Formation of singlet oxygen (1O2) was reported to accompany light stress in plants, contributing to cell signaling or oxidative damage. So far, Singlet Oxygen Sensor Green (SOSG) has been the only commercialized fluorescent probe for 1O2 imaging though it suffers from several limitations (unequal penetration and photosensitization) that need to be carefully considered to avoid misinterpretation of the analysed data. Herein, we present results of a comprehensive study focused on the appropriateness of SOSG for 1O2 imaging in three model photosynthetic organisms, unicellular cyanobacteria Synechocystis sp. PCC 6803, unicellular green alga Chlamydomonas reinhardtii and higher plant Arabidopsis thaliana. Penetration of SOSG differs in both unicellular organisms; while it is rather convenient for Chlamydomonas it is restricted by the presence of mucoid sheath of Synechocystis, which penetrability might be improved by mild heating. In Arabidopsis, SOSG penetration is limited due to tissue complexity which can be increased by pressure infiltration using a shut syringe. Photosensitization of SOSG and SOSG endoperoxide formed by its interaction with 1O2 might be prevented by illumination of samples by a red light. When measured under controlled conditions given above, SOSG might serve as specific probe for detection of intracellular 1O2 formation in photosynthetic organisms.
Singlet oxygen (1O2) formation is known as a distinctive functional response of organisms to stress stimuli. In plant cells, it has been linked mainly to high light1,2,3,4 but it has been known to occur also in other types of abiotic stress as high temperature, wounding or heavy metals5. At high light, 1O2 is formed by triplet-triplet energy transfer from triplet chlorophyll to molecular oxygen formed either by change in the spin orientation and charge recombination of the triplet radical pair3 [P680•+Pheo•−] in the antennae complex and the reaction centre of photosystem II (PSII)6,7,8. Under high temperature and wounding, 1O2 was shown to be formed by triplet-triplet energy transfer from triplet carbonyls to molecular oxygen formed during lipid peroxidation9,10,11. The role of 1O2 in plant organism is ambivalent; under moderate stress, 1O2 appears to act in retrograde signaling pathways12,13,14, whereas under severe stress, it causes oxidative damage of proteins and lipids15,16,17. At low 1O2 concentrations, retrograde signaling is associated with acclimation response, whereas at high 1O2 concentrations it is accompanied with programmed cell death13.
Several spectroscopic and microscopic techniques have been used to detect 1O2 formation in photosynthetic organisms both in vitro and in vivo2,18,19. Whereas in vitro 1O2 detection affords information on the quantification of 1O2 formation, in vivo techniques provide evidence on the spatiotemporal characterization of 1O2 within the plant cells. In vitro 1O2 detection comprises 1O2 phosphorescence, chemical trapping, and spin probe methods. Direct detection of 1O2 by phosphorescence at 1270 nm and chemical trapping based on O2 uptake due to the reaction of 1O2 with histidine or imidazole are feasible solely in isolated PSII reaction centres3. Spin probe technique based on the oxidation of diamagnetic nitroxide to paramagnetic nitroxyl radical detected by electron paramagnetic spectroscopy (EPR) is possible in PSII membranes, thylakoids and chloroplasts20,21,22. In vivo 1O2 detection includes cytochemical techniques using fluorescent and chemiluminescent probes combined with microscopic imaging23. In the last two decades, dansyl-based (DanePy)24 and Singlet Oxygen Sensor Green reagent® (SOSG)9 fluorescent probes based on the formation of endoperoxides were used to monitor 1O2 formation in photosynthetic organisms. These probes are composed of an anthracene moiety (electron donor) that quenches the fluorescence of the fluorochrome (electron acceptor) through electron transfer. Once the anthracene moiety traps 1O2, the resultant oxygen adduct fails to be functional intramolecular electron donor and the fluorescence is recovered.
Singlet Oxygen Sensor Green has been released and tested on plants since mid-2000’s9,23. Unlike other available fluorescent and chemiluminescent 1O2 probes, SOSG fulfils the requirement of high selectivity and specificity. It does not show an appreciable response to superoxide anion radical (O2•−) or hydroxyl radical (HO•) which is important especially in chloroplasts where a wide range of ROS are formed4. This fluorescein-based dye probe initially exhibits weak blue fluorescence at 395 and 416 nm, under excitation at 372 and 393 nm, respectively. Upon reaction with 1O2, the imminent product SOSG endoperoxide (SOSG-EP) provides green fluorescence, with the excitation and emission maxima lie, based on several authors, in the range of 504–508 nm and 525–536 nm, respectively25,26,27. Spectral properties of SOSG are similar to those of fluorescein which made this probe suitable for observation with a wide range of fluorescence and confocal microscope systems equipped with standard filters.
However, SOSG is known to have several drawbacks (unequal penetration and photosensitization) that must be taken into consideration. SOSG was introduced as a cell-impermeable probe but later studies shown its localization in most cell compartments under different stress conditions9,23,28. Further constraints of SOSG application in light-dependent studies is due to its photosensitization. It was demonstrated that SOSG can generate 1O2 under exposure to UV radiation (355 nm) and visible light (532 nm), respectively25. Later, it was shown that SOSG-EP can serve as photosensitizer even with much higher efficiency than SOSG26. A detailed study on SOSG photochemistry showed that singlet excited SOSG converts to triplet excited SOSG via intersystem crossing which further transfers the triplet excitation energy to molecular oxygen forming 1O227.
