Abstract

ConspectusMetalloproteins establish a comprehensive molecular space by combining inorganic cofactors with protein environments. The chemical interplay between a metal element and a protein matrix is remarkable yet elusive, as the chemical properties of metal ions do not directly translate into those of metalloenzymes when placed within a protein matrix. Instead, the biochemical context determines the metal-coordination geometries, reaction kinetics, and thermodynamic parameters, such as redox potential and Lewis acidity/basicity. The molecular design of novel metalloproteins, which involves varying the combination of the two major components, metal ion and protein, allows us to validate our current understanding of their chemical interactions, modulate protein structure and function toward specific directions, and create protein-based functional biomaterials and biocatalysts. Considering theoretically possible protein sequence combinations and several metal elements at several oxidation states, artificial metalloenzyme design is analogous to the drawing of new paintings with multiple colors and brush strokes.Our laboratory has developed minimalistic strategies to transform diverse proteins into artificial metalloproteins with novel architectures or catalytic functions. First, we analyzed the geometric parameters of native Zn-binding sites to introduce a tetrahedral zinc-binding motif to a non-α-helical protein scaffold that shows neither pre-existing affinity to any metal ion nor catalytic activity, such as the β-barrel outer membrane protein OmpF. We created a series of artificial Zn-binding OmpF variants that possess coordinatively unsaturated mononuclear Zn-ligation sites and exhibit hydrolytic activities with esters, β-lactams, and β-glycosides. The OmpF variants were further evolved to zinc-dependent glycosidases, addressing a central question in bioinorganic chemistry: can zinc ions directly associate with the hydrolytic cleavage of glycosidic bonds in sugars?To expand the scope of metalloprotein design, we also utilized a metal-chelating noncanonical amino acid, bipyridine-alanine, and constructed tunable dicopper-dependent oxidases and nickel/iridium-dependent photocatalytic cross-coupling enzymes. These advancements increased the complexity and precision of metalloenzyme design, revealing how protein matrices, in conjunction with metallocofactors in aqueous media, facilitate electron transfer and mediate multiple chemical events, such as proton transfer, substrate access, and product release, while suppressing adventitious reactions.Furthermore, we redesigned the secondary and tertiary metal-coordination spheres of manganese-dependent quercetin dioxygenase and zinc-dependent β-lactamase, respectively. Biochemical characterizations of the evolved enzymes revealed that metal ions harmoniously and selectively cooperate with protein environments such that seemingly unimportant residues play critical roles in tuning the electronic structures of the enzymes or determining the metal-dependent reactivity. Thus, our work establishes the fundamental basis of how metalloenzymes function via long-range intermolecular interactions and how we can control their structure and function in specific directions. Consequently, these novel metalloenzymes have provided possible snapshots of how they could have evolved under controlled chemical environments and potential prospects for how to design more sophisticated and efficient biocatalysts with accuracy at the molecular level.

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