12 publications
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Artificial Metalloenzymes for Enantioselective Catalysis: Recent Advances
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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.
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Artificial Transfer Hydrogenases Based on the Biotin-(Strept)avidin Technology: Fine Tuning the Selectivity by Saturation Mutagenesis of the Host Protein
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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.
Metal: IrHost protein: Streptavidin (Sav)Anchoring strategy: SupramolecularOptimization: Chemical & geneticNotes: ---
Metal: RhHost protein: Streptavidin (Sav)Anchoring strategy: SupramolecularOptimization: Chemical & geneticNotes: ---
Metal: RuHost protein: Streptavidin (Sav)Anchoring strategy: SupramolecularOptimization: Chemical & geneticNotes: ---
Metal: RuHost protein: Streptavidin (Sav)Anchoring strategy: SupramolecularOptimization: Chemical & geneticNotes: ---
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Asymmetric Hydrogenation with Antibody-Achiral Rhodium Complex
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Org. Biomol. Chem. 2006, 4, 3571, 10.1039/B609242J
Monoclonal antibodies have been elicited against an achiral rhodium complex and this complex was used in the presence of a resultant antibody, 1G8, for the catalytic hydrogenation of 2-acetamidoacrylic acid to produce N-acetyl-L-alanine in high (>98%) enantiomeric excess.
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Catalytic Reduction of NO to N2O by a Designed Heme Copper Center in Myoglobin: Implications for the Role of Metal Ions
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J. Am. Chem. Soc. 2006, 128, 6766-6767, 10.1021/ja058822p
The effects of metal ions on the reduction of nitric oxide (NO) with a designed heme copper center in myoglobin (F43H/L29H sperm whale Mb, CuBMb) were investigated under reducing anaerobic conditions using UV−vis and EPR spectroscopic techniques as well as GC/MS. In the presence of Cu(I), catalytic reduction of NO to N2O by CuBMb was observed with turnover number of 2 mol NO·mol CuBMb-1·min-1, close to 3 mol NO·mol enzyme-1·min-1 reported for the ba3 oxidases from T. thermophilus. Formation of a His-heme-NO species was detected by UV−vis and EPR spectroscopy. In comparison to the EPR spectra of ferrous-CuBMb-NO in the absence of metal ions, the EPR spectra of ferrous-CuBMb-NO in the presence of Cu(I) showed less-resolved hyperfine splitting from the proximal histidine, probably due to weakening of the proximal His-heme bond. In the presence of Zn(II), formation of a five-coordinate ferrous-CuBMb-NO species, resulting from cleavage of the proximal heme Fe-His bond, was shown by UV−vis and EPR spectroscopic studies. The reduction of NO to N2O was not observed in the presence of Zn(II). Control experiments using wild-type myoglobin indicated no reduction of NO in the presence of either Cu(I) or Zn(II). These results suggest that both the identity and the oxidation state of the metal ion in the CuB center are important for NO reduction. A redox-active metal ion is required to deliver electrons, and a higher oxidation state is preferred to weaken the heme iron−proximal histidine toward a five-coordinate key intermediate in NO reduction.
Notes: Sperm whale myoglobin
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Copper–Phthalocyanine Conjugates of Serum Albumins as Enantioselective Catalysts in Diels–Alder Reactions
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Angew. Chem. Int. Ed. 2006, 45, 2416-2419, 10.1002/anie.200504561
Chirality from blood: Serum albumins form strong complexes with CuII–phthalocyanines, leading to protein conjugates. These hybrid catalysts promote enantioselective Diels–Alder reactions, such as that of azachalcones 1 with cyclopentadiene (2) to give products 3 with 85–98 % ee.
Metal: CuLigand type: PhthalocyanineHost protein: Bovine serum albumin (BSA)Anchoring strategy: SupramolecularOptimization: ChemicalNotes: Chirality from blood: Serum albumins form strong complexes with CuII–phthalocyanines, leading to protein conjugates. These hybrid catalysts promote enantioselective Diels–Alder reactions, such as that of azachalcones 1 with cyclopentadiene (2) to give products 3 with 85–98 % ee.