Due to the SOSG and SOSG-EP photosensitization, an effort was initiated to discover fluorescent probe characterized by specificity and sensitivity similar to SOSG; however, lacking its negative trait of photosensitization25. Pedersen and co-workers discovered and applied on mammalian cells, a modified 1O2 indicator called Aarhus Sensor Green (ASG) (a tetrafluoro-substituted fluorescein derivative covalently linked to a 9,10-diphenyl anthracene moiety)29. Aarhus Sensor Green is characterized by spectral properties similar to SOSG omitting its negative trait of photosensitization. Nevertheless, ASG has neither been tested on plants nor available for routine applications. Thus developing new 1O2 sensors remained a goal of research teams. In chemical systems, more alternatives to SOSG exist, including FRET-based ratiometric monitoring of 1O2 with acene-doped conjugated polymer nanoparticles30 or 1O2 detection in solutions by Bodipy-based energy transfer cassette31. Recently, Tang et al.32 proposed an alternative indocyanine green (ICG), a near-infrared (NIR) tricarbocyanine probe that is decomposed after reaction with 1O2. However, the absorption and emission peaks of ICG at ~807 nm and ~822 nm, respectively, make it less convenient for the fluorescence microscopy.
The present study deals with the re-examination of SOSG properties for its possible utilization in model photosynthetic organisms (cyanobacteria, algae, and higher plants) under high light. Penetration of SOSG into the cells can be enhanced by mild heating (cyanobacteria) or moderate-pressure tissue infiltration (higher plants) under conditions avoiding 1O2 formation by high temperature or leaf wounding itself. Illumination by a red light (λ ≥ 600 nm) is advised to avoid 1O2 formation due to SOSG and SOSG-EP photosensitization. As the experimental conditions may significantly affect the obtained results, we attempt to summarize the principal factors that must be taken into account when imaging 1O2 with SOSG in photosynthetic organisms.
Material and Methods
Synechocystis sp. (PCC 6803) was grown in BG-11 medium supplemented with 5 mM glucose and 5 mM sodium bicarbonate as the main carbon source under a continuous white light (100 μmol photons m−2 s−1) at 25 °C33. The cell culture was permanently stirred using magnetic stirrer RT 5 power (IKA Werke GmbH, Staufen, Germany) to obtain a constant CO2 concentration in the growth medium. The cells from the end of log phase at a density of approximately 108–109 cells ml−1 were used for experiments. Chlamydomonas reinhardtii (CC-002) was obtained from the Chlamydomonas Genetic Center (Duke University, Durham, NC, USA). The cells were cultivated in Tris-Acetate-Phosphate (TAP) medium or in Bold’s basal medium (BBM) in a continuous white light (100 μmol photons m−2 s−1) in Algaetron AG 230 (Photon Systems Instruments, Drásov, Czech Republic). The growth was achieved under permanently stirred condition using shaker (Orbital Shaker PSU-10i, Biosan, Riga, Latvia) to obtain a constant CO2 concentration in the growing medium10,34. The cells were studied at a density of approximately 7 × 107 cells ml−1 during the stationary growth phase. Arabidopsis thaliana (Col-0) seeds from the Nottingham Arabidopsis Stock Centre (NASC) were soaked in distilled water for 4 days at 4 °C and transferred into the growing pots filled with a peat substrate (Klasmann, Potground H). The plants were grown for 4–6 weeks in a growing chamber at a photoperiod of 8/16 h light/dark (100 μmol photons m−2 s−1) at a temperature of 22 °C/20 °C, respectively and relative humidity 60%.
Synechocystis cells (BG-11 medium, pH 7.1), Chlamydomonas cells (TAP medium, pH 7.0 or BBM medium pH 6.8) and Arabidopsis leaf pieces with adaxial side of leaf up (5 × 5 mm, HEPES pH 7.5) were placed in 2 ml Eppendorf tube and treated with 50 μM SOSG (Molecular Probes Inc., Eugene, OR, USA) for 30 min either in dark or exposed to light. For Synechocystis and Chlamydomonas cells, the media containing SOSG was replaced with growing medium before measurement while for Arabidopsis leaf, the measurement was done in pure buffer.
The illumination was performed using a LED source with a light guide CL6000 LED Zeiss (Carl Zeiss Microscopy GmbH, Jena, Germany). Samples were exposed to continuous white light (λ = 400–750 nm) or red light (λ ≥ 600 nm) with an intensity of 1000 μmol photons m−2 s−1 transferred by optical fiber guide to the top of Eppendorf tube. Long-pass edge interference filter (600 nm) (Andover Corporation, Salem, NH, USA) was used to cut off the blue-green region of the spectra.
Fluorescence emission spectra
Fluorescence emission spectra were measured using a fluorescence spectrometer F-4500 (Hitachi, Tokyo, Japan). For fluorescence emission spectra, the SOSG was excited at 488 nm and SOSG-EP fluorescence was recorded in the spectral range of 500–640 nm.
