<i>p</i>-Hydroxyphenylacetate 3-Hydroxylase as a Biocatalyst for the Synthesis of Trihydroxyphenolic Acids

Dhammaraj, Taweesak; Phintha, Aisaraphon; Pinthong, Chatchadaporn; Medhanavyn, Dheeradhach; Tinikul, Ruchanok; Chenprakhon, Pirom; Sucharitakul, Jeerus; Vardhanabhuti, Nontima; Jiarpinitnun, Chutima; Chaiyen, Pimchai

doi:10.1021/acscatal.5b00439

Cited by 33 publications

(40 citation statements)

References 31 publications

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“…However, the comparison is limited to a very small number of the same substrates as those tested here and the other studies, namely, HPA, Ph, Cou, and HPG . It is also possible to compare the substrate specificity properties of EcHpaB with those of C 2 ‐HpaH from A. baumanii because the latter has also been studied in a pure enzyme system . It appears that C 2 ‐HpaH accepts much fewer substrates than that of EcHpaB: among the few phenols that can be hydroxylated, apart from HPA, HBA and Cou are much less efficiently converted into the corresponding catechols, compared with EcHpaB.…”

Section: Resultsmentioning

confidence: 96%

Structural and Functional Characterization of 4‐Hydroxyphenylacetate 3‐Hydroxylase from Escherichia coli

et al. 2019

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The hydroxylation of phenols into polyphenols, which are valuable chemicals and pharmaceutical products, is a challenging reaction. The search for green synthetic processes has led to considering microorganisms and pure hydroxylases as catalysts for phenol hydroxylation. Herein, we report the structural and functional characterization of the flavin adenine dinucleotide (FAD)‐dependent 4‐hydroxyphenylacetate 3‐monooxygenase from Escherichia coli, named HpaB. It is shown that this enzyme enjoys a relatively broad substrate specificity, which allows the conversion of a number of non‐natural phenolic compounds, such as tyrosol, hydroxymandelic acid, coumaric acid, hydroxybenzoic acid and its methyl ester, and phenol, into the corresponding catechols. The reaction can be performed by using a simple chemical assay based on formate as the electron donor and the organometallic complex [Rh(bpy)Cp*(H2O)]2+ (Cp*: 1,2,3,4,5‐pentamethylcyclopentadiene, bpy: 2,2′‐bipyridyl) as the catalyst for FAD reduction. The availability of a crystal structure of HpaB in complex with FAD at 1.8 Å resolution opens up the possibility of the rational tuning of the substrate specificity and activity of this interesting class of phenol hydroxylases.

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Section: Resultsmentioning

confidence: 96%

Structural and Functional Characterization of 4‐Hydroxyphenylacetate 3‐Hydroxylase from Escherichia coli

et al. 2019

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“…Furthermore, the individual rate constants associated with each step and the mechanism of reduced flavin transfer between the two components have been reported (24 -30). This knowledge has been useful for applying HPAH for the synthesis of bioactive phenolic acids and in the hydroxylation of aniline derivatives (31,32).…”

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confidence: 99%

Kinetic Mechanism of the Dechlorinating Flavin-dependent Monooxygenase HadA

Pimviriyakul

Thotsaporn

Sucharitakul

et al. 2017

Journal of Biological Chemistry

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108

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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.

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“…Hydroxylation of plant-derived PAs such as pCA results directly in production of CA. [94] The same enzyme can also hydroxylate other PAs such as 3-(4-hydroxyphenyl)propionic acid to form 3-(3,4dihydroxyphenyl)propionic acid and 3-(3,4,5-trihydroxyphenyl) propionic acid, p-hydroxyphenylacetic acid to form 3,4-dihydroxyphenylacetic acid and 3,4,5-trihydroxyphenylacetic acid, and pHBA to form 3,4-dihydroxybenzoic acid and 3,4,5trihydroxybenzoic acid or GA (Figure 2). [87,88] Whole-cell biocatalysis using E. coli expressing the F185L mutant of Cytochrome P450 CYP199A2 can produce CA with a yield of 2.8 g L À1 , [89] whole-cell biocatalysis using E. coli expressing the hpaBC gene encoding a two-component flavindependent monooxygenase from Pseudomonas aeruginosa is even more effective, yielding up to 10.2 g L À1 of CA within 24 h. [90] 3,4,5-Trihydroxycinnamic acid is a strong antioxidant, having greater antioxidant activity in aqueous solution than its monoand dihydroxyphenolic acid counterparts.…”

