CALCIUM RELEASE FROM INTRACELLULAR STORES IS NECESSARY FOR THE PHOTOPHOBIC RESPONSE IN THE BENTHIC DIATOM NAVICULA PERMINUTA (BACILLARIOPHYCEAE)1

Complex photoreceptor pathways exist in algae to exploit light as a sensory stimulus. Previous studies have implicated calcium in blue‐light signaling in plants and algae. A photophobic response to high‐intensity blue light was characterized in the marine benthic diatom Navicula perminuta (Grunow) in van Heurck. Calcium modulators were used to determine the involvement of calcium in the signaling of this response, and the fluorescent calcium indicator Calcium Crimson was used to image changes in intracellular [Ca²⁺] during a response. A localized, transient elevation of Calcium Crimson fluorescence was seen at the cell tip at the time of cell reversal. Intracellular calcium release inhibitors produced a significant decrease in the population photophobic response. Treatments known to decrease influx of extracellular calcium had no effect on the population photophobic response but did cause a significant decrease in average cell speed. As the increase in intracellular [Ca²⁺] at the cell tip corresponded to the time of direction change rather than the onset of the light stimulus, it would appear that Ca²⁺ constitutes a component of the switching mechanism that leads to reversal of the locomotion machinery. Our current evidence suggests that the source of this Ca²⁺ is intracellular.     

Gated ion fluxes involved in photophobic responses of the blue-green alga,Phormidium uncinatum

The sensory transduction chain of photophobic responses in the blue-green alga, Phormidium uncinatum seems to involve a gating cation transport through membrane bound ion channels which provides an effective amplification.The calcium conducting ionophore A23187 inhibits the photophobic response totally and induces frequent reversals which resemble phobic responses but occur without any light stimulation. This indicates that the electrogenic ion conductance may depend on a gradient of divalent cations, esp. calcium. The calcium conductance during a photophobic response is further confirmed by the inhibitory effect of ruthenium red and lanthanum, blockers of the electrogenic calcium transport. In the case of lanthanum this inhibition is found at a concentration at which neither the number of motile filaments nor the average speed of movement is impaired.Incorporation of ionophores for monovalent cations (gramicidin and valinomycin) only partially impairs the response. Similarly, inhibition of the Na⁺/K⁺ pump by ouabain is less effective. Thus, the existence of a countercurrent of monovalent cations during the response, which has been described for e.g. ciliates, is yet obscure in blue-green algae.     

Photosensory transduction in the flagellated alga,Euglena gracilis

Euglena were cultured under 3 W m^-2 constant white light. In culture medium, cells show immediate and long lasting step-down photophobic responses and photoaccumulation behavior to blue light if dim red light-adapted for 30 min. However, if cells are suspended in buffered, saltcontaining solutions (adaptation buffers), strong step-down photobehavior and photoaccumulation responses are not observed for several hours. These behaviors gradually increase in strength to reach a maximum after 6–12 h; after which a stable response is maintained. The relative rates of appearance and the relative strengths of the responses are influenced by the concentrations of Ca²⁺ and K⁺, but not H⁺ or Na⁺ ions, in the adaptation buffers. Expression of the stepdown photobehavior thus requires that the cells adapt to the chemical environment in which they are suspended.Abbreviations Hepes N-2-hydroxypiperazine-N-2-ethanesulfonic acid - Mes 2(N-morpholino)-ethanesulfonic acid - Pipes piperazine-N,N-bis (2-ethanesulfonic acid) - Taps tris(hydroxymethyl) methylaminopropanesulfonic acid This work was supported, in part, by grant No. PCM-79-05320 from the U.S. National Science Foundation to B.D.     

Anion sensitivity of motility and step-down photophobic responses of Euglena gracilis

The motility and step-down photophobic responses of Euglena are influenced by inorganic and organic anions. Persistent motility (with Ca²⁺, Mg²⁺ and K⁺ present) is supported with chloride or sulfate but not with acetate, nitrate or propionate as the only added anions. Cells in media containing acetate displayed a cell aggregation (clumping) behavior that was both red light sensitive and, under some conditions, was accompanied by suppression of the step-down photophobic response. Addition of sodium salts (Cl^-, SO ₄ ^2- , acetate or propionate) to cells in Cl^- or SO ₄ ^2- based media had differential effects on the duration of the step-down photophobic responses induced by blue light removal: anions alter the response. In addition, cells in all Cl^- containing media showed constant photophobic response duration following repeated stimulation. Cells in some SO₄ ^2- containing media, however, showed response summation to repeated stimulation. This latter effect was reversible and was overcome by the addition of chloride anions.     

