The extracellular domain of the human interferon gamma receptor interacts with a species-specific signal transducer

Deregulation of interferon-gamma receptor 1 expression and its implications for lung adenocarcinoma progression

Interferon-gamma (IFN-γ) plays a dual role in cancer; it is both a pro- and an antitumorigenic cytokine, depending on the type of cancer. The deregulation of the IFN-γ canonic pathway is associated with several disorders, including vulnerability to viral infections, inflammation, and cancer progression. In particular, the interplay between lung adenocarcinoma (LUAD) and viral infections appears to exist in association with the deregulation of IFN-γ signaling. In this mini-review, we investigated the status of the IFN-γ signaling pathway and the expression level of its components in LUAD. Interestingly, a reduction in IFNGR1 expression seems to be associated with LUAD progression, affecting defenses against viruses such as severe acute respiratory syndrome coronavirus 2. In addition, alterations in the expression of IFNGR1 may inhibit the antiproliferative action of IFN-γ signaling in LUAD.

Noncanonical IFN Signaling, Steroids, and STATs: A Probable Role of V-ATPase

A small group of only seven transcription factors known as STATs (signal transducer and activator of transcription) are considered to be canonical determinants of specific gene activation for a plethora of ligand/receptor systems. The activation of STATs involves a family of four tyrosine kinases called JAK kinases. JAK1 and JAK2 activate STAT1 in the cytoplasm at the heterodimeric gamma interferon (IFNγ) receptor, while JAK1 and TYK2 activate STAT1 and STAT2 at the type I IFN heterodimeric receptor. The same STATs and JAKs are also involved in signaling by functionally different cytokines, growth factors, and hormones. Related to this, IFNγ-activated STAT1 binds to the IFNγ-activated sequence (GAS) element, but so do other STATs that are not involved in IFNγ signaling. Activated JAKs such as JAK2 and TYK2 are also involved in the epigenetics of nucleosome unwrapping for exposure of DNA to transcription. Furthermore, activated JAKs and STATs appear to function coordinately for specific gene activation. These complex events have not been addressed in canonical STAT signaling. Additionally, the function of noncoding enhancer RNAs, including their role in enhancer/promoter interaction is not addressed in the canonical STAT signaling model. In this perspective, we show that JAK/STAT signaling, involving membrane receptors, is essentially a variation of cytoplasmic nuclear receptor signaling. Focusing on IFN signaling, we showed that ligand, IFN receptor, the JAKs, and the STATs all undergo endocytosis and ATP-dependent nuclear translocation to promoters of genes specifically activated by IFNs. We argue here that the vacuolar ATPase (V-ATPase) proton pump probably plays a key role in endosomal membrane crossing by IFNs for receptor cytoplasmic binding. Signaling of nuclear receptors such as those of estrogen and dihydrotestosterone provides templates for making sense of the specificity of gene activation by closely related cytokines, which has implications for lymphocyte phenotypes.

The antineoplastic agent bryostatin-1 differentially regulates IFN-gamma receptor subunits in monocytic cells: transcriptional and posttranscriptional control of IFN-gamma R2

Bryostatin-1 (Bryo-1) is a potent ligand and modulator of protein kinase C that exerts antineoplastic and immunomodulatory activities both in vitro and in vivo. We have previously reported that Bryo-1 synergized with IFN-gamma to induce NO synthase and NO by macrophages. To determine whether this effect was associated with changes in levels of IFN-gammaR, we investigated the effects of Bryo-1 on the expression and regulation of IFN-gammaR chains in monocytic cells. Northern blot analysis revealed that Bryo-1 treatment of the human monocytic cell lines MonoMac6 and THP-1 and human monocytes enhanced the expression of IFN-gammaR2 mRNA but did not affect IFN-gammaR1 mRNA expression. Bryo-1 increased IFN-gammaR2 mRNA in a dose-dependent manner as early as 3 h posttreatment. Bryo-1-induced up-regulation of IFN-gammaR2 mRNA levels is not dependent on de novo protein synthesis as shown by cell treatment with the protein-synthesis inhibitor cycloheximide. Bryo-1 treatment increased the IFN-gammaR2 mRNA half-life by 2 h. EMSA analysis from Bryo-1-treated MonoMac6 cells showed an increased nuclear protein binding to the NF-kappaB motif present in the 5' flanking region of the human IFN-gammaR2 promoter that was markedly decreased by pretreatment with the NF-kappaB inhibitor SN50. These results show for the first time that Bryo-1 up-regulates IFN-gammaR2 expression in monocytic cells. Given the pivotal role that IFN-gamma exerts on monocyte activation and in the initiation and outcome of the immune response, the induction of IFN-gammaR2 by Bryo-1 has significant implications in immunomodulation and could overcome some of the immune defects observed in cancer patients.

