DOUBLET Stentor DO NOT DISPLAY PHOTODISPERSAL

Normal Stentor, called singlets since they have a single membranellar band and oral groove surrounding their frontal field, swim away from light sources and collect in the darker areas of an unevenly illuminated container (photodispersal). Phenotypic variants, called doublets since they have 2 membranellar bands and 2 oral grooves, do not exhibit this behavior. Doublets produce photophobic responses and contractions when illuminated at the same fluence rates which produce those responses in singlets, hence their sensitivity to light is normal. Illumination of the frontal field of doublets produces a photophobic response at lower fluence rates than does illumination of their side or posterior. This directional sensitivity is quantitatively similar to that observed in singlets. However, doublets do not reorient their swimming direction after a phobic response as extensively as do singlets. This failure in reorientation is the probable reason that doublets fail to show photodispersal. These results imply that the mechanism producing photodispersal in singlets depends on photophobic responses or some other, presently undescribed, response which requires an asymmetric frontal field.     

BEHAVIORAL RESPONSES IN Paramecium multimicronucleatum TO VISIBLE LIGHT

Specimens of colorless Paramecium multimicronucleatum were found to respond to visible light. They accumulated in the shaded region (photodispersal) of a half-shaded glass tube during 2 min exposure to visible light. The specimens showed avoiding reaction upon both spatial and temporal increase in light intensity (step-up photophobic response). Steady-state swimming velocity (orthokinesis) was higher, while steady-state frequency of spontaneous change in swimming direction (klinokinesis) was lower when the light intensity was kept higher. In a light with wavelength of 440 nm the velocity was highest, while the frequency was lowest. The specimens did not show phototaxis (light direction-oriented locomotion). Spectral sensitivity curves for both the photodispersal and the step-up photophobic response showed a major peak at 520 nm and a minor peak at 680 nm. The photodispersal seems to be caused mainly by the step-up photophobic response exhibited by the specimens at the dark-light border. The photokinetic responses enhance the degree of the photodispersal.     

PHOTOTACTIC ORIENTATION BY THE CILIATE, STENTOR COERULEUS

Stentor coeruleus exhibits negative phototaxis to visible light, in addition to a step-up photophobic response. The negative phototaxis was established by demonstrating the swimming of Stentor toward a focused beam away from the light source. The action spectrum showed a maximum at 610–620 nm and is essentially identical to that of the step-up photophobic response. Proton uncouplers such as micromolar concentrations of FCCP and TPMP⁺ inhibited the negative phototaxis.     

Photosensory transduction in unicellular eukaryotes: a comparison between related ciliates Blepharisma japonicum and Stentor coeruleus and photoreceptor cells of higher organisms

Blepharisma japonicum and Stentor coeruleus are related ciliates, conspicuous by their photosensitivity. They are capable of avoiding illuminated areas in the surrounding medium, gathering exclusively in most shaded places (photodispersal). Such behaviour results mainly from motile photophobic response occurring in ciliates. This light-avoiding response is observed during a relatively rapid increase in illumination intensity (light stimulus) and consists of cessation of cell movement, a period of backward movement (ciliary reversal), followed by a forward swimming, usually in a new direction. The photosensitivity of ciliates is ascribed to their photoreceptor system, composed of pigment granules, containing the endogenous photoreceptor -- blepharismin in Blepharisma japonicum, and stentorin in Stentor coeruleus. A light stimulus, applied to both ciliates activates specific stimulus transduction processes leading to the electrical changes at the plasma membrane, correlated with a ciliary reversal during photophobic response. These data indicate that both ciliates Blepharisma japonicum and Stentor coeruleus, the lower eukaryotes, are capable of transducing the perceived light stimuli in a manner taking place in some photoreceptor cells of higher eukaryotes. Similarities and differences concerning particular stages of light transduction in eukaryotes at different evolutional levels are discussed in this article.     

