IL-5-Induced JAB-JAK2 interaction.

Receptor activation by the haematopoietic growth factor proteins interleukin 5 (IL-5) and granulocyte-macrophage colony-stimulating factor (GM-CSF) leads to phosphorylation of JAK2 as a key trigger of signal transduction. JAB has recently been identified as a regulator of JAK2 phosphorylation and activity by binding phosphorylated JAK2 and inducing its degradation. As part of our effort to define molecular recognition networks that lead to signalling, we investigated the effect of JAB on both JAK2 phosphorylation and JAK2 interaction state that ensue upon IL-5 stimulation in recombinant 293T cells cotransfected 293T cells with IL-5R alpha, beta c and hJAK2 either with or without JAB. Without JAB, stimulation with wild-type and re-engineered single chain (sc) IL-5 induced a time-dependent phosphorylation of JAK2. In the presence of JAB cotransfection, no phospho-JAK2 was observed, and JAB was observed co-immunoprecipitated with non-phosphorylated JAK2. The time dependence of JAB co-immunoprecipitation correlated with the time dependence of JAK2 phosphorylation when JAB was absent. Since JAB has already been shown to bind JAK2 via a phosphorylated tyrosine, the current data suggest that JAB binds to phosphorylated JAK2, enhances JAK2 dephosphorylation and remains associated in a complex, with dephosphorylated JAK2, that may be a precursor leading to irreversible JAK2 degradation.

Construction and binding kinetics of a soluble granulocyte-macrophage colony-stimulating factor receptor alpha-chain-Fc fusion protein.

Granulocyte-macrophage colony-stimulating factor (GM-CSF) activity is mediated by a cellular receptor (GM-CSFR) that is comprised of an alpha-chain (GM-CSFRalpha), which specifically binds GM-CSF, and a beta-chain (betac), shared with the interleukin-3 and interleukin-5 receptors. GM-CSFRalpha exists in both a transmembrane (tmGM-CSFRalpha) and a soluble form (sGM-CSFRalpha). We designed an sGM-CSFRalpha-Fc fusion protein to study GM-CSF interactions with the GM-CSFRalpha. The construct was prepared by fusing the coding region of the sGM-CSFRalpha with the CH2-CH3 regions of murine IgG2a. Purified sGM-CSFRalpha-Fc ran as a monomer of 60 kDa on reducing SDS-polyacrylamide gel electrophoresis but formed a trimer of 160-200 kDa under nonreducing conditions. The sGM-CSFRalpha-Fc bound specifically to GM-CSF as demonstrated by standard and competitive immunoassays, as well as by radioligand assay with 125I-GM-CSF. The sGM-CSFRalpha-Fc also inhibited GM-CSF-dependent cell growth and therein is a functional antagonist. Kinetics of sGM-CSFRalpha-Fc binding to GM-CSF were evaluated using an IAsys biosensor (Affinity Sensors, Paramus, NJ) with two assay systems. In the first, the sGM-CSFRalpha-Fc was bound to immobilized staphylococcal protein A on the biosensor surface, and binding kinetics of GM-CSF in solution were determined. This revealed a rapid koff of 2.43 x 10(-2)/s. A second set of experiments was performed with GM-CSF immobilized to the sensor surface and the sGM-CSFRalpha-Fc in solution. The dissociation rate constant (koff) for the sGM-CSFRalpha-Fc trimer from GM-CSF was 1.57 x 10(-3)/s, attributable to the higher avidity of binding in this assay. These data indicate rapid dissociation of GM-CSF from the sGM-CSFRalpha-Fc and suggest that in vivo, sGM-CSFRalpha may need to be present in the local environment of a responsive cell to exert its antagonist activity.