α-1 Antitrypsin regulates human neutrophil chemotaxis induced by soluble immune complexes and IL-8
David A. Bergin, … , Shane J. O’Neill, Noel G. McElvaney
David A. Bergin, … , Shane J. O’Neill, Noel G. McElvaney
Published November 8, 2010
Citation Information: J Clin Invest. 2010;120(12):4236-4250. https://doi.org/10.1172/JCI41196.
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Research Article Pulmonology

α-1 Antitrypsin regulates human neutrophil chemotaxis induced by soluble immune complexes and IL-8

Abstract

Hereditary deficiency of the protein α-1 antitrypsin (AAT) causes a chronic lung disease in humans that is characterized by excessive mobilization of neutrophils into the lung. However, the reason for the increased neutrophil burden has not been fully elucidated. In this study we have demonstrated using human neutrophils that serum AAT coordinates both CXCR1- and soluble immune complex (sIC) receptor–mediated chemotaxis by divergent pathways. We demonstrated that glycosylated AAT can bind to IL-8 (a ligand for CXCR1) and that AAT–IL-8 complex formation prevented IL-8 interaction with CXCR1. Second, AAT modulated neutrophil chemotaxis in response to sIC by controlling membrane expression of the glycosylphosphatidylinositol-anchored (GPI-anchored) Fc receptor FcγRIIIb. This process was mediated through inhibition of ADAM-17 enzymatic activity. Neutrophils isolated from clinically stable AAT-deficient patients were characterized by low membrane expression of FcγRIIIb and increased chemotaxis in response to IL-8 and sIC. Treatment of AAT-deficient individuals with AAT augmentation therapy resulted in increased AAT binding to IL-8, increased AAT binding to the neutrophil membrane, decreased FcγRIIIb release from the neutrophil membrane, and normalization of chemotaxis. These results provide new insight into the mechanism underlying the effect of AAT augmentation therapy in the pulmonary disease associated with AAT deficiency.

Authors

David A. Bergin, Emer P. Reeves, Paula Meleady, Michael Henry, Oliver J. McElvaney, Tomás P. Carroll, Claire Condron, Sanjay H. Chotirmall, Martin Clynes, Shane J. O’Neill, Noel G. McElvaney

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Figure 5

AAT binds FcγRIIIb on the neutrophil membrane.

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AAT binds FcγRIIIb on the neutrophil membrane. (A) Immunoprecipitate (IP...
(A) Immunoprecipitate (IP) employing rabbit (Rb) antibody to AAT. The AAT binding partner (labeled 1) was identified as FcγRIIIb (40–60 kDa). (B) Reciprocal immunoprecipitate with FcγRIIIb goat (Gt) antibody. Coimmunoprecipitated proteins were identified as FcγRIIIb (labeled 1; accession number AA128563) and as AAT (labeled 2; accession number CAJ15161). (C) Western blots of immunoprecipitate reactions were performed with goat antibody against AAT (top panel) and mouse (Mo) antibody against FcγRIIIb (bottom panel). Serum purified AAT and recombinant human (Rh) FcγRIIIb are included as positive controls. (D) Binding of Rh FcγRIIIb or Rh FcγRIIa to AAT (*P = 0.02 compared with control containing no FcγRIIIb). (E) FcγRIIIb-AAT complex in serum of CF (n = 4) individuals was significantly higher than that of normal MM (Con; n = 6) or AATD (n = 6) subjects (*P < 0.05, CF versus control or ZZ). (F) Colocalization (merged image in yellow) of rhodamine labeling for AAT and FITC for FcγRIIIb, at the membrane margin of cells (×64 magnification, ×4 zoom). (G) NaCl and PI-PLC treatment of neutrophil membranes. Immunoblots included untreated membranes (Con) and antibodies against p22phox. (H) Flow cytometry analysis of membrane-bound FcγRIIIb (mean fluorescence: MM, 41.93; ZZ, 15.44). The isotype control antibody is in black (filled). (I) Levels of FcγRIIIb in serum of ZZ-AATD individuals and MM controls (Con) (*P = 0.01). In AC and G, images are representative results from 1 of 3 separate experiments. Lanes in A and C were run on the same gel but were noncontiguous. D, E, H, and I represent results performed in triplicate. Images in F are representative results of 2 independent experiments.