1.12.1.3: hydrogen dehydrogenase (NADP+)
This is an abbreviated version!
For detailed information about hydrogen dehydrogenase (NADP+), go to the full flat file.
Word Map on EC 1.12.1.3
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1.12.1.3
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hydrogenases
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pyrococcus
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furiosus
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desulfovibrio
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fructosovorans
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hyperthermophilic
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synthesis
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clostridium
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ferredoxin
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heterotetrameric
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pasteurianum
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nife-hydrogenase
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viologen
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proton-coupled
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mononucleotide
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midpoint
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hydride
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photolysis
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binuclear
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hydrogen-producing
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denitrificans
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h2-dependent
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time-resolved
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typified
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metalloenzyme
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taurus
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nickel-iron
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energy production
- 1.12.1.3
- hydrogenases
-
pyrococcus
- furiosus
-
desulfovibrio
- fructosovorans
-
hyperthermophilic
- synthesis
- clostridium
- ferredoxin
-
heterotetrameric
- pasteurianum
- nife-hydrogenase
- viologen
-
proton-coupled
- mononucleotide
-
midpoint
-
hydride
-
photolysis
-
binuclear
-
hydrogen-producing
- denitrificans
-
h2-dependent
-
time-resolved
-
typified
-
metalloenzyme
- taurus
-
nickel-iron
- energy production
Reaction
Synonyms
hydrogenase [ambiguous], NADP-dependent hydrogenase, NADP-linked hydrogenase, NADP-reducing hydrogenase, NADPH-dependent hydrogenase I, NADPH-dependent [NiFe]-hydrogenase, NiFe-hydrogenase, SHI, soluble hydrogenase I, [NiFe]-hydrogenase, [NiFe]-hydrogenase I
ECTree
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Application
Application on EC 1.12.1.3 - hydrogen dehydrogenase (NADP+)
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energy production
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application in biofuel cells, to generate an electric current
synthesis
synthesis
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biohydrogen production. Photochemical hydrogen production system using zinc porphyrin and hydrogenase in a micellar system of cetyltrimethylammonium bromide. Cetyltrimethylammonium bromide acts as a cationic surfactant to effectively separate the charges
synthesis
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biohydrogen production. The enzyme is immobilized between two layers of montmorillonite clay and poly(butylviologen) mixture. The amount of hydrogen produced relates closely to the applied potential, buffer pH and temperature
synthesis
biohydrogen production from sugars using a mixture of enzymes in an in vitro cell-free synthetic pathway. Development of this process at an industrial scale is limited by the availability of the H2-producing enzyme
synthesis
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the study provides a cost-efficient method to obtain hyperthermostable hydrogenases, which can be used in in vitro synthetic enzymatic biosystems for cofactor regeneration and hydrogen production. It has great potential in biocatalysis, bioelectrochemistry, and clean energy production