Phototaxis and photophobic responses in Stentor coeruleus action spectrum and role of Ca2+ fluxes

Negative phototactic orientation, step-up photophobic responses and light-induced action potentials have been studied in the ciliate Stentor coeruleus. A resolved action spectrum, based on fluence rate-response curves, is consistent with stentorin as the photoreceptor. Calcium flux blockers prolong the response time for ciliary stop and reversal and inhibit step-up photophobic responses. Drugs believed to affect the membrane-bound calcium pump likewise inhibit phobic responses. On the other hand, α-phosphatidic acid promotes Ca²⁺-influx and enhances the photophobic sensitivity of the organism, thus providing an unambiguous evidence for the role of Ca²⁺ influx. A change in the response time decreases the degree of phototactic orientation, indicating that negative phototaxis in this organism is brought about by subsequent phobic responses of individual rows of cilia as the associated photoreceptor granules experience an increase in light intensity when the organism rotates during forward locomotion in lateral light.     

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

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

Effects of sequential stimuli on Halobacterium salinarium photobehavior.

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

Light-adaptation in the photophobic response by Stentor coeruleus

Effects of preillumination on photophobic response (light-adaptation) and recovery of the photophobic sensitivity in the dark (dark-adaptation) in Stentor coeruleus were examined. When the cells were preilluminated with white light of 7.80 W/m² for 2 min, the fluence-rate response curve of photophobic response was shifted toward higher light intensities by half an order of magnitude compared to the one without preillumination. Preillumination with a higher light intensity resulted in a further shift of the fluencerate response curve. An action spectrum for light-adaptation showed a primary peak at 610 nm and secondary peaks at 540 and 480 nm which are almost identical to the peaks observed in the photophobic action spectrum.The light-adapted cells showed a recovery of their photophobic sensing ability following dark treatment. Dark-adaptation resulted in total recovery of photophobic sensing ability in 8 minutes for the most cases examined.     

光谱和光强度对棕榈蓟马雌成虫行为反应的影响

室内研究了光谱、光强度对棕榈蓟马雌成虫的趋、避光行为的影响。结果显示:在340—605 nm波谱内棕榈蓟马雌成虫对14个单色光刺激的趋光行为反应为多峰型。其中蓝光483 nm处峰最高,趋光反应率达34.96%,其次为绿光498—524 nm、562—582 nm、紫外光340 nm处;其避光行为反应共有3个峰,其中紫外光380 nm处最高,避光率18.08%,另外2个峰分别在橙光605 nm、紫光420 nm处。在趋光率较高的单色光(340、483、524、582 nm)和避光率较高的单色光(380、605 nm)以及白光刺激下,棕榈蓟马雌成虫的趋光率随光强增强的增强而提高,而避光率则随着光强的增强而降低;光强最弱时仍均有一定趋光率,最强时均未出现高端平台。因此:棕榈蓟马雌成虫对不同单色光具有明显的选择性,光谱和光强度对其趋光行为和避光行为有较大影响,光强度的影响作用与波长因素有关。     

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

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

Photobehaviour of Paramecium bursaria infected with different symbiotic and aposymbiotic species of Chlorella

