New treatment for allergic response targets mast cells

New treatment for allergic response targets mast cells
Left: mast cells are activated by allergens reacting with IgE bound to IgE receptors on the mast cell surface to trigger the release of histamine and other inflammatory mediators that orchestrate an allergic response including recruitment of inflammatory cells. Right: exon skipping treatment eliminates trafficking of the IgE receptor to the surface of mast cells, rendering the cells unresponsive to allergen-mediated mast cell activation. Credit: Glenn Cruse

Researchers from North Carolina State University and the National Institutes of Health (NIH) have developed a method that stops allergic reactions by removing a key receptor from mast cells and basophils. Their work has implications for the treatment of skin allergies and asthma.

Allergic reactions are driven by and basophils - types of inflammatory cells found in tissues and the bloodstream, respectively, that function as part of our immune system. When you come into contact with an allergen - ragweed, for example - immunoglobulin E (IgE) specific to that allergen acts through its receptor on the mast cell, stimulating the mast cells and basophils to release mediators, such as histamine, that trigger an .

Currently, most allergy treatments focus on either stopping the effects of histamine and other mediators or on dampening the body's overall immune response by use of steroids. Unfortunately neither approach is totally effective, and in the case of dampening the immune response, can have significant drawbacks.

Glenn Cruse, formerly of the NIH, current assistant professor of immunology at NC State and corresponding author of a paper describing the work, along with NIH colleague and co-author Dean Metcalfe, wanted to try and block the allergic reaction at its source.

Cruse and Metcalfe looked at a gene called MS4A2, which is only expressed in mast cells and basophils, and is responsible for forming the IgE receptor on the mast cell.

The researchers utilized a technique known as , a form of RNA splicing, to eliminate the portion of one of the IgE receptor gene's mRNA that is essential to making a protein which places the IgE receptor on the mast cell surface. The cell's DNA remains unaffected. When the exon targeting therapy is stopped, the protein blocked by exon skipping is made again.

Cruse and Metcalfe tested their therapy on mast cells in vitro - where it eliminated activation of mast cells by allergen - and against allergic dermatitis in vivo, using a mouse model. Their results in vivo showed a marked reduction in the allergic dermatitis response in the mice.

"Asthma and allergic diseases affect up to 20 percent of people in developed countries, and their prevalence is increasing," says Cruse. "By eliminating the expression of the IgE receptor on the surface of mast cells, we have identified an innovative and targeted approach with the potential to treat allergic inflammation in millions of patients worldwide.

"Due to the specificity of our approach for mast cells and basophils, it should have significant advantages over current therapies. However, it is important to note that while our findings are very promising, we are still in the early stages of developing this therapeutic approach."

The research appears in Proceedings of the National Academy of Sciences. Funding was provided by the NIH Division of Intramural Research of NIAID and NHLBI.

More information: Exon skipping of FcεRIβ eliminates expression of the high affinity IgE receptor in mast cells with therapeutic potential for allergy, PNAS,

Citation: New treatment for allergic response targets mast cells (2016, November 21) retrieved 4 October 2023 from
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