Your search keyword '"Tender LM"' showing total 41 results

1. Performance of a combined electrotrophic and electrogenic biofilm operated under long-term, continuous cycling.

Author

Yates MD, Mickol RL, Vignola A, Baldwin JW, Glaven SM, and Tender LM

Subjects

Electron Transport, Biofilms, Electricity, Bioelectric Energy Sources

Abstract

Objectives: Evaluate electrochemically active biofilms as high energy density rechargeable microbial batteries toward providing persistent power in applications where traditional battery technology is limiting (, remote monitoring applications)., Results: Here we demonstrated that an electrochemically active biofilm was able to store and release electrical charge for alternating charge/discharge cycles of up to 24 h periodicity (50% duty cycle) with no significant decrease in average current density (0.16 ± 0.04 A/m 2 ) for over 600 days. However, operation at 24 h periodicity for > 50 days resulted in a sharp decrease in the current to nearly zero. This current crash was recoverable by decreasing the periodicity. Overall, the coulombic efficiency remained near unity within experimental error (102 ± 3%) for all of the tested cycling periods. Electrochemical characterization here suggests that electron transfer occurs through multiple routes, likely a mixture of direct and mediated mechanisms., Conclusions: These results indicate that bidirectional electrogenic/electrotrophic biofilms are capable of efficient charge storage/release over a wide range of cycling frequency and may eventually enable development of sustainable, high energy density rechargeable batteries., (© 2024. This is a U.S. Government work and not under copyright protection in the US; foreign copyright protection may apply.)

Published

2024

2. Pyocyanin-dependent electrochemical inhibition of Pseudomonas aeruginosa biofilms is synergistic with antibiotic treatment.

Author

Jiménez Otero F, Newman DK, and Tender LM

Subjects

Electron Transport drug effects, Electrochemical Techniques, Biofilms drug effects, Pyocyanine metabolism, Pseudomonas aeruginosa drug effects, Pseudomonas aeruginosa physiology, Pseudomonas aeruginosa metabolism, Anti-Bacterial Agents pharmacology, Oxidation-Reduction

Abstract

Pseudomonas aeruginosa biofilms are common in chronic wound infections and recalcitrant to treatment. Survival of cells within oxygen-limited regions in these biofilms is enabled by extracellular electron transfer (EET), whereby small redox active molecules act as electron shuttles to access distal oxidants. Here, we report that electrochemically controlling the redox state of these electron shuttles, specifically pyocyanin (PYO), can impact cell survival within anaerobic P. aeruginosa biofilms and can act synergistically with antibiotic treatment. Prior results demonstrated that under anoxic conditions, an electrode poised at sufficiently oxidizing potential (+100 mV vs Ag/AgCl) promotes EET within P. aeruginosa biofilms by re-oxidizing PYO for reuse by the cells. Here, when a reducing potential (-400 mV vs Ag/AgCl) was used to disrupt PYO redox cycling by maintaining PYO in the reduced state, we observed a 100-fold decrease in colony forming units within these biofilms compared with those exposed to electrodes poised at +100 mV vs Ag/AgCl. Phenazine-deficient Δ phz * biofilms were unaffected by the potential applied to the electrode but were re-sensitized by adding PYO. The effect at -400 mV was exacerbated when biofilms were treated with sub-MICs of a range of antibiotics. Most notably, addition of the aminoglycoside gentamicin in a reductive environment almost completely eradicated wild-type biofilms but had no effect on the survival of Δ phz * biofilms in the absence of phenazines. These data suggest that antibiotic treatment combined with the electrochemical disruption of PYO redox cycling, either through the toxicity of accumulated reduced PYO or the disruption of EET, or both, can lead to extensive killing. IMPORTANCE Biofilms provide a protective environment but also present challenges to the cells living within them, such as overcoming nutrient and oxygen diffusion limitations. Pseudomonas aeruginosa overcomes oxygen limitation by secreting soluble redox active phenazines, which act as electron shuttles to distal oxygen. Here, we show that electrochemically blocking the re-oxidation of one of these electron shuttles, pyocyanin, decreases cell survival within biofilms and acts synergistically with gentamicin to kill cells. Our results highlight the importance of the role that the redox cycling of electron shuttles fulfills within P. aeruginosa biofilms., Competing Interests: The authors declare no conflict of interest.

Published

2023

3. Marine Biofilm Engineered to Produce Current in Response to Small Molecules.

Author

Bird LJ, Leary DH, Hervey J, Compton J, Phillips D, Tender LM, Voigt CA, and Glaven SM

Subjects

Electron Transport, Genetic Engineering, Biofilms, Shewanella genetics, Shewanella metabolism

Abstract

Engineered electroactive bacteria have potential applications ranging from sensing to biosynthesis. In order to advance the use of engineered electroactive bacteria, it is important to demonstrate functional expression of electron transfer modules in chassis adapted to operationally relevant conditions, such as non-freshwater environments. Here, we use the Shewanella oneidensis electron transfer pathway to induce current production in a marine bacterium, Marinobacter atlanticus , during biofilm growth in artificial seawater. Genetically encoded sensors optimized for use in Escherichia coli were used to control protein expression in planktonic and biofilm attached cells. Significant current production required the addition of menaquinone, which M. atlanticus does not produce, for electron transfer from the inner membrane to the expressed electron transfer pathway. Current through the S. oneidensis pathway in M. atlanticus was observed when inducing molecules were present during biofilm formation. Electron transfer was also reversible, indicating that electron transfer into M. atlanticus could be controlled. These results show that an operationally relevant marine bacterium can be genetically engineered for environmental sensing and response using an electrical signal.

Published

2023

4. Metagenomic and Metatranscriptomic Characterization of a Microbial Community That Catalyzes Both Energy-Generating and Energy-Storing Electrode Reactions.

Author

Mickol RL, Eddie BJ, Malanoski AP, Yates MD, Tender LM, and Glaven SM

Subjects

Deltaproteobacteria genetics, Deltaproteobacteria metabolism, Electrodes, Metagenomics, Microbiota, Transcriptome

Abstract

Electroactive bacteria are living catalysts, mediating energy-generating reactions at anodes or energy storage reactions at cathodes via extracellular electron transfer (EET). The Cathode-ANode (CANode) biofilm community was recently shown to facilitate both reactions; however, the identities of the primary constituents and underlying molecular mechanisms remain unknown. Here, we used metagenomics and metatranscriptomics to characterize the CANode biofilm. We show that a previously uncharacterized member of the family Desulfobulbaceae, Desulfobulbaceae -2, which had <1% relative abundance, had the highest relative gene expression and accounted for over 60% of all differentially expressed genes. At the anode potential, differential expression of genes for a conserved flavin oxidoreductase (Flx) and heterodisulfide reductase (Hdr) known to be involved in ethanol oxidation suggests a source of electrons for the energy-generating reaction. Genes for sulfate and carbon dioxide reduction pathways were expressed by Desulfobulbaceae -2 at both potentials and are the proposed energy storage reactions. Reduction reactions may be mediated by direct electron uptake from the electrode or from hydrogen generated at the cathode potential. The Desulfobulbaceae -2 genome is predicted to encode at least 85 multiheme (≥3 hemes) c -type cytochromes, some with as many as 26 heme-binding domains, that could facilitate reversible electron transfer with the electrode. Gene expression in other CANode biofilm species was also affected by the electrode potential, although to a lesser extent, and we cannot rule out their contribution to observed current. Results provide evidence of gene expression linked to energy storage and energy-generating reactions and will enable development of the CANode biofilm as a microbially driven rechargeable battery. IMPORTANCE Microbial electrochemical technologies (METs) rely on electroactive bacteria to catalyze energy-generating and energy storage reactions at electrodes. Known electroactive bacteria are not equally capable of both reactions, and METs are typically configured to be unidirectional. Here, we report on genomic and transcriptomic characterization of a recently described microbial electrode community called the Cathode-ANode (CANode). The CANode community is able to generate or store electrical current based on the electrode potential. During periods where energy is not needed, electrons generated from a renewable source, such as solar power, could be converted into energy storage compounds to later be reversibly oxidized by the same microbial catalyst. Thus, the CANode system can be thought of as a living "rechargeable battery." Results show that a single organism may be responsible for both reactions demonstrating a new paradigm for electroactive bacteria.

