A new paradigm for the action of reactive oxygen species in the photoinhibition of photosystem II

Inhibition of the activity of photosystem II (PSII) under strong light is referred to as photoinhibition. This phenomenon is due to the imbalance between the rate of photodamage to PSII and the rate of the repair of damaged PSII. Photodamage is initiated by the direct effects of light on the oxygen-evolving complex and, thus, photodamage to PSII is unavoidable. Studies of the effects of oxidative stress on photodamage and subsequent repair have revealed that reactive oxygen species (ROS) act primarily by inhibiting the repair of photodamaged PSII and not by damaging PSII directly. Thus, strong light has two distinct effects on PSII; it damages PSII directly and it inhibits the repair of PSII via production of ROS. Investigations of the ROS-induced inhibition of repair have demonstrated that ROS suppress the synthesis de novo of proteins and, in particular, of the D1 protein, that are required for the repair of PSII. Moreover, a primary target for inhibition by ROS appears to be the elongation step of translation. Inhibition of the repair of PSII by ROS is accelerated by the deceleration of the Calvin cycle that occurs when the availability of CO(2) is limited. In this review, we present a new paradigm for the action of ROS in photoinhibition.     

Formation of radicals from singlet oxygen produced during photoinhibition of isolated light-harvesting proteins of photosystem II

Electron spin resonance spectroscopy and liquid chromatography have been used to detect radical formation and fragmentation of polypeptides during photoinhibition of purified major antenna proteins, free of protease contaminants. In the absence of oxygen and light, no radicals were observed and there was no damage to the proteins. Similarly illumination of the apoproteins did not induce any polypeptide fragmentation, suggesting that chlorophyll, light and atmospheric oxygen are all participating in antenna degradation. The use of TEMP and DMPO as spin traps showed that protein damage initiates with generation of ¹O₂, presumably from a triplet chlorophyll, acting as a Type II photosensitizer which attacks directly the amino acids causing a complete degradation of protein into small fragments, without the contribution of proteases. Through the use of scavengers, it was shown that superoxide and H₂O₂ were not involved initially in the reaction mechanism. A higher production of radicals was observed in trimers than in monomeric antenna, while radical production is strongly reduced when antennae were organized in the photosystem II (PSII) complex. Thus, monomerization of antennae as well as their incorporation into the PSII complex seem to represent physiologically protected forms. A comparison is made of the photoinhibition mechanisms of different photosynthetic systems.     

Photoinhibition of photosystem II under environmental stress

Inhibition of the activity of photosystem II (PSII) under strong light is referred to as photoinhibition. This phenomenon is due to an imbalance between the rate of photodamage to PSII and the rate of the repair of damaged PSII. In the “classical” scheme for the mechanism of photoinhibition, strong light induces the production of reactive oxygen species (ROS), which directly inactivate the photochemical reaction center of PSII. By contrast, in a new scheme, we propose that photodamage is initiated by the direct effect of light on the oxygen-evolving complex and that ROS inhibit the repair of photodamaged PSII by suppressing primarily the synthesis of proteins de novo. The activity of PSII is restricted by a variety of environmental stresses. The effects of environmental stress on damage to and repair of PSII can be examined separately and it appears that environmental stresses, with the exception of strong light, act primarily by inhibiting the repair of PSII. Studies have demonstrated that repair-inhibitory stresses include CO₂ limitation, moderate heat, high concentrations of NaCl, and low temperature, each of which suppresses the synthesis of proteins de novo, which is required for the repair of PSII. We postulate that most types of environmental stress inhibit the fixation of CO₂ with the resultant generation of ROS, which, in turn, inhibit protein synthesis.     