Singlet oxygen imaging by confocal laser scanning microscopy
Immediately after staining, the cells were transferred to corresponding fresh media and visualized by confocal laser scanning microscopy (Fluorview 1000 unit attached to IX80 microscope; Olympus Czech Group, Prague, Czech Republic). The excitation of SOSG was performed by a 488 nm line of an argon laser and the emission was detected by a 505–525 nm filter. Cell morphology was visualized by transmitted light detection module with 405 nm excitation using a near ultraviolet (405 nm) diode laser and differential interference contrast (DIC) filters. The proper intensity of all lasers was set according to unstained samples at the beginning of each experiment35. Integral distribution of signal intensity (0–4096) in 12-bit microphotographs was evaluated by image analysis software FV10-ASW 4.0 Viewer (Olympus).
To monitor 1O2 formation in unicellular photosynthetic organisms, SOSG-EP fluorescence was detected in Synechocystis (Figs 1–3) and Chlamydomonas (Fig. 4) cells by confocal laser scanning microscopy. Figures 1 and 4 demonstrate Nomarski DIC channel (greyscale), fluorescence channel (green), the combination of both channels and the integral distribution of the signal intensity within the sample. When Synechocystis cells were exposed to red light in the presence of SOSG, SOSG-EP fluorescence was observed. Detail focus shows that SOSG-EP fluorescence is distributed uniformly in the whole cell (Fig. 1). Similarly, exposure of Chlamydomonas cells to red light resulted in the appearance of SOSG-EP fluorescence localized predominantly within the chloroplasts (Fig. 4). Whereas the penetration of SOSG into the Chlamydomonas cells has no serious limitation and uptake can be achieved by the placement of cells in the dye, the penetration of SOSG into the Synechocystis cells is restricted due to the presence of polysaccharide matrix forming mucous surface structures. Figure 2 shows that SOSG penetration into the Synechocystis cells is improved largely by mild heating (37 °C) known to dissolve mucoid sheath. As mild heating of Synechocystis cells did not enhanced SOSG-EP fluorescence in dark (data not shown), it indicates that mild heating to 37 °C causes no 1O2 formation by lipid peroxidation initiated by lipoxygenase as previously shown in Chlamydomonas exposed to 40 °C10. Figure 3 (red circle) shows that some cells exhibit SOSG-EP fluorescence from the outer regions of the cell. A series of optical sections through the cells reveals that SOSG is uniformly spread out in these cells and SOSG-EP fluorescence from the outer regions of the cell is due to the plane of focus. In order to confirm that observed SOSG-EP fluorescence enhancement is due to 1O2 generation, the effect of scavengers of 1O2 (sodium azide/histidine) was measured in Chlamydomonas cells exposed to red light. A considerable suppression in SOSG-EP fluorescence was observed (see Supplementary Figs S4–S5).
Light-induced formation of 1O2 was accordingly visualized with SOSG in Arabidopsis leaves (Fig. 5). When Arabidopsis leaves were exposed to red light in the presence of SOSG, the SOSG-EP fluorescence was detected predominantly from the chloroplasts located at the periphery of the mesophyll cells (Fig. 5A). Figure 5B shows a series of SOSG-EP fluorescence at limiting shades [0–1500 or 50–1000] and increasing contrast of SOSG-EP channel [contrast range: 1–3]. In Arabidopsis leaves, SOSG penetration is limited due to the tissue complexity comprising the upper and lower epidermis covered by cuticle. Penetration of SOSG into the mesophyll cells can be achieved through cutting edge (to a less extent by stomata) by pressure infiltration using the shut syringe. The efficiency of SOSG penetration into the mesophyll cells depends on several factors including the leaf age and water content within the tissue (data not shown). This approach is efficient in the uniform delivery of SOSG into the mesophyll cells and gentle with respect to mechanical injury known to cause 1O2 formation as previously shown in Arabidopsis leaves11. Different approaches such as spontaneous diffusion measured either at the centre of the excised leaf or at cut edges and vacuum infiltration were used; however, no penetration or uneven penetration was possible to be achieved (Fig. 6A). Furthermore, force infiltration with syringe results in the uneven delivery of SOSG to the mesophyll cells and the leaf injury at the site of puncture. Figure 6B shows that penetration into the tissues is inconsistent, randomly distributed in the both intercellular and extracellular spaces. The mechanical injury provides the highest signal in the centre (100x magnification) and influences results of staining upon stress treatment (at 400x magnification focused on layers of sponge and below on palisade parenchyma cells).
To confirm that SOSG penetrates uniformly into the cells, 3-D distribution of SOSG-EP fluorescence within cells or tissues was visualized by Z-stacks of thin optical sections. Figure 7 shows a series of 5 optical sections with a distance of 0.5 µm (Synechocystis cells), 1 µm (Chlamydomonas cells) and 4 µm (Arabidopsis leaves), respectively. SOSG-EP fluorescence measured in the multiple layers in Synechocystis and Chlamydomonas cells were observed from overall cell volume with fluorescence intensity higher at the cell periphery. In Arabidopsis leaves, SOSG-EP fluorescence comes predominantly from the chloroplasts located at the periphery of the cells. These results show that penetration of the probe (at the depth of cells and tissues) can be reached with a proper modified procedure of staining.
