Your search keyword '"Plastid terminal oxidase"' showing total 9 results

1. Functional and molecular characterization of plastid terminal oxidase from rice (Oryza sativa)

Author

Anja Krieger-Liszkay, Kathleen Feilke, Peter Beyer, and Qiuju Yu

Subjects

PTOX, Chloroplasts, Light, Plastoquinone, Biophysics, Redox, Plastid terminal oxidase, Thylakoids, Biochemistry, Electron Transport, chemistry.chemical_compound, Oxidoreductase, Plastids, Photosynthesis, chemistry.chemical_classification, Chemistry, Arabidopsis Proteins, Substrate (chemistry), Oryza, Chlororespiration, Cell Biology, Electron transport chain, Kinetics, Carotene desaturation, Steady state (chemistry), Oxidoreductases, Reactive oxygen species

Abstract

The plastid terminal oxidase (PTOX) is a plastohydroquinone:oxygen oxidoreductase that shares structural similarities with alternative oxidases (AOX). Multiple roles have been attributed to PTOX, such as involvement in carotene desaturation, a safety valve function, participation in the processes of chlororespiration and setting the redox poise for cyclic electron transport. We have investigated a homogenously pure MBP fusion of PTOX. The protein forms a homo-tetrameric complex containing 2 Fe per monomer and is very specific for the plastoquinone head-group. The reaction kinetics were investigated in a soluble monophasic system using chemically reduced decyl-plastoquinone (DPQ) as the model substrate and, in addition, in a biphasic (liposomal) system in which DPQ was reduced with DT-diaphorase. While PTOX did not detectably produce reactive oxygen species in the monophasic system, their formation was observed by room temperature EPR in the biphasic system in a [DPQH 2 ] and pH-dependent manner. This is probably the result of the higher concentration of DPQ achieved within the partial volume of the lipid bilayer and a higher Km observed with PTOX-membrane associates which is ≈ 47 mM compared to the monophasic system where a Km of ≈ 74 μM was determined. With liposomes and at the basic stromal pH of photosynthetically active chloroplasts, PTOX was antioxidant at low [DPQH 2 ] gaining prooxidant properties with increasing quinol concentrations. It is concluded that in vivo, PTOX can act as a safety valve when the steady state [PQH 2 ] is low while a certain amount of ROS is formed at high light intensities.

Published

2014

2. In vitro analysis of the plastid terminal oxidase in photosynthetic electron transport

Author

Peter Beyer, Qiuju Yu, Anja Krieger-Liszkay, Kathleen Feilke, and Pierre Sétif

Subjects

Chlorophyll, Photosystem II, Biophysics, Plastoquinone, Biology, In Vitro Techniques, Photochemistry, Photosynthesis, Plastid terminal oxidase, Biochemistry, Fluorescence, Electron Transport, chemistry.chemical_compound, Photosynthetic electron transport, Plastids, Chlorophyll fluorescence, Photosystem, Cell Biology, Electron transport chain, chemistry, Thylakoid, Reactive oxygen species, Oxidoreductases

Abstract

The plastid terminal oxidase PTOX catalyzes the oxidation of plastoquinol (PQH2) coupled with the reduction of oxygen to water. In vivo PTOX is attached to the thylakoid membrane. PTOX is important for plastid development and carotenoid biosynthesis, and its role in photosynthesis is controversially discussed. To analyze PTOX activity in photosynthetic electron transport recombinant purified PTOX fused to the maltose-binding protein was added to photosystem II-enriched membrane fragments. These membrane fragments contain the plastoquinone (PQ) pool as verified by thermoluminescence. Experimental evidence for PTOX oxidizing PQH2 is demonstrated by following chlorophyll fluorescence induction. Addition of PTOX to photosystem II-enriched membrane fragments led to a slower rise, a lower level of the maximal fluorescence and an acceleration of the fluorescence decay. This effect was only observed at low light intensities indicating that PTOX cannot compete efficiently with the reduction of the PQ pool by photosystem II at higher light intensities. PTOX attached tightly to the membranes since it was only partly removable by membrane washings. Divalent cations enhanced the effect of PTOX on chlorophyll fluorescence compared to NaCl most likely because they increase connectivity between photosystem II centers and the size of the PQ pool. Using single turnover flashes, it was shown that the level of reactive oxygen species, generated by PTOX in a side reaction, increased when the spacing between subsequent double flashes was enlarged. This shows that PTOX generates reactive oxygen species under limited substrate availability.

