Ward, T.R.

Angew. Chem. Int. Ed. 2008, 47, 701-705, 10.1002/anie.200703159

Palladium in the active site: The incorporation of a biotinylated palladium diphosphine within streptavidin yielded an artificial metalloenzyme for the title reaction (see scheme). Chemogenetic optimization of the catalyst by the introduction of a spacer (red star) between biotin (green triangle) and palladium and saturation mutagenesis at position S112X afforded both R‐ and S‐selective artificial asymmetric allylic alkylases.

Roelfes, G.

Isr. J. Chem. 2015, 55, 21-31, 10.1002/ijch.201400094

Artificial metalloenzymes have emerged as a promising new approach to asymmetric catalysis. In our group, we are exploring novel artificial metalloenzyme designs involving creation of a new active site in a protein or DNA scaffold that does not have an existing binding pocket. In this review, we give an overview of the developments in the two approaches to artificial metalloenzymes for asymmetric catalysis investigated in our group: creation of a novel active site on a peptide or protein dimer interface and using DNA as a scaffold for artificial metalloenzymes.

Roelfes, G.

Curr. Opin. Chem. Biol. 2014, 19, 135-143, 10.1016/j.cbpa.2014.02.002

Artificial metalloenzymes have emerged over the last decades as an attractive approach towards combining homogeneous catalysis and biocatalysis. A wide variety of catalytic transformations have been established by artificial metalloenzymes, thus establishing proof of concept. The field is now slowly transforming to take on new challenges. These include novel designs, novel catalytic reactions, some of which have no equivalent in both homogenous catalysis and biocatalysis and the incorporation of artificial metalloenzymes in chemoenzymatic cascades. Some of these developments represent promising steps towards integrating artificial metalloenzymes in biological systems. This review will focus on advances in this field and perspectives discussed.

Ward, T.R.

J. Am. Chem. Soc. 2003, 125, 9030-9031, 10.1021/ja035545i

Homogeneous and enzymatic catalysis offer complementary means to generate enantiomerically pure compounds. Incorporation of achiral biotinylated rhodium−diphosphine complexes into (strept)avidin yields artificial metalloenzymes for the hydrogenation of N-protected dehydroamino acids. A chemogenetic optimization procedure allows one to produce (R)-acetamidoalanine with 96% enantioselectivity. These hybrid catalysts display features reminiscent both of enzymatic and of homogeneous systems.

Ward, T.R.

Chimia 2008, 62, 956-961, 10.2533/chimia.2008.956

Artificial metalloenzymes, based on the incorporation of a biotinylated catalytically active organometallic moiety within streptavidin, offer an attractive alternative to homogeneous, heterogeneous and enzymatic catalysis. In this account, we outline our recent results and implications in the developments of such artificial metalloenzymes for various asymmetric transformations, including hydrogenation, transfer hydrogenation, allylic alkylation and sulfoxidation.

Ward, T.R.

Top. Organomet. Chem. 2009, 10.1007/3418_2008_3

Artificial metalloenzymes can be created by incorporating an active metal catalyst precursor in a macromolecular host. When considering such artificial metalloenzymes, the first point to address is how to localize the active metal moiety within the protein scaffold. Although a covalent anchoring strategy may seem most attractive at first, supramolecular anchoring strategy has proven most successful thus far. In this context and inspired by Whitesides’ seminal paper, we have exploited the biotin–avidin technology to anchor a biotinylated active metal catalyst precursor within either avidin or streptavidin. A combined chemical and genetic strategy allows a rapid (chemogenetic) optimization of both the activity and the selectivity of the resulting artificial metalloenzymes. The chiral environment, provided by second coordination sphere interactions between the metal and the host protein, can be varied by introduction of a spacer between the biotin anchor and the metal moiety or by variation of the ligand scaffold. Alternatively, mutagenesis of the host protein allows a fine tuning of the activity and the selectivity. With this protocol, we have been able to produce artificial metalloenzymes based on the biotin–avidin technology for the enantioselective hydrogenation of N-protected dehydroaminoacids, the transfer hydrogenation of prochiral ketones as well as the allylic alkylation of symmetric substrates. In all cases selectivities >90% were achieved. Most recently, guided by an X-ray structure of an artificial metalloenzyme, we have extended the chemogenetic optimization to a designed evolution scheme. Designed evolution combines rational design with combinatorial screening. In this chapter, we emphasize the similarities and the differences between artificial metalloenzymes and their homogeneous or enzymatic counterparts.