Stentor coeruleus SHOWS POSITIVE PHOTOKINESIS

Abstract— Stentor coeruleus responds to a sudden increase in light intensity with a step-up photophobic response (avoiding reaction), and to collimated light with negative phototaxis. The peaks of the action spectra for the photophobic response and for the phototaxis are in common, 610 nm.
5. coeruleus showed changes in its steady-state swimming velocity induced with varying intensities of light (photokinesis). The cells swam fast in light regions but slowly in dark ones (positive photokinesis); the mean velocity of swimming was about 0.6 mm/s at 100 lx but reached about 1.0 mm/s at 50000 lx. The peak of the action spectrum for this photokinesis was about 680 nm.
The organism is the first protozoan cell reported to show three types of photoresponse: photophobic response, phototaxis and photokinesis.     

PHOTOMOVEMENT IN AN "EYELESS" MUTANT OF Chlamydomonas

The function of the stigma ("eyespot") in the green flagellate Chlamydomonas reinhardtii was investigated by comparing the photomovement of the wild-type alga with that of an "eyeless" mutant ( ey 627). Movements of individual cells in response to a blue-green stimulus light were recorded using a videomicroscope system and were analyzed using vectorial methods. Cells of the "eyeless" mutant were phototactic; at a high stimulus fluence rate, their swimming paths were directed away from the light source. Although the orientation of the mutant was not as strongly directional as that of the wild type, it was statistically significant. However, the swimming paths of the mutant cells were very erratic in the presence of the stimulus beam, undergoing frequent changes of direction. Despite the differences in their phototactic orientation, cells of mutant and wild type all showed a distinct step-up photophobic response at the onset of stimulation. These results are consistent with the hypothesis that the stigma plays an accessory role in phototaxis, either by shading the photoreceptor or by acting as a quarter-wave reflector.     

Phototactic orientation mechanism in the ciliate Fabrea salina, as inferred from numerical simulations

The marine ciliate Fabrea salina shows a clear positive phototaxis, but the mechanism by which a single cell is able to detect the direction of light and orient its swimming accordingly is still unknown. A simple model of phototaxis is that of a biased random walk, where the bias due to light can affect one or more of the parameters that characterize a random walk, i.e., the mean speed, the frequency distribution of the angles of directional changes and the frequency of directional changes. Since experimental evidence has shown no effect of light on the mean speed of Fabrea salina, we have excluded models depending on this parameter. We have, therefore, investigated the phototactic orientation of Fabrea salina by computer simulation of two simple models, the first where light affects the frequency distribution of the angles of directional changes (model M1) and the second where the light bias modifies the frequency of directional changes (model M2). Simulated M1 cells directly orient their swimming towards the direction of light, regardless of their current swimming orientation; simulated M2 cells, on the contrary, are unable to actively orient their motion, but remain locked along the light direction once they find it by chance. The simulations show that these two orientation models lead to different macroscopic behaviours of the simulated cell populations. By comparing the results of the simulations with the experimental ones, we have found that the phototactic behaviour of real cells is more similar to that of the M2 model.     

PHOTOTACTIC BEHAVIOR OF INDIVIDUAL CELLS OF CRYPTOMONAS SP. IN RESPONSE TO CONTINUOUS AND INTERMITTENT LIGHT STIMULI

Abstract— The phototactic response of cells of Cryptomonas sp. to stimulation with continuous or intermittent lateral light was determined by an individual cell method using photomicrography and videomicrography. The cells showed positive phototaxis under the conditions studied. The phototactic orientation of individual cells was induced most effectively by irradiation with light of 570 nm; blue light was less effective, and no orientation was found in red light. An intermittent stimulus regime with a long dark interval (250 ms) elicited a weaker phototactic orientation than did a regime with a short dark interval (63 ms) irrespective of the duration of light pulses (16, 250 and 1000 ms). The swimming rate was ca. 240 ums ^-1 and the rotation period ca. 450 ms in the dark, neither of which was greatly affected by stimulation with continuous or intermittent light. Neither step-up nor step-down photophobic responses were observed at the time of onset or removal of the light stimulus under the experimental conditions. The swimming direction of individual cells became gradually oriented toward the light source. Phototactic response was detectable within 4 s after the onset of light stimulation, reaching a saturation level after more than 30 s.     

