A Conserved Acidic Residue in Phenylalanine Hydroxylase Contributes to Cofactor Affinity and Catalysis

Ronau, J.A.; Paul, Lake N.; Fuchs, Julian E.; Liedl, Klaus R.; Abu‐Omar, Mahdi M.; Das, Chittaranjan

doi:10.1021/bi500734h

Cited by 7 publications

(15 citation statements)

References 70 publications

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“…The exact chemical identity of this pterin cofactor is flexible, as MPt, dimethyl pterin, and BPt have all been reported to be sufficient for proper enzymatic activity [24,96,97]. The pterin cofactor is coordinated in the enzymatic active site by a network of hydrogen bonds and a conserved aspartate residue on the cognate protein [98]. This aspartate residue is hypothesized to be essential for maintaining proper orientation of the cofactor to support productive catalysis.…”

Section: Phenylalanine Hydroxylasementioning

confidence: 99%

Pterin function in bacteria

Feirer

Fuqua

2017

Pteridines

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AbstractPterins are widely conserved biomolecules that play essential roles in diverse organisms. First described as enzymatic cofactors in eukaryotic systems, bacterial pterins were discovered in cyanobacteria soon after. Several pterin structures unique to bacteria have been described, with conjugation to glycosides and nucleotides commonly observed. Despite this significant structural diversity, relatively few biological functions have been elucidated. Molybdopterin, the best studied bacterial pterin, plays an essential role in the function of the Moco cofactor. Moco is an essential component of molybdoenzymes such as sulfite oxidase, nitrate reductase, and dimethyl sulfoxide reductase, all of which play important roles in bacterial metabolism and global nutrient cycles. Outside of the molybdoenzymes, pterin cofactors play important roles in bacterial cyanide utilization and aromatic amino acid metabolism. Less is known about the roles of pterins in nonenzymatic processes. Cyanobacterial pterins have been implicated in phenotypes related to UV protection and phototaxis. Research describing the pterin-mediated control of cyclic nucleotide metabolism, and their influence on virulence and attachment, points to a possible role for pterins in regulation of bacterial behavior. In this review, we describe the variety of pterin functions in bacteria, compare and contrast structural and mechanistic differences, and illuminate promising avenues of future research.

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Section: Phenylalanine Hydroxylasementioning

confidence: 99%

Pterin function in bacteria

Feirer

Fuqua

2017

Pteridines

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“…Phenylalanine hydroxylases (PAHs) are enzymes that catalyze the hydroxylation of phenylalanine to tyrosine (Fig. 1; Kappock & Caradonna, 1996;Erlandsen et al, 2002;Fitzpatrick, 2003;Ronau et al, 2013Ronau et al, , 2014. These enzymes belong to the aromatic amino-acid hydroxylase (AAAH) family, which includes tyrosine hydroxylases (THs) and tryptophan hydroxylases (TPHs) (Hufton et al, 1995;Fitzpatrick, 2003;Cao et al, 2010;Ronau et al, 2014;Skjaerven et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

“…1; Kappock & Caradonna, 1996;Erlandsen et al, 2002;Fitzpatrick, 2003;Ronau et al, 2013Ronau et al, , 2014. These enzymes belong to the aromatic amino-acid hydroxylase (AAAH) family, which includes tyrosine hydroxylases (THs) and tryptophan hydroxylases (TPHs) (Hufton et al, 1995;Fitzpatrick, 2003;Cao et al, 2010;Ronau et al, 2014;Skjaerven et al, 2014). AAAHs are nonheme iron(II)-containing enzymes and utilize (6R)-5,6,7,8-tetrahydrobiopterin (BH 4 ) as a cofactor (Cao et al, 2010;Skjaerven et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

“…AAAHs are nonheme iron(II)-containing enzymes and utilize (6R)-5,6,7,8-tetrahydrobiopterin (BH 4 ) as a cofactor (Cao et al, 2010;Skjaerven et al, 2014). The BH 4 cofactor is converted to 7,8-dihydrobiopterin (BH 2 ) during the enzymatic reaction of the corresponding AAAH and is then recycled to BH 4 by pterin 4a-carbiolamine dehydratase and dihydropteridine reductase (Crabtree & Channon, 2011;Ronau et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

