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Applied and Environmental Microbiology Feb 2021Rieske nonheme iron oxygenases (ROs) catalyze the oxidation of a wide variety of substrates and play important roles in aromatic compound degradation and polycyclic...
Rieske nonheme iron oxygenases (ROs) catalyze the oxidation of a wide variety of substrates and play important roles in aromatic compound degradation and polycyclic aromatic hydrocarbon degradation. Those Rieske dioxygenases that usually act on hydrophobic substrates have been extensively studied and structurally characterized. Here, we report the crystal structure of a novel Rieske monooxygenase, NagGH, the oxygenase component of a salicylate 5-monooxygenase from sp. strain U2 that catalyzes the hydroxylation of a hydrophilic substrate salicylate (2-hydroxybenzoate), forming gentisate (2, 5-dihydroxybenzoate). The large subunit NagG and small subunit NagH share the same fold as that for their counterparts of Rieske dioxygenases and assemble the same αβ hexamer, despite that they share low (or no identity for NagH) sequence identities with these dioxygenase counterparts. A potential substrate-binding pocket was observed in the vicinity of the nonheme iron site. It featured a positively charged residue Arg323 that was surrounded by hydrophobic residues. The shift of nonheme iron atom caused by residue Leu228 disrupted the usual substrate pocket observed in other ROs. Residue Asn218 at the usual substrate pocket observed in other ROs was likewise involved in substrate binding and oxidation, yet residues Gln316 and Ser367, away from the usual substrate pocket of other ROs, were shown to play a more important role in substrate oxidation than Asn218. The unique binding pocket and unusual substrate-protein hydrophilic interaction provide new insights into Rieske monooxygenases. Rieske oxygenases are involved in the degradation of various aromatic compounds. These dioxygenases usually carry out hydroxylation of hydrophobic aromatic compounds and supply substrates with hydroxyl groups for extradiol/intradiol dioxygenases to cleave rings, and have been extensively studied. Salicylate 5-hydroxylase NagGH is a novel Rieske monooxygenase with high similarity to Rieske dioxygenases, and also shares reductase and ferredoxin similarity with a Rieske dioxygenase naphthalene 1,2-dioxygenase (NagAcAd) in sp. strain U2. The structure of NagGH, the oxygenase component of salicylate 5-monooxygenase, gives a representative of those monooxygenases and will help us understand the mechanism of their substrate binding and product regio-selectivity.
Topics: Catalytic Domain; Crystallization; Mixed Function Oxygenases; Ralstonia; Salicylates
PubMed: 33452034
DOI: 10.1128/AEM.01629-20 -
Plant Physiology Mar 2019The functions and biochemical mechanisms of major classes of plant oxygenases are discussed, and their potential utility for plant synthetic biology is explored. (Review)
Review
The functions and biochemical mechanisms of major classes of plant oxygenases are discussed, and their potential utility for plant synthetic biology is explored.
Topics: Catalysis; Metabolic Networks and Pathways; Models, Molecular; Oxygenases; Plants; Synthetic Biology
PubMed: 30670605
DOI: 10.1104/pp.18.01223 -
Journal of Bacteriology Mar 2022Biodegradation of terephthalate (TPA) is a highly desired catabolic process for the bacterial utilization of this polyethylene terephthalate (PET) depolymerization...
Biodegradation of terephthalate (TPA) is a highly desired catabolic process for the bacterial utilization of this polyethylene terephthalate (PET) depolymerization product, but to date, the structure of terephthalate dioxygenase (TPDO), a Rieske oxygenase (RO) that catalyzes the dihydroxylation of TPA to a -diol, is unavailable. In this study, we characterized the steady-state kinetics and first crystal structure of TPDO from Comamonas testosteroni KF1 (TPDO). TPDO exhibited substrate specificity for TPA (/ = 57 ± 9 mM s). The TPDO structure harbors characteristic RO features as well as a unique catalytic domain that rationalizes the enzyme's function. The docking and mutagenesis studies reveal that its substrate specificity for TPA is mediated by the Arg309 and Arg390 residues, positioned on opposite faces of the active site. Additionally, residue Gln300 is also proven to be crucial for the activity, as its mutation to alanine decreases the activity () by 80%. This study delineates the structural features that dictate the substrate recognition and specificity of TPDO. Global plastic pollution has become the most pressing environmental issue. Recent studies on enzymes depolymerizing polyethylene terephthalate plastic into terephthalate (TPA) show some potential for tackling this. Microbial utilization of this released product, TPA, is an emerging and promising strategy for waste-to-value creation. Research in the last decade has identified terephthalate dioxygenase (TPDO) as being responsible for initiating the enzymatic degradation of TPA in a few Gram-negative and Gram-positive bacteria. Here, we determined the crystal structure of TPDO from Comamonas testosteroni KF1 and revealed that it possesses a unique catalytic domain featuring two basic residues in the active site to recognize TPA. Biochemical and mutagenesis studies demonstrated the crucial residues responsible for the substrate specificity of this enzyme.
