Interferon-gamma induces biosynthesis of complement components C2, C4 and factor H by human proximal tubular epithelial cells

In a previous study the authors demonstrated that the production of complement component C4 by human kidney proximal tubular epithelial cells (PTEC) is upregulated by interferon gamma (IFN-gamma). In the present study the authors describe that PTEC in culture express both mRNA and protein of the IFN-gamma receptor complex, and that culture of PTEC with 1000 U/ml IFN-gamma for 72 h results in enhanced production not only of C4 (36.1 ng/10(6) cells), but also of C2 (10.8 ng/10(6) cells) and Factor H (17.5 ng/10(6) cells). Unstimulated PTEC produced 0.5 ng/10(6) cells, 0.5 ng/10(6) cells and 0.4 ng/10(6) cells of C2, C4 and Factor H, respectively. The upregulation of the three complement components was dose- and time-dependent and specific for IFN-gamma because the effect of IFN-gamma was abolished by a monoclonal antibody directed against IFN-gamma. Furthermore no effect of other cytokines was observed. The regulation of synthesis of C2, C4 and Factor H occurred at the transcriptional level as shown by semi-quantitative RT-PCR and dot-blot analysis. Taken together with the observation that in normal kidney tissue the tubuli express IFN-gamma receptor alpha-chain and a signal transducing protein, the present study implies that enhanced production of complement by PTEC may occur during a local immune response by in situ generation of IFN-gamma by infiltrating T-cells in the interstitium of the kidney.

Contributions of cloned type I interferon receptor subunits to differential ligand binding

The human type I interferons, including at least 12 IFN-alphas, IFN-beta and IFN-omega, bind to a receptor (IFNAR) composed of at least two transmembrane subunits, IFNAR-1 and IFNAR-2. The contributions of the receptor subunits to ligand binding were investigated by measuring the binding properties of IFNAR-1 or IFNAR-2 alone, or when co-expressed. The affinity of IFNAR-2 for IFN-alpha2 was increased by the co-expression of IFNAR-1, which itself binds ligand very weakly. Most type I IFNs inhibited the binding of IFN-alpha2 to IFNAR-2 alone with IC50 values of 2-20 nM. For cells co-expressing IFNAR-1 and IFNAR-2, the IC50 values decreased 3-20-fold for various ligands, relative to their values on IFNAR-2 alone. Thus, while IFNAR-2 plays the major role in affinity determination and differential recognition of type I IFNs, IFNAR-1 modulates both the ligand affinity and selectivity of the IFNAR-1/IFNAR-2 receptor complex.

Interferons alpha/beta and their receptors: place in the hierarchy of cytokines

Interferons alpha/beta (IFNs-alpha/beta) are the first cytokines to be produced by recombinant DNA technology. They regulate growth and differentiation, affecting cellular communication, signal transduction pathways and immunological control. This review focuses on the relationships between the structure and biological activities of IFNs-alpha/beta induced as a result of specific interactions with different types of polypeptide receptors as well as on the role of glycolipids in the modulation of these activities. The discovery of the primary structure homology of HuIFNs-alpha and thymus hormone-thymosin alpha 1 (TM alpha 1), the experimental finding of the competition between IFN-alpha and TM alpha 1 for common receptors and the reproduction by reHuIFN-alpha 2 of TM alpha 1 immunomodulating activities create the basis of reHuIFN-alpha therapeutics instead of TM alpha 1, and potentiation of vaccines by reHuIFN-alpha. The first successful attempt at grafting of the HuIFN-alpha 2s TM alpha 1-like immunomodulating site to the designed de novo protein albeferon is described. This article also aims at reviewing recent data concerning the structure of other cytokines and their receptors. Their reciprocal structure-function taxonomy is proposed. The place of IFNs-alpha/beta and their receptors in the hierarchy of cytokines is determined.

