495 publications
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8-Amino-5,6,7,8-tetrahydroquinoline in Iridium(III) Biotinylated Cp* Complex as Artificial Imine Reductase
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New J. Chem. 2018, 42, 18773-18776, 10.1039/C8NJ04558E
The imine reductase formed by the (R)-CAMPY ligand bound to the S112M Sav mutant showed an 83% ee in the asymmetric transfer hydrogenation of 6,7-dimethoxy-1-methyl-3,4-dihydroisoquinoline.
Metal: IrHost protein: Streptavidin (Sav)Anchoring strategy: SupramolecularOptimization: Chemical & geneticNotes: ---
Metal: IrHost protein: Streptavidin (Sav)Anchoring strategy: SupramolecularOptimization: Chemical & geneticNotes: ---
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Abiological Catalysis by Artificial Haem Proteins Containing Noble Metals in Place of Iron
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Nature 2016, 534, 534-537, 10.1038/nature17968
Enzymes that contain metal ions—that is, metalloenzymes—possess the reactivity of a transition metal centre and the potential of molecular evolution to modulate the reactivity and substrate-selectivity of the system1. By exploiting substrate promiscuity and protein engineering, the scope of reactions catalysed by native metalloenzymes has been expanded recently to include abiological transformations2,3. However, this strategy is limited by the inherent reactivity of metal centres in native metalloenzymes. To overcome this limitation, artificial metalloproteins have been created by incorporating complete, noble-metal complexes within proteins lacking native metal sites1,4,5. The interactions of the substrate with the protein in these systems are, however, distinct from those with the native protein because the metal complex occupies the substrate binding site. At the intersection of these approaches lies a third strategy, in which the native metal of a metalloenzyme is replaced with an abiological metal with reactivity different from that of the metal in a native protein6,7,8. This strategy could create artificial enzymes for abiological catalysis within the natural substrate binding site of an enzyme that can be subjected to directed evolution. Here we report the formal replacement of iron in Fe-porphyrin IX (Fe-PIX) proteins with abiological, noble metals to create enzymes that catalyse reactions not catalysed by native Fe-enzymes or other metalloenzymes9,10. In particular, we prepared modified myoglobins containing an Ir(Me) site that catalyse the functionalization of C–H bonds to form C–C bonds by carbene insertion and add carbenes to both β-substituted vinylarenes and unactivated aliphatic α-olefins. We conducted directed evolution of the Ir(Me)-myoglobin and generated mutants that form either enantiomer of the products of C–H insertion and catalyse the enantio- and diastereoselective cyclopropanation of unactivated olefins. The presented method of preparing artificial haem proteins containing abiological metal porphyrins sets the stage for the generation of artificial enzymes from innumerable combinations of PIX-protein scaffolds and unnatural metal cofactors to catalyse a wide range of abiological transformations.
Metal: IrHost protein: Myoglobin (Mb)Anchoring strategy: Metal substitutionOptimization: Chemical & geneticNotes: ---
Metal: IrHost protein: Myoglobin (Mb)Anchoring strategy: Metal substitutionOptimization: Chemical & geneticNotes: ---
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Abiotic reduction of ketones with silanes catalysed by carbonic anhydrase through an enzymatic zinc hydride
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Nat. Chem. 2021, 13, 312-318, 10.1038/s41557-020-00633-7
Enzymatic reactions through mononuclear metal hydrides are unknown in nature, despite the prevalence of such intermediates in the reactions of synthetic transition-metal catalysts. If metalloenzymes could react through abiotic intermediates like these, then the scope of enzyme-catalysed reactions would expand. Here we show that zinc-containing carbonic anhydrase enzymes catalyse hydride transfers from silanes to ketones with high enantioselectivity. We report mechanistic data providing strong evidence that the process involves a mononuclear zinc hydride. This work shows that abiotic silanes can act as reducing equivalents in an enzyme-catalysed process and that monomeric hydrides of electropositive metals, which are typically unstable in protic environments, can be catalytic intermediates in enzymatic processes. Overall, this work bridges a gap between the types of transformation in molecular catalysis and biocatalysis.
Metal: ZnLigand type: Histidine residuesHost protein: Human carbonic anhydrase II (hCAII)Anchoring strategy: NativeOptimization: ChemicalNotes: ---
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A "Broad Spectrum" Carbene Transferase for Synthesis of Chiral α-Trifluoromethylated Organoborons
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ACS Cent. Sci. 2019, 5, 206-208, 10.1021/acscentsci.9b00015
Directed evolution generated an enzyme for the enantioselective synthesis of α-trifluoromethylated organoborons—potentially attractive synthons for fluorinated compounds.