Topics: Dioxygenases; Oxygenases; Phthalic Acids; Plastics; Polyethylene Terephthalates
PubMed: 35007143
DOI: 10.1128/JB.00543-21 -
Pharmacology & Therapeutics Jun 2005Flavin-containing monooxygenase (FMO) oxygenates drugs and xenobiotics containing a "soft-nucleophile", usually nitrogen or sulfur. FMO, like cytochrome P450 (CYP), is a... (Review)
Review
Flavin-containing monooxygenase (FMO) oxygenates drugs and xenobiotics containing a "soft-nucleophile", usually nitrogen or sulfur. FMO, like cytochrome P450 (CYP), is a monooxygenase, utilizing the reducing equivalents of NADPH to reduce 1 atom of molecular oxygen to water, while the other atom is used to oxidize the substrate. FMO and CYP also exhibit similar tissue and cellular location, molecular weight, substrate specificity, and exist as multiple enzymes under developmental control. The human FMO functional gene family is much smaller (5 families each with a single member) than CYP. FMO does not require a reductase to transfer electrons from NADPH and the catalytic cycle of the 2 monooxygenases is strikingly different. Another distinction is the lack of induction of FMOs by xenobiotics. In general, CYP is the major contributor to oxidative xenobiotic metabolism. However, FMO activity may be of significance in a number of cases and should not be overlooked. FMO and CYP have overlapping substrate specificities, but often yield distinct metabolites with potentially significant toxicological/pharmacological consequences. The physiological function(s) of FMO are poorly understood. Three of the 5 expressed human FMO genes, FMO1, FMO2 and FMO3, exhibit genetic polymorphisms. The most studied of these is FMO3 (adult human liver) in which mutant alleles contribute to the disease known as trimethylaminuria. The consequences of these FMO genetic polymorphisms in drug metabolism and human health are areas of research requiring further exploration.
Topics: Amino Acid Sequence; Animals; Humans; Molecular Sequence Data; Molecular Structure; Oxygenases; Pharmaceutical Preparations; Polymorphism, Genetic; Structure-Activity Relationship; Substrate Specificity
PubMed: 15922018
DOI: 10.1016/j.pharmthera.2005.01.001 -
Applied and Environmental Microbiology Oct 2017Indole is a molecule of considerable biochemical significance, acting as both an interspecies signal molecule and a building block of biological elements. Bacterial...
Indole is a molecule of considerable biochemical significance, acting as both an interspecies signal molecule and a building block of biological elements. Bacterial indole degradation has been demonstrated for a number of cases; however, very little is known about genes and proteins involved in this process. This study reports the cloning and initial functional characterization of genes ( and cluster) responsible for indole biodegradation in sp. strain O153. The catabolic cascade was reconstituted with recombinant proteins, and each protein was assigned an enzymatic function. Degradation starts with oxidation, mediated by the IifC and IifD flavin-dependent two-component oxygenase system. Formation of indigo is prevented by IifB, and the final product, anthranilic acid, is formed by IifA, an enzyme which is both structurally and functionally comparable to cofactor-independent oxygenases. Moreover, the cluster was identified in the genomes of a wide range of bacteria, suggesting the potential of widespread Iif-mediated indole degradation. This work provides novel insights into the genetic background of microbial indole biodegradation. The key finding of this research is identification of the genes responsible for microbial biodegradation of indole, a toxic -heterocyclic compound. A large amount of indole is present in urban wastewater and sewage sludge, creating a demand for an efficient and eco-friendly means to eliminate this pollutant. A common strategy of oxidizing indole to indigo has the major drawback of producing insoluble material. Genes and proteins of sp. strain O153 (DSM 103907) reported here pave the way for effective and indigo-free indole removal. In addition, this work suggests possible novel means of indole-mediated bacterial interactions and provides the basis for future research on indole metabolism.
Topics: Acinetobacter; Bacterial Proteins; Biodegradation, Environmental; Indoles; Oxygenases; Sewage
PubMed: 28778892
DOI: 10.1128/AEM.01453-17 -
Biochimica Et Biophysica Acta.... Jul 2019As lipid microconstituents mainly of plant origin, carotenoids are essential nutrients for humans and animals, and carotenoid coloration represents an important meat...
