Genetic and Transcriptomic Analysis of Microbial Electro-Extraction for Releasing Metals from Spent Lithium-Ion Batteries
authors.elsevier.com/a/1lxGf3QUFZ...
Introducing Microbial Electro-Extraction (MEE): a sustainable electromicrobiological strategy for recycling spent lithium-ion batteries.
authors.elsevier.com/a/1lxGf3QUFZ...
Introducing Microbial Electro-Extraction (MEE): a sustainable electromicrobiological strategy for recycling spent lithium-ion batteries.
Constructing artificial neurons with functional parameters comprehensively matching biological values
rdcu.be/eI8Aj
Artificial neurons fabricated with microbially produced protein nanowires closely emulate biological neurons
Yet another sustainable e-Biologics application
@UMassAmherst
rdcu.be/eI8Aj
Artificial neurons fabricated with microbially produced protein nanowires closely emulate biological neurons
Yet another sustainable e-Biologics application
@UMassAmherst
Constructing artificial neurons with functional parameters comprehensively matching biological values
Nature Communications - Artificial neurons typically have functional parameters that are mismatched with their biological counterpart. Here, the authors develop artificial neurons that emulate...
rdcu.be
Desulfovibrio ferrophilus corrosion mechanisms revealed!
authors.elsevier.com/a/1lSkc9pi-h...
Gene deletion study demonstrates the importance of H2 as an electron shuttle, rather than direct electron uptake, overturning a 20-year misconception in the field of microbial corrosion.
#Microbiology
authors.elsevier.com/a/1lSkc9pi-h...
Gene deletion study demonstrates the importance of H2 as an electron shuttle, rather than direct electron uptake, overturning a 20-year misconception in the field of microbial corrosion.
#Microbiology
Long-range electron transport in self-assembled fibrils of peptides rich in aromatic residues pubs.rsc.org/en/content/a...
@_IamRamesh_
Excellent overview of this topic.
#electrobiomaterials
@_IamRamesh_
Excellent overview of this topic.
#electrobiomaterials
Reposted by Derek R. Lovley
Check out a new preprint from my lab, led by Rhitu Kotoky, which shows the role of extracellular G-quadruplex RNA in cathodic extracellular electron transfer.
doi.org/10.1101/2025...
doi.org/10.1101/2025...
Extracellular RNA drives Electromethanogenesis in a Methanogenic Archaeon
Methanogenic archaea generate two-thirds of Earths methane. Some reduce CO2 by drawing electrons directly from solid substrates. Yet many, including Methanosarcina barkeri, lack the multiheme cytochromes (MHCs), that drive extracellular electron transfer (EET) in other microbes. Here we show that at growth onset, M. barkeri releases an extracellular nucleic-acid pool dominated by short RNAs (~80%) that self-assemble into G-quadruplexes (G4) on the cell surface. Addition of synthetic G4-RNA doubles cathodic methane production, whereas nuclease digestion abolishes EET. Neither treatment affected growth on soluble substrates. Thus, G4-RNA forms an electron conduit enabling cathodic EET in this MHC-deficient archaeon. The discovery broadens the inventory of biological wiring and hints that nucleic-acid electronics pre-date protein redox systems, with ramifications for early-Earth metabolism, bioenergy and living electronics. ### Competing Interest Statement The authors have declared no competing interest. Novo Nordisk Foundation, https://ror.org/04txyc737, NNF21OC0067353 European Research Council, 101045149
doi.org
Sensing devices fabricated with Escherichia coli expressing genetically tunable nanowires incorporated into a water-stable polymer
authors.elsevier.com/a/1knpe3PVtq...
Fabricating wearable sensors by mixing whole cells & their attached pilin-based nanowires into a flexible polymer composite.
authors.elsevier.com/a/1knpe3PVtq...
Fabricating wearable sensors by mixing whole cells & their attached pilin-based nanowires into a flexible polymer composite.