Published

2021

5. Microbial survival and growth on non-corrodible conductive materials.

Author

Bird LJ, Tender LM, Eddie B, Oh E, Phillips DA, and Glaven SM

Subjects

Biofilms, Electric Conductivity, Electrodes, Oxidation-Reduction, Bioelectric Energy Sources, Chromatiaceae

Abstract

Biofilms growing aerobically on conductive substrates are often correlated with a positive, sustained shift in their redox potential. This phenomenon has a beneficial impact on microbial fuel cells by increasing their overall power output but can be detrimental when occurring on stainless steel by enhancing corrosion. The biological mechanism behind this potential shift is unresolved and a metabolic benefit to cells has not been demonstrated. Here, biofilms containing the electroautotroph 'Candidatus Tenderia electrophaga' catalysed a shift in the open circuit potential of graphite and indium tin oxide electrodes by >100 mV. Biofilms on open circuit electrodes had increased biomass and a significantly higher proportion of 'Ca. Tenderia electrophaga' compared to those on plain glass. Addition of metabolic inhibitors showed that living cells were required to maintain the more positive potential. We propose a model to describe these observations, in which 'Ca. Tenderia electrophaga' drives the shift in open circuit potential through electron uptake for oxygen reduction and CO 2 fixation. We further propose that the electrode is continuously recharged by oxidation of trace redox-active molecules in the medium at the more positive potential. A similar phenomenon is possible on natural conductive substrates in the environment., (© 2021 Society for Applied Microbiology and John Wiley & Sons Ltd. This article has been contributed to by US Government employees and their work is in the public domain in the USA.)

Published

2021

6. Evidence of a Streamlined Extracellular Electron Transfer Pathway from Biofilm Structure, Metabolic Stratification, and Long-Range Electron Transfer Parameters.

Author

Jiménez Otero F, Chadwick GL, Yates MD, Mickol RL, Saunders SH, Glaven SM, Gralnick JA, Newman DK, Tender LM, Orphan VJ, and Bond DR

Subjects

Electricity, Electrodes, Electron Transport, Extracellular Space chemistry, Geobacter growth & development, Biofilms, Extracellular Space metabolism, Geobacter chemistry, Geobacter physiology

Abstract

A strain of Geobacter sulfurreducens, an organism capable of respiring solid extracellular substrates, lacking four of five outer membrane cytochrome complexes ( extABCD + strain) grows faster and produces greater current density than the wild type grown under identical conditions. To understand cellular and biofilm modifications in the extABCD + strain responsible for this increased performance, biofilms grown using electrodes as terminal electron acceptors were sectioned and imaged using electron microscopy to determine changes in thickness and cell density, while parallel biofilms incubated in the presence of nitrogen and carbon isotopes were analyzed using NanoSIMS (nanoscale secondary ion mass spectrometry) to quantify and localize anabolic activity. Long-distance electron transfer parameters were measured for wild-type and extABCD + biofilms spanning 5-μm gaps. Our results reveal that extABCD + biofilms achieved higher current densities through the additive effects of denser cell packing close to the electrode (based on electron microscopy), combined with higher metabolic rates per cell compared to the wild type (based on increased rates of 15 N incorporation). We also observed an increased rate of electron transfer through extABCD + versus wild-type biofilms, suggesting that denser biofilms resulting from the deletion of unnecessary multiheme cytochromes streamline electron transfer to electrodes. The combination of imaging, physiological, and electrochemical data confirms that engineered electrogenic bacteria are capable of producing more current per cell and, in combination with higher biofilm density and electron diffusion rates, can produce a higher final current density than the wild type. IMPORTANCE Current-producing biofilms in microbial electrochemical systems could potentially sustain technologies ranging from wastewater treatment to bioproduction of electricity if the maximum current produced could be increased and current production start-up times after inoculation could be reduced. Enhancing the current output of microbial electrochemical systems has been mostly approached by engineering physical components of reactors and electrodes. Here, we show that biofilms formed by a Geobacter sulfurreducens strain producing ∼1.4× higher current than the wild type results from a combination of denser cell packing and higher anabolic activity, enabled by an increased rate of electron diffusion through the biofilms. Our results confirm that it is possible to engineer electrode-specific G. sulfurreducens strains with both faster growth on electrodes and streamlined electron transfer pathways for enhanced current production.

Published

2021

7. Activation of Protein Expression in Electroactive Biofilms.

Author

Phillips DA, Bird LJ, Eddie BJ, Yates MD, Tender LM, Voigt CA, and Glaven SM

Subjects

Electric Conductivity, Electrochemical Techniques, Electrodes, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Marinobacter physiology, Printing, Three-Dimensional, Biofilms growth & development, Marinobacter metabolism, Protein Biosynthesis

Abstract

Microbes that form biofilms on electrodes and generate electrical current responses could be integrated into devices to perform sensing, conduct signals, or act as living microprocessors. A challenge in working with these species is the ability to visualize biofilm formation and protein expression in real-time while also measuring current, which is not possible with typical bio-electrochemical reactors. Here, we present a three-dimensional-printed flow cell for simultaneous electrochemistry and fluorescence imaging. Current-producing biofilms of Marinobacter atlanticus constitutively expressing green fluorescent protein were grown on the flow cell working electrode. Increasing current corresponded with increasing surface coverage and was comparable to biofilms grown in typical stirred-batch reactors. An isopropyl β-d-1-thiogalactopyranoside (IPTG) inducible system driving yellow fluorescent protein was used to assess the spatiotemporal activation of protein expression within the biofilm at different stages of growth and induction dynamics. The response time ranged from 30 min to 5 h, depending on the conditions. These data demonstrate that the electrochemical flow cell can evaluate the performance of an electrically active environmental bacterium under conditions relevant for development as a living electronic sensor.

Published

2020

8. Extracellular DNA Promotes Efficient Extracellular Electron Transfer by Pyocyanin in Pseudomonas aeruginosa Biofilms.

Author

Saunders SH, Tse ECM, Yates MD, Otero FJ, Trammell SA, Stemp EDA, Barton JK, Tender LM, and Newman DK

Subjects

DNA metabolism, Electrochemical Techniques, Electrodes, Electron Transport drug effects, Fluorescent Dyes chemistry, Hydrogen-Ion Concentration, Oxidation-Reduction, Phenazines chemistry, Phenazines metabolism, Phenazines pharmacology, Pyocyanine metabolism, Biofilms growth & development, DNA chemistry, Pseudomonas aeruginosa physiology, Pyocyanine chemistry

Abstract

Redox cycling of extracellular electron shuttles can enable the metabolic activity of subpopulations within multicellular bacterial biofilms that lack direct access to electron acceptors or donors. How these shuttles catalyze extracellular electron transfer (EET) within biofilms without being lost to the environment has been a long-standing question. Here, we show that phenazines mediate efficient EET through interactions with extracellular DNA (eDNA) in Pseudomonas aeruginosa biofilms. Retention of pyocyanin (PYO) and phenazine carboxamide in the biofilm matrix is facilitated by eDNA binding. In vitro, different phenazines can exchange electrons in the presence or absence of DNA and can participate directly in redox reactions through DNA. In vivo, biofilm eDNA can also support rapid electron transfer between redox active intercalators. Together, these results establish that PYO:eDNA interactions support an efficient redox cycle with rapid EET that is faster than the rate of PYO loss from the biofilm., Competing Interests: Declaration of Interests The authors declare no competing interests., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2020

9. Spatially Resolved Chemical Analysis of Geobacter sulfurreducens Cell Surface.

Author

Lebedev N, Stroud RM, Yates MD, and Tender LM

Subjects

Electric Conductivity, Electron Transport, Fimbriae, Bacterial ultrastructure, Geobacter cytology, Geobacter ultrastructure, Particle Size, Surface Properties, Fimbriae, Bacterial chemistry, Geobacter chemistry, Iron analysis

Abstract

Geobacter sulfurreducens is of interest for the highest efficiency of power generation and extremely long extracellular electron transfer (EET) between the bacterium and electrodes. Despite more than 15 years of intensive molecular biological research, there is still no clear answer which molecules are responsible for these processes. In the present work, we look at the problem from another (atomic) perspective and identify the location and shape of the compounds that are known to be conductive, particularly those containing Fe atoms. By using highly sophisticated energy dispersive X-ray spectroscopy combined with high-angle annular dark-field transmission electron microscopy enabling detection, identification, and localization of chemical compounds on the surface at nearly atomic spatial resolution, we analyze Fe spatial distribution within the G. sulfurreducens community. We discover the presence of small Fe-containing particles on the surface of the bacterium cells. The size of the particles (diameter 5.6 nm) is highly reproducible and comparable with the size of a single protein. The particles cover about 2% of the cell surface, which is similar to that expected for molecular conductors responsible for electron transfer through the bacterium cell wall. We find that G. sulfurreducens filaments ("bacterial molecular wires") also contain Fe atoms in their bundles. We observe that the bacterium enable changing the distance between the Fe-containing bundles in the filaments from separated to attached (the latter is needed for the efficient electron transfer between the Fe-containing particles), depending on the bacterium metabolic activity and attachment to extracellular substrates. These results are consistent with the recently published research about the role of Fe atoms in protein molecular conductance ( Phys. Chem. Chem. Phys. , 2018 , 20 , 14072 - 14081 ) and show what type of Fe-containing particles are involved in the bacterial extracellular communication. They can be used for the design and construction of artificial biomolecular wires and bioinorganic interfaces.