To test the photosensitization of SOSG and SOSG-EP, the probe was first illuminated in the absence of sample either with red (λ ≥ 600 nm) or white (400–750 nm) light (Fig. 8). Figure 8A shows SOSG/SOSG-EP fluorescence detected by confocal laser scanning microscopy. When SOSG was kept in dark or exposed to red light, negligible SOSG-EP fluorescence was detected. On the contrary, exposure of SOSG to white light resulted in pronounced SOSG-EP fluorescence. Figure 8B shows SOSG/SOSG-EP fluorescence spectra with an emission maximum at 535 nm measured using fluorescence spectrometer. When SOSG was exposed to white light, SOSG-EP fluorescence was several folds higher compared to red light. Based on these results, it is concluded that red light did not cause 1O2 formation due to the photosensitization of SOSG and SOSG-EP, whereas white light resulted in SOSG and SOSG-EP photosensitization. In further, SOSG was illuminated either with red or white light in Synechocystis cells (Fig. 9), Chlamydomonas cells (Fig. 10) and Arabidopsis leaves (Fig. 11) (also see Supplementary Figs S1–S3). In the dark, negligible SOSG-EP fluorescence was due to excitation of SOSG probe by a laser beam, 1O2 formation by excitation of photosynthetic pigments by a laser beam and/or dark 1O2 formation due to the spontaneous oxidative processes. When Synechocystis (Fig. 9) and Chlamydomonas (Fig. 10) cells were exposed to white light, SOSG-EP fluorescence was enhanced as compared to red light. Similarly, when Arabidopsis leaves were exposed to white light, the intensity of SOSG-EP fluorescence was higher compared to red light (Fig. 11). These results show that exposure of SOSG to white light causes SOSG and SOSG-EP photosensitization.
In the current study, the use of SOSG for monitoring of 1O2 formation was tested in three model photosynthetic organisms. It can be mentioned that despite being tested for numerous applications in the last decade, the exact composition of this probe was not known during initial 5 years of its utilization. Later, Ragas with co-workers showed a combination of fluorescein and anthracene moieties in SOSG by liquid chromatography and UV-VIS spectra, complemented with mass spectrometry and NMR spectroscopy25. As the use of SOSG for detection of 1O2 formation has a restriction regarding the probe penetration into the cells and probe photosensitization, it is crucial to control the uniform distribution of SOSG in the cells and prevent SOSG photosensitization36.
Penetration of fluorochromes into the plant cells has been a matter of discussions23,37,38. SOSG has been claimed as a cell-impermeant substance by the producer39; however, experiences acquired during the last decade of its application on biological samples by several research groups proved that it is uptaken by animal cells26,40. Unlike animal cells, the presence of cell wall in combination with additional mechanical barriers containing polysaccharide sheath enclosing in the cyanobacteria or cuticle waxes in the plant might hinder delivery of the fluorochrome to the precise organelles of plant cells38. Since no diacetate form of SOSG has been available to ease the probe uptake through the plasma membrane, a relatively high concentration (50–250 µM) and longer incubation periods (30 min) has to be used. Since Flors and co-workers9 reported the applications of SOSG on diatom species and Arabidopsis leaves, several teams employed SOSG in their experiments with unicellular organisms41 and higher plant42,43,44,45,46. SOSG-EP fluorescence visualized in the multiple optical sections through cells of Synechocystis, Chlamydomonas and Arabidopsis confirmed that SOSG penetrates into cells in all tested model photosynthetic organisms (Figs 3 and 7). However, it should be pointed here that confocal laser scanning microscopy has to be used to prove the proper even penetration of the probe into the cells. Detection of 1O2 formation exclusively by fluorescence spectrometer might lead to the detection of SOSG-EP fluorescence originating from the extracellular space and thus can be lead to a false signal and misinterpretation of the analysed data.
SOSG permeability in unicellular organisms
It is of note that some authors reported that SOSG does not penetrate inside the intact Synechocystis cells47,48. Synechocystis cells are known to excrete polysaccharides to form an outermost slimy layer during cell growth49. Penetration of SOSG into the cells enclosed by capsule and mucus might represent a mechanical barrier for SOSG penetration into the Synechocystis cells. In this study, we clearly demonstrated that using active cells from the log phase of the growing curve combined with an increase in temperature (37 °C for ca 15 min) as used previously47 can substantially increase the uptake of SOSG (Figs 1 and 2). It is proposed here that secreting the mucus out of Synechocystis cells can decrease SOSG infiltration at later stages of cultivation in liquid media or on agar.