The IFN gamma receptor: a paradigm for cytokine receptor signaling

During the last several years, the mechanism of IFN gamma-dependent signal transduction has been the focus of intense investigation. This research has recently culminated in the elucidation of a comprehensive molecular understanding of the events that underlie IFN gamma-induced cellular responses. The structure and function of the IFN gamma receptor have been defined. The mechanism of IFN gamma signal transduction has been largely elucidated, and the physiologic relevance of this process validated. Most recently, the molecular events that link receptor ligation to signal transduction have been established. Together these insights have produced a model of IFN gamma signaling that is nearly complete and that serves as a paradigm for signaling by other members of the cytokine receptor superfamily.

The human type I interferon receptor. Identification of the interferon beta-specific receptor-associated phosphoprotein

We used specific antibodies recognizing the receptor 1 (IFNAR1) and the recently cloned receptor 2.2 (IFNAR2.2) chains of the human type I interferon receptor complex to demonstrate that the interferon beta (IFN-beta)-specific receptor-associated phosphoprotein is IFNAR2.2 and not an unknown or additional receptor component. Immunoprecipitation experiments demonstrated that IFNAR2.2 is present in Daudi cells as a cell surface protein of approximately 90-100 kDa, which is tyrosine-phosphorylated and associated with IFNAR1, upon stimulation of cells with IFN-beta. IFNAR2.2 was not detected associated with IFNAR1 in cells stimulated with IFN-alpha, suggesting differences in receptor interaction between the two type I interferons. Both IFNAR1 and IFNAR2.2 undergo tyrosine phosphorylation upon induction by either IFN-alpha or IFN-beta. Therefore, it is unclear as to why IFNAR2.2 is not detectable in IFNAR1 immunoprecipitates in IFN-beta-treated cells. These data suggest that, although IFN-alpha and IFN-beta may utilize similar receptor chains, they interact with IFNAR1 and IFNAR2.2 in different ways.

A mutation in the interferon-gamma-receptor gene and susceptibility to mycobacterial infection

BACKGROUND

Genetic differences in immune responses may affect susceptibility to mycobacterial infection, but no specific genes have been implicated in humans. We studied four children who had an unexplained genetic susceptibility to mycobacterial infection and who appeared to have inherited the same recessive mutation from a common ancestor.

METHODS

We used microsatellite analysis, immunofluorescence studies, and sequence analysis to study the affected patients, unaffected family members, and normal controls.

RESULTS

A genome search using microsatellite markers identified a region on chromosome 6q in which the affected children were all homozygous for eight markers. The gene for interferon-gamma receptor 1 maps to this region. Immunofluorescence studies showed that the receptor was absent on leukocytes from the affected children. Sequence analysis of complementary DNA for the gene for interferon-gamma receptor 1 revealed a point mutation at nucleotide 395 that introduces a stop codon and results in a truncated protein that lacks the transmembrane and cytoplasmic domains.

CONCLUSIONS

Four children with severe mycobacterial infections had a mutation in the gene for interferon-gamma receptor 1 that leads to the absence of receptors on cell surfaces and a functional defect in the up-regulation of tumor necrosis factor alpha by macrophages in response to interferon-gamma. The interferon-gamma pathway is important in the response to intracellular pathogens such as mycobacteria.

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.

Structure of an ovine interferon receptor and its expression in endometrium

A sheep type I interferon receptor (oIFNAR1) cDNA was isolated from a lambda-ZAP library using a reverse transcription (RT)-PCR product probe generated from oestrous endometrial RNA. The oIFNAR1 cDNA was 79, 66 and 95% homologous to human, murine and bovine IFNAR1 cDNAs respectively. The encoded receptor was a 560-amino acid transmembrane protein 80, 66 and 95% similar to human, murine and bovine IFNAR1 respectively. Northern blot analysis of endometrial mRNA revealed the presence of 6.5, 4.3 and 3.7 kb transcripts. Using semi-quantitative RT-PCR the oIFNAR1 mRNA was not found to be down-regulated after 72 h treatment with bovine recombinant IFN-alpha I in in vitro experiments with endometrial explants.