Published

2019

10. Multiheme Cytochrome Mediated Redox Conduction through Shewanella oneidensis MR-1 Cells.

Author

Xu S, Barrozo A, Tender LM, Krylov AI, and El-Naggar MY

Subjects

Computer Simulation, Cytochromes chemistry, Electrochemistry, Electron Transport, Oxidation-Reduction, Temperature, Cell Membrane physiology, Cytochromes metabolism, Shewanella physiology

Abstract

Multiheme cytochromes function as extracellular electron transfer (EET) conduits that extend the metabolic reach of microorganisms to external solid surfaces. These conduits are also proposed to facilitate long-distance electron transport along cellular membranes and across multiple cells. Here we report electrochemical gating measurements of Shewanella oneidensis MR-1 cells linking interdigitated electrodes. The dependence of the source-drain current on gate potential demonstrates a redox conduction mechanism, which we link to the presence of multiheme cytochromes of the Mtr pathway. We also find that the measured thermal activation energy of 0.29 ± 0.03 eV is consistent with these obtained from electron hopping calculations through the S. oneidensis Mtr outer-membrane decaheme cytochromes. Our measurements and calculations have implications for understanding and controlling micrometer-scale electron transport in microbial systems.

Published

2018

11. Internal Redox Polarity of an Individual G. sulfurreducens Bacterial Cell Attached to an Inorganic Substrate.

Author

Lebedev N, Yates MD, Griva I, and Tender LM

Abstract

Bacterial cell polarity is an internal asymmetric distribution of subcellular components, including proteins, lipids, and other molecules that correlates with the cell ability to sense energy and metabolite sources, chemical signals, quorum signals, toxins, and movement in the desired directions. This ability also plays central role in cell attachment to various surfaces and biofilm formation. Mechanisms and factors controlling formation of this cell internal asymmetry are not completely understood. As a step in this direction, in the present work, we develop an approach for analyzing how information about inorganic substrate can be non-genetically coded inside an individual bacterial cell. As a model system, we use G. sulfurreducens cells attached to an inorganic mineral, mica. The approach utilizes confocal Raman microscopy, Gaussian deconvolution, and Principal Component Analysis (PCA) and allows for quick label-free identification of the molecular signature of cytochrome intracellular location and the cell to substrate binding down to the level of individual bacterial cells. Our results describe a spectroscopic signature of cell adhesion and how the information about cell adhesion can be coded inside individual bacterial cells., (© 2018 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2018

12. Redox-gradient driven electron transport in a mixed community anodic biofilm.

Author

Yates MD, Barr Engel S, Eddie BJ, Lebedev N, Malanoski AP, and Tender LM

Subjects

Biofilms growth & development, Electrodes, Electrons, Geobacter classification, Microscopy, Confocal, Oxidation-Reduction, Rivers microbiology, Electric Conductivity, Electron Transport physiology, Geobacter physiology, Geologic Sediments microbiology

Abstract

Here, we describe the long-distance (multi-cell-length) extracellular electron transport (LD-EET) that occurs in an anode-grown mixed community biofilm (MCB) enriched from river sediment that contains 3%-45% Geobacter spp. High signal-to-noise temperature-dependent electrochemical gating measurements (EGM) using interdigitated microelectrode arrays reveal a peak-shaped electrical conductivity vs. potential dependency, indicating MCB acts as a redox conductor, similar to pure culture anode-grown Geobacter sulfurreducens biofilms (GSB). EGM also reveal that the maximum sustained rate of LD-EET in MCB is comparable to GSB, and the same whether under acetate-oxidizing or acetate-free conditions. Voltammetry indicated that MCB possesses 3- to 5-fold less electrode-accessible redox cofactors than GSB, suggesting that MCB may be more efficiently organized than GSB for LD-EET or that a small portion of electrode accessible redox cofactors of GSB are involved in LD-EET. The activation energy for LD-EET (0.11 ± 0.01 eV) was comparable to GSB, consistent with the possible role of c-type cytochromes as LD-EET cofactors, detected in abundance by confocal resonance Raman microscopy. Taken together, the results demonstrate LD-EET for a mixed community anode-grown microbial biofilm that is remarkably similar to GSB even though it contains many different types of microorganisms and appears to utilize far fewer EET redox cofactors.

Published

2018

13. Effect of iron doping on protein molecular conductance.

Author

Lebedev N, Griva I, Blom A, and Tender LM

Subjects

Biocompatible Materials chemistry, Electronics, Electric Conductivity, Iron chemistry, Proteins chemistry

Abstract

Protein molecular conductance has attracted attention from researchers for the possibility of constructing innovative flexible biocompatible nanoscale electronic devices and smart hybrid materials. Due to protein complexity, most evaluations of protein conductivity are based on the simple estimation of protein's molecular orbital energy levels and spatial distributions without analysing its protein interaction with electrodes and the calculation of the rates of electron transfer (ET). In the present work, we included in our density functional theory (DFT) analysis an approach based on the non-equilibrium Green's function (NEGF) allowing for calculation from the first principles the molecular interaction with electrodes and thus the role of electrode materials, Fermi level, the thermal distribution of electronic energy levels, and the coupling efficiency between the molecule and the electrodes. Compared to proteins studied so far, mainly artificial peptides, heme-containing cytochromes, and bacterial pili, we choose rubredoxin for our calculation. Rubredoxin contains a non-heme iron that, as we have discovered recently, can be involved in extracellular ET in electroactive bacterial biofilms (Yates et al., Energy Environ. Sci., 2016, 9, 3544-3558). Our calculations show that an iron atom incorporated into the protein structure as an iron-sulfur cluster opens a transmission path at the energy corresponding to the Fermi level of the electrodes. This allows the protein to become an extremely efficient conductor at very low bias voltages (<±350 mV). Calculation of the role of protein amino acids based on the local density of states and electron transfer paths reveals that neither aromatic amino acid Tyr nor Phe at any ring orientation participates in coherent ET through the FeS cluster of the protein. Moreover, direct ET through surrounding amino acids, bypassing FeS, is possible only at biases ±1.5 to ±2 V. The polar amino acid Asn might participate in ET at these bias voltages. The conductivity of the protein core substantially depends on the polarity of the applied electric field, allowing for unidirectional ET and operation of the protein as a molecular rectifier. These results can be used for a wise de novo design of proteins for molecular electronics and cellular energy converting devices, particularly for utilization of iron doping in the construction of conductive protein wires.

Published

2018

14. On the relationship between long-distance and heterogeneous electron transfer in electrode-grown Geobacter sulfurreducens biofilms.

