MR-1 are described as a form of conductive pilus associated with the membrane. Also, the
lipids colocalized on these extracellular structures aid in performing a multistep redox
hopping mechanism that contributes to electron transfer (Figure 11.4).
Recently, Subramanian et al. [32], used electron cryotomography microscopy to de
termine the ultrastructure of the nanowire produced by the S. oneidensis strain. In the outer
membrane and periplasm of the strain, EET was observed on the microbial nanowires. In
this study, the authors used light and electrons which revealed that these structures on
S. oneidensis were curved and an extension tabulation form was observed. Moreover, less
c-cytochrome in mutant strain compared to the wild type strain was observed. The peri
plasm and outer membrane proteins were consistent with cytochromes [32]. The result
obtained revealed that S. oneidensis MR-1 nanowires were outer membrane vesicles with
variable lengths [33].
11.5 Geobacter and Shewanella EET Mechanism
11.5.1 The Hopping Mechanism by S. Oneidensis Strain MR-1 Nanowires
Several mechanisms are used by the bacteria in electron transfer including DET, mediated
electron transfer, and through nanowires, as represented in Figure 11.3. For the S. onei
densis strain MR-1 nanowires, the electron transfer by extracellular nanowires occurred
through the hopping mechanism. The hopping mechanism is a transferred electron that
can be determined between two sites in a solid specimen from one molecule to another
with the acquisition of energy (Figure 11.5) [23].
This concept has been described in connection with ionic conduction in amorphous
non-metallic solids and after it has been extended to electrons. The hopping transition can
be determined by both the distance between the two sites and the potential. If the po
tential barrier width is larger than 10 Å, it causes the electrons to hop rather than tunnel
from one molecule to the neighboring one. In fact, the hopping process is similar to the
atomic diffusion process. However, in hopping, there is no electron transfer until the
thermal motion of nuclei permits electron motion over the barrier by rearrangement of
the molecule. In the electron hopping mechanism, it was suggested that the outer surface
cytochromes were aligned along the filament, which enabled sufficient electronic cou
pling. To form the microbial nanowires, the S. oneidensis MR-1 strain requires cyto
chromes called MtrC and OmcA, which can be involved in electron transfer [4,34]. The
composition analysis of the bacterial nanowires by electron microscopy imaging of
Shewanella S. oneidensis MR-1 nanowires showed that the outer membrane extensions
contained components rather than pilin-based structures, which include cytochromes that
improve the electron hopping pattern. These multiheme cytochromes of the MtrC and
OmcA are localized on the outer membranes. They can be associated with the nanowires
of Shewanella and are mediators for electron transfer.
11.5.2 Tunneling Mechanism
Tunneling is a mechanical phenomenon in which the excited state electron can tunnel to
the neighboring molecule in one of the multiple consecutive steps by exchanging energy
through the tunneling process. In the tunneling effect, an electron moves through the
Microbial Nanowires
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