The proximal tyrosines of the cytoplasmic domain of the beta chain of the type I interferon receptor are essential for signal transducer and activator of transcription (Stat) 2 activation. Evidence that two Stat2 sites are required to reach a threshold of interferon alpha-induced Stat2 tyrosine phosphorylation that allows normal formation of interferon-stimulated gene factor 3.

The precise role of the different subunits (alpha/IFNAR1 and betaL/IFNAR2) of the type I interferon receptor (IFN-R) in the activation of signal transducer and activator of transcription (Stat) 1, Stat2, and Stat3 has not yet been established. In this report we demonstrate that there are functionally redundant phosphotyrosine-dependent and -independent binding sites for Stat2 in the alpha and beta subunits of the type I IFN-R. Expression of a type I IFN-R containing only the constitutive Stat2 site or the proximal tyrosines of betaL, but not the docking site on the alpha chain (Tyr466 and Tyr481), supported low levels of Stat2 activation. However, the presence of only one intact Stat2 site did not lead to induction of interferon-stimulated gene factor 3 (ISGF3) or an antiviral state. Normal levels of Stat2 tyrosine phosphorylation, induction of ISGF3, and an antiviral effect always required the proximal tyrosines of betaL and at least one of the other Stat2 sites (Tyralpha466, 481 or betaL404-462). These data suggest that a threshold of Stat2 tyrosine phosphorylation is required for complete activation of ISGF3. Interestingly, a receptor in which all tyrosines were mutated to phenylalanine shows normal Stat3 phosphorylation and low levels of activation of Stat1.

Identification of a domain in the beta subunit of the type I interferon (IFN) receptor that exhibits a negative regulatory effect in the growth inhibitory action of type I IFNs.

Expression of human alpha and long form of the beta (betaL) subunits of type I interferon receptor (IFN-R) in mouse cells is sufficient to activate the Jak-Stat pathway and to elicit an antiviral state in response to human IFNalpha2 and IFNbeta. We demonstrate herein, however, that these cells respond to the antiproliferative effects of murine IFNalphabeta but not human type I IFNs. These results suggest that an unknown species-specific component is required for the antiproliferative effect of human type I IFNs. The absence of this component can be complemented by expressing the human betaL chain truncated at amino acid 346. Thus, the distal region of betaL appears to function as a negative regulator of the growth inhibitory effects of type I IFNs. Further studies looking for possible targets of the betaL regulatory domain demonstrated that this region associates with a tyrosine phosphatase. These results suggest that a protein associated with the negative regulatory domain of betaL, likely a tyrosine phosphatase, plays a role in regulating the growth inhibitory effects of human type I IFNs.

Differential use of the betaL subunit of the type I interferon (IFN) receptor determines signaling specificity for IFNalpha2 and IFNbeta.

The signaling specificity for cytokines that have common receptor subunits is achieved by the presence of additional cytokine-specific receptor components. In the type I interferon (IFN) family, all 14 subtypes of IFNalpha, IFNbeta, and IFNomega bind to the same alpha and betaL subunits of the type I IFN-R, yet differences in signaling and biological effects exist among them. Our data demonstrate that IFNalpha2 and IFNbeta utilize different regions of the betaL subunit for signaling. Thus, in contrast to other cytokine systems, signal diversity in the type I IFN system can be accomplished within the same receptor complex by utilizing different regions of the same receptor subunits.

A region of the beta subunit of the interferon alpha receptor different from box 1 interacts with Jak1 and is sufficient to activate the Jak-Stat pathway and induce an antiviral state.

