Structural requirements for gp80 independence of human herpesvirus 8 interleukin-6 (vIL-6) and evidence for gp80 stabilization of gp130 signaling complexes induced by vIL-6

Human herpesvirus 8 interleukin-6 (vIL-6) displays 25% amino acid identity with human IL-6 (hIL-6) and shares an overall four-helix-bundle structure and gp130-mediated STAT/mitogen-activated protein kinase signaling with its cellular counterpart. However, vIL-6 is distinct in that it can signal through gp130 alone, in the absence of the nonsignaling gp80 alpha-subunit of the IL-6 receptor. To investigate the structural requirements for gp80 independence of vIL-6, a series of expression vectors encoding vIL-6/hIL-6 chimeric and site-mutated IL-6 proteins was generated. The replacement of hIL-6 residues with three vIL-6-specific tryptophans implicated in gp80 independence from crystallographic studies or the A and C helices containing these residues did not confer gp80 independence to hIL-6. The N- and C-terminal regions of vIL-6 could be substituted with hIL-6 sequences with the retention of gp80-independent signaling, but substitutions of other regions of vIL-6 (helix A, A/B loop, helix B, helix C, and proximal half of helix D) with equivalent sequences of hIL-6 abolished gp80 independence. Interestingly, the B helix of vIL-6 was absolutely required for gp80 independence, despite the fact that this region contains no receptor-binding residues. Point mutational analysis of helix C, which contains residues involved in physical and functional interactions with gp130 domains 2 and 3 (cytokine-binding homology region), identified a variant, VI120EE, that was able to signal and dimerize gp130 only in the presence of gp80. gp80 was also found to stabilize gp130:g130 dimers induced by a distal D helix variant of vIL-6 that was nonetheless able to signal independently of gp80. Together, our data reveal the crucial importance of overall vIL-6 structure and conformation for gp80-independent signaling and provide functional and physical evidence of the stabilization of vIL-6-induced gp130 signaling complexes by gp80.     

Signal transduction by human herpesvirus 8 viral interleukin-6 (vIL-6) is modulated by the nonsignaling gp80 subunit of the IL-6 receptor complex and is distinct from signaling induced by human IL-6

Human herpesvirus 8 (HHV-8) viral interleukin-6 (vIL-6) mediates signaling through the gp130 signal transducer but unlike human IL-6 (hIL-6) does not require the nonsignaling gp80 alpha subunit of the IL-6 receptor complex. By utilizing a gp80-refractory vIL-6 variant, vIL-6(R189L), we found that signal transduction, as measured by STAT1 and STAT3 activation and gp130 tyrosine phosphorylation in gp80+/gp130+ HEK293T cells, was modulated by gp80. Furthermore, the signaling and BAF-130 cell growth-promoting activities of vIL-6 and hIL-6 could be distinguished, and exogenous addition of soluble gp80 enhanced cell growth supported by vIL-6. Our findings demonstrate that gp80 can modulate vIL-6 activity and that vIL-6 and hIL-6 signaling are not directly equivalent.     

Viral Interleukin-6: Structure, pathophysiology and strategies of neutralization

Viral Interleukin-6 (vIL-6) is encoded by Human herpes virus 8 (HHV8), also known as Kaposi's sarcoma (KS)-associated herpes virus (KSHV). HHV8 infection is found in patients with KS, primary effusion lymphoma (PEL) and plasma cell-type of multicentric Castleman's disease (MCD), with a high incidence observed in HIV infected individuals. vIL-6 shares about 25% identity with its human counterpart. Human IL-6 (hIL-6) binds to the human IL-6 receptor (hIL-6R) and the hIL-6/hIL-6R complex associates with the signaling receptor subunit gp130. Upon dimerization of gp130 intracellular signaling is initiated. All cells in the body express gp130 but only some cell types express the hIL-6R. Human IL-6 does not stimulate cells, which do not express hIL-6R. However, a naturally occurring soluble form of the hIL-6R (shIL-6R) can bind hIL-6 and the complex of hIL-6/shIL-6R can stimulate cells, which only express gp130 but no hIL-6R. This process, which has been named trans-signaling, leads to a dramatic increase in the spectrum of hIL-6 target cells during inflammation and cancer. vIL-6, in contrast to hIL-6, can directly bind to and activate gp130 without the need of the hIL-6R. Therefore, at least in theory, vIL-6 can stimulate every cell in the human body. This review highlights the properties of vIL-6 regarding structural features, implications for pathophysiology, and strategies of neutralization. Furthermore, mechanisms of activation of gp130 by hIL-6, vIL-6, and by forced dimerization will be discussed.     