Metal: FeLigand type: PorphyrinHost protein: Cytochrome cAnchoring strategy: NativeOptimization: GeneticNotes: ---
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A Cell-Penetrating Artificial Metalloenzyme Regulates a Gene Switch in a Designer Mammalian Cell
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Nat. Commun. 2018, 9, 10.1038/s41467-018-04440-0
Complementing enzymes in their native environment with either homogeneous or heterogeneous catalysts is challenging due to the sea of functionalities present within a cell. To supplement these efforts, artificial metalloenzymes are drawing attention as they combine attractive features of both homogeneous catalysts and enzymes. Herein we show that such hybrid catalysts consisting of a metal cofactor, a cell-penetrating module, and a protein scaffold are taken up into HEK-293T cells where they catalyze the uncaging of a hormone. This bioorthogonal reaction causes the upregulation of a gene circuit, which in turn leads to the expression of a nanoluc-luciferase. Relying on the biotin–streptavidin technology, variation of the biotinylated ruthenium complex: the biotinylated cell-penetrating poly(disulfide) ratio can be combined with point mutations on streptavidin to optimize the catalytic uncaging of an allyl-carbamate-protected thyroid hormone triiodothyronine. These results demonstrate that artificial metalloenzymes offer highly modular tools to perform bioorthogonal catalysis in live HEK cells.
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A Chaperonin as Protein Nanoreactor for Atom-Transfer Radical Polymerization
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Angew. Chem. Int. Ed. 2014, 53, 1443-1447, 10.1002/anie.201306798
The group II chaperonin thermosome (THS) from the archaea Thermoplasma acidophilum is reported as nanoreactor for atom‐transfer radical polymerization (ATRP). A copper catalyst was entrapped into the THS to confine the polymerization into this protein cage. THS possesses pores that are wide enough to release polymers into solution. The nanoreactor favorably influenced the polymerization of N‐isopropyl acrylamide and poly(ethylene glycol)methylether acrylate. Narrowly dispersed polymers with polydispersity indices (PDIs) down to 1.06 were obtained in the protein nanoreactor, while control reactions with a globular protein–catalyst conjugate only yielded polymers with PDIs above 1.84.
Metal: CuLigand type: N,N,N’,N’-tetraethyldiethylene triamine (TEDETA)Host protein: Thermosome (THS)Anchoring strategy: CovalentOptimization: ---Notes: Non-ROMP
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Achiral Cyclopentadienone Iron Tricarbonyl Complexes Embedded in Streptavidin: An Access to Artificial Iron Hydrogenases and Application in Asymmetric Hydrogenation
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Catal. Lett. 2016, 146, 564-569, 10.1007/s10562-015-1681-6
We report on the synthesis of biotinylated (cyclopentadienone)iron tricarbonyl complexes, the in situ generation of the corresponding streptavidin conjugates and their application in asymmetric hydrogenation of imines and ketones.
Metal: FeHost protein: Streptavidin (Sav)Anchoring strategy: SupramolecularOptimization: ChemicalNotes: ---
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A Clamp-Like Biohybrid Catalyst for DNA Oxidation
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Nat. Chem. 2013, 5, 945-951, 10.1038/NCHEM.1752
In processive catalysis, a catalyst binds to a substrate and remains bound as it performs several consecutive reactions, as exemplified by DNA polymerases. Processivity is essential in nature and is often mediated by a clamp-like structure that physically tethers the catalyst to its (polymeric) template. In the case of the bacteriophage T4 replisome, a dedicated clamp protein acts as a processivity mediator by encircling DNA and subsequently recruiting its polymerase. Here we use this DNA-binding protein to construct a biohybrid catalyst. Conjugation of the clamp protein to a chemical catalyst with sequence-specific oxidation behaviour formed a catalytic clamp that can be loaded onto a DNA plasmid. The catalytic activity of the biohybrid catalyst was visualized using a procedure based on an atomic force microscopy method that detects and spatially locates oxidized sites in DNA. Varying the experimental conditions enabled switching between processive and distributive catalysis and influencing the sliding direction of this rotaxane-like catalyst.