Functional replacement of cytokine receptor extracellular domains by leucine zippers

Granulocyte-macrophage colony-stimulating factor receptor signals by a complex which includes the ligand and two different receptor subunits: a low affinity alpha receptor binding chain (granulocyte-macrophage colony-stimulating factor receptor alpha subunit (GM-Ralpha)) and a signal-transducing beta chain (GM-Rbeta). To investigate two unresolved issues in the initiation of signaling, the role of receptor extracellular domains and receptor stoichiometry, we replaced the mouse GM-Ralpha and GM-Rbeta extracellular domains with the leucine zipper domain of either the Fos or Jun molecule. We co-transfected combinations of chimeric receptors into Ba/F3 cells and found that both simple heterodimers of the GM-Ralpha and GM-Rbeta intracellular domains and homodimers of the GM-Rbeta intracellular domain signaled for proliferation. Surprisingly, homodimers of the GM-Ralpha intracellular domain also signaled for prevention of apoptosis in transfected cells. We similarly engineered dimers of the intracellular domain of the human interferon gamma receptor beta subunit and found that homodimers of the intracellular domain signaled for proliferation. When Fos peptide was added to Ba/F3 cells expressing the human interferon gamma receptor beta subunit construct, thereby preventing homodimer formation, the cells no longer proliferated in the absence of mouse interleukin 3.

A negative regulatory region in the intracellular domain of the human interferon-alpha receptor

Interferon-alpha (IFN-alpha)-mediated intracellular signaling is initiated by ligand-induced receptor dimerization, tyrosine phosphorylation of the Tyk2 and Jak1 tyrosine kinases, and subsequent phosphorylation of the Stat1 and Stat2 proteins. The IFN-alpha receptor consists of at least two distinct subunits. One subunit, IFNAR1, has low affinity binding for interferon yet is required for signal transduction. We introduced mutations in the cytoplasmic domain of human IFNAR1 in order to identify residues involved in the mediation of biological responses. We took advantage of the species specificity of the interferon receptors by analyzing human IFN-alpha-induced major histocompatibility complex class I antigen expression in mouse L929 cells stably transfected with mutant human receptors. The membrane proximal 60-amino acids were insufficient to signal a biological response even though within these residues Tyk2 and Stat2 binding sites have been identified. IFN-alpha-induced receptor tyrosine phosphorylation was not critical for signaling because mutation of Tyr residues to Phe did not prevent the biological response to IFN-alpha. The deletion of a 16-amino acid region highly homologous between species created a receptor which signals an enhanced response. Tyrosine dephosphorylation is a component of this enhanced response as mutation of the Tyr residues within this region to Phe resulted in a receptor with increased sensitivity to IFN. The known signaling molecules that interact with IFNAR1 are positive regulators of IFN-alpha function. The presence of this domain in the COOH-terminal region suggests that the receptor may interact with signaling molecules that negatively regulate interferon responses.

Human interferon-alpha receptor: identification of the region involved in binding to interferon-alpha B

Three polypeptides comprising amino acids 1-102, 93-260, and 261-410 of the extracellular domain of the human interferon-alpha receptor HuIFN-alpha R (Uzé, G., Lutfalla, G., and Gresser, I. Cell 1990; 60:225-234) have been expressed in Escherichia coli. The polypeptides were sequestered within bacterial inclusion bodies. Inclusion body material was solubilized by 8 M urea, and the polypeptides were purified by gel filtration or histidine tag-based affinity chromatography. Overall recovery of each purified and refolded polypeptide was approximately 0.5-0.8 mg/liter of cell culture. The polypeptides migrated as homogeneous monomers of 12 kDa, 22 kDa, and 17 kDa, respectively on reduced sodium dodecylsulfate polyacrylamide gel electrophoresis. The polypeptide fragments corresponding to amino acids 1-102, and 93-260 of the extracellular domain of HuIFN-alpha R lacked the ability to bind to IFN-alpha B and to inhibit its biologic activities. The polypeptide fragment corresponding to amino acids 261-410 of the receptor molecule inhibited the antiproliferative activity of IFN-alpha B and competed with the Daudi cell surface receptor for binding to this IFN-alpha species.