Detection of direct binding of human herpesvirus 8-encoded interleukin-6 (vIL-6) to both gp130 and IL-6 receptor (IL-6R) and identification of amino acid residues of vIL-6 important for IL-6R-dependent and -independent signaling

Human herpesvirus 8 (HHV-8) is associated with Kaposi's sarcoma, primary effusion lymphoma, and multicentric Castleman's disease; in all of these diseases, interleukin-6 (IL-6) has been implicated as a likely mitogenic and/or angiogenic factor. HHV-8 encodes a homologue of IL-6 (viral IL-6 [vIL-6]) that has been shown to be biologically active in several assays and whose activities mirror those of its mammalian counterparts. Like these proteins, vIL-6 mediates its effects through the gp130 signal transducer, but signaling is not dependent on the structurally related IL-6 receptor (IL-6R; gp80) subunit of the receptor-signal transducer complex. However, as we have shown previously, IL-6R can enhance vIL-6 signal transduction and can enable signaling through a gp130 variant (gp130.PM5) that is itself unable to support vIL-6 activity, indicating that IL-6R can form part of the signaling complex. Also, our analysis of a panel of vIL-6 mutants in transfection experiments in Hep3B cells (that express IL-6R and gp130) showed that most were able to function normally in this system. Here, we have used in vitro vIL-6-receptor binding assays to demonstrate direct binding of vIL-6 to both gp130 and IL-6R and vIL-6-induced gp130-IL-6R complex formation, and we have extended our functional analyses of the vIL-6 variants to identify residues important for IL-6R-independent and IL-6R-dependent signaling through native gp130 and gp130.PM5, respectively. These studies have identified residues in vIL-6 that are important for IL-6R-independent and IL-6R-mediated functional complex formation between vIL-6 and gp130 and that may be involved directly in binding to gp130 and IL-6R.     

Molecular mechanisms for viral mimicry of a human cytokine: activation of gp130 by HHV-8 interleukin-6

Kaposi's sarcoma-associated herpesvirus (KSHV, or HHV-8) encodes a pathogenic viral homologue of human interleukin-6 (IL-6). In contrast to human IL-6 (hIL-6), viral IL-6 (vIL-6) binds directly to, and activates, the shared human cytokine signaling receptor gp130 without the requirement for pre-complexation to a specific alpha-receptor. Here, we dissect the biochemical and functional basis of vIL-6 mimicry of hIL-6. We find that, in addition to the "alpha-receptor-independent" tetrameric vIL-6/gp130 complex, the viral cytokine can engage the human alpha-receptor (IL-6Ralpha) to form a hexameric vIL-6/IL-6Ralpha/gp130 complex with enhanced signaling potency. In contrast to the assembly sequence of the hIL-6 hexamer, the preformed vIL-6/gp130 tetramer can be decorated with IL-6Ralpha, post facto, in a "vIL-6-dependent" fashion. A detailed comparison of the viral and human cytokine/gp130 interfaces indicates that vIL-6 has evolved a unique molecular strategy to interact with gp130, as revealed by an almost entirely divergent structural makeup of its receptor binding sites. Viral IL-6 appears to utilize an elegant combination of both convergent, and unexpectedly divergent, molecular strategies to oligomerize gp130 and activate similar downstream signaling cascades as its human counterpart.     

