Genetic glitch at the root of allergies revealed

Posted: Published on July 25th, 2013

This post was added by Dr Simmons

July 24, 2013 Newly published research by investigators at Johns Hopkins Children's Center and the Johns Hopkins Institute of Genetic Medicine reveals that a faulty genetic pathway already known for its role in some connective tissue disorders is also a potent player in many types of allergies.

Scientists have long understood that allergies are the result of a complex interplay between environment and genes, but now, in what investigators believe is a scientific first, a single genetic pathway has been implicated in an array of allergic disorders.

A report on the study's findings, published July 24 in Science Translational Medicine, shows that aberrant signaling by a protein called transforming growth factor-beta, or TGF-beta, may be responsible for disrupting the way immune cells respond to common foods and environmental allergens, leading to a wide range of allergic disorders.

TGF-beta is well known for its widespread effects in the body, from controlling how cells in a various organs grow and develop to overseeing how they communicate with one another. Mutations in the genes that lead to abnormal TGF-beta signaling are also keys to Marfan and Loeys-Dietz syndromes, genetic conditions marked by blood vessel laxity and dangerous stretching of the aorta, the body's largest blood vessel.

"We have evidence that the same glitch in TGF-beta that is responsible for some of the clinical manifestations seen in Marfan and Loeys-Dietz diseases also lies behind the cascade of events that culminates in the development of conditions like asthma, food allergies and eczema," says lead investigator Pamela Frischmeyer-Guerrerio, M.D., Ph.D., an immunologist at Johns Hopkins Children's Center.

Notably, the researchers add, their experiments suggest TGF-beta is more than a mere contributor in the disease process.

"Disruption in TGF-beta signaling does not simply nudge immune cells to misbehave but appears to singlehandedly unlock the very chain reaction that eventually leads to allergic disease," says senior investigator Harry "Hal" Dietz, M.D., a cardiologist at Johns Hopkins Children's Center, professor in the McKusick-Nathans Institute of Genetic Medicine at Hopkins and director of the William S. Smilow Center for Marfan Research.

The researchers' curiosity about a wider role for TGF-beta was ignited years ago when they first noticed that patients with Loeys-Dietz syndrome (LDS) had higher than normal rates of allergies.

The present study involved 58 children with LDS, ages 7 to 20, followed at Johns Hopkins. Most of them had either a history of allergic disease or active allergies, like allergic rhinitis, eczema, food allergies, asthma, and gastrointestinal and esophageal allergic disease. Not surprisingly, these patients also had abnormally high levels of several traditional markers of allergic disease, including IgE -- an antibody that drives life-threatening allergic responses -- and high numbers of eosinophils, white blood cells involved in allergic reactions.

Because TGF-beta is known to control immune cell maturation, the researchers homed in on a group of cells known as regulatory T cells, which keep tabs on other immune cells to ensure that they don't go into overdrive. LDS patients had unusually high levels of regulatory T cells, but the real surprise came when researchers noticed that instead of acting in their regular role as inflammation tamers, the regulatory T cells were doing the opposite -- secreting allergy-promoting signaling molecules called cytokines. Regulatory T cells obtained from patients with known allergies but without LDS were misbehaving in much the same way, a finding that suggests TGF-beta may induce immune cell malfunction even in the absence of LDS, the researchers say.

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Genetic glitch at the root of allergies revealed

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