Ward, T.R.

Chem. - Eur. J. 2005, 11, 3798-3804, 10.1002/chem.200401232

Enzymatic and homogeneous catalysis offer complementary means to produce enantiopure products. Incorporation of achiral, biotinylated aminodiphosphine–rhodium complexes in (strept)avidin affords enantioselective hydrogenation catalysts. A combined chemogenetic procedure allows the optimization of the activity and the selectivity of such artificial metalloenzymes: the reduction of acetamidoacrylate proceeds to produce N‐acetamidoalanine in either 96 % ee (R) or 80 % ee (S). In addition to providing a chiral second coordination sphere and, thus, selectivity to the catalyst, the phenomenon of protein‐accelerated catalysis (e.g., increased activity) was unraveled. Such artificial metalloenzymes based on the biotin–avidin technology display features that are reminiscent of both homogeneous and of enzymatic catalysis.

Ward, T.R.

ChemBioChem 2006, 7, 1845-1852, 10.1002/cbic.200600264

Creating new catalytic function in proteins. Anchoring an organometallic moiety within a protein affords artificial metalloenzymes for enantioselective catalysis. Both chemical and genetic tools can be applied in the optimization of such systems, which lie at the interface between homogeneous and enzymatic catalysis. This minireview presents the latest developments in the field of artificial metalloenzymes.

Ward, T.R.

J. Organomet. Chem. 2004, 689, 4868-4871, 10.1016/j.jorganchem.2004.09.032

We report on the phenomenon of protein-accelerated catalysis in the field of artificial metalloenzymes based on the non-covalent incorporation of biotinylated rhodium–diphosphine complexes in (strept)avidin as host proteins. By incrementally varying the [Rh(COD)(Biot-1)]+ vs. (strept)avidin ratio, we show that the enantiomeric excess of the produced acetamidoalanine decreases slowly. This suggests that the catalyst inside (strept)avidin is more active than the catalyst outside the host protein. Both avidin and streptavidin display protein-accelerated catalysis as the protein embedded catalyst display 12.0- and 3.0-fold acceleration over the background reaction with a catalyst devoid of protein. Thus, these artificial metalloenzymes display an increase both in activity and in selectivity for the reduction of acetamidoacrylic acid.

Klein Gebbink, R.J.M.

Artificial Metalloenzymes and MetalloDNAzymes in Catalysis: From Design to Applications 2018, 171-197, 10.1002/9783527804085.ch6

The development of artificial hydrogenases (AHases) and transfer hydrogenases (ATHases) has played a leading and guiding role for the field of artificial metalloenzymes. Starting from the early studies by Whitesides and coworkers, this chapter showcases the conceptual development of AHases and ATHases, highlighting the different conjugation strategies used for their construction and exemplifying the stereoselective control in product formation that can be reached.

Ward, T.R.

Chem. Commun. 2011, 47, 12065, 10.1039/c1cc15004a

Incorporation of a biotinylated Hoveyda-Grubbs catalyst within (strept)avidin affords artificial metalloenzymes for the ring-closing metathesis of N-tosyl diallylamine in aqueous solution. Optimization of the performance can be achieved either by chemical or genetic means.

Ward, T.R.

Org. Biomol. Chem. 2015, 13, 357-360, 10.1039/c4ob02071e

Stereoselectively labelled isotopomers of NAD(P)H are highly relevant for mechanistic studies of enzymes which utilize them as redox equivalents.

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).

Jeschek, M.