Preassembly and ligand-induced restructuring of the chains of the IFN-gamma receptor complex: the roles of Jak kinases, Stat1 and the receptor chains

We previously demonstrated using noninvasive technologies that the interferon-gamma (IFN-gamma) receptor complex is preassembled (1). In this report we determined how the receptor complex is preassembled and how the ligand-mediated conformational changes occur. The interaction of Stat1 with IFN-gammaR1 results in a conformational change localized to IFN-gammaR1. Jak1 but not Jak2 is required for the two chains of the IFN-gamma receptor complex (IFN-gammaR1 and IFN-gammaR2) to interact; however, the presence of both Jak1 and Jak2 is required to see any ligand-dependant conformational change. Two IFN-gammaR2 chains interact through species-specific determinants in their extracellular domains. Finally, these determinants also participate in the interaction of IFN-gammaR2 with IFN-gammaR1. These results agree with a detailed model of the IFN-gamma receptor that requires the receptor chains to be pre-associated constitutively for the receptor to be active.

Interferon-gamma: an overview of signals, mechanisms and functions

Interferon-gamma (IFN-gamma) coordinates a diverse array of cellular programs through transcriptional regulation of immunologically relevant genes. This article reviews the current understanding of IFN-gamma ligand, receptor, signal transduction, and cellular effects with a focus on macrophage responses and to a lesser extent, responses from other cell types that influence macrophage function during infection. The current model for IFN-gamma signal transduction is discussed, as well as signal regulation and factors conferring signal specificity. Cellular effects of IFN-gamma are described, including up-regulation of pathogen recognition, antigen processing and presentation, the antiviral state, inhibition of cellular proliferation and effects on apoptosis, activation of microbicidal effector functions, immunomodulation, and leukocyte trafficking. In addition, integration of signaling and response with other cytokines and pathogen-associated molecular patterns, such as tumor necrosis factor-alpha, interleukin-4, type I IFNs, and lipopolysaccharide are discussed.

An anti-idiotypic antibody with an internal image of human interferon-gamma and human interferon-gamma-like antiviral activity

D9D10, a monoclonal antibody that inhibits the biological activity of human interferon-gamma (IFN-gamma), was used to generate monoclonal anti-idiotypic antibodies. After a first selection, the monoclonal anti-idiotypic antibody AA1E5 was chosen to be fully characterized. To the best of our knowledge this is the first description of a monoclonal antibody with an IFN-gamma-like antiviral activity; AA1E5 competed with IFN-gamma for binding to D9D10 indicating its anti-idiotypic character. However, AA1E5 also fully mimics HuIFN-gamma as it not only binds to the HuIFN-gamma-receptor, where it competes with HuIFN-gamma, but more importantly AA1E5 and its Fv fragment, cloned and expressed in Escherichia coli, mimic the antiviral activity of HuIFN-gamma. Indeed, 15 microg of AA1E5 and 2.5 microg of its Fv fragment had an effect comparable to that of 10 IU of HuIFN-gamma in an antiviral assay on A549 cells. Sequence comparison between the complementarity determination regions of the antibody and the sequence of HuIFN-gamma revealed that both the heavy chain variable domain, VH, and the kappa light chain variable domain, Vkappa, have epitopes of 3-4 amino acids that are present in the HuIFN-gamma sequence, some of which contribute to receptor binding, as identified by Walter et al. [M. R. Walter, W. T. Windsor, T. L. Nagabhushan, D. J. Lundell, C. A. Lunn, P. J. Zauodny & S. K. Narula (1995) Nature 376, 230-235].

