Engineering of an alternative electron transfer path in photosystem II

Larom, Shirley; Salama, Faris; Schuster, Gadi; Adir, Noam

doi:10.1073/pnas.1000187107

Cited by 52 publications

(45 citation statements)

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“…Binding of the Flv4/Flv2 heterodimer to PSII likely occurs via charge interaction between the heterodimer and the PSII cytoplasmic side (Larom et al, 2010). The role of Flv2/Flv4 in interaction of PBS with PSII is likely to be linked to their electron transfer properties.…”

Section: Flv2/flv4 Heterodimer and Sll0218 Protein Are Functionally Lmentioning

confidence: 99%

Operon flv4-flv2 Provides Cyanobacterial Photosystem II with Flexibility of Electron Transfer

et al. 2012

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Synechocystis sp PCC 6803 has four genes encoding flavodiiron proteins (FDPs; Flv1 to Flv4). Here, we investigated the flv4-flv2 operon encoding the Flv4, Sll0218, and Flv2 proteins, which are strongly expressed under low inorganic carbon conditions (i.e., air level of CO 2 ) but become repressed at elevated CO 2 conditions. Different from FDP homodimers in anaerobic microbes, Synechocystis Flv2 and Flv4 form a heterodimer. It is located in cytoplasm but also has a high affinity to membrane in the presence of cations. Sll0218, on the contrary, resides in the thylakoid membrane in association with a high molecular mass protein complex. Sll0218 operates partially independently of Flv2/Flv4. It stabilizes the photosystem II (PSII) dimers, and according to biophysical measurements opens up a novel electron transfer pathway to the Flv2/Flv4 heterodimer from PSII. Constructed homology models suggest efficient electron transfer in heterodimeric Flv2/Flv4. It is suggested that Flv2/Flv4 binds to thylakoids in light, mediates electron transfer from PSII, and concomitantly regulates the association of phycobilisomes with PSII. The function of the flv4-flv2 operon provides many b-cyanobacteria with a so far unknown photoprotection mechanism that evolved in parallel with oxygen-evolving PSII.

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Section: Flv2/flv4 Heterodimer and Sll0218 Protein Are Functionally Lmentioning

confidence: 99%

Operon flv4-flv2 Provides Cyanobacterial Photosystem II with Flexibility of Electron Transfer

et al. 2012

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“…Modification of this lysine to glutamate (Glu, E), i.e., K238E resulted in alternative electron transfer pathway to soluble electron acceptor protein (cytochrome c) near the Q A -site. 42 This redirection along with the addition of an herbicide that blocks the electron flow at Q B site resulted in decreased oxidative damage. In another attempt, cationic redox-active metal complexes …”

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confidence: 99%

“…Electrons from Q A -in PSII were redirected to engineered collection sites approximately 13 Å away on the stromal side of the thylakoid membrane. 42 The positively charged amino acid lysine (Lys, K) at position 238 of D1 protein in PSII is important for the insulation of the PSII electron flow from external oxidation by soluble species and is also highly conserved in PSII of higher plants and algae. Modification of this lysine to glutamate (Glu, E), i.e., K238E resulted in alternative electron transfer pathway to soluble electron acceptor protein (cytochrome c) near the Q A -site.…”

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confidence: 99%

“…Accordingly various efforts have been undertaken to collect more electrons from PSII. 42 Certain genetic engineering approaches have been used to redirect the electrons from the photosystem complexes, thereby manipulating P-ETC for generating higher photocurrent. Electrons from Q A -in PSII were redirected to engineered collection sites approximately 13 Å away on the stromal side of the thylakoid membrane.…”

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confidence: 99%

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Photosynthetic Energy Conversion: Recent Advances and Future Perspective

