Incorporation of oxygen into the succinate co‐product of iron(II) and 2‐oxoglutarate dependent oxygenases from bacteria, plants and humans

Welford, Richard W. D.; Kirkpatrick, Joanna; McNeill, Luke A.; Puri, Munish; Oldham, Neil J.; Schofield, Christopher J.

doi:10.1016/j.febslet.2005.08.033

Cited by 32 publications

(28 citation statements)

References 31 publications

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“…It represents a wide diversity of enzymes that catalyze the hydroxylation of unactivated C-H groups of a variety of substrates by coupling reductive activation of dioxygen with a decarbox-ylation of αKG, the co-substrate, to succinate. In the event of oxidation one of the oxygen atoms from O 2 is incorporated into the succinate and the other as a hydroxyl in the product [24]. This group of enzymes is known for their importance in many environmental, pharmacological, and medical fields, and many of these reactions have not been successfully performed in the laboratory, especially ones involving the functionalization of inert C-H bonds.…”

Section: E Coli Alkbmentioning

confidence: 99%

Oxidative dealkylation DNA repair mediated by the mononuclear non-heme iron AlkB proteins

Mishina

2006

Journal of Inorganic Biochemistry

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DNA can be damaged by various intracellular and environmental alkylating agents to produce alkylation base lesions. These base damages, if not repaired promptly, may cause genetic changes that lead to diseases such as cancer. Recently, it was discovered that some of the alkylation DNA base damage can be directly removed by a family of proteins called the AlkB proteins that utilize a mononuclear non-heme iron(II) and α-ketoglutarate as cofactor and cosubstrate. These proteins activate dioxygen and perform an unprecedented oxidative deal-kylation of the alkyl adducts on DNA heteroatoms. This review summarizes the discovery of this activity and the recent research advances in studying this unique DNA repair pathway. The focus is placed on the chemical mechanism and function of these proteins. KeywordsDNA repair; AlkB; ABH; Direct repair; Mononuclear non-heme iron; Dioxygenase; Oxidative dealkylation; Demethylation Direct repair of alkylation DNA damageCellular DNA is subject to nonenzymatic alkylation (methylation) by environmental or chemical mutagens, resulting in adducts that are toxic and mutagenic [1][2][3][4][5][6]. Organisms have evolved a variety of mechanisms to repair these mutagenic damages. Escherichia coli (E. coli) responds to this threat by activating an adaptive responsive pathway, mediated by the E. coli Ada protein [7]. Upon receiving a methyl group from the damaged DNA, Ada turns into a transcriptional activator and activates its own expression and that of the alkB gene and two other genes, alkA and aidB ( Fig. 1(a)) [4,7,8]. The upregulated Ada is a bifunctional protein, which uses a N-terminal Cys38 residue to remove a methyl group fromS p -methylphosphotriester and a C-terminal Cys321 residue to remove a methyl adduct from O 6 -methylguanaine ( Fig. 1(b)) [9][10][11]. Both repair functions are irreversible and represent rare examples of direct repair of DNA damage. AlkA is a glycosylase that cleaves methylated bases from DNA and performs the first step of the well-known base excision repair of base lesions [12][13][14]. The precise function of AidB is still unknown. The function of the last member of this adaptive response, AlkB, also remained unknown until recently despite extensive research efforts. E. coli AlkBSince the first genetic study in 1983 isolating the E. coli mutant with specific sensitivity to the alkylating agent methylmethane sulfonate, MMS [15], the activity of AlkB was undisclosed The Fe II /αKG-dependent dioxygenase superfamily is widespread from bacteria to humans [19] and is the largest known non-heme iron protein family [20][21][22][23]. It represents a wide diversity of enzymes that catalyze the hydroxylation of unactivated C-H groups of a variety of substrates by coupling reductive activation of dioxygen with a decarbox-ylation of αKG, the co-substrate, to succinate. In the event of oxidation one of the oxygen atoms from O 2 is incorporated into the succinate and the other as a hydroxyl in the product [24]. This group of enzymes is known for their importance in ...

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Section: E Coli Alkbmentioning

confidence: 99%

Oxidative dealkylation DNA repair mediated by the mononuclear non-heme iron AlkB proteins

Mishina

2006

Journal of Inorganic Biochemistry

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“…The four identified human HIF hydroxylases belong to the non-haem Fe(II) and 2OG (2-oxoglutarate) dioxygenase superfamily [3,17,18]. Like most other family members they catalyse the incorporation of one oxygen atom from dioxygen into their alcohol product and one into the succinate co-product [15,19,20].…”

Section: Introductionmentioning

confidence: 99%

Studies on the activity of the hypoxia-inducible-factor hydroxylases using an oxygen consumption assay