Application of low temperatures during photoinhibition allows characterization of individual steps in photodamage and the repair of photosystem II

Recent investigations of photoinhibition have revealed that photodamage to photosystem II (PSII) involves two temporally separated steps: the first is the inactivation of the oxygen-evolving complex by light that has been absorbed by the manganese cluster and the second is the impairment of the photochemical reaction center by light that has been absorbed by chlorophyll. Our studies of photoinhibition in Synechocystis sp. PCC 6803 at various temperatures demonstrated that the first step in photodamage is not completed at low temperatures, such as 10°C. Further investigations suggested that an intermediate state, which is stabilized at low temperatures, might exist at the first stage of photodamage. The repair of PSII involves many steps, including degradation and removal of the D1 protein, synthesis de novo of the precursor to the D1 protein, assembly of the PSII complex, and processing of the precursor to the D1 protein. Detailed analysis of photodamage and repair at various temperatures has demonstrated that, among these steps, only the synthesis of the precursor to D1 appears to proceed at low temperatures. Investigations of photoinhibition at low temperatures have also indicated that prolonged exposure of cyanobacterial cells or plant leaves to strong light diminishes their ability to repair PSII. Such non-repairable photoinhibition is caused by inhibition of the processing of the precursor to the D1 protein after prolonged illumination with strong light at low temperatures.     

Photoinactivation of photosystem II during photoinhibition in the cyanobacterium Microcystis aeruginosa

Sites of photoinhibition and photo-oxidative damage to the photosynthetic electrontransport system of the unicellular cyanobacterium Microcystis aeruginosa were identified by studies of the kinetics of chlorophyll fluorescence induction by whole cells at room temperature and from partial photosynthetic electron-transport reactions in vitro in thylakoid preparations. Chlorophyll fluorescence intensity decreased following photoinhibitory light treatment. This was attributed to decreases both in the activity of photosystem II and in electron flow through the primary electron acceptor, Q. This inhibition was only partially reversed over a 50-min dark recovery period. Partial photosynthetic electron-transport experiments in vitro demonstrated that photosystem I was not affected by the photoinhibitory treatment. Light damage was associated exclusively with the light reactions, of photosystem II, at a site close to the reaction centre, between the site where diphenylcarbazide can donate electrons and the site where silicomolybdate can accept electrons. This damage presumably reduced production of ATP by noncyclic photophosphorylation and production of NADPH by photosystem I, decreasing the availability of these co-factors for reducing CO₂ in the dark reactions of photosynthesis. The importance of these findings is discussed.Abbreviations Chl chlorophyll - DCPIP 2,6-dichlorophenolindophenol - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - DPC diphenylcarbazide - PSI photosystem I - PSH photosystem II     

Studies on the mechanism of photosystem II photoinhibition II. The involvement of toxic oxygen species

In a previous paper it was shown that photoinhibition of reaction centre II of spinach thylakoids was predominantly caused by the degradation of D1-protein. An initial inactivation step at the Q_B-site was distinguished from its breakdown. The present paper deals with the question as to whether this loss of Q_B-function is caused by oxygen radical attack. For this purpose the photoinhibition of thylakoids was induced at 20°C in the presence of either superoxide dismutase and catalase or the antioxidants glutathione and ascorbic acid. This resulted in comparable though not total protection of D1-protein, photochemistry and fluorescence from photoinhibition. The combined action of both the enzymatic and the non-enzymatic radical scavenging systems brought about an even more pronounced protective effect against photoinhibition than did either of the two systems singularly at saturating concentrations. The results signify a major contribution of activated oxygen species to the degradation process of D1-protein and the related phenomena of photoinhibition. Thylakoids treated with hydroxyl radicals generated through a Fenton reaction showed a loss of atrazine binding sites, electron transport capacity and variable fluorescence in a similar manner, though not to the same extent, as usually observed following photoinhibitory treatment.Abbreviations Asc ascorbate - Fecy ferricyanide - GSH reduced glutathione - PQ plastoquinone - Q_A primary quinone acceptor of PS II - Q_B secondary quinone acceptor of PS II - SOD superoxide dismutase     

Phosphorylation and disassembly of the photosystem II core as an early stage of photoinhibition

The presence of heterogeneity in phosphorylated PSII core populations in grana membranes of spinach (Spinacia oleracea L.) was previously demonstrated (Giardi et al., 1991, Biochem. Biophys. Res. Commun. 176, 1298–1304). The effect of photoinhibitory conditions on the distribution of these phosphorylated PSII core populations in thylakoids and PSII particles has been investigated. The sensitivity of the PSII core to strong illumination depended on the phosphorylation state of D₁ and D₂ proteins as well as on the content of the 9-kDa PsbH phosphoprotein. When D₁ and D₂ proteins are under-phosphorylated, the 9-kDa phosphoprotein is tightly bound to the PSII core; thus, a partial protection from photoinhibition is observed. Of the different PSII core populations isolated from membranes photoinhibited for 10 min, the highly phosphorylated populations lack internal antennae CP43 and CP47; perhaps these migrate out to the non-appressed regions of thylakoids. The degradation of the D₁ protein seems to follow the disassembly of the PSII core.     