Coexpression of the alpha and betaL subunits of the human interferon alpha (IFNalpha) receptor is required for the induction of an antiviral state by human IFNalpha. To explore the role of the different domains of the betaL subunit in IFNalpha signaling, we coexpressed wild-type alpha subunit and truncated forms of the betaL chain in L-929 cells. Our results demonstrated that the first 82 amino acids (AAs) (AAs 265-346) of the cytoplasmic domain of the betaL chain are sufficient to activate the Jak-Stat pathway and trigger an antiviral state after IFNalpha2 binding to the receptor. This region of the betaL chain, required for Jak1 binding and activation, contains the Box 1 motif that is important for the interaction of some cytokine receptors with Jak kinases. However, using glutathione S-transferase fusion proteins containing amino- and carboxyl-terminal deletions of the betaL cytoplasmic domain, we demonstrate that the main Jak1-binding region (corresponding to AAs 300-346 on the beta subunit) is distinct from the Box 1 domain (AAs 287-295).

Differences in interferon alpha and beta signaling. Interferon beta selectively induces the interaction of the alpha and betaL subunits of the type I interferon receptor.

All Type I interferons (IFNalpha, IFNbeta, IFNomega) bind to the Type I IFN receptor (IFNR) and elicit a common set of signaling events, including activation of the Jak/Stat and IRS pathways. However, IFNbeta selectively induces the association of the alpha subunit of the Type I IFNR with p100, a tyrosyl phosphoprotein, to transduce IFNbeta-specific signals. Using antibodies raised against the different components of the Type I IFNR, we identified p100 as the long form of the beta subunit (betaL subunit) of the Type I IFNR. This was also confirmed in experiments with mouse L-929 cells transfected with truncated forms of betaL. Thus, IFNbeta stimulation of human cells or mouse L-929 transfectants expressing the human alpha and betaL subunits, selectively induces the formation of a signaling complex containing the alpha and betaL subunits of the receptor. The IFNbeta-regulated interaction of the alpha and betaL chains is rapid and transient and follows a similar time course with the tyrosine phosphorylation of these receptor components. These data demonstrate that the signaling specificity for different Type I IFNs is established early in the signaling cascade, at the receptor level, and results from distinct interactions between components of the Type I IFNR.

The type-I interferon receptor. The long and short of it.

The type-I interferon receptor is a multisubunit receptor of the cytokine receptor superfamily. The production of specific monoclonal antibodies against the receptor and the cloning of different receptor subunits have contributed to understanding the type-I interferon receptor structure and function. The present article analyzes these new advances and the role of the different receptor subunits in type-I interferon signaling.

Homodimerization and intermolecular tyrosine phosphorylation of the Tyk-2 tyrosine kinase.

The Jak kinases and Stat transcription factors play a major role in signaling of various cytokines including IFN alpha. In this report we show a ligand-independent interaction between Tyk-2 and Jak-1 kinases. We also demonstrate that the Tyk-2 kinase forms a homodimer that has the ability to undergo intermolecular tyrosine phosphorylation. The formation of the Tyk-2 homodimer is independent of both tyrosine phosphorylation and the presence of the tyrosine kinase domain.

Cloning and expression of a long form of the beta subunit of the interferon alpha beta receptor that is required for signaling.

The interferon alpha beta receptor (IFN alpha R) or type I IFN-R is formed by a 110-kDa alpha subunit or IFNAR and by a beta subunit, which has short and long forms (molecular masses of 55 and 95-100 kDa, respectively). In this report, we demonstrate that the IFN alpha/beta R cDNA recently cloned corresponds to the 55-kDa or short form of the beta subunit, while the 95-100-kDa species reported here corresponds to a longer form of the IFN alpha/beta R cDNA that is probably produced by alternative splicing of the same gene. Stable transfection of the alpha subunit with either form of the beta subunit results in the expression of low and high affinity receptors, while expression of either form of the beta subunit alone only produces low affinity receptors. More important, only expression of the alpha and long form of the human beta subunits in mouse L-929 cells reconstitutes the activation of the Jak kinases and the Stat factors, as well as the antiviral response to human type I IFNs.

Vaccinia virus B18R gene encodes a type I interferon-binding protein that blocks interferon alpha transmembrane signaling.