PHOTOTACTIC RESPONSE OF CHLAMYDOMONAS TO FLASHES OF LIGHT –II. RESPONSE OF INDIVIDUAL CELLS

Abstract— –Video-microscope studies provide further evidence that Chlamydomonas can become oriented in response to a single short flash of light. Following a flash, 50% of the cells in a negatively phototactic population undergo a transient deflection in swimming path ('turn response'), 10% show a 'stop response', and 40% continue to swim straight ahead. The direction of turning is related to the direction of the stimulus; a majority of cells turn away from the flash source. Repetitive flashing at 60 per s elicits oriented swimming, indistinguishable from that observed with continuous light. Responses at the onset of repetitive flashing resemble single-flash responses, reinforcing the idea that response to a single flash corresponds to the initial stages of orientation to continuous light. A stop response sometimes occurs at the onset of orientation to repetitive flashing, but it is apparently not an essential component of orientation. The fact that only 60% of the cells turn or stop in response to a flash is consistent with the hypothesis that light direction is perceived by comparing light absorbed in one photoreceptive region at two instants in time (before and during the flash). The only cells to turn or to stop would be those in which the photoreceptor organelle is appropriately oriented at the instant of the flash.     

EFFECTS OF IONOPHORES AND RUTHENIUM RED ON THE PHOTOTAXIS OF STENTOR COERULEUS AS MEASURED BY SIMPLE DEVICES

Abstract— Two simple methods of phototaxis measurements have been applied to study the effects of ionophores on the negative phototactic response in Stentor coeruleus. The inhibitory effects of Ca²⁺-ionophore (A23187), Ca²⁺-blocking agent (Ruthenium Red), and K⁺ -ionophore (valinomycin) on photo-taxis have been determined. Results suggest that the influx of Ca²⁺ plays a transducing role in the phototaxis of Stentor.     

EFFECTS OF UV-B IRRADIATION ON PHOTOMOVEMENT IN THE DESMID, Cosmarium cucumis

Abstract Monochromatic UV-B irradiation affects neither the absorption nor the fluorescence of the bulk pigments in the desmid Cosmarium cucumis but it impairs photomovement of these organisms at fluence rates which are not higher than the ambient level of solar UV-B irradiation. Photoaccumula-tions and phototaxis are strongly inhibited especially at wavelengths ≤ 300 nm while photodispersal at higher white light fluence rates is hardly affected by supplementary UV-B. This effect has important consequences for the growth and survival of populations in their natural environment: these photosyn-thetic organisms utilize photomovement to find and stay in areas of suitable visible light fluence rates. The UV-B component of solar irradiation both impairs the strategy of the organisms to find a suitable position and the escape mechanism by which the cells move out of areas with too strong white illuminances which photooxidize the bulk pigments and bleach the population within a few days.     

CALCIUM CONTROL OF PHOTOTACTIC ORIENTATION IN Chlamydomonas reinhardtii: SIGN AND STRENGTH OF RESPONSE

Abstract— Chlamydomonas reinhardtii responds to a blue light stimulus by an oriented swimming (phototaxis) toward or away from the stimulus source. In this study it is established that the sign and strength of the phototactic response are a complex function of extracellular [Ca²⁺], stimulus fluence rate, time of analysis after onset of stimulation and light pretreatment. At very low extracellular [Ca²⁺] the response is weak and usually negative. At [Ca²⁺] close to the preconditioning level, phototactic response becomes stronger and positive. As [Ca²⁺] is raised further, the initial (2 s) response remains positive but the long term (20 s) becomes negative and very strong. At extremely high [Ca²⁺] the cells become immobile. This bimodal behavior suggests that two different mechanisms determine the direction of the turn. Data cannot be explained in terms of a simple model. The model which accounts for most of the details of the behavior is that of Kamiya and Witman (1984), which proposes that positive response is triggered by a transient increase in intracellular [Ca²⁺] and negative response by a decrease below unstimulated level of Ca²⁺, at least in the range of 10^-9-10^-6 M [Ca²⁺]. The strong negative orientation which follows an initial positive response above this level of [Ca²⁺], in these experiments, is best explained by an adaptation of the cells due to an increased (on average) intracellular [Ca²⁺].     