Sekar

Ramasamy

2015

Interface magazine

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Photosynthesis is the most important natural process on earth, which transformed the once lifeless planet into a living world. While primitive photosynthetic bacteria such as purple sulfur bacteria and green sulfur bacteria carry out anoxygenic photosynthesis, producing elemental sulfur from hydrogen sulfide with the help of sunlight, cyanobacteria, algae and plants carry out oxygenic photosynthesis to convert water and carbon dioxide to sugars with the help of sunlight and release oxygen as a byproduct. The conversion of solar energy to chemical energy via photosynthesis with the release of oxygen has an evolutionary significance on life as we know it today. In fact, photosynthesis is the only natural process known on earth to form oxygen from water. Further, fossil fuels such as coal, petroleum and natural gas are formed from the remains of the dead plants by exposure to heat and pressure in the earth's crust over millions of years. With increasing energy crisis and environmental issues lately, now is the time to revisit photosynthesis in order to address these issues. In this context, a great deal of ongoing research is focused on utilizing photosynthetic energy conversion as a renewable, self-sustainable and environment friendly source of energy. When compared to the finite reserve of fossil fuels, sunlight, the energy source for photosynthesis, is abundant around the planet and is inexhaustible.The earth receives solar energy at the rate of about 120,000 TW, which far exceeds our current global demand of ~16 TW.1 However the only major technology available for solar energy conversion is photovoltaics (PV). PV devices such as solar panels generate electrical power by converting solar radiation into direct current electricity using semiconductors. Solar cells include first generation conventional wafer-based cells made up of crystalline silicon (Fig. 1a), second generation thin film solar cells (Fig. 1b)

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“…This limitation can be overcome by redirecting the electrons from the inner part of the protein to the surface (Sekar and Ramasamy, 2015). For instance, Larom et al (2010) successfully used an artificial mediator to redirect electrons from QA -to an artificial acceptor at a distance of about 1.3 nm from the stromal side of the membrane. This change in the direction of electron flow along with additional blocking of QB led to a reduction of oxidative damages at the expense of reducing the time of the intermediate electron transfer at the stage of QA/QB.…”

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confidence: 99%

Photoelectrochemical cells based on photosynthetic systems: a review

et al. 2015

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HIGHLIGHTSPhotosynthesis is a process which converts light energy into energy contained in the chemical bonds of organic compounds by photosynthetic pigments such as chlorophyll (Chl a, b, c, d, f) or bacteriochlorophyll. It occurs in phototrophic organisms, which include higher plants and many types of photosynthetic bacteria, including cyanobacteria. In the case of the oxygenic photosynthesis, water is a donor of both electrons and protons, and solar radiation serves as inexhaustible source of energy. Efficiency of energy conversion in the primary processes of photosynthesis is close to 100%. Therefore, for many years photosynthesis has attracted the attention of researchers and designers looking for alternative energy systems as one of the most efficient and eco-friendly pathways of energy conversion. The latest advances in the design of optimal solar cells include the creation of converters based on thylakoid membranes, photosystems, and whole cells of cyanobacteria immobilized on nanostructured electrode (gold nanoparticles, carbon nanotubes, nanoparticles of ZnO and TiO2). The mode of solar energy conversion in photosynthesis has a great potential as a source of renewable energy while it is sustainable and environmentally safety as well. Application of pigments such as Chl f and Chl d (unlike Chl a and Chl b), by absorbing the far-red and near infrared region of the spectrum (in the range 700-750 nm), will allow to increase the efficiency of such light transforming systems. This review article presents the last achievements in the field of energy photoconverters based on photosynthetic systems.

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Engineering of an alternative electron transfer path in photosystem II

Cited by 52 publications

References 51 publications

Operon flv4-flv2 Provides Cyanobacterial Photosystem II with Flexibility of Electron Transfer

Operon flv4-flv2 Provides Cyanobacterial Photosystem II with Flexibility of Electron Transfer

Photosynthetic Energy Conversion: Recent Advances and Future Perspective

Photoelectrochemical cells based on photosynthetic systems: a review

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