Poxviruses encode a large number of proteins that attenuate the inflammatory and immune responses to infection. In this report we demonstrate that a number of orthopoxviruses express a type I interferon (IFN)-binding protein, which is encoded by the B18R open reading frame in the WR strain of vaccinia virus. The B18R protein has significant regions of homology with the alpha subunits of the mouse, human, and bovine type I IFN receptors, bound human IFN alpha 2 with high affinity, and inhibited transmembrane signaling as demonstrated by inhibition of Fc receptor factor gamma 1/gamma 2 and interferon-stimulated gene factor-3 formation as well as inhibition of the IFN alpha antiviral response. Among viral host response modifiers, the B18R protein is unique inasmuch as it exists as a soluble extracellular as well as a cell surface protein and thus should effectively block both autocrine and paracrine functions of IFN.

Transmembrane signaling by the alpha subunit of the type I interferon receptor is essential for activation of the JAK kinases and the transcriptional factor ISGF3.

The Type I interferon (IFN) receptor has a multisubunit structure. The component of the receptor that has been most thoroughly studied is the alpha subunit. Expression of the alpha subunit in mouse L-929 cells confers antiviral response to human IFN alpha 8, but not to human IFN alpha 2 or IFN beta. This antiviral effect is observed without a significant increase in IFN binding. It has not been determined why mouse cells expressing the human alpha subunit show different response to the antiviral activity of distinct human Type I IFNs. In this report, we demonstrate that the response to human Type I IFNs in mouse cells expressing the alpha subunit is dependent on cross-binding to the mouse receptor. This is supported by the finding that human IFN alpha 8, but not human IFN alpha 2, cross-binds to the mouse receptor even in the absence of expression of the human alpha subunit. We also demonstrate that only mouse cells expressing the human alpha subunit are able to tyrosine-phosphorylate p135tyk2 and JAK-1 and to form the ISGF3 complex in response to human IFN alpha 8. These results demonstrate that the alpha subunit is essential for IFN alpha signaling through the JAK kinases and ISGF3.

Direct binding to and tyrosine phosphorylation of the alpha subunit of the type I interferon receptor by p135tyk2 tyrosine kinase.

Binding of type I interferons (IFNs) to their receptors induces rapid tyrosine phosphorylation of multiple proteins, including the alpha and beta subunits of the receptor, the polypeptides that form the transcriptional activator ISGF3 alpha (Stat113, Stat84, and Stat91), and the p135tyk2 and Jak-1 tyrosine kinases. In this report, we demonstrate that the alpha subunit of the type I IFN receptor (IFN-R) corresponds to the product of a previously cloned receptor subunit cDNA and, further, that the p135tyk2 tyrosine kinase directly binds and tyrosine phosphorylates this receptor subunit. Glutathione S-transferase (GST) fusion proteins encoding the different regions of the cytoplasmic domain of the alpha subunit can bind the p135tyk2 contained in human cell lysates. The association between the alpha subunit and Tyk2 was demonstrated by immunoblotting with anti-Tyk2 and antiphosphotyrosine antibodies and by using an in vitro kinase assay. Analogous experiments were then performed with recombinant baculoviruses encoding constitutively active Jak family tyrosine kinases. In this case, p135tyk2, but not Jak-1 or Jak-2 protein, binds to the GST-IFN-R proteins, suggesting that the interaction between these two proteins is both direct and specific. We also demonstrate that Tyk2, from extracts of either IFN alpha-treated human cells or insect cells infected with the recombinant baculoviruses, can catalyze in vitro phosphorylation of GST-IFN-R protein in a specific manner. Deletion mutants of the GST-IFN-R protein were used to localize both the binding and tyrosine phosphorylation site(s) to a 46-amino-acid juxtamembrane region of the alpha subunit, which shows sequence homology to functionally similar regions of other cytokine receptor proteins. These data support the hypothesis that the Tyk2 protein functions as part of a receptor complex to initiate intracellular signaling in response to type I IFNs.

Ligand-independent anti-oncogenic activity of the alpha subunit of the type I interferon receptor.

