Tellurite Adsorption onto Bacterial Surfaces

Goff, Jennifer; Wang, Yuwei; Boyanov, Maxim I.; Yu, Qiang; Kemner, Kenneth M.; Fein, Jeremy B.; Yee, Nathan

doi:10.1021/acs.est.1c01001

Cited by 13 publications

(12 citation statements)

References 68 publications

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“…This mechanism explains the decrease of the adsorption with the pH (Figure 4). The reduction-induced oxyanion adsorption (Goff et al, 2021;Yu et al, 2018) is a possible mechanism, which is consistent with the presence of Re(VI) on the surface (Figure S1). In this mechanism, a surface thiol is covalently bound with the cationic element of the oxyanion substituting oxygen.…”

Section: Equilibrium and Kinetics Of Adsorptionsupporting

confidence: 77%

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Effective adsorption of perrhenate ions on the filamentous sheath-forming bacteria, Sphaerotilus montanus, Sphaerotilus natans and Thiothrix fructosivorans

Faizan

Takeda

Yoshitake

2022

Journal of Applied Microbiology

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Aims This study aimed to unveil perrhenate sorption properties of the filamentous sheaths formed by Sphaerotilus montanus, Sphaerotilus natans and Thiothrix fructosivorans. Methods and Results The adsorptions of perrhenate on lyophilizates of the above‐mentioned filamentous sheaths were analysed by ICP, IR, XPS and EDX. The capacity reached 82 mg per g‐adsorbent, when using S. natans. The Langmuir coefficient of this adsorbent was found to be the largest of the three. The adsorption capacity was discussed with respect to the amount of nitrogen and phosphorus in the adsorbents. The occurrence of anion exchange was implied by the IR spectrum changes before and after adsorption. The adsorption data fitted well with a pseudo‐second‐order equation, suggesting that the rate is determined by the chemical bond formation. Conclusions A significant amount of perrhenate was adsorbed on the sheaths formed by S. montanus, S. natans and T. fructosivorans. The adsorption was correlated with the elemental compositions. A strong chemical bond formation was suggested from the results of the Langmuir adsorption isotherm and kinetic analysis. Significance and Impact of Study The capacity obtained for S. natans is one of the largest adsorptions amongst the similar biomaterials, implying the possibility of providing economical adsorbents of rare metal oxyanions.

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Section: Equilibrium and Kinetics Of Adsorptionsupporting

confidence: 77%

“…For all the adsorbents, about 60% is attributed to heptavalent rhenium, implying that the anion is reduced by adsorption. The reduction of selenate and tellurate occurs by the adsorption on bacterial surfaces (Goff et al, 2021; Yu et al, 2018). The reaction is induced by the bond formation with two vicinal thiol sites.…”

Section: Resultsmentioning

confidence: 99%

Effective adsorption of perrhenate ions on the filamentous sheath-forming bacteria, Sphaerotilus montanus, Sphaerotilus natans and Thiothrix fructosivorans

Faizan

Takeda

Yoshitake

2022

Journal of Applied Microbiology

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“…4f), thus enabling more efficient and directional bioconversion of the precursors towards bio-QD formation. 38,39 The anaerobically stimulated uptake and reduction of Se by the cells were supported by metal content analysis (Fig. 4e), which showed a similar Cd content but a 3.5-fold higher Se content of the bio-hybrid under anaerobic conditions over aerobic conditions after 4 h incubation.…”

Section: Resultsmentioning

confidence: 62%

Anaerobic self-assembly of a regenerable bacteria-quantum dot hybrid for solar hydrogen production

Wang

Chen

et al. 2022

Nanoscale

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“…The importance of polysaccharide variations also arose from PCA analysis, in which the vector describing these contributions distinguished unchallenged cells from those challenged ( Figure 7 ). Interestingly, Goff and coworkers (2021) recently reported that sulfhydryl groups of the proteinaceous material within EPS of Bacillus subtilis play a crucial role in binding TeO 3 2− , mediating its sorption on bacterial surfaces [ 76 ]. At this stage, it cannot be ruled out that sulfhydryl groups in the EPS of Micromonospora EPS could bind TeO 3 2− to limit its translocation into the cell cytoplasm.…”

Section: Discussionmentioning

confidence: 99%

“…However, a direct comparison between the profiles describing RSH depletion in Micromonospora growing cells with the available literature is challenging, as most studies focused on the earliest stages (up to 2.5-h) of either bacterial growth or exposure to this oxyanion. In the case of Micromonospora growing cells, RSH depletion may rely on (i) RSH groups within EPS binding with TeO 3 2− [ 76 ], (ii) Painter-type reactions, (iii) ROS detoxification [ 84 ], and (iv) the modification of RSH-rich proteins caused by oxidative stress [ 27 ]. Hypotheses (i–iii) were sustained by the detection of vibrational modes attributable to RSH-, thiolate (RS − )-, and disulfide (RSSR)-containing molecules ( Figure 6 b,c; Table S1 ).…”

Section: Discussionmentioning

confidence: 99%

Tolerance, Adaptation, and Cell Response Elicited by Micromonospora sp. Facing Tellurite Toxicity: A Biological and Physical-Chemical Characterization

Piacenza

Campora

Pavia

et al. 2022

IJMS

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The intense use of tellurium (Te) in industrial applications, along with the improper disposal of Te-derivatives, is causing their accumulation in the environment, where oxyanion tellurite (TeO32−) is the most soluble, bioavailable, and toxic Te-species. On the other hand, tellurium is a rare metalloid element whose natural supply will end shortly with possible economic and technological effects. Thus, Te-containing waste represents the source from which Te should be recycled and recovered. Among the explored strategies, the microbial TeO32− biotransformation into less toxic Te-species is the most appropriate concerning the circular economy. Actinomycetes are ideal candidates in environmental biotechnology. However, their exploration in TeO32− biotransformation is scarce due to limited knowledge regarding oxyanion microbial processing. Here, this gap was filled by investigating the cell tolerance, adaptation, and response to TeO32− of a Micromonospora strain isolated from a metal(loid)-rich environment. To this aim, an integrated biological, physical-chemical, and statistical approach combining physiological and biochemical assays with confocal or scanning electron (SEM) microscopy and Fourier-transform infrared spectroscopy in attenuated total reflectance mode (ATR-FTIR) was designed. Micromonospora cells exposed to TeO32− under different physiological states revealed a series of striking cell responses, such as cell morphology changes, extracellular polymeric substance production, cell membrane damages and modifications, oxidative stress burst, protein aggregation and phosphorylation, and superoxide dismutase induction. These results highlight this Micromonospora strain as an asset for biotechnological purposes.

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Tellurite Adsorption onto Bacterial Surfaces

Cited by 13 publications

References 68 publications

Effective adsorption of perrhenate ions on the filamentous sheath-forming bacteria, Sphaerotilus montanus, Sphaerotilus natans and Thiothrix fructosivorans

Effective adsorption of perrhenate ions on the filamentous sheath-forming bacteria, Sphaerotilus montanus, Sphaerotilus natans and Thiothrix fructosivorans

Anaerobic self-assembly of a regenerable bacteria-quantum dot hybrid for solar hydrogen production

Tolerance, Adaptation, and Cell Response Elicited by Micromonospora sp. Facing Tellurite Toxicity: A Biological and Physical-Chemical Characterization

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