When neurons are out of shape, antidepressants may not work
Altered neuron growth and gene expression may be related to why some depressed individuals do not respond to SSRIs
Credit: Salk Institute
LA JOLLA–(March 22, 2019) Selective serotonin reuptake inhibitors (SSRIs) are the most commonly prescribed medication for major depressive disorder (MDD), yet scientists still do not understand why the treatment does not work in nearly thirty percent of patients with MDD. Now, Salk Institute researchers have discovered differences in growth patterns of neurons of SSRI-resistant patients. The work, published in Molecular Psychiatry on March 22, 2019, has implications for depression as well as other psychiatric conditions such as bipolar disorder and schizophrenia that likely also involve abnormalities of the serotonin system in the brain.
“With each new study, we move closer to a fuller understanding of the complex neural circuitry underlying neuropsychiatric diseases, including major depression,” says Salk Professor Rusty Gage, the study’s senior author, president of the Institute, and the Vi and John Adler Chair for Research on Age-Related Neurodegenerative Disease. “This paper, along with another we recently published, not only provides insights into this common treatment, but also suggests that other drugs, such as serotonergic antagonists, could be additional options for some patients.”
The cause of depression is still unknown, but scientists believe the disease is partly linked to the serotonergic circuit in the brain. This is largely because SSRIs, which increase levels of the neurotransmitter serotonin at neuron connections, help alleviate the symptoms of many people diagnosed with depression. Yet, the mechanism of why some people respond to SSRIs, while others do not, remains a mystery. Unraveling the puzzle of SSRI resistance has been challenging because it requires studying the 300,000 neurons that use the neurotransmitter serotonin for communication within a brain of 100 billion total neurons. One way scientists have recently overcome this obstacle is to generate these serotonergic neurons in the lab.
The team’s previous paper in Molecular Psychiatry showed that SSRI non-responders had increased receptors for serotonin, which made the neurons hyperactive in response to serotonin. The current paper wanted to examine SSRI non-responders from a different angle.
“We wanted to know if serotonin biochemistry, gene expression and circuitry were altered in SSRI non-responders compared to responders using serotonergic neurons derived from MDD patients,” says Krishna Vadodaria, a Salk staff scientist and first author of the new paper. “Using neurons derived from actual MDD patients provides a novel representation of how SSRI responders compare to non-responders.”
From a large-scale clinical study of 800 MDD patients, the researchers selected the most extreme cases of SSRI response–patients who drastically improved when taking SSRIs, and patients who saw no effect. The team took skin samples from these patients and reprogrammed the cells into induced pluripotent stem cells (iPSCs) in order to create serotonergic neurons that they could study.
The scientists examined serotonin targets in patient serotonergic neurons, including the enzyme that makes serotonin, the protein that transports it, and the enzyme that breaks it down, but found no differences in biochemistry interactions between groups. Instead, the researchers observed a difference in how the neurons responded based on their shape.
Neurons from SSRI non-responders had longer neuron projections than responders. Gene analysis revealed that the SSRI non-responders also had low levels of key genes (protocadherins PCDHA6 and PCDHA8) involved in forming neuronal circuits. When these genes were made non-functional in serotonergic neurons (mimicking the low gene levels previously observed), the neurons developed the same unusually long projections in the SSRI non-responders. These abnormal features could lead to too much neuronal communication in some areas of the brain and not enough in other parts, altering communication within the serotonergic circuitry and explaining why SSRIs do not always work to treat MDD.
“These results contribute to a new way of examining, understanding, and addressing depression,” says Gage.
The next step is to examine the protocadherin genes to better understand the genetics of SSRI non-responders.
Other authors included: Apua Paquola, Kelly J. Heard, Callie Fredlender, Yalin Deng, James Elkins, Komal Dani, Amy T. Le, and Maria C. Marchetto of Salk; Yuan Ji of the University of Utah; and Michelle Skime, Timothy Nelson, Daniel Hall-Flavin and Richard Weinshilboum of the Mayo Clinic
This work was funded by the Robert and Mary Jane Engman Foundation, Lynn and Edward Streim, a Takeda-Sanford Consortium Innovation Alliance grant program (Takeda Pharmaceutical Company), the Swiss National Science Foundation (SNSF), the Minnesota Partnership Award for Biotechnology and Medical Genomics, the Mayo Clinic Center for Regenerative Medicine, the NIH-Mayo Clinic KL2 Mentored Career Development Award (NCAT UL1TR000135), the Gerstner Family Mayo Career Development Award in Individualized Medicine, and the National Institutes of Health (GM61388 PGRN and RO1 GM28157).
About the Salk Institute for Biological Studies:
Every cure has a starting point. The Salk Institute embodies Jonas Salk’s mission to dare to make dreams into reality. Its internationally renowned and award-winning scientists explore the very foundations of life, seeking new understandings in neuroscience, genetics, immunology, plant biology and more. The Institute is an independent nonprofit organization and architectural landmark: small by choice, intimate by nature and fearless in the face of any challenge. Be it cancer or Alzheimer’s, aging or diabetes, Salk is where cures begin. Learn more at: salk.edu.
Related Journal Article