Crystallization of the complex of human IFN-gamma and the extracellular domain of the IFN-gamma receptor

A complex of human interferon-gamma (IFN-gamma) with the soluble extracellular domain of the IFN-gamma receptor alpha-chain (IFN-gamma-R) has been crystallised. Crystals of the complex were grown using PEG 4000 as the precipitating agent in the presence of beta-octyl glucoside. The receptor-ligand complex crystallizes in a monoclinic space group and diffracts to about 3.0 A resolution. Isomorphous crystals have been obtained with complex containing selenomethionine and cysteine mutants of IFN-gamma, which may facilitate the ongoing X-ray structure determination.

A three-dimensional model of interferon-tau

The interferon-tau (IFN-tau) are type I IFN whose expression is restricted to the embryonic trophectoderm of the developing placenta of ruminant ungulate species, where they act as hormones of pregnancy. Here computer modeling has been used to generate homology models of bovine and ovine IFN-tau based on the refined crystal structure of murine IFN-beta. The IFN-tau structure, like that of MuIFN-beta, is based on five long alpha helices (A-E), one short helix in the middle of the loop connecting helices C and D and a long loop between helices A and B. BoIFN-tau differs from MuIFN-beta in three important respects. First, as in all IFN-tau, there is a carboxyl tail of nine amino acids that cannot be accurately modeled but that would have a length of approximately 30 A when fully extended. Second, like the IFN-alpha subtype, all IFN-tau have a three-amino acid insertion in loop AB and a likely disulfide bridge between Cys29 and Cys139 that lead to marked conformational differences between them and MuIFN-beta in a region (Leu22 to Arg33 in IFN-tau) believed to interact with the receptor. Third, all IFN-tau, as well as the related IFN-omega, possess a Gly at position 126 (rather than the equivalent Arg on MuIFN-beta and IFN-alpha) that will impair an extensive hydrogen bonding interaction between helix D and loop AB. As a result, the polypeptide segment around this region (Phe36 to Gln40) of loop AB is likely to be considerably more flexible than in other type I IFN.

Expression of interferon-gamma receptors on murine oligodendrocytes and its regulation by cytokines and mitogens

Interferon-gamma (IFN-gamma) is a cytokine known to exert an important immunological role on astrocytes and oligodendrocytes. As a receptor for IFN-gamma has been demonstrated on murine astrocytes, we have searched for a specific receptor on the cell surface of pure mouse oligodendrocytes maintained in tissue culture. Using recombinant murine IFN-gamma labelled with 125I, we have established the basic physicochemical parameters of the binding. A single receptor was found with a Kd of 1 x 10(-9) M. The number of receptors per cell was 3000-4000 and its molecular weight, as determined by cross-linking experiments, is 87,000. The binding of IFN-gamma to its oligodendrocyte receptor is saturable, specific and temperature-dependent. The receptor-IFN-gamma complex is quickly endocytosed at 37 degrees (the half-time of maximal internalization is around 1 min). Some cytokines, such as interleukin-1 alpha and interleukin-6, up-regulated the expression of the oligodendrocyte receptor, but others, such as tumour necrosis factor-alpha, did not. A dramatic increase in receptor expression is induced by lipopolysaccharide but it is not detectable after treatment with concanavalin A.

Separate estimation of biological and analytical variance components when quantities and reagents are unstable

A model for reliable estimation of variance components for biological within- and between-subject variation as well as for analytical variation when both the quantity and the reagents are unstable has been established. This model was applied to the alpha-interferon receptor on human leucocytes which involves two major problems. First, the receptor has to be quantified within a few hours after blood sampling, and second, the reagents for the measurement procedure must be used within 2 weeks. For the number of receptors per cell the biological estimates of coefficients of variation were 14% for within-subject variation and 20% for between-subject variation, respectively. For the dissociation constant both estimates were zero as expected. The model is robust and applicable to other systems with unstable quantities and reagents.

