A single genetic fault makes one hand mirror the other’s movements
Clench your left hand into a fist. What happened to your right hand when you did it?
If you’re like most people, the answer is nothing. But, surprisingly, not everyone can do this. Some people make “mirror movements”, where moving one side of the body, particularly the hands, causes the other to move unintentionally. Clench the left fist, and the right one closes too. Doing things like playing the piano or typing are very difficult. In 2002, a Chinese man with the disorder failed to get into the military because he couldn’t use the monkey bars.
Young children sometimes make mirror movements but they almost always grow out of it by the age of 10. The only exceptions tend to be people with rare genetic disorders of the nervous system, like Klippel-Feil and Kallmann syndromes. Now, Myriam Srour from the University of Montreal has found that a single faulty gene can cause the condition.
She studied a large French Canadian family with four generations of members who had been making mirror movements from birth. Not everyone was affected, and the pattern of the disorder strongly suggested that a single dominant genetic fault was responsible. Srour tracked it down by comparing the genomes of affected and normal family members, and her search led her to a short area on the 18th chromosome, which contained three genes.
One of these genes is called DCC and it turned out to be the true culprit behind the disorder. In the Canadia family, those who make mirror movements have a version of DCC with a single altered DNA ‘letter’. This tiny fault means that the protein encoded by DCC is manufactured with a missing chunk. That chunk happens to include many of the most important segments of the DCC protein, which, in its abridged form, is completely useless.
Srour found this mutation in every case of mirror movements, and never in 760 unrelated people whose left and right sides are typically independent. To confirm DCC’s role, she turned to an Iranian family, many of who also demonstrated the quirk from birth. She sequenced their DCC genes and again, she found that those who make mirror movements had broken copies. In this case, the mutation was different but the result was the same – a shortened and ineffectual protein.
It’s not just humans who are affected in this way. If mice have mutated and shortened copies of DCC, they too show mirror movements and they move with a distinctive hopping gait. These strains are affectionately known as Kanga mice. If they lack any copies of the gene entirely, their problems are more severe. The gap between the brain’s hemispheres doesn’t develop properly and the fibres that connect the two halves– the corpus callosum – are fewer in number and misrouted.
These mutant mice hint at DCC’s role. The DCC protein is a docking bay (a receptor) for another protein called netrin-1, whose role is to guide the neurons of the developing nervous system across the midline of the body. Its name even comes from the Sanskrit word “netr”, meaning “one who guides”. But this neural shepherd can’t stick to broken DCC proteins and without its good work, the neuronal connections between the body’s two halves don’t form properly.
Reference: Science http://dx.doi.org/10.1126/science.1186463
More on genetic disorders:
- Brain damage pops woman’s personal bubble
- How inbreeding killed off a line of kings
- Genome sequencing reverses a faulty diagnosis for a genetic disorder
- Pocket Science – geneticist hunts down the cause of his own genetic disorder
- Williams syndrome children show no racial stereotypes or social fear
tweetmeme_source = ‘DiscoverMag’;
tweetmeme_service = ‘bit.ly’;
Go Further
Animals
- Orangutan seen using plants to heal wound for first timeOrangutan seen using plants to heal wound for first time
- What La Palma's 'lava tubes' tell us about life on other planetsWhat La Palma's 'lava tubes' tell us about life on other planets
- This fungus turns cicadas into zombies who procreate—then dieThis fungus turns cicadas into zombies who procreate—then die
- How can we protect grizzlies from their biggest threat—trains?How can we protect grizzlies from their biggest threat—trains?
Environment
- What La Palma's 'lava tubes' tell us about life on other planetsWhat La Palma's 'lava tubes' tell us about life on other planets
- How fungi form ‘fairy rings’ and inspire superstitionsHow fungi form ‘fairy rings’ and inspire superstitions
- Your favorite foods may not taste the same in the future. Here's why.Your favorite foods may not taste the same in the future. Here's why.
- Are the Great Lakes the key to solving America’s emissions conundrum?Are the Great Lakes the key to solving America’s emissions conundrum?
- The world’s historic sites face climate change. Can Petra lead the way?The world’s historic sites face climate change. Can Petra lead the way?
History & Culture
- Meet the ruthless king who unified the Kingdom of Hawai'iMeet the ruthless king who unified the Kingdom of Hawai'i
- Hawaii's Lei Day is about so much more than flowersHawaii's Lei Day is about so much more than flowers
- When treasure hunters find artifacts, who gets to keep them?When treasure hunters find artifacts, who gets to keep them?
Science
- Why ovaries are so crucial to women’s health and longevityWhy ovaries are so crucial to women’s health and longevity
- Orangutan seen using plants to heal wound for first timeOrangutan seen using plants to heal wound for first time
Travel
- Is it possible to climb Mount Everest responsibly?Is it possible to climb Mount Everest responsibly?
- 5 of Uganda’s most magnificent national parks
- Paid Content
5 of Uganda’s most magnificent national parks - On this Croatian peninsula, traditions are securing locals' futuresOn this Croatian peninsula, traditions are securing locals' futures