Environmental Mercury Chemistry – In Silico

Asaduzzaman, Abu; Riccardi, Demian; Afaneh, Akef T.; Cooper, Connor J.; Smith, Jeremy C.; Wang, Fei; Parks, Jerry M.; Schreckenbach, Georg

doi:10.1021/acs.accounts.8b00454

Cited by 41 publications

(25 citation statements)

References 55 publications

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“…With the continuous improvement of the industrial level and the continuous utilization of pure water resources, the detection of water pollution by heavy metals has become an increasingly concerning global issue. , As a kind of a heavy metal pollutant, mercury ions (Hg 2+ ) have a great threat to living things especially to human beings. Even small amounts of Hg 2+ in water can cause irreversible damage to the human body, including headaches, low-grade fevers, adrenaline surges, sleep disorders, etc. − Therefore, it is very important for people to quickly detect Hg 2+ in living water. , There are many common methods for Hg 2+ detection, such as fluorescence spectrometry, atomic absorption spectrometry, etc. − Stobiecka et al have reported the competing fluorescence methods for Hg(II) detection. , However, these methods still have the disadvantages of long detection time, complex instrument, and high cost. Therefore, it is very important to establish a rapid and effective method to detect Hg 2+ .…”

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confidence: 99%

Ultrasensitive Controlled Release Aptasensor Using Thymine–Hg²⁺–Thymine Mismatch as a Molecular Switch for Hg²⁺ Detection

Ren

Wang

et al. 2020

Anal. Chem.

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An ultrasensitive controlled release system electrochemical aptasensor (CRSEA) has been developed for supersensitive determination of mercury ions (Hg 2+ ), using gold nanoparticle-linked specific single-stranded DNA (Au NPs-ssDNA) as a molecular gate and mesoporous silica nanocontainers (MSNs) as containers. MSNs have a rich porous structure, thus entrapping the toluidine blue (TB) molecules inside. It is worth noting that Hg 2+ binds to the ssDNA with multiple thymine (T) and induces the ssDNA to form a hairpin structure, which makes the separation of the Au NPs-ssDNA from the MSNs. Eventually, the stored TB molecules were released from MSNs. The electron transfer signals of TB were detected stably by a differential pulse voltammetry (DPV) detection method, which are correlated with the concentration of Hg 2+ . Therefore, the wide linear range (10 pM−100 μM) and low limit of detection (2.9 pM) were obtained, and the system also displayed an apparent electrochemical signal response in real sample detection and showed a promising possibility in actual monitoring.

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mentioning

confidence: 99%

Ultrasensitive Controlled Release Aptasensor Using Thymine–Hg²⁺–Thymine Mismatch as a Molecular Switch for Hg²⁺ Detection

Ren

Wang

et al. 2020

Anal. Chem.

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“…Previous studies had not shown direct in silico interactions of mer A with toxic Hg 2+ compounds (Asaduzzaman et al, 2019 ). Methylmercury is highly toxic for central and peripheral nervous system.…”

Section: Discussionmentioning

confidence: 92%

In vitro and in silico Studies Reveal Bacillus cereus AA-18 as a Potential Candidate for Bioremediation of Mercury-Contaminated Wastewater

et al. 2022

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Mercury (Hg) pollution is a worldwide problem and increasing day by day due to natural and anthropogenic sources. In this study, mercury-resistant (HgR) bacterial isolates were isolated from industrial wastewater of Ittehad Chemicals Ltd., Kala Shah Kaku, Lahore, Pakistan. Out of 65 bacterial isolates, five isolates were screened out based on showing resistance at 30–40 μg/ml against HgCl2. Selected Hg-resistant bacterial isolates were characterized as Bacillus subtilis AA-16 (OK562835), Bacillus cereus AA-18 (OK562834), Bacillus sp. AA-20 (OK562833), Bacillus paramycoides AA-30 (OK562836), and Bacillus thuringiensis AA-35 (OK562837). B. cereus AA-18 showed promising results in the resistance of HgCl2 (40 μg/ml) due to the presence of merA gene. Scanning electron microscopy (SEM) analysis of immobilized B. cereus AA-18 showed the accumulation Hg on the cell surface. The inoculation of immobilized B. cereus AA-18 remediated 86% Hg of industrial wastewater up to 72 h at large scale (p < 0.05). In silico analysis showed structural determination of MerA protein encoded by merA gene of B. cereus AA-18 (OK562598) using ProtParam, Pfam, ConSurf Server, InterPro, STRING, Jpred4, PSIPRED, I-TASSER, COACH server, TrRosetta, ERRAT, VERIFY3D, Ramachandran plot, and AutoDock Vina (PyRx 8.0). These bioinformatics tools predicted the structural-based functional homology of MerA protein (mercuric reductase) associated with mer operon harboring bacteria involved in Hg-bioremediation system.