The human interferon alpha species and receptors

Interferon (IFN) was approved by the U.S. Food and Drug Administration on June 5, 1986. As the first biotherapeutic approved, IFN-alpha paved the way for development of many other cytokines and growth factors. Nevertheless, we have just touched the surface of understanding the multitude of human IFNs. This paper reviews the history of the purification of human leukocyte IFN and key aspects of our current state of knowledge of human interferon alpha genes, proteins, and receptors.

Surface redistribution of interferon gamma-receptor and its colocalization with the actin cytoskeleton

BACKGROUND

Specific antibodies for human IFN gamma-R1 were used to examine its mobilization in Colo 205 cells.

METHODS

We report here that antibody-IFN gamma-R1 complex induced capping and actin colocalization. Pretreatment with cytochalasin D abolished this capping. To define the role of the IFN gamma-R1 in the possible interaction with actin, transfected murine fibroblasts cell line with human cDNA IFN gamma-R1 were used.

RESULTS

Only those cells expressing the full receptor and cultured in suspension polarized the receptor and this colocalized with actin filaments. Nevertheless, cells truncated in their intracellular domain displayed no capping and actin remained unaltered either in suspension or in monolayer culture conditions. A mutant bearing an IFN gamma-R1 with substitutions in positions 270-271 of the intracellular domain redistributed both IFN gamma-R1 and actin as micropatches instead of capping. Mutation in 256-303 residues resulted in IFN gamma-R1 microaggregates but actin remained unchanged.

CONCLUSIONS

These experimental models allowed us to highlight an apparent receptor-microfilament association through the intracellular domain of IFN gamma-R1, and to specifically locate it within the intracellular region 256-303 that has been identified as relevant for ligand-receptor internalization and biological function.

The interferon gamma (IFN-gamma) receptor: a paradigm for the multichain cytokine receptor

With the purification and cloning of the interferon gamma (IFN-gamma) receptor chains the mechanism of IFN-gamma action and the resultant signal transduction events were delineated in remarkable detail. The interferon gamma (IFN-gamma) receptor complex consists of two chains: IFN-gammaR1, the ligand-binding chain, and IFN-gammaR2, the accessory chain. Binding of IFN-gamma causes oligomerization of the two IFN-gamma receptor subunits, IFN-gammaR1 and IFN-gammaR2, which initiates the signal transduction events: activation of Jak1 and Jak2 receptor associated protein tyrosine kinases, phosphorylation of the IFN-gammaR1 intracellular domain on Tyr440 followed by phosphorylation and activation of Stat1alpha, the latent transcriptional factor. With all these steps established, the IFN-gamma receptor complex has provided the basic model for understanding the receptors for other members of the family of class II cytokine receptors.

Chimeric erythropoietin-interferon gamma receptors reveal differences in functional architecture of intracellular domains for signal transduction

Binding of interferon gamma (IFN-gamma) causes oligomerization of the two interferon gamma receptor (IFN-gammaR) subunits, receptor chain 1 (IFN-gammaR1, the ligand-binding chain) and the second chain of the receptor (IFN-gammaR2), and causes activation of two Jak kinases (Jak1 and Jak2). In contrast, the erythropoietin receptor (EpoR) requires only one receptor chain and one Jak kinase (Jak2). Chimeras between the EpoR and the IFN-gammaR1 and IFN-gammaR2 chains demonstrate that the architecture of the EpoR and the IFN-gammaR complexes differ significantly. Although IFN-gammaR1 alone cannot initiate signal transduction, the chimera EpoR/gammaR1 (extracellular/intracellular) generates slight responses characteristic of IFN-gamma in response to Epo and the EpoR/gammaR1. EpoR/gammaR2 heterodimer is a fully functional receptor complex. The results demonstrate that the configuration of the extracellular domains influences the architecture of the intracellular domains.

