Distribution of Hydrogenases in Cyanobacteria: A Phylum-Wide Genomic Survey

Puggioni, Vincenzo; Tempel, Sébastien; Latifi, Amel

doi:10.3389/fgene.2016.00223

Cited by 21 publications

(16 citation statements)

References 102 publications

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“…Group 3d [NiFe]-hydrogenases consist of a heteromeric hydrogenase and a NADH-dehydrogenase module that binds to NAD(P)H (20). The amount of hydrogenase subunits varies greatly, consisting of, for example, a heterodimeric enzyme in C. necator (56) or a heteropentameric enzyme in Cyanobacteria (57). These hydrogenases are used to balance the NAD ϩ /NADH pool by reducing NAD ϩ using H 2 (20).…”

Section: Hydrogenase Classification: An Overviewmentioning

confidence: 99%

Molecular Hydrogen, a Neglected Key Driver of Soil Biogeochemical Processes

Piché-Choquette

Constant

2019

Appl Environ Microbiol

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The atmosphere of the early Earth is hypothesized to have been rich in reducing gases such as hydrogen (H2). H2has been proposed as the first electron donor leading to ATP synthesis due to its ubiquity throughout the biosphere as well as its ability to easily diffuse through microbial cells and its low activation energy requirement. Even today, hydrogenase enzymes enabling the production and oxidation of H2are found in thousands of genomes spanning the three domains of life across aquatic, terrestrial, and even host-associated ecosystems. Even though H2has already been proposed as a universal growth and maintenance energy source, its potential contribution as a driver of biogeochemical cycles has received little attention. Here, we bridge this knowledge gap by providing an overview of the classification, distribution, and physiological role of hydrogenases. Distribution of these enzymes in various microbial functional groups and recent experimental evidence are finally integrated to support the hypothesis that H2-oxidizing microbes are keystone species driving C cycling along O2concentration gradients found in H2-rich soil ecosystems. In conclusion, we suggest focusing on the metabolic flexibility of H2-oxidizing microbes by combining community-level and individual-level approaches aiming to decipher the impact of H2on C cycling and the C-cycling potential of H2-oxidizing microbes, via both culture-dependent and culture-independent methods, to give us more insight into the role of H2as a driver of biogeochemical processes.

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Section: Hydrogenase Classification: An Overviewmentioning

confidence: 99%

Molecular Hydrogen, a Neglected Key Driver of Soil Biogeochemical Processes

Piché-Choquette

Constant

2019

Appl Environ Microbiol

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“…The annual solar flux received by Earth is in vast excess of the total energy used by human societies, and the burning of hydrogen liberates a high amount of energy (142 MJ/kg for H 2 vs. 44.2 MJ/kg for oil) while producing only water (H 2 O) as a by-product. As a consequence, there is a growing interest in cyanobacteria, the photosynthetic microorganisms that can use solar energy, water, CO 2 , mineral and salts for the production of H 2 , while saving arable soils, fertilizers and fresh waters for agriculture (for recent reviews see [ 1 – 3 ]). Furthermore, several model cyanobacteria have a small sequenced genome easily manipulable, such as the presently studied unicellular strain Synechocystis PCC6803 (hereafter designated as Synechocystis ).…”

Section: Introductionmentioning

confidence: 99%

Overproduction of the cyanobacterial hydrogenase and selection of a mutant thriving on urea, as a possible step towards the future production of hydrogen coupled with water treatment

et al. 2018

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Using a combination of various types of genetic manipulations (promoter replacement and gene cloning in replicating plasmid expression vector), we have overproduced the complex hydrogenase enzyme in the model cyanobacterium Synechocystis PCC6803. This new strain overproduce all twelve following proteins: HoxEFUYH (hydrogen production), HoxW (maturation of the HoxH subunit of hydrogenase) and HypABCDEF (assembly of the [NiFe] redox center of HoxHY hydrogenase). This strain when grown in the presence of a suitable quantities of nickel and iron used here exhibit a strong (25-fold) increase in hydrogenase activity, as compared to the WT strain growing in the standard medium. Hence, this strain can be very useful for future analyses of the cyanobacterial [NiFe] hydrogenase to determine its structure and, in turn, improve its tolerance to oxygen with the future goal of increasing hydrogen production. We also report the counterintuitive notion that lowering the activity of the Synechocystis urease can increase the photoproduction of biomass from urea-polluted waters, without decreasing hydrogenase activity. Such cyanobacterial factories with high hydrogenase activity and a healthy growth on urea constitute an important step towards the future development of an economical industrial processes coupling H2 production from solar energy and CO2, with wastewater treatment (urea depollution).

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“…The second type of enzymes producing H 2 are hydrogenases (H 2 ases). Bidirectional NiFe H 2 ases (called Hox), which catalyze both H 2 oxidation and proton reduction, are largely distributed across the cyanobacterial phylum [2,3]. They form a heteropentamer with a H 2 ase part (HoxYH) and a diaphorase part (HoxEFU).…”

Section: Introductionmentioning

confidence: 99%

Overproduction of the Flv3B flavodiiron, enhances the photobiological hydrogen production by the nitrogen-fixing cyanobacterium Nostoc PCC 7120

et al. 2020

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Background: The ability of some photosynthetic microorganisms, particularly cyanobacteria and microalgae, to produce hydrogen (H 2) is a promising alternative for renewable, clean-energy production. However, the most recent, related studies point out that much improvement is needed for sustainable cyanobacterial-based H 2 production to become economically viable. In this study, we investigated the impact of induced O 2-consumption on H 2 photoproduction yields in the heterocyte-forming, N 2-fixing cyanobacterium Nostoc PCC7120. Results: The flv3B gene, encoding a flavodiiron protein naturally expressed in Nostoc heterocytes, was overexpressed. Under aerobic and phototrophic growth conditions, the recombinant strain displayed a significantly higher H 2 production than the wild type. Nitrogenase activity assays indicated that flv3B overexpression did not enhance the nitrogen fixation rates. Interestingly, the transcription of the hox genes, encoding the NiFe Hox hydrogenase, was significantly elevated, as shown by the quantitative RT-PCR analyses. Conclusion: We conclude that the overproduced Flv3B protein might have enhanced O 2-consumption, thus creating conditions inducing hox genes and facilitating H 2 production. The present study clearly demonstrates the potential to use metabolic engineered cyanobacteria for photosynthesis driven H 2 production.

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Distribution of Hydrogenases in Cyanobacteria: A Phylum-Wide Genomic Survey

Cited by 21 publications

References 102 publications

Molecular Hydrogen, a Neglected Key Driver of Soil Biogeochemical Processes

Molecular Hydrogen, a Neglected Key Driver of Soil Biogeochemical Processes

Overproduction of the cyanobacterial hydrogenase and selection of a mutant thriving on urea, as a possible step towards the future production of hydrogen coupled with water treatment

Overproduction of the Flv3B flavodiiron, enhances the photobiological hydrogen production by the nitrogen-fixing cyanobacterium Nostoc PCC 7120

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