Published

2014

3. Mitochondrial alternative oxidase (AOX1a) is required for the mitigation of arsenic-induced oxidative stress in Arabidopsis thaliana

Author

Gokhan Cucun, Nil Demircan, Baris Uzilday, and Ege Üniversitesi

Subjects

0106 biological sciences, 0301 basic medicine, Alternative oxidase, Redox signalling, Arabidopsis thaliana, Mutant, Plant Science, medicine.disease_cause, 01 natural sciences, Plastid terminal oxidase, 03 medical and health sciences, medicine, chemistry.chemical_classification, Reactive oxygen species, biology, fungi, Wild type, food and beverages, Arsenic stress, biology.organism_classification, Heavy metal, 030104 developmental biology, Biochemistry, chemistry, biology.protein, Oxidative stress, Alternative electron sinks, 010606 plant biology & botany, Biotechnology, Peroxidase

Abstract

The element arsenic (As) is a non-essential metalloid that is found naturally in all soils and at high concentrations it is toxic to plant cells. As (V) can act as a chemical analogue of phosphate, it can disrupt phosphate-related energy metabolism and lipid structure. in this study, the contribution of mitochondrial alternative oxidase (AOX) and chloroplastic plastid terminal oxidase (PTOX) to As (V) stress tolerance was investigated. Our data indicate that As (V) stress (100, 200 and 300 mu M) induces AOX gene expression by 3.3- to 10.5-fold depending on AOX gene, but not PTOX expression in wild-type A. thaliana plants. To further elucidate the role of AOX in As (V) stress tolerance, we utilized aox1a mutants and observed that aox1a mutants had decreased growth and higher oxidative stress damage under stress conditions, while there were no differences under control conditions. Moreover, acclimation of aox1a plants to new cellular redox environment was investigated by measuring the activities of reactive oxygen species (ROS)-scavenging enzymes. Induction of mitochondrial MnSOD activity at 300 mu M As (V) was higher in aox1a plants (70%), when compared to wild type (43%). However, total ascorbate peroxidase and dehydroascorbate reductase activities were lower in aox1a plants when compared to wild type, which might explain higher oxidative damage observed in this genotype. on the other hand, NADPH oxidase activity, which is involved in ROS signaling, was lower in aox1a plants under normal conditions but a higher induction was observed with As (V) stress. Overall, our data indicate that AOX1a is involved in adaptation to As (V)-induced oxidative stress., Korean Acad Sci & Technol, Assoc Acad & Sco Sci Asia

Published

2020

4. Computational Analysis of Alternative Photosynthetic Electron Flows Linked With Oxidative Stress

Author

Nima P. Saadat, Tim Nies, Marvin van Aalst, Brandon Hank, Büsra Demirtas, Oliver Ebenhöh, and Anna Matuszyńska

Subjects

reactive oxygen species, photosynthesis, Chemistry, Plant culture, Context (language use), Plant Science, Photosystem I, Photosynthesis, Plastid terminal oxidase, SB1-1110, cyclic electron flow, Light intensity, Photosynthetic acclimation, Biophysics, Flux (metabolism), mathematical model, Photosystem, Original Research, electron transport (photosynthetic)

Abstract

During photosynthesis, organisms respond to their energy demand and ensure the supply of energy and redox equivalents that sustain metabolism. Hence, the photosynthetic apparatus can, and in fact should, be treated as an integrated supply-demand system. Any imbalance in the energy produced and consumed can lead to adverse reactions, such as the production of reactive oxygen species (ROS). Reaction centres of both photosystems are known sites of ROS production. Here, we investigate in particular the central role of Photosystem I (PSI) in this tightly regulated system. Using a computational approach we have expanded a previously published mechanistic model of C3 photosynthesis by including ROS producing and scavenging reactions around PSI. These include two water to water reactions mediated by Plastid terminal oxidase (PTOX) and Mehler and the ascorbate-glutathione (ASC-GSH) cycle, as a main non-enzymatic antioxidant. We have used this model to predict flux distributions through alternative electron pathways under various environmental stress conditions by systematically varying light intensity and enzymatic activity of key reactions. In particular, we studied the link between ROS formation and activation of pathways around PSI as potential scavenging mechanisms. This work shines light on the role of alternative electron pathways in photosynthetic acclimation and investigates the effect of environmental perturbations on PSI activity in the context of metabolic productivity.

