A genetically encoded fluorescent sensor to detect hallucinogenic compounds could aid in discovering new treatments for mental illness, neuroscience research, and detecting drugs.
Details of the sensor, called psychLight, appear in the journal Cell.
Compounds related to psychedelic drugs such as LSD and dimethyltryptamine (DMT) show great promise for treating disorders such as depression, post-traumatic stress disorder, and substance use disorder. These drugs are called psychoplastogens because of their ability to rapidly alter brain connections. But drugs that can cause hallucinations require very careful use and monitoring of patients.
Currently, the most effective way to test an experimental drug to see if it causes hallucinations is the “head twitch” assay in rodents. “Scientific studies on psychedelic drugs have been conducted since the 1940s but we still don’t have an effective cellular assay for them,” says coauthor David Olson, assistant professor in the chemistry department at the University of California, Davis.
The lab of Lin Tian, associate professor at the UC Davis School of Medicine, develops fluorescent indicators for neural chemicals in the brain such as serotonin and dopamine. These neuromodulators allow the brain to react quickly to changing conditions, Tian says. Like neuromodulators, both psychedelic drugs and those used to treat mental illness can have profound impacts on brain function.
The psychLight biosensor is based on the serotonin 2A receptor (HT2AR). Within the brain, serotonin released from neurons and picked up by serotonin receptors on other neurons acts to regulate mood. Both psychedelic drugs and drugs used to treat psychiatric disorders act through the serotonin 2A receptor.
Jason (Chunyang) Dong, a graduate student in Tian’s lab in the department of biochemistry and molecular biology, worked with graduate students Calvin Ly and Lee Dunlap in Olson’s lab to engineer a modified version of the HT2A receptor with a fluorescent component. When psychLight binds to serotonin or a hallucinogenic ligand it changes its conformation, causing the fluorescence to increase. Non-hallucinogenic ligands can also bind to psychLight, lead to a different fluorescence profile.
Researchers can use psychLight to see how naturally occurring neuromodulators like serotonin, or hallucinogenic drugs, act on different parts of the brain. They could also use it to screen candidate drugs for those which activate the HT2A receptor and could cause hallucinations. When psychLight is expressed in cells and those cell cultures are exposed to a hallucinogenic drug, they light up.
The sensor can help look for pharmaceutical potential without the side effect of hallucinations, Tian says.
The researchers set up a high-throughput system to use cells expressing psychLight to screen compounds for hallucinogenic activity and for binding of the HT2A receptor. Using this, they showed that a previously untested compound, AAZ-A-154, activates the receptor but is not hallucinogenic. Subsequent tests in animal models confirmed that AAZ-A-154 shows promise as an antidepressant.
Seven Biosciences, a company that Tian and former graduate student Grace Mizuno founded, is working with UC Davis InnovationAccess to license the psychLight technology and develop it for commercial use. Delix Therapeutics, which Olson founded, is developing AAZ-A-154 and hopes to apply the psychLight assay to search for new pharmaceutical drugs.
Additional authors of the paper are from UC Davis, the University of Colorado, and Duke University. The National Institutes of Health, a Hellman Fellowship, and the UC Davis STAIR grant program supported the work.
Source: UC Davis
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