All intermediates of the arsenate reductase mechanism, including an intramolecular dynamic disulfide cascade

Messens, Joris; Martins, José; Belle, Karolien Van; Brosens, Elke; Desmyter, Aline; Gieter, M. De; Wieruszeski, Jean‐Michel; Wyns, Lode; Zegers, Ingrid

doi:10.1073/pnas.132142799

Cited by 72 publications

(137 citation statements)

References 40 publications

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“…The reversible conformational transitions monitored by two-dimensional NMR spectroscopy along with the catalytic reaction provide insights into the mechanism of arsenate reduction. A similar result regarding the conformational switch in S. aureus ArsC was reported previously (18).…”

Section: Characteristics Of the Reduced And Oxidized Forms Of B Subtsupporting

confidence: 90%

“…between them are 1.38 and 1.51 Å for 130 pairs of C ␣ atoms determined using DALI (39). The conservation of the P-loop and the three essential cysteine residues (Cys 10 , Cys 82 , and Cys 89 ) suggests that they may share a similar catalytic mechanism of arsenate reduction (18,22). A previous study demonstrated that the arsenate reduction activity of S. aureus ArsC takes place via a triple disulfide cascade involving three cysteines (Cys 10 , Cys 82 , and Cys 89 ) (18).…”

Section: Solution Structures Of the Reduced And Oxidized Forms Of B mentioning

confidence: 95%

“…Several families of ArsC have been identified and characterized (10 -14). Among these, Staphylococcus aureus ArsC has been extensively studied (8,(15)(16)(17)(18)(19)(20)(21). These studies revealed that three redox active cysteine residues (Cys 10 , Cys 82 , and Cys 89 ) are critical for arsenate reduction.…”

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confidence: 99%

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Solution Structures and Backbone Dynamics of Arsenate Reductase from Bacillus subtilis

Guo

Peng

et al. 2005

Journal of Biological Chemistry

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Arsenate reductase encoded by the chromosomal arsC gene in Bacillus subtilis catalyzes the intracellular reduction of arsenate to arsenite, which is then extruded from cells through an efficient and specific transport system. Herein, we present the solution structures and backbone dynamics of both the reduced and oxidized forms of arsenate reductase from B. subtilis. The overall structures of both forms are similar to those of bovine low molecular weight protein-tyrosine phosphatase and arsenate reductase from Staphylococcus aureus. However, several features of the tertiary structure and mobility are notably different between the reduced and oxidized forms of B. subtilis arsenate reductase, particularly in the P-loop region and the segment Cys 82 -Cys 89 . The backbone dynamics results demonstrated that the reduced form of arsenate reductase undergoes millisecond conformational changes in the functional P-loop and Cys 82 -Cys 89 , which may facilitate the formation of covalent intermediates and subsequent reduction of arsenate. In the oxidized form, Cys 82 -Cys 89 shows motional flexibility on both picosecond-to-nanosecond and possibly millisecond time scales, which may facilitate the reduction of the oxidized enzyme by thioredoxin to regenerate the active enzyme. Overall, the internal dynamics and static structures of the enzyme provide insights into the molecular mechanism of arsenate reduction, especially the reversible conformational switch and changes in internal motions associated with the catalytic reaction.

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Section: Characteristics Of the Reduced And Oxidized Forms Of B Subtsupporting

confidence: 90%

Section: Solution Structures Of the Reduced And Oxidized Forms Of B mentioning

confidence: 95%

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Solution Structures and Backbone Dynamics of Arsenate Reductase from Bacillus subtilis

Guo

Peng

et al. 2005

Journal of Biological Chemistry

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“…The structure of the ArsA component of the ATP-dependent extrusion pump ArsAB with antimonite bound in close proximity to the nucleotide-binding site was able to provide some insight into the active transport of As(III) out of the cell (2). Additionally, structural characterization of substrate and product complexes of the arsenate reductase ArsC, which reduces arsenate (AsO 4 3Ϫ ) to arsenite (AsO 2 Ϫ ), has helped elucidate this step of the arsenic detoxification pathway (3,4). Recent studies of E. coli ArsD indicate that it is a metallochaperone, transporting As(III) to ArsA for extrusion (5).…”

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confidence: 99%

“…Previously, we have shown that the three-stranded coiled coil TRI peptides [Ac-G(L a K b A c L d E e E f K g ) 4 G-NH 2 ] designed with the heptad repeat strategy, such as TRI L16C (sequences of all peptides are in Table 1), were able to model the unusual trigonal thiolate Hg(II) coordination geometry seen in the MerR metalloregulatory protein (7). We have also examined the binding of the heavy metals Cd(II), Pb(II), and Bi(III) to the TRI peptides to better understand their modes of toxicity (8,9).…”

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confidence: 99%

Identifying important structural characteristics of arsenic resistance proteins by using designed three-stranded coiled coils

