23 May 2017
By Jessica Hamzelou
Cut off the head of a planarian
flatworm, and a new one will grow in its place. The worm is one of many
creatures that have some kind of memory for lost limbs, enabling them to
regenerate what was there before.
Now it seems that this memory can
be altered by meddling with the electrical
activity of the animals’ cells. Shifting the bioelectric
current at the site of the cut changes the type of appendage regenerated –
allowing a head to be regrown in place of a tail, for instance.
Michael
Levin at Tufts University in Medford, Massachusetts, and his
colleagues have shown that after changing the electrical current of the cells
once, the animals will continue to randomly regrow a head or a tail. The
findings suggest that an animal’s body plan is not just down to its genes and
environment – electricity plays a key role, too. “It’s pretty profound,” says
Levin.
His team has long been trying to
understand how electric currents in the body’s cells affect health and the
ability to regenerate damaged tissues – what Levin calls the “bioelectric
code”.
On the charge
Charged ions are constantly
moving in and out of cells, giving cells a natural electrical charge. The
patterns of electrical activity are thought to have an important role in
controlling how embryos develop limbs. Levin wants to find out whether they
might work in adult animals – and potentially humans – too.
Drugs, including commonly used
anaesthetics, can destabilise the electrical charge of cells. In a recent
experiment, Levin’s team took this approach to see if altering the electrical
charge in worms that had had their heads and their tails cut off might
encourage them to grow two heads or tails instead of one head and one tail.
The team found that about 70 per
cent of the worms regrew a second tail or head instead of the “correct” body
part. The rest appeared to be unaffected.
To probe further, Levin’s student
Fallon Durant re-cut the worms that had regenerated the normal body part without
giving them any other treatment. She saw the same trend – 70 per cent regrew
the wrong part, while 30 per cent looked the same as they had originally. The
team repeated the experiment, and saw the same outcome over and over again.
After destabilising a worm’s
electrical current once, it is as if each end of the worm makes its own
decision – with a preference for the wrong part – as to whether it
will develop a head or a tail whenever it is cut, says Levin. By altering the
bioelectric code, the animal’s body plan can be permanently rewritten, he says.