A common amino acid, glycine, can deliver a “slow-down” signal to the brain, likely contributing to major depression, anxiety and other mood disorders in some people, scientists have found.
The discovery, outlined in the journal Science, improves understanding of the biological causes of major depression and could accelerate efforts to develop new, faster-acting medications for such hard-to-treat mood disorders, said the corresponding author of the study.
“Most medications for people with depression take weeks before they kick in, if they do at all. New and better options are really needed,” said the author.
The team spent many years working toward this discovery. They didn’t set out to find a cause, much less a possible treatment route for depression. Instead, they asked a basic question: How do sensors on brain cells receive and transmit signals into the cells? Therein lay the key to understanding vision, pain, memory, behavior and possibly much more, the author suspected.
“It’s amazing how basic science goes. Fifteen years ago we discovered a binding partner for proteins we were interested in, which led us to this new receptor,” the author said. “We’ve been unspooling this for all this time.”
In 2018 the the team found the new receptor was involved in stress-induced depression. If mice lacked the gene for the receptor, called GPR158, they proved surprisingly resilient to chronic stress.
That offered strong evidence that GPR158 could be therapeutic target, the author said. But what sent the signal?
A breakthrough came in 2021, when the team solved the structure of GPR158. What they saw surprised them. The GPR158 receptor looked like a microscopic clamp with a compartment — akin to something they had seen in bacteria, not human cells.
“We were barking up the completely wrong tree before we saw the structure,” the author said. “We said, ‘Wow, that’s an amino acid receptor. There are only 20, so we screened them right away and only one fit perfectly. That was it. It was glycine.”
That wasn’t the only odd thing. The signaling molecule was not an activator in the cells, but an inhibitor. The business end of GPR158 connected to a partnering molecule that hit the brakes rather than the accelerator when bound to glycine.
“Usually receptors like GPR158, known as G protein Coupled Receptors, bind G proteins. This receptor was binding an RGS protein, which is a protein that has the opposite effect of activation,” said the first author of the study.
Scientists have been cataloging the role of cell receptors and their signaling partners for decades. Those that still don’t have known signalers, such as GPR158, have been dubbed “orphan receptors.”
The finding means that GPR158 is no longer an orphan receptor, the author said. Instead, the team renamed it mGlyR, short for “metabotropic glycine receptor.”
“An orphan receptor is a challenge. You want to figure out how it works,” the author said. “What makes me really excited about this discovery is that it may be important for people’s lives. That’s what gets me up in the morning.”
Glycine itself is sold as a nutritional supplement billed as improving mood. It is a basic building block of proteins and affects many different cell types, sometimes in complex ways. In some cells, it sends slow-down signals, while in other cell types, it sends excitatory signals. Some studies have linked glycine to the growth of invasive prostate cancer.
More research is needed to understand how the body maintains the right balance of mGlyR receptors and how brain cell activity is affected, the author said.
“We are in desperate need of new depression treatments,” the senior author said. “If we can target this with something specific, it makes sense that it could help. We are working on it now.
https://www.science.org/doi/10.1126/science.add7150
Orphan receptor GPR158 serves as a metabotropic glycine receptor, mGlyR
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