TY - JOUR
T1 - Temperature-Dependent Characterization of Long-Range Conduction in Conductive Protein Fibers of Cable Bacteria
AU - van der Veen, Jasper R.
AU - Hidalgo Martinez, Silvia
AU - Wieland, Albert
AU - De Pellegrin, Matteo
AU - Verweij, Rick
AU - Blanter, Yaroslav M.
AU - van der Zant, Herre S.J.
AU - Meysman, Filip J.R.
PY - 2024
Y1 - 2024
N2 - Multicellular cable bacteria display an exceptional form of biological conduction, channeling electric currents across centimeter distances through a regular network of protein fibers embedded in the cell envelope. The fiber conductivity is among the highest recorded for biomaterials, but the underlying mechanism of electron transport remains elusive. Here, we performed detailed characterization of the conductance from room temperature down to liquid helium temperature to attain insight into the mechanism of long-range conduction. A consistent behavior is seen within and across individual filaments. The conductance near room temperature reveals thermally activated behavior, yet with a low activation energy. At cryogenic temperatures, the conductance at moderate electric fields becomes virtually independent of temperature, suggesting that quantum vibrations couple to the charge transport through nuclear tunneling. Our data support an incoherent multistep hopping model within parallel conduction channels with a low activation energy and high transfer efficiency between hopping sites. This model explains the capacity of cable bacteria to transport electrons across centimeter-scale distances, thus illustrating how electric currents can be guided through extremely long supramolecular protein structures.
AB - Multicellular cable bacteria display an exceptional form of biological conduction, channeling electric currents across centimeter distances through a regular network of protein fibers embedded in the cell envelope. The fiber conductivity is among the highest recorded for biomaterials, but the underlying mechanism of electron transport remains elusive. Here, we performed detailed characterization of the conductance from room temperature down to liquid helium temperature to attain insight into the mechanism of long-range conduction. A consistent behavior is seen within and across individual filaments. The conductance near room temperature reveals thermally activated behavior, yet with a low activation energy. At cryogenic temperatures, the conductance at moderate electric fields becomes virtually independent of temperature, suggesting that quantum vibrations couple to the charge transport through nuclear tunneling. Our data support an incoherent multistep hopping model within parallel conduction channels with a low activation energy and high transfer efficiency between hopping sites. This model explains the capacity of cable bacteria to transport electrons across centimeter-scale distances, thus illustrating how electric currents can be guided through extremely long supramolecular protein structures.
KW - biological electron transport
KW - cable bacteria
KW - conductivity
KW - nuclear tunneling
KW - protein fibers
UR - http://www.scopus.com/inward/record.url?scp=85210288353&partnerID=8YFLogxK
U2 - 10.1021/acsnano.4c12186
DO - 10.1021/acsnano.4c12186
M3 - Article
AN - SCOPUS:85210288353
SN - 1936-0851
VL - 18
SP - 32878
EP - 32889
JO - ACS Nano
JF - ACS Nano
IS - 47
ER -