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Crystal Structure and Peroxidase Activity of Myoglobin Reconstituted with Iron Porphycene
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Inorg. Chem. 2006, 45, 10530-10536, 10.1021/ic061130x
The incorporation of an artificially created metal complex into an apomyoglobin is one of the attractive methods in a series of hemoprotein modifications. Single crystals of sperm whale myoglobin reconstituted with 13,16-dicarboxyethyl-2,7-diethyl-3,6,12,17-tetramethylporphycenatoiron(III) were obtained in the imidazole buffer, and the 3D structure with a 2.25-Å resolution indicates that the iron porphycene, a structural isomer of hemin, is located in the normal position of the heme pocket. Furthermore, it was found that the reconstituted myoglobin catalyzed the H2O2-dependent oxidations of substrates such as guaiacol, thioanisole, and styrene. At pH 7.0 and 20 °C, the initial rate of the guaiacol oxidation is 11-fold faster than that observed for the native myoglobin. Moreover, the stopped-flow analysis of the reaction of the reconstituted protein with H2O2 suggested the formation of two reaction intermediates, compounds II- and III-like species, in the absence of a substrate. It is a rare example that compound III is formed via compound II in myoglobin chemistry. The enhancement of the peroxidase activity and the formation of the stable compound III in myoglobin with iron porphycene mainly arise from the strong coordination of the Fe−His93 bond.
Metal: FeLigand type: PorphyceneHost protein: Myoglobin (Mb)Anchoring strategy: ReconstitutionOptimization: ---Notes: ---
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Design and Evolution of New Catalytic Activity with an Existing Protein Scaffold
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Science 2006, 311, 535-538, 10.1126/science.1118953
The design of enzymes with new functions and properties has long been a goal in protein engineering. Here, we report a strategy to change the catalytic activity of an existing protein scaffold. This was achieved by simultaneous incorporation and adjustment of functional elements through insertion, deletion, and substitution of several active site loops, followed by point mutations to fine-tune the activity. Using this approach, we were able to introduce β-lactamase activity into the αβ/βα metallohydrolase scaffold of glyoxalase II. The resulting enzyme, evMBL8 (evolved metallo β-lactamase 8), completely lost its original activity and, instead, catalyzed the hydrolysis of cefotaxime with a (kcat /Km)app of 1.8 × 102 (mole/liter)–1 second–1, thus increasing resistance to Escherichia coli growth on cefotaxime by a factor of about 100.
Metal: ZnLigand type: Amino acidHost protein: Glyoxalase II (Human)Anchoring strategy: DativeOptimization: GeneticNotes: kcat/KM ≈ 184 M-1*s-1
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Designer Zinc Finger Proteins: Tools for Creating Artificial DNA-Binding Functional Proteins
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Acc. Chem. Res. 2006, 39, 45-52, 10.1021/ar050158u
The design of artificial functional DNA-binding proteins has long been a goal for several research laboratories. The zinc finger proteins, which typically contain many fingers linked in tandem fashion, are some of the most studied DNA-binding proteins. The zinc finger protein's tandem arrangement and its the ability to recognize a wide variety of DNA sequences make it an attractive framework to design novel DNA-binding peptides/proteins. Our laboratory has utilized several design strategies to create novel zinc finger peptides by re-engineering the C2H2-type zinc finger motif of transcription factor Sp1. Some of the engineered zinc fingers have shown nuclease and catalytic functional properties. Based on these results, we present the design strategies for the creation of novel zinc fingers.
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Design of Metal Cofactors Activated by a Protein–Protein Electron Transfer System
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Proc. Natl. Acad. Sci. U. S. A. 2006, 103, 9416-9421, 10.1073/pnas.0510968103
Protein-to-protein electron transfer (ET) is a critical process in biological chemistry for which fundamental understanding is expected to provide a wealth of applications in biotechnology. Investigations of protein–protein ET systems in reductive activation of artificial cofactors introduced into proteins remains particularly challenging because of the complexity of interactions between the cofactor and the system contributing to ET. In this work, we construct an artificial protein–protein ET system, using heme oxygenase (HO), which is known to catalyze the conversion of heme to biliverdin. HO uses electrons provided from NADPH/cytochrome P450 reductase (CPR) through protein–protein complex formation during the enzymatic reaction. We report that a FeIII(Schiff-base), in the place of the active-site heme prosthetic group of HO, can be reduced by NADPH/CPR. The crystal structure of the Fe(10-CH2CH2COOH-Schiff-base)·HO composite indicates the presence of a hydrogen bond between the propionic acid carboxyl group and Arg-177 of HO. Furthermore, the ET rate from NADPH/CPR to the composite is 3.5-fold faster than that of Fe(Schiff-base)·HO, although the redox potential of Fe(10-CH2CH2COOH-Schiff-base)·HO (−79 mV vs. NHE) is lower than that of Fe(Schiff-base)·HO (+15 mV vs. NHE), where NHE is normal hydrogen electrode. This work describes a synthetic metal complex activated by means of a protein–protein ET system, which has not previously been reported. Moreover, the result suggests the importance of the hydrogen bond for the ET reaction of HO. Our Fe(Schiff-base)·HO composite model system may provide insights with regard to design of ET biosystems for sensors, catalysts, and electronics devices.