Ehrismann

Flashman

Genn

et al. 2006

Biochemical Journal

196

170

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cMyBP-C [cardiac (MyBP-C) myosin-binding protein-C)] is a sarcomeric protein involved both in thick filament structure and in the regulation of contractility. It is composed of eight IgI-like and three fibronectin-3-like domains (termed C0-C10). Mutations in the gene encoding cMyBP-C are a principal cause of HCM (hypertrophic cardiomyopathy). cMyBP-C binds to the LMM (light meromyosin) portion of the myosin rod via its C-terminal domain, C10. We investigated this interaction in detail to determine whether HCM mutations in beta myosin heavy chain located within the LMM portion alter the binding of cMyBP-C, and to define the precise region of LMM that binds C10 to aid in developing models of the arrangement of MyBP-C on the thick filament. In co-sedimentation experiments recombinant C10 bound full-length LMM with a K(d) of 3.52 microM and at a stoichiometry of 1.14 C10 per LMM. C10 was also shown to bind with similar affinity to LMM containing either the HCM mutations A1379T or S1776G, suggesting that these HCM mutations do not perturb C10 binding. Using a range of N-terminally truncated LMM fragments, the cMyBP-C-binding site on LMM was shown to lie between residues 1554 and 1581. Since it had been reported previously that acidic residues on myosin mediate the C10 interaction, three clusters of acidic amino acids (Glu1554/Glu1555, Glu1571/Glu1573 and Glu1578/Asp1580/Glu1581/Glu1582) were mutated in full-length LMM and the proteins tested for C10 binding. No effect of these mutations on C10 binding was however detected. We interpret our results with respect to the localization of the proposed trimeric collar on the thick filament.

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“…The amino acid sequence of EctD possesses this type of iron-binding motif [5], [7], [16], [17] and EctD catalyzes an enzymatic reaction [5], [7] that is common in non-heme iron(II)-containing and 2-oxoglutarate-dependent dioxygenases [38]. In this reaction, the O 2 -dependent hydroxylation of the substrate ectoine is accompanied by the oxidative decarboxylation of 2-oxoglutarate to form succinate and CO 2 (Figure 1).…”

Section: Introductionmentioning

confidence: 99%

Synthesis of 5-Hydroxyectoine from Ectoine: Crystal Structure of the Non-Heme Iron(II) and 2-Oxoglutarate-Dependent Dioxygenase EctD

et al. 2010

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As a response to high osmolality, many microorganisms synthesize various types of compatible solutes. These organic osmolytes aid in offsetting the detrimental effects of low water activity on cell physiology. One of these compatible solutes is ectoine. A sub-group of the ectoine producer's enzymatically convert this tetrahydropyrimidine into a hydroxylated derivative, 5-hydroxyectoine. This compound also functions as an effective osmostress protectant and compatible solute but it possesses properties that differ in several aspects from those of ectoine. The enzyme responsible for ectoine hydroxylation (EctD) is a member of the non-heme iron(II)-containing and 2-oxoglutarate-dependent dioxygenases (EC 1.14.11). These enzymes couple the decarboxylation of 2-oxoglutarate with the formation of a high-energy ferryl-oxo intermediate to catalyze the oxidation of the bound organic substrate. We report here the crystal structure of the ectoine hydroxylase EctD from the moderate halophile Virgibacillus salexigens in complex with Fe3+ at a resolution of 1.85 Å. Like other non-heme iron(II) and 2-oxoglutarate dependent dioxygenases, the core of the EctD structure consists of a double-stranded β-helix forming the main portion of the active-site of the enzyme. The positioning of the iron ligand in the active-site of EctD is mediated by an evolutionarily conserved 2-His-1-carboxylate iron-binding motif. The side chains of the three residues forming this iron-binding site protrude into a deep cavity in the EctD structure that also harbours the 2-oxoglutarate co-substrate-binding site. Database searches revealed a widespread occurrence of EctD-type proteins in members of the Bacteria but only in a single representative of the Archaea, the marine crenarchaeon Nitrosopumilus maritimus. The EctD crystal structure reported here can serve as a template to guide further biochemical and structural studies of this biotechnologically interesting enzyme family.

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Incorporation of oxygen into the succinate co‐product of iron(II) and 2‐oxoglutarate dependent oxygenases from bacteria, plants and humans

Cited by 32 publications

References 31 publications

Oxidative dealkylation DNA repair mediated by the mononuclear non-heme iron AlkB proteins

Oxidative dealkylation DNA repair mediated by the mononuclear non-heme iron AlkB proteins

Studies on the activity of the hypoxia-inducible-factor hydroxylases using an oxygen consumption assay

Synthesis of 5-Hydroxyectoine from Ectoine: Crystal Structure of the Non-Heme Iron(II) and 2-Oxoglutarate-Dependent Dioxygenase EctD

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