R.C. Wilmouth scite author profile

Flavonoids are common colorants in plants and have long-established biomedicinal properties. Anthocyanidin synthase (ANS), a 2-oxoglutarate iron-dependent oxygenase, catalyzes the penultimate step in the biosynthesis of the anthocyanin class of flavonoids. The crystal structure of ANS reveals a multicomponent active site containing metal, cosubstrate, and two molecules of a substrate analog (dihydroquercetin). An additional structure obtained after 30 min exposure to dioxygen is consistent with the oxidation of the dihydroquercetin to quercetin and the concomitant decarboxylation of 2-oxoglutarate to succinate. Together with in vitro studies, the crystal structures suggest a mechanism for ANS-catalyzed anthocyanidin formation from the natural leucoanthocyanidin substrates involving stereoselective C-3 hydroxylation. The structure of ANS provides a template for the ubiquitous family of plant nonhaem oxygenases for future engineering and inhibition studies.

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Toward a Structural Understanding of the Dehydratase Mechanism

Allard

et al. 2002

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dTDP-D-glucose 4,6-dehydratase (RmlB) was first identified in the L-rhamnose biosynthetic pathway, where it catalyzes the conversion of dTDP-D-glucose into dTDP-4-keto-6-deoxy-D-glucose. The structures of RmlB from Salmonella enterica serovar Typhimurium in complex with substrate deoxythymidine 5'-diphospho-D-glucose (dTDP-D-glucose) and deoxythymidine 5'-diphosphate (dTDP), and RmlB from Streptococcus suis serotype 2 in complex with dTDP-D-glucose, dTDP, and deoxythymidine 5'-diphospho-D-pyrano-xylose (dTDP-xylose) have all been solved at resolutions between 1.8 A and 2.4 A. The structures show that the active sites are highly conserved. Importantly, the structures show that the active site tyrosine functions directly as the active site base, and an aspartic and glutamic acid pairing accomplishes the dehydration step of the enzyme mechanism. We conclude that the substrate is required to move within the active site to complete the catalytic cycle and that this movement is driven by the elimination of water. The results provide insight into members of the SDR superfamily.

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Crystal Structure of Carbapenem Synthase (CarC)

Clifton¹,

Doan²,

Sleeman³

et al. 2003

Journal of Biological Chemistry

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The proposed biosynthetic pathway to the carbapenem antibiotics proceeds via epimerization/desaturation of a carbapenam in an unusual process catalyzed by an iron-and 2-oxoglutarate-dependent oxygenase, CarC. Crystal structures of CarC complexed with Fe(II) and 2-oxoglutarate reveal it to be hexameric (space group C222 1 ), consistent with solution studies. CarC monomers contain a double-stranded ␤-helix core that supports ligands binding a single Fe(II) to which 2-oxoglutarate complexes in a bi-dentate manner. A structure was obtained with L-N-acetylproline acting as a substrate analogue. Quantum mechanical/molecular mechanical modeling studies with stereoisomers of carbapenams and carbapenems were used to investigate substrate binding. The combined work will stimulate further mechanistic studies and aid in the engineering of carbapenem biosynthesis.

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Structure of a specific acyl-enzyme complex formed between β-casomorphin-7 and porcine pancreatic elastase

Wilmouth

Clifton

Robinson³

et al. 1997

Nat Struct Mol Biol

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Mass spectrometric screening reveals that an unmodified natural heptapeptide--human beta-casomorphin-7, an internal sequence of human beta-casein that possesses opioid-like activity--reacts with porcine pancreatic elastase to form an unusually stable acyl-enzyme complex at low pH. X-ray crystallographic analysis (to 1.9 A resolution) at pH 5 shows continuous electron density linking the C-terminal isoleucine of beta-casomorphin-7 to Ser 195 through an ester bond. The structure reveals a well defined water molecule (Wat 317), equidistant between the carbon of the ester carbonyl and N epsilon 2 of His 57. Deprotonation of Wat 317 will produce a hydroxide ion positioned to attack the ester carbonyl through the favoured Bürgi-Dunitz trajectory.

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X-ray Structure of a Serine Protease Acyl-Enzyme Complex at 0.95-Å Resolution

Katona¹,

Wilmouth²,

Wright³

et al. 2002

Journal of Biological Chemistry

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Kinetic analyses led to the discovery that N-acetylated tripeptides with polar residues at P 3 are inhibitors of porcine pancreatic elastase (PPE) that form unusually stable acyl-enzyme complexes. Peptides terminating in a C-terminal carboxylate were more potent than those terminating in a C-terminal amide, suggesting recognition by the oxy-anion hole is important in binding. X-ray diffraction data were recorded to 0.95-Å resolution for an acyl-enzyme complex formed between PPE and N-acetyl-Asn-Pro-Ile-CO 2 H at ϳpH 5. The accuracy of the crystallographic coordinates allows structural issues concerning the mechanism of serine proteases to be addressed. Significantly, the ester bond of the acyl-enzyme showed a high level of planarity, suggesting geometric strain of the ester link is not important during catalysis. Several hydrogen atoms could be clearly identified and were included within the model. In keeping with a recent x-ray structure of subtilisin at 0.78 Å (1), limited electron density is visible consistent with the putative location of a hydrogen atom approximately equidistant between the histidine and aspartate residues of the catalytic triad. Comparison of this high resolution crystal structure of the acyl-enzyme complex with that of native elastase at 1.1 Å (2) showed that binding of the N-terminal part of the substrate can be accommodated with negligible structural rearrangements. In contrast, comparison with structures obtained as part of "time-resolved" studies on the reacting acyl-enzyme complex at >pH 7 (3) indicate small but significant structural differences, consistent with the proposed synchronization of ester hydrolysis and substrate release.Because of the historical importance of the serine proteases in studies on enzyme catalysis and continuing medicinal interest in their inhibition, the details of their catalytic mechanism remain of interest. For some time there has been a consensus on the overall sequence of steps and key residues involved (4, 5). Catalysis is initiated by the noncovalent binding of the polypeptide substrate to an active site cleft. After attack by a nucleophilic serine onto the scissile amide bond, the acylation phase of the reaction proceeds via the formation of a tetrahedral oxy-anion intermediate that collapses to form an acylenzyme (ester) complex with concomitant release of the Cterminal product fragment. In the deacylation phase of catalysis, attack of a water molecule onto the ester bond results in a second tetrahedral intermediate that collapses, releasing the N-terminal product fragment and regenerating the vacant enzyme.Pioneering work on the structural biology of the serine protease family (4, 6 -10) led to the concept of a conserved active site catalytic triad formed by active site serine, histidine, and aspartate residues. A crucial role as a general base was postulated for the conserved histidine, i.e. it deprotonates both the nucleophilic serine in the acylation phase and the "hydrolytic" water during the deacylation phase. A hydrogen bond between the acti...

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R.C. Wilmouth

Structure and Mechanism of Anthocyanidin Synthase from Arabidopsis thaliana

Toward a Structural Understanding of the Dehydratase Mechanism

Crystal Structure of Carbapenem Synthase (CarC)

Structure of a specific acyl-enzyme complex formed between β-casomorphin-7 and porcine pancreatic elastase

X-ray Structure of a Serine Protease Acyl-Enzyme Complex at 0.95-Å Resolution

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