Interaction between the components of the interferon gamma receptor complex

Interferon gamma (IFN-gamma) signals through a multimeric receptor complex consisting of two different chains: the IFN-gamma receptor binding subunit (IFN-gamma R, IFN-gamma R1), and a transmembrane accessory factor (AF-1, IFN-gamma R2) necessary for signal transduction. Using cell lines expressing different cloned components of the IFN-gamma receptor complex, we examined the function of the receptor components in signal transduction upon IFN-gamma treatment. A specific IFN-gamma R2:IFN-gamma cross-linked complex was observed in cells expressing both IFN-gamma R1 and IFN-gamma R2 indicating that IFN-gamma R2 (AF-1) interacts with IFN-gamma and is closely associated with IFN-gamma R1. We show that the intracellular domain of IFN-gamma R2 is necessary for signaling. Cells coexpressing IFN-gamma R1 and truncated IFN-gamma R2, lacking the COOH-terminal 51 amino acids (residues 286-337), or cells expressing IFN-gamma R1 alone were unresponsive to IFN-gamma treatment as measured by MHC class I antigen induction. Jak1, Jak2, and Stat1 alpha were activated, and IFN-gamma R1 was phosphorylated only in cells expressing both IFN-gamma R1 and IFN-gamma R2. Jak2 kinase was shown to associate with the intracellular domain of the IFN-gamma R2.

Crystal structure of a complex between interferon-gamma and its soluble high-affinity receptor

The crystal structure of interferon-gamma bound to the extracellular fragment of its high-affinity cell-surface receptor reveals the first view of a class-2 cytokine receptor-ligand complex. In the complex, one interferon-gamma homodimer binds two receptor molecules. Unlike the class-1 growth hormone receptor complex, the two interferon-gamma receptors do not interact with one another and are separated by 27 A. Upon receptor binding, the flexible AB loop of interferon-gamma undergoes a conformational change that includes the formation of a 3(10) helix.

Interferon gamma signals via a high-affinity multisubunit receptor complex that contains two types of polypeptide chain

Signaling by interferon gamma (IFN-gamma) requires two structurally related cell surface proteins: a ligand-binding polypeptide, known as the IFN-gamma receptor (IFN-gamma R), and an accessory factor. However, it is not known whether IFN-gamma forms a ternary complex with the IFN-gamma R and accessory factor to initiate signaling. Here we demonstrate complex formation between IFN-gamma and the two proteins, both in solution and at the cell surface. We observe complexes containing ligand, two molecules of IFN-gamma R (designated the IFN-gamma R alpha chain), and one or two molecules of accessory factor (designated the IFN-gamma R beta chain). Transfected cells expressing both IFN-gamma R chains bind IFN-gamma with higher affinity than do cells expressing alpha chain alone. Anti-beta-chain antibodies prevent the beta chain from participating in the ligand-receptor complex, reduce the affinity for IFN-gamma, and block signaling. Soluble alpha- or beta-chain extracellular domains also inhibit function. These results demonstrate that IFN-gamma signals via a high-affinity multisubunit complex that contains two types of receptor chain and suggest a potential approach to inhibiting specific actions of IFN-gamma by blocking the association of receptor subunits.

Soluble and membrane-anchored forms of the human IFN-alpha/beta receptor

The recently cloned ligand binding component of the type I human interferon-alpha/beta receptor (IFN-alpha/beta R) and its soluble analogue (p40) were characterized. p40 is a potent inhibitor of type I IFNs and antibodies directed against p40 completely block the activity of type I IFNs in human cells. These antibodies immunoprecipitate cellular 102-kDa (major) and 51-kDa (minor) forms of IFN-alpha/beta R. We find that the 51-kDa IFN-alpha/beta R. Two types of cDNA clones were isolated and sequenced, a 1.5-kb cDNA coding for the transmembrane 51-kDa IFN-alpha/beta R and a 4.5-kb cDNA coding for p40. In addition to ligand binding, IFN-alpha/beta R is directly involved in signaling, because it becomes phosphorylated at Tyr residues on ligand binding and it is physically associated with the cytoplasmic tyrosine kinase JAK1.

