Scientists use light to map neurons' effects on one another
All-optical technique determines when neurons inhibit or excite one another
"This approach gives us a powerful new tool for analyzing small neural circuits, and directly measuring how neurons talk to each other," says Sharad Ramanathan, an assistant professor of molecular and cellular biology and of applied physics at Harvard. "While we've only mapped out the interplay of four neurons, it's the first time scientists have determined the ability of multiple neurons in a circuit to excite or inhibit their neighbors."
Zengcai Guo and Ramanathan combined genetically encoded calcium sensors and light-activated ion channels with optics. The scientists used a mirror array to excite individual neurons - each just two to three millionths of a meter wide - while simultaneously measuring calcium activity in multiple other neurons. This calcium activity serves to indicate whether these other neurons were activated or inhibited by the neuron that was primed with a burst of light.
"Using this technique, for the first time, we could excite both a sensory neuron and an interneuron and monitor how activity propagates," says Guo, a research assistant in Harvard's Center for Systems Biology, Department of Molecular Biology, and School of Engineering and Applied Sciences. "We expect that our technique can eventually be used more broadly to measure how activity propagates through neural circuits."
Manipulating neurons with light, Guo and Ramanathan were able to evoke an avoidance response - causing the worm to back away from light - that is normally prompted only when the organism is touched.
With a compact nervous system consisting of only 302 neurons linked by some 7,000 synapses, the nematode C. elegans is an ideal system for studying the interplay between neural circuits and behavior. While the physical connectivity of the neurons in this nematode is well known, scientists know very little about which of these connections are excitatory and which are inhibitory.
Because of the small sizes of the neurons and a tough cuticle surrounding the worm, electrophysiological recordings can be made from only one neuron at a time, precluding the possibility of any circuit-level analysis of neural activity. By establishing this first fully genetically encoded light-based electrophysiology, the authors have developed a way to overcome this limitation.
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