Two interferon (IFN) alpha-regulated genes, IRF1/ISGF2 and PKR/p68 kinase, may function as tumor suppressor genes suggesting that the IFN system may function as a tumor suppressor system. We report that the expression of the alpha subunit of the type I IFN receptor in human K-562 cells had anti-oncogenic effects that include a marked decrease in: (i) cell proliferation rate, (ii) the cell density at which growth arrest normally occurs, and (iii) the tumorigenicity in nude mice. Furthermore, expression of the alpha subunit in K-562 cells induced erythroid differentiation. While most cytokine receptors become activated after binding their corresponding ligands, the overexpression of the alpha subunit has a physiological effect in the absence of its natural ligand, type I IFNs, suggesting a novel function for this type I IFN receptor subunit. The anti-oncogenic effect of the alpha subunit is mediated by a pathway that does not involve two tumor suppressor genes induced by type I IFNs, the transcriptional regulator IFN response factor-1 and the RNA-dependent protein kinase, or the p135tyk2 tyrosine kinase that directly associates and phosphorylates the alpha subunit.

Complementation of the interferon alpha response in resistant cells by expression of the cloned subunit of the interferon alpha receptor. A central role of this subunit in interferon alpha signaling.

A subunit of the interferon alpha receptor (IFN alpha R) that confers biologic response to and specific "binding" for IFN alpha 8 has recently been cloned. We have explored the biological consequences of expressing the cloned IFN alpha R subunit in human cells resistant to IFN alpha and in mouse cell lines nonresponsive to human IFN alpha. The expression of the cloned IFN alpha R subunit in the human IFN alpha-resistant K-562 cell line restored sensitivity to the antiviral effect of not only IFN alpha 8 but also IFN alpha 2 and IFN alpha Con1. In mouse L-929 cells the expression of the cloned receptor subunit markedly increased antiviral sensitivity to human type I IFNs. In either human K-562 or mouse L-929 cells these effects were observed without a detectable increase in the binding for any of the subtypes of IFN alpha tested. We propose that the cloned IFN alpha R subunit functions as a transducer subunit for the IFN alpha R. This concept is supported by the finding that the cloned receptor protein, when it is expressed in Cos cells, has an M(r) of 75 kDa, which is different from the main IFN alpha-binding proteins, the alpha and beta subunits of the IFN alpha R. This report also suggests that alterations at the receptor level could be involved in IFN alpha resistance in some cell lines.

p135tyk2, an interferon-alpha-activated tyrosine kinase, is physically associated with an interferon-alpha receptor.

Recent genetic studies have linked the tyk2 gene, which encodes a novel type of non-receptor tyrosine kinase, to the interferon-alpha intracellular signaling pathway. In this report, biochemical evidence is presented which supports this proposed function for the tyk2 tyrosine kinase and further defines its role in the interferon-alpha signaling cascade. Specifically, the tyk2 gene is shown to encode a 135-kDa protein which is rapidly phosphorylated on tyrosine in response to interferon-alpha treatment. Indirect evidence suggests that the tyrosine phosphorylation of p135tyk2 is the result of autokinase activity, implying that the Tyk2 tyrosine kinase is activated by interferon-alpha treatment. Two complementary methods demonstrate a physical association between p135tyk2 and the alpha-subunit of the interferon-alpha receptor. First, immunoblots show that monoclonal antibodies against the alpha-subunit of the interferon-alpha receptor can co-immunoprecipitate p135tyk2. Second, interferon-alpha receptor proteins which have been labeled by affinity cross-linking with 125I-interferon-alpha 2 can be co-immunoprecipitated using anti-tyk2 antisera. Taken together, these data suggest that an interferon-alpha receptor-p135tyk2 complex functions, in a manner analogous to the CD4-lck tyrosine kinase complex, to initiate the interferon-alpha signaling cascade.

Interferon alpha (IFN alpha) signaling in cells expressing the variant form of the type I IFN receptor.