Trends Biotechnol. 2018, 36, 60-72, 10.1016/j.tibtech.2017.10.003

Residing at the interface of chemistry and biotechnology, artificial metalloenzymes (ArMs) offer an attractive technology to combine the versatile reaction repertoire of transition metal catalysts with the exquisite catalytic features of enzymes. While earlier efforts in this field predominantly comprised studies in well-defined test-tube environments, a trend towards exploiting ArMs in more complex environments has recently emerged. Integration of these artificial biocatalysts in enzymatic cascades and using them in whole-cell biotransformations and in vivo opens up entirely novel prospects for both preparative chemistry and synthetic biology. We highlight selected recent developments with a particular focus on challenges and opportunities in the in vivo application of ArMs.

Ward, T.R.

Chem. Soc. Rev. 2005, 34, 337, 10.1039/b314695m

Enantioselective catalysis is one of the most efficient ways to synthesize high-added-value enantiomerically pure organic compounds. As the subtle details which govern enantioselection cannot be reliably predicted or computed, catalysis relies more and more on a combinatorial approach. Biocatalysis offers an attractive, and often complementary, alternative for the synthesis of enantiopure products. From a combinatorial perspective, the potential of directed evolution techniques in optimizing an enzyme's selectivity is unrivaled. In this review, attention is focused on the construction of artificial metalloenzymes for enantioselective catalytic applications. Such systems are shown to combine properties of both homogeneous and enzymatic kingdoms. This review also includes our recent research results and implications in the development of new semisynthetic metalloproteins for the enantioselective hydrogenation of N-protected dehydro-amino acids.

Lewis, J.C.; Ward, T.R.

Chem. Rev. 2018, 118, 142-231, 10.1021/acs.chemrev.7b00014

The incorporation of a synthetic, catalytically competent metallocofactor into a protein scaffold to generate an artificial metalloenzyme (ArM) has been explored since the late 1970’s. Progress in the ensuing years was limited by the tools available for both organometallic synthesis and protein engineering. Advances in both of these areas, combined with increased appreciation of the potential benefits of combining attractive features of both homogeneous catalysis and enzymatic catalysis, led to a resurgence of interest in ArMs starting in the early 2000’s. Perhaps the most intriguing of potential ArM properties is their ability to endow homogeneous catalysts with a genetic memory. Indeed, incorporating a homogeneous catalyst into a genetically encoded scaffold offers the opportunity to improve ArM performance by directed evolution. This capability could, in turn, lead to improvements in ArM efficiency similar to those obtained for natural enzymes, providing systems suitable for practical applications and greater insight into the role of second coordination sphere interactions in organometallic catalysis. Since its renaissance in the early 2000’s, different aspects of artificial metalloenzymes have been extensively reviewed and highlighted. Our intent is to provide a comprehensive overview of all work in the field up to December 2016, organized according to reaction class. Because of the wide range of non-natural reactions catalyzed by ArMs, this was done using a functional-group transformation classification. The review begins with a summary of the proteins and the anchoring strategies used to date for the creation of ArMs, followed by a historical perspective. Then follows a summary of the reactions catalyzed by ArMs and a concluding critical outlook. This analysis allows for comparison of similar reactions catalyzed by ArMs constructed using different metallocofactor anchoring strategies, cofactors, protein scaffolds, and mutagenesis strategies. These data will be used to construct a searchable Web site on ArMs that will be updated regularly by the authors.

Ward, T.R.

J. Am. Chem. Soc. 2004, 126, 14411-14418, 10.1021/ja0476718

We report on the generation of artificial metalloenzymes based on the noncovalent incorporation of biotinylated rhodium−diphosphine complexes in (strept)avidin as host proteins. A chemogenetic optimization procedure allows one to optimize the enantioselectivity for the reduction of acetamidoacrylic acid (up to 96% ee (R) in streptavidin S112G and up to 80% ee (S) in WT avidin). The association constant between a prototypical cationic biotinylated rhodium−diphosphine catalyst precursor and the host proteins was determined at neutral pH:  log Ka = 7.7 for avidin (pI = 10.4) and log Ka = 7.1 for streptavidin (pI = 6.4). It is shown that the optimal operating conditions for the enantioselective reduction are 5 bar at 30 °C with a 1% catalyst loading.

