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A catalytically active [Mn]-hydrogenase incorporating a non-native metal cofactor.

Hui-Jie PanGangfeng HuangMatthew D WodrichFarzaneh Fadaei TiraniKenichi AtakaSeigo ShimaXile Hu
Published in: Nature chemistry (2019)
Nature carefully selects specific metal ions for incorporation into the enzymes that catalyse the chemical reactions necessary for life. Hydrogenases, enzymes that activate molecular H2, exclusively utilize Ni and Fe in [NiFe]-, [FeFe]- and [Fe]-hydrogeanses. However, other transition metals are known to activate or catalyse the production of hydrogen in synthetic systems. Here, we report the development of a biomimetic model complex of [Fe]-hydrogenase that incorporates a Mn, as opposed to a Fe, metal centre. This Mn complex is able to heterolytically cleave H2 as well as catalyse hydrogenation reactions. The incorporation of the model into an apoenzyme of [Fe]-hydrogenase results in a [Mn]-hydrogenase with an enhanced occupancy-normalized activity over an analogous semi-synthetic [Fe]-hydrogenase. These findings demonstrate a non-native metal hydrogenase that shows catalytic functionality and that hydrogenases based on a manganese active site are viable.
Keyphrases
  • metal organic framework
  • aqueous solution
  • room temperature
  • visible light
  • transition metal
  • human health
  • heavy metals