Natural antibodies to interferon-gamma

Natural antibodies to interferon (IFN)-gamma were detected in the serum of virus-infected patients and also, at a low titre, in the serum of healthy subjects. The increased titre of antibodies to IFN-gamma in the sera of virus-infected patients, and its decrease with clinical resolution, indicate that these antibodies are related to viral infection and probably reflect IFN-gamma production as a result of antigenic stimulation in vivo. Natural antibodies to IFN-gamma were affinity purified and studied for their capability to interfere in vitro with the multiple activities of the lymphokine. Data obtained show that these human anti-IFN-gamma antibodies have no inhibitory effect on the antiviral and antiproliferative activity of IFN-gamma and do not interfere with the binding of the lymphokine to its specific cell receptor. Instead, they can inhibit the expression of HLA-DR antigens induced by IFN-gamma on U937 cells and interfere, in mixed lymphocyte culture, with the proliferation of lymphocytes and the generation of cytotoxic lymphocytes. Experiments in animal models suggest that natural antibodies to IFN-gamma may have a role in the immunoregulatory process limiting the intensity and/or duration of immune response. As they can interfere only with the immunomodulating activities of IFN-gamma, these antibodies might open up new therapeutic approaches to diseases with evidence of activated cell-mediated immunity.

Mouse macrophages carrying both subunits of the human interferon-gamma (IFN-gamma) receptor respond to human IFN-gamma but do not acquire full protection against viral cytopathic effect

Studies of hamster-human and mouse-human somatic fibroblast hybrids and transfected mouse fibroblasts have demonstrated that signaling through the human interferon-gamma receptor (hu-IFN-gammaR) requires the formation of a complex consisting of ligand (IFN-gamma), a ligand binding receptor chain (IFN-gammaR1), and a signal transducing receptor chain (IFN-gammaR2). To date, the ability of this receptor complex to transduce the full repertoire of biological signals has been difficult to assess due to the limited number of activities that IFN-gamma can exert on fibroblasts. The current report assesses the ability of hu-IFN-gammaR chains to transduce signals in the absence of background human gene products by expressing hu-IFN-gammaR2 in a transformed macrophage cell line (F10/96) derived from a hu-IFN-gammaR1 transgenic mouse. Our results indicate that F10/96 clones expressing both human receptor proteins bind hu-IFN-gamma with an affinity comparable to that of human cells. Binding of either human or mouse IFN-gamma to its respective receptor elicits classic IFN-gamma responses such as up-regulation of major histocompatibility complex antigens, enhanced expression of IRF-1, and increased production of NO2- radicals, interleukin-6, tumor necrosis factor-alpha, and granulocyte macrophage-colony stimulating factor. However, hu-IFN-gamma could not fully protect the clones from cytopathic effects of encephalomyocarditis virus and vesicular stomatitis virus while mo-IFN-gamma could. These results demonstrate that while co-expression of hu-IFN-gammaR1 and hu-IFN-gammaR2 is necessary and sufficient for most IFN-gamma-induced responses, it is not sufficient to confer a generalized antiviral state. These findings further suggest that additional species-specific accessory factor(s) are necessary for full signaling potential through the IFN-gamma receptor complex. The nature and potential role of such factors in IFN-gammaR signaling is discussed.

