Kittisak Thotsaporn scite author profile

Kittisak Thotsaporn

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5Publications

530Citation Statements Received

309Citation Statements Given

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Chulalongkorn University, Mahidol University, Center for Excellence in Education

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Multiple pathways guide oxygen diffusion into flavoenzyme active sites

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et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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Dioxygen (O2) and other gas molecules have a fundamental role in a variety of enzymatic reactions. However, it is only poorly understood which O2 uptake mechanism enzymes employ to promote efficient catalysis and how general this is. We investigated O2 diffusion pathways into monooxygenase and oxidase flavoenzymes, using an integrated computational and experimental approach. Enhanced-statistics molecular dynamics simulations reveal spontaneous protein-guided O2 diffusion from the bulk solvent to preorganized protein cavities. The predicted protein-guided diffusion paths and the importance of key cavity residues for oxygen diffusion were verified by combining site-directed mutagenesis, rapid kinetics experiments, and high-resolution X-ray structures. This study indicates that monooxygenase and oxidase flavoenzymes employ multiple funnel-shaped diffusion pathways to absorb O 2 from the solvent and direct it to the reacting C4a atom of the flavin cofactor. The difference in O 2 reactivity among dehydrogenases, monooxygenases, and oxidases ultimately resides in the fine modulation of the local environment embedding the reactive locus of the flavin.computational biochemistry ͉ enzymology ͉ flavin ͉ oxygen reactivity

Kinetic Mechanism of the Dechlorinating Flavin-dependent Monooxygenase HadA

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et al. 2017

Journal of Biological Chemistry

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Edited by F. Peter GuengerichThe accumulation of chlorophenols (CPs) in the environment, due to their wide use as agrochemicals, has become a serious environmental problem. These organic halides can be degraded by aerobic microorganisms, where the initial steps of various biodegradation pathways include an oxidative dechlorinating process in which chloride is replaced by a hydroxyl substituent. Harnessing these dechlorinating processes could provide an opportunity for environmental remediation, but detailed catalytic mechanisms for these enzymes are not yet known. To close this gap, we now report transient kinetics and product analysis of the dechlorinating flavin-dependent monooxygenase, HadA, from the aerobic organism Ralstonia pickettii DTP0602, identifying several mechanistic properties that differ from other enzymes in the same class. We first overexpressed and purified HadA to homogeneity. Analyses of the products from single and multiple turnover reactions demonstrated that HadA prefers 4-CP and 2-CP over CPs with multiple substituents. Stopped-flow and rapid-quench flow experiments of HadA with 4-CP show the involvement of specific intermediates (C4a-hydroperoxy-FAD and C4a-hydroxy-FAD) in the reaction, define rate constants and the order of substrate binding, and demonstrate that the hydroxylation step occurs prior to chloride elimination. The data also identify the non-productive and productive paths of the HadA reactions and demonstrate that product formation is the rate-limiting step. This is the first elucidation of the kinetic mechanism of a two-component flavin-dependent monooxygenase that can catalyze oxidative dechlorination of various CPs, and as such it will serve as the basis for future investigation of enzyme variants that will be useful for applications in detoxifying chemicals hazardous to human health.

Cloning and expression of p-hydroxyphenylacetate 3-hydroxylase from Acinetobacter baumannii: evidence of the divergence of enzymes in the class of two-protein component aromatic hydroxylases

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et al. 2004

Biochimica et Biophysica Acta (BBA) - Gene Structure and Expres

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Stabilization of C4a-Hydroperoxyflavin in a Two-component Flavin-dependent Monooxygenase Is Achieved through Interactions at Flavin N5 and C4a Atoms

