SCIENCE sciencemag.org 21 AUGUST 2020 • VOL 369 ISSUE 6506 903
battle pollution and power electronic devices
(see sidebar, p. 904). “We are seeing way more
interactions within microbes and between
microbes being done by electricity,” Meysman
says. “I call it the electrical biosphere.”
MOST CELLS THRIVE by robbing electrons
from one molecule, a process called oxida-
tion, and donating them to another mol-
ecule, usually oxygen—so-called reduction.
Energy harvested from these reactions
drives the other processes of life. In eukary-
otic cells, including our own, such “redox”
reactions take place on the inner membrane
of the mitochondria, and the distances in-
volved are tiny—just micrometers. That is
why so many researchers were skeptical
of Nielsen’s claim that cable bacteria were
moving electrons across a span of mud
equivalent to the width of a golf ball.
The vanishing hydrogen sulfide was key
to proving it. Bacteria produce the com-
pound in mud by breaking down plant de-
bris and other organic material; in deeper
sediments, hydrogen sulfide builds up be-
cause there is little oxygen to help other
bacteria break it down. Yet, in Nielsen’s lab-
oratory beakers, the hydrogen sulfide was
disappearing anyway. Moreover, a rusty hue
appeared on the mud’s surface, indicating
that an iron oxide had formed.
One night, waking from his sleep, Nielsen
came up with a bizarre explanation: What if
bacteria buried in the mud were completing
the redox reaction by somehow bypassing
the oxygen-poor layers? What if, instead,
they used the ample supplies of hydrogen
sulfide as an electron donor, then shuttled
the electrons upward to the oxygen-rich
surface? There, the oxidation process would
produce rust if iron was present.
Finding what was carrying these electrons
proved complicated. First, Nils Risgaard-
Petersen on Nielsen’s team had to rule out a
simpler possibility: that metallic particles in
the sediment were shuttling electrons to the
surface and causing the oxidation. He ac-
complished that by inserting a layer of glass
beads, which don’t conduct electricity, into
a column of mud. Despite that obstacle, the
researchers still detected an electric current
moving through the mud, suggesting metal-
lic particles were not the conductor.
To see whether some kind of cable or wire
was ferrying electrons, the researchers next
used a tungsten wire to make a horizontal
slice through a column of mud. The current
flickered out, as if a wire had been snipped.
Other work narrowed down the conductor’s
size, suggesting it had to be at least 1 micro-
meter in diameter. “That’s the conventional
size for bacteria,” Nielsen says.
Ultimately, electron micrographs re-
vealed a likely candidate: long, thin, bac-
terial filaments that appeared in the layer
of glass beads inserted in the beakers filled
with the Aarhus Harbor mud. Each fila-
ment was composed of a stack of cells—up
to 2000—encased in a ridged outer mem-
brane. In the space between that membrane
and the stacked cells, many parallel “wires”
stretched the length of the filament. The
cablelike appearance inspired the microbe’s
common name.
Meysman, the one-time skeptic, quickly
became a convert. Not long after Nielsen
announced his discovery, Meysman decided
to examine one of his own marine mud
samples. “I noticed the same color changes
in the sediment that he saw,” Meysman re-
calls. “It was an instruction from Mother
Nature to take this more seriously.”
His team began to develop tools and tech-
niques for investigating the microbes, some-
times working collaboratively with Nielsen’s
group. It was tough going. The bacterial
filaments tended to degrade quickly once
isolated, and standard electrodes for mea-
suring currents in small conductors didn’t
work. But once the researchers learned how
to pick out a single filament and quickly at-
tach a customized electrode, “We saw really
high conductivity,” Meysman says. The liv-
ing cables don’t rival copper wires, he says,
Hydrogen sulfde
Oxygen (O 2 )
O 2
e–
e–
e–
e–
e–
e–
O 2
e–
e–
e–
e–
OX I DAT I O N
REDUCTION
ELECTRON TRANSFER
Acetate Carbon dioxide +e–
Electrons travel along
nanowires or bacterial cables.
Sulfde Sulfate +e–
+ Hydrogen
Fe+3 Fe+2
Water
Reactions such as
Reactions such as
free up electrons.
1
2
3
e–
1 cm^2
1
3
1
(^23)
Littorella
unifora
Water
Protein wire
Bacterium
Wire
Bacterium
Iron oxide (Fe+3))))
NEWS | FEATURES | MUD
Mud’s electric microbes
At least two kinds of bacteria have evolved electric solutions to gaining energy. These microbes, first discovered
in mud, separate the reduction and oxidation reactions that release the energy needed to fuel life. To enable
these reactions, nanowire bacteria move electrons just micrometers between cells, particles, or other electron
acceptors. Cable bacteria move electrons farther: up to 5 centimeters to oxygen-rich sediments.
A challenging
environment
In ocean and freshwater
sediments, the oxygen
needed for metabolism
is typically restricted
to surface layers or near
plant roots. In deeper
layers, toxic hydrogen
sulfide accumulates as
organic matter decays.
Nanowire bacteria
Found almost
everywhere
microbiologists
have looked, these
bacteria shuttle
electrons gained
through oxidation of
organic compounds
along protein
nanowires to
electron-accepting
substances or cells.
Sometimes these
wires are used
to grab electrons
instead.
Cable bacteria
These bacteria
create a cylinder
of conducting
wires that encases
a chain of cells.
The wires enable
the microbes to
transfer electrons
gained by oxidizing
hydrogen sulfide
to oxygen-rich
sediment, where
the electrons are
used to make water.
GRAPHIC: V. ALTOUNIAN/
SCIENCE
Published by AAAS