Fruit fly brain with neurons targeted using SpaRCLIn marked in green. Image credit: Haojiang Luan (CC BY 4.0)
In humans – as well as flies and most other animals – the brain controls how we move and behave, and regulates heartbeat, breathing and other core processes. To perform these different roles, cells known as neurons form large networks that quickly carry messages around the brain and to other parts of the body. In order to fully understand how the brain works, it is important to first understand how individual neurons connect to each other and operate within these networks.
Fruit flies and other animals with small brains are often used as models to study how the brain works. There are several methods currently available that allow researchers to manipulate small groups of fruit fly neurons for study, and in some cases it is even possible to target individual neurons. However, it remains an aspirational goal to be able to target every neuron in the fly brain individually.
The Gal4-UAS system is a way of manipulating gene activity widely used to study neurons in fruit flies. The system consists of two parts: a protein that can bind DNA and control the activity of genes (Gal4); and a genetic sequence (the UAS) that tells Gal4 where to bind and therefore which genes to activate. Fruit flies can be genetically engineered so that only specific cells make Gal4. This makes it possible, for example, to limit the activity of a gene under the control of the UAS to a specific set of neurons and therefore to identify or target these neurons. Luan et al. developed a new technique named SpaRCLIn that allows the targeting of a subset of neurons within a group already identified with the Gal4-UAS system.
During embryonic development, all neurons originate from a small pool of cells called neuroblasts, and it is possible to target the descendants of particular neuroblasts. SpaRCLIn exploits this strategy to limit the activity of Gal4 to smaller and smaller numbers of neuroblast descendants. In this way, Luan et al. found that SpaRCLIn was routinely capable of limiting patterns of Gal4 activity to one, or a few, neurons at a time. Further experiments used SpaRCLIn to identify two pairs of neurons that trigger a well-known feeding behavior in fruit flies. Luan et al. also developed a SpaRCLIn toolkit that will form the basis of a community resource other researchers can use to study neurons in fruit flies. These findings could also benefit researchers developing similar tools in mice and other animals.