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Structural studies of a novel auxiliary-domain-containing phenylalanine hydroxylase from Bacillus cereus ATCC 14579

Park¹,

Hong²,

Seok³

et al. 2022

Acta Cryst Sect D Struct Biol

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Phenylalanine hydroxylase (PAH), which belongs to the aromatic amino-acid hydroxylase family, is involved in protein synthesis and pyomelanine production through the hydroxylation of phenylalanine to tyrosine. In this study, the crystal structure of PAH from Bacillus cereus ATCC 14579 (BcPAH) with an additional 280 amino acids in the C-terminal region was determined. The structure of BcPAH consists of three distinct domains: a core domain with two additional inserted α-helices and two novel auxiliary domains: BcPAH-AD1 and BcPAH-AD2. Structural homologues of BcPAH-AD1 and BcPAH-AD2 are known to be involved in mRNA regulation and protein–protein interactions, and thus it was speculated that BcPAH might utilize the auxiliary domains for interaction with its partner proteins. Furthermore, phylogenetic tree analysis revealed that the three-domain PAHs, including BcPAH, are completely distinctive from both conventional prokaryotic PAHs and eukaryotic PAHs. Finally, biochemical studies of BcPAH showed that BcPAH-AD1 might be important for the structural integrity of the enzyme and that BcPAH-AD2 is related to enzyme stability and/or activity. Investigations into the intracellular functions of the two auxiliary domains and the relationship between these functions and the activity of PAH are required.

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“…Moreover, the residues related to enzymatic activity and substrate binding in CvPAH were identified using molecular modification. Tyr179 plays a role in substrate binding and the ratedetermining step in catalytic processes [13], and Asp139 contributes to stabilization of the transition state by direct binding with the cofactor [14]. CvPAH displayed low Ltryptophan hydroxylation activity, and the double variant L101Y/W180F exhibited a 5.2-fold increase in activity compared to the wild type [15].…”

Section: Introductionmentioning

confidence: 99%

Catalytic Ability Improvement of Phenylalanine Hydroxylase from Chromobacterium violaceum by N-Terminal Truncation and Proline Introduction

Liu¹,

Cheng²,

Ye³

et al. 2019

Journal of Microbiology and Biotechnology

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Phenylalanine hydroxylase from Chromobacterium violaceum (CvPAH) is a monomeric enzyme that converts phenylalanine to tyrosine. It shares high amino acid identity and similar structure with a subunit of human phenylalanine hydroxylase that is a tetramer, resulting in the latent application in medications. In this study, semirational design was applied to CvPAH to improve the catalytic ability based on molecular dynamics simulation analyses. Four Nterminal truncated variants and one single point variant were constructed and characterized. The D267P variant showed a 2.1-fold increased thermal stability compared to the wild type, but lower specific activity was noted compared with the wild type. The specific activity of all truncated variants was a greater than 25% increase compared to the wild type, and these variants showed similar or slightly decreased thermostability with the exception of the N-Δ9 variant. Notably, the N-Δ9 variant exhibited a 1.2-fold increased specific activity, a 1.3-fold increased thermostability and considerably increased catalytic activity under the neutral environment compared with the wild type. These properties of the N-Δ9 variant could advance medical and pharmaceutical applications of CvPAH. Our findings indicate that the N-terminus might modulate substrate binding, and are directives for further modification and functional research of PAH and other enzymes.

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A Conserved Acidic Residue in Phenylalanine Hydroxylase Contributes to Cofactor Affinity and Catalysis

Cited by 7 publications

References 70 publications

Pterin function in bacteria

Pterin function in bacteria

Structural studies of a novel auxiliary-domain-containing phenylalanine hydroxylase from Bacillus cereus ATCC 14579

Catalytic Ability Improvement of Phenylalanine Hydroxylase from Chromobacterium violaceum by N-Terminal Truncation and Proline Introduction

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