New compound halts progression of multiple sclerosis
3 May 2011
A new class of highly selective compounds that effectively
suppresses the severity of multiple sclerosis in animal models has been
developed by the Scripps Research Institute in Florida.
The new compound could provide new and potentially more effective
therapeutic approaches to multiple sclerosis and other autoimmune
diseases that affect patients worldwide. The study appeared
Nature online [1].
Current treatments for autoimmunity suppress the patient’s entire
immune system, leaving patients vulnerable to a range of adverse
side effects. Because the new compound, known as SR1001, only blocks
the actions of a specific cell type playing a significant role in
autoimmunity, it appears to avoid many of the widespread side
effects of current therapies.
“This is a novel drug that works effectively in animal models with
few side effects,” said Tom Burris, PhD, a professor in the
Department of Molecular Therapeutics at Scripps Florida who led the
study, which was a multidisciplinary collaboration with scientists
including Patrick Griffin, William Roush, and Ted Kamenecka of
Scripps Research, and Paul Drew of the University of Arkansas for
Medical Sciences.
“We have been involved in several discussions with both
pharmaceutical and biotechnology firms who are very interested in
developing it further,” he continued
A lengthy process of drug development and review is required to
ensure a new drug’s safety and efficacy before it can be brought to
market.
“This impressive multidisciplinary team has used a combined
structural and functional approach to describe a class of molecules
that could lead to new medicines for treating autoimmune diseases,”
said Charles Edmonds, Ph.D. who oversees structural biology grants
at the National Institutes of Health. “Breakthroughs such as this
highlight the value of scientists with diverse expertise joining
forces to solve important biological problems that have the
potential to benefit human health.”
Targeting specific receptors
For several years, Burris and his colleagues have been investigating
small-molecule compounds that affect particular disease-related
receptors (structures that bind other molecules, triggering some
effect on the cell). In particular, the scientists have been
interested in a pair of “orphan nuclear receptors” (receptors with
no known natural binding partner) called RORα and RORγ involved in
both autoimmune and metabolic diseases.
These particular receptors play a critical role in the
development of TH17 cells, a form of T helper cells that make up
part of the immune system. A relatively new discovery, TH17 cells
have been implicated in the pathology of numerous autoimmune
diseases, including multiple sclerosis, rheumatoid arthritis,
inflammatory bowel disease, and lupus. TH17 cells produce
Interleukin-17, a natural molecule that can induce inflammation, a
characteristic of autoimmunity.
“If you eliminate TH17 cell signals, you basically eliminate the
disease in animal models,” Burris said. “Our compound is the first
small-molecule orally active drug that targets this specific cell
type and shuts it down. Once SR1001 is optimized, chances are it
will be far more potent and effective.”
The compound works without affecting other types of T helper
cells and without any significant metabolic impact, Burris added.
Reference
1. Solt LA, et al.
Suppression of TH17 differentiation and autoimmunity by a synthetic
ROR ligand. Nature, 17 April 2011. DOI: 10.1038/nature10075