Two different Type I interferon receptors (IFN-R) have been described: the normal and the variant receptors. The alpha subunit of the Type I IFN-R has a molecular mass of 110 kDa in cells expressing normal and variant receptors. The beta subunit has a molecular mass of approximately 100 kDa in cells that express normal receptors and 55 kDa in cells expressing the variant form of the receptor. The IFN alpha-resistant U-937 cell line expresses variant receptors and fails to down-regulate and phosphorylate the alpha subunit on tyrosine residues. We report that two other myelomonocytic cell lines, YK-M2 and ML-2, also expressing the variant form of the receptor, fail to down-regulate and phosphorylate the alpha subunit on tyrosine residues. However, YK-M2 and ML-2 cells are sensitive to the antiproliferative and antiviral effects of IFN alpha 2, indicating that phosphorylation of the alpha subunit is not necessary to elicit an IFN alpha response and that expression of variant receptors is not a source of IFN alpha resistance. We also determined if other proteins involved in the IFN alpha signal transduction pathway had a different phosphorylation pattern. Treatment of cells expressing variant receptors induced tyrosine phosphorylation of the p135tyk2 tyrosine kinase, and the three interferon-stimulated gene factor 3 alpha (ISGF3 alpha) polypeptides (p113, p91, and p84), albeit at lower levels. These results indicate that cells expressing either form of the Type I IFN-R phosphorylate a similar set of proteins, with the exception of the alpha subunit.

Identification of a novel subunit of the type I interferon receptor localized to human chromosome 21.

Expression in mouse cells of the cloned human IFN alpha receptor (IFN alpha R) subunit selectively confers response and binding to human IFN alpha 8, indicating that other subunits are involved in IFN alpha binding. We report here that a new monoclonal antibody (mAb), termed IFNaR beta 1, recognizes a novel IFN alpha R subunit different from the one recently cloned and distinct from the alpha subunit recognized by the IFN alpha R3 mAb. The IFNaR beta 1 mAb blocks the biological effect of seven different Type I IFNs. Immunoprecipitations after cell surface iodination demonstrate that the IFNaR beta 1 mAb recognizes a protein with a molecular mass of 100 kDa in Daudi and U-266 cells that express normal IFN alpha R. However, a 55-kDa protein instead of the 100-kDa product was immunoprecipitated in the IFN alpha-resistant U-937 cell line that express the variant form of the receptor. We also demonstrate that the gene that codes for this novel IFN alpha R subunit maps to human chromosome 21, as do the cloned IFN alpha R subunit and the alpha subunit, indicating the existence of a locus on this chromosome that regulates binding for Type I IFNs.

Correlation between interferon (IFN) alpha resistance and deletion of the IFN alpha/beta genes in acute leukemia cell lines suggests selection against the IFN system.

Homozygous and hemizygous deletions of the interferon A (IFNA) and IFNB genes have been frequently observed in acute leukemia cell lines, primary acute leukemia cases, and gliomas. Because IFNs have an antiproliferative effect, selection against the IFN alpha/beta system could play a role or accompany the development of the malignant phenotype. Although the deletion of the IFNA/B genes could interrupt an autocrine loop that controls cell proliferation, cells would still respond to exogenous IFN alpha/beta and, thus, lesions at the receptor or signal transduction level should also be present to render cells resistant to exogenous IFN alpha/beta. To test if selection against the IFN system was operating in acute leukemias, the sensitivity to the antiproliferative effect of IFN alpha 2 was studied in acute leukemia cell lines with and without alterations of the IFNA/B genes. We found that 10 of 11 acute leukemia cell lines with alterations of the IFNA/B genes were resistant to the antiproliferative effect of IFN alpha 2, whereas only two of eight cell lines with normal IFNA/B genes were IFN-resistant. We then examined the possibility that an alteration of the receptor expression could account for the lack of response to IFN alpha 2. No significant alteration in the expression or structure of the IFN alpha receptor was observed. We also studied the downmodulation of the alpha subunit of the IFN alpha receptor upon IFN alpha 2 binding. One cell line with deletion of the IFNA/B genes showed impaired downmodulation of the IFN alpha receptor. The data presented here suggest that selection against the IFN alpha/beta system could play a role or accompany the development of the malignant phenotype.