Harnessing the Mechanism of Glutathione Reductase for Synthesis of Active Site Bound Metallic Nanoparticles and Electrical Connection to Electrodes

Scott, Daniel; Toney, Michael D.; Muzikář, Martin

doi:10.1021/ja074660g

Cited by 77 publications

(71 citation statements)

References 32 publications

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“…These types of proteins are ubiquitous membrane proteins that facilitate unidirectional substrate translocation across the lipid bilayer by utilizing the energy obtained from the hydrolysis of ATP and have been found to be very diverse with respect to their physiological function and substrate unlike oxidoreductases which mainly catalyse oxidation-reduction reactions coupled to NADP/NAD + utilization [43][44][45]. Subsequent cloning and sequencing of the gene revealed the presence of a disulphide bond (between amino acid 337C and 481C) which confirms the hypothesis of Scott and coworkers [34], implicating an electron shuttle mechanism via a reduced disulphide bridge. This is further supported by the work done by Cason and co-workers [46] who found that reduction of the disulphide bonds resulted in electron transfer to a metal, in their case U(VI).…”

Section: Nanoparticles From Cell-free Extractssupporting

confidence: 74%

“…This was shown by Cason and co-workers [46] as well as Scott and co-workers [34]. Varying dithionite concentrations revealed that a stoichiometric ratio of less than 1:1 (4.6 μM sodium dithionite to protein) resulted in particles with defined edges.…”

Section: Au(iii): Reductant Ratiomentioning

confidence: 65%

“…Proteins present in cell-free extracts were routinely assayed for gold reducing ability by incubating the sample with 2 mM HAuCl 4 in 50 mM sodium phosphate buffer (pH 7.4) at 65°C for 24 h. Nanoparticle synthesis using the purified protein was performed under the same reaction conditions but with 4.6 μM sodium dithionite [33] added as a reducing agent [34]. In a living cell, natural reductants are present that are capable of reducing co-factors and in this case the disulphide bridge present in the protein, but these are absent in the purified protein fractions; thus, the reductant facilitates the reduced state of the protein.…”

Section: Microorganisms and Growthmentioning

confidence: 99%

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Gold nanoparticle synthesis using the thermophilic bacterium Thermus scotoductus SA-01 and the purification and characterization of its unusual gold reducing protein

et al. 2014

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Nanoparticles are very important materials for implementing nanotechnology in diverse areas and are abundant in nature as living organisms operate at a nanoscale. As nanoparticles exhibit interesting size-and shape-dependent physical and chemical properties, the synthesis of uniform nanoparticles with controlled sizes and shapes is of great importance. Nanoparticles are the end products of a wide variety of physical, chemical and biological processes, some of which are novel and radically different and others of which are quite commonplace. The ability to produce nanoparticles with specific shapes and controlled sizes could result in interesting new applications that can potentially be utilized in areas such as optics, electronics and the biomedical field. In the present study, we have demonstrated the ability of the thermophilic bacterium Thermus scotoductus SA-01 to synthesize gold nanoparticles and determined the effect of the physico-chemical parameters on particle synthesis. Furthermore, a protein purified from this bacterium is shown to be capable of reducing HAuCl 4 to form elemental nanoparticles in vitro. The protein was purified to homogeneity and identified through N-terminal sequencing as an ABC transporter, peptidebinding protein. It is speculated that this protein reduces Au(III) through an electron shuttle mechanism involving a cysteine disulphide bridge. Through manipulation of physico-chemical parameters, it was possible to vary nanoparticles in terms of number, shape and size. This is the first report of a transporter protein from a thermophile with the ability to produce nanoparticles in vitro thus expanding the limited knowledge around biological gold nanoparticle synthesis.

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Section: Nanoparticles From Cell-free Extractssupporting

confidence: 74%

Section: Au(iii): Reductant Ratiomentioning

confidence: 65%

Section: Microorganisms and Growthmentioning

confidence: 99%

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Gold nanoparticle synthesis using the thermophilic bacterium Thermus scotoductus SA-01 and the purification and characterization of its unusual gold reducing protein

et al. 2014

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“…36 More recently, electrode surfaces prepared from nanomaterials facilitated protein ET have attracted particular interest due to excellent electrical conductivity, tunable surface chemistry and morphology. 37 Several groups reported that gold nanoparticles (AuNP) and carbon nanotubes (CNT) can serve as electron relays to electrically wire a range of redox proteins (e.g., cytochrome c (Cyt c), 38,39 glucose oxidase (GOD), 40 glutathione reductase, 41 and hydrogenase 23,42 to electrodes. Analogously, "molecular-wire"-like conjugated oligomers were also employed to wire the deeply buried redox site of a copper amine oxidase to a gold electrode.…”

Section: Introductionmentioning

confidence: 99%

Probing the nature of electron transfer in metalloproteins on graphene-family materials as nanobiocatalytic scaffold using electrochemistry

