceptor that mediates positive phototaxis. Wild-type cells exhibited negative phototaxis under high-intensity broad-spectrum light. This phenomenon is predominantly blue light responsive, with a maximum sensitivity at approximately 470 nm. A weakly negative phototactic response was also observed in the spectral region between 600 and 700 nm. A deltataxD1 mutant, which exhibits negative phototaxis even under low-fluence light, has a similar action maximum in the blue region of the spectrum, with minor peaks from green to infrared (500 to 740 nm). These results suggest that while positive phototaxis is controlled by the red light photoreceptor TaxD1, negative phototaxis in Synechocystis sp. strain PCC6803 is mediated by one or more (as yet) unidentified blue light photoreceptors.     

Diaphototaxis and gravitaxis in a freshwater Cryptomonas

Phototaxis and gravitaxis are characterized in a freshwater species of the flagellate Cryptomonas. The phototactic orientation in this limnetic species is unusual and differs from all other Cryptomonas species studied so far: At both low (< or = 1O W m-2) and higher fluence rates it orients perpendicular to the light beam (diaphototaxis) while another freshwater Cryptomonas species (strain CR-1) is restricted to positive phototaxis and the marine species, C. maculata, shows both a positive and a more pronounced negative phototaxis. The mechanism of light direction detection seems to depend on a periodic shading or irradiation mechanism as confirmed by the disturbance of phototaxis in the presence of high viscosity media. In addition, this freshwater species possesses a rather pronounced negative gravitaxis which is only partially modified by phototaxis. The ecological consequences of this behavior are discussed.     

Photoreceptor current and photoorientation in chlamydomonas mediated by 9-demethylchlamyrhodopsin

Green flagellates possess rhodopsin-like photoreceptors involved in control of their behavior via generation of photocurrents across the plasma membrane. Chlamydomonas mutants blocked in retinal biosynthesis are "blind," but they can be rescued by the addition of exogenous retinoids. Photosignaling by chlamyrhodopsin regenerated with 9-demethylretinal was investigated by recording photocurrents from single cells and cell suspensions, and by measuring phototactic orientation. The addition of a saturating concentration of this analog led to reconstitution of all receptor molecules. However, sensitivity of the photoreceptor current in cells reconstituted with the analog was smaller compared with retinal-reconstituted cells, indicating a decreased signaling efficiency of the analog receptor protein. Suppression of the photoreceptor current in double-flash experiments was smaller and its recovery faster with 9-demethylretinal than with retinal, as it would be expected from a decreased PC amplitude in the analog-reconstituted cells. Cells reconstituted with either retinal or the analog displayed negative phototaxis at low light and switched to positive one upon an increase in stimulus intensity, as opposed to the wild type. The reversal of the phototaxis direction in analog-reconstituted cells was shifted to a higher fluence rate compared with cells reconstituted with retinal, which corresponded to the decreased signaling efficiency of 9-demethylchlamyrhodopsin.     

Evolution of phototaxis

Phototaxis in the broadest sense means positive or negative displacement along a light gradient or vector. Prokaryotes most often use a biased random walk strategy, employing type I sensory rhodopsin photoreceptors and two-component signalling to regulate flagellar reversal. This strategy only allows phototaxis along steep light gradients, as found in microbial mats or sediments. Some filamentous cyanobacteria evolved the ability to steer towards a light vector. Even these cyanobacteria, however, can only navigate in two dimensions, gliding on a surface. In contrast, eukaryotes evolved the capacity to follow a light vector in three dimensions in open water. This strategy requires a polarized organism with a stable form, helical swimming with cilia and a shading or focusing body adjacent to a light sensor to allow for discrimination of light direction. Such arrangement and the ability of three-dimensional phototactic navigation evolved at least eight times independently in eukaryotes. The origin of three-dimensional phototaxis often followed a transition from a benthic to a pelagic lifestyle and the acquisition of chloroplasts either via primary or secondary endosymbiosis. Based on our understanding of the mechanism of phototaxis in single-celled eukaryotes and animal larvae, it is possible to define a series of elementary evolutionary steps, each of potential selective advantage, which can lead to pelagic phototactic navigation. We can conclude that it is relatively easy to evolve phototaxis once cell polarity, ciliary swimming and a stable cell shape are present.     