Author

Yates MD, Eddie BJ, Lebedev N, Kotloski NJ, Strycharz-Glaven SM, and Tender LM

Subjects

Electrochemistry, Electrodes, Electron Transport, Geobacter physiology, Kinetics, Biofilms growth & development, Geobacter metabolism

Abstract

The ability of certain microorganisms to live in a multi-cell thick, electrode-grown biofilm by utilizing the electrode as a metabolic electron acceptor or donor requires electron transfer across cell membranes, through the biofilm, and across the biofilm/electrode interface. Even for the most studied system, anode-grown Geobacter sulfurreducens, the mechanisms underpinning each process and how they connect is largely unresolved. Here we report on G. sulfurreducens biofilms grown across the gap separating two electrodes by maintaining one electrode at 0.300V vs. Ag/AgCl (0.510V vs. SHE) to act as a sustained metabolic electron acceptor while the second electrode was at open circuit. The poised electrode exhibited the characteristic current-time profile for electrode-dependent G. sulfurreducens biofilm growth. The open circuit potential (OCP) of the second electrode however increased after initially decreasing for 1.5-2days. The increase in OCP is taken to indicate the point at which the growing biofilm bridged the gap between the electrodes, enabling cells in contact with the open circuit electrode to utilize the poised electrode as an electron acceptor. After but not prior to reaching this point, the second electrode was able to act as a sustainable electron acceptor immediately after being placed under potential control without requiring further time to develop. These results indicate that heterogeneous ET (H-ET) across the biofilm/electrode interface and long-distance ET (LD-ET) through the biofilm are highly correlated, if not inseparable, and may share many common components., (Copyright © 2017. Published by Elsevier B.V.)

Published

2018

15. Metatranscriptomics Supports the Mechanism for Biocathode Electroautotrophy by " Candidatus Tenderia electrophaga".

Author

Eddie BJ, Wang Z, Hervey WJ 4th, Leary DH, Malanoski AP, Tender LM, Lin B, and Strycharz-Glaven SM

Abstract

Biocathodes provide a stable electron source to drive reduction reactions in electrotrophic microbial electrochemical systems. Electroautotrophic biocathode communities may be more robust than monocultures in environmentally relevant settings, but some members are not easily cultivated outside the electrode environment. We previously used metagenomics and metaproteomics to propose a pathway for coupling extracellular electron transfer (EET) to carbon fixation in " Candidatus Tenderia electrophaga," an uncultivated but dominant member of an electroautotrophic biocathode community. Here we validate and refine this proposed pathway using metatranscriptomics of replicate aerobic biocathodes poised at the growth potential level of 310 mV and the suboptimal 470 mV (versus the standard hydrogen electrode). At both potentials, transcripts were more abundant from " Ca. Tenderia electrophaga" than from any other constituent, and its relative activity was positively correlated with current. Several genes encoding key components of the proposed " Ca. Tenderia electrophaga" EET pathway were more highly expressed at 470 mV, consistent with a need for cells to acquire more electrons to obtain the same amount of energy as at 310 mV. These included cyc2 , encoding a homolog of a protein known to be involved in iron oxidation. Mean expression of all CO 2 fixation-related genes is 0.27 log 2 -fold higher at 310 mV, indicating that reduced energy availability at 470 mV decreased CO 2 fixation. Our results substantiate the claim that " Ca. Tenderia electrophaga" is the key electroautotroph, which will help guide further development of this community for microbial electrosynthesis. IMPORTANCE Bacteria that directly use electrodes as metabolic electron donors (biocathodes) have been proposed for applications ranging from microbial electrosynthesis to advanced bioelectronics for cellular communication with machines. However, just as we understand very little about oxidation of analogous natural insoluble electron donors, such as iron oxide, the organisms and extracellular electron transfer (EET) pathways underlying the electrode-cell direct electron transfer processes are almost completely unknown. Biocathodes are a stable biofilm cultivation platform to interrogate both the rate and mechanism of EET using electrochemistry and to study the electroautotrophic organisms that catalyze these reactions. Here we provide new evidence supporting the hypothesis that the uncultured bacterium " Candidatus Tenderia electrophaga" directly couples extracellular electron transfer to CO 2 fixation. Our results provide insight into developing biocathode technology, such as microbial electrosynthesis, as well as advancing our understanding of chemolithoautotrophy.

Published

2017

16. Measuring conductivity of living Geobacter sulfurreducens biofilms.

Author

Yates MD, Strycharz-Glaven SM, Golden JP, Roy J, Tsoi S, Erickson JS, El-Naggar MY, Barton SC, and Tender LM

Subjects

Biofilms, Electric Conductivity, Geobacter physiology

Published

2016

17. Biofilm as a redox conductor: a systematic study of the moisture and temperature dependence of its electrical properties.

Author

Phan H, Yates MD, Kirchhofer ND, Bazan GC, Tender LM, and Nguyen TQ

Subjects

Electric Conductivity, Electron Transport, Geobacter metabolism, Oxidation-Reduction, Temperature, Bioelectric Energy Sources standards, Biofilms, Geobacter chemistry

Abstract

Some microbial biofilms are electrically conductive. However, the mechanism of electron transport remains unclear. Here, we show that μm-scale long-distance electron transport through electrode-grown Geobacter sulfurreducens biofilms occurs via redox conduction, as determined by electrical measurements performed under varied hydration states and temperatures.

Published

2016

18. Imaging Active Surface Processes in Barnacle Adhesive Interfaces.

Author

Golden JP, Burden DK, Fears KP, Barlow DE, So CR, Burns J, Miltenberg B, Orihuela B, Rittshof D, Spillmann CM, Wahl KJ, and Tender LM

Subjects

Adhesiveness, Animals, Glass chemistry, Gold chemistry, Molting physiology, Optical Imaging, Oxidation-Reduction, Proteins metabolism, Refractometry, Seawater, Thoracica physiology, Adhesives chemistry, Amides chemistry, Proteins chemistry, Thoracica chemistry

Abstract

Surface plasmon resonance imaging (SPRI) and voltammetry were used simultaneously to monitor Amphibalanus (=Balanus) amphitrite barnacles reattached and grown on gold-coated glass slides in artificial seawater. Upon reattachment, SPRI revealed rapid surface adsorption of material with a higher refractive index than seawater at the barnacle/gold interface. Over longer time periods, SPRI also revealed secretory activity around the perimeter of the barnacle along the seawater/gold interface extending many millimeters beyond the barnacle and varying in shape and region with time. Ex situ experiments using attenuated total reflectance infrared (ATR-IR) spectroscopy confirmed that reattachment of barnacles was accompanied by adsorption of protein to surfaces on similar time scales as those in the SPRI experiments. Barnacles were grown through multiple molting cycles. While the initial reattachment region remained largely unchanged, SPRI revealed the formation of sets of paired concentric rings having alternately darker/lighter appearance (corresponding to lower and higher refractive indices, respectively) at the barnacle/gold interface beneath the region of new growth. Ex situ experiments coupling the SPRI imaging with optical and FTIR microscopy revealed that the paired rings coincide with molt cycles, with the brighter rings associated with regions enriched in amide moieties. The brighter rings were located just beyond orifices of cement ducts, consistent with delivery of amide-rich chemistry from the ducts. The darker rings were associated with newly expanded cuticle. In situ voltammetry using the SPRI gold substrate as the working electrode revealed presence of redox active compounds (oxidation potential approx 0.2 V vs Ag/AgCl) after barnacles were reattached on surfaces. Redox activity persisted during the reattachment period. The results reveal surface adsorption processes coupled to the complex secretory and chemical activity under barnacles as they construct their adhesive interfaces.

Published

2016

19. Thermally activated long range electron transport in living biofilms.

Author

Yates MD, Golden JP, Roy J, Strycharz-Glaven SM, Tsoi S, Erickson JS, El-Naggar MY, Calabrese Barton S, and Tender LM

Subjects

Electric Conductivity, Electron Transport, Geobacter metabolism, Temperature, Biofilms

Abstract

Microbial biofilms grown utilizing electrodes as metabolic electron acceptors or donors are a new class of biomaterials with distinct electronic properties. Here we report that electron transport through living electrode-grown Geobacter sulfurreducens biofilms is a thermally activated process with incoherent redox conductivity. The temperature dependency of this process is consistent with electron-transfer reactions involving hemes of c-type cytochromes known to play important roles in G. sulfurreducens extracellular electron transport. While incoherent redox conductivity is ubiquitous in biological systems at molecular-length scales, it is unprecedented over distances it appears to occur through living G. sulfurreducens biofilms, which can exceed 100 microns in thickness.

Published

2015

20. Metaproteomic evidence of changes in protein expression following a change in electrode potential in a robust biocathode microbiome.