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A Cofactor Approach to Copper-Dependent Catalytic Antibodies
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Proc. Natl. Acad. Sci. U. S. A. 2002, 99, 2648-2653, 10.1073/pnas.052001099
A strategy for the preparation of semisynthetic copper(II)-based catalytic metalloproteins is described in which a metal-binding bis-imidazole cofactor is incorporated into the combining site of the aldolase antibody 38C2. Antibody 38C2 features a large hydrophobic-combining site pocket with a highly nucleophilic lysine residue, LysH93, that can be covalently modified. A comparison of several lactone and anhydride reagents shows that the latter are the most effective and general derivatizing agents for the 38C2 Lys residue. A bis-imidazole anhydride (5) was efficiently prepared from N-methyl imidazole. The 38C2–5-Cu conjugate was prepared by either (i) initial derivatization of 38C2 with 5 followed by metallation with CuCl2, or (ii) precoordination of 5 with CuCl2 followed by conjugation with 38C2. The resulting 38C2–5-Cu conjugate was an active catalyst for the hydrolysis of the coordinating picolinate ester 11, following Michaelis–Menten kinetics [kcat(11) = 2.3 min−1 and Km(11) 2.2 mM] with a rate enhancement [kcat(11)kuncat(11)] of 2.1 × 105. Comparison of the second-order rate constants of the modified 38C2 and the Cu(II)-bis-imidazolyl complex k(6-CuCl2) gives a rate enhancement of 3.5 × 104 in favor of the antibody complex with an effective molarity of 76.7 M, revealing a significant catalytic benefit to the binding of the bis-imidazolyl ligand into 38C2.
Metal: CuLigand type: BisimidazolHost protein: Antibody 38C2Anchoring strategy: CovalentOptimization: GeneticNotes: ---
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Active Site Topology of Artificial Peroxidase-like Hemoproteins Based on Antibodies Constructed from a Specifically Designed Ortho-carboxy-substituted Tetraarylporphyrin
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Eur. J. Biochem. 1998, 257, 121-130, 10.1046/j.1432-1327.1998.2570121.x
The topology of the binding site has been studied for two monoclonal antibodies 13G10 and 14H7, elicited against iron(III)‐α,α,α,β‐meso‐tetrakis(ortho‐carboxyphenyl)porphyrin {α,α,α,β‐Fe[(o‐COOHPh)4‐porphyrin]}, and which exhibit in the presence of this α,α,α,β‐Fe[(o‐COOHPh)4‐porphyrin] cofactor a peroxidase activity. A comparison of the dissociation constants of the complexes of 13G10 and 14H7 with various tetra‐aryl‐substituted porphyrin has shown that : (a) the central iron(III) atom of α,α,α,β‐Fe[(o‐COOHPh)4‐porphyrin] is not recognized by either of the two antibodies; and (b) the ortho‐carboxylate substituents of the meso‐phenyl rings of α,α,α,β‐Fe[(o‐COOHPh)4‐porphyrin] are essential for the recognition of the porphyrin by 13G10 and 14H7. Measurement of the dissociation constants for the complexes of 13G10 and 14H7 with the four atropoisomers of (o‐COOHPh)4‐porphyrinH2 as well as mono‐ and di‐ortho‐carboxyphenyl‐substituted porphyrins suggests that the three carboxylates in the α, α, β position are recognized by both 13G10 and 14H7 with the two in the α, β positions more strongly bound to the antibody protein. Accordingly, the topology of the active site of 13G10 and 14H7 has roughly two‐thirds of the α,α,α,β‐Fe[(o‐COOHPh)4‐porphyrin] cofactor inserted into the binding site of the antibodies, with one of the aryl ring remaining outside. Three of the carboxylates are bound to the protein but no amino acid residue acts as an axial ligand to the iron atom. Chemical modification of lysine, histidine, tryptophan and arginine residues has shown that only modification of arginine residues causes a decrease in both the binding of α,α,α,β‐Fe[(o‐COOHPh)4‐porphyrin] and the peroxidase activity of both antibodies. Consequently, at least one of the carboxylates of the hapten is bound to an arginine residue and no amino acids such as lysine, histidine or tryptophan participate in the catalysis of the heterolytic cleavage of the O‐O bond of H2O2. In addition, the amino acid sequence of both antibodies not only reveals the presence of arginine residues, which could be those involved in the binding of the carboxylates of the hapten, but also the presence of several amino acids in the complementary determining regions which could bind other carboxylates through a network of H bonds.
