Methane-Linked Mechanisms of Electron Uptake from Cathodes by Methanosarcina barkeri

The , a lineage of cytochrome-containing methanogens, have recently been proposed to participate in direct extracellular electron transfer interactions within syntrophic communities. To shed light on this phenomenon, we applied electrochemical techniques to measure electron uptake from cathodes by ,...

Full description

Saved in:
Bibliographic Details
Published in:mBio 2019-03, Vol.10 (2)
Main Authors: Rowe, Annette R, Xu, Shuai, Gardel, Emily, Bose, Arpita, Girguis, Peter, Amend, Jan P, El-Naggar, Mohamed Y
Format: Article
Language:English
Subjects:
Applied and Environmental Science
archaea
BASIC BIOLOGICAL SCIENCES
Bioelectric Energy Sources
bioelectrochemistry
cathode
Electrodes - microbiology
Electron Transport
electrosynthesis
Gene Deletion
Hydrogen - metabolism
Hydrogenase - genetics
Hydrogenase - metabolism
Methane - metabolism
methanogenesis
Methanosarcina
Methanosarcina barkeri - metabolism
Microbiology
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The , a lineage of cytochrome-containing methanogens, have recently been proposed to participate in direct extracellular electron transfer interactions within syntrophic communities. To shed light on this phenomenon, we applied electrochemical techniques to measure electron uptake from cathodes by , which is an important model organism that is genetically tractable and utilizes a wide range of substrates for methanogenesis. Here, we confirm the ability of to perform electron uptake from cathodes and show that this cathodic current is linked to quantitative increases in methane production. The underlying mechanisms we identified include, but are not limited to, a recently proposed association between cathodes and methanogen-derived extracellular enzymes (e.g., hydrogenases) that can facilitate current generation through the formation of reduced and diffusible methanogenic substrates (e.g., hydrogen). However, after minimizing the contributions of such extracellular enzymes and using a mutant lacking hydrogenases, we observe a lower-potential hydrogen-independent pathway that facilitates cathodic activity coupled to methane production in Our electrochemical measurements of wild-type and mutant strains point to a novel and hydrogenase-free mode of electron uptake with a potential near -484 mV versus standard hydrogen electrode (SHE) (over 100 mV more reduced than the observed hydrogenase midpoint potential under these conditions). These results suggest that can perform multiple modes (hydrogenase-mediated and free extracellular enzyme-independent modes) of electrode interactions on cathodes, including a mechanism pointing to a direct interaction, which has significant applied and ecological implications. Methanogenic archaea are of fundamental applied and environmental relevance. This is largely due to their activities in a wide range of anaerobic environments, generating gaseous reduced carbon that can be utilized as a fuel source. While the bioenergetics of a wide variety of methanogens have been well studied with respect to soluble substrates, a mechanistic understanding of their interaction with solid-phase redox-active compounds is limited. This work provides insight into solid-phase redox interactions in spp. using electrochemical methods. We highlight a previously undescribed mode of electron uptake from cathodes that is potentially informative of direct interspecies electron transfer interactions in the .
ISSN:2161-2129
2150-7511
2150-7511
DOI:10.1128/mbio.02448-18