Author

Leary DH, Hervey WJ 4th, Malanoski AP, Wang Z, Eddie BJ, Tender GS, Vora GJ, Tender LM, Lin B, and Strycharz-Glaven SM

Subjects

Biofilms growth & development, Bioreactors, Marinobacter genetics, Transcriptome, Microbiota genetics, Protein Biosynthesis genetics, Proteomics, RNA, Ribosomal, 16S genetics

Abstract

Microorganisms that respire electrodes may be exploited for biotechnology applications if key pathways for extracellular electron transfer can be identified and manipulated through bioengineering. To determine whether expression of proposed Biocathode-MCL extracellular electron transfer proteins are changed by modulating electrode potential without disrupting the relative distribution of microbial constituents, metaproteomic and 16S rRNA gene expression analyses were performed after switching from an optimal to suboptimal potential based on an expected decrease in electrode respiration. Five hundred and seventy-nine unique proteins were identified across both potentials, the majority of which were assigned to three previously defined Biocathode-MCL metagenomic clusters: a Marinobacter sp., a member of the family Chromatiaceae, and a Labrenzia sp (abbreviated as MCL). Statistical analysis of spectral counts using the Fisher's exact test identified 16 proteins associated with the optimal potential, five of which are predicted electron transfer proteins. The majority of proteins associated with the suboptimal potential were involved in protein turnover/synthesis, motility, and membrane transport. Unipept and 16S rRNA gene expression analyses indicated that the taxonomic profile of the microbiome did not change after 52 h at the suboptimal potential. These findings show that protein expression is sensitive to the electrode potential without inducing shifts in community composition, a feature that may be exploited for engineering Biocathode-MCL. All MS data have been deposited in the ProteomeXchange with identifier PXD001590 (http://proteomecentral.proteomexchange.org/dataset/PXD001590)., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

21. A previously uncharacterized, nonphotosynthetic member of the Chromatiaceae is the primary CO2-fixing constituent in a self-regenerating biocathode.

Author

Wang Z, Leary DH, Malanoski AP, Li RW, Hervey WJ 4th, Eddie BJ, Tender GS, Yanosky SG, Vora GJ, Tender LM, Lin B, and Strycharz-Glaven SM

Subjects

Biota, Chromatiaceae genetics, DNA, Bacterial chemistry, DNA, Bacterial genetics, Metagenome, Microbial Consortia, Molecular Sequence Data, Proteome, Sequence Analysis, DNA, Bioelectric Energy Sources, Carbon Dioxide metabolism, Chromatiaceae isolation & purification, Chromatiaceae metabolism, Electrodes microbiology

Abstract

Biocathode extracellular electron transfer (EET) may be exploited for biotechnology applications, including microbially mediated O2 reduction in microbial fuel cells and microbial electrosynthesis. However, biocathode mechanistic studies needed to improve or engineer functionality have been limited to a few select species that form sparse, homogeneous biofilms characterized by little or no growth. Attempts to cultivate isolates from biocathode environmental enrichments often fail due to a lack of some advantage provided by life in a consortium, highlighting the need to study and understand biocathode consortia in situ. Here, we present metagenomic and metaproteomic characterization of a previously described biocathode biofilm (+310 mV versus a standard hydrogen electrode [SHE]) enriched from seawater, reducing O2, and presumably fixing CO2 for biomass generation. Metagenomics identified 16 distinct cluster genomes, 15 of which could be assigned at the family or genus level and whose abundance was roughly divided between Alpha- and Gammaproteobacteria. A total of 644 proteins were identified from shotgun metaproteomics and have been deposited in the the ProteomeXchange with identifier PXD001045. Cluster genomes were used to assign the taxonomic identities of 599 proteins, with Marinobacter, Chromatiaceae, and Labrenzia the most represented. RubisCO and phosphoribulokinase, along with 9 other Calvin-Benson-Bassham cycle proteins, were identified from Chromatiaceae. In addition, proteins similar to those predicted for iron oxidation pathways of known iron-oxidizing bacteria were observed for Chromatiaceae. These findings represent the first description of putative EET and CO2 fixation mechanisms for a self-regenerating, self-sustaining multispecies biocathode, providing potential targets for functional engineering, as well as new insights into biocathode EET pathways using proteomics., (Copyright © 2015, American Society for Microbiology. All Rights Reserved.)

Published

2015

22. Spatially resolved confocal resonant Raman microscopic analysis of anode-grown Geobacter sulfurreducens biofilms.

Author

Lebedev N, Strycharz-Glaven SM, and Tender LM

Subjects

Biofilms, Cytochromes c chemistry, Cytochromes c metabolism, Electrochemical Techniques, Electrodes, Electron Transport, Geobacter growth & development, Heme chemistry, Microscopy, Confocal, Oxidation-Reduction, Spectrum Analysis, Raman, Geobacter physiology

Abstract

When grown on the surface of an anode electrode, Geobacter sulfurreducens forms a multi-cell thick biofilm in which all cells appear to couple the oxidation of acetate with electron transport to the anode, which serves as the terminal metabolic electron acceptor. Just how electrons are transported through such a biofilm from cells to the underlying anode surface over distances that can exceed 20 microns remains unresolved. Current evidence suggests it may occur by electron hopping through a proposed network of redox cofactors composed of immobile outer membrane and/or extracellular multi-heme c-type cytochromes. In the present work, we perform a spatially resolved confocal resonant Raman (CRR) microscopic analysis to investigate anode-grown Geobacter biofilms. The results confirm the presence of an intra-biofilm redox gradient whereby the probability that a heme is in the reduced state increases with increasing distance from the anode surface. Such a gradient is required to drive electron transport toward the anode surface by electron hopping via cytochromes. The results also indicate that at open circuit, when electrons are expected to accumulate in redox cofactors involved in electron transport due to the inability of the anode to accept electrons, nearly all c-type cytochrome hemes detected in the biofilm are oxidized. The same outcome occurs when a comparable potential to that measured at open circuit (-0.30 V vs. SHE) is applied to the anode, whereas nearly all hemes are reduced when an exceedingly negative potential (-0.50 V vs. SHE) is applied to the anode. These results suggest that nearly all c-type cytochrome hemes detected in the biofilm can be electrochemically accessed by the electrode, but most have oxidation potentials too negative to transport electrons originating from acetate metabolism. The results also reveal a lateral heterogeneity (x-y dimensions) in the type of c-type cytochromes within the biofilm that may affect electron transport to the electrode., (Copyright © 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2014

23. Electrochemical investigation of a microbial solar cell reveals a nonphotosynthetic biocathode catalyst.

Author

Strycharz-Glaven SM, Glaven RH, Wang Z, Zhou J, Vora GJ, and Tender LM

Subjects

Base Sequence, Biocatalysis, Cloning, Molecular, DNA Primers genetics, Electrochemistry, Graphite, Marinobacter ultrastructure, Microscopy, Confocal, Microscopy, Electron, Scanning, Molecular Sequence Data, Oxidation-Reduction, Phylogeny, RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA, Bioelectric Energy Sources microbiology, Biofilms, Electrodes microbiology, Marinobacter genetics, Solar Energy

Abstract

Microbial solar cells (MSCs) are microbial fuel cells (MFCs) that generate their own oxidant and/or fuel through photosynthetic reactions. Here, we present electrochemical analyses and biofilm 16S rRNA gene profiling of biocathodes of sediment/seawater-based MSCs inoculated from the biocathode of a previously described sediment/seawater-based MSC. Electrochemical analyses indicate that for these second-generation MSC biocathodes, catalytic activity diminishes over time if illumination is provided during growth, whereas it remains relatively stable if growth occurs in the dark. For both illuminated and dark MSC biocathodes, cyclic voltammetry reveals a catalytic-current-potential dependency consistent with heterogeneous electron transfer mediated by an insoluble microbial redox cofactor, which was conserved following enrichment of the dark MSC biocathode using a three-electrode configuration. 16S rRNA gene profiling showed Gammaproteobacteria, most closely related to Marinobacter spp., predominated in the enriched biocathode. The enriched biocathode biofilm is easily cultured on graphite cathodes, forms a multimicrobe-thick biofilm (up to 8.2 μm), and does not lose catalytic activity after exchanges of the reactor medium. Moreover, the consortium can be grown on cathodes with only inorganic carbon provided as the carbon source, which may be exploited for proposed bioelectrochemical systems for electrosynthesis of organic carbon from carbon dioxide. These results support a scheme where two distinct communities of organisms develop within MSC biocathodes: one that is photosynthetically active and one that catalyzes reduction of O2 by the cathode, where the former partially inhibits the latter. The relationship between the two communities must be further explored to fully realize the potential for MSC applications.

