Most swimming photoautotrophic organisms show photo-induced behavioral changes (photobehavior). The present protocol observes the said photobehavior in the model organism Chlamydomonas reinhardtii.
For the survival of the motile phototrophic microorganisms, being under proper light conditions is crucial. Consequently, they show photo-induced behaviors (or photobehavior) and alter their direction of movement in response to light. Typical photobehaviors include photoshock (or photophobic) response and phototaxis. Photoshock is a response to a sudden change in light intensity (e.g., flash illumination), wherein organisms transiently stop moving or move backward. During phototaxis, organisms move toward the light source or in the opposite direction (called positive or negative phototaxis, respectively). The unicellular green alga Chlamydomonas reinhardtii is an excellent organism to study photobehavior because it rapidly changes its swimming pattern by modulating the beating of cilia (a.k.a., flagella) after photoreception. Here, various simple methods are shown to observe photobehaviors in C. reinhardtii. Research on C. reinhardtii's photobehaviors has led to the discovery of common regulatory mechanisms between eukaryotic cilia and channelrhodopsins, which may contribute to a better understanding of ciliopathies and the development of new optogenetics methods.
Light is an indispensable energy source for photosynthetic organisms, but too much light may cause photo-oxidative damage. Thus, phototrophic organisms need to survive under moderate intensity light, where they can photosynthesize but not suffer photo-oxidative damage1. In land plants, chloroplasts cannot move out from the leaf and show photo movements in the cell; chloroplasts move to the periphery of the cell under high light and the cell surface under low light2, whereas many motile algae show photobehaviors that allow them to find proper light conditions for photosynthesis and, thus, facilitate their survival3.
Chlamydomonas reinhardtii is a unicellular green alga regarded as a model organism in research fields like cilia (a.k.a., flagella), photosynthesis, and photobehavior. C. reinhardtii presents with one eyespot and two cilia per cell, used for photoreception and swimming, respectively. The eyespot has two components: channelrhodopsins (ChRs), light-gated ion channels in the plasma membrane, and the carotenoid-rich granule layers located right behind the ChRs. The eyespot acts as a directional light receptor since the carotenoid-rich granule layers function as a light reflector4,5.
ChRs were initially identified as photoreceptors causing photobehaviors in C. reinhardtii6,7,8,9. Although two isoforms, ChR1 and ChR2, are found in the eyespot, knock-down experiments showed that ChR1 is the primary photoreceptor for photobehaviors10. Despite this, ChR2 has received more attention and played a central role in developing optogenetics, a technique to control cell excitation by light11. Therefore, studying the regulatory mechanisms governing photobehaviors in C. reinhardtii will further the understanding of ChR function and improve optogenetics.
After photoreception, C. reinhardtii cells show two types of photobehaviors: phototaxis and photoshock response12. Phototaxis is the behavior of cells swimming in the direction of the light source or the opposite direction, called positive or negative phototaxis, respectively. Photoshock response is a behavior that cells show after sensing a sudden change in light intensity, such as when illuminated by a flash. Cells stop swimming or swim backward (i.e., swimming with the cell body forward) for a short period, typically <1 s.
Ciliary movements in C. reinhardtii are involved in its photobehaviors. Two cilia usually beat like a human's breaststroke swimming, and this is modulated for photobehaviors. For phototaxis, the forces generated by the two cilia are imbalanced by the modulation of the beating frequency and the waveform amplitude of each cilium13. The cilium closest to the eyespot is called cis cilium, and the other is called trans cilium. These two cilia differ on various points. For example, the ciliary beating frequency of trans cilium in vitro is 30%-40% higher14. In addition, their Ca2+ sensitivity is different. Reactivation of demembranated cell models15 showed that the cis cilium beats more strongly than the trans cilium for Ca2+ <1 x 10−8 M, while the opposite is true for Ca2+ >1 x 10−7 M. This asymmetry in Ca2+ sensitivity is possibly important for phototactic turns since mutants lacking this asymmetry do not exhibit normal phototaxis16,17. Conversely, waveform conversion is necessary for photoshock. The ciliary waveform transforms from the asymmetrical waveform in forward swimming to the symmetrical waveform in backward swimming. This waveform conversion is also regulated by Ca2+, at a threshold of 1 x 10−4 M18,19. Since defects in regulating ciliary movements cause primary ciliary dyskinesia in humans, studying photobehaviors in C. reinhardtii might help in better understanding of these diseases and therapeutic developments20.
