How to Build a Metalloenzyme: Lessons from a Protein-Based Model of Acetyl Coenzyme A Synthase.

"What I cannot create, I do not understand"─Richard Feynman. This sentiment motivates the entire field of artificial metalloenzymes. Naturally occurring enzymes catalyze reactions with efficiencies, rates, and selectivity that generally cannot be achieved in synthetic systems. Many of these processes represent vital building blocks for a sustainable society, including CO2 conversion, nitrogen fixation, water oxidation, and liquid fuel synthesis. Our inability as chemists to fully reproduce the functionality of naturally occurring enzymes implicates yet-unknown contributors to reactivity. To identify these properties, it is necessary to consider all of the components of naturally occurring metalloenzymes, from the active site metal(s) to large-scale dynamics. In this Account, we describe the holistic development of a metalloprotein-based model that functionally reproduces the acetyl coenzyme A synthase (ACS) enzyme.ACS catalyzes the synthesis of a thioester, acetyl coenzyme A, from gaseous carbon monoxide, a methyl group donated by a cobalt corrinoid protein, and coenzyme A. The active site of ACS contains a bimetallic nickel site coupled to a [4Fe-4S] cluster. This reaction mimics Monsanto's acetic acid synthesis and represents an ancient process for incorporating inorganic carbon into cellular biomass through the primordial Wood-Ljungdahl metabolic pathway. From a sustainability standpoint, the reversible conversion of C1 substrates into an acetyl group and selective downstream transfer to a thiolate nucleophile offer opportunities to expand this reactivity to the anthropogenic synthesis of liquid fuels. However, substantial gaps in our understanding of the ACS catalytic mechanism coupled with the enzyme's oxygen sensitivity and general instability have limited these applications. It is our hope that development of an artificial metalloenzyme that carries out ACS-like reactions will advance our mechanistic understanding and enable synthesis of robust compounds with the capacity for similar reactivity.To construct this model, we first focused on the catalytic proximal nickel (NiP) site, which has a single metal center bound by three bridging cysteine residues in a "Y"-shaped arrangement. With an initial emphasis on reproducing the general structure of a low-coordinate metal binding site, the type I cupredoxin, azurin, was selected as the protein scaffold, and a nickel center was incorporated into the mononuclear site. Using numerous spectroscopic and computational techniques, including electron paramagnetic resonance (EPR) spectroscopy, nickel-substituted azurin was shown to have similar electronic and geometric structures to the NiP center in ACS. A substrate access channel was installed, and both carbon monoxide and a methyl group were shown to bind individually to the reduced NiI center. The elusive EPR-active S = 1/2 Ni-CH3 species, which has never been detected in native ACS, was observed in the azurin-based model, establishing the capacity of a biological NiI species to support two-electron organometallic reactions. Pulsed EPR studies on the S = 1/2 Ni-CH3 species in azurin suggested a noncanonical electronic structure with an inverted ligand field, which was proposed to prevent irreversible site degradation. This model azurin protein was ultimately shown to perform carbon-carbon and carbon-sulfur bond formation using sequential, ordered substrate addition for selective, stoichiometric thioester synthesis. X-ray spectroscopic methods were used to provide characterization of the remaining catalytic intermediates, resolving some debate over key mechanistic details.The overall approach and strategies that we employed for the successful construction of a functional protein-based model of ACS are described in this Account. We anticipate that these principles can be adapted across diverse metalloenzyme classes, providing essential mechanistic details and guiding the development of next-generation, functional artificial metalloenzymes.

Thioester synthesis by a designed nickel enzyme models prebiotic energy conversion.

The formation of carbon-carbon bonds from prebiotic precursors such as carbon dioxide represents the foundation of all primordial life processes. In extant organisms, this reaction is carried out by the carbon monoxide dehydrogenase (CODH)/acetyl coenzyme A synthase (ACS) enzyme, which performs the cornerstone reaction in the ancient Wood-Ljungdahl metabolic pathway to synthesize the key biological metabolite, acetyl-CoA. Despite its significance, a fundamental understanding of this transformation is lacking, hampering efforts to harness analogous chemistry. To address these knowledge gaps, we have designed an artificial metalloenzyme within the azurin protein scaffold as a structural, functional, and mechanistic model of ACS. We demonstrate the intermediacy of the NiI species and requirement for ordered substrate binding in the bioorganometallic carbon-carbon bond-forming reaction from the one-carbon ACS substrates. The electronic and geometric structures of the nickel-acetyl intermediate have been characterized using time-resolved optical, electron paramagnetic resonance, and X-ray absorption spectroscopy in conjunction with quantum chemical calculations. Moreover, we demonstrate that the nickel-acetyl species is chemically competent for selective acyl transfer upon thiol addition to biosynthesize an activated thioester. Drawing an analogy to the native enzyme, a mechanism for thioester generation by this ACS model has been proposed. The fundamental insight into the enzymatic process provided by this rudimentary ACS model has implications for the evolution of primitive ACS-like proteins. Ultimately, these findings offer strategies for development of highly active catalysts for sustainable generation of liquid fuels from one-carbon substrates, with potential for broad applications across diverse fields ranging from energy storage to environmental remediation.

Controlling the Direction of S-Nitrosation versus Denitrosation: Reversible Cleavage and Formation of an S-N Bond within a Dicopper Center.

Iron and copper enzymes are known to promote reversible S-nitrosation/denitrosation in biology. However, it is unclear how the direction of S-N bond formation/scission is controlled. Herein, we demonstrate the interconversion of metal-S-nitrosothiol adduct M(RSNO) and metal nitrosyl thiolate complex M(NO)(SR), which may regulate the direction of reversible S-(de)nitrosation. Treatment of a dicopper(I,I) complex with RSNO leads to a mixture of two structural isomers: dicopper(I,I) S-nitrosothiol [CuICuI(RSNO)]2+ and dicopper(II,II) nitrosyl thiolate [CuIICuII(NO)(SR)]2+. The Keq between these two structural isomers is sensitive to temperature, the solvent coordination ability, and counterions. Our study illustrates how copper centers can modulate the direction of RS-NO bond formation and cleavage through a minor perturbation of the local environment.