Comparative genomic analysis of the interferon/interleukin-10 receptor gene cluster.

Interferons and interleukin-10 are involved in key aspects of the host defence mechanisms. Human chromosome 21 harbors the interferon/interleukin-10 receptor gene cluster linked to the GART gene. This cluster includes both components of the interferon alpha/beta-receptor (IFNAR1 and IFNAR2) and the second components of the interferon gamma-receptor (IFNGR2) and of the IL-10 receptor (IL10R2). We report here the complete gene content of this GART-cytokine receptor gene cluster and the use of comparative genomic analysis to identify chicken IFNAR1, IFNAR2, and IL10R2. We show that the large-scale structure of this locus is conserved in human and chicken but not in the pufferfish Fugu rubripes. This establishes that the receptor components of these host defense mechanisms were fixed in an ancestor of the amniotes. The extraordinary diversification of the interferon ligand family during the evolution of birds and mammals has therefore occurred in the context of a fixed receptor structure.

Differences in activity between alpha and beta type I interferons explored by mutational analysis.

Type I interferon (IFN) subtypes alpha and beta share a common multicomponent, cell surface receptor and elicit a similar range of biological responses, including antiviral, antiproliferative, and immunomodulatory activities. However, alpha and beta IFNs exhibit key differences in several biological properties. For example, IFN-beta, but not IFN-alpha, induces the association of tyrosine-phosphorylated receptor components ifnar1 and ifnar2, and has activity in cells lacking the IFN receptor-associated, Janus kinase tyk2. To define the structural basis for these functional differences we produced human IFN-beta with point mutations and compared them to wild-type IFN-beta in assays that distinguish alpha and beta IFN subtypes. IFN-beta mutants with charged residues (N86K, N86E, or Y92D) introduced at two positions in the C helix lost the ability to induce the association of tyrosine-phosphorylated receptor chains and had reduced activity on tyk2-deficient cells. The combination of negatively charged residues N86E and Y92D (homologous with IFN-alpha8) increased the cross-species activity of the mutant IFN-betas on bovine cells to a level comparable to that of human IFN-alphas. In contrast, point mutations in the AB loop and D helix had no significant effect on these subtype-specific activities. A subset of these latter mutations did, however, reduce activity in a manner analogous to IFN-alpha mutations. The effects of these mutations on IFN-beta activity are discussed in the context of a family of related ligands acting through a common receptor and signaling pathway.

Mutant U5A cells are complemented by an interferon-alpha beta receptor subunit generated by alternative processing of a new member of a cytokine receptor gene cluster.

The cellular receptor for the alpha/beta interferons contains at least two components that interact with interferon. The ifnar1 component is well characterized and a putative ifnar2 cDNA has recently been identified. We have cloned the gene for ifnar2 and show that it produces four different transcripts encoding three different polypeptides that are generated by exon skipping, alternative splicing and differential use of polyadenylation sites. One polypeptide is likely to be secreted and two are transmembrane proteins with identical extracellular and transmembrane domains but divergent cytoplasmic tails of 67 and 251 amino acids. A mutant cell line U5A, completely defective in IFN-alpha beta binding and response, has been isolated and characterized. Expression in U5A cells of the polypeptide with the long cytoplasmic domain reconstitutes a functional receptor that restores normal interferon binding, activation of the JAK/STAT signal transduction pathway, interferon-inducible gene expression and antiviral response. The IFNAR2 gene maps at 0.5 kb from the CRFB4 gene, establishing that together IFNAR2, CRFB4, IFNAR1 and AF1 form a cluster of class II cytokine receptor genes on human chromosome 21.

Domains of interaction between alpha interferon and its receptor components.

We describe how constraints on the binding of human interferons (IFNs), alpha1 and alpha2 and alpha8 on mouse cells are partially relieved by the expression of the bovine (Bo) or human (Hu) IFN alpha/beta receptor (IFNAR) component in these cells. We show that, while the binding of all three is substantially increased by the transfection of Bo IFNAR, it is accompanied by an increase in activity only in the case of alpha2 and alpha8 (IFNs that otherwise have little activity on mouse cells). IFN alpha1, which shows some partial activity on mouse cells, responds to the presence of Bo IFNAR by acting, at low concentrations, as a competitive antagonist to IFNs alpha2 and alpha8. A review of published results on IFN hybrid scanning and on the effects of expressing Bo IFNAR in human cells led us to propose that an N-terminal segment of the IFN molecule interacts directly with IFNAR. Applying site-directed mutagenesis to an IFN hybrid; alpha8[60]alpha1[92]alpha8, we show that the point mutations K84 to E84 and Y90 to D90 act synergistically to cause the hybrid to behave as the parental IFN alpha8, switching the preference from Mu to Hu IFNAR in transfected mouse cells. The published structural models for IFN reveal that positions 84 and 90 span the exposed residues of the alpha-helix C of the IFN molecule. We derive a model of IFN-receptor interaction in which the A helix and the C helix of IFN interact with IFNAR and in which a binding phase can be distinguished from a binding/activity phase. We propose that the so-called "hot" domains of the IFN molecule (the AB loop and the D helix) are presented by IFNAR to interact with an additional component of the functional receptor.