SOSG permeability in higher plants
Conversely, higher plants with multiple types of cells and tissues represent a significantly greater challenge. Based on our experiences, the effort to detect intracellular generation of 1O2 in multicellular plants can be complicated by uneven staining or mechanical injury during handling with samples. It should be also noted that O2, CO2 and other gases produced by the metabolism of living tissue create microbubbles within intercellular space which counteract with uniform sensor delivery to all cells. We have tested several approaches for SOSG infiltration to tissues of Arabidopsis leaves comprising spontaneous diffusion, vacuum infiltration, force infiltration with a syringe and pressure infiltration using the shut syringe. Spontaneous diffusion in centre of the excised leaf based on transpiration stream (Fig. 6A, upper row) and vacuum filtration (Fig. 6A, lower row) were found to be with no or uneven distribution of the fluorescent probe. Spontaneous diffusion at cut edges allows uniform distribution of SOSG within several layers of cells from the cut edge (Fig. 6A, middle row). However, the light-induced formation of 1O2 was largely overlapped by 1O2 formed due to the mechanical injury at the cut edge. It has been recently demonstrated that 1O2 is formed by lipid peroxidation initiated by lipoxygenase at the cut edge in the Arabidopsis wounding response11. The use of spontaneous diffusion at cut edge is possible when 1–3 layers of cells on the cut edge with 1O2 formation due to the mechanical injury is excluded from the evaluation. Force infiltration of SOSG with syringe into the leaf tissues through a hole exerted by a needle leads to uneven distribution of the fluorescent probe limited to a leaf mesophyll enclosed by vascular bundles. Furthermore, 1O2 is largely formed at the site of hole due to the mechanical injury. The observation that force infiltration of SOSG with syringe is inappropriate is in agreement with previous finding that pinhole infiltration maintains SOSG penetration into the epidermal cells which is unsuitable for study of high light stress23. Pressure infiltration using the shut syringe of leaf pieces was found to be both efficient in the uniform distribution of SOSG in the whole sample and unaffected by 1O2 formation due to the mechanical injury.
Both SOSG and SOSG-EP were shown to serve as photosensitizers at visible light range25,26,27. In this reaction, singlet excited SOSG formed by excitation of SOSG by visible light passes to the triplet excited SOSG by a change in the orientation of the spin of excited electron via intersystem crossing. Triplet-triplet energy transfer from a triplet excited SOSG to molecular oxygen results in the formation of 1O2 and ground state SOSG. Due to these considerations, the relevance of pioneering works published need to be reconsidered cautiously as it might be possible that part of the 1O2 was produced by SOSG and SOSG-EP itself.
SOSG photosensitization in high-light treatment
Our results demonstrated that SOSG kept in dark or exposed to red light emits only negligible SOSG-EP fluorescence compared to white light (Fig. 8). Similarly, when Synechocystis cells (Fig. 9), Chlamydomonas cells (Fig. 10) and Arabidopsis leaves (Fig. 11) were exposed to white light, pronounced enhancement in SOSG-EP fluorescence was observed as compared to red light. These results demonstrate that a significant increase in SOSG-EP fluorescence upon illumination of SOSG with white light is caused by SOSG and SOSG-EP photosensitization. It is proposed that red light led to the formation of 1O2 by triplet-triplet energy transfer from excited chlorophyll to molecular oxygen, while white light caused the overall 1O2 formation due to the triplet-triplet energy transfer from excited chlorophyll and excited SOSG/SOSG-EP to molecular oxygen.
SOSG photosensitization during data collection
Imaging of SOSG and SOSG-EP fluorescence signal is mostly provided by confocal systems employing a 488 nm laser for excitation. However, the complex part of the microscopic study is finding the site of interest within a biological sample. Several authors23,25 registered an increase of SOSG fluorescence upon exposure to visible radiation. Epifluorescence microscopy of SOSG also utilizes visible light filters but the artefactual SOSG-EP fluorescence can be diminished by a standardized imaging design in which observations under a proper filter, in our case U-MNB-2 (excitation 470–490 nm, emission 520-IF, dichroic at 500 nm), are limited to a minimum time necessary for the only fast sample navigation and focusing.
SOSG imaging and post-processing techniques
Synechocystis is characterized by a prokaryotic cell type (i.e. without internal compartmentalization) which size changes over the cell cycle; cells from the logarithmic and stationary phase of growth curve usually reach 1.5–2.5 µm in diameter50. Confocal laser scanning microscopy enables detection of the signal from a single focal plane and therefore imaging of more cyanobacterial cells in a single figure might be confusing as it usually includes also cells out of focus. In Chlamydomonas, the presence of flagella exerting algal movement hampers the relatively long confocal imaging. Unfortunately, the requirement of intactness of the cell for in vivo studies excludes the use of heat or chemicals used for flagella release. Thus, for unicellular organisms (cyanobacteria, algae) small volumes (ca 5–10 µl under cover slide) of the treated cell suspension can be advised for their immobilization throughout the microscopic observation. To study the 3-D distribution of SOSG-EP fluorescence within cells or tissues, Z-stacks of thin optical sections are employed in confocal microscopy. However, the time vs. resolution during scanning vs. number of optical sections must be compromised to avoid photobleaching. The mode how studied biological matrices affect the outcome of SOSG staining was compared in the three photosynthetic models and SOSG proved to be rather stable, i.e. suitable for multi-layer scans. To verify signal location, particularly in small objects like prokaryotic cells, it is advisable to decrease the pinhole size to 0.9–0.5 airy units, according to signal intensity. Based on the results when SOSG-EP fluorescence was detected in almost all optical sections of the various photosynthetic samples, ranging from unicellular prokaryote Synechocystis to complex tissue structure in Arabidopsis leaves, it can be pointed out that SOSG does not suffer from a significant photobleaching compared to other fluorescein probes.
