Jianping Yu scite author profile

The photobiological production of H2 gas, using water as the only electron donor, is a property of two types of photosynthetic microorganisms: green algae and cyanobacteria. In these organisms, photosynthetic water splitting is functionally linked to H(2) production by the activity of hydrogenase enzymes. Interestingly, each of these organisms contains only one of two major types of hydrogenases, [FeFe] or [NiFe] enzymes, which are phylogenetically distinct but perform the same catalytic reaction, suggesting convergent evolution. This idea is supported by the observation that each of the two classes of hydrogenases has a different metallo-cluster, is encoded by entirely different sets of genes (apparently under the control of different promoter elements), and exhibits different maturation pathways. The genetics, biosynthesis, structure, function, and O2 sensitivity of these enzymes have been the focus of extensive research in recent years. Some of this effort is clearly driven by the potential for using these enzymes in future biological or biohybrid systems to produce renewable fuel or in fuel cell applications.

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Sustained photosynthetic conversion of CO2 to ethylene in recombinant cyanobacterium Synechocystis 6803

Ungerer

Tao

Davis

et al. 2012

Energy Environ. Sci.

222

201

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Photobiological hydrogen-producing systems

et al. 2009

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Hydrogen photoproduction by micro-organisms combines the photosynthetic properties of oxygenic and non-oxygenic microbes with the activity of H2-producing enzymes in nature: hydrogenases and nitrogenases. The overall efficiency of the process depends on the separate efficiencies of photosynthesis and enzymatic catalysis. This tutorial review discusses the biochemical pathways for H2 production in different organisms, barriers to be overcome, and possible suggestions for integrating photobiological H2 production with fermentative, anaerobic systems for a potentially more efficient process.

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The plasticity of cyanobacterial metabolism supports direct CO2 conversion to ethylene

et al. 2015

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Glycogen Synthesis and Metabolite Overflow Contribute to Energy Balancing in Cyanobacteria

et al. 2018

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Understanding how living cells manage high-energy metabolites such as ATP and NADPH is essential for understanding energy transformations in the biosphere. Using light as the energy input, we find that energy charge (ratio of ATP over ADP+ATP) in the cyanobacterium Synechocystis sp. PCC 6803 varies in different growth stages, with a peak upon entry into the rapid growth phase, as well as a positive correlation with light intensity. In contrast, a mutant that can no longer synthesize the main carbon storage compound glycogen showed higher energy charge. The overflow of organic acids in this mutant under nitrogen depletion could also be triggered under high light in nitrogen-replete conditions, with an energy input level dependency. These findings suggest that energy charge in cyanobacteria is tightly linked to growth and carbon partition and that energy management is of key significance for their application as photosynthetic carbon dioxide-assimilating cell factories.

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Jianping Yu

Hydrogenases and Hydrogen Photoproduction in Oxygenic Photosynthetic Organisms

Sustained photosynthetic conversion of CO2 to ethylene in recombinant cyanobacterium Synechocystis 6803

Photobiological hydrogen-producing systems

The plasticity of cyanobacterial metabolism supports direct CO2 conversion to ethylene

Glycogen Synthesis and Metabolite Overflow Contribute to Energy Balancing in Cyanobacteria

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