Reversal of some viral IL-6 electrostatic properties compared to IL-6 contributes to a loss of alpha receptor component recruitment

Human interleukin-6 (hIL-6) is a pleiotropic mediator of activation and proliferation across a large number of different cell types. Human herpesvirus-8 (HHV-8) has been associated with classical and AIDS-related Kaposi's sarcoma (KS). HHV-8 encodes viral IL-6 (vIL-6), a functional homolog of human interleukin-6, that promotes the growth of KS and of some lymphoma cells. Signaling induced by human IL-6 requires recruitment of the glycoprotein gp130, which acts as the signal transducing chain, and of IL-6Ralpha, which is necessary for cognate recognition and high affinity receptor complex formation. In contrast, the formation of a functional complex between vIL-6 and gp130 does not require the presence of IL-6Ralpha. The physico-chemical properties of vIL-6 have been analyzed and compared to those of hIL-6 and of the receptor chains, gp130 and IL-6Ralpha. Interaction sites on vIL-6 involve more hydrophobic residues than those of hIL-6. The electrostatic fields induced by vIL-6 and IL-6Ralpha are repulsive and prevent interaction between vIL-6 and IL-6Ralpha, whereas the electrostatic field induced by hIL-6 steers the complex formation with IL-6Ralpha. Subsequently, electrostatic binding free energy in the vIL-6/IL-6Ralpha complex is destabilizing, whereas it is stabilizing in the complex comprising hIL-6. These properties result from charge reversals between viral and human IL-6, an unusual phenomenon of amino acid substitutions within a homologous protein family. This suggests a selection pressure for vIL-6 to by-pass the IL-6Ralpha control of host defense against virus infection. This selection pressure has yielded the reversal of electrostatic properties of vIL-6 when compared to hIL-6.     

IL-6 receptor independent stimulation of human gp130 by viral IL-6

The genome of human herpes virus 8, which is associated with Kaposi's sarcoma, encodes proteins with similarities to cytokines and chemokines including a homologue of IL-6. Although the function of these viral proteins is unclear, they might have the potential to modulate the immune system. For viral IL-6 (vIL-6), it has been demonstrated that it stimulates IL-6-dependent cells, indicating that the IL-6R system is used. IL-6 binds to IL-6R, and the IL-6/IL-6R complex associates with gp130 which dimerizes and initiates intracellular signaling. Cells that only express gp130 but no IL-6R cannot be stimulated by IL-6 unless a soluble form of the IL-6R is present. This type of signaling has been shown for hematopoietic progenitor cells, endothelial cells, and smooth muscle cells. In this paper we show that purified recombinant vIL-6 binds to gp130 and stimulates primary human smooth muscle cells. IL-6R fails to bind vIL-6 and is not involved in its signaling. A Fc fusion protein of gp130 turned out to be a potent inhibitor of vIL-6. Our data demonstrate that vIL-6 is the first cytokine which directly binds and activates gp130. This property points to a possible role of this viral cytokine in the pathophysiology of human herpes virus 8.     

Determinants of Secretion and Intracellular Localization of Human Herpesvirus 8 Interleukin-6