Soluble interferon-gamma receptors encoded by poxviruses

Poxviruses encode a broad range of proteins that counteract the formidable attack of the immune response initiated in the host after infection, among which are proteins that mimic the extracellular binding domain of host cytokine receptors and are secreted from virus-infected cells. A soluble interferon-gamma receptor (IFN-gamma R) is produced early after infection and efficiently blocks the binding of IFN-gamma to cellular receptors, thus inhibiting both the anti-viral and immune functions of IFN-gamma. An IFN-gamma R is highly conserved among members of the poxvirus family, suggesting a major role in viral pathogenesis. The highly species-specific nature of the IFN system enables questions concerning the evolutionary relationship between poxviruses and their hosts to be addressed. The IFN-gamma R encoded by myxoma virus, a natural pathogen of rabbits, is specific for rabbit IFN-gamma. However, the IFN-gamma R encoded by orthopoxviruses (vaccinia, cowpox, camelpox, ectromelia) shows a novel, broad species specificity suggesting that these viruses have evolved in several species. The implications for the unknown origin and natural host(s) of vaccinia virus are discussed.

Switching on of the proliferation or apoptosis of activated human T lymphocytes by IFN-gamma is correlated with the differential expression of the alpha- and beta-chains of its receptor

To find out how physiologically secreted IFN-gamma controls either the proliferation or the apoptosis of human T lymphocytes, the kinetics of expression of the alpha- and beta-chains of its receptor (IFN-gamma R) were sequentially followed on T lymphocytes first activated with PHA and then cultured in the presence of IL-2, and related to the kinetics of expression of Fas, Bcl-2, and IL-2R p55 chain. Both IFN-gamma R chains were poorly expressed on the membrane of resting T lymphocytes. Following their stimulation with PHA, IFN-gamma R alpha but not IFN gamma R beta-chain up-modulated before T lymphocyte entry into the S phase, and then IFN-gamma R alpha down-modulated when they passed through the S and G2/M. The ensuing proliferative response was inhibited by an anti-IFN-gamma R alpha mAb that impeded the binding of IFN-gamma. When PHA-activated T lymphoblasts were cultured for 16 days with IL-2, IFN-gamma R alpha expression increased, whereas that of the beta-chain remained barely detectable. Fas and Bcl-2 were both highly expressed. When these T lymphoblasts were restimulated by PHA, OKT3, or Staphylococcus enterotoxin beta-pokeweed mitogen, both chains up-modulated and most cells underwent apoptosis in a way apparently independent of Bcl-2, but not of Fas. This apoptosis, too, was prevented by the anti-IFN-gamma R alpha mAb. Physiologically secreted IFN-gamma is thus involved in the activation of resting T lymphocytes and in the apoptosis of reactivated lymphoblasts. However, high expression of IFN-gamma R beta took place when IFN-gamma induced apoptosis, but not when it induced proliferation. In conclusion, a correlation exists between differential expression of the IFN-gamma R beta-chain and the delivery by IFN-gamma of proliferative or apoptotic signals.

Purification and crystallization of a complex between human interferon gamma receptor (extracellular domain) and human interferon gamma

X-ray diffraction quality crystals have been obtained from a complex between interferon gamma and the extracellular domain of its high-affinity cell surface receptor. The crystals were obtained from interferon gamma/interferon gamma receptor complexes purified by size exclusion chromatography. Diffraction quality crystals required analyzing these complex samples by isoelectric focusing gels to select purified complex fractions devoid of unbound interferon gamma. These studies used interferon gamma receptor engineered with an eight amino acid N-terminal deletion to eliminate heterogeneity generated due to proteolytic cleavage. In addition, the receptor was expressed in an E. coli secretion cell line which eliminated the need to refold the protein. Hexagonal crystals were grown from 1.6 M ammonium phosphate solutions and belong to a spacegroup of P6(5)22 with unit cell dimensions a = 145.9 A and c = 180.3 A. These crystals diffract to at least 2.9 A resolution when exposed to synchrotron radiation. SDS PAGE analysis of the crystals demonstrated that both interferon gamma and the receptor were present. Analysis of the x-ray diffraction data revealed that the crystals contain complexes with a stoichiometry of 2:1 receptor: ligand within the crystallographic asymmetric unit and consist of approximately 55% solvent.

