Psychedelics may treat depression by invading brain cells March 6, 2023 - Live Science
A study suggests that psychedelics can access receptors inside cells that standard antidepressants usually can't affect.
Psychedelic drugs have shown promise as therapies for hard-to-treat depression. Now, scientists have a potential explanation for why: The drugs may be able to slip through the outer membranes of brain cells and essentially flip switches inside the cells that other depression treatments can't.
The findings of the new study, published Feb. 16 in the journal Science (opens in new tab), may help explain why, in some cases, psychedelics, in conjunction with talk therapy, work better and faster for patients than traditional antidepressants, The Scientist reported.
Psychedelics include LSD; N,N-Dimethyltryptamine (DMT), found in the psychoactive drink ayahuasca; and psilocybin, the active compound in magic mushrooms. All of these substances are known to plug into a structure called the serotonin 2A receptor, which binds the chemical messenger serotonin. These receptors appear in high concentrations within the brain's wrinkled surface, the cerebral cortex, and they can be found both on the outer surface of brain cells and inside the cells.
Specifically, in cells of the cerebral cortex, the receptors can be found on the cells' surface and clustered around the so-called Golgi body inside the cell, which is responsible for packaging and shipping proteins, the researchers reported.
Prior research suggests that psychedelics' beneficial effects may stem from their ability to activate serotonin 2A receptors, which, in turn, encourages brain cells to forge new connections with each other. But given that serotonin can also activate these receptors, there was a question as to why psychedelics seem to work differently to traditional antidepressants, senior author David Olson, director of the Institute for Psychedelics and Neurotherapeutics at the University of California, Davis, told The Scientist.
(Antidepressants — including selective serotonin reuptake inhibitors, or SSRIs — typically work by boosting the amount of serotonin in the spaces between brain cells.)
Through various experiments in lab dishes and rodents, Olson's team found that although serotonin binds easily to the receptors on the outsides of brain cells, it can't easily pass through the cells' fatty outer membranes to reach the additional receptors within. Similar to how water and oil don't mix, serotonin can't easily pass through cell membranes because their chemical structures don't jibe.
However, the team found that several psychedelic drugs can slip right through these membranes; that's because they're far less polar than serotonin, meaning they're "greasier" and don't have a positive end and a negative end. Once inside a brain cell, the psychedelics plug into the internal serotonin 2A receptors that serotonin can't reach.
In their experiments, the team found that by tweaking serotonin to make it less polar, they could boost the molecules' ability to build new connections between neurons. This likely happened because the chemical passed through the cells' membranes and activated their internal serotonin receptors, the team hypothesized.
They also showed the opposite effect. When the researchers tweaked DMT and psilocin (which the body produces when it breaks down psilocybin) to make them more polar, they found that these modified drugs were less able to cross the membranes of rat neurons and thus couldn't boost their connectivity.
The team also genetically modified mice so that serotonin could pass into their neurons more easily, and found that the chemical boosted brain connectivity as a psychedelic would, according to The Scientist.
The study cannot completely rule out that serotonin might be able to cross cell membranes, to some degree, The Scientist reported. But the research does hint that psychedelics might treat depression, in part, by triggering effects in the brain that standard antidepressants typically cannot.
The study also raises questions as to why brain cells contain so many receptors that serotonin can't get to — it could be that a different chemical can access the receptors and activate them, or perhaps the receptors only accumulate in the cell temporarily as they're waiting to get shipped to the cell surface, Olson suggested.
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Very cool article which explains a lot.
I just had a crazy idea: so psychedelics are binding to receptors inside brain cells that normal serotonin can't reach right? I've always wondered about why lysergamides have effects other than just psychedelic effects, what I think of as "lysergamide effects," and for a long time I've wondered if maybe it's possible to separate the two. Well, the lysergamides bind to dopamine. What if they're doing the same thing that psychedelics are doing to serotonin, only to dopamine? Passing right through the cell membrane to bind to internal dopamine receptors?
Anyway, that's pure speculation, but this is really huge. If true, this could alter the course of drug development forever, opening up an entire genre of mind altering drugs that have never existed before. Soon, new drugs will be developed that specifically target these internal receptors, and likely that are selective for these internal receptors. This is like the discovery of receptors themselves all over again, it potentially doubles (or more!) the number of things that drugs can target in the brain.
Very cool, very exciting, crazy news. But it does make me wonder what the lysergamides are doing... Maybe it really would be possible to make a pure lysergamide that isn't a psychedelic.
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