The integration of chemo- and enzymatic
catalysis for effective
multistep cascades has presented critical challenges for decades.
In this work, the biomimetic quasi NH2-MIL-101 (qNM) with
highly efficient peroxidase-like activity was synthesized via a palmitic
acid-induced strategy followed by pyrolysis. The effects of the amount
of palmitic acid and calcination temperature on the synthesis of qNM
were optimized. It was found that qNM was an excellent catalyst for
oxidations of various peroxidase substrates, and a possible mechanism
was proposed, i.e., the presence of FeII species in qNM
was responsible for its excellent activity, which facilitated the
transition between FeII and FeIII species to
produce more hydroxyl radicals by H2O2 decomposition.
The qNM served as the potential matrix for enzyme immobilization through
a cross-linking method, and kinetic studies revealed that the catalytic
efficiency (kcat
/Km
) for the immobilized GOx (23.7 mM–1 s–1) is comparable to that of free GOx (26.9 mM–1 s–1). The immobilized GOx also showed improved
stability against high temperatures and organic solvents compared
to free GOx, and analysis of the secondary structure of GOx indicated
that the improved stability resulted from enzyme rigidity by the intense
covalent linkage with qNM. Furthermore, qNM contributed its biomimetic
activity to cooperate with a single enzyme (GOx) or two enzymes (β-Gal
and GOx) for the enzymatic cascade reactions. Compared with the mixture
of each component in the solution, the combination of the single-enzyme
system (GOx) or the two-enzyme system (β-Gal and GOx) in qNM
achieved 2.67-fold and 1.83-fold enhancements in the activity of catalytic
cascades, respectively. This study provides new insights into the
construction of effective and synergistic cascade reactions by integrating
biomimetic MOF with natural enzyme, which holds potential for applications
in biotechnology and ecofriendly and biomimetic catalysis.
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