This colorful web is the most complete look yet at a fruit fly’s brain cells

This colorful web is the most complete look yet at a fruit fly’s brain cells

If the secret to getting the perfect photo is taking a lot of shots, then one lucky fruit fly is the subject of a masterpiece.

Using high-speed electron microscopy, scientists took 21 million nanoscale-resolution images of the brain of Drosophila melanogaster to capture every one of the 100,000 nerve cells that it contains. It’s the first time the entire fruit fly brain has been imaged in this much detail, researchers report online July 19 in Cell.

Experimental neurobiologists can now use the rich dataset as a roadmap to figure out which neurons talk to each other in the fly’s brain, says study coauthor Davi Bock, a neurobiologist at Howard Hughes Medical Institute’s Janelia Research Campus in Ashburn, Va.

Learning to fly

A high-resolution look at the fruit fly brain allows scientists to trace the paths of individual nerve cells. One new find: The discovery of a new type of neuron (orange) that talks to other neurons called Kenyon cells (teal), which live in a part of the fly brain associated with learning and memory.

The rainbow image shown here captures the progress on that mapping so far. Despite the complex tangle of neural connections pictured, the mapping is far from complete, Bock says. Neurons with cell bodies close to each other are colored the same hue, to demonstrate how neurons born in the same place in the poppy seed–sized brain tend to send their spidery tendrils out in the same direction, too.

The dataset is already enabling new discoveries about the fruit fly brain. For instance, Bock and colleagues are interested in the neurons that help flies make memories. He and his team traced neurons that send messages to and from a structure in the fly’s brain called the mushroom body, which is involved in learning and memory. In the process, the researchers discovered a new type of neuron that talks to cells in the mushroom body. The brain has two such neurons, one on each side, Bock says. Each has a broad crown of dendrites that receive signals from neurons in many different places in the brain. Because of their far-reaching influence, the cells might be involved in integrating different kinds of sensory information, he suggests.