Herein, four simple methods to observe photobehaviors in C. reinhardtii are demonstrated. First, a phototaxis assay using Petri dishes is shown, and second, a phototaxis assay against cell suspension droplets. The phenomenon observed in both cases is not strictly phototaxis but photo accumulation, where the cells tend to accumulate close to the light source side or the opposite side. In C. reinhardtii, photo accumulation is mainly caused by phototaxis in a way that can be used as an approximation to phototaxis. Third, a more rigorous assay for phototaxis under a microscope is shown, and last is a photoshock assay under a microscope.
In the present study, a wild-type strain of Chlamydomonas reinhardtii, a progeny of the cross CC-124 x CC-125 with agg1+mt-, was used21. CC-124 and CC-125 were obtained from the Chlamydomonas Resource Center (see Table of Materials) and maintained on a Tris-acetate-phosphate (TAP)22, 1.5% agarose medium at 20-25 °C. Any motile strain can be used for this protocol.
1. Cell culture
Figure 1: Liquid culture after 2-day culturing. From a TAP-1.5% agar plate, a chunk of wild-type cells filling the platinum loop was inoculated into ~150 mL of TAP liquid medium in a flask. The cell density after 2-day culture was ~5.0 x 106 cells/mL. Please click here to view a larger version of this figure.
2. Pretreatment of cells
Figure 2: Cell suspension under red light. A regular fluorescent white light covered with a sheet of red cellophane. A tube containing the cell suspension is placed under ~10 µmol photons·m−2·s−1 red light. Please click here to view a larger version of this figure.
3. Phototaxis assay using the Petri dish (so-called "dish assay")
Figure 3: Side illumination for phototaxis dish assay. (A) A Petri dish containing a cell suspension placed on a lightbox in a desktop darkroom. Green light (525 nm LED plate, ~100 µmol photons·m−2·s−1) illuminated from the side. (B) Alternative illumination method. A 5 mm cannonball-type LED. (C) To block light from the outside, a box with a black cloth on the inside can be used instead of a desktop darkroom. Please click here to view a larger version of this figure.
Figure 4: Example of negative phototaxis after 5 min side illumination. (A) Wild-type cell suspension in a Petri dish illuminated for 5 min. Most cells accumulated on the opposite side of the light source. These data can be interpreted as negative phototaxis. (B) Image of the dish from the top. Please click here to view a larger version of this figure.
Figure 5: Quantification of the dish phototaxis assay. An example of cells showing negative phototaxis (the light source is on the right side). The color picture is converted to a grayscale (Step 3.5.) and then inverted (Step 3.6.). Regions of interest (ROI), the whole dish (Step 3.7.), and the light-source-side half of the dish (Step 3.8.) were delimited. The density of each ROI was measured (Step 3.9.). In this case, the phototactic index (PI) is about 0.18 ([1,512 x 11.671] / [2,970 x 26.077]). PI is 1 or 0 when all cells show positive or negative phototaxis, respectively. Please click here to view a larger version of this figure.
4. Phototaxis assay using cell culture droplets
Figure 6: Droplet phototaxis assay. (A) Nine droplets of a 25 µL cell suspension placed on a white plastic sheet and illuminated from the side by a green LED. (B) After 3 min illumination. In each droplet, cells either accumulated on the light-source side (positive phototaxis), accumulated on the opposite side (negative phototaxis), or diffused into the droplet (no phototaxis). Scale bar = 1 cm. Please click here to view a larger version of this figure.
5. Phototaxis assay under a microscope
Figure 7: Making spacers on coverslip edges. (A) A thin layer of Vaseline was applied to the palm of a hand. A small amount of white petroleum was scraped off with the edge of a coverslip. (B) A spacer on the edge of a coverslip. (C) Another spacer on the opposite edge. Please click here to view a larger version of this figure.
Figure 8: Side illumination under a microscope. (A) Setup of a green LED. A cannonball-type green LED is fixed to the muff and fixed to the stand next to the microscope. Cells were observed under a dark-field microscope with a sharp cut filter (λ > 630 nm). (B) Side illumination by the green LED. Please click here to view a larger version of this figure.
Movie 1: Phototaxis assay under a microscope. Green light illuminated at ~0 s from the right. At that point, cells tended to swim in a random direction. After 0 s in the time counter, cells swam either to the right or left, showing positive or negative phototaxis. The light was turned off at ~15 s when cells started to swim in a random direction again. Scale bar = 100 µm. Please click here to download this Movie.
6. Tracking of phototactic cells and polar histogram drawing
7. Photoshock response assay under a microscope
Movie 2: Photoshock illumination by a camera flash. The camera flash was held up to the microscope stage and turned on. Please click here to download this Movie.
