Metal Ion Promiscuity and Structure of 2,3‐Dihydroxybenzoic Acid Decarboxylase of Aspergillus oryzae

Abstract: Broad substrate tolerance and excellent regioselectivity, as well as independence from sensitive cofactors have established benzoic acid decarboxylases from microbial sources as efficient biocatalysts. Robustness under process conditions makes them particularly attractive for preparative‐scale applications. The divalent metal‐dependent enzymes are capable of catalyzing the reversible non‐oxidative (de)carboxylation of a variety of electron‐rich (hetero)aromatic substrates analogously to the chemical Kolbe‐Schm… Show more

“…11 kcal/mol. This approximation has been applied in all the studies presented here and has been shown to yield satisfactory results [44] , [45] , [46] , [54] .…”

“…Interestingly, Zn was initially proposed to be the divalent metal ion commonly adopted by AHS decarboxylases [33] , [35] , [42] , but Mn was recently determined to be the catalytic metal in LigW [43] , γ-RSD [44] and IDCase [45] . 2,3-DHBD has been shown to be active with both Mn and Mg [46] .…”

“…Crystal structures have been reported for a number of AHS metal-dependent decarboxylases, including the above-mentioned LigW [43] , γ-RSD [33] , [44] , IDCase [45] , and 2,3-DHBD [46] . Comparisons revealed that they have significant structural similarities, in particular the characteristic (β/α) 8 TIM‐barrel fold and the overall active site architectures.…”

“…We have in recent years employed this technique to uncover the reaction mechanisms of the four AHS metal-dependent decarboxylases mentioned above: LigW [54] , γ-RSD [44] , 2,3-DHBD [46] , and IDCase [45] . In this mini-review, we summarize the results of these computational studies, all of which were published in combination with experiments.…”

Mechanisms of metal-dependent non-redox decarboxylases from quantum chemical calculations

“…11 kcal/mol. This approximation has been applied in all the studies presented here and has been shown to yield satisfactory results [44] , [45] , [46] , [54] .…”

“…Interestingly, Zn was initially proposed to be the divalent metal ion commonly adopted by AHS decarboxylases [33] , [35] , [42] , but Mn was recently determined to be the catalytic metal in LigW [43] , γ-RSD [44] and IDCase [45] . 2,3-DHBD has been shown to be active with both Mn and Mg [46] .…”

“…Crystal structures have been reported for a number of AHS metal-dependent decarboxylases, including the above-mentioned LigW [43] , γ-RSD [33] , [44] , IDCase [45] , and 2,3-DHBD [46] . Comparisons revealed that they have significant structural similarities, in particular the characteristic (β/α) 8 TIM‐barrel fold and the overall active site architectures.…”

“…We have in recent years employed this technique to uncover the reaction mechanisms of the four AHS metal-dependent decarboxylases mentioned above: LigW [54] , γ-RSD [44] , 2,3-DHBD [46] , and IDCase [45] . In this mini-review, we summarize the results of these computational studies, all of which were published in combination with experiments.…”

Mechanisms of metal-dependent non-redox decarboxylases from quantum chemical calculations

“…Several decarboxylases employ divalent metal ions without requiring any organic cofactors. For example, 2,6‐dihydroxybenzoic acid decarboxylases (2,6‐DHBDs) [48] and 2, 3‐DHBDs [49] utilize Zn 2+ and Mg 2+ /Mn 2+ respectively to facilitate the carboxylation of dihydroxybenzenes, while the aliphatic carboxylase, phosphoenolpyruvate carboxylase (PEPC) [50,51] employs either Co 2+ , Mg 2+ , or Mn 2+. in its carboxylation process.…”

Synthetic Enzyme‐Catalyzed CO₂ Fixation Reactions

Mechanistic Insights into the electron‐transfer driven substrate activation by [4Fe‐4S]‐dependent Enzymes