Mechanistic Analysis of Anti-IgE Therapy of Asthma
Gruchalla, Rebecca S.   
University of Texas Sw Medical Center Dallas, Dallas, TX, United States

Morbidity and mortality from asthma have been found to be disproportionately high in the inner-city pediatric population compared to other pediatric populations. Over the last several years, the Inner City Asthma Study (ICAS) group has focused on a variety of potential factors that may account for this health disparity. Studies to date indicate that the majority of inner-city children with asthma are sensitized to a number of indoor environmental allergens. However, while IgE-mediated immune responses are known to play an important role in allergic I diseases, including allergic asthma, the clinical relevance of this high degree of allergen sensitivity in this inner-city population currently is not clearly known. In order to better understand the role played by IgE antibodies in allergic asthma, a therapeutic trial using RhuMab-E25, a humanized murine monoclonal anti-IgE antibody, will be carried out in inner-city asthmatic children by 6 of the 7 ICAS sites. The proposed mechanistic studies will seek to elucidate the immunomodulatory mechanisms underlying the clinical effects of RhuMab-E25 therapy. This agent has been shown to modulate both basophil and mast cell function and to suppress the late-phase asthmatic response and possibly B cell IgE synthesis in humans. In addition, monoclonal anti-IgE treatment of mice leads to altered Th2 cytokine profiles. These findings indicate that IgE plays a major role in orchestrating the complex inflammatory events that occur in asthma and that RhuMab-E25 may act on multiple effector cells. In the mechanistic studies, we will address three specific aims. Specifically, we will: a) determine if children who have the highest dust mite-and/or cockroach-specific IgE levels will demonstrate the most clinical benefit from RhuMab-E25 therapy; b) determine if RhuMab-E25 therapy will lead to decreased allergen-driven Th2 cytokine production and increased Th1 cytokine production by patient peripheral blood mononuclear cells; and c) determine if polymorphisms in genes associated with IgE synthesis and/or function are responsible for individual variation in response to RhuMab-E25 therapy. These studies will allow us to better understand the cellular and molecular events associated with RhuMab-E25 therapy and they will allow us to determine which allergic diseases as well as which patient populations will receive the most therapeutic benefit.