Published

2013

24. Long-range electron transport in Geobacter sulfurreducens biofilms is redox gradient-driven.

Author

Snider RM, Strycharz-Glaven SM, Tsoi SD, Erickson JS, and Tender LM

Subjects

Bioelectric Energy Sources, Catalysis, Electrochemistry methods, Electrodes, Electron Transport, Electrons, Microbiology, Microscopy, Electron, Scanning methods, Models, Biological, Oxygen chemistry, Biofilms, Geobacter metabolism, Oxidation-Reduction

Abstract

Geobacter spp. can acquire energy by coupling intracellular oxidation of organic matter with extracellular electron transfer to an anode (an electrode poised at a metabolically oxidizing potential), forming a biofilm extending many cell lengths away from the anode surface. It has been proposed that long-range electron transport in such biofilms occurs through a network of bound redox cofactors, thought to involve extracellular matrix c-type cytochromes, as occurs for polymers containing discrete redox moieties. Here, we report measurements of electron transport in actively respiring Geobacter sulfurreducens wild type biofilms using interdigitated microelectrode arrays. Measurements when one electrode is used as an anode and the other electrode is used to monitor redox status of the biofilm 15 μm away indicate the presence of an intrabiofilm redox gradient, in which the concentration of electrons residing within the proposed redox cofactor network is higher farther from the anode surface. The magnitude of the redox gradient seems to correlate with current, which is consistent with electron transport from cells in the biofilm to the anode, where electrons effectively diffuse from areas of high to low concentration, hopping between redox cofactors. Comparison with gate measurements, when one electrode is used as an electron source and the other electrode is used as an electron drain, suggests that there are multiple types of redox cofactors in Geobacter biofilms spanning a range in oxidation potential that can engage in electron transport. The majority of these redox cofactors, however, seem to have oxidation potentials too negative to be involved in electron transport when acetate is the electron source.

Published

2012

25. On electron transport through Geobacter biofilms.

Author

Bond DR, Strycharz-Glaven SM, Tender LM, and Torres CI

Subjects

Bacterial Proteins metabolism, Catalysis, Cytochrome c Group metabolism, Electrodes microbiology, Electron Transport, Hydrogen-Ion Concentration, Nanostructures, Oxidation-Reduction, Bioelectric Energy Sources, Biofilms, Geobacter physiology

Abstract

Geobacter spp. can form a biofilm that is more than 20 μm thick on an anode surface by utilizing the anode as a terminal respiratory electron acceptor. Just how microbes transport electrons through a thick biofilm and across the biofilm/anode interface, and what determines the upper limit to biofilm thickness and catalytic activity (i.e., current, the rate at which electrons are transferred to the anode), are fundamental questions attracting substantial attention. A significant body of experimental evidence suggests that electrons are transferred from individual cells through a network of cytochromes associated with cell outer membranes, within extracellular polymeric substances, and along pili. Here, we describe what is known about this extracellular electron transfer process, referred to as electron superexchange, and its proposed role in biofilm anode respiration. Superexchange is able to account for many different types of experimental results, as well as for the upper limit to biofilm thickness and catalytic activity that Geobacter biofilm anodes can achieve., (Copyright © 2012 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2012

26. Study of the mechanism of catalytic activity of G. sulfurreducens biofilm anodes during biofilm growth.

Author

Strycharz-Glaven SM and Tender LM

Subjects

Catalysis, Electrodes microbiology, Electron Transport, Oxidation-Reduction, Bioelectric Energy Sources, Biofilms growth & development, Geobacter physiology

Abstract

The number of investigations involving bioelectrochemical systems (BES), processes in which microorganisms catalyze electrode reactions, is increasing while their mechanisms remain unresolved. Geobacter sulfurreducens strain DL1 is a model electrode catalyst that forms multimicrobe-thick biofilms on anodes that catalyze the oxidation of acetate to result in an electric current. Here, we report the characterization by cyclic voltammetry (CV) of DL1 biofilm-modified anodes (biofilm anodes) performed during biofilm development. This characterization, based on our recently reported model of biofilm anode catalytic activity, indicates the following. 1) As a biofilm grows, catalytic activity scales linearly with the amount of anode-accessible redox cofactor in the biofilm. This observation is consistent with a catalytic activity that is limited during biofilm growth by electron transport from within cells to the extracellular redox cofactor. 2) Distinct voltammetric features are exhibited that reflect the presence of a redox cofactor expressed by cells that initially colonize an anode that is not involved in catalytic current generation., (Copyright © 2012 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2012

27. Selection of a variant of Geobacter sulfurreducens with enhanced capacity for current production in microbial fuel cells.

Author

Yi H, Nevin KP, Kim BC, Franks AE, Klimes A, Tender LM, and Lovley DR

Subjects

Equipment Design, Equipment Failure Analysis, Species Specificity, Bioelectric Energy Sources microbiology, Electrochemistry instrumentation, Geobacter classification, Geobacter physiology

Abstract

Geobacter sulfurreducens produces current densities in microbial fuel cells that are among the highest known for pure cultures. The possibility of adapting this organism to produce even higher current densities was evaluated. A system in which a graphite anode was poised at -400 mV (versus Ag/AgCl) was inoculated with the wild-type strain of G. sulfurreducens, strain DL-1. An isolate, designated strain KN400, was recovered from the biofilm after 5 months of growth on the electrode. KN400 was much more effective in current production than strain DL-1. This was apparent with anodes poised at -400 mV, as well as in systems run in true fuel cell mode. KN400 had current (7.6A/m(2)) and power (3.9 W/m(2)) densities that respectively were substantially higher than those of DL1 (1.4A/m(2) and 0.5 W/m(2)). On a per cell basis KN400 was more effective in current production than DL1, requiring thinner biofilms to make equivalent current. The enhanced capacity for current production in KN400 was associated with a greater abundance of electrically conductive microbial nanowires than DL1 and lower internal resistance (0.015 versus 0.130 Omega/m(2)) and mass transfer limitation in KN400 fuel cells. KN400 produced flagella, whereas DL1 does not. Surprisingly, KN400 had much less outer-surface c-type cytochromes than DL1. KN400 also had a greater propensity to form biofilms on glass or graphite than DL1, even when growing with the soluble electron acceptor, fumarate. These results demonstrate that it is possible to enhance the ability of microorganisms to electrochemically interact with electrodes with the appropriate selective pressure and that improved current production is associated with clear differences in the properties of the outer surface of the cell that may provide insights into the mechanisms for microbe-electrode interactions.

Published

2009

28. Influence of anode pretreatment on its microbial colonization.

Author

Liu JL, Lowy DA, Baumann RG, and Tender LM

Subjects

Alphaproteobacteria isolation & purification, Biodiversity, Biofilms, Deltaproteobacteria isolation & purification, Deltaproteobacteria metabolism, Electrochemistry, Gammaproteobacteria isolation & purification, Gammaproteobacteria metabolism, Oxidation-Reduction, Proteobacteria metabolism, RNA, Bacterial, RNA, Ribosomal, 16S, Seawater microbiology, Sulfates metabolism, Sulfur metabolism, Water Microbiology, Bioelectric Energy Sources microbiology, Electrodes, Geologic Sediments microbiology, Proteobacteria isolation & purification

Abstract

Aims: To assess the influence of chemical treatment of the anode of a marine sediment biofuel cell (MSBFC) on the microbial diversity of the anode biofilm., Methods and Results: A MSBFC was equipped with two graphite plate anodes, one pretreated by electrochemical oxidation in sulfuric acid and the other untreated. After 6 weeks of operation, 16S rRNA clone libraries were constructed from each anode biofilm. The pretreated anode exhibited a fourfold depletion in gamma-proteobacteria, a fourfold enrichment in delta-proteobacteria, a sixfold increase in sulfate reducers, a fivefold enrichment in unclassified micro-organisms, and 6% of the colonies were sulfur oxidizers while none were detected on the untreated anode., Conclusion: Anode pretreatment significantly affects the anode-colonized microbial communities of MSBFCs., Significance and Impact of the Study: The MSBFC is one of a new class of microbial fuel cells in which the anode is spontaneously colonized by a subset of micro-organisms indigenous to a complex anaerobic mixture (such as sewage and food processing effluents). These micro-organisms utilize the anode as an oxidant, catalysing power generation by oxidizing fuel in the mixture and reducing the anode. This study reveals that pretreatment of the anode can greatly affect the composition of the microbial colony of such fuel cells.