Kamer, P.C.J.

ChemBioChem 2010, 11, 1236-1239, 10.1002/cbic.201000159

Pinning phosphines on proteins: A method for the cysteine‐selective bioconjugation of phosphines has been developed. The photoactive yellow protein has been site‐selectively functionalized with phosphine ligands and phosphine transition metal complexes to afford artificial metalloenzymes that are active in palladium‐catalysed allylic nucleophilic substitution reactions.

Mahy, J.-P.; Ricoux, R.

ChemBioChem 2016, 17, 433-440, 10.1002/cbic.201500445

A new artificial enzyme formed by associating NCS‐3.24 with a copper complex catalyzed the Diels–Alder cyclization of cyclopentadiene with 2‐azachalcone and led to an increase in the formation of the exo‐products. Molecular modeling proposed the preferred relative positioning of both the Trojan horse complex and the two substrates.

Borovik, A.S.; Don Tilley, T.

J. Am. Chem. Soc. 2018, 140, 2739-2742, 10.1021/jacs.7b13052

Artificial metalloproteins (ArMs) containing Co4O4 cubane active sites were constructed via biotin–streptavidin technology. Stabilized by hydrogen bonds (H-bonds), terminal and cofacial CoIII–OH2 moieties are observed crystallographically in a series of immobilized cubane sites. Solution electrochemistry provided correlations of oxidation potential and pH. For variants containing Ser and Phe adjacent to the metallocofactor, 1e–/1H+ chemistry predominates until pH 8, above which the oxidation becomes pH-independent. Installation of Tyr proximal to the Co4O4 active site provided a single H-bond to one of a set of cofacial CoIII–OH2 groups. With this variant, multi-e–/multi-H+ chemistry is observed, along with a change in mechanism at pH 9.5 that is consistent with Tyr deprotonation. With structural similarities to both the oxygen-evolving complex of photosystem II (H-bonded Tyr) and to thin film water oxidation catalysts (Co4O4 core), these findings bridge synthetic and biological systems for water oxidation, highlighting the importance of secondary sphere interactions in mediating multi-e–/multi-H+ reactivity.

Watanabe, Y.

Top. Organomet. Chem. 2009, 10.1007/3418_2008_4

Molecular design of artificial metalloproteins is one of the most attractive subjects in bioinorganic chemistry. Protein vacant space has been utilized to prepare metalloproteins because it provides a unique chemical environment for application to catalysts and to biomaterials bearing electronic, magnetic, and medical properties. Recently, X-ray crystal structural analysis has increased in this research area because it is a powerful tool for understanding the interactions of metal complexes and protein scaffolds, and for providing rational design of these composites. This chapter reviews the recent studies on the preparation methods and X-ray crystal structural analyses of metal/protein composites, and their functions as catalysts, metal-drugs, etc.

Borovik, A.S.; Hendrich, M.P.; Moënne-Loccoz, P.

J. Am. Chem. Soc. 2021, 143, 2384-2393, 10.1021/jacs.0c12564

Dinuclear iron centers with a bridging hydroxido or oxido ligand form active sites within a variety of metalloproteins. A key feature of these sites is the ability of the protein to control the structures around the Fe centers, which leads to entatic states that are essential for function. To simulate this controlled environment, artificial proteins have been engineered using biotin–streptavidin (Sav) technology in which Fe complexes from adjacent subunits can assemble to form [FeIII–(μ-OH)–FeIII] cores. The assembly process is promoted by the site-specific localization of the Fe complexes within a subunit through the designed mutation of a tyrosinate side chain to coordinate the Fe centers. An important outcome is that the Sav host can regulate the Fe···Fe separation, which is known to be important for function in natural metalloproteins. Spectroscopic and structural studies from X-ray diffraction methods revealed uncommonly long Fe···Fe separations that change by less than 0.3 Å upon the binding of additional bridging ligands. The structural constraints imposed by the protein host on the di-Fe cores are unique and create examples of active sites having entatic states within engineered artificial metalloproteins.

