New dopamine sensors could help unlock the mysteries of brain chemistry

Researchers develop a wider spectrum for dLight1 sensor, allowing multiplex imaging of neurotransmitters

(SACRAMENTO)

In 2018, Lin Tian and her team at UC Davis Health developed dLight1, a single fluorescent protein-based biosensor. This family of highly specific sensors detects dopamine, a hormone released by neurons to send signals to other nerve cells. When combined with advanced microscopy, dLight1 provides high resolution, real-time imaging of the spatial and temporal release of dopamine in live animals.

RdLight1 sensors detecting dopamine in neurons
RdLight1 sensors detecting dopamine in neurons

Recently, Tian and her team succeeded in expanding the color spectrum of the dLight1 sensor. In an article published Sept. 7 in Nature Methods, they introduced two new spectral variants of dLight1: the yellow YdLight1 and the red RdLight1.

“The new sensors will help researchers to detect and monitor different information processing activities in the brain,” said Lin Tian, associate professor of biochemistry and molecular medicine and the lead author on the study. “With the different colors, we will be able to see multiple neurochemical release and neural activities at the same time.”

The RdLight1 permits the simultaneous assessment of dopamine, pre- or post-synaptic neuronal activity and the glutamate release in specific types of cells and neuronal projections in animals. Its increased light penetration and imaging depth provide enhanced dopamine signal quality. This allows researchers to optically dissect dopamine’s release and model its effects on neural circuits

As a neurotransmitter, dopamine plays an important role in movement, attention, learning and the brain's pleasure and reward system.

“These exciting new tools opened a new door to developing color-shifted neurochemical indicators. Together with other tools, they have great potential to unlock the mysteries of brain chemistry in health and disease,” Tian said. “The knowledge we gain from these sensors will facilitate the development of safer next-generation therapies to neuropsychiatric disorders such as depression, anxiety, schizophrenia and addiction.”

Collaborations bring discoveries

Tian Laboratory team applied and received the MAP Program Collaboration Seed Grant. This grant, sponsored by the UC Davis Memory and Plasticity Program, supported their cross-disciplinary research with the Wiltgen Lab at UC Davis.

The team was also awarded BRAIN Initiative grants from the National Institutes of Health to fund their collaboration with Von Zastrow Lab and Berke Lab at the University of California, San Francisco. These collaborations resulted in the successful development and testing of the new spectrum of dLight1 sensors.

The coauthors on this study at University of California, Davis are Tommaso Patriarchi, Junqing Sun, Ruqiang Liang, Chunyang Dong, Kyle Pugher, Grace Or Mizuno, Carolyn M. Davis and Brian Wiltgen, and at the University of California, San Francisco are Ali Mohebi, Aaron Marley Mark von Zastrow and Joshua D. Berke.

This work was supported by National Institutes of Health grant (DP2MH107056); BRAIN Initiative awards (U01NS090604, U01NS013522, U01NS103571, U01NS094375); Rita Allen Young Investigator Award and R01DA045783; Olga Mayenfisch Foundation; and Novartis Foundation for medical-biological Research.

Article: Patriarchi et al. An expanded palette of dopamine sensors for multiplex imaging in vivo, Nature Methods. https://doi.org/10.1038/s41592-020-0936-3