The endosymbiotic unit of Paramecium bursaria and Chlorella spec. shows two types of photobehaviour: 1) A step-up photophobic response which possibly depends on photosensitive agents in the ciliate cell itself — as is also shown by alga-free Paramecium bursaria - and can be drastically enhanced by photosynthetic activity of symbiotic algae; and 2) a step-down photophobic response. The step-down response leads to photoaccumulation of green paramecia. Both types of photobehaviour in Paramecium bursaria do not depend on any special kind of algal partners: The infection of alga-free Paramecium bursaria with different Chlorella species results in new ciliatealgae-associations. They are formed not only by combination of the original symbiotic algae with their host, but also by infection with other symbiotic or free-living (aposymbiotic) chlorellae, respecitively. Systems with other than the original algae are not permanently stable — algae are lost under stress conditions — but show the same types of photobehaviour. Photoaccumulation in general requires algal photosynthesis and occurs only with ciliates containing more than fifty algae/cell. It is not mediated by a chemotactic response to oxygen in the medium, since it occurs at light fluence rates not sufficient for a release of oxygen by the symbiotic system, e.g., below its photosynthetic compensation point. Photoresponses can be inhibited by 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU). Sensory transduction does not depend on any special symbiotic features of the algae, e.g., sugar excretion. The participation of oxygen in the Paramecium cell, of its cytoplasmic pH and of ions released or taken up by endosymbiotic algae in sensory transduction is discussed.     

Photomovement of the red alga Porphyridium cruentum (Ag.) Naegeli

Photophobic reactions of the red alga Porphyridium cruentum have been studied by single cell observations and by population experiments with the light trap method. In white light traps photoaccumulation is saturated at about 6000 lx. Experiments with monochromatic light demonstrate the necessity of carefully separating the three basic light reactions, viz. phototaxis, photokinesis and photophobic response by an appropriate experimental set-up: In single-beam experiments trap wavelengths >695 nm cause photodispersal which is not due to photophobic entrance reactions, but is exclusively due to the positive photokinetic effect of the trap light. This photodispersal can be cancelled by a photokinetically active background light. In the short wavelength range not only photokinesis, but also phototaxis interferes with photophobic reactions thus affecting the density of photoaccumulations in the light trap. Phototactic and photokinetic interference can be avoided by a blue background light. The action spectrum measured this way indicates activity of photosystem I and photosystem II pigments in the perception of the step-down photophobic stimulus. Varying the wavelength of the background light at constant trap light absorbed mainly by photosystem I or photosystem II respectively, efficient spill-over of light energy from photosystem II to the light reaction of photosystem I could be demonstrated. From the results it is concluded that phobic reactions are induced by a decrease of the electron flow rate in the linear electron transport chain.     

Electrical and proton gradients in the sensory transduction of photophobic responses in the blue-green alga,Phormidium uncinatum

The gliding filaments of the blue-green alga Phormidium uncinatum stop their movement almost instantaneously when transfered from their growth pH of 7.2 into a buffer 4.5 or 12.5. A pH jump into the range between 5.6 and 12.0 induces no visible response while in the range between 4.9 and 5.5 the organisms reverse the direction of their movement. The pH jump is believed to simulate an early step during the sensory transduction chain of the photophobic response which eventually results in a reversal of movement.One of the subsequent steps is the inversion of an electric potential gradient existing between the front and rear ends of a filament which dictates the direction of movement. A similar reversal of the naturally existing potential gradient can be provoked by switching on an external do field when the filaments move towards the anode or switching it off when the filaments glide in the opposite direction. Implications of these results on the current model of sensory transduction of the photophobic response in Phormidium uncinatum are being discussed.     

Temperature Effect on the Photo-Accumulation and Phobic Response of Volvox aureus*

SYNOPSIS. The effect of temperature on photoaccumulation and photophobic response of Volvox aureus were studied. The algae exhibited positive photoaccumulation at room temperature and negative at low temperature. When stimulated with light of intermediate intensiy (～ 5 × 10³ lux), the phobic response of the algae consisted of a decrease in the frequency or the cessation of flagellar movement in the anterior cells. At room temperature, an increase in light intensity elicited the phobic response, whereas at low temperature a decrease in light intensity was the effective stimulus. The phobic response lasted only a few seconds. The positive and negative photoaccumulations of the algae could be explained by the brief cessation of flagellar movement in the anterior cells, elicited by an increase of stimulus light at room temperature or a decrease of stimulus at low temperature.     