Published

2021

5. Effect of constitutive expression of bacterial phytoene desaturase CRTI on photosynthetic electron transport in Arabidopsis thaliana

Author

Peter Beyer, Anja Krieger-Liszkay, Kathleen Feilke, Denise Galzerano, and Patrick Schaub

Subjects

Chlorophyll, Phytoene desaturase, plastid terminal oxidase, Photoinhibition, Plastoquinone, Immunoblotting, Arabidopsis, Biophysics, Biology, Thylakoids, Biochemistry, Plastid terminal oxidase, Gene Expression Regulation, Enzymologic, Electron Transport, chemistry.chemical_compound, Bacterial Proteins, Superoxides, Gallic Acid, Photosynthesis, bacterial phytoene desaturase, reactive oxygen species, chemistry.chemical_classification, Reactive oxygen species, Singlet Oxygen, photoinhibition, Arabidopsis Proteins, DCMU, Hydrogen Peroxide, Cell Biology, Plants, Genetically Modified, Carotenoids, Electron transport chain, Plant Leaves, chemistry, A. thaliana, Thylakoid, Oxidoreductases, Oxidation-Reduction, photosynthetic electron transport

Abstract

The constitutive expression of the bacterial carotene desaturase (CRTI) in Arabidopsis thaliana leads to increased susceptibility of leaves to light-induced damage. Changes in the photosynthetic electron transport chain rather than alterations of the carotenoid composition in the antenna were responsible for the increased photoinhibition. A much higher level of superoxide/hydrogen peroxide was generated in the light in thylakoid membranes from the CRTI expressing lines than in wild-type while the level of singlet oxygen generation remained unchanged. The increase in reactive oxygen species was related to the activity of plastid terminal oxidase (PTOX) since their generation was inhibited by the PTOX-inhibitor octyl gallate, and since the protein level of PTOX was increased in the CRTI-expressing lines. Furthermore, cyclic electron flow was suppressed in these lines. We propose that PTOX competes efficiently with cyclic electron flow for plastoquinol in the CRTI-expressing lines and that it plays a crucial role in the control of the reduction state of the plastoquinone pool.

Published

2014

6. Redox and Reactive Oxygen Species Network in Acclimation for Salinity Tolerance in Sugar Beet

Author

Marten Moore, Karl-Josef Dietz, Abdelaleim Ismail ElSayed, and M Sazzad Hossain

Subjects

0106 biological sciences, 0301 basic medicine, Alternative oxidase, Antioxidant, Physiology, medicine.medical_treatment, Acclimatization, Plant Science, Biology, 01 natural sciences, Plastid terminal oxidase, Superoxide dismutase, 03 medical and health sciences, Gene Expression Regulation, Plant, medicine, Homeostasis, Phylogeny, salinity stress, chemistry.chemical_classification, Reactive oxygen species, NADPH oxidase, antioxidant defense, fungi, food and beverages, peroxiredoxin, Salt Tolerance, Sequence Analysis, DNA, RBOH, sugar beet, biology.organism_classification, superoxide dismutase, Salinity, 030104 developmental biology, chemistry, Biochemistry, biology.protein, Sugar beet, Beta vulgaris, Reactive Oxygen Species, Oxidation-Reduction, 010606 plant biology & botany, Research Paper