Singlet oxygen production in herbicide-treated photosystem II

Photo-generated reactive oxygen species in herbicide-treated photosystem II were investigated by spin-trapping. While the production of .OH and O2-* was herbicide-independent, 1O2 with a phenolic was twice that with a urea herbicide. This correlates with the reported influence of these herbicides on the redox properties of the semiquinone QA-* and fits with the hypothesis that 1O2 is produced by charge recombination reactions that are stimulated by herbicide binding and modulated by the nature of the herbicide. When phenolic herbicides are bound, charge recombination at the level of P+*Pheo-* is thermodynamically favoured forming a chlorophyll triplet and hence 1O2. With urea herbicides this pathway is less favourable.     

Ceramide-induced preconditioning involves reactive oxygen species

INTRODUCTION: Ceramide induces programmed cell death and it is thought to contribute to cardiac ischemia/reperfusion (I/R) injury. In contrast, we have demonstrated that administration of low doses of ceramide engenders cardiac preconditioning (PC). Ceramide is known to generate reactive oxygen species (ROS) in cells. Since mechanisms triggering the ceramide-induced cardioprotection remain unknown, we investigated the role of ROS in the genesis of this protective mechanism. METHODS: Using an isolated Langendorff-perfused rat heart model, four groups (n > or = 6 in each group) were considered: Control hearts underwent 30 min index regional ischemia and 120 min of reperfusion. In the ceramide group, hearts were preconditioned with c2-ceramide 1 microM for 7 min followed by 10 min washout prior to the I/R insult. In additional groups, MPG (1 mM), a synthetic antioxidant was given for 15 min alone or bracketing the ceramide perfusion. In each group, infarct size was determined at the end of the reperfusion period and superoxide dismutases (CuZnSOD and MnSOD) and catalase activities were evaluated. RESULTS: Ceramide preconditioning reduced the infarct/area at risk (I/AAR) ratio (8.3 +/- 1.1% for ceramide vs. 36.4 +/- 1.2% for control, p < 0.001). Perfusion with MPG abolished the preconditioning effect of ceramide (I/AAR ratio = 36.7 +/- 4.9%). Ceramide was also associated with a 29% and 38% increase in catalase and CuZnSOD activities, respectively, compared with control group. CONCLUSION: Production of reactive oxygen species following ceramide preconditioning of the ischemic-reperfused heart appears to play a role in the cardioprotective effect of ceramide.     

Strong-light photoinhibition treatment accelerates the changes of protein secondary structures in triton-treated photosystem I and photosystem II complexes

Changes in the protein secondary structure and electron transport activity of the Triton X-100-treated photosystem I (PSI) and photosystem II (PSII) complexes after strong illumination treatment were studied using Fourier transform-infrared (FT-IR) spectroscopy and an oxygen electrode. Short periods of photoinhibitory treatment led to obvious decreases in the rates of PSI-mediated electron transport activity and PSII-mediated oxygen evolution in the native or Triton-treated PSI and PSII complexes. In the native PSI and PSII complexes, the protein secondary structures had little changes after the photoinhibitory treatment. However, in both Triton-treated PSI and PSII complexes, short photoinhibition times caused significant loss of -helical content and increase of -sheet structure, similar to the conformational changes in samples of Triton-treated PSI and PSII complexes after long periods of dark incubation. Our results demonstrate that strong-light treatment to the Triton-treated PSI and PSII complexes accelerates destruction of the transmembrane structure of proteins in the two photosynthetic membranes.     