Metal: FeLigand type: ---Host protein: Antibody 13G10 / 14H7Anchoring strategy: AntibodyOptimization: Chemical & geneticNotes: ---
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Addressable DNA–Myoglobin Photocatalysis
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Chem. - Asian J. 2009, 4, 1064-1069, 10.1002/asia.200900082
A hybrid myoglobin, containing a single‐stranded DNA anchor and a redox‐active ruthenium moiety tethered to the heme center can be used as a photocatalyst. The catalyst can be selectively immobilized on a surface‐bound complementary DNA molecule and thus readily recycled from complex reaction mixtures. This principle may be applied to a range of heme‐dependent enzymes allowing the generation of novel light‐triggered photocatalysts. Photoactivatable myoglobin containing a DNA oligonucleotide as a structural anchor was designed by using the reconstitution of artificial heme moieties containing Ru3+ ions. This semisynthetic DNA–enzyme conjugate was successfully used for the oxidation of peroxidase substrates by using visible light instead of H2O2 for the activation. The DNA anchor was utilized for the immobilization of the enzyme on the surface of magnetic microbeads. Enzyme activity measurements not only indicated undisturbed biofunctionality of the tethered DNA but also enabled magnetic separation‐based enrichment and recycling of the photoactivatable biocatalyst.
Metal: RuLigand type: BipyridineHost protein: Myoglobin (Mb)Anchoring strategy: SupramolecularOptimization: ---Notes: Horse heart myoglobin
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A De Novo‐Designed Artificial Metallopeptide Hydrogenase: Insights into Photochemical Processes and the Role of Protonated Cys
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ChemSusChem 2021, 14, 2237-2246, 10.1002/cssc.202100122
Hydrogenase enzymes produce H2 gas, which can be a potential source of alternative energy. Inspired by the [NiFe] hydrogenases, we report the construction of a de novo-designed artificial hydrogenase (ArH). The ArH is a dimeric coiled coil where two cysteine (Cys) residues are introduced at tandem a/d positions of a heptad to create a tetrathiolato Ni binding site. Spectroscopic studies show that Ni binding significantly stabilizes the peptide producing electronic transitions characteristic of Ni-thiolate proteins. The ArH produces H2 photocatalytically, demonstrating a bell-shaped pH-dependence on activity. Fluorescence lifetimes and transient absorption spectroscopic studies are undertaken to elucidate the nature of pH-dependence, and to monitor the reaction kinetics of the photochemical processes. pH titrations are employed to determine the role of protonated Cys on reactivity. Through combining these results, a fine balance is found between solution acidity and the electron transfer steps. This balance is critical to maximize the production of NiI-peptide and protonation of the NiII−H− intermediate (Ni−R) by a Cys (pKa≈6.4) to produce H2.
Metal: NiLigand type: Amino acidHost protein: Synthetic peptideAnchoring strategy: DativeOptimization: ChemicalNotes: ---
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A De Novo Designed Metalloenzyme for the Hydration of CO2
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Angew. Chem. Int. Ed. 2014, 53, 7900-7903, 10.1002/anie.201404925
Protein design will ultimately allow for the creation of artificial enzymes with novel functions and unprecedented stability. To test our current mastery of nature’s approach to catalysis, a ZnII metalloenzyme was prepared using de novo design. α3DH3 folds into a stable single‐stranded three‐helix bundle and binds ZnII with high affinity using His3O coordination. The resulting metalloenzyme catalyzes the hydration of CO2 better than any small molecule model of carbonic anhydrase and with an efficiency within 1400‐fold of the fastest carbonic anhydrase isoform, CAII, and 11‐fold of CAIII.
Metal: ZnLigand type: Amino acidHost protein: α3D peptideAnchoring strategy: DativeOptimization: Chemical & geneticNotes: kcat/KM ≈ 3.8*104 M-1*s-1
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A Designed Functional Metalloenzyme that Reduces O2 to H2O with Over One Thousand Turnovers
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Angew. Chem. Int. Ed. 2012, 51, 5589-5592, 10.1002/anie.201201981
Rational design of functional enzymes with a high number of turnovers is a challenge, especially those with a complex active site, such as respiratory oxidases. Introducing two His and one Tyr residues into myoglobin resulted in enzymes that reduce O2 to H2O with more than 1000 turnovers (red line, see scheme) and minimal release of reactive oxygen species. The positioning of the Tyr residue is critical for activity.
