In Adam Cohen's lab, neurons to light up as they fire

Harvard researchers create neurons that light up when they fire.

Genetic alterations allow researchers to observe the electrical firing of a neuron (pink) as a flash of light, detectable by specially modified optical microscopes.

Genetic alterations allow researchers to observe the electrical firing of a neuron (pink) as a flash of light, detectable by specially modified optical microscopes. | Image by Daniel Hochbaum and Adam Cohen

A new tool developed in the lab of Adam Cohen, Loeb associate professor of the natural sciences, may illuminate neuroscience research: it allows neurons to light up as they fire. “For decades, people have wanted a way to look at a neuron and tell what it’s doing,” Cohen says. But just as we can’t see electricity coursing through a telephone wire, there’s been no good way to watch electrical signals move across neurons.

Until now. Cohen’s team used a protein from a Dead Sea microorganism that normally absorbs sunlight and converts it into electricity. “A few years ago, I wondered if it was possible to run [similar proteins] in reverse,” he says, “so instead of taking in light and generating electricity, we could use it to sense electrical energy in a cell and convert that into a detectable optical signal.” MIT researcher Ed Boyden recently conducted research that involved placing the gene that expresses this protein in an animal neuron, and he shared the gene with Cohen.

Cohen’s team genetically modified a virus to carry the gene, and then used the virus to infect rat neurons. Once inside a neuron, the gene prompts production of these proteins, which settle in the cell membrane. There they act like microscopic voltmeters, monitoring voltage changes. When a neuron is at rest, the inside of the cell is electrically negative compared to the outside, keeping the protein “dark.” But when a neuron fires, it causes a brief voltage spike that reverses the charge, prompting the protein to light up.

Although Cohen has already shared them with more than 60 labs, these voltage-indicator proteins aren’t ready for wide use yet, he says. The flashes are infrared and invisible to the naked eye, so Cohen’s team has had to develop specialized optical equipment to see them, and it will take other labs some time to set up similar equipment. “The neuroscientist’s dream,” he explains, “is to look into a brain and see all the neurons firing,” which would allow researchers to watch how signals spread, and even to see whether the speed at which they move is modulated by learning. “But we need to make our indicator brighter for that to work.”

Cohen believes the proteins have a range of additional applications as well. They could help test new drugs, for example: his team has added the voltage indicators to cardiac cells, which would allow them to study the effect of new medications on signaling in the heart. The fact that scientists would see the results through a microscope, he says, could dramatically increase the speed of drug testing.

Adam Cohen e-mail address:

cohen@chemistry.harvard.edu

 

Adam Cohen website:

www2.lsdiv.harvard.edu/labs/cohen

Read more articles by Erin O’Donnell
Related topics

You might also like

The Harvard Kennedy School professor has led inquiries into the polarizing conflicts in the Middle East.

A colleague remembers the late Harvard professor and child psychiatrist, who died this month.

The retired government professor has been a rare conservative voice on campus for decades.

Most popular

The Supreme Court Affirmative Action Rulings: An Analysis

The underlying arguments project clashing worldviews of race and appropriate remedies.

An animal’s journey from grief to love shows how much humans need each other, too.

One of Harvard’s Oldest Structures Is Hiding Behind a Beer Garden

A crumbling wall in Harvard Square holds centuries of the city’s story, if you know how to read it.

Explore More From Current Issue

Katie O’Dair in academic regalia holds a ceremonial staff outdoors at a graduation ceremony.

How Katie O’Dair makes kings, comedians, and parents feel welcome on campus.

A blue refrigerator covered with animal pictures, notes, and drawings, surrounded by greenery.

An animal’s journey from grief to love shows how much humans need each other, too.

Label showing the anatomy of a worker bee, featuring a detailed illustration.

Science and art capture the microscopic natural world.