Discovery Points to Ketamine’s Long-Term Antidepressant Effects

Summary: The MeCP2 gene influences ketamine’s behavioral effect and strengthens synapses, leading to an improvement in the drug’s antidepressant effect over time.

Source: Vanderbilt University

Building on recent research confirming how ketamine induces rapid antidepressant action, Professor of Pharmacology Lisa Monteggia and her collaborators show how the molecular mechanism of the gene MeCP2 and associated synaptic adaptability are critical to the long-term antidepressant effects of ketamine.

While MeCP2 has been shown to be important for typical antidepressants, this research indicates that, in cooperation with ketamine’s initial target, the gene is important for long-term antidepressant action, Monteggia said.

The researchers discovered that MeCP2 influences ketamine’s behavioral effect as well as potentiation—the strengthening of synapses—improving its antidepressant effects over time. This work also shows that the long-term effects of ketamine involve synaptic adaptability, or plasticity—not simply structural changes.

Monteggia and her team went on to show that repeated exposure to ketamine further strengthened synaptic plasticity—eliciting more plasticity of plasticity—which the team termed “metaplasticity.” This may explain why repeated doses of ketamine produce a cumulative and prolonged effect.

WHY IT MATTERS

“We think we have the pathway in the brain to engage these long-term effects,” said Monteggia, also director of the Vanderbilt Brain Institute. “To have an impact on treatment or clinical drug development, you must know the processes in the brain that are involved. This is the first research that gives us an explanation for how ketamine produces long-term effects involving synaptic plasticity in the brain and why ketamine has cumulative antidepressant effects—a huge step forward.”

This shows a depressed looking man
The researchers discovered that MeCP2 influences ketamine’s behavioral effect as well as potentiation—the strengthening of synapses—improving its antidepressant effects over time. Image is in the public domain

This discovery will allow researchers to target the neural pathway that prolongs ketamine’s antidepressant effects without the drug itself. While ketamine has significant promise, it also carries abuse liabilities, as the drug can trigger psychomedical effects. At low doses the drug is not harmful, but no one knows the outcome of sustained use of ketamine to date. This discovery may be a way to circumvent the unintended and still unknown negative effects of ketamine exposure.

WHAT’S NEXT

With the knowledge that MeCP2 can regulate gene expression, researchers are now looking to understand the neural pathway of the gene more fully, and to find commonalities with common antidepressants to extend their effects.

FUNDING

This work was supported by National Institutes of Health grants MH070727, MH081060 and MH066198, the Basic Science Research Program through the National Research Foundation of Korea funded by the Ministry of Education grant 2016R1A6A3A03008533, and the Swedish Pharmaceutical Society and the Swedish Society for Medical Research.

About this ketamine and depression research news

Source: Vanderbilt University
Contact: Marissa Shapiro – Vanderbilt University
Image: The image is in the public domain

Original Research: Closed access.
Sustained effects of rapidly acting antidepressants require BDNF-dependent MeCP2 phosphorylation” by Ji-Woon Kim, Anita E. Autry, Elisa S. Na, Megumi Adachi, Carl Björkholm, Ege T. Kavalali & Lisa M. Monteggia. Nature Neuroscience


Abstract

Sustained effects of rapidly acting antidepressants require BDNF-dependent MeCP2 phosphorylation

The rapidly acting antidepressants ketamine and scopolamine exert behavioral effects that can last from several days to more than a week in some patients.

The molecular mechanisms underlying the maintenance of these antidepressant effects are unknown. Here we show that methyl-CpG-binding protein 2 (MeCP2) phosphorylation at Ser421 (pMeCP2) is essential for the sustained, but not the rapid, antidepressant effects of ketamine and scopolamine in mice.

Our results reveal that pMeCP2 is downstream of BDNF, a critical factor in ketamine and scopolamine antidepressant action. In addition, we show that pMeCP2 is required for the long-term regulation of synaptic strength after ketamine or scopolamine administration.

These results demonstrate that pMeCP2 and associated synaptic plasticity are essential determinants of sustained antidepressant effects.

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