Mahy, J.-P.

FEBS Lett. 1996, 395, 73-76, 10.1016/0014-5793(96)01006-X

In order to get catalytic antibodies modelling peroxidases BALB/c mice have been immunized with iron(III)α,α,α,β‐mesotetrakis‐orthocarboxyphenyl‐porphyrin (Fe(ToCPP))‐KLH conjugates. Monoclonal antibodies have been produced by the hybridoma technology. Three antibodies, 2 IgG, and 1 IgG2a, were found to bind both Fe(ToCPP) and the free base ToCPPH2 with similar binding constants. None of those antibodies was found to bind tetraphenylporphyrin. Those results suggest that the recognition of Fe(ToCPP) by the antibodies was mainly due to the binding of the carboxylate groups to some amino acid residues of the protein. True K d values of 2.9 × 10−9 M and 5.5 × 10−9 M have been determined for the two IgG1‐Fe(ToCPP) complexes. Those values are the best ones ever reported for iron‐porphyrin‐antibody complexes. UV‐vis. studies have shown that the two IgG1‐Fe(ToCPP) complexes were highspin hexacoordinate iron(III) complexes, with no amino acid residue binding the iron, whereas the IgG2α‐Fe(ToCPP) complex was a low‐spin hexacoordinate iron(III) complex with two strong ligands binding the iron atom. Both IgG1 ‐Fe(ToCPP) complexes were found to catalyze the oxidation of 2,2′‐azinobis (3ethylbenzothiazoline‐6‐sulfonic acid (ABTS) 5‐fold more efficiently than Fe(ToCPP) alone whereas the binding of IgG2a to this iron‐porphyrin had no effect on its catalytic activity. k cat values of 100 min−1 and 63 min−1 and k cat/K m. values of 105 M−1 s−1 and 119 M−1 s−1 have been found respectively for the two IgG1‐Fe(ToCPP) complexes.

Ward, T.R.

J. Am. Chem. Soc. 2006, 128, 8320-8328, 10.1021/ja061580o

Incorporation of biotinylated racemic three-legged d6-piano stool complexes in streptavidin yields enantioselective transfer hydrogenation artificial metalloenzymes for the reduction of ketones. Having identified the most promising organometallic catalyst precursors in the presence of wild-type streptavidin, fine-tuning of the selectivity is achieved by saturation mutagenesis at position S112. This choice for the genetic optimization site is suggested by docking studies which reveal that this position lies closest to the biotinylated metal upon incorporation into streptavidin. For aromatic ketones, the reaction proceeds smoothly to afford the corresponding enantioenriched alcohols in up to 97% ee (R) or 70% (S). On the basis of these results, we suggest that the enantioselection is mostly dictated by CH/π interactions between the substrate and the η6-bound arene. However, these enantiodiscriminating interactions can be outweighed in the presence of cationic residues at position S112 to afford the opposite enantiomers of the product.

Ward, T.R.

Angew. Chem. Int. Ed. 2011, 50, 3026-3029, 10.1002/anie.201007820

Man‐made activity: Introduction of a biotinylated iridium piano stool complex within streptavidin affords an artificial imine reductase (see scheme). Saturation mutagenesis allowed optimization of the activity and the enantioselectivity of this metalloenzyme, and its X‐ray structure suggests that a nearby lysine residue acts as a proton source during the transfer hydrogenation.

Distefano, M.D.