Metal: CuLigand type: Amino acidHost protein: Myoglobin (Mb)Anchoring strategy: DativeOptimization: Chemical & geneticNotes: Sperm whale myoglobin
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A Designed Heme-[4Fe-4S] Metalloenzyme Catalyzes Sulfite Reduction like the Native Enzyme
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Science 2018, 361, 1098-1101, 10.1126/science.aat8474
Multielectron redox reactions often require multicofactor metalloenzymes to facilitate coupled electron and proton movement, but it is challenging to design artificial enzymes to catalyze these important reactions, owing to their structural and functional complexity. We report a designed heteronuclear heme-[4Fe-4S] cofactor in cytochrome c peroxidase as a structural and functional model of the enzyme sulfite reductase. The initial model exhibits spectroscopic and ligand-binding properties of the native enzyme, and sulfite reduction activity was improved—through rational tuning of the secondary sphere interactions around the [4Fe-4S] and the substrate-binding sites—to be close to that of the native enzyme. By offering insight into the requirements for a demanding six-electron, seven-proton reaction that has so far eluded synthetic catalysts, this study provides strategies for designing highly functional multicofactor artificial enzymes.
Metal: FeHost protein: Cytochrome c peroxidaseAnchoring strategy: DativeOptimization: Chemical & geneticNotes: Designed heteronuclear heme-[4Fe-4S] cofactor in cytochrome c peroxidase
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A Designed Metalloenzyme Achieving the Catalytic Rate of a Native Enzyme
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J. Am. Chem. Soc. 2015, 137, 11570-11573, 10.1021/jacs.5b07119
Terminal oxidases catalyze four-electron reduction of oxygen to water, and the energy harvested is utilized to drive the synthesis of adenosine triphosphate. While much effort has been made to design a catalyst mimicking the function of terminal oxidases, most biomimetic catalysts have much lower activity than native oxidases. Herein we report a designed oxidase in myoglobin with an O2 reduction rate (52 s–1) comparable to that of a native cytochrome (cyt) cbb3 oxidase (50 s–1) under identical conditions. We achieved this goal by engineering more favorable electrostatic interactions between a functional oxidase model designed in sperm whale myoglobin and its native redox partner, cyt b5, resulting in a 400-fold electron transfer (ET) rate enhancement. Achieving high activity equivalent to that of native enzymes in a designed metalloenzyme offers deeper insight into the roles of tunable processes such as ET in oxidase activity and enzymatic function and may extend into applications such as more efficient oxygen reduction reaction catalysts for biofuel cells.
Metal: CuLigand type: Amino acidHost protein: Myoglobin (Mb)Anchoring strategy: DativeOptimization: GeneticNotes: O2 reduction rates of 52 s-1 were achieved in combination with the native redox partner cyt b5.
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A Designed Supramolecular Protein Assembly with In Vivo Enzymatic Activity
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Science 2014, 346, 1525-1528, 10.1126/science.1259680
The generation of new enzymatic activities has mainly relied on repurposing the interiors of preexisting protein folds because of the challenge in designing functional, three-dimensional protein structures from first principles. Here we report an artificial metallo-β-lactamase, constructed via the self-assembly of a structurally and functionally unrelated, monomeric redox protein into a tetrameric assembly that possesses catalytic zinc sites in its interfaces. The designed metallo-β-lactamase is functional in the Escherichia coli periplasm and enables the bacteria to survive treatment with ampicillin. In vivo screening of libraries has yielded a variant that displays a catalytic proficiency [(kcat/Km)/kuncat] for ampicillin hydrolysis of 2.3 × 106 and features the emergence of a highly mobile loop near the active site, a key component of natural β-lactamases to enable substrate interactions.
Metal: ZnLigand type: Amino acidHost protein: Cytochrome cb562Anchoring strategy: DativeOptimization: GeneticNotes: ---
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A Dual Anchoring Strategy for the Localization and Activation of Artificial Metalloenzymes Based on the Biotin−Streptavidin Technology
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J. Am. Chem. Soc. 2013, 135, 5384-5388, 10.1021/ja309974s
Artificial metalloenzymes result from anchoring an active catalyst within a protein environment. Toward this goal, various localization strategies have been pursued: covalent, supramolecular, or dative anchoring. Herein we show that introduction of a suitably positioned histidine residue contributes to firmly anchor, via a dative bond, a biotinylated rhodium piano stool complex within streptavidin. The in silico design of the artificial metalloenzyme was confirmed by X-ray crystallography. The resulting artificial metalloenzyme displays significantly improved catalytic performance, both in terms of activity and selectivity in the transfer hydrogenation of imines. Depending on the position of the histidine residue, both enantiomers of the salsolidine product can be obtained.