As lipid microconstituents mainly of plant origin, carotenoids are essential nutrients for humans and animals, and carotenoid coloration represents an important meat quality parameter for many farmed animals. Currently, the mechanism of carotenoid bioavailability in animals is largely unknown mainly due to the limited approaches applied, the shortage of suitable model systems and the restricted taxonomic focus. The mollusk Yesso scallop (Patinopecten yessoensis) possessing orange adductor muscle with carotenoid deposition, provides a unique opportunity to research the mechanism underlying carotenoid utilization in animals. Herein, through family construction and analysis, we found that carotenoid coloration in scallop muscle is inherited as a recessive Mendelian trait. Using a combination of genomic approaches, we mapped this trait onto chromosome 8, where PyBCO-like 1 encoding carotenoid oxygenase was the only differentially expressed gene between the white and orange muscles (FDR = 2.75E-21), with 11.28-fold downregulation in the orange muscle. Further functional assays showed that PyBCO-like 1 is capable of degrading β-carotene, and inhibiting PyBCO-like 1 expression in the white muscle resulted in muscle coloration and carotenoid deposition. In the hepatopancreas, which is the organ for digestion and absorption, neither the scallop carotenoid concentration nor PyBCO-like 1 expression were significantly different between the two scallops. These results indicate that carotenoids could be taken up in both white- and orange-muscle scallops and then degraded by PyBCO-like 1 in the white muscle. Our data suggest that PyBCO-like 1 is the essential gene for carotenoid metabolism in scallop muscle, and its downregulation leads to carotenoid deposition and muscle coloration.
Topics: Animals; Carotenoids; Chromosomes; Color; Muscle, Skeletal; Oxygenases; Pectinidae
PubMed: 30858126
DOI: 10.1016/j.bbalip.2019.03.003 -
Journal of Biological Inorganic... Apr 2017Since our initial report in 1976, the oxygen rebound mechanism has become the consensus mechanistic feature for an expanding variety of enzymatic C-H functionalization... (Review)
Review
Since our initial report in 1976, the oxygen rebound mechanism has become the consensus mechanistic feature for an expanding variety of enzymatic C-H functionalization reactions and small molecule biomimetic catalysts. For both the biotransformations and models, an initial hydrogen atom abstraction from the substrate (R-H) by high-valent iron-oxo species (Fe=O) generates a substrate radical and a reduced iron hydroxide, [Fe-OH ·R]. This caged radical pair then evolves on a complicated energy landscape through a number of reaction pathways, such as oxygen rebound to form R-OH, rebound to a non-oxygen atom affording R-X, electron transfer of the incipient radical to yield a carbocation, R, desaturation to form olefins, and radical cage escape. These various flavors of the rebound process, often in competition with each other, give rise to the wide range of C-H functionalization reactions performed by iron-containing oxygenases. In this review, we first recount the history of radical rebound mechanisms, their general features, and key intermediates involved. We will discuss in detail the factors that affect the behavior of the initial caged radical pair and the lifetimes of the incipient substrate radicals. Several representative examples of enzymatic C-H transformations are selected to illustrate how the behaviors of the radical pair [Fe-OH ·R] determine the eventual reaction outcome. Finally, we discuss the powerful potential of "radical rebound" processes as a general paradigm for developing novel C-H functionalization reactions with synthetic, biomimetic catalysts. We envision that new chemistry will continue to arise by bridging enzymatic "radical rebound" with synthetic organic chemistry.
Topics: Biotransformation; Carbon; Ferric Compounds; Hydrogen; Hydroxylation; Oxygenases
PubMed: 27909920
DOI: 10.1007/s00775-016-1414-3 -
Biochemistry Dec 2018Members of the orthosomycin family of natural products are decorated polysaccharides with potent antibiotic activity and complex biosynthetic pathways. The defining...
Members of the orthosomycin family of natural products are decorated polysaccharides with potent antibiotic activity and complex biosynthetic pathways. The defining feature of the orthosomycins is an orthoester linkage between carbohydrate moieties that is necessary for antibiotic activity and is likely formed by a family of conserved oxygenases. Everninomicins are octasaccharide orthosomycins produced by Micromonospora carbonacea that have two orthoester linkages and a methylenedioxy bridge, three features whose formation logically requires oxidative chemistry. Correspondingly, the evd gene cluster encoding everninomicin D encodes two monofunctional nonheme iron, α-ketoglutarate-dependent oxygenases and one bifunctional enzyme with an N-terminal methyltransferase domain and a C-terminal oxygenase domain. To investigate whether the activities of these domains are linked in the bifunctional enzyme EvdMO1, we determined the structure of the N-terminal methyltransferase domain to 1.1 Å and that of the full-length protein to 3.35 Å resolution. Both domains of EvdMO1 adopt the canonical folds of their respective superfamilies and are connected by a short linker. Each domain's active site is oriented such that it faces away from the other domain, and there is no evidence of a channel connecting the two. Our results support EvdMO1 working as a bifunctional enzyme with independent catalytic activities.