Section: Biotransformation By Hydroxylationmentioning

confidence: 99%

“…Native microorganisms including Pycnoporus cinnabarinus and Streptomyces caeruleus have been used to synthesize CA from pCA with production yields of 21% (257 mg L À1 ) and 16.6% (150 mg L À1 ), respectively. [94,95] As the wild-type enzyme cannot use pCA efficiently as a substrate, rational engineering was carried out to obtain the Y398S variant that is more efficient than the wild-type enzyme in producing 3,4,5-trihydroxycinnamic acid from pCA with a yield of 23 mg L À1 . [91] Therefore, the compound has great potential for use as an antioxidant in the food and pharmaceutical industries.…”

Section: Biotransformation By Hydroxylationmentioning

confidence: 99%

“…[87,88] Whole-cell biocatalysis using E. coli expressing the F185L mutant of Cytochrome P450 CYP199A2 can produce CA with a yield of 2.8 g L À1 , [89] whole-cell biocatalysis using E. coli expressing the hpaBC gene encoding a two-component flavindependent monooxygenase from Pseudomonas aeruginosa is even more effective, yielding up to 10.2 g L À1 of CA within 24 h. [90] 3,4,5-Trihydroxycinnamic acid is a strong antioxidant, having greater antioxidant activity in aqueous solution than its monoand dihydroxyphenolic acid counterparts. [94] Recently, an efficient process to extract pCA and CA from palm oil mill effluent, a renewable and sustainable feedstock, was developed and followed by their conversion to 3,4,5-trihydroxycinnamic acid. Recently, it has been shown that the flavin-dependent p-hydroxyphenylacetate 3-hydroxylase from Acinetobacter baumannii [92,93] can be used as a biocatalyst for the synthesis of CA and 3,4,5-trihydroxycinnamic acid from pCA in vitro.…”

Section: Biotransformation By Hydroxylationmentioning

confidence: 99%

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Biotransformation of Plant-Derived Phenolic Acids

et al. 2018

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Phenolic acids are abundant biomass feedstock that can be derived from the processing of lignin or other byproducts from agro-industrial waste. Although phenolic acids such as p-hydroxybenzoic acid, p-coumaric acid, caffeic acid, vanillic acid, cinnamic acid, gallic acid, syringic acid, and ferulic acid can be used directly in various applications, their value can be significantly increased when they are further modified to high value-added compounds. This review summarizes and discusses the new advances in cell-free and whole-cell biocatalysis technologies for reactions important for conversion of phenolic acids including esterification, decarboxylation, amination, halogenation, hydroxylation, and ring-breakage reactions. The products of these reactions are useful for the pharmaceutical, cosmetic, food, fragrance, and polymer industries. Production of phenolic acids is sustainable, and these processes for their biotransformation are clean technologies that do not produce toxic waste and use less energy than conventional physical and chemical methods. Thus, biotransformation of phenolic acids provides an economically viable and sustainable means for producing useful materials for society.

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p-Hydroxyphenylacetate 3-Hydroxylase as a Biocatalyst for the Synthesis of Trihydroxyphenolic Acids

Cited by 33 publications

References 31 publications

Structural and Functional Characterization of 4‐Hydroxyphenylacetate 3‐Hydroxylase from Escherichia coli

Structural and Functional Characterization of 4‐Hydroxyphenylacetate 3‐Hydroxylase from Escherichia coli

Kinetic Mechanism of the Dechlorinating Flavin-dependent Monooxygenase HadA

Biotransformation of Plant-Derived Phenolic Acids

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