Bäckvall, J.E.; Diéguez, M.; Pàmies, O.

Adv. Synth. Catal. 2015, 357, 1567-1586, 10.1002/adsc.201500290

Artificial metalloenzymes combine the excellent selective recognition/binding properties of enzymes with transition metal catalysts, and therefore many asymmetric transformations can benefit from these entities. The search for new successful strategies in the construction of metal‐enzyme hybrid catalysts has therefore become a very active area of research. This review discusses all the developed strategies and the latest advances in the synthesis and application in asymmetric catalysis of artificial metalloenzymes with future directions for their design, synthesis and application (Sections 2–4). Finally, advice is presented (to the non‐specialist) on how to prepare and use artificial metalloenzymes (Section 5).

Head-Gordon, T.

ACS Cent. Sci. 2021, 7, 72-80, 10.1021/acscentsci.0c01556

As biocatalysts, enzymes are characterized by their high catalytic efficiency and strong specificity but are relatively fragile by requiring narrow and specific reactive conditions for activity. Synthetic catalysts offer an opportunity for more chemical versatility operating over a wider range of conditions but currently do not reach the remarkable performance of natural enzymes. Here we consider some new design strategies based on the contributions of nonlocal electric fields and thermodynamic fluctuations to both improve the catalytic step and turnover for rate acceleration in arbitrary synthetic catalysts through bioinspired studies of natural enzymes. With a focus on the enzyme as a whole catalytic construct, we illustrate the translational impact of natural enzyme principles to synthetic enzymes, supramolecular capsules, and electrocatalytic surfaces.

Arnold, F.H.

Artificial Metalloenzymes and MetalloDNAzymes in Catalysis: From Design to Applications 2018, 137-170, 10.1002/9783527804085.ch5

Directed evolution is a powerful algorithm for engineering proteins to have novel and useful properties. However, we do not yet fully understand the characteristics of an evolvable system. In this chapter, we present examples where directed evolution has been used to enhance the performance of metalloenzymes, focusing first on “classical” cases such as improving enzyme stability or expanding the scope of natural reactivity. We then discuss how directed evolution has been extended to artificial systems, in which a metalloprotein catalyzes reactions using abiological reagents or in which the protein utilizes a nonnatural cofactor for catalysis. These examples demonstrate that directed evolution can also be applied to artificial systems to improve catalytic properties, such as activity and enantioselectivity, and to favor a different product than that favored by small‐molecule catalysts. Future work will help define the extent to which artificial metalloenzymes can be altered and optimized by directed evolution and the best approaches for doing so.

Craik, C.S.

Biochemistry 1995, 34, 2172-2180, 10.1021/bi00007a010

Histidine substrate specificity has been engineered into trypsin by creating metal binding sites for Ni2+ and Zn2+ ions. The sites bridge the substrate and enzyme on the leaving-group side of the scissile bond. Application of simple steric and geometric criteria to a crystallographically derived enzyme- substrate model suggested that histidine specificity at the P2' position might be acheived by a tridentate site involving amino acid residues 143 and 151 of trypsin. Trypsin N143H/E151H hydrolyzes a P2'- His-containing peptide (AGPYAHSS) exclusively in the presence of nickel or zinc with a high level of catalytic efficiency. Since cleavage following the tyrosine residue is normally highly disfavored by trypsin, this result demonstrates that a metal cofactor can be used to modulate specificity in a designed fashion. The same geometric criteria applied in the primary SI binding pocket suggested that the single-site mutation D189H might effect metal-dependent His specificity in trypsin. However, kinetic and crystallographic analysis of this variant showed that the design was unsuccessful because His 189 rotates away from substrate causing a large perturbation in adjacent surface loops. This observation suggests that the reason specificity modification at the trypsin S1 site requires extensive mutagenesis is because the pocket cannot deform locally to accommodate alternate PI side chains. By taking advantage of the extended subsites, an alternate substrate specificity has been engineered into trypsin.

Arnold, F.H.; Fasan, R.