Tracking phototactic responses and modeling motility of Synechocystis sp. strain PCC6803

The unicellular cyanobacterium Synechocystis sp. Strain PCC 6,803 exhibits phototaxis by moving along a surface towards a light source. This process requires Type IV pili and a phytochrome-like photoreceptor coupled to a complex signal transduction pathway. Cells progress through different phases of interaction before the development of finger-like projections moving in the direction of the light that are characteristic of phototaxis. To probe the interaction between individual cells during the initial phase of phototaxis we tracked and analyzed a large number of cells. We observed that individual cells have limited motility, but when cells divide and/or aggregate to attain a certain minimal group size, enhanced motility and phototaxis is observed. At the later stages of motility, there is noticeable phototactic behavior which results in the appearance of the finger-like projections. Our results indicate that cells prefer to move over areas previously traversed by other cells and confine themselves to these areas and that cells alter local surface characteristics allowing for enhanced motility. Based on cell tracking data we present a preliminary random walk model showing the forces that might interact to create the typical phases of phototaxis and motility. In this model, we can simulate the formation of finger-like projections that are characteristic of phototaxis.     

LIGHT REACTIONS OF THE CILIATE Stentor coeruleus-A THREE-DIMENSIONAL ANALYSIS

A computer-controlled three-dimensional tracking and motion analysis system was developed to study the responses of Stentor coeruleus to short light pulses and to evaluate its distribution patterns. In addition to photokinesis and phototaxis, the step-up photophobic response was analyzed, which includes a gravity-controlled component at higher fluence rates and a light direction-dependent component at lower fluence rates.     

PHOTOSENSORY TRANSDUCTION IN CILIATES. I. AN ANALYSIS OF LIGHT-INDUCED ELECTRICAL AND MOTILE RESPONSES IN Stentor coeruleus

Abstract— Light-induced membrane potantial changes and motile responses have been studied in Stentor cells with intracellular microelectrodes and video microscopy, respectively. Intracellulae microelectrode showed that step-up increase in light induced an electrical membrane response which consisted of an initial membrane depolarization (photoreceptor potential) followed by an action potential and maintaining phase of depolarization (afterdepolarization). The amplitude of the receptor potetial is dependent on the intensity of light stimulus and the action potetials appears with a lag period (latency) after the onset of light stimuklus. The extent of the membrane established between the latency for te action poitential and the onset of ciliary reversal (stop responses). A time correlation was also observed between the duration of the membrane afterdepolarization and the duration of backward swimming. the action spectrum for the photoreceptor potential amplitude of Stentor resembled the action spectra for the latency of ciliary reversal and the photoresponsiveness, iondicating that the photomovement response and membrane potential changes are coupled through the same photosensor system. A hypothesis on the photosensory transduction chain in Stentor is discussed according to ehich the photoreceptors and the ciliary apparatus is mediated by the membrane potential canges.     

Phototaxis in the ciliated protozoan Ophryoglena flava: dose-effect curves and action spectrum determination

The sensitivity of positive phototactic orientation of cells of the ciliated protozoan Ophryoglena flava has been measured for white light, broad-band blue and red light, and narrow-band monochromatic light, using a laboratory-developed computer aided system. The white-light fluence rate-response curve shows that there is no negative phototaxis in the fluence rate range investigated (0-15 W/m2) and no adaptation phenomena; it is very well fitted by a hyperbolic function; the fluence rate curves under broad band blue and red light (full width at half maximum, FWHM= 100 nm) can be fitted by the same model. The saturation level is, within experimental errors, the same for the three curves, indicating that there are no chromaticity effects and that if there is more than one photoreceptor pigment, they act independently of each other. The fluence rate-response curves determined under narrow band monochromatic light (FWHM = 10 nm) can also be fitted by the same model and show, within experimental errors, the same saturation level. An action spectrum for positive phototaxis at 10-nm intervals has been calculated from fluence rate-response curves: it shows three maxima, at 420, 540 and 590 nm. This action spectrum is significantly different from the ones for photomotile responses in Blepharisma japonicum, Stentor coeruleus and Chlamydodon mnemosyne, whereas it resembles the ones of Paramecium bursaria and Fabrea salina.     

