Expression of a glycosylphosphatidylinositol-anchored ligand, growth hormone, blocks receptor signalling.

We have investigated the interaction between GH (growth hormone) and GHR (GH receptor). We previously demonstrated that a truncated GHR that possesses a transmembrane domain but no cytoplasmic domain blocks receptor signalling. Based on this observation we investigated the impact of tethering the receptor's extracellular domain to the cell surface using a native lipid GPI (glycosylphosphatidylinositol) anchor. We also investigated the effect of tethering GH, the ligand itself, to the cell surface and demonstrated that tethering either the ecGHR (extracellular domain of GHR) or the ligand itself to the cell membrane via a GPI anchor greatly attenuates signalling. To elucidate the mechanism for this antagonist activity, we used confocal microscopy to examine the fluorescently modified ligand and receptor. GH-GPI was expressed on the cell surface and formed inactive receptor complexes that failed to internalize and blocked receptor activation. In conclusion, contrary to expectation, tethering an agonist to the cell surface can generate an inactive hormone receptor complex that fails to internalize.

Functional characterization of NF-kappaB inhibitor-like protein 1 (NFkappaBIL1), a candidate susceptibility gene for rheumatoid arthritis.

Several studies have implicated the NF-kappaB inhibitor-like protein 1 (NFkBIL1) gene located in the class III region of the major histocompatibility complex (MHC) as a possible susceptibility locus for rheumatoid arthritis (RA). Based on limited homology, it has been suggested to be a member of the inhibitor of NF-kappaB (IkappaB) family of proteins, but a role in mRNA processing has also been proposed. We have investigated the expression of NFkBIL1 in RA synovial tissue and characterized its function. Real-time PCR showed the two NFkBIL1 mRNA splice variants are expressed in a tissue-specific manner. Dual immunofluorescent staining of human RA synovium with polyclonal anti-NFkBIL1 antibodies and anti-CD68, anti-CD3 or anti-factor VIII showed that NFkBIL1 was expressed in the rheumatoid synovial lining and sub-lining layers and co-localized in CD68+ and CD3+, but not Factor VIII+ cells. Confocal microscopy of cultured synovial fibroblasts revealed expression in speckled nuclear and homogenous cytoplasmic distributions, suggesting shuttling between the cytoplasmic and nuclear compartments. Functional tests showed that NFkBIL1 isoforms were incapable of associating with NF-kappaB and did not inhibit it, thus disproving the hypothesis that NFkBIL1 functions as an IkappaB. Affinity purification of endogenous NFkBIL1 proteins and co-immunoprecipitation experiments showed that NFkBIL1 can associate with mRNA and with three protein partners, identified by mass spectrometry as leukophysin, translation elongation factor 1 alpha and CTP synthase I. These data support a potential role for NFkBL1 in the pathogenesis of RA and indicates that it may be involved in mRNA processing or the regulation of translation.

Identification of threonine 66 as a functionally critical residue of the interleukin-1 receptor-associated kinase.

We have mutated a conserved residue of the death domain of the interleukin-1 (IL-1) receptor-associated kinase (IRAK), threonine 66. The substitution of Thr-66 with alanine or glutamate prevented spontaneous activation of NF-kappaB by overexpressed IRAK but enhanced IL-1-induced activation of the factor. Like the kinase-inactivating mutation, K239S, the T66A and T66E mutations interfered with the ability of IRAK to autophosphorylate and facilitated the interactions of IRAK with TRAF6 and with the IL-1 receptor accessory protein, AcP. Wild-type IRAK constructs tagged with fluorescent proteins formed complexes that adopted a punctate distribution in the cytoplasm. The Thr-66 mutations prevented the formation of these complexes. Measurements of fluorescence resonance energy transfer among fluorescent constructs showed that the Thr-66 mutations abolished the capacity of IRAK to dimerize. In contrast, the K239S mutation did not inhibit dimerization of IRAK as evidenced by fluorescence resonance energy transfer measurements, even though microscopy showed that it prevented the formation of punctate complexes. Our results show that Thr-66 plays a crucial role in the ability of IRAK to form homodimers and that its kinase activity regulates its ability to form high molecular weight complexes. These properties in turn determine key aspects of the signaling function of IRAK.