J. Am. Chem. Soc. 1997, 119, 11643-11652, 10.1021/JA970820K

In an effort to prepare selective and efficient catalysts for ester and amide hydrolysis, we are designing systems that position a coordinated metal ion within a defined protein cavity. Here, the preparation of a protein-1,10-phenanthroline conjugate and the hydrolytic chemistry catalyzed by this construct are described. Iodoacetamido-1,10-phenanthroline was used to modify a unique cysteine residue in ALBP (adipocyte lipid binding protein) to produce the conjugate ALBP-Phen. The resulting material was characterized by electrospray mass spectrometry, UV/vis and fluorescence spectroscopy, gel filtration chromatography, and thiol titration. The stability of ALBP-Phen was evaluated by guanidine hydrochloride denaturation experiments, and the ability of the conjugate to bind Cu(II) was demonstrated by fluorescence spectroscopy. ALBP-Phen-Cu(II) catalyzes the enantioselective hydrolysis of several unactivated amino acid esters under mild conditions (pH 6.1, 25 °C) at rates 32−280-fold above the background rate in buffered aqueous solution. In 24 h incubations 0.70 to 7.6 turnovers were observed with enantiomeric excesses ranging from 31% ee to 86% ee. ALBP-Phen-Cu(II) also promotes the hydrolysis of an aryl amide substrate under more vigorous conditions (pH 6.1, 37 °C) at a rate 1.6 × 104-fold above the background rate. The kinetics of this amide hydrolysis reaction fit the Michaelis−Menten relationship characteristic of enzymatic processes. The rate enhancements for ester and amide hydrolysis reported here are 102−103 lower than those observed for free Cu(II) but comparable to those previously reported for Cu(II) complexes.

Lu, Y.

J. Am. Chem. Soc. 2004, 126, 10812-10813, 10.1021/ja046908x

Introducing nonnative metal ions or metal-containing prosthetic groups into a protein can dramatically expand the repertoire of its functionalities and thus its range of applications. Particularly challenging is the control of substrate-binding and thus reaction selectivity such as enantioselectivity. To meet this challenge, both non-covalent and single-point attachments of metal complexes have been demonstrated previously. Since the protein template did not evolve to bind artificial metal complexes tightly in a single conformation, efforts to restrict conformational freedom by modifying the metal complexes and/or the protein are required to achieve high enantioselectivity using the above two strategies. Here we report a novel site-selective dual anchoring (two-point covalent attachment) strategy to introduce an achiral manganese salen complex (Mn(salen)), into apo sperm whale myoglobin (Mb) with bioconjugation yield close to 100%. The enantioselective excess increases from 0.3% for non-covalent, to 12.3% for single point, and to 51.3% for dual anchoring attachments. The dual anchoring method has the advantage of restricting the conformational freedom of the metal complex in the protein and can be generally applied to protein incorporation of other metal complexes with minimal structural modification to either the metal complex or the protein.

Hartwig, J.F.

J. Am. Chem. Soc. 2022, 144, 883-890, 10.1021/jacs.1c10975

The potential applications afforded by the generation and reactivity of artificial metalloenzymes (ArMs) in microorganisms are vast. We show that a non-pathogenic E. coli strain, Nissle 1917 (EcN), is a suitable host for the creation of ArMs from cytochrome P450s and artificial heme cofactors. An outer-membrane receptor in EcN transports an iridium porphyrin into the cell, and the Ir-CYP119 (CYP119 containing iridium porphyrin) assembled in vivo catalyzes carbene insertions into benzylic C–H bonds enantioselectively and site-selectively. The application of EcN as a whole-cell screening platform eliminates the need for laborious processing procedures, drastically increases the ease and throughput of screening, and accelerates the development of Ir-CYP119 with improved catalytic properties. Studies to identify the transport machinery suggest that a transporter different from the previously assumed ChuA receptor serves to usher the iridium porphyrin into the cytoplasm.

Apfel, U.-P.; Happe, T.; Kurisu, G.

Chem. Sci. 2016, 7, 959-968, 10.1039/C5SC03397G

Crystal structures of semisynthetic [FeFe]-hydrogenases with variations in the [2Fe] cluster show little structural differences despite strong effects on activity.

Bian, H.-D.; Huang, F.-P.

RSC Adv. 2016, 6, 44154-44162, 10.1039/C6RA08153C

Enantioselective oxidation of a series of alkyl aryl sulfides catalyzed by a novel VIV8 cluster is tested in an aqueous medium in the presence of serum albumin. The procedure is simple, environmentally friendly, selective, and highly reactive.