Researchers pinpoint link between diabetes and nervous system autoimmunity

Researchers have extended their earlier discovery of an unsuspected link between Type 1 diabetes and nervous system autoimmunity, such as that found in multiple sclerosis. This research has identified new therapeutic targets for diabetes prevention, and a strategy for diagnostic tests for early detection of diabetes risk. The research is described in the February issue of the scientific journal Nature Medicine, available online on January 21, 2003. From the University of Toronto :Sick Kids researchers pinpoint link between diabetes and nervous system autoimmunity, resulting in new therapeutic and diagnostic targets

TORONTO – Researchers at The Hospital for Sick Children (HSC) and the University of Toronto (U of T) have extended their earlier discovery of an unsuspected link between Type 1 diabetes and nervous system autoimmunity, such as that found in multiple sclerosis (MS). This research has identified new therapeutic targets for diabetes prevention, and a strategy for diagnostic tests for early detection of diabetes risk. The research is described in the February issue of the scientific journal Nature Medicine, available online on January 21, 2003.

The research group of HSC’s Dr. Michael Dosch traced the link between Type 1 diabetes and nervous system autoimmunity to nervous tissue surrounding insulin-producing beta cells in the pancreas. They unexpectedly found that it is these nervous system structures that are first destroyed in the earliest stages of diabetes, with autoimmunity subsequently veering off to attack insulin-producing cells. Modification of the early nervous tissue attack prevented subsequent diabetes in the major animal model for the disease.

“This study maps the puzzling link between Type 1 diabetes and nervous system autoimmunity,” said Dr. Dosch, the study’s principal investigator, an HSC senior scientist and a professor of Paediatrics and Immunology at U of T. “In focusing previous research efforts strictly on insulin-producing beta cells, we may have missed the start of the diabetes process in its early, perhaps earliest, stages. The new data may shed a different light on the process, providing new targets for preventive treatments and new, early markers for the detection of disease risk, a prerequisite for intervention treatments.”

Dr. Dosch’s research group used a vaccine-type approach to alter autoimmunity against the pancreatic nervous system cells in mice, and they observed that subsequent diabetes development was reduced by a large margin. This implied a critical role of early neuronal autoimmunity in the process that eventually leads to beta cell destruction and then to diabetes.

The research team included co-lead authors Shawn Winer and Hubert Tsui, PhD students at U of T, Dr. Pamela Ohashi from the Ontario Cancer Institute, Dr. Pere Santamaria at the University of Calgary, and Dr. Dorothy Becker, University of Pittsburgh. The group also collaborated with SYNoX Pharma, a Toronto proteomics research and development company, to first identify and develop diagnostic tests. These are based on the SYNoX discovery that the early phase of autoimmune attack leaves traces (protein markers) that can be detected in blood. Work in Dr. Dosch’s lab, in collaborating labs in Europe and the US, and at SYNoX, is focused on refining the detection of these traces into lab tests that may possibly diagnose diabetes risk much earlier than is presently possible.

“SYNoX’s unique Proteomics Discovery PlatformTM helped in the discovery of a family of markers, unexpected in diabetes, that may lead to new therapeutics and diagnostics for Type 1 diabetes, a new target disease for SYNoX. Once proven in a larger clinical trial, the diagnostics, in a rapid and affordable doctor’s-office format, could be applied for mass screening of diabetes risk in every five to 10-year-old child,” said SYNoX Chairman and Chief Scientific Officer, Dr. George Jackowski.

“This research may also open a new door for understanding the persistent mystery in autoimmune diseases: why does the immune system attack its own tissue? It now seems possible that the nervous system and cells that separate nervous system from other tissue in the body may play an unsuspected, critical role in this process,” added Dr. Dosch.


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