Phototaxis in Daphnia magna: the influence of temperature and acidity on the phototactic behaviour of Daphnia genotypes

The influence of culture temperature, temperature shocks andpH shocks on the phototactic behaviour of four Daphnia magnaclones was studied. Test animals tended to become more positivelyphototactic when the pH of the medium was raised, and less positivelyphototactic when cultured at high (27°C) temperature. Responsesto temperature changes at the start of the experiment were clonedependent. Differences between genotypes remained highly significantdespite the broader environmental circumstances in which experimentswere carried out. Broad heritability estimates for the phototacticbehaviour of Daphnia under the different environmental conditionsstudied ranged from 0.78 to 0.88.     

Effect of pH on the Membrane Potential and Electrical Resistance of Nitella flexilis in the Presence of Calcium

Effects of pH on the membrane potential and electrical resistanceof Nitella were investigated in a bathing medium with or withoutcalcium. The membrane potential became more negative as theexternal pH was raised, at a faster rate in the presence ofcalcium than in its absence. The value then achieved by thepotential could be reversed by restoring the original pH whilstin a Ca-free medium the cell remained ‘hyperpolarized’.Tenfold changes of the external concentration of potassium broughtabout larger modifications of the membrane potential when thepH of the solution was high and calcium concentration low. Theelectrical resistance was lowest in alkaline and calcium-freesolutions. We conclude that calcium prevents the mediation ofsome changes in the membrane structure by lowering the concentrationof external H⁺ ions, and that the permeability of Nitella topotassium increases with rising pH.     

Two photophobic responses in Volvox carteri

Phototaxis of Volvox carteri is the result of two photophobicresponses: stop and accelerationof flagellar activity in theanterior region of the colony. These responses of a colony fixedunder a microscope were analyzed quantitatively by cine-micrography. The phototactic sign of Volvox is temperature-dependent: itis positive at room temperature and negative at low temperature.When the temperature was lowered, the stop response to the on-stimuluswas reduced and changed to the acceleration response, whilethe acceleration response to the off-stimulus changed to thestop response. Decrease in light inteasity resulted in reduction in both stopresponses, i.e., the response to the on-stimulus at 24?C andthat to the off-stimulus at 16?C, but scarcely affected theacceleration responses. The action spectra of the photophobic responses at 24? and 14?Care similar, with a peak at 520 nm. (Received January 24, 1979; )     

Effects of Some Inhibitors on the Temperature-Dependent Component of Resting Potential in Lobster Axon

The resting membrane potential of the lobster axon becomes 5–8 mv more negative when the temperature of the perfusion solution is increased 10°C. This potential change is about twice that predicted if the axon membrane potential followed that expected for a potassium ion electrode potential. When the inhibitors, 2, 4-dinitrophenol, sodium cyanide, and sodium azide, were added separately to the perfusion medium the potential change was reduced to about 1.4 times that predicted for a potassium ion electrode potential. Assays of axons exposed to these inhibitors showed that ATP levels were reduced to about one-fourth that obtained for control axons. Ouabain added to the perfusion medium reduced the potential change to that expected for a potassium ion electrode potential. These results suggest that the resting potential changes with temperature as a result of the activity of an electrogenic ion pump.     

Phototactic motility in the unicellular cyanobacterium Synechocystis sp. PCC 6803.

Synechocystis sp. PCC 6803 is a unicellular motile cyanobacterium that shows positive and negative phototaxis on agar plates under lateral illumination. Recent studies on the molecular mechanisms of the phototactic motility of Synechocystis have revealed that a number of genes are responsible for its pilus-dependent motility and phototaxis. Here we describe what is known about these genes. We also discuss the novel spectral properties of the phytochrome-like photoreceptor PixJ1 in Synechocystis, that is essential for positive phototaxis and which has revealed the existence of a new group of chromophore-binding proteins in cyanobacteria.     

Phototactic Orientation in Plasmodia of the Acellular Slime Mold, Physarum polycephalum

Phototactic orientation to lateral light was studied in plasmodiaof the yellow-pigmented strain (CL) and a white mutant of theslime mold Physarum polycephalum. The orientation changes wereperformed by either a turn or a reversal of the internal polarityof the plasmodium. Fluence rate-response curves for white andmonochromatic light showed positive phototaxis with low fluencerates and negative phototaxis with higher ones. The wavelengthdependences for both strains were similar and indicated thepredominant role of a UV/blue light-absorbing photoreceptor,which was not the same as one of the yellow pigments found inthe wild-type strains. Wavelengths >500 nm induced only aninsignificant effect. The control of the motor apparatus andthe possible linkage of the photoresponse with the other sensoryprocesses known in Physarum are discussed. (Received June 3, 1983; Accepted October 11, 1983)