Abstract

Highlight Sugar beet acclimation to high salinity stress involves the down-regulation of reactive oxygen species generator systems and the up-regulation of antioxidant enzymes., Fine-tuned and coordinated regulation of transport, metabolism and redox homeostasis allows plants to acclimate to osmotic and ionic stress caused by high salinity. Sugar beet is a highly salt tolerant crop plant and is therefore an interesting model to study sodium chloride (NaCl) acclimation in crops. Sugar beet plants were subjected to a final level of 300 mM NaCl for up to 14 d in hydroponics. Plants acclimated to NaCl stress by maintaining its growth rate and adjusting its cellular redox and reactive oxygen species (ROS) network. In order to understand the unusual suppression of ROS accumulation under severe salinity, the regulation of elements of the redox and ROS network was investigated at the transcript level. First, the gene families of superoxide dismutase (SOD), peroxiredoxins (Prx), alternative oxidase (AOX), plastid terminal oxidase (PTOX) and NADPH oxidase (RBOH) were identified in the sugar beet genome. Salinity induced the accumulation of Cu-Zn-SOD, Mn-SOD, Fe-SOD3, all AOX isoforms, 2-Cys-PrxB, PrxQ, and PrxIIF. In contrast, Fe-SOD1, 1-Cys-Prx, PrxIIB and PrxIIE levels decreased in response to salinity. Most importantly, RBOH transcripts of all isoforms decreased. This pattern offers a straightforward explanation for the low ROS levels under salinity. Promoters of stress responsive antioxidant genes were analyzed in silico for the enrichment of cis-elements, in order to gain insights into gene regulation. The results indicate that special cis-elements in the promoters of the antioxidant genes in sugar beet participate in adjusting the redox and ROS network and are fundamental to high salinity tolerance of sugar beet

Published

2017

7. Changes in the alternative electron sinks and antioxidant defence in chloroplasts of the extreme halophyte Eutrema parvulum (Thellungiella parvula) under salinity

Author

Baris Uzilday, Ismail Turkan, A. Hediye Sekmen, Rengin Ozgur, Evren Yildiztugay, Selçuk Üniversitesi, and Ege Üniversitesi

Subjects

Salinity, plastid terminal oxidase, Chloroplasts, Osmotic shock, Molecular Sequence Data, Plant Science, Biology, Sodium Chloride, Photosynthesis, water-water cycle, Plastid terminal oxidase, Antioxidants, Electron Transport, antioxidant enzymes, Halophyte, Botany, oxidative stress, proline, Ferredoxin, Eutrema parvulum, Plant Proteins, peroxiredoxin, Salt-Tolerant Plants, thioredoxin, Sequence Analysis, DNA, Articles, Alternative electron sink, Plant Leaves, Ion homeostasis, Biochemistry, halophyte, Brassicaceae, Thellungiella parvula, Thioredoxin, Peroxiredoxin, Reactive Oxygen Species, chloroplastic redox, Plant Shoots

Abstract

WOS: 000349560400011, PubMed ID: 25231894, Background and Aims Eutrema parvulum (synonym, Thellungiella parvula) is an extreme halophyte that thrives in high salt concentrations (100-150 mM) and is closely related to Arabidopsis thaliana. The main aim of this study was to determine how E. parvulum uses reactive oxygen species (ROS) production, antioxidant systems and redox regulation of the electron transport system in chloroplasts to tolerate salinity. Methods Plants of E. parvulum were grown for 30 d and then treated with either 50, 200 or 300 mM NaCl. Physiological parameters including growth and water relationships were measured. Activities of antioxidant enzymes were determined in whole leaves and chloroplasts. In addition, expressions of chloroplastic redox components such as ferrodoxin thioredoxin reductases (FTR), NADPH thioredoxin reductases (NTRC), thioredoxins (TRXs) and peroxiredoxins (PRXs), as well as genes encoding enzymes of the water-water cycle and proline biosynthesis were measured. Key Results Salt treatment affected water relationships negatively and the accumulation of proline was increased by salinity. E. parvulum was able to tolerate 300 mM NaCl over long periods, as evidenced by H2O2 content and lipid peroxidation. While Ca2+ and K+ concentrations were decreased by salinity, Na+ and Cl-concentrations increased. Efficient induction of activities and expressions of water-water cycle enzymes might prevent accumulation of excess ROS in chloroplasts and therefore protect the photosynthetic machinery in E. parvulum. The redox homeostasis in chloroplasts might be achieved by efficient induction of expressions of redox regulatory enzymes such as FTR, NTRC, TRXs and PRXs under salinity. Conclusions E. parvulum was able to adapt to osmotic stress by an efficient osmotic adjustment mechanism involving proline and was able to regulate its ion homeostasis. In addition, efficient induction of water-water cycle enzymes and other redox regulatory components such as TRXs and PRXs in chloroplasts were able to protect the chloroplasts from salinity-induced oxidative stress.