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.

Dimerization of a chimeric CD4-interferon-alpha receptor reconstitutes the signaling events preceding STAT phosphorylation

Interferon-alpha induces the rapid tyrosine phosphorylation of a number of molecules, including the cognate receptors, JAK-family kinases (Jak1 and tyk2), and latent transcription factors (STATs 1 and 2). Here, we describe the use of chimeric molecules composed of the extracellular domain of CD4 fused to the intracellular domain of the interferon-alpha receptor subunit 1 (IFNaR1). Antibody mediated crosslinking dimerizes the transfected chimeras, activates tyk2 and induces a tyk2-dependent tyrosine phosphorylation of the intracellular domain of the chimera. We further define the major site of IFNaR1 phosphorylation, and show that phosphorylation of this site is required for association with STAT2. Finally, we show that homodimerization of IFNaR1 is not sufficient to activate the STATs, suggesting a role for the IFNaR2 subunit and Jak1 in the transduction of the interferon-alpha signal.

Differential responsiveness of a splice variant of the human type I interferon receptor to interferons

Chinese hamster ovary cells containing the yeast artificial chromosome F136C5 (alphaYAC) respond to all type I human interferons including IFN-alphaA, IFN-beta, and IFN-omega. The alphaYAC contains at least two genes encoding interferon-alpha receptor (IFN-alphaR) chains that are required for response to type I human interferons: Hu-IFN-alphaR1 and Hu-IFN-alphaR2. We previously isolated a splice variant of the Hu-IFN-alphaR1 chain designated Hu-IFN-alphaR1s. Chinese hamster ovary cells containing a disrupted alphaYAC, which contains a deletion in the human IFNAR1 gene, were transfected with expression vectors for the Hu-IFN-alphaR1 and Hu-IFN-alphaR1s chains. With these cells, two type I interferons have been identified which can interact with the splice variant (Hu-IFN-alphaR1s) and with the Hu-IFN-alphaR1 chains: Hu-IFN-alphaA and IFN-omega. Two other type I interferons, Hu-IFN-alphaB2 and Hu-IFN-alphaF, are capable of signaling through the Hu-IFN-alphaR1 chain only and cannot utilize the splice variant Hu-IFN-alphaR1s. Hu-IFN-alphaR1 and Hu-IFN-alphaR1s differ in that the latter is missing a single subdomain of the receptor extracellular domain encoded by exons 4 and 5 of the IFNAR1 gene. These results therefore indicate that different type I interferons require different subdomains of the Hu-IFN-alphaR1 receptor chain, and that the splice variant chain (Hu-IFN-alphaR1s) is functional.

Modulation of the expression of the IFN-gamma receptor beta-chain controls responsiveness to IFN-gamma in human peripheral blood T cells

IFN-gamma has potent antiproliferative and apoptotic effects in T cells that are important in determining T cell development and polarized differentiation. Therefore, any event that enables T cells to become less responsive to IFN- gamma may potentially alter immune responsiveness to Ag. In this work, we show that human peripheral blood T cells that are stimulated through the TCR and expanded with IL-2 are unresponsive to IFN-gamma, as determined by a lack of activation of jak kinases and the transcription factor, STAT1(alpha), a signal transducer and activator of transcription. This nonresponsiveness occurs because of a lack of expression of the beta- chain (accessory factor) of the IFN-gamma receptor, while at the same time maintaining IFN-gamma receptor alpha-chain expression. Expression of the beta-chain can be restored by secondary TCR ligation or PMA treatment. T cell blasts treated with PMA are now responsive to IFN-gamma. When freshly isolated, highly enriched (>98%) T cells are examined for IFN-gamma responsiveness; these cells can respond to IFN-gamma and express beta-chain. Therefore, as T cells progress from primary TCR activation through IL-2-dependent proliferation, followed by secondary TCR stimulation, their responsiveness to IFN-gamma varies, and this may affect their ability to participate in an ongoing immune response.