Gupta

Irihamye

2015

AIP Advances

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Graphene-based nanomaterials have shown great promise not only in nanoelectronics due to ultrahigh electron mobility but also as biocatalytic scaffolds owing to irreversible protein surface adsorption and facilitating direct electron transfer. In this work, we synthesized stable dispersions of graphene using liquid-phase exfoliation approach based on non-covalent interactions between graphene and 1-pyrenesulfonic acid sodium salt (Py–1SO3), 1-pyrenemethylamine salt (Py − Me-NH2) and Pluronic® P-123 surfactant using only water as solvent compatible with biomolecules. The resulting graphene nanoplatelets (Gr_LPE) are characterized by a combination of analytical (microscopy and spectroscopy) techniques revealing mono- to few-layer graphene displaying that the exfoliation efficiency strongly depends upon the type of pyrene-based salts and organic surfactants. Moreover being completely water-based approach, we build robust nanoscaffolds of graphene-family nanomaterials (GFNs) namely, monolayer graphene, Gr_LPE (the one prepared with Pluronic® P-123), graphene oxide (GO) and its reduced form (rGO) on glassy carbon electrode surface with three important metalloproteins include cytochrome c (Cyt c) [for electron transfer], myoglobin (Mb) [for oxygen storage] and horseradish peroxidase (HRP) [for catalyzing the biochemical reaction]. In order to demonstrate the nanobiocatalytical activity of these proteins, we used electrochemical interfacial direct electron transfer (DET) kinetics and attempt to determine the rate constant (kET) using two different analytical approaches namely, linear sweep voltammetry and Laviron’s theory. We elucidated that all of the metalloproteins retain their structural integrity (secondary structure) upon forming mixtures with GFNs confirmed through optical and vibrational spectroscopy and biological activity using electrochemistry. Among the GFNs studied, Gr-LPE, GO and rGO support the efficient electrical wiring of the redox centers (with an increase in catalytic efficiency of Cyt c and Mb in the presence of GFNs attributed partially to the surface functional (carboxyl, epoxide and hydroxyl) groups on GO and rGO facilitating rapid charge transfer.

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“…[16][17][18][19] GSHR is reported to reduce Au(III) to zerovalent form as well. 20 Thus, the class of pyridine nucleoside dependent oxidoreductases may represent an evolutionarily adaptable platform of inorganic ion reductases, with modifications to the enzyme altering metal ion selectivity. Such a catalytic center, with alterable precursor selectivity, is of interest in biogenic inorganic nanoparticle synthesis.…”

mentioning

confidence: 99%

The Metalloid Reductase of Pseudomonas Moravenis Stanleyae Conveys Nanoparticle Mediated Metalloid Tolerance

Nemeth

Neubert²,

Ni³

et al. 2018

Preprint

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When cultured independently in liquid media, it tolerates SeO 3 2-supplementation in liquid culture up to 10mM. This is 10-fold more than the SeO 3 2-tolerance of most other microbes. We attributed the observed selenite reduction activity of P. moravenis to a GSHR-like enzyme on the basis of proteomic mass spectrometry of an in-gel in situ selenium reductase activity.GSHRs generally belong to the family of pyridine nucleoside dependent oxidoreductases.This enzyme family also, notably, includes another well-characterized metal reducing enzyme -- 4In prior study, we characterized commercially sourced Saccharomyces Cervisiae (S. Cervisiae) GSHR for selenite reductase activity, showing the ability of the enzyme to oxidize NADPH while reducing SeO 3 2-to Se(0) nanoparticles. 13 In the present study, we characterize a homologous metalloid reductase from the seleno-specialist P. moravenis. We find that the substrate selectivity of the metalloid reductase (K M ) shows a substantially larger preference for GS-Se-SG relative to all other reported glutathione reductase enzymes. These enzymatic properties can be partially rationalized in terms of sequence and corresponding homologymodeled structure of the enzyme. We also observe that expressing this enzyme in laboratory strains of E. Coli (BL21, SS320) results in increased tolerance to SeO 3 2-, as well as the presence of Se nanoparticles in these cells. Overall, our data suggests that the enzyme may be best described as a glutathione reductase-like-metalloid reductase (GRLMR). RESULTS AND DISCUSSIONAltered substrate specificity of GRLMR enzymes, favoring selenodiglutathione (GS-Se-SG) over oxidized glutathione (GSSG) as a substrate could underlie the remarkable SeO 3 2-tolerance of P. Moravenis stanleyae. We therefore characterized the P. Moravenis stanleyae GRLMR enzyme identified previously. The DNA sequence of the enzyme was acquired through a fullgenome sequencing (ACGT Inc,Wheeling, IL). Sequencing was conducted using de novo paired end sequencing. 21 This revealed a genome where 70.3% of the nucleobases have, at the most, a 1:1000 probability of mis-assignment. Figure S1 shows the "Quality Score" (Q score) for each sequenced base with Q=-log10(e). Q scores, are derived from a phred-like error probability assessment of each individual nucleotide. 5A BLAST search of the genomic sequence, using the Pseudomonas R-28S GSHR as a reference, identified one GSHR-like sequence, with 93% sequence homology. Sequence alignment of this GRLMR DNA using Serial Cloner show high similarity (98.00%) toPseudomonas fluorescines (P. fluorescines) GSHR and modest similarity (67 -71%) to E. coli, S. cervisiae, and Homo sapiens (H. sapiens) GSHR DNA. The sequence similarities are summarized in Table 1, and full alignments are shown in the supporting information, Figure S2.The DNA sequence, combined with homology modeling of the structure suggest that all of the

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Harnessing the Mechanism of Glutathione Reductase for Synthesis of Active Site Bound Metallic Nanoparticles and Electrical Connection to Electrodes

Cited by 77 publications

References 32 publications

Gold nanoparticle synthesis using the thermophilic bacterium Thermus scotoductus SA-01 and the purification and characterization of its unusual gold reducing protein

Gold nanoparticle synthesis using the thermophilic bacterium Thermus scotoductus SA-01 and the purification and characterization of its unusual gold reducing protein

Probing the nature of electron transfer in metalloproteins on graphene-family materials as nanobiocatalytic scaffold using electrochemistry

The Metalloid Reductase of Pseudomonas Moravenis Stanleyae Conveys Nanoparticle Mediated Metalloid Tolerance

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