Metal: FeLigand type: SalophenHost protein: Heme oxygenase (HO)Anchoring strategy: ReconstitutionOptimization: ChemicalNotes: ---
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Directed Evolution of Hybrid Enzymes: Evolving Enantioselectivity of an Achiral Rh-Complex Anchored to a Protein
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Chem. Commun. 2006, 4318, 10.1039/b610461d
The concept of utilizing the methods of directed evolution for tuning the enantioselectivity of synthetic achiral metal–ligand centers anchored to proteins has been implemented experimentally for the first time.
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Manganese-Substituted Carbonic Anhydrase as a New Peroxidase
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Chem. - Eur. J. 2006, 12, 1587-1596, 10.1002/chem.200501413
Carbonic anhydrase is a zinc metalloenzyme that catalyzes the hydration of carbon dioxide to bicarbonate. Replacing the active‐site zinc with manganese yielded manganese‐substituted carbonic anhydrase (CA[Mn]), which shows peroxidase activity with a bicarbonate‐dependent mechanism. In the presence of bicarbonate and hydrogen peroxide, (CA[Mn]) catalyzed the efficient oxidation of o‐dianisidine with kcat/KM=1.4×106 m−1 s−1, which is comparable to that for horseradish peroxidase, kcat/KM=57×106 m−1 s−1. CA[Mn] also catalyzed the moderately enantioselective epoxidation of olefins to epoxides (E=5 for p‐chlorostyrene) in the presence of an amino‐alcohol buffer, such as N,N‐bis(2‐hydroxyethyl)‐2‐aminoethanesulfonic acid (BES). This enantioselectivity is similar to that for natural heme‐based peroxidases, but has the advantage that CA[Mn] avoids the formation of aldehyde side products. CA[Mn] degrades during the epoxidation limiting the yield of the epoxidations to <12 %. Replacement of active‐site residues Asn62, His64, Asn67, Gln92, or Thr200 with alanine by site‐directed mutagenesis decreased the enantioselectivity demonstrating that the active site controls the enantioselectivity of the epoxidation.
Metal: MnLigand type: Amino acidHost protein: Bovine carbonic anhydrase II (CA)Anchoring strategy: Metal substitutionOptimization: Chemical & geneticNotes: ---
Metal: MnLigand type: Amino acidHost protein: Human carbonic anhydrase II (hCAII)Anchoring strategy: Metal substitutionOptimization: Chemical & geneticNotes: PDB ID 4CAC = Structure of Zn containing hCAII
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Transforming Carbonic Anhydrase into Epoxide Synthase by Metal Exchange
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ChemBioChem 2006, 7, 1013-1016, 10.1002/cbic.200600127
Enantioselective epoxidation of styrene was observed in the presence of manganese‐containing carbonic anhydrase as catalyst. The probable oxygen‐transfer reagent is peroxymonocarbonate, which has a structural similarity with the hydrogenocarbonate substrate of the natural reaction. Styrene was chosen as the enzyme possesses a small hydrophobic cavity close to the active site.
Metal: MnLigand type: Amino acidHost protein: Bovine carbonic anhydrase II (CA)Anchoring strategy: Metal substitutionOptimization: Chemical & geneticNotes: ---
Metal: MnLigand type: Amino acidHost protein: Human carbonic anhydrase II (hCAII)Anchoring strategy: Metal substitutionOptimization: Chemical & geneticNotes: ---