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Researchers identify protein that drives progression of MS

Posted: 29 October 2015 | Victoria White

If scientists can find an antagonist to block the CCR2 receptor, they may be able to control the progression of MS…

Researchers from the University of Adelaide have made another important step in the progress towards being able to block the development of multiple sclerosis (MS) and other autoimmune diseases.

The researchers have identified a key protein involved in a ‘super-inflammatory’ immune response that drives the progression of MS and other autoimmune diseases.

The protein is a specific ‘chemokine receptor’ involved in moving T-cells around the body when they are in the super-inflammatory mode needed to fight persistent infections or conversely, as in the case of autoimmune diseases like MS, attacking the body’s own tissues. This chemokine receptor, called CCR2, is a different receptor than was widely assumed to be involved.

“Everybody has been focussing on the CCR6 receptor as the one to target to control this inflammatory response,” says project leader Professor Shaun McColl, Director of the Centre for Molecular Pathology at the University of Adelaide.

Blocking CCR2 could lead to control of MS progression

“We’ve now shown that the receptor to target is actually CCR2. Blocking CCR6 makes the disease worse. If we can find an antagonist to block the CCR2 receptor specifically on these T-cells, we should be able to control the progression of MS.”

The University of Adelaide research was conducted by PhD student Ervin Kara under the supervision of Professor McColl and research fellow Dr Iain Comerford, also in the University’s School of Biological Sciences.

Another potential benefit of the research is in making improved vaccines to fight infection.

“Unlike in autoimmune diseases, where the body’s immune response is destroying its own cells and the aim is to block T-cell migration, with persistent infection we want to turn on the super-inflammatory response and enhance the migration of the immune cells to sites where they are needed,” says Professor McColl. “This research may help guide development of vaccines that can better force that immune response.”

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