Once collected the whole set of microphotographs (taken under the same standardized conditions) can be post-processed in suitable software to optimize signal-to-noise ratio and thus unable more clear presentation of the signal on screen or in print, particularly for figures with merged channels. This can help especially in 12-bit and 16-bit images, characterized by 4,096 and 65,536 shades, respectively. A universal approach cannot be advised due to the variability of plant materials but the crucial point is to apply the identical algorithm to all variants compared in the experiment to avoid false positive signals. Especially in multi-celled tissues, like Arabidopsis leaf sections, the signal location in chloroplasts is better visible after filtering the background and highlighting the SOSG signal in merged figures (Fig. 5B).
The data presented in this study are expected to contribute to better understanding of the limitation in the use of SOSG for 1O2 detection in the photosynthetic organism. Although SOSG penetration into the cell and photosensitization of SOSG by visible light entails the main limitation of SOSG applicability in studies focused on high light stress in the photosynthetic organism, awareness of all the previously mentioned criteria (suitable infiltration procedure and red light) may lead to credible results. When measured under these conditions, SOSG can attend as highly sensitive and specific probe to identify the site of 1O2 formation in unicellular photosynthetic organisms and higher plants. However, quantitative analysis of 1O2 formation performed exclusively based on SOSG-EP fluorescence images is misleading. Only combination of several methods, e.g. SOSG-EP fluorescence imaging in vivo and spin probe EPR spectroscopy in vitro, provides comprehensive spatiotemporal and quantitative characterization of 1O2 formation in photosynthetic organisms. The different level of 1O2 production in different organism can also be attributed to variable cell density, different chlorophyll content, antioxidant level, within the cell/tissues etc. and thus based on the parameters to be evaluated, proper control experiments are required.
Triantaphylides, C. & Havaux, M. Singlet oxygen in plants: production, detoxification and signaling. Trends Plant Sci 14, 219–228, https://doi.org/10.1016/j.tplants.2009.01.008 (2009).
Fischer, B. B., Hideg, E. & Krieger-Liszkay, A. Production, Detection, and Signaling of Singlet Oxygen in Photosynthetic Organisms. Antioxidants & Redox Signaling 18, 2145–2162, https://doi.org/10.1089/ars.2012.5124 (2013).
Telfer, A. Singlet Oxygen Production by PSII Under Light Stress: Mechanism, Detection and the Protective role of beta-Carotene. Plant and Cell Physiology 55, 1216–1223, https://doi.org/10.1093/pcp/pcu040 (2014).
Pospíšil, P. Production of Reactive Oxygen Species by Photo system II as a Response to Light and TemperatureStress. Frontiers in Plant Science 7, 12, https://doi.org/10.3389/fpls.2016.01950 (2016).
Pospíšil, P. & Prasad, A. Formation of singlet oxygen and protection against its oxidative damage in Photosystem II under abiotic stress. Journal of Photochemistry and Photobiology B-Biology 137, 39–48, https://doi.org/10.1016/j.jphotobiol.2014.04.025 (2014).
Krieger-Liszkay, A., Fufezan, C. & Trebst, A. Singlet oxygen production in photosystem II and related protection mechanism. Photosynthesis Research 98, 551–564, https://doi.org/10.1007/s11120-008-9349-3 (2008).
Vass, I. Molecular mechanisms of photodamage in the Photosystem II complex. Biochim Biophys Acta 1817, 209–217, https://doi.org/10.1016/j.bbabio.2011.04.014 (2012).
Pospíšil, P. Molecular mechanisms of production and scavenging of reactive oxygen species by photosystem II. Biochim Biophys Acta 1817, 218–231, https://doi.org/10.1016/j.bbabio.2011.05.017 (2012).
Flors, C. et al. Imaging the production of singlet oxygen in vivo using a new fluorescent sensor, Singlet Oxygen Sensor Green. J Exp Bot 57, 1725–1734, https://doi.org/10.1093/jxb/erj181 (2006).
Prasad, A., Ferretti, U., Sedlářová, M. & Pospíšil, P. Singlet oxygen production in Chlamydomonas reinhardtii under heat stress. Scientific Reports 6, 20094, https://doi.org/10.1038/srep20094 (2016).
Prasad, A., Sedlářová, M., Kale, R. S. & Pospíšil, P. Lipoxygenase in singlet oxygen generation as a response to wounding: in vivo imaging in Arabidopsis thaliana. Scientific Reports 7, https://doi.org/10.1038/s41598-017-09758-1 (2017).
Apel, K. & Hirt, H. Reactive oxygen species: metabolism, oxidative stress, and signal transduction. Annual Review of Plant Biology 55, 373–399, https://doi.org/10.1146/annurev.arplant.55.031903.141701 (2004).
Laloi, C. & Havaux, M. Key players of singlet oxygen-induced cell death in plants. Frontiers in Plant Science 6, https://doi.org/10.3389/fpls.2015.00039 (2015).
Gollan, P. J., Tikkanen, M. & Aro, E.-M. Photosynthetic light reactions: integral to chloroplast retrograde signalling. Current Opinion in Plant Biology 27, 180–191, https://doi.org/10.1016/j.pbi.2015.07.006 (2015).