Published

2007

29. Effect of electrode potential on electrode-reducing microbiota.

Author

Finkelstein DA, Tender LM, and Zeikus JG

Subjects

Acetates metabolism, Electrodes, Oxidation-Reduction, Oxygen chemistry, Bioelectric Energy Sources, Geologic Sediments microbiology, Seawater microbiology

Abstract

The benthic microbial fuel cell (BMFC) generates power by coupling oxidation of fuels naturally residing in marine sediments with reduction of oxygen in overlying waters. A central feature of BMFCs is spontaneous colonization of the anode by mineral-reducing microorganisms indigenous to marine sediments that catalyze the power-generating anodic reactions. Described here is a preliminary investigation of how the anode potential affects this feature. Different oxidative potentials were applied to a set of anodes under conditions known to promote anode enrichment of acetate oxidizing/mineral reducing microorganisms. In-situ analysis of current, acetate consumption, and reducing ability of the anode colonies suggest thatthe microorganisms conserve a significant portion (as much as 95%) of potential energy liberated from oxidation of acetate and reduction of the anode for their own metabolic benefit. The implication of this result with respect to BMFCs, and other MFCs utilizing electrode-reducing microbial catalysts, is that although the microorganisms enable long-term stability of such fuel cells, they may significantly impact efficiency of power output per equivalent of fuel consumed.

Published

2006

30. Harvesting energy from the marine sediment-water interface II. Kinetic activity of anode materials.

Author

Lowy DA, Tender LM, Zeikus JG, Park DH, and Lovley DR

Subjects

Electrodes, Ferrosoferric Oxide, Kinetics, Oceans and Seas, Seawater, Electrochemistry, Energy-Generating Resources, Geologic Sediments

Abstract

Here, we report a comparative study on the kinetic activity of various anodes of a recently described microbial fuel cell consisting of an anode imbedded in marine sediment and a cathode in overlying seawater. Using plain graphite anodes, it was demonstrated that a significant portion of the anodic current results from oxidation of sediment organic matter catalyzed by microorganisms colonizing the anode and capable of directly reducing the anode without added exogenous electron-transfer mediators. Here, graphite anodes incorporating microbial oxidants are evaluated in the laboratory relative to plain graphite with the goal of increasing power density by increasing current density. Anodes evaluated include graphite modified by adsorption of anthraquinone-1,6-disulfonic acid (AQDS) or 1,4-naphthoquinone (NQ), a graphite-ceramic composite containing Mn2+ and Ni2+, and graphite modified with a graphite paste containing Fe3O4 or Fe3O4 and Ni2+. It was found that these anodes possess between 1.5- and 2.2-fold greater kinetic activity than plain graphite. Fuel cells were deployed in a coastal site near Tuckerton, NJ (USA) that utilized two of these anodes. These fuel cells generated ca. 5-fold greater current density than a previously characterized fuel cell equipped with a plain graphite anode, and operated at the same site.

Published

2006

31. Electron conduction across electrode-immobilized neutravidin bound with biotin-labeled ruthenium pentaamine.

Author

Jhaveri SD, Trammell SA, Lowy DA, and Tender LM

Subjects

Amines metabolism, Avidin metabolism, Electrochemistry, Electrodes, Electrons, Models, Molecular, Molecular Structure, Organometallic Compounds chemistry, Organometallic Compounds metabolism, Propionates chemistry, Ruthenium metabolism, Staining and Labeling, Amines chemistry, Avidin chemistry, Biotin chemistry, Ruthenium chemistry

Abstract

Voltammetry is reported here of a self-assembled redox-protein conjugate consisting of neutravidin conjugated with a biotin derivative redox probe, Ru(NH3)5(N-[(N-[(4-pyridyl)methyl]biotinamide], immobilized on gold electrodes modified by self-assembled monolayers of mercaptoundecanoic acid. This voltammetry indicates that self-assembly of the conjugate/electrode electronic interface, driven by electrostatic binding between the monolayer and a single redox probe, favors orientation of the conjugate, resulting in electronic accessibility of the remaining three redox probes.

Published

2004

32. A reagentless electrochemical biosensor based on a protein scaffold.

Author

Jhaveri SD, Mauro JM, Goldston HM, Schauer CL, Tender LM, and Trammell SA

Subjects

Animals, Apoproteins chemistry, Avidin chemistry, Biotin chemistry, Electrochemistry, Electrodes, Molecular Probe Techniques, Organometallic Compounds, Oxidation-Reduction, Protein Engineering, Whales, Biosensing Techniques methods, Myoglobin chemistry, Ruthenium chemistry

Abstract

Apo-myoglobin, labeled with the environmentally sensitive redox probe RuII(NH3)4(1,10-phenanthroline-5-maleimide)2+, was immobilized onto gold electrodes modified with 11-mercaptoundecanoic acid and subsequently labeled with biotin; avidin binding to the immobilized biotin was specifically and quantitatively detected by a change in cyclic voltammetry of the co-immobilized probe.

Published

2003

33. Harnessing microbially generated power on the seafloor.

Author

Tender LM, Reimers CE, Stecher HA 3rd, Holmes DE, Bond DR, Lowy DA, Pilobello K, Fertig SJ, and Lovley DR

Subjects

Bacteria classification, Bacteria genetics, Biotechnology methods, Carbon metabolism, Conservation of Energy Resources methods, DNA, Ribosomal analysis, DNA, Ribosomal genetics, Electricity, Electrodes, Molecular Sequence Data, New Jersey, Oceans and Seas, Oregon, Oxidation-Reduction, RNA, Bacterial analysis, RNA, Bacterial genetics, RNA, Ribosomal, 16S genetics, Sulfides metabolism, Bacteria metabolism, Bioelectric Energy Sources microbiology, Environmental Microbiology, Geologic Sediments microbiology

Abstract

In many marine environments, a voltage gradient exists across the water sediment interface resulting from sedimentary microbial activity. Here we show that a fuel cell consisting of an anode embedded in marine sediment and a cathode in overlying seawater can use this voltage gradient to generate electrical power in situ. Fuel cells of this design generated sustained power in a boat basin carved into a salt marsh near Tuckerton, New Jersey, and in the Yaquina Bay Estuary near Newport, Oregon. Retrieval and analysis of the Tuckerton fuel cell indicates that power generation results from at least two anode reactions: oxidation of sediment sulfide (a by-product of microbial oxidation of sedimentary organic carbon) and oxidation of sedimentary organic carbon catalyzed by microorganisms colonizing the anode. These results demonstrate in real marine environments a new form of power generation that uses an immense, renewable energy reservoir (sedimentary organic carbon) and has near-immediate application.

Published

2002

34. Ion-induced discrete charging of immobilized water-soluble gold nanoclusters.

Author

Jhaveri SD, Lowy DA, Foos EE, Snow AW, Ancona MG, and Tender LM

Abstract

Hydrophilic gold nanoclusters were immobilized onto monolayer-modified gold electrodes and PF6-(-)induced rectification and stepwise capacitance charging was studied in aqueous supporting electrolyte by cyclic voltammetry and ac voltammetry.