Development of a receptor peptide antagonist to human gamma-interferon and characterization of its ligand-bound conformation using transferred nuclear Overhauser effect spectroscopy

Polyclonal anti-idiotypic antibody raised to a synthetic discontinuous peptide derived from the human gamma-interferon (huIFN-gamma) sequence recognizes soluble human gamma-interferon receptor (Seelig, G. F., Prosise, W. W., and Taremi, S. S. (1994) J. Biol. Chem. 269, 358-363). We sought to use this reagent to identify a ligand-binding domain within IFN-gamma-receptor. To do this, the neutralizing anti-idiotypic antibody was used to probe overlapping linear peptide octamers of the extracellular domain of the huIFN-gamma receptor. A 22-amino-acid residue receptor segment 120-141 identified by the antibody was synthesized. CD and NMR analysis indicates that peptide 120-141 has no apparent secondary structure in water or in water containing 50% trifluoroethanol. The synthetic receptor peptide inhibited huIFN-gamma induced expression of HLA/DR antigen on Colo 205 cells with an approximate IC50 of 35 microM. Immobilized peptide specifically bound recombinant huIFN-gamma but did not bind human granulocyte-macrophage colony-stimulating factor on a microtiter plate in a direct binding enzyme-linked immunosorbent assay. The binding results are supported by two-dimensional transferred nuclear Overhauser effect (TRNOE) NMR data obtained on the peptide in the presence of recombinant huIFN-gamma. Characterization of the conformation of the bound peptide by TRNOE suggests that this peptide assumes a distinct conformation. Intramolecular interactions within the bound peptide were detected at two non-contiguous regions and at a third region comprising a beta-turn formed by the sequence DIRK. We believe that this represents the structure of the receptor within the ligand-binding domain.

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.

Phosphoric acid entrapment leads to apparent protein heterogeneity

Recombinant proteins produced in prokaryotes or eukaryotes show certain types of heterogeneity due to post-translational modifications. Some preparations of a soluble interferon gamma receptor, produced in Escherichia coli, appeared as a double band with slightly different mobilities in non-reducing sodium dodecylsulfate and native polyacrylamide gels. Ion spray mass spectrometry showed that the two forms had a mass difference of one to three multiples of 97 +/- 2 D. Gas chromatography-mass spectrometry analysis revealed the presence of phosphoric acid in the hydrolysate and in the intact protein. The more slowly migrating protein species had trapped molecules of phosphoric acid during the protein extraction. Most of the trapped phosphoric acid was loosely associated with the protein. One to three molecules were tightly, but non-covalently linked per receptor molecule. Phosphoric acid entrapment did not affect biological activity and most likely did not affect protein conformation. The species carrying phosphoric acid showed higher solubility. Trapping of phosphoric acid by proteins may be a general phenomenon and the results reported here thus useful in the characterization of other recombinant proteins.

Homology model of human interferon-alpha 8 and its receptor complex

Human interferon-alpha 8 (HuIFN alpha 8), a type I interferon (IFN), is a cytokine belonging to the hematopoietic super-family that includes human growth hormone (HGH). Recent data identified two human type I IFN receptor components. One component (p40) was purified from human urine by its ability to bind to immobilized type I IFN. A second receptor component (IFNAR), consisting of two cytokine receptor-like domains (D200 and D200'), was identified by expression cloning. Murine cells transfected with a gene encoding this protein were able to produce an antiviral response to human IFN alpha 8. Both of these receptor proteins have been identified as members of the immunoglobulin superfamily of which HGH receptor is a member. The cytokine receptor-like structural motifs present in p40 and IFNAR were modeled based on the HGH receptor X-ray structure. Models of the complexes of HuIFN alpha 8 with the receptor subunits were built by superpositioning the conserved C alpha backbone of the HuIFN alpha 8 and receptor subunit models with HGH and its receptor complex. The HuIFN alpha 8 model was constructed from the C alpha coordinates of murine interferon-beta crystal structure. Electrostatic potentials and hydrophobic interactions appear to favor the model of HuIFN alpha 8 interacting with p40 at site 1 and the D200' domain of IFNAR at site 2 because there are regions of complementary electrostatic potential and hydrophobic interactions at both of the proposed binding interfaces. Some of the predicted receptor binding residues within HuIFN alpha 8 correspond to functionally important residues determined previously for human IFN alpha 1, IFN alpha 2, and IFN alpha 4 subtypes by site-directed mutagenesis studies. The models predict regions of interaction between HuIFN alpha 8 and each of the receptor proteins, and provide insights into interactions between other type I IFNs (IFN-alpha subtypes and IFN-beta) and their respective receptor components.