The intracellular domain of the second chain of the interferon-gamma receptor is interchangeable between species

In this report we show that the mouse interferon (IFN)-gamma R1 and IFN-gamma R2 subunits expressed in hamster cells are capable of rendering the cells sensitive to mouse IFN-gamma as measured by induction of class I MHC antigens and the activation of the transcription factor Stat1 alpha. However, these cells showed no antiviral protection in response to IFN-gamma when challenged with vesicular stomatitis virus (VSV) but limited protection when challenged with encephalomyocarditis virus (EMCV). Furthermore, the cytoplasmic domains of the IFN-gamma R2 subunits, like the cytoplasmic domains of the IFN-gamma R1 chains, can be interchanged between species with no loss of biologic activity, demonstrating that the species-specific interaction of the IFN-gamma R1 and IFN-gamma R2 chains involves only the extracellular domains of the two proteins.

T-lymphocyte immunointerferon receptors in patients with multiple sclerosis

Multiple sclerosis (MS) is a T-cell-mediated autoimmune demyelinating disease of the central nervous system (CNS), associated with an altered immunoregulation. Interferon (IFN)-gamma, also known as immune IFN, is a cytokine with several effects on the immune system. Specific IFN-gamma receptors have been found on human lymphocytes, as well as on other cell types (e.g. gliocytes), even in the CNS. The aim of the present study was to evaluate IFN-gamma binding on peripheral blood T-lymphocytes from MS patients, compared with those from healthy subjects. Thirty-two patients were selected according to the classical criteria for definite MS; as controls, 21 healthy subjects were studied. We have found that T-lymphocytes from MS patients bear a significantly smaller amount of IFN-gamma receptors than those from controls [Bmax: 568, 18 vs 708, 14 (mean, SE) receptors/ cell]. Such IFN-gamma binding sites are of the same type in patients and healthy subjects [Kd: 1.0, 0.05 vs 0.9, 0.02 (mean, SE) nM]. These findings are discussed in terms of immunopathogenesis of MS, since it has been reported that activated T-lymphocytes have decreased amounts of IFN-gamma receptors.

Variable region cDNA sequences and characterization of murine anti-human interferon gamma receptor monoclonal antibodies that inhibit receptor binding by interferon gamma

Murine monoclonal antibodies (mAbs) are described that recognize the extracellular human interferon gamma receptor alpha-chain (IFN gamma R) and inhibit the binding to it of interferon gamma. The inhibitory activities (IC50s) of these mAbs, quantified by radioimmunoassay using native receptor on human Raji cells, lie in the range 0.5-24 nM, whereas their relative affinities for the immobilised recombinant extracellular receptor, determined using surface plasmon resonance technology, are in the range 0.6-40.9 nM. Nine mAbs derived from one immunization, were shown by variable region cDNA sequencing to be clonally related, with mAb A6 from this group showing the highest affinity for the receptor. Another two mAbs, gamma R38 and gamma R99, derived from a separate immunization, are clonally unrelated to each other and to those in the A6 family. From the V-region sequences, the L-chains of mAbs A6, gamma R38 and gamma R99 were shown to belong to the V kappa 34C, V kappa 34C and V kappa 1 families, whereas the H-chains belong to the 3069, J606 and J558 families, respectively. The mAbs A6 and gamma R38 recognize overlapping epitopes on the N-terminal Ig-like domain of the IFN gamma R, whereas the gamma R99 epitope is located largely in the membrane proximal Ig-like domain. Sequence comparisons with Ig structures solved by X-ray diffraction allowed deductions concerning likely CDR canonical conformations. These studies provide essential information for crystallographic and mutagenesis experiments aimed at understanding the molecular basis of the interactions of these mAbs with the extracellular IFN gamma R.

