Solar water-splitting into H2 and O2: design principles of photosystem II and hydrogenases

Lubitz, Wolfgang; Reijerse, Edward J.; Messinger, Johannes

doi:10.1039/b808792j

Cited by 405 publications

(380 citation statements)

References 200 publications

(248 reference statements)

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“…Potential H 2 ase reactivation was also observed after the exposure to 25% headspace oxygen for 48 h. Photosynthetic organisms were previously reported to display a slow rate of H 2 production owing to the oxygen sensitivity of H 2 ase 20,21 . Thus, the sensitivity of H 2 ase to oxygen has been implicated as a major obstacle to improving phototrophic biological hydrogen production 22 . However, Chader et al 23 showed that Chlorella sp.…”

Section: Discussionmentioning

confidence: 99%

Photoautotrophic hydrogen production by eukaryotic microalgae under aerobic conditions

et al. 2014

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Eukaryotic algae and cyanobacteria produce hydrogen under anaerobic and limited aerobic conditions. Here we show that novel microalgal strains (Chlorella vulgaris YSL01 and YSL16) upregulate the expression of the hydrogenase gene (HYDA) and simultaneously produce hydrogen through photosynthesis, using CO 2 as the sole source of carbon under aerobic conditions with continuous illumination. We employ dissolved oxygen regimes that represent natural aquatic conditions for microalgae. The experimental expression of HYDA and the specific activity of hydrogenase demonstrate that C. vulgaris YSL01 and YSL16 enzymatically produce hydrogen, even under atmospheric conditions, which was previously considered infeasible. Photoautotrophic H 2 production has important implications for assessing ecological and algae-based photolysis.

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Section: Discussionmentioning

confidence: 99%

Photoautotrophic hydrogen production by eukaryotic microalgae under aerobic conditions

et al. 2014

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“…Prominent examples are the only biological catalyst for solar water-splitting, photosystem II, and hydrogenases that reduce protons to molecular hydrogen. [9] A combination of both enzymes leads in principle to a direct solar-to-H 2 conversion via photolytic water-splitting, resulting in molecular oxygen (O 2 ) as by-product. In practice however, this has proven very difficult for many reasons, including enzyme instability and O 2 -sensitivity of many hydrogenases.…”

Section: Biological Approaches To Solar Energy Conversionmentioning

confidence: 99%

“…One of the more successful areas is solar energy related research. This research covers projects involving the synthesis and application of nanomaterials such as carbon nanotubes [16][17][18] ; the production of organic optoelectronic devices [19][20][21] ; synthesis of industrial catalysts [22][23][24] ; fundamental studies on the mechanism of enzymes (such as photosystem II) [9,11,[25][26][27] ; elucidation of the genome sequence, metabolism and biomass formation of various species [28][29][30] ; combustion, gasification and torrefaction of biomass including ash behaviour [31][32][33][34][35][36][37] ; the improvement of biomass (wood) quantity and quality by breeding and genetic modification [38,39] ; and implementation of a biorefinery concept at industrial scale. [40][41][42][43][44][45] For building and maintaining these research facilities and efforts, internal and external funding is required.…”

Section: An Institutional Approach To Solar Energy Conversionmentioning

confidence: 99%

“…2) connects 15 group leaders that cover the fields of plant physiology and natural photosynthesis (including photosynthetic water-splitting), catalysis, photochemistry, spectroscopy, crystallography, nanomaterials, physics, mathematics, and device-building. The approach is two-fold: (a) understanding and improving natural photosynthesis, [9,11,[25][26][27] and (b) applying this knowledge to the construction of low cost, printable artificial membranes for the direct (wireless) conversion of solar energy into fuels. [12,66] This environment is led by the author.…”

Section: Solar Fuels Strong Research Environmentmentioning

confidence: 99%

“…In practice however, this has proven very difficult for many reasons, including enzyme instability and O 2 -sensitivity of many hydrogenases. [9] Man-made Devices for Solar Energy Conversion (Artificial Photosynthesis)…”

Section: Biological Approaches To Solar Energy Conversionmentioning

confidence: 99%

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An Institutional Approach to Solar Fuels Research

Messinger¹

2012

Aust. J. Chem.

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Hydrogenases: Theoretical Investigations Towards Bioinspired H ₂ Production and Activation

Bruschi

Zampella

Greco

et al. 2005

Encyclopedia of Inorganic Chemistry

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Hydrogenases catalyze the reduction of protons, and have great biotechnological relevance in light of the key role played by H 2 in several industrial processes. Moreover, the industrial and social relevance of H 2 stems also from the observation that dihydrogen could be an efficient and cost‐attractive energy carrier for the future. Hydrogenases invariably contain a transition metal ion (Fe and in some case Ni) in their active site, and therefore have attracted the attention of experimental and theoretical bioinorganic chemists, which have given fundamental contributions to the elucidation of structure‐activity relationships in this class of enzymes. In addition, the recent elucidation of the X‐ray structure of [NiFe]‐ and [FeFe]‐hydrogenases has prompted synthetic chemists to design and characterize bioinspired coordination compounds, with the aim of obtaining efficient catalysts for H 2 production/activation. Here, we briefly review the contributions given by quantum chemistry to the characterization of key forms of the enzymes, the elucidation of reaction pathways and catalytic mechanisms, as well as the complementation of experimental data in the investigation of synthetic models. Emphasis is mainly given to underline the kind of insights that can be obtained using quantum chemical methods when investigating coordination compounds related to the hydrogenases active site, and to highlight some strengths and limitations of density functional theory, which currently is the most frequently used quantum chemical method to investigate metalloenzymes.

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Solar water-splitting into H2 and O2: design principles of photosystem II and hydrogenases

Cited by 405 publications

References 200 publications

Photoautotrophic hydrogen production by eukaryotic microalgae under aerobic conditions

Photoautotrophic hydrogen production by eukaryotic microalgae under aerobic conditions

An Institutional Approach to Solar Fuels Research

Hydrogenases: Theoretical Investigations Towards Bioinspired H ₂ Production and Activation

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Solar water-splitting into H2 and O2: design principles of photosystem II and hydrogenases

Cited by 405 publications

References 200 publications

Photoautotrophic hydrogen production by eukaryotic microalgae under aerobic conditions

Photoautotrophic hydrogen production by eukaryotic microalgae under aerobic conditions

An Institutional Approach to Solar Fuels Research

Hydrogenases: Theoretical Investigations Towards Bioinspired H 2 Production and Activation

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Hydrogenases: Theoretical Investigations Towards Bioinspired H ₂ Production and Activation