Human herpesvirus 8 (HHV-8) interleukin-6 (vIL-6) is distinct from human and other cellular IL-6 proteins in that it does not require the nonsignaling α-receptor subunit for the formation of gp130-based signal transducing complexes and also is largely retained intracellularly rather than being secreted. We and others have reported that vIL-6 is retained and is active in the endoplasmic reticulum (ER) compartment, and data from our laboratory have demonstrated that intracellular vIL-6 is functional in the autocrine promotion of proliferation and survival of HHV-8 latently infected primary effusion lymphoma cells. It has also been reported that vIL-6 secretion in gp130-deficient cells can be enhanced by introduced gp130, thereby implicating the signal transducer in vIL-6 trafficking to the cell surface. We examine here the requirements for intracellular retention and localization of vIL-6. Using vIL-6-hIL-6 chimeric and point-mutated vIL-6 proteins, we identified regions and residues of vIL-6 influencing vIL-6 secretion. However, there was no correlation between vIL-6 secretion and gp130 interaction. We found that vIL-6, but not hIL-6, could associate stably with ER-resident chaperone protein calnexin. Glycosylation-dependent interaction of vIL-6 with calnexin correlated with proper protein folding, but there was no direct relationship between vIL-6-calnexin interaction and intracellular retention. While calnexin depletion had little influence on absolute amounts of secreted vIL-6, it led to markedly reduced levels of intracellular cytokine. This was reversed by gp130 transduction, which had no detectable effect on vIL-6 secretion, but redistributed vIL-6 into ER-distinct locations in calnexin-depleted cells, specifically. Our data reveal that calnexin plays a role in ER localization of vIL-6 and that gp130 promotes ER exit, but not secretion, of the viral cytokine.The viral homologue of interleukin-6, vIL-6, specified by human herpesvirus 8 (HHV-8) shows only 25% amino acid identity to human IL-6 (hIL-6) but is highly related structurally (2, 5). Despite the high degree of conservation of three-dimensional structure and equivalence of receptor interaction interfaces (1, 6), the viral cytokine can associate functionally with the gp130 signal transducer in the absence of the gp80 α-subunit, absolutely required for cellular IL-6 signaling through gp130. The nonsignaling gp80 subunit can be incorporated into vIL-6-induced signaling complexes and indeed seems to have a stabilizing effect that enhances signal transduction (1, 3, 11). Another major difference between vIL-6 and cellular IL-6 proteins, including hIL-6, is that the viral cytokine is very inefficiently secreted, retained largely within the endoplasmic reticulum (ER) compartment, where it is able to transduce signal via gp80-deficient vIL-6₂/gp130₂ tetrameric complexes, exclusively (4, 15). Thus, the unique ability of vIL-6 to signal intracellularly may be explained by its gp80 independence; hIL-6 cannot signal in the ER even when targeted to this compartment (4). The biological significance of intracellular, strictly autocrine signaling by vIL-6 was demonstrated recently in primary effusion lymphoma (PEL) cells, which are latently infected with HHV-8; these cells grew with markedly reduced kinetics and displayed higher rates of apoptosis upon shRNA-mediated vIL-6 depletion relative to cocultured untransduced cells (4). Thus, vIL-6 appears not only to be expressed in latently infected PEL cultures but also to be biologically active in this setting via intracrine signaling.Despite these findings and other mechanistic studies of vIL-6, the means by which the viral cytokine is retained in the ER and secreted so inefficiently is unknown. The elegant work of Meads and Medveczky (15) demonstrated the slow secretion kinetics of vIL-6 relative to hIL-6 and implicated gp130 as a necessary cofactor for vIL-6 secretion. Thus, vIL-6 expressed in gp130-negative Ba/F3 cells was able to be secreted only if gp130 was supplied via expression vector transduction. However, most cell types express gp130; thus, while the signal transducer may be involved in vIL-6 trafficking, the underlying explanation for the very slow rate of vIL-6 secretion must involve other factors.We report here investigations of the structural requirements for vIL-6 intracellular retention, the influence of gp130 on this process, and the possible involvement of ER-resident chaperon proteins for retention of vIL-6 in the ER. Our data identify effects of structural alterations and point mutations of vIL-6 on secretion efficiency, the lack of gp130 involvement in these observed effects, mechanistically relevant interactions of calnexin with the viral cytokine, and the influence of gp130 on vIL-6 subcellular localization and stability in the context of calnexin depletion. The results presented thus further advance our understanding of vIL-6-cellular protein interactions that impact upon its intracellular function.     

Human herpes virus 8 interleukin-6 homologue triggers gp130 on neuronal and hematopoietic cells.