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A General Method for Artificial Metalloenzyme Formationthrough Strain-Promoted Azide–Alkyne Cycloaddition
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ChemBioChem 2014, 15, 223-227, 10.1002/cbic.201300661
Strain‐promoted azide–alkyne cycloaddition (SPAAC) can be used to generate artificial metalloenzymes (ArMs) from scaffold proteins containing a p‐azido‐L‐phenylalanine (Az) residue and catalytically active bicyclononyne‐substituted metal complexes. The high efficiency of this reaction allows rapid ArM formation when using Az residues within the scaffold protein in the presence of cysteine residues or various reactive components of cellular lysate. In general, cofactor‐based ArM formation allows the use of any desired metal complex to build unique inorganic protein materials. SPAAC covalent linkage further decouples the native function of the scaffold from the installation process because it is not affected by native amino acid residues; as long as an Az residue can be incorporated, an ArM can be generated. We have demonstrated the scope of this method with respect to both the scaffold and cofactor components and established that the dirhodium ArMs generated can catalyze the decomposition of diazo compounds and both SiH and olefin insertion reactions involving these carbene precursors.
Metal: RhLigand type: Poly-carboxylic acidHost protein: tHisFAnchoring strategy: CovalentOptimization: ---Notes: ---
Metal: RhLigand type: Poly-carboxylic acidHost protein: tHisFAnchoring strategy: CovalentOptimization: ---Notes: ---
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A Highly Active Biohybrid Catalyst for Olefin Metathesis in Water: Impact of a Hydrophobic Cavity in a β-Barrel Protein
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ACS Catal. 2015, 5, 7519-7522, 10.1021/acscatal.5b01792
A series of Grubbs–Hoveyda type catalyst precursors for olefin metathesis containing a maleimide moiety in the backbone of the NHC ligand was covalently incorporated in the cavity of the β-barrel protein nitrobindin. By using two protein mutants with different cavity sizes and choosing the suitable spacer length, an artificial metalloenzyme for olefin metathesis reactions in water in the absence of any organic cosolvents was obtained. High efficiencies reaching TON > 9000 in the ROMP of a water-soluble 7-oxanorbornene derivative and TON > 100 in ring-closing metathesis (RCM) of 4,4-bis(hydroxymethyl)-1,6-heptadiene in water under relatively mild conditions (pH 6, T = 25–40 °C) were observed.
Metal: RuLigand type: CarbeneHost protein: Nitrobindin (Nb)Anchoring strategy: CovalentOptimization: ChemicalNotes: ROMP (cis/trans: 48/52)
Metal: RuLigand type: CarbeneHost protein: Nitrobindin (Nb)Anchoring strategy: CovalentOptimization: ChemicalNotes: RCM
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A Highly Specific Metal-Activated Catalytic Antibody
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J. Am. Chem. Soc. 1993, 115, 4906-4907, 10.1021/ja00064a068
n/a
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A Hybrid Ring- Opening Metathesis Polymerization Catalyst Based on an Engineered Variant of the Beta-Barrel Protein FhuA
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Chem. - Eur. J. 2013, 19, 13865-13871, 10.1002/chem.201301515
A β‐barrel protein hybrid catalyst was prepared by covalently anchoring a Grubbs–Hoveyda type olefin metathesis catalyst at a single accessible cysteine amino acid in the barrel interior of a variant of β‐barrel transmembrane protein ferric hydroxamate uptake protein component A (FhuA). Activity of this hybrid catalyst type was demonstrated by ring‐opening metathesis polymerization of a 7‐oxanorbornene derivative in aqueous solution.
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A Hydrogenase Model System Based on the Sequence of Cytochrome c: Photochemical Hydrogen Evolution in Aqueous Media
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Chem. Commun. 2011, 47, 8229, 10.1039/c1cc11157d
The diiron carbonyl cluster is held by a native CXXC motif, which includes Cys14 and Cys17, in the cytochrome c sequence. It is found that the diiron carbonyl complex works well as a catalyst for H2 evolution. It has a TON of ∼80 over 2 h at pH 4.7 in the presence of a Ru-photosensitizer and ascorbate as a sacrificial reagent in aqueous media.