Characterization of a domain of a human type I interferon receptor protein involved in ligand binding

Two monoclonal antibodies that recognize different epitopes of the extracellular domain of one of the proteins that constitute the type I interferon receptor were used to delineate the interferon binding site. Antibody 64G12 both inhibits the binding of radiolabeled interferon-alpha 2 and IFN-alpha 8 to their cell surface receptors and neutralizes the antiviral and antiproliferative actions of all the type I interferons tested, including IFN-beta, IFN-omega, and human leukocyte IFN, a mixture of different interferon-alpha isotypes. Antibody 34F10 recognizes the type I interferon receptor with an affinity similar to that of the MAb 64G12 but does not inhibit either the binding or the biologic activity of any of the type I interferons tested. Both antibodies recognize a protein of 105 +/- 5 kD from either Daudi or Ly28 cells. Immunoprecipitation following surface iodination demonstrated that the neutralizing MAb recognizes a protein of 105 kD and the nonneutralizing MAb a protein of 110 kD in extracts of Daudi cells. A second less intense band was also detected by both antibodies. Cross-linking of IFN-alpha 2 to its receptor before immunoprecipitation prevented the neutralizing antibody from immunoprecipitating the receptor protein, but the nonneutralizing MAb was still able to recognize a 140 kD protein corresponding to the cross-linked interferon-receptor protein complex. Thus, an interferon binding domain appears to be localized in a region between amino acids 23 and 229 of the extracellular domain of a transmembrane protein that forms part of the type I interferon receptor complex containing the epitopes recognized by each antibody.

Dissection of the extracellular human interferon gamma receptor alpha-chain into two immunoglobulin-like domains. Production in an Escherichia coli thioredoxin gene fusion expression system and recognition by neutralizing antibodies

The extracellular interferon gamma receptor alpha-chain (IFN gamma R) is believed to comprise two discrete approximately 110 amino acid immunoglobulin-like domains, perhaps similar to those seen in the crystal structure of the extracellular human growth hormone receptor [De Vos, A. M., Ultsch, M., & Kossiakoff, A. (1992) Science 255, 306-312], a distant relative in the cytokine receptor superfamily. In accord with this idea, we show that these IFN gamma R immunoglobulin-like domains can be produced separately in a soluble form with a native-like fold. The N-terminal domain (residues 1-108), with a Cys105 to Ser105 mutation, was produced at a high level, in a soluble form, as a thioredoxin-interferon gamma receptor fragment fusion protein in the cytoplasm of Escherichia coli. Upon extraction, the receptor Cys60-Cys68 disulfide bond formed spontaneously, to generate a native-like structure directly without the need for refolding. Cleavage of the fusion protein by enterokinase released the receptor fragment (approximately 12 kDa), which was recognized by several neutralizing antibodies with affinities, measured using surface plasmon resonance technology, that were essentially indistinguishable from those seen with the full length extracellular IFN gamma R produced in eukaryotic cells. Circular dichroism and 1D 1H nuclear magnetic resonance spectra indicated that the receptor fragment adopts a folded state, with mainly beta-sheet and reverse turn secondary structure. The second membrane-proximal Ig-like domain of the IFN gamma R (residues 90-229) was produced, albeit less efficiently, and characterized in a similar way. The production of these two independently folded proteins provides experimental support for the two domain organization of the IFN gamma R and opens new avenues for structural studies on these Ig-like molecules by NMR and crystallographic methods.

Human type I interferons: structure and function

Human type I interferons (IFNs) comprise a family of 13 IFN-alpha subtypes and single species of IFN-beta and IFN-omega. Their 20% overall sequence homology determines identical secondary and tertiary folding of polypeptides. Three-dimensional models suggest that the globular structure of type I IFNs consists of a bundle of 5 alpha-helices, which might form two polypeptide domains. Disulfide bond Cys 29-Cys 139 stabilizes both domains in a bioactive configuration. The IFN molecule exerts its functional entity only as an organic polypeptide complex and therefore molecular fragments apparently lack biological activity. IFN-beta, IFN-omega and some IFN-alpha subtypes are glycoproteins, but the sugar moiety was found to be neither structurally nor functionally relevant. Type I IFNs share a common cellular receptor, a fact that implies a high structural conservativity of their receptor-binding areas. Two conservative hydrophilic regions associated with the amino acids (aa) 30-41 and 120-145 appear to constitute the basic framework of receptor recognition site in type I IFNs. However, the individual IFN-(sub)types induce different spectra of biological effects which reflect some specificity in modelling of binding sites. Besides a subtle sequential heterogeneity in the segments aa 30-41 and 120-145, also the variable hydrophilic aa regions 23-26, 68-85 and 112-121 are responsible for structural and functional individuality among human type I IFNs. The interaction between IFN and its receptor seems to be a complex event which triggers simultaneously antiviral, antiproliferative and immunomodulating actions, although different parts of IFN molecule are not involved equally in eliciting of respective basal activities.