A generic method for expression and use of "tagged" soluble versions of cell surface receptors

A general method for expression, purification, immobilization, detection and radiolabeling of extracellular domains (ECD) of type I membrane proteins. The type I interleukin-1 receptor (IL-1RtI), the alpha-subunit of interleukin-2 receptor (IL-2R alpha) and E-selectin are used as illustrative examples of cell surface receptors. DNA encoding the ECD of the proteins are fused at their 3' end to a chimeric DNA which serves to generically "tag" the recombinant ECD. The resulting fusion protein contains a substrate sequence for protein kinase-A (PKA) adjacent to the signal sequence from human placental alkaline phosphatase (HPAP), The HPAP signal sequence directs the formation of the phosphatidylinositol-glycan (PI-G) anchorage of the protein at the cell surface. When these chimeric genes are expressed in CHO cells, the ECDs are detected on the cell surface and can be released by treatment with phosphatidylinositol-specific phospholipase-C (PI-PLC). Based on protein processing known to occur for native HPAP, twenty amino acids from the HPAP signal sequence remain at the C-terminus of the ECD. A high affinity monoclonal antibody was generated against this common epitope. This antibody can be used to detect, purify and immobilize the ECDs. In addition, the ECDs can be radiolabeled with 32P by treatment with PKA and maintain the ability to bind their natural ligands. This "tagging" method has been successfully applied to many other type I proteins which serve as cell surface receptors.

Configuration of the interferon-alpha/beta receptor complex determines the context of the biological response

Constituents of the Type 1 interferon (IFN) receptor (IFNABR) identified to date include the alpha and beta transmembrane subunits and the associated intracellular kinases, Jak 1 and Tyk 2. In this report, we demonstrate that a human cell type that expresses both subunits of IFNABR, together with Jak 1 and Tyk 2, exhibits a limited binding capacity for and is only partially sensitive to the effects of IFN-alpha/beta, despite adequate levels of the cytoplasmic transcription factors Stat1, Stat2, and Stat3. Specifically, a low affinity interaction between IFN-alpha/beta and cell surface receptors results in ISGF3 (Stat1:2) activation and an antiviral response, yet no IFN-inducible growth inhibition. Using a panel of murine cells that are variably configured with respect to the human IFNABR-alpha/beta subunits, we provide evidence that an additional component(s) encoded on human chromosome 21 is required to confer high affinity binding and IFN-inducible growth inhibition to cells that express the alpha and beta subunits of the IFNABR. The data indicate that transcriptional activation that leads to an antiviral response is mediated by IFN-alpha/beta activation of IFNABR-alpha and IFNABR-beta in the context of a low affinity interaction, yet a high affinity interaction is necessary for signal transducing events that mediate growth inhibition. We provide evidence that the extent of ISGF3 activation correlates directly with the magnitude of an antiviral but not a growth inhibitory response.

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.

The Jak kinases differentially associate with the alpha and beta (accessory factor) chains of the interferon gamma receptor to form a functional receptor unit capable of activating STAT transcription factors

Interferon gamma (IFN gamma) induces the expression of early response genes by tyrosine phosphorylation of Jak kinases and transcription factors referred to as STAT proteins. The topology of the IFN gamma receptor is partially understood and the relationship between the alpha chain that binds the ligand and the beta chain that is required for signal transduction is undefined. In a cell line which expresses only the human alpha chain, we show that these cells did not activate Jak kinases or STAT proteins with human IFN gamma, even though Jak1 co-immunoprecipitated with the alpha chain. In cells unexposed to IFN gamma, Jak1 preferentially associated with the alpha chain, while Jak2 associated with the beta chain. There was evidence for Jak1 kinase activity in untreated cells. For Jak2, kinase activity was IFN gamma-dependent. Although the alpha chain was tyrosine-phosphorylated in response to ligand, we found no evidence for tyrosine phosphorylation of the beta chain. These data are consistent with a model of the IFN gamma receptor in which Jak1 associates with the alpha chain, whereas Jak2 associates with the beta chain. IFN gamma clusters at least two receptor units which results in the tyrosine phosphorylation of Jak1 and Jak2, the activation of Jak2 kinase activity, and the recruitment of STAT1 alpha resulting in its activation by tyrosine phosphorylation.

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.

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.

