DeGrado, W.F.

Nat. Rev. Chem. 2022, 6, 31-50, 10.1038/s41570-021-00339-5

Natural metalloproteins perform many functions — ranging from sensing to electron transfer and catalysis — in which the position and property of each ligand and metal are dictated by protein structure. De novo protein design aims to define an amino acid sequence that encodes a specific structure and function, providing a critical test of the hypothetical inner workings of (metallo)proteins. To date, de novo metalloproteins have used simple, symmetric tertiary structures — uncomplicated by the large size and evolutionary marks of natural proteins — to interrogate structure–function hypotheses. In this Review, we discuss de novo design applications, such as proteins that induce complex, increasingly asymmetric ligand geometries to achieve function, as well as the use of more canonical ligand geometries to achieve stability. De novo design has been used to explore how proteins fine-tune redox potentials and catalyse both oxidative and hydrolytic reactions. With an increased understanding of structure–function relationships, functional proteins including O2-dependent oxidases, fast hydrolases and multi-proton/multielectron reductases have been created. In addition, proteins can now be designed using xenobiological metals or cofactors and principles from inorganic chemistry to derive new-to-nature functions. These results and the advances in computational protein design suggest a bright future for the de novo design of diverse, functional metalloproteins.

Leow, T.C.

3 Biotech 2018, 8, 10.1007/s13205-018-1333-9

Artificial metalloenzymes are unique as they combine the good features of homogeneous and enzymatic catalysts, and they can potentially improve some difficult catalytic assays. This study reports a method that can be used to create an artificial metal-binding site prior to proving it to be functional in a wet lab. Haloalkane dehalogenase was grafted into a metal-binding site to form an artificial metallo-haloalkane dehalogenase and was studied for its potential functionalities in silico. Computational protocols regarding dynamic metal docking were studied using native metalloenzymes and functional artificial metalloenzymes. Using YASARA Structure, a simulation box covering template structure was created to be filled with water molecules followed by one mutated water molecule closest to the metal-binding site to metal ion. A simple energy minimization step was subsequently run using an AMBER force field to allow the metal ion to interact with the metal-binding residues. Long molecular dynamic simulation using YASARA Structure was performed to analyze the stability of the metal-binding site and the distance between metal-binding residues. Metal ions fluctuating around 2.0 Å across a 20 ns simulation indicated a stable metal-binding site. Metal-binding energies were predicted using FoldX, with a native metalloenzyme (carbonic anhydrase) scoring 18.0 kcal/mol and the best mutant model (C1a) scoring 16.4 kcal/mol. Analysis of the metal-binding site geometry was performed using CheckMyMetal, and all scores for the metalloenzymes and mutant models were in an acceptable range. Like native metalloenzymes, the metal-binding site of C1a was supported by residues in the second coordination shell to maintain a more coordinated metal-binding site. Short-chain multihalogenated alkanes (1,2-dibromoethane and 1,2,3-trichloropropane) were able to dock in the active site of C1a. The halides of the substrate were in contact with both the metal and halide-stabilizing residues, thus indicating a better stabilization of the substrate. The simple catalytic mechanism proposed is that the metal ion interacted with halogen and polarized the carbon–halogen bond, thus making the alpha carbon susceptible to attack by nucleophilic hydroxide. The interaction between halogen in the metal ion and halide-stabilizing residues may help to improve the stabilization of the substrate–enzyme complex and reduce the activation energy. This study reports a modified dynamic metal-docking protocol and validation tests to verify the metal-binding site. These approaches can be applied to design different kinds of artificial metalloenzymes or metal-binding sites.

Ward, T.R.

Coordination Chemistry in Protein Cages: Principles, Design, and Applications 2013, 203-219, 10.1002/9781118571811.ch8

Enzymes catalyze a wide variety of chemical reactions with high selectivity and activity under mild conditions. The research strategy in the construction of artificial metalloenzyme relies on noncovalent attachment of the metal moiety using biotin‐(strept)avidin technology. The construction of artificial metalloenzyme can be carried out by anchoring a metal moiety within a protein scaffold with the help of an anchoring group. This chapter presents the results obtained upon applying this strategy toward the generation of artificial metalloenzymes for various enantioselective transformations. The palladium‐catalyzed asymmetric allylic alkylation (AAA) is a powerful tool for the elaboration of enantiopure high‐added value compounds. The current hypothesis is that proteins with a given catalytic function are difficult to use as host for the creation of artificial metalloenzymes. Proteins which merely act as transporters (myoglobin, serum albumins, (strept)avidin, etc.) may be more suited for the creation of artificial metalloenzymes.

Mayer, C.; Roelfes, G.

Nat. Rev. Chem. 2019, 3, 687-705, 10.1038/s41570-019-0143-x

The ability of one enzyme to catalyse multiple, mechanistically distinct transformations likely played a crucial role in organisms’ abilities to adapt to changing external stimuli in the past and can still be observed in extant enzymes. Given the importance of catalytic promiscuity in nature, enzyme designers have recently begun to create catalytically promiscuous enzymes in order to expand the canon of transformations catalysed by proteins. This article aims to both critically review different strategies for the design of enzymes that display catalytic promiscuity for new-to-nature reactions and highlight the successes of subsequent directed-evolution efforts to fine-tune these novel reactivities. For the former, we put a particular emphasis on the creation, stabilization and repurposing of reaction intermediates, which are key for unlocking new activities in an existing or designed active site. For the directed evolution of the resulting catalysts, we contrast approaches for enzyme design that make use of components found in nature and those that achieve new reactivities by incorporating synthetic components. Following the critical analysis of selected examples that are now available, we close this Review by providing a set of considerations and design principles for enzyme engineers, which will guide the future generation of efficient artificial enzymes for synthetically useful, abiotic transformations.

Happe, T.; Hemschemeier, A.

Nat. Rev. Chem. 2018, 2, 231-243, 10.1038/s41570-018-0029-3

Metal cofactors considerably widen the catalytic space of naturally occurring enzymes whose specific and enantioselective catalytic activity constitutes a blueprint for economically relevant chemical syntheses. To optimize natural enzymes and uncover novel reactivity, we need a detailed understanding of cofactor–protein interactions, which can be challenging to obtain in the case of enzymes with sophisticated cofactors. As a case study, we summarize recent research on the [FeFe]-hydrogenases, which interconvert protons, electrons and dihydrogen at a unique iron-based active site. We can now chemically synthesize the complex cofactor and incorporate it into an apo-protein to afford functional enzymes. By varying both the cofactor and the polypeptide components, we have obtained detailed knowledge on what is required for a metal cluster to process H2. In parallel, the design of artificial proteins and catalytically active nucleic acids are advancing rapidly. In this Perspective, we introduce these fields and outline how chemists and biologists can use this knowledge to develop novel tailored semisynthetic catalysts.