Identification of the factor VIIa binding site on tissue factor by homologous loop swap and alanine scanning mutagenesis

Tissue factor (TF) is a membrane-bound glycoprotein that functions as a cofactor for coagulation factor VIIa (VIIa) and initiates blood coagulation at sites of vascular injury. On the basis of sequence alignments, TF was predicted to be a member of the cytokine receptor superfamily. Utilizing the structural information available for the cytokine receptor superfamily, we have used site-directed mutagenesis to identify the binding site on TF for VIIa. The predicted loop regions in TF were systematically replaced with the homologous loops from the gamma-interferon receptor (gamma-IFN-R), the protein most related to TF in the superfamily of cytokine receptors. Six discontinuous regions (residues 16-20, 40-46, 60-69, 101-111, 129-151, 193-207) were identified that are required for interaction with VIIa and enhancement of activity. Individual substitution of 68 residues within these loops with alanine revealed eight residues (K20, D44, W45, K46, Q110, R135, F140, V207) that are required for cofactor activity. These residues fall into two groups, those that are required only for interactions with VIIa (K46, Q110, R135, F140, V207) and those that are also required to induce the conformational change in VIIa required for enhanced activity (K20, D44, W45). The discontinuous regions of TF required for interactions with VIIa form a single binding surface for VIIa that is analogous to the interface defined by the crystal structure of the complex between growth hormone and its receptor.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

Evidence for glycosphingolipid modification of the type 1 IFN receptor

P1-determinant glycolipids that include two membrane glycosphingolipids, globotriaosylceramide (Gal alpha 1-4Gal beta 1-4Glc-ceramide, Gb3) and galabiosylceramide (Gal alpha 1-4Gal-ceramide, Gb2) are receptors for an Escherichia coli-derived subunit toxin, verotoxin (VT-1). Studies with Daudi cells and glycosphingolipid-deficient Daudi mutants and U937 cells identified that the presence of Gb2/Gb3 correlates with IFN-alpha sensitivity. Comparison of amino acid sequences between VT-1 and the extracellular region of the 63-kDa IFN-alpha beta receptor (IFNAR) peptide reveals regions of identity, specifically in those domains in the VT-1 B subunit, that have been implicated as Gb2/Gb3 binding sites. In direct ligand binding studies, we show that membrane Gb2/Gb3 content affects the binding capacity of cells for IFN-alpha, although IFNAR cell surface expression is unaffected. Binding of IFN-alpha to the receptor leads to kinase-associated phosphorylation of the latent transcription factor, ISGF3, which activates transcription by binding to IFN-stimulated regulatory elements in IFN-sensitive genes. Electrophoretic mobility band shift assays indicated that U-937 and Daudi mutant cells, deficient in Gb2 and Gb3, exhibited reduced nuclear factor binding to the human 2-5A synthetase IFN-stimulated regulatory element when compared with wild-type Daudi cells, after exposure to IFN-alpha. Moreover, when Daudi cells were treated with a ceramide analogue, 1-phenyl-2-(decanoylamino)-3-morpholino-1-propanol, Gb2 and Gb3 synthesis was inhibited and a concomitant reduction in IFN-induced ISGF3 activation was noted. IFNAR cell surface expression was unaffected by 1-phenyl-2-(decanoylamino)-3-morpholino-1-propanol treatment. By using a fusion protein of the extracellular domain of IFNAR linked at the carboxyl terminus to the Fc portion of IgG1, we demonstrate that IFNAR is able to bind preferentially to Gb2. These results suggest that an association of IFNAR with membrane Gal alpha 1-4Gal containing glycolipids facilitates receptor-mediated signaling.

