Zapping Worm Brains With Lasers Reveals the Duty of Each Neuron
Taking advantage of the emerging technique of optogenetics, Harvard researchers report in the journal Nature Methods that they can target any individual neuron of the tiny transparent worm C. elegans, whether the creature is moving or at rest, and zap it with a laser to see what the particular cell doesâ€”move the worm to the left or right, or even cause it to lay eggs.
The whole process, from finding the cell to light hitting its target, takes about 20 milliseconds. As the wormâ€™s position changes, that information is fed back into the computer program, and the laser is adjusted. If the worm crawls too far, a motorized microscope stage brings the animal back. One of the biggest benefits of the new method, [biologist William] Ryu says, is that it works in a roving animal. â€œThe worms are not held down in any way â€” theyâ€™re freely moving. There arenâ€™t many systems where you can look at such truly free organisms.â€ [Science News]
The transparent outer layer of C. elegans makes it one of the most popular test subjects in biology, as does its simple structure: the millimeter-long worm boasts just 302 neurons, with about 5,000 connections between them.
But science still does not know exactly “how neurons work together in a network,” says Andrew Leifer, a graduate student in biophysics at Harvard, For example, how does the worm coordinate its 100 or so muscles to relax and contract in a wave pattern as the worm swims? [Scientific American]
Other optogenetic studies have fired lasers into the brain of C. elegans, but couldn’t answer Leifer’s question because they required restraining the worms in some way to hit the correct spot in the brain. Leifer’s system allowed him to hit a moving target, and thus allowed his study to become the first to zap the neurons of free-moving worms.
He and his collaborators were able to show, for example, that during swimming, motor signals move down the body through muscle cells themselves as well as through nerve connections, by selectively blocking sections of its musculature and nervous system. [Scientific American]
Examining the worms this way could let Leifer build an entire behavioral map of their brain cells and connections. And hopefully someday the technique will move to more complex creatures, too.
Image: Leifer et. al. / Nature Methods (The targeting system, and the worm)