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Tailoring Heme-Thiolate Proteins into Efficient Biocatalysts with High Specificity and SelectivityTian, Hui 29 March 2010 (has links)
Cytochrome P450 monooxygenases, one of the most important classes of heme-thiolate proteins, have attracted considerable interest in the biochemical community because of its catalytic versatility, substrate diversity and great number in the superfamily. Although P450s are capable of catalyzing numerous difficult oxidation reactions, the relatively low stability, low turnover rates and the need of electron-donating cofactors have limited their practical biotechnological and pharmaceutical applications as isolated enzymes. The goal of this study is to tailor such heme-thiolate proteins into efficient biocatalysts with high specificity and selectivity by protein engineering and to better understand the structure-function relationship in cytochromes P450. In the effort to engineer P450cam, the prototype member of the P450 superfamily, into an efficient peroxygenase that utilizes hydrogen peroxide via the “peroxide-shunt” pathway, site-directed mutagenesis has been used to elucidate the critical roles of hydrophobic residues in the active site. Various biophysical, biochemical and spectroscopic techniques have been utilized to investigate the wild-type and mutant proteins. Three important P450cam variants were obtained showing distinct structural and functional features. In P450camV247H mutant, which exhibited almost identical spectral properties with the wild-type, it is demonstrated that a single amino acid switch turned the monooxygenase into an efficient preoxidase by increasing the peroxidase activity nearly one thousand folds. In order to tune the distal pocket of P450cam with polar residues, Leu 246 was replaced with a basic residue, lysine, resulting in a mutant with spectral features identical to P420, the inactive species of P450. But this inactive-species-like mutant showed catalytic activities without the facilitation of any cofactors. By substituting Gly 248 with a histidine, a novel Cys-Fe-His ligation set was obtained in P450cam which represented the very rare case of His ligation in heme-thiolate proteins. In addition to serving as a convenient model for hemoprotein structural studies, the G248H mutant also provided evidence about the nature of the axial ligand in cytochrome P420 and other engineered hemoproteins with thiolate ligations. Furthermore, attempts have been made to replace the proximal ligand in sperm whale myoglobin to construct a heme-thiolate protein model by mimicking the protein environment of cytochrome P450cam and chloroperoxidase.
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The Influence of the Proximal Amide Hydrogen Bonds and the Proximal Helix Dipole on the Catalytic Activity of Chloroperoxidasepardillo, armando d. 02 November 2015 (has links)
Chloroperoxidase (CPO) is a heme-thiolate protein with exceptional versatility and great potential as a biocatalyst. The CPO reactive species, Compound I ( Cpd I) is of particular interest, as well as the Cytochrome P450 (P450) -type monoxygenase catalytic activity, which has significant biotechnological potential. Proximal hydrogen bonding of the axial sulfur with the backbone amides (NH•••S) is a conserved feature of heme-thiolate enzymes. In CPO, the effect of NH•••S bonds is amplified by the dipole moment of the proximal helix. The role of the proximal region has been disputed as to whether it simply protects the axial sulfur, or whether it additionally influences catalysis via modulation of the push effect.
The objective of the research presented herein is two-fold. First, the influence of the NH•••S bonds on Cpd I formation is determined by obtaining the reaction coordinate, starting from a peroxide bound heme, for two model systems (one with proximal residues providing NH•••S bonds and one without) and comparing the results. Secondly, the influence of the proximal region on the epoxidation of Cis-β-methylsterene is obtained. This is performed similarly to the first objective however, the reaction coordinate begins with a Cpd I-CBMS complex and the proximal contribution is extended to include the influence of the proximal helix dipole.
Our findings show that the proximal region stabilizes Cpd 0 relative to all other minima and reduces the barrier for Cpd 0’s formation. The stability of protonated Compound 0 is reduced, favoring a hybrid homo-heterolytic relative to a classic heterolytic mechanism for O-O bond scission. Additionally, the proximal region significantly enhances CPO’s reactivity; the Cβ-O bond barrier is stabilized, while Cα-O-Cβ ring closure becomes barrierless. The stabilization of the reaction barrier correlates with increased electron density transfer to residues of the proximal pocket and involves a change in the electron transfer mechanism. These results can be traced to a reduction in the pKa of the heme-bound substrate and an increase in oxidation potential, a result of the proximal region reducing the “push effect”.
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Side chain removal from corticosteroids by unspecific peroxygenaseUllrich, René, Hofrichter, Martin, Poraj-Kobielska, Marzena, Pecyna, Marek, Scheibner, Katrin, Scholze, Steffi, Sandvoss, Martin, Halbout, Claire 07 June 2018 (has links) (PDF)
Two unspecific peroxygenases (UPO, EC 1.11.2.1) from the basidiomycetous fungi Marasmius rotula and Marasmius wettsteinii oxidized steroids with hydroxyacetyl and hydroxyl functionalities at C17 - such as cortisone, Reichstein's substance S and prednisone - via stepwise oxygenation and final fission of the side chain. The sequential oxidation started with the hydroxylation of the terminal carbon (C21) leading to a stable geminal alcohol (e.g. cortisone 21-gem-diol) and proceeded via a second oxygenation resulting in the corresponding α-ketocarboxylic acid (e.g. cortisone 21-oic acid). The latter decomposed under formation of adrenosterone (4-androstene-3,11,17-trione) as well as formic acid and carbonic acid (that is in equilibrium with carbon dioxide); fission products comprising two carbon atoms such as glycolic acid or glyoxylic acid were not detected. Protein models based on the crystal structure data of MroUPO (Marasmius rotula unspecific peroxygenase) revealed that the bulky cortisone molecule suitably fits into the enzyme's access channel, which enables the heme iron to come in close contact to the carbons (C21, C20) of the steroidal side chain. ICP-MS analysis of purified MroUPO confirmed the presence of magnesium supposedly stabilizing the porphyrin ring system.
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Side chain removal from corticosteroids by unspecific peroxygenaseUllrich, René, Hofrichter, Martin, Poraj-Kobielska, Marzena, Pecyna, Marek, Scheibner, Katrin, Scholze, Steffi, Sandvoss, Martin, Halbout, Claire 07 June 2018 (has links)
Two unspecific peroxygenases (UPO, EC 1.11.2.1) from the basidiomycetous fungi Marasmius rotula and Marasmius wettsteinii oxidized steroids with hydroxyacetyl and hydroxyl functionalities at C17 - such as cortisone, Reichstein's substance S and prednisone - via stepwise oxygenation and final fission of the side chain. The sequential oxidation started with the hydroxylation of the terminal carbon (C21) leading to a stable geminal alcohol (e.g. cortisone 21-gem-diol) and proceeded via a second oxygenation resulting in the corresponding α-ketocarboxylic acid (e.g. cortisone 21-oic acid). The latter decomposed under formation of adrenosterone (4-androstene-3,11,17-trione) as well as formic acid and carbonic acid (that is in equilibrium with carbon dioxide); fission products comprising two carbon atoms such as glycolic acid or glyoxylic acid were not detected. Protein models based on the crystal structure data of MroUPO (Marasmius rotula unspecific peroxygenase) revealed that the bulky cortisone molecule suitably fits into the enzyme's access channel, which enables the heme iron to come in close contact to the carbons (C21, C20) of the steroidal side chain. ICP-MS analysis of purified MroUPO confirmed the presence of magnesium supposedly stabilizing the porphyrin ring system.
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