Metal: FeLigand type: CarbonylHost protein: Cytochrome cAnchoring strategy: DativeOptimization: ---Notes: Horse heart cytochrome C
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A Hydroxyquinoline‐Based Unnatural Amino Acid for the Design of Novel Artificial Metalloenzymes
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ChemBioChem 2020, 21, 3077-3081, 10.1002/cbic.202000306
We have examined the potential of the noncanonical amino acid (8-hydroxyquinolin-3-yl)alanine (HQAla) for the design of artificial metalloenzymes. HQAla, a versatile chelator of late transition metals, was introduced into the lactococcal multidrug-resistance regulator (LmrR) by stop codon suppression methodology. LmrR_HQAla was shown to complex efficiently with three different metal ions, CuII, ZnII and RhIII to form unique artificial metalloenzymes. The catalytic potential of the CuII-bound LmrR_HQAla enzyme was shown through its ability to catalyse asymmetric Friedel-Craft alkylation and water addition, whereas the ZnII-coupled enzyme was shown to mimic natural Zn hydrolase activity.
Metal: CuLigand type: HydroxyquinolineHost protein: Lactoccal multidrug resistant regulator (LmrR)Anchoring strategy: SupramolecularOptimization: GeneticNotes: Also used Rh, but no reaction detected.
Metal: CuLigand type: HydroxyquinolineHost protein: Lactoccal multidrug resistant regulator (LmrR)Anchoring strategy: SupramolecularOptimization: GeneticNotes: ---
Metal: ZnLigand type: HydroxyquinolineHost protein: Lactoccal multidrug resistant regulator (LmrR)Anchoring strategy: SupramolecularOptimization: GeneticNotes: ---
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Albumin as a Promiscuous Biocatalyst in Organic Synthesis
Review -
RSC Adv. 2015, 5, 10588-10598, 10.1039/C4RA11206G
Albumin emerged as a biocatalyst in 1980 and the continuing interest in this protein is proved by numerous papers.
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Albumin-Conjugated Corrole Metal Complexes: Extremely Simple Yet Very Efficient Biomimetic Oxidation Systems
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J. Am. Chem. Soc. 2005, 127, 2883-2887, 10.1021/ja045372c
An extremely simple biomimetic oxidation system, consisting of mixing metal complexes of amphiphilic corroles with serum albumins, utilizes hydrogen peroxide for asymmetric sulfoxidation in up to 74% ee. The albumin-conjugated manganese corroles also display catalase-like activity, and mechanistic evidence points toward oxidant-coordinated manganese(III) as the prime reaction intermediate.
Metal: MnLigand type: CorroleHost protein: Bovine serum albumin (BSA)Anchoring strategy: SupramolecularOptimization: Chemical & geneticNotes: ---
Metal: MnLigand type: CorroleHost protein: Bovine serum albumin (BSA)Anchoring strategy: SupramolecularOptimization: Chemical & geneticNotes: ---
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Allosteric Cooperation in a De Novo-Designed Two-Domain Protein
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Proc. Natl. Acad. Sci. U.S.A. 2020, 117, 33246-33253, 10.1073/pnas.2017062117
We describe the de novo design of an allosterically regulated protein, which comprises two tightly coupled domains. One domain is based on the DF (Due Ferri in Italian or two-iron in English) family of de novo proteins, which have a diiron cofactor that catalyzes a phenol oxidase reaction, while the second domain is based on PS1 (Porphyrin-binding Sequence), which binds a synthetic Zn-porphyrin (ZnP). The binding of ZnP to the original PS1 protein induces changes in structure and dynamics, which we expected to influence the catalytic rate of a fused DF domain when appropriately coupled. Both DF and PS1 are four-helix bundles, but they have distinct bundle architectures. To achieve tight coupling between the domains, they were connected by four helical linkers using a computational method to discover the most designable connections capable of spanning the two architectures. The resulting protein, DFP1 (Due Ferri Porphyrin), bound the two cofactors in the expected manner. The crystal structure of fully reconstituted DFP1 was also in excellent agreement with the design, and it showed the ZnP cofactor bound over 12 Å from the dimetal center. Next, a substrate-binding cleft leading to the diiron center was introduced into DFP1. The resulting protein acts as an allosterically modulated phenol oxidase. Its Michaelis–Menten parameters were strongly affected by the binding of ZnP, resulting in a fourfold tighter Km and a 7-fold decrease in kcat. These studies establish the feasibility of designing allosterically regulated catalytic proteins, entirely from scratch.