Movie 3: Photoshock response caused by a flash under a microscope. Cells were observed under dim red light. A flash was emitted at ~0 s. Almost all cells stopped forward swimming, swam backward for a short period, and recovered forward swimming. Scale bar = 100 µm. Please click here to download this Movie.
Movie 4: Photoshock response caused by removing a red filter under a microscope. Cells were observed under dim red light. The red filter was removed at ~5 s. Almost all cells stopped forward swimming, swam backward for a short period, and recovered forward swimming. Scale bar = 100 µm. Please click here to download this Movie.
Movie 5: Removing a red filter. Fast removal of a red filter set in the light path to deliver photoshock. Please click here to download this Movie.
Typical C. reinhardtii phototaxis and photoshock response assays are shown here. After cell density estimation, wild-type cell culture (a progeny of the cross CC-124 × CC-125 with agg1+ mt -)23 was washed with photobehavior experimental solution for the phototaxis dish assay. The cell suspension was placed under dim red light for ~1 h. A 2 mL cell suspension was placed in a 3.5 cm Petri dish. The Petri dish was shaken gently, put on a lightbox, and photographed with a camera fixed on a stand. The cells showed clear negative phototaxis in this case (i.e., cells accumulated to the opposite side of the light source) (Figure 4B).
The phototaxis and photoshock response assays under a microscope were carried out in a dark room to avoid light interference. Another wild-type strain, CC-125, which shows positive phototaxis, was used for these assays26. For the phototaxis assay, the recording is usually performed for ~25 s. Cells' trajectories were tracked from the position of each cell at 15 s to that at 16.5 s by Fiji.
The photoshock response assay was performed using a camera flash. Almost all cells exhibited the photoshock response, swam backward for a short period (~0.3 s), and recovered forward swimming (Movie 3). To quantify the data from this movie, two methods were followed (see previously published reports16,25): calculating the percentage of cells showing photoshock response among all cells16, and measuring the time from the beginning of each cell's backward swimming to the recovery of forward swimming25. The dependence of these values on light intensity can be verified by placing neutral density (ND) filters between the light source and the sample16.
Supplementary Figure 1: Frequency distribution table. Column A shows the sample number, and Column B shows the angle at Step 6.6. Column D shows the bins (12 bins of 30°). Column E shows the angular range per bin for reference. After selecting F2-F14, the FREQUENCY function in F2 is entered as shown in the fx window, and Shift + Ctrl + Enter is pressed to prepare the frequency distribution table. The sum (F15) must be equal to the total sample count in Column A. Please click here to download this File.
Supplementary Figure 2: Data rotation. To match the direction of the polar histograms with the actual direction of light illumination (from the right), the bins' angles are rotated in the frequency distribution table by −90°. For example, the sample count in the range 165°-135° (F3) shifts to 75°-45° (I6). The counts in the ranges 180°-165° (F2) and −165°-−180° (F14) are combined into the new range 105°-75° (I5). Please click here to download this File.
Supplementary Figure 3: Setting new bins for drawing the polar histogram. Rename the bins using the middle value of each 30° bin (Column K: e.g., rename the bin of 165°-−165° as −180°). The radar chart in Excel is set up with the first bin at 90°. Change the sample count (Column L) to a percentage (Column M) to compare different data regardless of the number of samples. Enter 0 between each datum (e.g., M3, M5, M7…) to represent the values of each bin as a line in the radar chart. Please click here to download this File.
Supplementary Figure 4: Radar chart representing a polar histogram for a phototaxis assay. Draw a radar chart using the bins (Column K) as horizontal axis labels and the percentage values (Column M) as a legend. A typical polar histogram depicting the percentage of CC-125 cells moving in a particular direction relative to light illuminated from the right (0°) (12 bins of 30°; n = 30 cells). Please click here to download this File.
The present protocol is easy and not time-consuming. If a C. reinhardtii mutant is suspected of presenting with defects in photoreception or ciliary motion, this method could serve as primary phenotypic analysis.
However, some critical steps exist. One is to use cells in the experiment in the early to mid-log growth phase. After culturing for long periods, cells become less motile, less light-sensitive, and even form palmelloids (cell clumps)27. Another important step is to expose the cells to the red light before the experiment (Step 2.4.). Cells exhibit high light responsiveness and motility by avoiding ChR stimulation while maintaining photosynthetic activity. Cell observation under a microscope must confirm that the light is shining on the cells. Especially when using a small, highly directional LED, a slight deviation of the optical axis can prevent the light from illuminating the cells.
