Schizophrenia study finds new biomarker, drug candidate to treat cognitive symptoms

• For Journalists
• News Releases
• Latest Releases
• News Release

Schizophrenia study finds new biomarker, drug candidate to treat cognitive symptoms

Large study was in human cerebral spinal fluid and mouse models

• Cognitive symptoms can result in patients relying on family for lifelong support or even suicide
• Current drugs treat hallucinations, delusions but not disorganized thinking, executive dysfunction
• Synthetic protein added to schizophrenia mouse models corrected overexcited brain circuits

CHICAGO --- Current schizophrenia medications treat symptoms such as hallucinations and delusions, but do little for cognitive symptoms like disorganized thinking or executive dysfunction. As a result, many patients are unable to work, rely on family for lifelong support, become homeless or, in some cases, experience suicidal thoughts and actions.

A new Northwestern University study in humans and mice has discovered a novel biomarker of schizophrenia that could also serve as a new drug candidate to treat the cognitive symptoms of the disorder. Schizophrenia affects .5% of the world's population, including about two million people in the U.S.

"A lot of people with schizophrenia cannot integrate well into society because of these cognitive deficits," said corresponding author Peter Penzes, professor of neuroscience, pharmacology and psychiatry and behavioral sciences at Northwestern University Feinberg School of Medicine. "Our discovery could solve these challenges by establishing the basis of a revolutionary and completely novel treatment strategy through a tandem biomarker-peptide therapeutic approach."

The study will be published March 19 in the journal Neuron.

Penzes also is the director of the Center for Autism and Neurodevelopment at Feinberg.

Adding synthetic protein corrects abnormal brain circuit activity

By examining the cerebral spinal fluid of more than 100 schizophrenia patients and healthy controls, the scientists identified a previously unknown, freely circulating form of a brain protein called Cacna2d1. In patients with schizophrenia, levels of this protein signal are reduced compared to controls, the study found, which results in overactive or overexcited brain circuits.

The team created a synthetic version of the protein (named SEAD1) and tested it in a mouse model of genetic schizophrenia. A single injection of SEAD1 into the animals' brains corrected both the abnormal brain circuit activity - and the behavioral problems linked to the disorder. Importantly, the treatment did not cause observable negative side effects, such as sedation or reduced movement, the study authors said.

"Our treatment reopens a crucial window to rewire connections in adult brains," said first author Marc Dos Santos, research assistant professor of neuroscience at Feinberg. "The lack of brain plasticity is believed to be a key factor in the development of symptoms in schizophrenia. Reforming synapses could also be beneficial for other mental disorders, such as depression."

Dos Santos said the team does not yet know how long the therapeutic effects last, but they plan to study this aspect in future experiments. The research team is now optimizing this protein for future clinical trials in patients with 16p11.2 duplication syndrome, which is associated with a tenfold risk of developing schizophrenia, Penzes said.

Why a biomarker for a psychiatric disorder is so important

While there are biomarkers to diagnose diseases - such as blood sugar for diabetes or cholesterol for heart disease - diagnosing psychiatric disorders is much more subjective, Penzes said.

Additionally, many potential drugs don't perform well in clinical trials or later fail because of the diversity of people's biology. By identifying a specific schizophrenia biomarker in this study, the scientists can now identify a subgroup of people who would most likely respond well to this SEAD1-based peptide drug.

The biomarker-therapeutic combination is revolutionary because it uses the biomarker to identify patients most likely to benefit from this treatment and uses the biomarker-related peptide drug to treat those same patients.

"The clinical trials would have much higher success rate, and the treatments would work much better because you would give the new drug to the exact people who actually could respond to that drug," Penzes said. "The next step for us would be to develop a blood biomarker to identify a subset of schizophrenia patients who can respond to this treatment, and then we can give them this peptide - almost like Ozempic for schizophrenia, an injection that you can give once a week."

The study is titled, "Soluble α2δ-1, altered in disease CSF, modulates network homeostasis and rescues deficits in a neuropsychiatric mouse model." Other Northwestern study authors include Marc P. Forrest, Ewa Bomba-Warczak, Soumil Dey, Euan Parnell, Jessica M. Christiansen, Seby L. Edassery, Blair L. Eckman, Catherine R. Lammert, M. Dolores Martin-de-Saavedra, Marco Martina and Jeffrey N. Savas.

Funding for the study was provided by National Institute of Neurological Disorders and Stroke (grant 5R01NS114977-04); the National Institute of Mental Health (grants 5R01MH097216-07, MH135860, MH-094268, MH-107730, MH-129480 and MH-136297), both of the National Institutes of Health; foundation grants from Stanley and RUSK/S-R; and Brain & Behavior Research Foundation (grant 32147).

• Video
• Images