Damage to the oxygen-evolving complex by superoxide anion, hydrogen peroxide, and hydroxyl radical in photoinhibition of photosystem II

Under strong illumination of a photosystem II (PSII) membrane, endogenous superoxide anion, hydrogen peroxide, and hydroxyl radical were successively produced. These compounds then cooperatively resulted in a release of manganese from the oxygen-evolving complex (OEC) and an inhibition of oxygen evolution activity. The OEC inactivation was initiated by an acceptor-side generated superoxide anion, and hydrogen peroxide was most probably responsible for the transportation of reactive oxygen species (ROS) across the PSII membrane from the acceptor-side to the donor-side. Besides ROS being generated in the acceptor-side induced manganese loss; there may also be a ROS-independent manganese loss in the OEC of PSII. Both superoxide anion and hydroxyl radical located inside the PSII membrane were directly identified by a spin trapping-electron spin resonance (ESR) method in combination with a lipophilic spin trap, 5-(diethoxyphosphoryl)-5-phenethyl-1-pyrroline N-oxide (DEPPEPO). The endogenous hydrogen peroxide production was examined by oxidation of thiobenzamide.     

Protein synthesis is the primary target of reactive oxygen species in the photoinhibition of photosystem II

Photoinhibition of photosystem II (PSII) occurs when the rate of photodamage to PSII exceeds the rate of the repair of photodamaged PSII. Recent examination of photoinhibition by separate determinations of photodamage and repair has revealed that the rate of photodamage to PSII is directly proportional to the intensity of incident light and that the repair of PSII is particularly sensitive to the inactivation by reactive oxygen species (ROS). The ROS-induced inactivation of repair is attributable to the suppression of the synthesis de novo of proteins, such as the D1 protein, that are required for the repair of PSII at the level of translational elongation. Furthermore, molecular analysis has revealed that the ROS-induced suppression of protein synthesis is associated with the specific inactivation of elongation factor G via the formation of an intramolecular disulfide bond. Impairment of various mechanisms that protect PSII against photoinhibition, including photorespiration, thermal dissipation of excitation energy, and the cyclic transport of electrons, decreases the rate of repair of PSII via the suppression of protein synthesis. In this review, we present a newly established model of the mechanism and the physiological significance of repair in the regulation of the photoinhibition of PSII.     

Down-regulation of transglutaminase II leads to impaired motility of cancer cells by inactivation of the protein kinase, Akt, and decrease of reactive oxygen species

We employed RNA interference to determine the role of tissue transglutaminase II (TGase II) in motility of cancer cells. Down-regulation of TGase II by small interfering RNA against TGase II impaired adhesion and motility of HeLa cells by decreasing phosphorylation of the protein kinase, Akt, and reactive oxygen species (ROS). Over-expression of TGase II showed opposite effects. These results suggest potential utility of TGase II for development of therapeutic anti cancer vaccine.     

Involvement of Ca in globular adiponectin-induced reactive oxygen species

Globular adiponectin (gAd) induces the generation of reactive oxygen species (ROS) and nitric oxide (NO) in the murine macrophage cell line RAW 264. We investigated the role of Ca²⁺ in gAd-induced ROS and NO generation. Pretreatment with BAPTA-AM, a selective chelator of intracellular Ca²⁺ ([Ca²⁺]_i), partially reduced gAd-induced generation of ROS and NO in gAd-treated RAW 264 cells. The lowest [Ca²⁺]_i occurred 30 min after gAd treatment, after which [Ca²⁺]_i increased continually and exceeded the initial level. The mitochondrial Ca²⁺ ([Ca²⁺]_m) detected by Rhod-2 fluorescence started to increase at 6 h after gAd treatment. Pretreatment with a NAD(P)H oxidase inhibitor, diphenyleneiodonium, prevented the reduction of [Ca²⁺]_i in the early phase after gAd treatment. Calcium depletion by BAPTA-AM had no effect on the gAd-induced [Ca²⁺]_m oscillation. The administration of a specific calmodulin inhibitor, calmidazolium, significantly suppressed gAd-induced ROS and NO generation and NOS activity.     

D1 protein degradation during photoinhibition of intact leaves a modification of the D1 protein precedes degradation

Illumination of intact pumpkin leaves with high light led to severe photoinhibition of photosystem II with no net degradation of the D1 protein. Instead, however, a modified form of D1 protein with slightly slower electrophoretic mobility was induced with corresponding loss in the original form of the D1 protein. When the leaves were illuminated in the presence of chloramphenicol the modified form was degraded, which led to a decrease in the total amount of the D1 protein. Subfractionation of the thylakoid membranes further supported the conclusion that the novel form of the D1 protein was not a precursor but a high-light modified form that was subsequently degraded.     