Curr. Opin. Biotechnol. 2017, 47, 102-111, 10.1016/j.copbio.2017.06.005

The surge in reports of heme-dependent proteins as catalysts for abiotic, synthetically valuable carbene and nitrene transfer reactions dramatically illustrates the evolvability of the protein world and our nascent ability to exploit that for new enzyme chemistry. We highlight the latest additions to the hemoprotein-catalyzed reaction repertoire (including carbene Si–H and C–H insertions, Doyle–Kirmse reactions, aldehyde olefinations, azide-to-aldehyde conversions, and intermolecular nitrene C–H insertion) and show how different hemoprotein scaffolds offer varied reactivity and selectivity. Preparative-scale syntheses of pharmaceutically relevant compounds accomplished with these new catalysts are beginning to demonstrate their biotechnological relevance. Insights into the determinants of enzyme lifetime and product yield are providing generalizable cues for engineering heme-dependent proteins to further broaden the scope and utility of these non-natural activities.

Coleman, J.E.

Nature 1967, 214, 193-194, 10.1038/214193a0

ACETAZOLAMIDE (2-acetylamino-1,3,4-thiadiazole-5-sulphonamide, ‘Diamox’) is the most potent known inhibitor of the zinc enzyme carbonic anhydrase. This communication reports the direct demonstration that binding of acetazolamide to human carbonic anhydrase requires the presence of a metal ion at the active site and that binding depends on the species of divalent metal ion present. Zinc (II) and cobalt (II) ions are the only ions which induce the formation of very stable acetazolamide carbonic anhydrase complexes and are also the ions which most effectively catalyse the hydration of carbon dioxide and the hydrolysis of p-nitrophenyl acetate. Metal-binding monodentate ions, CN−, HS−, OCN−, and N3−, known as effective carbonic anhydrase inhibitors, compete for the acetazolamide binding site of the zinc enzyme.

Arnold, F.H.

J. Am. Chem. Soc. 2019, 141, 19585-19588, 10.1021/jacs.9b11608

Transition-metal catalysis is a powerful tool for the construction of chemical bonds. Here we show that Pseudomonas savastanoi ethylene-forming enzyme, a non-heme iron enzyme, can catalyze olefin aziridination and nitrene C−H insertion, and that these activities can be improved by directed evolution. The nonheme iron center allows for facile modification of the primary coordination sphere by addition of metalcoordinating molecules, enabling control over enzyme activity and selectivity using small molecules.

Arnold, F.H.

Curr. Opin. Chem. Biol. 2019, 49, 67-75, 10.1016/j.cbpa.2018.10.004

C–H functionalization is an attractive strategy to construct and diversify molecules. Heme proteins, predominantly cytochromes P450, are responsible for an array of C–H oxidations in biology. Recent work has coupled concepts from synthetic chemistry, computation, and natural product biosynthesis to engineer heme protein systems to deliver products with tailored oxidation patterns. Heme protein catalysis has been shown to go well beyond these native reactions and now accesses new-to-nature C–H transformations, including C–N and C–C bond forming processes. Emerging work with these systems moves us along the ambitious path of building complexity from the ubiquitous C–H bond.

Clark, D.S.; Hartwig, J.F.; Keasling, J.D.; Mukhopadhyay, A.

Nat. Chem. 2021, 13, 1186-1191, 10.1038/s41557-021-00801-3

Synthetic biology enables microbial hosts to produce complex molecules from organisms that are rare or difficult to cultivate, but the structures of these molecules are limited to those formed by reactions of natural enzymes. The integration of artificial metalloenzymes (ArMs) that catalyse unnatural reactions into metabolic networks could broaden the cache of molecules produced biosynthetically. Here we report an engineered microbial cell expressing a heterologous biosynthetic pathway, containing both natural enzymes and ArMs, that produces an unnatural product with high diastereoselectivity. We engineered Escherichia coli with a heterologous terpene biosynthetic pathway and an ArM containing an iridium–porphyrin complex that was transported into the cell with a heterologous transport system. We improved the diastereoselectivity and product titre of the unnatural product by evolving the ArM and selecting the appropriate gene induction and cultivation conditions. This work shows that synthetic biology and synthetic chemistry can produce, by combining natural and artificial enzymes in whole cells, molecules that were previously inaccessible to nature.