Aro, E. M. et al. Dynamics of photosystem II: a proteomic approach to thylakoid protein complexes. Journal of Experimental Botany 56, 347–356, https://doi.org/10.1093/jxb/eri041 (2005).
Triantaphylides, C. et al. Singlet oxygen is the major reactive oxygen species involved in photooxidative damage to plants. Plant Physiology 148, 960–968, https://doi.org/10.1104/pp.108.125690 (2008).
Pospíšil, P. & Yamamoto, Y. Damage to photosystem II by lipid peroxidation products. Biochimica Et Biophysica Acta-General Subjects 1861, 457–466, https://doi.org/10.1016/j.bbagen.2016.10.005 (2017).
Mattila, H., Khorobrykh, S., Havurinne, V. & Tyystjarvi, E. Reactive oxygen species: Reactions and detection from photosynthetic tissues. Journal of Photochemistry and Photobiology B-Biology 152, 176–214, https://doi.org/10.1016/j.jphotobiol.2015.10.001 (2015).
Koh, E. & Fluhr, R. Singlet oxygen detection in biological systems: Uses and limitations. Plant Signaling & Behavior 11, 5, https://doi.org/10.1080/15592324.2016.1192742 (2016).
Hideg, E., Spetea, C. & Vass, I. Singlet Oxygen Production In Thylakoid Membranes During Photoinhibition As Detected by Epr Spectroscopy. Photosynthesis Research 39, 191–199, https://doi.org/10.1007/bf00029386 (1994).
Krieger, A., Rutherford, A. W., Vass, I. & Hideg, E. Relationship between activity, D1 loss, and Mn binding in photoinhibition of photosystem II. Biochemistry 37, 16262–16269, https://doi.org/10.1021/bi981243v (1998).
Yadav, D. K. & Pospíšil, P. Evidence on the Formation of Singlet Oxygen in the Donor Side Photoinhibition of Photosystem II: EPR Spin-Trapping Study. Plos One 7, https://doi.org/10.1371/journal.pone.0045883 (2012).
Hideg, E. A comparative study of fluorescent singlet oxygen probes in plant leaves. Central European Journal of Biology 3, 273–284, https://doi.org/10.2478/s11535-008-0018-5 (2008).
Hideg, E., Kalai, T., Kos, P. B., Asada, K. & Hideg, K. Singlet oxygen in plants- Its significance and possible detection with double (fluorescent and spin) indicator reagents. Photochemistry and Photobiology 82, 1211–1218, https://doi.org/10.1562/2006-02-06-ra-797 (2006).
Ragas, X., Jimenez-Banzo, A., Sanchez-Garcia, D., Batllori, X. & Nonell, S. Singlet oxygen photosensitisation by the fluorescent probe Singlet Oxygen Sensor Green (R). Chemical Communications, 2920–2922, https://doi.org/10.1039/b822776d (2009).
Gollmer, A. et al. Singlet Oxygen Sensor Green (R): Photochemical Behavior in Solution and in a Mammalian Cell. Photochemistry and Photobiology 87, 671–679, https://doi.org/10.1111/j.1751-1097.2011.00900.x (2011).
Kim, S., Fujitsuka, M. & Majima, T. Photochemistry of Singlet Oxygen Sensor Green. Journal of Physical Chemistry B 117, 13985–13992, https://doi.org/10.1021/jp406638g (2013).
Mor, A. et al. Singlet Oxygen Signatures Are Detected Independent of Light or Chloroplasts in Response to Multiple Stresses. Plant Physiology 165, 249–261, https://doi.org/10.1104/pp.114.236380 (2014).
Pedersen, S. K. et al. Aarhus Sensor Green: A Fluorescent Probe for Singlet Oxygen. Journal of Organic Chemistry 79, 3079–3087, https://doi.org/10.1021/jo500219y (2014).
Frausto, F. & Thomas, S. W. Ratiometric Singlet Oxygen Detection in Water Using Acene-Doped Conjugated Polymer Nanoparticles. Acs Applied Materials & Interfaces 9, 15768–15775, https://doi.org/10.1021/acsami.7b02034 (2017).
Erbas-Cakmak, S. & Akkaya, E. U. Toward Singlet Oxygen Delivery at a Measured Rate: A Self-Reporting Photosensitizer. Organic Letters 16, 2946–2949, https://doi.org/10.1021/ol501084n (2014).
Tang, C. Y. et al. A Classic Near-Infrared Probe Indocyanine Green for Detecting Singlet Oxygen. Int J Mol Sci 17, 219, https://doi.org/10.3390/ijms17020219 (2016).
Rippka, R., Deruelles, J., Waterbury, J. B., Herdman, M. & Stanier, R. Y. Generic Assignments, Strain Histories and Properties of Pure Cultures of Cyanobacteria. Journal of General Microbiology 111, 1–61, https://doi.org/10.1099/00221287-111-1-1 (1979).
Prasad, A. & Pospíšil, P. Linoleic Acid-Induced Ultra-Weak Photon Emission from Chlamydomonas reinhardtii as a Tool for Monitoring of Lipid Peroxidation in the Cell Membranes. Plos One 6, e22345, https://doi.org/10.1371/journal.pone.0022345 (2011).
