Methylmercury(II) binding to single-stranded and duplex DNA: complexes formed are distinguishable by optical detection of magnetic resonance spectroscopy.

Maki, August H.; Ott, Christopher M.

doi:10.1073/pnas.78.5.2972

Cited by 6 publications

(8 citation statements)

References 14 publications

(20 reference statements)

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“…Also, addition of Hg 2+ to a 1 μM solution of FMN causes a linear decrease in I PL with increasing Hg 2+ concentration (the red trace of Figure e), whereas addition of this metal ion to a 10 μM FMN solution results in an exponential decrease in the PL intensity. Moreover, the fact that addition of a 10-fold excess of Hg 2+ , which should promote predominant formation of the 1:1 complex, does not completely quench the PL of FMN suggests that, along with chemical bonding with FMN, Hg 2+ might be involved in modulation of the aggregation state of FMN. , Hg(II) is known to bind with bases of DNA and RNA, resulting in quenching of nucleotide PL owing to the heavy-atom effect . This is the primary reason for quenching of FMN PL.…”

Section: Resultsmentioning

confidence: 99%

“…Moreover, the fact that addition of a 10-fold excess of Hg 2+ , which should promote predominant formation of the 1:1 complex, does not completely quench the PL of FMN suggests that, along with chemical bonding with FMN, Hg 2+ might be involved in modulation of the aggregation state of FMN. 48,49 Hg(II) is known to bind with bases of DNA and RNA, 50 resulting in quenching of nucleotide PL owing to the heavy-atom effect. 51 This is the primary reason for quenching of FMN PL.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

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Helical Assembly of Flavin Mononucleotides on Carbon Nanotubes as Multimodal Near-IR Hg(II)-Selective Probes

Park

Hong

Jin

et al. 2019

ACS Appl. Mater. Interfaces

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The development of novel methods to detect mercury is of paramount importance owing to the impact of this metal on human health and the environment. We observed that flavin mononucleotide (FMN) and its helical assembly with a single-walled carbon nanotube (SWNT) selectively bind Hg2+ arising from HgCl2 and MeHgCl. Absorption spectroscopic studies show that FMN preferentially forms a 2:1 rather than a 1:1 complex with Hg2+ at high FMN concentrations. On the basis of the analogy to the thymine–Hg–thymine complex, it is proposed that the 2:1 complex between FMN and Hg2+ comprises a Hg-bridged pair of FMN groups, regardless of the presence of SWNT. Upon addition of as little as a few hundred nanomoles of Hg2+, both FMN and FMN–SWNT exhibit absorption and photoluminescence (PL) changes. Moreover, FMN–SWNT displays simultaneous multiple sigmoidal changes in PL of SWNT tubes having different chiral vectors. Assessment of binding affinities using the Hill equation suggests that 2:1 and 1:1 complexes form between Hg2+ and FMN groups on the FMN–SWNT. Theoretical calculations indicate that optical changes of the FMN–SWNT originate from Hg-mediated conformational changes occurring on the helical array of FMN on the SWNT. High-resolution transmission electron microscopy revealed that the presence of Hg2+ in complexes with the FMN–SWNT enables visualization of helical periodic undulation of FMN groups along SWNT without the need for staining. Circular dichroism (CD) study revealed that FMN–SWNT whose CD signal mainly originates from FMN decreases dichroic bands upon the addition of Hg2+ owing to the formation of a centrosymmetric FMN–Hg–FMN triad on SWNT. The binding mode specificity and multimodal changes observed in response to Hg2+ ions suggest that systems based on FMN–SWNT can serve as in vivo NIR beacons for the detection of various mercury derivatives.

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Section: Resultsmentioning

confidence: 99%

Section: ■ Results and Discussionmentioning

confidence: 99%

Helical Assembly of Flavin Mononucleotides on Carbon Nanotubes as Multimodal Near-IR Hg(II)-Selective Probes

Park

Hong

Jin

et al. 2019

ACS Appl. Mater. Interfaces

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“…Higher generation PAMAMs possessed more primary amine groups on the surfaces available for DNA immobilization, and hence enhanced removal capacities and efficiencies were expected. Regarding MeHg(I), however, it coordinated most strongly at the N3 site of thymine and somewhat less tightly at the N1 site of guanine, which were involved in Watson‐Crick base pairing of the DNA duplex. Therefore, coordination between MeHg(I) and normal‐structured DNA duplex was theoretically not very strong.…”

Section: Resultsmentioning

confidence: 99%

DNA fragments assembled on polyamidoamine‐grafted core‐shell magnetic silica nanoparticles for removal of mercury(II) and methylmercury(I)