Comparative studies of gamma-interferon receptor-like proteins of variola major and variola minor viruses

To study specific properties of the human gamma-interferon (gamma-IFN) receptor-like proteins of the highly virulent and low virulent strains of variola (smallpox) virus (VAR) recombinant plasmids determining synthesis of these proteins in E. coli cells have been constructed. The recombinant viral gamma-IFN receptor-like proteins have been found to have high interferon-neutralising activity with regard to human gamma-IFN but not murine gamma-IFN and human alpha-IFN. The variola major and variola minor proteins under study do not differ in the efficiency of human gamma-IFN antiviral activity inhibition.

Phosphorylated interferon-alpha receptor 1 subunit (IFNaR1) acts as a docking site for the latent form of the 113 kDa STAT2 protein

Interferon-alpha (IFN alpha) induces rapid tyrosine phosphorylation of its receptors, two JAK kinases and three STAT transcription factors. One kinase, p135tyk2, is complexed with the IFNaR1 receptor, and may catalyze some of these phosphorylation events. We demonstrate that, in vitro, p135tyk2 phosphorylates two tyrosines on IFNaR1. A phosphopeptide corresponding to the major phosphorylation site (Tyr466) binds STAT2, but not STAT1, in an SH-2-dependent manner. Furthermore, only latent, non-phosphorylated STAT2 interacts with this phosphopeptide. When this phosphopeptide is introduced into permeabilized cells, the IFN alpha-dependent tyrosine phosphorylation of both STATs is blocked. Finally, mutant versions of IFNaR1, in which Tyr466 is changed to phenylalanine, can act in a dominant negative manner to inhibit phosphorylation of STAT2. These observations are consistent with a model in which IFNaR1 mediates the interaction between JAK kinases and the STAT transcription factors.

Apparent heterogeneity of recombinant interferon gamma receptors produced in prokaryotic and eukaryotic expression systems

Recombinant proteins show several types of heterogeneity and post-translational modifications which are usually related to their production system. The apparent heterogeneity of recombinant interferon gamma receptors and interferon gamma receptor-immunoglobulin G fusion proteins expressed in Escherichia coli, baculovirus-infected insect cells and Chinese hamster ovary cells have been studied. In general, all proteins tested showed some type of heterogeneity which was detectable by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The E. coli-derived receptor included non-native conformations involving mis-paired or non-formed disulfides. This type of heterogeneity affected the biological activity of the protein. In addition, the prokaryotic protein had trapped phosphoric acid during downstream processing. The phosphoric acid entrapment did not affect ligand binding capacity. The eukaryotic proteins showed heterogeneity because of the unequal cleavage of the signal peptide and because of differences in glycosylation. The latter types of heterogeneity did not affect activity. Glycosylation-related heterogeneity was partially derived from the unequal utilization of the potential N-glycosylation sites and differently affected the apparent molecular masses and migrations of the proteins on polyacrylamide gels. The results may be useful in characterization studies of recombinant proteins.

Identification of an interferon-gamma receptor alpha chain sequence required for JAK-1 binding

We have shown previously that a four-amino acid block residing at positions 266-269 (LPKS) in the intracellular domain of the human interferon-gamma (IFN-gamma) receptor alpha chain is critical for IFN-gamma-dependent tyrosine kinase activation and biologic response induction. Herein we show that this sequence is required for the constitutive attachment of the tyrosine kinase JAK-1. Using a vaccinia expression system, a receptor alpha chain-specific monoclonal antibody coprecipitated JAK-1 from cells coexpressing JAK-1 and either (a) wild type IFN-gamma receptor alpha chain, (b) a receptor alpha chain truncation mutant containing only the first 59 intracellular domain amino acids, or (c) a receptor mutant containing alanine substitutions for the functionally irrelevant residues 272-275. In contrast, JAK-1 was not coprecipitated when coexpressed with a receptor alpha chain mutant containing alanine substitutions for the functionally critical residues 266-269 (LPKS). Mutagenesis of the LPKS sequence revealed that Pro-267 is the only residue obligatorily required for receptor function. In addition, Pro-267 is required for JAK-1 binding. These results thus identify a site in the IFN-gamma receptor alpha chain required for constitutive JAK-1 association and establish that this association is critical for IFN-gamma signal transduction.