A clear drawback of the dish and droplet phototaxis assays is that they are rather qualitative. Although the results can be quantified, as shown in Steps 3.4.-3.9., phenomena other than phototaxis may affect the results. For example, cells may stick to dishes or plastic plates depending on culture conditions or the dish/plate material. Thus, caution must be exercised if data suggest no or poor phototaxis. Selecting the appropriate method according to the purpose is important because these methods demonstrate the great advantage of simplicity.
These methods are remarkable in that they are easy and simple. Several sophisticated methods are available to assess photobehavior in Chlamydomonas28 or Euglena29. However, they can be difficult to perform in many laboratories. The methods described here do not require a special microscope but a cheap LED or a camera flash. Due to this simple setting, the methods are also very versatile. For example, to study the effect of light intensity on photobehavior, ND filter can be placed between the light source and the sample16. To examine the action spectrum of the behavior, the color of the LED light source can be exchanged30.
The rationale for using green light (λ = 525 nm) for phototaxis assays is that the maximum absorption wavelength of ChR1, the photoreceptor for phototaxis, is ~485 nm, close to the absorption peak of chlorophyll b at ~470 nm10,31. Since a change in photosynthetic activity can affect phototactic signs, using green is recommended as it can be absorbed by ChR1 but not so well by chlorophyll32. However, if only phototactic ability is tested, blue light could be used as a light source instead. To examine temporal changes in photosynthetic activity over phototactic signs, it is recommended to use a white light source containing the wavelength range between 425-550 nm, which is well absorbed by ChR1.
Phototactic signs are regulated by cellular reactive oxygen species (ROS). When ROS accumulates, cells show positive phototaxis, and when depleted, cells show negative phototaxis26. Membrane-permeable ROS reagents or ROS-scavenging reagents induce positive or negative phototaxis, respectively. Typically, H2O2 or t-BOOH are used as ROS reagents, while dimethylthiourea (DMTU) is used as an ROS-scavenger. Thus, a phototactic assay in these reagents can be used to screen for mutants with defects in phototaxis sign-switching, which may relate to defects in photoreception or ROS-related metabolism4,21,33.
Photoshock responses are caused by Ca2+ influx from the tip of the cilia via voltage-dependent Ca2+ channels following ciliary waveform conversion18,34. Although the Ca2+-dependent waveform conversion of cilia is common to many eukaryotic organisms, its molecular mechanism is not yet fully understood35. If a C. reinhardtii mutant shows defects in the photoshock response but normal phototaxis, it would suggest normal photoreception ability. In short, the quick and simple assay for the photoshock response shown here can help to understand the common molecular mechanism for the Ca2+-dependent waveform conversion in eukaryotic cilia.
The authors have nothing to disclose.
This study was supported by grants from the Japan Society for the Promotion of Science KAKENHI (https://www.jsps.go.jp/english/index.html) to NU (19K23758, 21K06295), TH (16H06556), and KW (19H03242, 20K21420, 21H00420), from the Ohsumi Frontier Science Foundation (https://www.ofsf.or.jp/en/) to KW, and from the Dynamic Alliance for Open Innovation Bridging Human, Environment and Materials (http://alliance.tagen.tohoku.ac.jp/english/) to NU, TH, and KW.
15 mL conical tube | SARSTEDT | 62.554.502 | |
5 mm Cannonball green LED | Optosupply | OSPG5161P | |
50 mL conical tube | SARSTEDT | 62.547.254 | |
AC adaptor for the light box | ATTO | 2196161 | |
Auto cell counter | DeNovix | CellDrop BF | |
CaCl2 | Nakalai tesque | 06731-05 | |
Camera flash | NEWWER | TT560 | |
Centrifuge | KUBOTA | 2800 | |
Chlamydomonas strains CC-124 and CC-125 | Chlamydomonas Resource Center | https://www.chlamycollection.org/ | |
C-mout CCD camera | Wraymer | 1129HMN1/3 | |
Desktop darkroom | Scientex | B-S8 | |
Digital still camera | SONY | RX100II | |
EGTA | Dojindo | G002 | |
Fiji | https://fiji.sc/ | ||
Green LED plate | CCS | ISLM-150X150-GG | |
HCl | Fujifilm WAKO | 080-01066 | |
HEPES | Dojindo | GB70 | |
KCl | Nakalai tesque | 238514-75 | |
Lightbox (Flat viewer) | ATTO | 2196160 | |
Microscope | Olympus | BX-53 | |
Petri dish (φ3.5 cm) | IWAKI | 1000-035 | |
Pottasium acetate | Nakalai tesque | 28434-25 | |
Power supply for the green LED plate | CCS | ISC-201-2 | |
Red filter | Shibuya Optical | S-RG630 |