Human herpes virus-8 (HHV8) encodes a cytokine named viral interleukin-6 (vIL-6) that shares 25% amino-acid identity with its human homologue. Human IL-6 is known to be a growth and differentiation factor of lymphatic cells and plays a potential role in the pathophysiology of various lymphoproliferative diseases. vIL-6 is expressed in HHV8-associated-diseases including Kaposi's sarcoma, Body-cavity-based-lymphoma and Castleman's disease, suggesting a pathogenetic involvement in the malignant growth of B-cell associated diseases and other malignant tumours. We expressed vIL-6 in Escherichia coli as a fusion protein with recombinant periplasmic maltose binding protein. After cleavage from the maltose binding protein moiety and purification, vIL-6 was shown to be correctly folded using circular dichroism spectroscopy. A rabbit antiserum was raised against the recombinant vIL-6 protein. vIL-6 turned out to be active on cells that expressed gp130 but no IL-6 receptor (IL-6-R) suggesting that, in contrast to human IL-6, vIL-6 stimulated gp130 directly. Accordingly, vIL-6 activity could be inhibited by a soluble gp130 Fc Fusion protein. vIL-6 was shown to induce neuronal differentiation of rat pheochromocytoma cells and to stimulate colony formation of human hematopoietic progenitor cells. Thus, vIL-6 exhibits biologic activity that has only been observed for the IL-6/soluble IL-6-R complex but not for IL-6 alone. These properties are important for the evaluation of the pathophysiological potential of vIL-6.     

Two distinct and independent sites on IL-6 trigger gp 130 dimer formation and signalling.

The helical cytokine interleukin (IL) 6 and its specific binding subunit IL-6R alpha form a 1:1 complex which, by promoting homodimerization of the signalling subunit gp130 on the surface of target cells, triggers intracellular responses. We expressed differently tagged forms of gp130 and used them in solution-phase binding assays to show that the soluble extracellular domains of gp130 undergo dimerization in the absence of membranes. In vitro receptor assembly reactions were also performed in the presence of two sets of IL-6 variants carrying amino acid substitutions in two distinct areas of the cytokine surface (site 2, comprising exposed residues in the A and C helices, and site 3, in the terminal part of the CD loop). The binding affinity to IL-6R alpha of these variants is normal but their biological activity is poor or absent. We demonstrate here that both the site 2 and site 3 IL-6 variants complexed with IL-6R alpha bind a single gp130 molecule but are unable to dimerize it, whereas the combined site 2/3 variants lose the ability to interact with gp130. The binding properties of these variants in vitro, and the result of using a neutralizing monoclonal antibody directed against site 3, lead to the conclusion that gp130 dimer is formed through direct binding at two independent and differently oriented sites on IL-6. Immunoprecipitation experiments further reveal that the fully assembled receptor complex is composed of two IL-6, two IL-6R alpha and two gp130 molecules. We propose here a model representing the IL-6 receptor complex as hexameric, which might be common to other helical cytokines.     

Interleukin-6 receptor signaling. I. gp80 and gp130 receptor interaction in the absence of interleukin-6

Interleukin-6 (IL-6) is used as a growth factor by various tumor cells. It binds to a gp80 specific receptor (IL-6R) and then to a gp130 transducing chain. Both receptor chains are released as soluble functional proteins which circulate in biological fluids. To study the physiological role of these soluble receptors, both proteins were purified from human plasma and the kinetic constants of equilibria between IL-6 and its natural soluble IL-6R (sIL-6R) and gp130 receptor (sgp130) were measured using surface plasmon resonance analysis. Unexpectedly, natural sIL-6R and natural sgp130 were found to interact (Kd = 2.8 nM) in the absence of IL-6. No interaction was seen between the recombinant soluble receptors or between either natural soluble receptor and its recombinant partner. This binary complex was not due to copurification of IL-6 and was detected in human plasma of healthy donors. It results from either direct interaction between the two natural soluble receptors or indirect binding mediated by a yet unidentified copurified plasma molecule playing the role of an IL-6 antagonist. Once formed, the binary complex was found to be unable to bind IL-6. Soluble gp130 had already been shown to inhibit IL-6 signaling by inactivating the IL-6/IL-6R complex. In addition we show that, in the absence of IL-6, circulating natural sgp130 is able to inhibit directly the circulating sIL-6R that is a strong synergic molecule of IL-6 signaling.     