Interferon gamma receptor extracellular domain expressed as IgG fusion protein in Chinese hamster ovary cells. Purification, biochemical characterization, and stoichiometry of binding

Agents that antagonize the functions of interferon gamma (IFN gamma) are potential pharmaceuticals against several immunological and inflammatory disorders. IFN gamma receptor-immunoglobulin G fusion proteins (IFN gamma R-IgG) function as antagonists of endogenous IFN gamma and have longer half-lives in vivo in comparison with soluble IFN gamma receptors (sIFN gamma R), consisting of the extracellular region of the native sequence. A fusion protein comprising the extracellular domain of the human IFN gamma receptor and the hinge, CH2 and CH3 domains of the human IgG3 constant region, was expressed in Chinese hamster ovary cells. The IFN gamma R-IgG3 fusion protein was secreted into the culture medium as a 175-kDa glycoprotein and was purified over Protein G-Sepharose, DEAE-Sepharose, and size exclusion chromatography. IFN gamma R-IgG3 bound IFN gamma in solid phase assays and ligand blots, competed for the binding of radiolabeled IFN gamma to the cell surface receptor of Raji cells, and inhibited the IFN gamma-mediated antiviral activity with an efficiency at least one order of magnitude higher than that of the soluble receptor produced in the same expression system. Two IFN gamma R-IgG3 fusion proteins bound two IFN gamma dimers forming a complex of approximately 380 kDa. In immunodiffusion assays, the IFN gamma R-IgG3 fusion protein did not precipitate IFN gamma. Dissociation of bound IFN gamma from IFN gamma R-IgG3 was 2-fold slower than from the sIFN gamma R produced in insect cells.

Structural elements required for receptor recognition of human interferon-gamma

Interferon (IFN)-gamma is a central factor in numerous immune responses. Recently the three-dimensional structure of human and rabbit IFN-gamma has been elucidated. This review attempts to bring together the structure and function information into a working model of IFN-gamma: receptor interaction. Based on mutagenesis studies, and corroborated by work with peptides, antibodies and proteolytic digestion, three regions have been found to be important for receptor binding: a long loop connecting the A and B helices, His111 in the F helix and a conserved section of the flexible carboxyl terminus. These three regions may form one continuous binding domain.

Structural and functional basis for hormone binding and receptor oligomerization

Most single-pass transmembrane receptors undergo a change in oligomeric state upon hormone binding. Recent mutational, biophysical and structural studies of the human growth hormone and tumor necrosis factor receptor complexes have revealed much about the mechanisms and molecular bases for binding and oligomerization. Principles learned from these examples and others should apply to many other hormone-receptor complexes.

A novel member of the interferon receptor family complements functionality of the murine interferon gamma receptor in human cells

Expression of the human interferon gamma receptor (IFN-gamma R) in mouse cells is not sufficient to confer biological responsiveness to human IFN-gamma and vice versa. An additional species-specific component is required for signal transduction. We identified this cofactor by expression cloning in simian COS cells stably transfected with the nonfunctional murine IFN-gamma R and a IFN-gamma-inducible reporter construct encoding the human Tac antigen (interleukin-2 receptor alpha chain, CD25). A cDNA clone was obtained that, upon stable transfection, rendered human HEp-2 cells expressing the murine IFN-gamma R fully responsive to murine IFN-gamma. This cDNA encodes a novel 332 amino acid type I transmembrane protein that belongs to the IFN receptor family and that we designate IFN-gamma R beta chain.

Identification and sequence of an accessory factor required for activation of the human interferon gamma receptor

Human chromosomes 6 and 21 are both necessary to confer sensitivity to human interferon gamma (Hu-IFN-gamma), as measured by induction of class I human leukocyte antigen (HLA) and protection against encephalomyocarditis virus (EMCV) infection. Whereas human chromosome 6 encodes the Hu-IFN-gamma receptor, human chromosome 21 encodes accessory factors for generating biological activity through the Hu-IFN-gamma receptor. Probes from a genomic clone were used to identity cDNA clones expressing a species-specific accessory factor. These cDNA clones are able to substitute for human chromosome 21 to reconstitute the Hu-IFN-gamma receptor-mediated induction of class I HLA antigens. However, the factor encoded by the cDNA does not confer full antiviral protection against EMCV, confirming that an additional factor encoded on human chromosome 21 is required for reconstitution of antiviral activity against EMCV. We conclude that this accessory factor belongs to a family of such accessory factors responsible for different actions of IFN-gamma.