活性氧在昆虫体内的功能研究进展

活性氧（Reactive oxygen species,ROS）是一类由氧气不完全还原产生的高活性分子或离子的总称,包括过氧化氢（H2O2）、超氧阴离子（O2-）、羟基自由基（OH·）和一氧化氮（NO）等,它们参与昆虫体内许多重要的信号转导过程。在昆虫受伤或遭受逆境胁迫时,体内ROS水平会迅速升高,影响昆虫正常的生长发育,甚至导致细胞凋亡;但是适当浓度的ROS有利于维持昆虫体内微生物稳态,在细胞存活、生长、增殖、分化及免疫反应等多种生物功能中起着重要作用。本文围绕ROS在昆虫体内的产生原因、功能、测定方法以及宿主对ROS的调控和清除机制等研究进行了全面深入的综述。     

Ethylene-induced overproduction of reactive oxygen species is responsible for the development of watersoaking in immature cucumber fruit

Watersoaking is an ethylene-induced disorder observed in some members of the Cucurbitaceae including cucumber (Cucumis sativus L.), watermelon (Citrullus lanatus Thunb. Matsum and Nakai), and tropical pumpkin (Cucurbita moschata Duch.). Previous studies have found that immature beit-alpha cucumber (cv. Manar) exhibit watersoaking after 6 d of continuous exposure to 10 μL L⁻¹ ethylene in air (21 kPa O₂). The present study was designed to investigate the early dynamics of ethylene responses in immature cucumber fruit in order to provide insight into the watersoaking triggering mechanism. Changes in respiration, epidermal color, firmness, reactive oxygen species (ROS) production and electrolyte leakage were evaluated as a function of time under different ethylene concentrations and exposure duration. Ethylene concentrations exceeding 10 μL L⁻¹ did not accelerate changes in any of the evaluated responses. The first detectable change was a significant rise in respiration on day 2, followed by a significant rise in ROS on day 4, and significant degreening, mesocap softening, and increased electrolyte leakage on day 6; the latter responses coincident with incipient watersoaking. Varying the duration of exposure to ethylene indicated that the critical exposure time is between 2 and 4 d. Notably, all deleterious responses to ethylene were suppressed under a hypoxic atmosphere. A model is proposed in which ethylene induces a sharp increase in respiration with a concomitant sharp rise in ROS, which the immature fruit is incapable of quenching. The resulting production of excess ROS leads to discoloration and membrane deterioration, leading to the release of cytoplasmic content, rapid softening, and the visual symptom of watersoaking.     

Peroxisomes and reactive oxygen species,a lasting challenge

Oxidases generating and enzymes scavenging H₂O₂ predestine peroxisomes (PO) to a pivotal organelle in oxygen metabolism. Catalase, the classical marker enzyme of PO, exhibits both catalatic and peroxidatic activity. The latter is responsible for the staining with 3,3′-diamino-benzidine, which greatly facilitated the visualization of the organelle and promoted further studies on PO. d-Amino acid oxidase catalyzes with strict stereospecificity the oxidative deamination of d-amino acids. The oxidase is significantly more active in the kidney than in liver and more in periportal than pericentral rat hepatocytes. Peroxisomes in these tissues differ in their enzyme activity and protein concentration not only in adjacent cells but even within the same one. Moreover, the enzyme appears preferentially concentrated in the central region of the peroxisomal matrix compartment. Urate oxidase, a cuproprotein catalyzing the oxidation of urate to allantoin, is confined to the peroxisomal core, yet is lacking in human PO. Recent experiments revealed that cores in rat hepatocytes appear in close association with the peroxisomal membrane releasing H₂O₂ generated by urate oxidase to the surrounding cytoplasma. Xanthine oxidase is exclusively located to cores, oxidizes xanthine thereby generating H₂O₂ and O₂ ^– radicals. The latter are converted to O₂ and H₂O₂ by CuZn superoxide dismutase, which has been shown recently to be a bona fide peroxisomal protein. Presented at the 50th Anniversary Symposium of the Society for Histochemistry, Interlaken, Switzerland, October 1-4, 2008.