Biogenic Control of Manganese Doping in Zinc Sulfide Nanomaterial Using Shewanella oneidensis MR-1

Chellamuthu, Prithiviraj; Naughton, Kyle L.; Pirbadian, Sahand; Silva, Kalinga Pavan T.; Chavez, Marko S.; El‐Naggar, Mohamed Y.; Boedicker, James

doi:10.3389/fmicb.2019.00938

“…In the case of C. freundii mostly extracellular clusters of CdS nanoparticles were observed around of the cells (Figure 2 E/F). The CdS nanoparticles formed by S. oneidensis appeared as smaller spherical spots uniformly distributed on the cell surface (Figure 2 I/H), in agreement with previous studies [41, 42] . In the case of E. coli , small clusters of CdS particles were observed on the cell surface (Figure 2 K/L).…”

Section: Resultssupporting

confidence: 90%

Enhanced Light‐Driven Hydrogen Production by Self‐Photosensitized Biohybrid Systems

Martins

¹

,

Toste

²

,

Pereira

³

2021

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Storage of solar energy as hydrogen provides aplatform towards decarbonizing our economy.One emerging strategy for the production of solar fuels is to use photocatalytic biohybrid systems that combine the high catalytic activity of non-photosynthetic microorganisms with the high light-harvesting efficiency of metal semiconductor nanoparticles.However,few such systems have been tested for H 2 production. We investigated light-driven H 2 production by three novel organisms,D esulfovibrio desulfuricans,C itrobacter freundii, and Shewanella oneidensis,s elf-photosensitized with cadmium sulfide nanoparticles,a nd compared their performance to Escherichia coli. All biohybrid systems produced H 2 from light, with D. desulfuricans-CdS demonstrating the best activity overall and outperforming the other microbial systems even in the absence of am ediator.W itht his system, H 2 was continuously produced for more than 10 days with as pecific rate of 36 mmol g dcw À1 h À1 .High apparent quantum yields of 23 %and 4% were obtained, with and without methyl viologen, respectively,exceeding values previously reported.

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“…TheC dS nanoparticles formed by S. oneidensis appeared as smaller spherical spots uniformly distributed on the cell surface (Figure 2I/H), in agreement with previous studies. [41,42] In the case of E. coli,s mall clusters of CdS particles were observed on the cell surface (Figure 2K/L). Theb iohybrid systems were further characterized by X-ray powder diffraction (XRD,F igure 3).…”

Section: Characterization Of the Biohybrid Systemsmentioning

confidence: 94%

Enhanced Light‐Driven Hydrogen Production by Self‐Photosensitized Biohybrid Systems

Martins

¹

,

Toste

²

,

Pereira

³

2021

View full text Add to dashboard Cite

Storage of solar energy as hydrogen provides aplatform towards decarbonizing our economy.One emerging strategy for the production of solar fuels is to use photocatalytic biohybrid systems that combine the high catalytic activity of non-photosynthetic microorganisms with the high light-harvesting efficiency of metal semiconductor nanoparticles.However,few such systems have been tested for H 2 production. We investigated light-driven H 2 production by three novel organisms,D esulfovibrio desulfuricans,C itrobacter freundii, and Shewanella oneidensis,s elf-photosensitized with cadmium sulfide nanoparticles,a nd compared their performance to Escherichia coli. All biohybrid systems produced H 2 from light, with D. desulfuricans-CdS demonstrating the best activity overall and outperforming the other microbial systems even in the absence of am ediator.W itht his system, H 2 was continuously produced for more than 10 days with as pecific rate of 36 mmol g dcw À1 h À1 .High apparent quantum yields of 23 %and 4% were obtained, with and without methyl viologen, respectively,exceeding values previously reported.

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“…Recently, Chellamuthu et al developed a genetic-control strategy to biosynthesize manganese-doped ZnS (Mn:ZnS) nanoparticles with different doping levels (Fig. 5 ) [ 155 ]. The authors found that the Mn doping level changed as a function of added inducer when the engineered strain of S. oneidensis with inducible expression of MtrCAB complex was used to control the reduction of Mn 4+ oxide.…”

Section: Biosynthesis Of Metal Nanoparticlesmentioning

confidence: 99%

“…5 Controlling manganese doping of ZnS quantum dots by engineered S. oneidensis JG3631 with the inducible expression of MtrCAB complex. a Chemically synthesized Mn doped ZnS NPs with varying optical properties, b the amount of the inducer (TMAO) regulating expression of MtrCAB complex that performs extracellular reduction, c relationship between Mn 2+ concentration and the addition of TMAO, d biogenic Mn doped ZnS quantum dots with varying optical properties as a function of Mn 2+ concentration [ 155 ]. …”

Section: Biosynthesis Of Metal Nanoparticlesmentioning

confidence: 99%

Bacterial extracellular electron transfer: a powerful route to the green biosynthesis of inorganic nanomaterials for multifunctional applications

Zou

¹

,

Zhu

²

,

Long

³

et al. 2021

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Synthesis of inorganic nanomaterials such as metal nanoparticles (MNPs) using various biological entities as smart nanofactories has emerged as one of the foremost scientific endeavors in recent years. The biosynthesis process is environmentally friendly, cost-effective and easy to be scaled up, and can also bring neat features to products such as high dispersity and biocompatibility. However, the biomanufacturing of inorganic nanomaterials is still at the trial-and-error stage due to the lack of understanding for underlying mechanism. Dissimilatory metal reduction bacteria, especially Shewanella and Geobacter species, possess peculiar extracellular electron transfer (EET) features, through which the bacteria can pump electrons out of their cells to drive extracellular reduction reactions, and have thus exhibited distinct advantages in controllable and tailorable fabrication of inorganic nanomaterials including MNPs and graphene. Our aim is to present a critical review of recent state-of-the-art advances in inorganic biosynthesis methodologies based on bacterial EET using Shewanella and Geobacter species as typical strains. We begin with a brief introduction about bacterial EET mechanism, followed by reviewing key examples from literatures that exemplify the powerful activities of EET-enabled biosynthesis routes towards the production of a series of inorganic nanomaterials and place a special emphasis on rationally tailoring the structures and properties of products through the fine control of EET pathways. The application prospects of biogenic nanomaterials are then highlighted in multiple fields of (bio-) energy conversion, remediation of organic pollutants and toxic metals, and biomedicine. A summary and outlook are given with discussion on challenges of bio-manufacturing with well-defined controllability.

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Biogenic Control of Manganese Doping in Zinc Sulfide Nanomaterial Using Shewanella oneidensis MR-1

Cited by 17 publications

References 56 publications

Enhanced Light‐Driven Hydrogen Production by Self‐Photosensitized Biohybrid Systems

Enhanced Light‐Driven Hydrogen Production by Self‐Photosensitized Biohybrid Systems

Enhanced Light‐Driven Hydrogen Production by Self‐Photosensitized Biohybrid Systems

Bacterial extracellular electron transfer: a powerful route to the green biosynthesis of inorganic nanomaterials for multifunctional applications

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