Role of interferon alpha/beta receptor chain 1 in the structure and transmembrane signaling of the interferon alpha/beta receptor complex

A previously cloned cDNA encodes one subunit of the human interferon alpha/beta receptor (IFN alpha R), denoted IFN alpha R1. To study the expression and signaling of IFN alpha R1, we used monoclonal antibodies (mAbs) generated against the baculovirus-expressed ectodomain of IFN alpha R1. Immunoprecipitation and immunoblotting of lysates from a variety of human cell lines showed that IFN alpha R1 has an apparent molecular mass of 135 kDa. Binding analysis with 125I-labeled mAb demonstrated high levels of cell surface expression of IFN alpha R1 in human cells and in mouse cells transfected with IFN alpha R1 cDNA, whereas no cross-reactivity was observed in control mouse L929 cells expressing only the endogenous mouse receptor. The subunit was rapidly down-regulated by IFN alpha (80% decrease within 2 hr) and degraded upon internalization. The IFN alpha R1 chain appeared to be constitutively associated with the 115-kDa subunit of the IFN alpha/beta receptor, since the mAbs coprecipitated this protein. IFN alpha/beta treatment induced tyrosine phosphorylation of IFN alpha R1 within 1 min, with kinetics paralleling that of the IFN-activated protein-tyrosine kinases Jak1 and Tyk2. Ligand-induced tyrosine phosphorylation of IFN alpha R1 was blocked by the kinase inhibitors genistein or staurosporine. Although IFN alpha R1 cDNA-transfected mouse cells expressed high levels of this subunit when compared with empty vector-transfected cells the number of binding sites for human IFN alpha (50-75 sites per cell) was not increased. Human IFN alpha induced the expression of a mouse IFN alpha/beta-responsive gene (the 204 gene) in mouse L929 cells transfected with the IFN alpha R1 cDNA, but not in mock-transfected cells. These results suggest that the IFN alpha R1 subunit acts as a species-specific signal transduction component of the IFN alpha/beta receptor complex.

Tyrosine phosphorylation of the alpha and beta subunits of the type I interferon receptor. Interferon-beta selectively induces tyrosine phosphorylation of an alpha subunit-associated protein

We studied the phosphorylation of the alpha and beta subunits of the Type I interferon (IFN) receptor induced by Type I IFNs in the human U-266 and MOLT-4 cell lines. Both IFN-alpha and IFN-beta induced tyrosine phosphorylation of the beta subunit of the receptor. The Type I IFN-induced tyrosine phosphorylation of the beta subunit was rapid and transient, being detectable within 1 min of Type I IFN treatment and gradually diminishing to almost base-line levels by 60 min. All Type I IFNs studied were found to induce tyrosine phosphorylation of the alpha subunit of the Type I IFN receptor, the p135tyk2 and JAK-1 tyrosine kinases, and the ISGF3 alpha components. Interestingly, IFN-beta, but not IFN-alpha or IFN-omega, induced tyrosine phosphorylation of an alpha subunit-associated protein with an apparent molecular mass of approximately 100 kDa (p100). These data suggest the existence of a common signaling pathway(s) for Type I IFNs involving the alpha and beta subunits of the receptor, the tyrosine kinases p135tyk2 and JAK-1, and the ISGF3 alpha components. However, differences between the signaling pathways of different Type I IFNs exist, as suggested by tyrosine phosphorylation of an alpha subunit-associated protein only in response to IFN-beta.

The interferon-gamma receptor extracellular domain. Non-identical requirements for ligand binding and signaling

The human interferon-gamma receptor (hIFN-gamma R) extracellular domain interacts in a species-specific manner with both its ligand and an accessory factor encoded on human chromosome 21. Mutant interferon-gamma receptors were constructed by homolog-scanning mutagenesis, replacing segments of the human extracellular domain with the corresponding murine sequence. Replacement of hIFN-gamma R amino acids 1-100, 100-132, 134-183, or 183-245 abolished binding to human interferon-gamma (hIFN-gamma). However, replacement of hIFN-gamma R amino acids 134-209, 183-209, 134-153, 153-167, or 167-183 or deletion of residues 156-165 affected hIFN-gamma binding only partially or not at all. Receptors that bound hIFN-gamma were tested for their ability to signal a functional response, induction of major histocompatibility complex class I antigen expression. Replacement of residues 134-209 greatly reduced the ability of the receptor to signal. This signaling defect could not be attributed solely to a reduction in affinity for ligand and could not be localized to any subregion.