Myxoma virus M-T7, a secreted homolog of the interferon-gamma receptor, is a critical virulence factor for the development of myxomatosis in European rabbits

Myxoma virus is a leporipoxvirus of New World rabbits (Sylvilagus sp.) that induces a rapidly lethal infection known as myxomatosis in the European rabbit (Oryctolagus cuniculus). Like all poxviruses, myxoma virus encodes a plethora of proteins to circumvent or inhibit a variety of host antiviral immune mechanisms. M-T7, the most abundantly secreted protein of myxoma virus-infected cells, was originally identified as an interferon-gamma receptor homolog (Upton, Mossman, and McFadden, Science 258, 1369-1372, 1992). Here, we demonstrate that M-T7 is dispensable for virus replication in cultured cells but is a critical virulence factor for virus pathogenesis in European rabbits. Disruption of both copies of the M-T7 gene in myxoma virus was achieved by the deletion of 372 bp of M-T7 coding sequences, replacement with a selectable marker, p7.5Ecogpt, and selection of a recombinant virus (vMyxlac-T7gpt) resistant to mycophenolic acid. vMyxlac-T7gpt expressed no detectable M-T7 protein and infected cells supernatants were devoid of any detectable interferon-gamma binding activities. Immunohistochemical staining with anti-beta-galactosidase and anti-CD43 antibodies demonstrated that in vMyxlac-T7gpt-infected rabbits the loss of M-T7 not only caused a dramatic reduction in disease symptoms and viral dissemination to secondary sites, but also dramatically influenced host leukocyte behavior. Notably, primary lesions in wild-type virus infections were generally underlayed by large masses of inflammatory cells that did not effectively migrate into the dermal sites of viral replication, whereas in vMyxlac-T7gpt infections this apparent block to leukocyte influx was relieved. A second major phenotypic distinction noted for the M-T7 knockout virus was the extensive activation of lymphocytes in secondary immune organs, particularly the spleen and lymph nodes, by Day 4 of the infection. This is in stark contrast to infection by wild-type myxoma virus, which results in relatively little, if any, cellular activation of germinal centers of spleen and lymph node by Day 4. We conclude that M-T7 functions early in infection to (1) retard inflammatory cell migration into infected tissues and (2) disrupt the communication between sentinel immune cells at the site of primary virus infection in the subdermis and lymphocytes in the secondary lymphoid organs, thereby disabling the host from mounting an effective cellular immune response. To summarize, in addition to neutralizing host interferon-gamma at infected sites, we propose that M-T7 protein also modifies leukocyte traffic in the vicinity of virus lesions, thus effectively severing the link between antigen presenting cells of the infected tissue and the effector lymphocytes of the peripheral immune organs.

A bivalent immunoadhesin of the human interferon-gamma receptor is an effective inhibitor of IFN-gamma activity

We describe here the bioengineering of a bivalent IFN-gamma-RFc immunoadhesin consisting of the extracellular domain of the human IFN-gamma receptor alpha chain (IFN-gamma-R) fused to a human IgG1 Fc region (encoding hinge, CH2 and CH3 domain) that was efficiently expressed as a covalently linked homodimer in insect cells and purified in a one-step purification procedure. The IFN-gamma-RFc fusion protein exerted a 3-fold higher ligand binding affinity in binding competition studies in vitro compared with the monovalent extracellular IFN-gamma-R domain. In addition, the in vitro antagonistic activity of IFN-gamma-RFc, as determined by inhibition of IFN-gamma-induced virus protection and HLA-DR expression, was more than 30-fold higher in comparison with the monovalent soluble receptor. The described IFN-gamma-R immunoadhesin is a potential therapeutic reagent to interfere with the disease-promoting activities of IFN-gamma in several autoimmune diseases.