Published

2014

8. Double antisense plants lacking ascorbate peroxidase and catalase are less sensitive to oxidative stress than single antisense plants lacking ascorbate peroxidase or catalase

Author

Jason E. Barr, Ludmila Rizhsky, Ron Mittler, Steven R. Rodermel, Shimon Rachmilevitch, Dirk Inzé, Elza Hallak-Herr, and Frank Van Breusegem

Subjects

Alternative oxidase, Chloroplasts, Plant Science, Pentose phosphate pathway, Plastid terminal oxidase, Gene Expression Regulation, Enzymologic, Ascorbate Peroxidases, L-ascorbate peroxidase, Gene Expression Regulation, Plant, Pseudomonas, Tobacco, Genetics, Photosynthesis, biology, Gene Expression Profiling, food and beverages, Cell Biology, APX, Catalase, Oxidative Stress, Antisense Elements (Genetics), Biochemistry, Peroxidases, biology.protein, Reactive Oxygen Species, Peroxidase

Abstract

The plant genome is a highly redundant and dynamic genome. Here, we show that double antisense plants lacking the two major hydrogen peroxide-detoxifying enzymes, ascorbate peroxidase (APX) and catalase (CAT), activate an alternative/redundant defense mechanism that compensates for the lack of APX and CAT. A similar mechanism was not activated in single antisense plants that lacked APX or CAT, paradoxically rendering these plants more sensitive to oxidative stress compared to double antisense plants. The reduced susceptibility of double antisense plants to oxidative stress correlated with suppressed photosynthetic activity, the induction of metabolic genes belonging to the pentose phosphate pathway, the induction of monodehydroascorbate reductase, and the induction of IMMUTANS, a chloroplastic homologue of mitochondrial alternative oxidase. Our results suggest that a co-ordinated induction of metabolic and defense genes, coupled with the suppression of photosynthetic activity, can compensate for the lack of APX and CAT. In addition, our findings demonstrate that the plant genome has a high degree of plasticity and will respond differently to different stressful conditions, namely, lack of APX, lack of CAT, or lack of both APX and CAT.

Published

2002

9. [Untitled]

Subjects

0106 biological sciences, 0301 basic medicine, chemistry.chemical_classification, Alternative oxidase, Reactive oxygen species, Plant Science, Biology, medicine.disease_cause, 01 natural sciences, Redox, Plastid terminal oxidase, Malate dehydrogenase, Salinity, 03 medical and health sciences, 030104 developmental biology, Ion homeostasis, Biochemistry, chemistry, medicine, Biophysics, Oxidative stress, 010606 plant biology & botany

Abstract

Soil salinity is a crucial environmental constraint which limits biomass production at many sites on a global scale. Saline growth conditions cause osmotic and ionic imbalances, oxidative stress and perturb metabolism, e.g., the photosynthetic electron flow. The plant ability to tolerate salinity is determined by multiple biochemical and physiological mechanisms protecting cell functions, in particular by regulating proper water relations and maintaining ion homeostasis. Redox homeostasis is a fundamental cell property. Its regulation includes control of reactive oxygen species (ROS) generation, sensing deviation from and readjustment of the cellular redox state. All these redox related functions have been recognized as decisive factors in salinity acclimation and adaptation. This review focuses on the core response of plants to overcome the challenges of salinity stress through regulation of ROS generation and detoxification systems and to maintain redox homeostasis. Emphasis is given to the role of NADH oxidase (RBOH), alternative oxidase (AOX), the plastid terminal oxidase (PTOX) and the malate valve with the malate dehydrogenase isoforms under salt stress. Overwhelming evidence assigns an essential auxiliary function of ROS and redox homeostasis to salinity acclimation of plants.