Touw

Nordman

Stuckey³

et al. 2007

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

154

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Arsenic, a contaminant of water supplies worldwide, is one of the most toxic inorganic ions. Despite arsenic's health impact, there is relatively little structural detail known about its interactions with proteins. Bacteria such as Escherichia coli have evolved arsenic resistance using the Ars operon that is regulated by ArsR, a repressor protein that dissociates from DNA when As(III) binds. This protein undergoes a critical conformational change upon binding As(III) with three cysteine residues. Unfortunately, structures of ArsR with or without As(III) have not been reported. Alternatively, de novo designed peptides can bind As(III) in an endo configuration within a thiolate-rich environment consistent with that proposed for both ArsR and ArsD. We report the structure of the As(III) complex of Coil Ser L9C to a 1.8-Å resolution, providing x-ray characterization of As(III) in a Tris thiolate protein environment and allowing a structural basis by which to understand arsenated ArsR.arsenic-binding proteins ͉ coiled coil peptides ͉ crystallography ͉ heavy metal toxicity ͉ protein design A rsenic toxicity is a worldwide problem as a natural contaminant of water supplies. Despite the fact that it is a human toxin and carcinogen, few structural reports on its interaction with biological ligands have appeared. Escherichia coli and other bacteria have evolved a detoxification mechanism that employs the arsRDABC operon (1). Arsenic removal by these encoded proteins is initiated when As(III) binds to ArsR, resulting in the dissociation of the repressor protein from the promoter DNA. The structure of the ArsA component of the ATP-dependent extrusion pump ArsAB with antimonite bound in close proximity to the nucleotide-binding site was able to provide some insight into the active transport of As(III) out of the cell (2). Additionally, structural characterization of substrate and product complexes of the arsenate reductase ArsC, which reduces arsenate (AsO 4 3Ϫ ) to arsenite (AsO 2 Ϫ ), has helped elucidate this step of the arsenic detoxification pathway (3, 4). Recent studies of E. coli ArsD indicate that it is a metallochaperone, transporting As(III) to ArsA for extrusion (5). Extended x-ray absorption fine structure and mutagenesis studies have shown that ArsR coordinates As(III) with three cysteine thiolates at a distance of 2.25 Å, a coordination mode that ArsD is also proposed to employ (1, 5). However, no x-ray or NMR structures of ArsR, the repressor protein, or ArsD have been reported to date. Furthermore, AsS 3 structures have not been reported for any biologically relevant small-molecule thiolates, such as glutathione, and only a handful of related AsS 3 complexes with aromatic ligands or chelated alkyl dithiolate coordination are reported (6).We set out to model the putative As(III) coordination environments of ArsR and ArsD in a designed peptide system. Previously, we have shown that the three-stranded coiled coildesigned with the heptad repeat strategy, such as TRI L16C (sequences of all peptides are in Table 1...

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Biomethylation of Arsenic, Antimony and Bismuth

Jenkins

2010

Biological Chemistry of Arsenic, Antimony and Bismuth

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Biomethylation of metals or metalloids refers to the process whereby living organisms cause direct linkage of methyl groups to the metal(loid)s through enzymatic transfer of a preformed methyl group. The attachment of a methyl group to a metal(loid) changes the chemical and physical properties of the element, which in turn influences its mobility, geological cycling and toxicity. Biomethylation of the following metal(loid)s have been definitively established, although for most very little is known about the biological mechanism involved: Cd, Hg, Tl, Ge, Sn, Pb, As, Sb, Bi, Se and Te. The biological systems responsible for metal(loid) biomethylation are almost exclusively microorganisms. Anaerobic prokaryotes, operating in anoxic environments such as sediments from environmental waters and landfill sites, are major biocatalysts of metal(loid) biomethylation in the natural environment. Methylmetal(loid)s have also been shown to occur in soils from disparate locations and some aerobic and facultatively anaerobic bacteria, fungi and lower algae have been shown to be capable of metal(loid) biomethylation. Although higher organisms have not been shown to biomethylate true metals, methyl derivatives of some metalloids (including those of Se and As) are formed in a wide range of higher animals and plants.Over the past decade there has been a diversification of methods for the detection and measurement of organometallic compounds. Generally, this has been accompanied by improvements in reliability of detection and measurement of organometal(loid)s at low

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All intermediates of the arsenate reductase mechanism, including an intramolecular dynamic disulfide cascade

Cited by 72 publications

References 40 publications

Solution Structures and Backbone Dynamics of Arsenate Reductase from Bacillus subtilis

Solution Structures and Backbone Dynamics of Arsenate Reductase from Bacillus subtilis

Identifying important structural characteristics of arsenic resistance proteins by using designed three-stranded coiled coils

Biomethylation of Arsenic, Antimony and Bismuth

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