Modulation of murine and human interferon-gamma receptor expression by their ligands or phorbol ester

IFN-gamma receptor expression on murine leukaemic L1210-cells has been studied. With the help of a transfected cell-line expressing the heterologous human receptor it was possible to discern receptor-specific properties like internalization from those regulating their expression on the surface. Recombinant IFN-gamma binds specifically to its homologous receptor at 4 degrees C and is rapidly internalized at physiologic temperatures. For this effect to occur, ligand binding to its receptor at 37 degrees C is necessary and sufficient. This notion is confirmed since a reduction in the number of heterologous human IFN-gamma receptors on the murine cell surface occurred exclusively after treatment with human IFN-gamma. Even weak doses of ligand, insufficient to occupy all receptors, led to a pronounced disappearance of binding sites. However, both receptors are simultaneously up-regulated in the presence of TPA, indicating a separate pathway which is not species-specific. Our findings imply that similar elements of the intracellular signal transduction machinery are involved in the control of MuIFN-gamma and HuIFN-gamma receptor expression. The results indicate also that factors involved in binding, internalization, and regulation of receptor gene expression are not species-specific.

Alignment of disulfide bonds of the extracellular domain of the interferon gamma receptor and investigation of their role in biological activity

The extracellular ligand binding domain of the human interferon gamma receptor includes eight cysteine residues forming four disulfide bonds. Only the nonreduced protein binds interferon gamma. We investigated the alignment of the disulfide bonds, using an enzymatically deglycosylated form of a soluble interferon gamma receptor, produced in baculovirus-infected insect cells. The soluble receptor was digested with endoproteinase Glu-C and proteinase K, and the proteolytic fragments were characterized by amino acid sequence analysis and mass spectrometry. It was found that four consecutive disulfide bonds are formed between residues Cys60-Cys68, Cys105-Cys150, Cys178-Cys183, and Cys197-Cys218. We also investigated the role of the disulfide bonds in biological activity of the receptor, using site-directed mutagenesis and by exchanging the cysteine residues for serines. The mutated proteins were expressed in Escherichia coli and analyzed for ligand binding capacity on protein blots. The assays showed that all disulfide bonds are essential for full ligand binding capacity. Double or quadruple mutations at cysteine residues 60 and 68, and residues 178, 183, 197, and 218, respectively, resulted in complete loss of the activity, whereas double mutations at residues 105 and 150, 178 and 183, and 197 and 218, respectively, resulted in a residual activity about 1 order of magnitude lower than that of the wild type. The specific antibodies gamma R38 and gamma R99 detected conformational epitopes stabilized by disulfide bonds involving cysteine residues 60 and 68, and 178 and 183, respectively.

The human gamma interferon receptor accessory factor encoded by chromosome 21 transduces the signal for the induction of 2',5'-oligoadenylate-synthetase, resistance to virus cytopathic effect, and major histocompatibility complex class I antigens

Mouse fibroblasts, and human-mouse hybrid fibroblasts carrying only human chromosome 21, were transfected with cDNA encoding full-length human gamma interferon (IFN-gamma) receptor or chimeric IFN-gamma receptor (extracellular domain of the human receptor; transmembrane and intracellular domains of mouse origin). These transfected mouse cells were sensitive to human IFN-gamma only when human chromosome 21 was present. These results show that the species-specific accessory protein encoded by human chromosome 21 interacts with the extracellular domain of human IFN-gamma receptor and transduces the IFN-gamma signal not only for up-regulation of mouse major histocompatibility complex class I antigen expression but also for the induction of 2',5'-oligoadenylate-synthetase and resistance to virus cytopathic effect.