Detection of hydrogen peroxide in Photosystem II (PSII) using catalytic amperometric biosensor

Prasad, Ankush; Kumar, Aditya; Suzuki, Makoto; Kikuchi, Hiroyuki; Sugai, Tomoya; Kobayashi, Masaki; Pospı́šil, Pavel; Tada, Mika; Kasai, Shuya

doi:10.3389/fpls.2015.00862

Cited by 20 publications

(19 citation statements)

References 74 publications

(105 reference statements)

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“…In the spontaneous dismutation, the interaction of two O 2 •– is restricted due to repulsion of the negative charge on the molecule, whereas the interaction of the protonated form of superoxide, hydroperoxyl radical (HO 2 • ), either with O 2 •– or HO 2 • is feasible. Spontaneous dismutation has been recently monitored by real-time detection of H 2 O 2 in PSII membrane under high light using highly sensitive and selective osmium-horseradish modified electrode (Prasad et al, 2015). In the enzymatic dismutation, reduction and oxidation of O 2 •– is associated with the redox change of the redox active metal center which serves as a superoxide oxidase (SOO) and superoxide reductase (SOR), respectively.…”

Section: High Lightmentioning

confidence: 99%

Production of Reactive Oxygen Species by Photosystem II as a Response to Light and Temperature Stress

2016

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The effect of various abiotic stresses on photosynthetic apparatus is inevitably associated with formation of harmful reactive oxygen species (ROS). In this review, recent progress on ROS production by photosystem II (PSII) as a response to high light and high temperature is overviewed. Under high light, ROS production is unavoidably associated with energy transfer and electron transport in PSII. Singlet oxygen is produced by the energy transfer form triplet chlorophyll to molecular oxygen formed by the intersystem crossing from singlet chlorophyll in the PSII antennae complex or the recombination of the charge separated radical pair in the PSII reaction center. Apart to triplet chlorophyll, triplet carbonyl formed by lipid peroxidation transfers energy to molecular oxygen forming singlet oxygen. On the PSII electron acceptor side, electron leakage to molecular oxygen forms superoxide anion radical which dismutes to hydrogen peroxide which is reduced by the non-heme iron to hydroxyl radical. On the PSII electron donor side, incomplete water oxidation forms hydrogen peroxide which is reduced by manganese to hydroxyl radical. Under high temperature, dark production of singlet oxygen results from lipid peroxidation initiated by lipoxygenase, whereas incomplete water oxidation forms hydrogen peroxide which is reduced by manganese to hydroxyl radical. The understanding of molecular basis for ROS production by PSII provides new insight into how plants survive under adverse environmental conditions.

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Section: High Lightmentioning

confidence: 99%

Production of Reactive Oxygen Species by Photosystem II as a Response to Light and Temperature Stress

2016

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“…In photosynthetic organism, generation of reactive oxygen species (ROS) is a quite universal and fast defense mechanism, known to be associated with various stresses both in vivo and in vitro (Yadav and Pospíšil, 2012;Prasad et al, 2015;Prasad et al, 2016;Prasad et al, 2017a;Prasad et al, 2018;Kumar et al, 2019), in both local as well as systemic responses (Grant and Loake, 2000;Slesak et al, 2007). In tomato, it has been observed that hydrogen peroxide (H 2 O 2 ) was produced at the site within an hour of wounding and its level was enhanced even in distant part (upper unwounded leaves) in the following 4 to 6 h (Orozco-Cardenas and Ryan, 1999).…”

Section: Introductionmentioning

confidence: 99%

Reactive Oxygen Species as a Response to Wounding: In Vivo Imaging in Arabidopsis thaliana

et al. 2020

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Mechanical injury or wounding in plants can be attributed to abiotic or/and biotic causes. Subsequent defense responses are either local, i.e. within or in the close vicinity of affected tissue, or systemic, i.e. at distant plant organs. Stress stimuli activate a plethora of early and late reactions, from electric signals induced within seconds upon injury, oxidative burst within minutes, and slightly slower changes in hormone levels or expression of defense-related genes, to later cell wall reinforcement by polysaccharides deposition, or accumulation of proteinase inhibitors and hydrolytic enzymes. In the current study, we focused on the production of reactive oxygen species (ROS) in wounded Arabidopsis leaves. Based on fluorescence imaging, we provide experimental evidence that ROS [superoxide anion radical (O 2 •−) and singlet oxygen (1 O 2)] are produced following wounding. As a consequence, oxidation of biomolecules is induced, predominantly of polyunsaturated fatty acid, which leads to the formation of reactive intermediate products and electronically excited species.

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“…From a methodological point of view, the detection of ROS depends mainly on staining and imaging, which would not be easily applied in biohybrids (Steffens et al, 2013 ). Interestingly, constant development of electrochemical methods of H 2 O 2 detection in plant cells should be mentioned (Olvera-González et al, 2013 ; Prasad et al, 2015 ). Probably, they are more applicable in biohybrids, for they omit microscopic image acquisition and processing.…”

Section: Long-distance Signalingmentioning

confidence: 99%

Plant Science View on Biohybrid Development

Skrzypczak

Krela

Kwiatkowski

et al. 2017

Front. Bioeng. Biotechnol.

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Biohybrid consists of a living organism or cell and at least one engineered component. Designing robot–plant biohybrids is a great challenge: it requires interdisciplinary reconsideration of capabilities intimate specific to the biology of plants. Envisioned advances should improve agricultural/horticultural/social practice and could open new directions in utilization of plants by humans. Proper biohybrid cooperation depends upon effective communication. During evolution, plants developed many ways to communicate with each other, with animals, and with microorganisms. The most notable examples are: the use of phytohormones, rapid long-distance signaling, gravity, and light perception. These processes can now be intentionally re-shaped to establish plant–robot communication. In this article, we focus on plants physiological and molecular processes that could be used in bio-hybrids. We show phototropism and biomechanics as promising ways of effective communication, resulting in an alteration in plant architecture, and discuss the specifics of plants anatomy, physiology and development with regards to the bio-hybrids. Moreover, we discuss ways how robots could influence plants growth and development and present aims, ideas, and realized projects of plant–robot biohybrids.

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Detection of hydrogen peroxide in Photosystem II (PSII) using catalytic amperometric biosensor

Cited by 20 publications

References 74 publications

Production of Reactive Oxygen Species by Photosystem II as a Response to Light and Temperature Stress

Production of Reactive Oxygen Species by Photosystem II as a Response to Light and Temperature Stress

Reactive Oxygen Species as a Response to Wounding: In Vivo Imaging in Arabidopsis thaliana

Plant Science View on Biohybrid Development

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