Anne E. Shelburne scite author profile

Allergic disease is mediated by high levels of allergen-specific IgE. IgE binding to CD23, the low affinity receptor for IgE, results in a negative feedback signal leading to a decrease in IgE production. Previous studies have shown that CD23 associates as an oligomer and that cooperative binding of at least two lectin domains is required for high affinity IgE binding to CD23. We have previously shown that cooperative binding is required for regulation of IgE production. This study describes the production of several mAbs that bind the stalk region of murine CD23. One of the Abs, 19G5, inhibited the IgE/CD23 interaction at 37°C, but not at 4°C. Analysis of the binding properties of these Abs revealed that CD23 dissociates at high temperatures, such as 37°C; however, the N terminus is constitutively associated, indicating partial, rather than complete, dissociation. A novel finding was that the stalk region, previously thought to mediate trimer association, was not required for oligomerization. These data reveal important information about the structure of CD23 that may be useful in modulating IgE production.

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In vivo murine CD23 destabilization enhances CD23 shedding and IgE synthesis

Ford

Kilmon

Haas

et al. 2006

Cellular Immunology

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Temperature Effect on IgE Binding to CD23 Versus FcεRI

Chen

Kilmon

et al. 2003

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A chimeric soluble CD23, consisting of the extracellular domain of mouse CD23 and a modified leucine zipper (lz-CD23), has been shown to inhibit IgE binding to the FcεRI. A similar human CD23 construct was also shown to inhibit binding of human IgE to human FcεRI. In both systems, the inhibition was found to be temperature dependent; a 10-fold molar excess of lz-CD23 gave 90–98% inhibition at 4°C, dropping to 20–30% inhibition at 37°C. Surface plasmon resonance analysis of lz-CD23 binding to an IgE-coated sensor chip suggested that the effective concentration of lz-CD23 was lower at the higher temperatures. Analysis of 125I-IgE binding to CD23+-Chinese hamster ovary cells also indicated that increased temperature resulted in a lower percentage of IgE capable of interacting with CD23. In contrast, IgE interacts more effectively with FcεRI+-rat basophilic leukemia cells at 37°C compared with 4°C. The results support the concept that the open and closed IgE structures found by crystallography interact differently with the two IgE receptors and suggest that temperature influences the relative percentage of IgE in the respective structural forms. Changes in CD23 oligomerization also plays a role in the decreased binding seen at physiological temperatures.

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Anne E. Shelburne

IL-21 dependent IgE production in human and mouse in vitro culture systems is cell density and cell division dependent and is augmented by IL-10

CD23 Trimers Are Preassociated on the Cell Surface Even in the Absence of Its Ligand, IgE

In vivo murine CD23 destabilization enhances CD23 shedding and IgE synthesis

Temperature Effect on IgE Binding to CD23 Versus FcεRI

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