ACTION SPECTRUM AND ELECTROPHYSIOLOGICAL RESPONSES CORRELATED WITH THE PHOTOPHOBIC RESPONSE OF STENTOR COERULEUS

Abstract— The blue-green ciliate. Stentor coeruleus , is found predominantly in shady places. This concentration occurs because stentor responds when swimming from a shaded area to a lighted area by reversing the direction of its ciliary beat and reorienting its swimming direction until it once again is in the shaded area. A graded receptor potential is recorded from microelectrodes in vacuoles of stentor when the animal is photically stimulated. For all but very weak stimuli this receptor potential is sufficient to elicit a regenerative transmembrane response of variable amplitude in a swimming animal. Suprathreshold electrical stimuli also elicit this regenerative response. In turn the regenerative response is coupled to ciliary reversal. Thus ciliary reversal appears to be produced whenever the photic receptor potential crosses the threshold for elicitation of the regenerative response.
Using the threshold for production of ciliary reversal as a criterion response, an action spectrum was obtained. This action spectrum correlates well with the absorption spectrum of the major pigment of S. coeruleus , stentorin. Stentor bleached of pigment also have an elevated threshold for ciliary reversal. Thus stentorin seems to be the photosensitive pigment in stentor responsible for its photophobic behavior.     

REAL TIME COMPUTER-CONTROLLED TRACKING OF MOTILE MICROORGANISMS

Abstract— A hardware and software system is described which is capable of automatically following the movement of microorganisms and analyzing the deviation of individuals in a population from a predefined direction. The image of the moving organisms is viewed by a video camera, digitized in real time and stored in a dedicated video memory holding 512 times 256 pixels with 64 grey levels. A microcomputer has access to this video memory via four parallel ports. The software analyzes the position of an organism selected randomly and attempts to follow its track for a predefined period of time. If successful, it calculates the direction of movement and stores the data in a file for statistical analysis.
Using this system, the movement of populations of the unicellular flagellate, Euglena gracilis, in unilateral and bilateral light beams has been studied and compared with the dark behavior. When irradiated from two opposite light sources of equal fluence rates half of the population swims towards either light source. However, when the light sources are oriented at an angle of 90° to each other the cells move on the resultant away from the light. These results confirm the shading hypothesis for negative phototaxis.     

THE EFFECT OF POTASSIUM IODIDE ON PHOTOPHOBIC RESPONSES IN EUGLENA: EVIDENCE FOR TWO PHOTORECEPTOR PIGMENTS*

Abstract— Potassium iodide, a quencher of flavin fluorescence, inhibits the shock reaction which Euglena experiences upon a sudden decrease in light intensity (inverse photophobic response) completely at a concentration of 150 mM. The rate of swimming of the cells at the same concentration of KI is reduced to 30% of the control. The direct photophobic response, a shock reaction which appears identical but occurs upon an increase in light intensity, is unaffected by KI as is negative phototaxis of Euglena. It is concluded that a non-flavin pigment system mediates photoreception for the direct photophobic response and negative phototaxis.     

A microfluidic device that forms and redirects pheromone gradients to study chemotropism in yeast

Chemotropism, or directed cell growth in response to a chemical gradient, is integral to many biological processes. The mating response of the budding yeast, Saccharomyces cerevisiae, is a well studied model chemotropic system. Yeast cells of opposite mating type signal their positions by secreting soluble mating pheromones. The mutual exchange of pheromones induces the cells to grow towards one another, resulting in mating projections or "shmoos." Yeast cells exhibit a remarkable ability to orient their growth toward the nearest potential mating partner, and to reorient (i.e., bend their mating projections) in response to a change in the direction of the pheromone gradient. Although a number of microfluidic devices have been used to generate linear pheromone gradients and to measure initial orientation, none of them have the capability to change the direction of the gradient, other than to invert it. We have developed a microfluidic device that can produce stable pheromone gradients and rapidly rotate them in 90° increments, mimicking the dynamic gradients yeast are exposed to in situ, and allowing for the study of reorientation as well as initial orientation. The mean angle of orientation exhibited by gradient-stimulated yeast cells in this device was 56.9°. In control experiments, cells subjected to pheromone coming from all four directions showed no evidence of orientation. Switching the direction of the pheromone source by 90° induced 83.6% of the polarized cells to change their direction of growth. Of these, 85.2% bent their mating projections toward the second source, demonstrating the utility of this device in the study of reorientation with specifically controlled gradients.