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et al. 2011

Journal of Biological Chemistry

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p-Hydroxyphenylacetate (HPA) 3-hydroxylase is a two-component flavin-dependent monooxygenase. Based on the crystal structure of the oxygenase component (C 2 ), His-396 is 4.5 Å from the flavin C4a locus, whereas Ser-171 is 2.9 Å from the flavin N5 locus. We investigated the roles of these two residues in the stability of the C4a-hydroperoxy-FMN intermediate. The results indicated that the rate constant for C4a-hydroperoxy-FMN formation decreased ϳ30-fold in H396N, 100-fold in H396A, and 300-fold in the H396V mutant, compared with the wild-type enzyme. Lesser effects of the mutations were found for the subsequent step of H 2 O 2 elimination. Studies on pH dependence showed that the rate constant of H 2 O 2 elimination in H396N and H396V increased when pH increased with pK a >9.6 and >9.7, respectively, similar to the wild-type enzyme (pK a >9.4). These data indicated that His-396 is important for the formation of the C4a-hydroperoxy-FMN intermediate but is not involved in H 2 O 2 elimination. Transient kinetics of the Ser-171 mutants with oxygen showed that the rate constants for the H 2 O 2 elimination in S171A and S171T were ϳ1400-fold and 8-fold greater than the wild type, respectively. Studies on the pH dependence of S171A with oxygen showed that the rate constant of H 2 O 2 elimination increased with pH rise and exhibited an approximate pK a of 8.0. These results indicated that the interaction of the hydroxyl group side chain of Ser-171 and flavin N5 is required for the stabilization of C4a-hydroperoxy-FMN. The double mutant S171A/H396V reacted with oxygen to directly form the oxidized flavin without stabilizing the C4a-hydroperoxy-FMN intermediate, which confirmed the findings based on the single mutation that His-396 was important for formation and Ser-171 for stabilization of the C4a-hydroperoxy-FMN intermediate in C 2 .

Interactions with the Substrate Phenolic Group Are Essential for Hydroxylation by the Oxygenase Component of p-Hydroxyphenylacetate 3-Hydroxylase

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et al. 2011

Journal of Biological Chemistry

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plex, which in turn promotes oxygen atom transfer via an electrophilic aromatic substitution mechanism. Analysis of Ser-146 variants revealed that this residue is necessary for but not directly engaged in hydroxylation. Product formation in S146A is pH-independent and constant at ϳ70% over a pH range of 6 -10, whereas product formation for S146C decreased from ϳ65% at pH 6.0 to 27% at pH 10.0. These data indicate that the ionization of Cys-146 in the S146C variant has an adverse effect on hydroxylation, possibly by perturbing formation of the His ␦؉ ⅐HPA ␦؊ complex needed for hydroxylation.Incorporation of single oxygen atoms into organic compounds (monooxygenation) by hydroxylation or epoxidation is an important biological process for aerobic organisms. The monooxygenation reaction is generally catalyzed by cytochrome P450, metalloenzymes, pterin-dependent and flavindependent monooxygenases (1). Flavin-dependent monooxygenases are involved in a wide variety of biological processes (2, 3). These enzymes catalyze the monooxygenation of many aromatic and aliphatic compounds (3).Based on the number of proteins required for catalysis, flavin-dependent monooxygenases can be classified into singleprotein component and two-protein component types (2-5). Besides an organic substrate, both types of enzymes require NAD(P)H and oxygen as co-substrates. The initial part of the reaction is the reduction of an enzyme-bound flavin by NAD(P)H to generate reduced flavin followed by the reaction of reduced flavin with oxygen to form the C4a-(hydro)peroxy flavin, a key intermediate that is required for oxygenation of an organic substrate. Oxygenation occurs via an oxygen atom transfer from C4a-hydroperoxy flavin to an organic substrate, resulting in the formation of a C4a-hydroxy flavin intermediate and an oxygenated product. The C4a-hydroxy flavin dehydrates at the last step of the reaction to form the final species, oxidized flavin (2-4, 6). All steps for the reactions of singleprotein component flavin-dependent monooxygenases occur within the same polypeptide, whereas for the two-protein component type the flavin reduction occurs on a reductase component and the oxygenation occurs on an oxygenase component (4 -8). The mechanism by which the reduced flavin is transferred involves simple diffusion or protein-protein contacts (5,8). Although single-component flavin-dependent monooxygenases have been studied for more than 40 years, two-component flavin-dependent monooxygenases have only received significant attention during the past decade after recent discoveries of their involvement in a wide variety of reactions (2, 5).The mechanism by which the oxygen atom transfer occurs in flavin-dependent monooxygenases is well understood for only a few enzymatic systems. The best understood oxygenation reaction is the hydroxylation of aromatic compounds catalyzed *

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