Data
stored in multiplying bacteria
- 11:02 08
January 2003 by Natasha McDowell
A message
encoded as artificial DNA can be stored within the genomes of multiplying
bacteria and then accurately retrieved, US scientists have shown.
Their
concern that all current ways of storing information, from paper to electronic
memory, can easily be lost or destroyed prompted them to devise a new type of
memory - within living organisms.
"A big
concern is the protection of valuable information in the case of a nuclear
catastrophe," says information technologist Pak Chung Wong, of the Pacific
Northwest National Laboratory in Washington State. The laboratory was set up as
a nuclear energy research institute.
A similar
catastrophe strikes the US in the cult television series Dark Angel, in which a
colossal electromagnetic pulse wipes out the electronic infrastructure.
"Bacteria may be an inexpensive and stable long-term means of data
storage," Wong told New Scientist.
Small
world
The
scientists took the words of the song It's a Small World and translated
it into a code based on the four "letters" of DNA. They then created
artificial DNA strands recording different parts of the song. These DNA
messages, each about 150 bases long, were inserted into bacteria such as E.
coli and Deinococcus radiodurans.
The
latter is especially good at surviving extreme conditions, says Wong. It can
tolerate high temperatures, desiccation, ultraviolet light and ionising
radiation doses 1000 times higher than would be fatal to humans.
The
beginning and end of each inserted message have special DNA tags devised by the
scientists. These "sentinels" stop the bacteria from identifying the
message as an invading a virus and destroying it, says Wong.
"The
magic of the sentinel is that it protects the information, so that even after a
hundred bacterial generations we were able to retrieve the exact message,"
says Wong. "Once the DNA message is in bacteria, it is protected and can
survive." And as a millilitre of liquid can contain up to billion
bacteria, the potential capacity of such a memory system is enormous.
Spontaneous
mutations
Deinococcus
is adapted to survive in extreme conditions and is consequently very good at
repairing any mutations that spontaneously arise in its DNA code. But Huw
Williams, a bacteriologist at Imperial College, London, says that the small
size of the inserted messages makes it no surprise that they survive 100
generations intact.
Williams
thinks a greater danger than mutations changing the message is that they could
make some bugs better adapted to their environment than others. So far, Wong
and colleagues have kept the different message colonies separate, but in future
they aim to retrieve messages from a mixed colony.
"If you
grow the colonies indefinitely, less well-adapted bacteria may be lost over
time," he says. "The question is whether you will be able to retain
all your message populations. But this is intriguing work and very forward
looking."
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