Assessing the role of Asp 194 in the transmembrane domains of the α-chain of the high-affinity receptor complex for immunoglobulin E in signal transduction.

The high-affinity receptor complex for IgE plays a pivotal role in allergic responses since cross-linking of the high-affinity IgE receptor (FcɛRI) on target cells initiates a signaling cascade facilitating release of inflammatory mediators causing allergic responses. The transmembrane regions of the ligand binding domains of the high-affinity IgE and low-affinity IgG receptors share an invariant motif (LFAVDTGL) containing a polar aspartate within a predominantly non-polar setting. The functional importance of this aspartate residue (D194) in FcɛRI-mediated receptor signaling was assessed by site-directed mutagenesis. Rat basophilic leukemia cells (RBL-2H3) transfected with the human IgE binding subunit (FcɛRIα) incorporating polar substitutions like asparagine (D194N) or threonine (D194T) resulted in the formation of a functional rat/human chimeric receptor complex. When activated via huIgE and antigen, cells transfected with these variant receptor subunits supported mediator release, intracellular calcium mobilisation and tyrosine phosphorylation of γ-chain and Syk kinase while a non-polar substitution (D194L) gave rise to cell surface expression of the mutated receptor subunit but failed to initiate downstream signaling. No cell surface expression of huFcɛRIα gene constructs was observed when D194 was replaced with the non-polar Ile (D194I) residue of similar size, the larger positively charged Arg (D194R) or lysine (D194K) residues, or the negatively charged glutamate (D194E) and smaller polar Ser (D194S) non-polar Ala (D194A) and V (D194V). These observations highlight importance of the size and charge of amino acid residue at position 194 in determining IgE receptor subunit interactions, cell surface localization, and initiation of downstream signaling events.

Characterization of an early signaling defect following Fc epsilonRI activation in the canine mastocytoma cell line, C2.

A comparison of IgE recognition by cognate receptors expressed on the C2 canine mastocytoma cell line with analogous events in a rat basophilic leukemia cell line transfected with the alpha-chain subunit of the canine high-affinity IgE receptor using flow cytometry show that canine IgE recognizes the alpha-chain of its cognate receptor on both cell lines. Our study confirms the expression of functional IgE receptors in both cell lines, but receptor-mediated signaling in the C2 line only supports the early stages of downstream signaling as shown by the phosphorylation of the gamma-chain and the failure to effect the phosphorylation of Syk. In contrast RBL-2H3 cells respond to sensitization with IgE and challenge with cognate antigen with tyrosine phosphorylation of the gamma-subunits of the receptor complex followed by downstream phosphorylation of Syk and Ca(2+) mobilization, culminating in beta-hexosaminidase release. We propose that the identification of the precise signaling defect in C2 cells will yield useful information regarding the pathway leading to mast cell exocytosis and facilitate the restoration of the complete signaling cascade through complementation of the missing/defective signal transducer since signaling events downstream of Ca(2+) mobilization are intact as demonstrated by beta-hexosaminidase release following non-immunologic stimulation with the calcium ionophore, A23187.