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“…Particularly, Schreckenbach and coworkers carried out an extensive analysis on structural, electronic, and thermodynamic properties of methylmercury complexes with cysteine and selenocysteine, but also on the chalcogenophilicity of mercury, assessing that Hg S bond has a higher bond dissociation energy than Hg Se and Hg Te in different compounds ranging from small molecules to large complexes. In addition, they investigated in silico the thermodynamic feasibility of a degradation mechanism of selenocysteinate complexes of methylmercury [16][17][18][19] in order to rationalize mercury-selenium antagonism. 20 The development of an accurate computational method to study CH 3 Hg + binding, interactions, and reactivity is critical for future work focused on model compounds as well as on systems of increasing complexity up to the thiol-and selenol-based enzymes.…”

Section: Rs Ementioning

confidence: 99%

Chalcogen–mercury bond formation and disruption in model Rabenstein's reactions: A computational analysis

et al. 2020

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Methylmercury is a highly toxic compound and human exposure is mainly related to consumption of polluted fish and seafood. The inactivation of thiol-based enzymes, promoted by the strong affinity binding of electrophilic mercuric ions to thiol and selenol groups of proteins, is likely an important factor explaining its toxicity. A key role is played by the chemistry and reactivity of the mercury-chalcogens bond, particularly Hg S and Hg Se, which is the focus of this computational work (level of theory: (COSMO)-ZORA-BLYP-D3(BJ)/TZ2P). We analyze nine ligand-exchange model reactions (the so-called Rabenstein's reactions) involving an entering ligand (methylchalcogenolate) and a substrate (methylchalcogenolatemethylmercury). Trends in reaction and activation energies are discussed and a change in mechanism is reported for all cases when going from gas phase to water, that is, from a single-well potential energy surface (PES) to a canonical S N 2-like mechanism. The reasons accounting for the biochemically challenging and desired displacement of methylmercury from a seleno/ thiol protein can be found already in these model reactions, as can be seen from the similarities of the ligand exchange reactions in solution in thermodynamics and kinetics.

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Environmental Mercury Chemistry – In Silico

Cited by 41 publications

References 55 publications

Ultrasensitive Controlled Release Aptasensor Using Thymine–Hg²⁺–Thymine Mismatch as a Molecular Switch for Hg²⁺ Detection

Ultrasensitive Controlled Release Aptasensor Using Thymine–Hg²⁺–Thymine Mismatch as a Molecular Switch for Hg²⁺ Detection

In vitro and in silico Studies Reveal Bacillus cereus AA-18 as a Potential Candidate for Bioremediation of Mercury-Contaminated Wastewater

Chalcogen–mercury bond formation and disruption in model Rabenstein's reactions: A computational analysis

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Environmental Mercury Chemistry – In Silico

Cited by 41 publications

References 55 publications

Ultrasensitive Controlled Release Aptasensor Using Thymine–Hg2+–Thymine Mismatch as a Molecular Switch for Hg2+ Detection

Ultrasensitive Controlled Release Aptasensor Using Thymine–Hg2+–Thymine Mismatch as a Molecular Switch for Hg2+ Detection

In vitro and in silico Studies Reveal Bacillus cereus AA-18 as a Potential Candidate for Bioremediation of Mercury-Contaminated Wastewater

Chalcogen–mercury bond formation and disruption in model Rabenstein's reactions: A computational analysis

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Ultrasensitive Controlled Release Aptasensor Using Thymine–Hg²⁺–Thymine Mismatch as a Molecular Switch for Hg²⁺ Detection

Ultrasensitive Controlled Release Aptasensor Using Thymine–Hg²⁺–Thymine Mismatch as a Molecular Switch for Hg²⁺ Detection