Published

2002

35. Voltage-induced inhibition of antigen-antibody binding at conducting optical waveguides.

Author

Liron Z, Tender LM, Golden JP, and Ligler FS

Subjects

Animals, Antigen-Antibody Reactions, Binding Sites, Antibody, Biosensing Techniques instrumentation, Biosensing Techniques methods, Coated Materials, Biocompatible chemistry, Electric Conductivity, Electromagnetic Fields, Equipment Design, Fluorescent Antibody Technique instrumentation, Fluorescent Antibody Technique methods, Fluoroimmunoassay instrumentation, Fluoroimmunoassay methods, Glass, Microchemistry methods, Optics and Photonics, Rabbits, Sensitivity and Specificity, Antigen-Antibody Complex chemistry, Electrochemistry methods, Fluorescence Polarization Immunoassay instrumentation, Fluorescence Polarization Immunoassay methods, Ovalbumin analysis, Tin Compounds chemistry

Abstract

Optical waveguides coated with electrically conducting indium-tin oxide (ITO) are demonstrated here as a new class of substrate for fluorescent immunosensors. These waveguides combine electrochemical control with evanescent excitation and image-based detection. Presented here are preliminary results utilizing these waveguides that demonstrate influence of waveguide voltage on antigen binding. Specifically, waveguide surfaces were bisected into electrically addressable halves, anti-ovalbumin immobilized in patterns on their surfaces, and a 1.3 V bias applied between waveguide halves in the presence of Cy5-labeled ovalbumin in 10 mM phosphate buffer (pH 7.4) containing 150 mM NaCl and 0.05% Tween-20. Fluorescence imaging indicated that binding of the antigen to positively biased waveguide halves was inhibited nearly 10-fold compared with negatively biased waveguide halves and unbiased controls. Furthermore, it is shown that ovalbumin binding to positively biased waveguide regions is regenerated after removal of applied voltage. These results suggest that electrochemical control of immunosensor substrates can be used as a possible strategy toward minimizing cross-reactive binding and/or nonspecific adsorption, immunosensor regeneration, and controlled binding.

Published

2002

36. A model recognition switch. Electrochemical control and transduction of imidazole binding by electrode-immobilized microperoxidase-11.

Author

Goldston HM Jr, Scribner AN, Trammell SA, and Tender LM

Subjects

Electrochemistry, Electrodes, Protein Binding, Titrimetry, Enzymes, Immobilized metabolism, Imidazoles pharmacokinetics, Peroxidases metabolism

Abstract

Electrode-immobilized microperoxidase-11 exhibited a titratable potentiometric response to imidazole, demonstrating both molecular recognition and the capability for "switchable" changes in the affinity of an immobilized redox-receptor for a target ligand.

Published

2002

37. Electrode-reducing microorganisms that harvest energy from marine sediments.

Author

Bond DR, Holmes DE, Tender LM, and Lovley DR

Subjects

Aerobiosis, Anaerobiosis, Anthraquinones pharmacology, Benzoates metabolism, Biodegradation, Environmental, Carbon Dioxide metabolism, Colony Count, Microbial, DNA, Ribosomal analysis, DNA, Ribosomal genetics, Deltaproteobacteria classification, Deltaproteobacteria genetics, Deltaproteobacteria growth & development, Electrons, Energy Metabolism, Oxidation-Reduction, RNA, Ribosomal, 16S genetics, Sodium Acetate metabolism, Deltaproteobacteria metabolism, Electricity, Electrodes, Geologic Sediments microbiology, Seawater

Abstract

Energy in the form of electricity can be harvested from marine sediments by placing a graphite electrode (the anode) in the anoxic zone and connecting it to a graphite cathode in the overlying aerobic water. We report a specific enrichment of microorganisms of the family Geobacteraceae on energy-harvesting anodes, and we show that these microorganisms can conserve energy to support their growth by oxidizing organic compounds with an electrode serving as the sole electron acceptor. This finding not only provides a method for extracting energy from organic matter, but also suggests a strategy for promoting the bioremediation of organic contaminants in subsurface environments.

Published

2002

38. Synthesis and characterization of a ruthenium(II)-based redox conjugate for reagentless biosensing.

Author

Trammell SA, Goldston HM Jr, Tran PT, Tender LM, Conrad DW, Benson DE, and Hellinga HW

Subjects

Carrier Proteins genetics, Chemical Phenomena, Chemistry, Physical, Maltose metabolism, Maltose-Binding Proteins, Oxidation-Reduction, Protein Binding physiology, Protein Engineering, Biosensing Techniques, Carrier Proteins chemistry, Maleimides chemical synthesis, Phenanthrolines chemistry, Ruthenium chemistry

Abstract

Synthesis of a novel sulfhydryl-specific, tetraammine Ru(II)polypyridyl complex, [Ru(II)(NH(3))(4)(1,10-phenanthroline-5-maleimide)](PF(6))(2), which exhibits environment-sensitive electrochemical properties is described. When conjugated to an allosteric site in a genetically engineered mutant of maltose binding protein, the formal potential of the conjugated redox probe is shifted to higher potential upon maltose binding. The magnitude of this potential shift was used to measure maltose affinity of the protein-redox conjugate complex and to monitor maltose concentration in solution. These results are presented in context of reagentless biosensing.

Published

2001

39. Harvesting energy from the marine sediment--water interface.

Author

Reimers CE, Tender LM, Fertig S, and Wang W

Subjects

Electrodes, Oceanography, Electric Power Supplies, Geologic Sediments chemistry, Seawater chemistry

Abstract

Pairs of platinum mesh or graphite fiber-based electrodes, one embedded in marine sediment (anode), the other in proximal seawater (cathode), have been used to harvest low-level power from natural, microbe established, voltage gradients at marine sediment-seawater interfaces in laboratory aquaria. The sustained power harvested thus far has been on the order of 0.01 W/m2 of electrode geometric area but is dependent on electrode design, sediment composition, and temperature. It is proposed that the sediment/anode-seawater/cathode configuration constitutes a microbial fuel cell in which power results from the net oxidation of sediment organic matter by dissolved seawater oxygen. Considering typical sediment organic carbon contents, typical fluxes of additional reduced carbon by sedimentation to sea floors < 1,000 m deep, and the proven viability of dissolved seawater oxygen as an oxidant for power generation by seawater batteries, it is calculated that optimized power supplies based on the phenomenon demonstrated here could power oceanographic instruments deployed for routine long-term monitoring operations in the coastal ocean.

Published

2001

40. Array biosensor for simultaneous identification of bacterial, viral, and protein analytes.

Author

Rowe CA, Tender LM, Feldstein MJ, Golden JP, Scruggs SB, MacCraith BD, Cras JJ, and Ligler FS

Subjects

Enzyme-Linked Immunosorbent Assay, Sensitivity and Specificity, Antibodies analysis, Antigens, Bacterial analysis, Antigens, Viral analysis, Biosensing Techniques

Abstract

The array biosensor was fabricated to analyze multiple samples simultaneously for multiple analytes. The sensor utilized a standard sandwich immunoassay format: Antigen-specific "capture" antibodies were immobilized in a patterned array on the surface of a planar waveguide and bound analyte was subsequently detected using fluorescent tracer antibodies. This study describes the analysis of 126 blind samples for the presence of three distinct classes of analytes. To address potential complications arising from using a mixture of tracer antibodies in the multianalyte assay, three single-analyte assays were run in parallel with a multianalyte assay. Mixtures of analytes were also assayed to demonstrate the sensor's ability to detect more than a single species at a time. The array sensor was capable of detecting viral, bacterial, and protein analytes using a facile 14-min assay with sensitivity levels approaching those of standard ELISA methods. Limits of detection for Bacillus globigii, MS2 bacteriophage, and staphylococcal enterotoxin B (SEB) were 10(5) cfu/mL, 10(7) pfu/mL, and 10 ng/mL, respectively. The array biosensor also analyzed multiple samples simultaneously and detected mixtures of the different types of analytes in the multianalyte format.

Published

1999

41. Computer-controlled laser ablation: a convenient and versatile tool for micropatterning biofunctional synthetic surfaces for applications in biosensing and tissue engineering.

Author

Vaidya R, Tender LM, Bradley G, O'Brien MJ 2nd, Cone M, and López GP

Subjects

Computers, Culture Techniques, Electrochemistry, Lasers, Biosensing Techniques, Biotechnology

Abstract

This paper describes laser-based methods for preparing micropatterns of bioactive molecular species in self-assembled monolayers (SAMs) and micropatterns of proteins and other biological molecules immobilized on solid substrates. Applications of these micropatterned surfaces in multianalyte biosensing and tissue engineering are emphasized. The focus of the paper is on the use of a computer-controlled laser ablation system comprising a research-grade inverted optical microscope, a pulsed nitrogen-pumped dye laser emitting at 390 nm, a programmable sample stage, and the computerized control system. The laser system can be implemented in a typical biosensor or tissue culture laboratory to enable the facile and reproducible fabrication of micropatterned surfaces by several methods. Various methods for patterning are discussed with examples given and emphasis placed on (1) laser ablation in the fabrication of photolithography masks, (2) electrochemical patterning of SAMs, and (3) laser desorption of SAMs. The relative merits of each technique are discussed with respect to application in fabrication of active surfaces for biosensing and tissue culture applications.

Published

1998