Liang

et al. 2016

J of Chemical Tech & Biotech

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BACKGROUND Hg(II) and MeHg(I) are toxic pollutants causing wide concerns. Polyamidoamine‐grafted magnetic silica nanoparticles (Fe3O4‐SiO2‐PAMAMs) were synthesized as beads, on which herring sperm DNA fragments were immobilized as reacting moieties for removal of Hg(II) and MeHg(I) from water matrices. The factors influencing the removal, such as DNA fragments, generation of the polyamidoamine spacers and pH, were studied. Further, the adsorption mechanisms were explored by means of adsorption kinetics and isotherms. RESULTS Assembling DNA fragments on the polyamidoamine‐grafted beads promoted sharply the removal of both Hg(II) and MeHg(I). Adsorptions of Hg(II) and MeHg(I) followed pseudo‐second‐order kinetics; but their adsorption isotherms obeyed Langmuir and Freundlich models, respectively. Under the optimum conditions, the adsorption equilibrium time was approximately 5 min for Hg(II) and 5 s for MeHg(I) with maximum percentage removals of ∼95% and ∼90%, respectively. The adsorbent could be regenerated easily without significant decrease in removal efficiencies. CONCLUSION The Fe3O4‐SiO2‐PAMAM beads could bind DNA steadily, and the DNA fragments interacted strongly with mercury species. The strategy enabled the water‐soluble DNAs to work as efficient removing reagents for rapid and cost‐effective removal of Hg(II) and MeHg(I). © 2016 Society of Chemical Industry

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“…In support of these conclusions, at the in vivo morphologic studies of Moller-Madsen ( 1990 , 1991 ) in which it is shown that CH3Hg+ deposits extensively throughout the CNS of rodents after administration via intraperitoneal and oral routes. It can be postulated that, upon permeation of barriers, the final common pathway underlying the mechanism of intracellular CH3Hg+ toxicity is genotoxicity (Grotto et al 2009 ) due to its covalent binding of DNA (Maki and Ott 1981 ) and disruption of transcription pathways, leading to cellular instability and cell death. Exposure to significant doses of CH3Hg+ during pregnancy have resulted in offspring with significant neurodevelopmental abnormalities as was the case at Minamata Bay (Eto et al 2010 ).…”

Section: Discussionmentioning

confidence: 99%

Permeation thresholds for hydrophilic small biomolecules across microvascular and epithelial barriers are predictable on basis of conserved biophysical properties

Sarin¹

2015

In Silico Pharmacol.

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PurposeNeutral small hydrophiles are permeable to varying degrees, across the aqueous pores of phospholipid bilayer protein channels, with their potential for permeation into cells being predictable, on the basis of hydrophilicity and size. Here, it is hypothesized that permeation thresholds for small hydrophiles, across capillary zona occludens tight junction and inter-epithelial junction pore complexes are predictable, on the basis of predicted hydrophilicity in context of predicted molecular size and charge distribution, as are those of cations and anions, on the basis of predicted ionization in context of predicted atomic size.MethodsSmall hydrophiles are categorized by charge distribution. 2-dimensional plots of predicted hydrophilic octanol-to-water partition coefficient (HOWPC; unitless) and predicted van der Waals diameter (vdWD; nm) are generated for each category. The predicted HOWPC-to-vdWD ratio (nm-1), and vdWDs for permeable hydrophile at the maximum and minimum HOWPC-to-vdWD, vdWD @ MAXimum HOWPC-to-vdWD and vdWD @ MINimum HOWPC-to-vdWD are determined. For cations and anions, the ionization-to-atomic diameter ratios (CI or AI-to-AD ratios; nm-1) are determined.ResultsPer sizes of mixed and pure polyneutral hydrophiles, the permeation size maximum for hydrophiles across tight junction pore complexes is >0.69 ≤ 0.73 nanometers and across inter-epithelial junction pore complexes is ≥ 0.81 nanometers. For hydrophiles with anionicity or cationicity, the vdWDs @ MAXimum HOWPC-to-vdWD are less than those of mixed and polyneutral hydrophiles across both tight and inter-epithelial junctions, ranges specific to category and junction type. For cations, the permeation threshold across tight junctions is between the CI-to-AD ratio of Na+ (+2.69 nm-1) and CH3-Hg+ (+2.36 nm-1), with CH3-Hg+ and K+ (+2.20 nm-1) being permeable; and for divalent cations, the threshold across inter-epithelial junctions is between the CI-to-AD ratio of Mg2+ (+6.25 nm-1) and Ca2+ (+5.08 nm-1) , Ca2+ being semi-permeable. For anions, the permeation threshold across tight junctions is between the AI-to-AD ratio of Cl- (-4.91 nm-1) and Br- (-4.17 nm-1), and the threshold across inter-epithelial junctions is between the AI-to-AD ratio of F- (-7.81 nm-1) and Cl- (-4.91 nm-1).ConclusionsIn silico modeling reveals that permeation thresholds, of small molecule hydrophiles, cations and anions across junctional pore complexes, are conserved in the physiologic state.Electronic supplementary materialThe online version of this article (doi:10.1186/s40203-015-0009-y) contains supplementary material, which is available to authorized users.

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Methylmercury(II) binding to single-stranded and duplex DNA: complexes formed are distinguishable by optical detection of magnetic resonance spectroscopy.

Cited by 6 publications

References 14 publications

Helical Assembly of Flavin Mononucleotides on Carbon Nanotubes as Multimodal Near-IR Hg(II)-Selective Probes

Helical Assembly of Flavin Mononucleotides on Carbon Nanotubes as Multimodal Near-IR Hg(II)-Selective Probes

DNA fragments assembled on polyamidoamine‐grafted core‐shell magnetic silica nanoparticles for removal of mercury(II) and methylmercury(I)

Permeation thresholds for hydrophilic small biomolecules across microvascular and epithelial barriers are predictable on basis of conserved biophysical properties

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