Physical and Functional Association of FcαR With Protein Tyrosine Kinase Lyn

Crosslinking of the Human Fc Receptor for IgA (FcαRI/CD89) Triggers FcR γ-Chain-Dependent Shedding of Soluble CD89

CD89/FcαRI is a 55- to 75-kDa type I receptor glycoprotein, expressed on myeloid cells, with important immune effector functions. At present, no information is available on the existence of soluble forms of this receptor. We developed an ELISA for the detection of soluble CD89 (sCD89) forms and investigated the regulation of sCD89 production. PMA/ionomycin stimulation of monocytic cell lines (U937, THP-1, and MM6), but not of neutrophils, resulted in release of sCD89. Crosslinking of CD89 either via its ligand IgA or with anti-CD89 mAbs similarly resulted in sCD89 release. Using CD89-transfected cells, we showed ligand-induced shedding to be dependent on coexpression of the FcR γ-chain subunit. Shedding of sCD89 was dependent on signaling via the γ-chain and prevented by addition of inhibitors of protein kinase C (staurosporine) or protein tyrosine kinases (genistein). Western blotting revealed sCD89 to have an apparent molecular mass of 30 kDa and to bind IgA in a dose-dependent fashion. In conclusion, the present data document a ligand-binding soluble form of CD89 that is released upon activation of CD89-expressing cells. Shedding of CD89 may play a role in fine-tuning CD89 immune effector functions.

γ-Chain Dependent Recruitment of Tyrosine Kinases to Membrane Rafts by the Human IgA Receptor FcαR

We show that the human IgA receptor, FcαR, redistributes to plasma membrane rafts after cross-linking and that tyrosine kinases are relocated to these sites following FcαR capping. We demonstrate by confocal microscopy that FcαR caps in membrane rafts by a γ-chain-independent mechanism but that γ-chain expression is necessary for Lyn redistribution. Immunoblotting of rafts isolated by sucrose density gradient centrifugation demonstrated recruitment of γ-chain and phosphorylated tyrosine kinases Lyn and Bruton’s tyrosine kinase to membrane rafts after FcαR cross-linking. Time-dependent differences in Lyn phosphorylation and Bruton’s tyrosine kinase distribution were observed between cells expressing FcαR plus γ-chain and cells expressing FcαR only. This study defines early FcαR-triggered membrane dynamics that take place before FcαR internalization.

Role of Src in the Modulation of Multiple Adaptor Proteins in FcRI Oxidant Signaling

Cross-linking of Fc receptors for IgA, FcR (CD89), on monocytes/macrophages is known to enhance phagocytic activity and generation of oxygen free radicals. We provide evidence here that the FcR signals through the γ subunit of FcɛRI in U937 cells differentiated with interferon γ (IFNγ). Our results provide the first evidence that FcR-mediated signals modulate a multimolecular adaptor protein complex containing Grb2, Shc, SHIP, CrkL, Cbl, and SLP-76. Cross-linking of FcRI using anti-FcRI induces the phosphorylation of the γ subunit as detected by mobility retardation on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Stimulation of FcRI induced the tyrosine phosphorylation of Shc and increased the association of Grb2 with Shc and CrkL. Grb2 associates constitutively with Sos, and the latter undergoes mobility shift upon FcRI stimulation. The complex adapter proteins, Cbl and SLP-76, are physically associated in myeloid cells and both proteins undergo tyrosine phosphorylation upon FcR stimulation. These data indicate that the stimulation of FcR results in the modulation of adaptor complexes containing tyrosine-phosphorylated Cbl, Shc, SHIP, Grb2, and Crkl. Experiments performed with the Src kinase inhibitor, PP1, provide the first evidence that Src kinase activation is required for FcRI-induced production of superoxide anions and provide insight into the mechanism for FcR-mediated activation of downstream oxidant signaling in myeloid cells.

Human Immunoglobulin A Receptor (FcRI, CD89) Function in Transgenic Mice Requires Both FcR γ Chain and CR3 (CD11b/CD18)

Even though more immunoglobulin A (IgA) is produced in humans than all other isotypes combined, relatively little is known about receptors that bind the Fc part of IgA. The myeloid IgA receptor, FcRI (CD89), triggers various effector functions in vitro, but its in vivo role remains unclear. Here, a transgenic mouse model is described in which FcRI is expressed under its own regulatory sequences. Receptor expression and regulation by cytokines was comparable to the human situation and hFcRI can trigger phagocytosis and lysis of tumor cells. To analyze the contribution of the FcR γ chain or the β2 integrin CR3 (CD11b/CD18) in FcRI biological function, FcRI transgenic mice were crossed with either FcR γ chain −/− or CR3 −/− mice. In contrast to in vitro data, FcR γ chain was essential for surface expression of hFcRI in vivo. Functional studies in hFcRI/ γ−/−mice were, therefore, limited. In vitro studies showed FcR γ chain to be necessary for phagocytosis. Neither hFcRI expression nor phagocytosis, triggered via hFcRI, were influenced by CR3. Remarkably, the capacity to lyse tumor targets was ablated in hFcRI transgenic/ CR3−/− mice, although binding of neutrophils to tumor cells was intact. This shows a previously unrecognized importance of CR3 for hFcRI-mediated antibody-dependent cellular cytotoxicity (ADCC).

The Mapping of the Lyn Kinase Binding Site of the Common β Subunit of IL-3/Granulocyte-Macrophage Colony- Stimulating Factor/IL-5 Receptor

It has been shown that a membrane-proximal region within common β (βc) receptor of IL-3/granulocyte-macrophage CSF/IL-5 (amino acids 450–517) is important for Lyn binding. We have shown previously that Lyn kinase is physically associated with the IL-5R βc subunit in unstimulated cells. The result suggests that this association involves binding modules that are not activation or phosphorylation dependent. The objective of this study was to map the exact Lyn binding site on βc. Using overlapping and/or sequential peptides derived from βc 450–517, we narrowed down the Lyn binding site to nine amino acid residues, βc 457–465. The P→A mutation in this region abrogated the binding to Lyn, indicating a critical role of proline residues. We created a cell-permeable Lyn-binding peptide by N-stearation. This cell-permeable peptide blocked the association of Lyn, but not Jak2 with βc in situ. We also investigated the βc binding site of Lyn kinase. Our results suggest that the N-terminal unique domain of Lyn kinase is important for binding to βc receptor. To our knowledge, this is the first molecular identification of the Lyn binding site of βc receptor. This finding may help develop specific inhibitors of Lyn-coupled signaling pathways.