Topics: Amino Acid Sequence; Aminoglycosides; Bacterial Proteins; Biosynthetic Pathways; Catalytic Domain; Conserved Sequence; Crystallography, X-Ray; Gene Fusion; Genes, Bacterial; Methyltransferases; Micromonospora; Models, Molecular; Oxygenases; Protein Interaction Domains and Motifs; Sequence Homology, Amino Acid
PubMed: 30525509
DOI: 10.1021/acs.biochem.8b00836 -
The Journal of General and Applied... 2015Nitro group-containing natural products are rare in nature. There are few examples of N-oxygenases, enzymes that incorporate atmospheric oxygen into primary and...
Nitro group-containing natural products are rare in nature. There are few examples of N-oxygenases, enzymes that incorporate atmospheric oxygen into primary and secondary amines, characterized in the literature. N-oxygenases have yet to be characterized from the Corynebacterineae, a metabolically diverse group of organisms that includes the genera Rhodococcus, Gordonia, and Mycobacterium. A preliminary in silico search for N-oxygenase AurF gene orthologs revealed multiple protein candidates present in the genome of the Actinomycete Rhodococcus jostii RHAI (RHAI_ro06104). Towards the goal of identifying novel biocatalysts with potential utility for the biosynthesis of nitroaromatics, AurF ortholog RHAI_ro6104 was cloned, expressed and purified in E. coli and amine and nitro containing phenol substrates tested for activity. RHAI-ro06104 showed the highest activity with 4-aminophenol, producing a Vmax of 18.76 μM s(-1) and a Km of 15.29 mM and demonstrated significant activities with 2-aminophenol and 2-amino-5-methylphenol, producing a Vmax of 12.86 and 12.72 μM s(-1) with a Km of 8.34 and 2.81 mM, respectively. These findings are consistent with a substrate range observed in other N-oxygenases, which seem to accommodate substrates that lack halogenated substitutions and side groups directly flanking the amine group. Attempts to identify modulators of RHAI-ro06104 gene activity demonstrated that aromatic amino acids inhibit expression by almost 50%.
Topics: Aminophenols; Cloning, Molecular; Computational Biology; Escherichia coli; Gene Expression; Kinetics; Nitrophenols; Oxygenases; Rhodococcus; Substrate Specificity
PubMed: 26782651
DOI: 10.2323/jgam.61.217 -
Journal of Microbiology and... Mar 2022The hydroxylation of methane (CH) is crucial to the field of environmental microbiology, owing to the heat capacity of methane, which is much higher than that of carbon...
The hydroxylation of methane (CH) is crucial to the field of environmental microbiology, owing to the heat capacity of methane, which is much higher than that of carbon dioxide (CO). Soluble methane monooxygenase (sMMO), a member of the bacterial multicomponent monooxygenase (BMM) superfamily, is essential for the hydroxylation of specific substrates, including hydroxylase (MMOH), regulatory component (MMOB), and reductase (MMOR). The diiron active site positioned in the MMOH α-subunit is reduced through the interaction of MMOR in the catalytic cycle. The electron transfer pathway, however, is not yet fully understood due to the absence of complex structures with reductases. A type II methanotroph, 5, successfully expressed sMMO and hydroxylase, which were purified for the study of the mechanisms. Studies on the MMOH-MMOB interaction have demonstrated that Tyr76 and Trp78 induce hydrophobic interactions through π-π stacking. Structural analysis and sequencing of the ferredoxin domain in MMOR (MMOR-Fd) suggested that Tyr93 and Tyr95 could be key residues for electron transfer. Mutational studies of these residues have shown that the concentrations of flavin adenine dinucleotide (FAD) and iron ions are changed. The measurements of dissociation constants (Ks) between hydroxylase and mutated reductases confirmed that the binding affinities were not significantly changed, although the specific enzyme activities were significantly reduced by MMOR-Y93A. This result shows that Tyr93 could be a crucial residue for the electron transfer route at the interface between hydroxylase and reductase.
Topics: Electron Transport; Electrons; Methane; Mixed Function Oxygenases; Oxygenases
PubMed: 35131957
DOI: 10.4014/jmb.2201.01029