Notes: diFe-DFP3: Km 2.9 mM, kcat 0.7 min-1, 10 turnovers for 1 mM substrate, 20 uM protein. On binding ZnP, Km decreased 4x, and kcat decreased 7x, resulting in a lower kcat/Km overall.
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Alteration of the Oxygen-Dependent Reactivity of De Novo Due Ferri Proteins
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Nat. Chem. 2012, 4, 900-906, 10.1038/NCHEM.1454
De novo proteins provide a unique opportunity to investigate the structure–function relationships of metalloproteins in a minimal, well-defined and controlled scaffold. Here, we describe the rational programming of function in a de novo designed di-iron carboxylate protein from the Due Ferri family. Originally created to catalyse the O2-dependent, two-electron oxidation of hydroquinones, the protein was reprogrammed to catalyse the selective N-hydroxylation of arylamines by remodelling the substrate access cavity and introducing a critical third His ligand to the metal-binding cavity. Additional second- and third-shell modifications were required to stabilize the His ligand in the core of the protein. These structural changes resulted in at least a 106-fold increase in the relative rate between the arylamine N-hydroxylation and hydroquinone oxidation reactions. This result highlights the potential for using de novo proteins as scaffolds for future investigations of the geometric and electronic factors that influence the catalytic tuning of di-iron active sites.
Metal: FeLigand type: Amino acidHost protein: Due FerriAnchoring strategy: DativeOptimization: GeneticNotes: ---
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Alternative Strategy to Obtain Artificial Imine Reductase by Exploiting Vancomycin/D-Ala-D-Ala Interactions with an Iridium Metal Complex
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Inorg. Chem. 2021, 60, 2976-2982, 10.1021/acs.inorgchem.0c02969
Based on the supramolecular interaction between vancomycin (Van), an antibiotic glycopeptide, and D-Ala-D-Ala (DADA) dipeptides, a novel class of artificial metalloenzymes was synthesized and characterized. The presence of an iridium(III) ligand at the N-terminus of DADA allowed the use of the metalloenzyme as a catalyst in the asymmetric transfer hydrogenation of cyclic imines. In particular, the type of link between DADA and the metal-chelating moiety was found to be fundamental for inducing asymmetry in the reaction outcome, as highlighted by both computational studies and catalytic results. Using the [IrCp*(m-I)Cl]Cl ⊂ Van complex in 0.1 M CH3COONa buffer at pH 5, a significant 70% (S) e.e. was obtained in the reduction of quinaldine B.
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A Mechanistic Rationale Approach Revealed the Unexpected Chemoselectivity of an Artificial Ru-Dependent Oxidase: A Dual Experimental/Theoretical Approach
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ACS Catal. 2020, 10, 5631-5645, 10.1021/acscatal.9b04904
Artificial enzymes represent an attractive alternative to design abiotic biocatalysis. EcNikA-Ru1, an artificial metalloenzyme developed by embedding a ruthenium-based catalyst into the cavity of the periplasmic nickel-binding protein NikA, was found to efficiently and selectively transform certain alkenes. The objective of this study was to provide a rationale on the enzymatic function and the unexpected substrate-dependent chemoselectivity of EcNikA-Ru1 thanks to a dual experimental/computational study. We observed that the de novo active site allows the formation of the terminal oxidant via the formation of a ruthenium aquo species that subsequently reacts with the hypervalent iodine of phenyl iodide diacetic acid. The oxidation process relies on a RuIV═O pathway via a two-step reaction with a radical intermediate, resulting in the formation of either a chlorohydrin or an epoxide. The results emphasize the impact of the protein scaffold on the kinetics of the reaction, through (i) the promotion of the starting oxidizing species via the exchange of a CO ligand with a water molecule; and (ii) the control of the substrate orientation on the intermediate structures, formed after the RuIV═O attack. When a Cα attack is preferred, chlorohydrins are formed while an attack on Cβ leads to an epoxide. This work provides evidence that artificial enzymes mimic the behavior of their natural counterparts.
Metal: RuLigand type: PyrazoleHost protein: NikAAnchoring strategy: Hydrogen bondOptimization: Chemical & computational designNotes: ---