At the bottom of the
ocean, there is a strange world of microbes thriving in mud sediments. They all
strive toward the same vital goal of using oxygen and available nutrients to
produce energy for growth, so competition is fierce.
The bacteria on the seabed
surface are the lucky ones, as they can readily take up oxygen from sea water.
But a couple of centimeters below oxygen is scarce, and bacteria buried deep
into the mud need to come up with more ingenious ways to gain energy.
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| Bacteria cables in the sea bed mud (Credit: Mingdong Dong, Jie Song and Nils Risgaard-Petersen) |
In a new study published in Nature, a research team led by Nils Risgaard-Petersen and Lars Nielsen
at Aarhus University in Denmark, shows how some bizarre bacteria employ a
cunning trick to both feed from nutrients in deep marine sediment and consume
oxygen at the surface: they function as living electric cables.
A couple of years ago, the team made the astonishing discovery that electric currents linked oxygen consumption at the top sediment layers with hydrogen sulfide at the bottom, more than a centimeter away. "The identity of the electron conductor has however been an enigma" Risgaard-Petersen says.
A couple of years ago, the team made the astonishing discovery that electric currents linked oxygen consumption at the top sediment layers with hydrogen sulfide at the bottom, more than a centimeter away. "The identity of the electron conductor has however been an enigma" Risgaard-Petersen says.
The scientists postulated
that bacteria could work together to conduct these electric currents through a
network of tiny hair-like appendages called nanowires. However, evidence so far
shows that bacterial nanowires can only transfer electrons over shorter
distances, so this alone could not explain the intriguing results.
To solve this riddle,
Risgaard-Petersen and colleagues collected samples of marine sediment from
Aarhus bay and carefully scrutinized the top sediment layers. In a true eureka
moment, they found tufts of entangled centimeter-long filamentous bacteria. "Before us nobody had hypothesized
about its existence, so nobody had looked for it" says Risgaard-Petersen.
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| The filaments of bacteria stretch between the top and bottom sediment layers (Credit: Nils Risgaard-Petersen) |
The filamentous microbes
turned out to be new members of the Desulfobulbaceae family, which includes
bacteria capable of consuming hydrogen sulfide in deep sediment zones. This
seemed like a good indication that these long bacteria filaments could be
mediating the flow of electrons across distant sediment layers. Indeed, when
the scientists cut the filaments, the electric currents stopped and the
consumption of oxygen and hydrogen sulfide plunged.
"Risgaard-Petersen
and collaborators linked the presence of bacterial filaments to the electrical
coupling of the oxygen and sulfide layers in marine sediments, which are
typically separated by millimeter to centimeter distances" says Gemma Reguera, a microbiologist from
Michigan State University specialized in the study of sediment bacteria "These [distance] scales truly defy
our current knowledge of biological electron transfer".
Each filament consists of
many bacterial cells lined up in a long chain and surrounded by a shared outer
membrane. Interestingly, this outer membrane has uniform ridges filled up with
charged material running along the entire length of the filament. The authors
of the study believe these ridges could be 'internal insulated wires' for
driving the electron flow across sediment layers. However, these molecular
details remain unclear.
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| A cross-section of four cable bacteria viewed with an transmission electron microscope (Credit: Karen Thomsen) |
Derek Lovley, an expert
on electromicrobiology at the University of Massachusetts thinks that
discovering the source of this 'potentially conductive material' is crucial. "As with the initial studies with
[bacterial nanowires] there will be skeptics because they have not been able to
measure long-range electron transport directly" and adds "It will be
interesting to watch this story unfold."
More
than tens of thousand kilometers of filamentous bacteria live in a single
square meter of mud from the undisturbed seabed, so it is possible that this
type of long-distance electron transport could be widespread in nature. The
long filaments are however very fragile, and small disturbances such as sea
waves could lead to 'fatal cable breakage'. Eric Roden, an expert on
biogeochemistry at the University of Wisconsin notes "Whether
or not such filamentous networks are actually present and active in natural
sediments, where all sorts of mixing processes and other disturbances are
common, remains to be determined".
Since
the discovery of bacterial nanowires, several research teams have explored
their potential biotechnological applications, for example, in bioelectronic
devices or for electricity generation from renewable sources, such as waste.
Could the filamentous bacteria potentially be used for technology development?
"We need to know more about how current is transported inside these organisms" explains Risgaard-Petersen "but perhaps there is a possibility to grow electric conductive structures for use in electrical devices".
This article was published in The Munich Eye on 26-10-2012. You can read it here.
Source:
Pfeffer, C. et al. Nature (2012) http://dx.doi.org/10.1038/nature11586
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