Effects of calcium channel blockers and DCMU on motility and the photophobic response of Gyrodinium dorsum

The effects of the calcium channel blockers, verapamil, diltiazem and lanthanum ions and the Ca²⁺ dependency on motility as well as the photophobic response (stop-response) of Gyrodinium dorsum were studied. At Ca²⁺ concentrations below 10^-3 M, motility was inhibited. La³⁺ inhibits the stop-response, in contrast to verapamil and diltiazem. The only calcium channel blocker that increased the amount of non-motile cells was verapamil. The results indicate that motility are Ca²⁺ dependent and that the stop-responses of G. dorsum could be affected by extracellular Ca²⁺. Effects of the photosythesis inhibitor (DCMU) on the stop-response was also determined. With background light of different wavelength (614, 658 and 686 nm) the stop-response increased. DCMU inhibited this effect of background light. Negative results with the monoclonal antibody Pea-25 directed to phytochrome and the results with DCMU, indicate that the stop-response of G. dorsum is coupled to photosynthesis rather than to a phytochrome-like pigment. Oxygen evolution, but not cell movement, was completely inhibited by 10^-6 M DCMU.Abbreviations DCMU 3-(3,4-dichlorophenyl)-1,1-methylurea - DILT diltiazem - DMSO dimethylsulfoxide - SDS-PAGE sodium dodecyl sulphate-polyacrylamide gel electrophoresis - VER verapamil     

Photophobic responses of the cyanobacterium Anabaena variabilis

The photophobic responses in the Cyanobacterium Anabaena variabilis which belongs to the Nostocaceae have been studied with aid of a population method as well as by single trichome observations. In white light experiments both step-up and step-down photophobic responses were observed. The wavelength dependence was examined at a constant fluence rate. The photophobically active light is absorbed by the photosynthetic pigments, mainly by the phycobiliproteins and chlorohyll a. Above 690 nm only negative reactions were observed, i.e. the trichomes left the light trap. In white light experiments DCMU strongly inhibited the photophobic responses, whereas photokinesis was not affected to the same extent indicating that the reaction is coupled with the non cyclic photosynthetic electron transport. DBMIB impaired the photophobic behaviour only slightly. It seems that the photophobic responses of A. variabilis are controlled by a similar mechanism as in Phormidium uncinatum (Oscillatoriaceae) although the two families and, hence, the two species differ in their movement mechanism as well as in their photoactic behaviour.     

Evidence of electrical potential changes in photophobically reacting blue-green algae

The correlation between photophobic responses and light-induced electric potential changes has been studied in the blue-green alga Phormidium uncinatum.

1. The photophobic reaction time depends on both length of preillumination and presentation time of stimulus. Under optimal conditions a reaction time of about 10 s has been determined.
2. Light-induced potential changes can be measured by means of external electrodes with a small gap between them bridged by a population of perpendicularly oriented trichomes. These potential changes follow a light-dark cycle with a lag phase of about 10 s.
3. The amplitude of these light-induced potential changes increases with light intensity until it reaches a saturation value of about 12 mV at 10000 lx. The action spectrum resembles the photophobic action spectrum with peaks in the absorption region of C-phycoerythrin and chlorophyll a.

The significance of light-induced potential changes as a means of sensory transduction for photophobic responses in blue-green algae is being discussed.     

Phototaxis in the flagellates,Euglena gracilis and Ochromonas danica

Oriented movement with respect to laterally impinging white light of the flagellates Euglena gracilis and Ochromonas danica has been analyzed in an individual cell study with a microvideographic technique. Using the deviation of track segments (in given time intervals of 1 s) from the light direction as raw data allowed a computer based analysis of the direction distribution. A number of statistical methods employed to test the significance of the obtained results demonstrated an obvious phototactic orientation in Ochromonas which was positive (toward the light source) in low illuminance (1.25 lx=5.3×10^-3 Wm^-2) and negative in higher illuminance (>12.5 lx=5.3×10^-2 Wm^-2). Since in this flagellate the threshold for negative phototaxis is much lower than that for the step-up photophobic response, the hypothesis that negative phototaxis may be brought about by repetitive step-up phobic responses can be rejected for at least this organism. In Euglena positive phototaxis was observed in 50 lx (=0.21 Wm^-2), while an illuminance of 500 lx (=2.1 Wm^-2) caused a negative phototaxis.The experiments were carried out in this laboratory