Sedlářová, M. et al. Influence of nitric oxide and reactive oxygen species on development of lettuce downy mildew in Lactuca spp. European Journal of Plant Pathology 129, 267–280, https://doi.org/10.1007/s10658-010-9626-9 (2011).
Ogilby, P. R. Singlet oxygen: there is indeed something new under the sun. Chemical Society Reviews 39, 3181–3209, https://doi.org/10.1039/b926014p (2010).
Hideg, E. & Ayaydin, F. In Plant Image Analysis: Fundamentals and Applications 265–277 (Crc Press-Taylor & Francis Group, 2015).
Sedlářová, M. & Luhová, L. Re-Evaluation of Imaging Methods of Reactive Oxygen and Nitrogen Species in Plants and Fungi: Influence of Cell Wall Composition. Frontiers in Physiology 8, 7, https://doi.org/10.3389/fphys.2017.00826 (2017).
Probes, M. Product information, http://probes.invitrogen.com/media/pis/mp36002.pdf?id=;mp36002. (2014).
Shen, Y. et al. Indirect imaging of singlet oxygen generation from a single cell. Laser Physics Letters 8, 232–238, https://doi.org/10.1002/lapl.201010113 (2011).
Sinha, R. K., Komenda, J., Knoppova, J., Sedlářová, M. & Pospíšil, P. Small CAB-like proteins prevent formation of singlet oxygen in the damaged photosystem II complex of the cyanobacterium Synechocystis sp PCC 6803. Plant Cell and Environment 35, 806–818, https://doi.org/10.1111/j.1365-3040.2011.02454.x (2012).
Dall’Osto, L., Fiore, A., Cazzaniga, S., Giuliano, G. & Bassi, R. Different roles of alpha- and beta-branch xanthophylls in photosystem assembly and photoprotection. Journal of Biological Chemistry 282, 35056–35068, https://doi.org/10.1074/jbc.M704729200 (2007).
Alboresi, A. et al. Reactive oxygen species and transcript analysis upon excess light treatment in wild-type Arabidopsis thaliana vs a photosensitive mutant lacking zeaxanthin and lutein. Bmc Plant Biology 11, 22, https://doi.org/10.1186/1471-2229-11-62 (2011).
Ramel, F. et al. Chemical Quenching of Singlet Oxygen by Carotenoids in Plants. Plant Physiology 158, 1267–1278, https://doi.org/10.1104/pp.111.182394 (2012).
Ballottari, M., Mozzo, M., Girardon, J., Hienerwadel, R. & Bassi, R. Chlorophyll Triplet Quenching and Photoprotection in the Higher Plant Monomeric Antenna Protein Lhcb5. Journal of Physical Chemistry B 117, 11337–11348, https://doi.org/10.1021/jp402977y (2013).
Shumbe, L. et al. Singlet Oxygen-Induced Cell Death in Arabidopsis under High-Light Stress Is Controlled by OXI1 Kinase. Plant Physiology 170, 1757–1771, https://doi.org/10.1104/pp.15.01546 (2016).
Rehman, A. U., Cser, K., Sass, L. & Vass, I. Characterization of singlet oxygen production and its involvement in photodamage of Photosystem II in the cyanobacterium Synechocystis PCC 6803 by histidine-mediated chemical trapping. Biochimica Et Biophysica Acta-Bioenergetics 1827, 689–698, https://doi.org/10.1016/j.bbabio.2013.02.016 (2013).
Rehman, A. U. et al. Symbiodinium sp cells produce light-induced intra- and extracellular singlet oxygen, which mediates photodamage of the photosynthetic apparatus and has the potential to interact with the animal host in coral symbiosis. New Phytologist 212, 472–484, https://doi.org/10.1111/nph.14056 (2016).
Jurgens, U. J. & Weckesser, J. Polysaccharide Covalently Linked to the Peptidoglycan of the Cyanobacterium Synechocystic Sp Strain-Pcc6714. Journal of Bacteriology 168, 568–573 (1986).
Foster, J. S., Havemann, S. A., Singh, A. K. & Sherman, L. A. Role of mrgA in peroxide and light stress in the cyanobacterium Synechocystis sp PCC 6803. Fems Microbiology Letters 293, 298–304, https://doi.org/10.1111/j.1574-6968.2009.01548.x (2009).
We thank Prof. Josef Komenda for providing Synechocystis cells and Dr. Marek Rác for discussions regarding SOSG infiltration in Arabidopsis leaves. This work was financially supported by the Ministry of Education, Youth and Sports of the Czech Republic Grant No. LO1204 (National Program of Sustainability I) and Palacký University, Olomouc, Czech Republic Grant No. IGA_PrF_2018_001.
The authors declare no competing interests.
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Prasad, A., Sedlářová, M. & Pospíšil, P. Singlet oxygen imaging using fluorescent probe Singlet Oxygen Sensor Green in photosynthetic organisms. Sci Rep 8, 13685 (2018). https://doi.org/10.1038/s41598-018-31638-5
- Singlet Oxygen Sensor Green (SOSG)
- Photosynthetic Model Organism
- Pressure Infiltration
- Unequal Penetration
- Arabidopsis Leaves