Past studies have indicated that rather than being a single disease, schizophrenia is a collection of different disorders. Now, a new study by researchers at Washington University in St. Louis, MO, claims the condition consists of eight distinct genetic disorders, all of which present their own specific symptoms.
The research team, including senior investigator Dr. C. Robert Cloninger, the Wallace Renard Professor of Psychiatry and Genetics at Washington University, says their findings may pave the way for better diagnosis and treatment strategies for schizophrenia.
Schizophrenia is a mental disorder characterized by hallucinations, delusions, abnormal thoughts, cognitive problems and agitated body movements.
People with a family history of schizophrenia are at much higher risk of developing the condition. Approximately 1% of the general population in the US have schizophrenia, but it occurs in around 10% of individuals who have a first-degree relative with the disorder.
Researchers have worked long and hard to identify specific genes associated with schizophrenia. Earlier this year, Medical News Today reported on a study led by researchers from the Cardiff University School of Medicine in the UK, in which they identified 83 new genes linked to schizophrenia.
But Dr. Cloninger says that rather than trying to pinpoint specific genes to schizophrenia development, he and his colleagues wanted to look at how individual genes work together.
“Genes don’t operate by themselves,” he says. “They function in concert much like an orchestra, and to understand how they’re working, you have to know not just who the members of the orchestra are but how they interact.”
Analyzing genetic variations and identifying clusters
For their study, results of which are published in The American Journal of Psychiatry, the team analyzed the genomes of 4,200 people with schizophrenia and 3,800 people without the disorder.
By comparing the SNPs of schizophrenic individuals with those of healthy controls, the team was able to identify the genetic variations linked to schizophrenia. Individuals with schizophrenia were divided into groups based on the type and severity of their symptoms. The team looked at how the genetic variations interacted with each other to produce specific symptoms of the disorder.
Dr. Cloninger and colleagues say they identified specific gene clusters associated with eight different types of schizophrenia, all of which present recognizable symptoms. For example, the team discovered a gene cluster that posed a 95% risk of schizophrenia, which they specifically linked to hallucinations or delusions.
The researchers also analyzed two other databases of individuals with schizophrenia and were able to replicate their findings.
“What we’ve done here, after a decade of frustration in the field of psychiatric genetics, is identify the way genes interact with each other, how the ‘orchestra’ is either harmonious and leads to health, or disorganized in ways that lead to distinct classes of schizophrenia,” says Dr. Cloninger.
Genes ‘work in concert’ to disrupt brain structure and function, causing schizophrenia
The team explains that individual genes linked to schizophrenia only have weak and inconsistent associations with the disorder. But when these genes interact and work as clusters, they pose a 70-100% risk of developing schizophrenia, meaning those with such clusters are unlikely to avoid the disorder.
Commenting on their findings, co-investigator Dr. Dragan Svrakic, a professor of psychiatry at the university, says:
“In the past, scientists had been looking for associations between individual genes and schizophrenia. When one study would identify an association, no one else could replicate it. What was missing was the idea that these genes don’t act independently. They work in concert to disrupt the brain’s structure and function, and that results in the illness.”
The researchers believe their findings could lead to better diagnosis and treatments for people with schizophrenia. By identifying genetic variations in people with schizophrenia and linking them to specific symptoms, they say it may be possible to target treatments to specific pathways that contribute to the disorder.
The team says the approach used in this study may also improve understanding of how genes collaborate to cause other common disorders.
“People have been looking at genes to get a better handle on heart disease, hypertension and diabetes, and it’s been a real disappointment,” says Dr. Cloninger. “Most of the variability in the severity of disease has not been explained, but we were able to find that different sets of genetic variations were leading to distinct clinical syndromes. So I think this really could change the way people approach understanding the causes of complex diseases.”
Autor: Honor Whiteman
Comments are closed.