Interleukin-11 signals through the formation of a hexameric receptor complex

Interleukin-11 (IL-11) is a member of the gp130 family of cytokines. These cytokines drive the assembly of multisubunit receptor complexes, all of which contain at least one molecule of the transmembrane signaling receptor gp130. IL-11 has been shown to induce gp130-dependent signaling through the formation of a high affinity complex with the IL-11 receptor (IL-11R) and gp130. Site-directed mutagenesis studies have identified three distinct receptor binding sites of IL-11, which enable it to form this high affinity receptor complex. Here we present data from immunoprecipitation experiments, using differentially tagged forms of ligand and soluble receptor components, which show that multiple copies of IL-11, IL-11R, and gp130 are present in the receptor complex. Furthermore, it is demonstrated that sites II and III of IL-11 are independent gp130 binding epitopes and that both are essential for gp130 dimerization. We also show that a stable high affinity complex of IL-11, IL-11R, and gp130 can be resolved by nondenaturing polyacrylamide gel electrophoresis, and its composition verified by second dimension denaturing polyacrylamide gel electrophoresis. Results indicate that the three receptor binding sites of IL-11 and the Ig-like domain of gp130 are all essential for this stable receptor complex to be formed. We therefore propose that IL-11 forms a hexameric receptor complex composed of two molecules each of IL-11, IL-11R, and gp130.     

Kaposi's sarcoma-associated herpesvirus-encoded viral interleukin-6 is secreted and modified differently than human interleukin-6: evidence for a unique autocrine signaling mechanism

Viral interleukin-6 (vIL-6) is a homolog of cellular IL-6 that is encoded by the Kaposi's sarcoma-associated herpesvirus (KSHV) genome. vIL-6 binds to the IL-6 signal transducer gp130 without the cooperation of the IL-6 high affinity receptor to induce STAT3 DNA binding and cell proliferation. Although vIL-6 is believed to be important in the pathogenesis of KSHV-induced diseases, its secretion and post-translational modifications have not previously been characterized. Pulse-chase analysis revealed that the half-time of vIL-6 secretion is approximately 8-fold longer than that of human IL-6. Yet, the vIL-6 signal sequence targets human IL-6 secretion to nearly wild-type levels. Surprisingly, vIL-6 was not secreted from a cell line that does not express gp130 but expression of human gp130 in these cells enabled the secretion of vIL-6. Consistent with this observation, complete maturation of gp130 N-glycans is inhibited by vIL-6 coexpression, suggesting that the binding of the receptor to vIL-6 occurs intracellularly in early or pre-Golgi compartments. Furthermore, a vIL-6 mutant containing an endoplasmic reticulum retention signal is not secreted but does still induce receptor activation and signaling. Secreted vIL-6 is completely glycosylated at both possible N-glycosylaton sites and contains a large proportion of immature high-mannose glycans that is not typical of cytokines. These findings suggest that vIL-6 may induce gp130 signaling by an exclusively autocrine mechanism that relies on intracellular binding to its receptor. During KSHV infection, vIL-6 may only induce signaling in KSHV-infected cells to benefit the viral life cycle and promote oncogenic transformation.     

Intracellular signaling mechanisms and activities of human herpesvirus 8 interleukin-6

Human herpesvirus 8 (HHV-8)-encoded viral interleukin-6 (vIL-6) has been implicated as a key factor in virus-associated neoplasia because of its proproliferative and survival effects and also in view of its angiogenic properties. A major difference between vIL-6 and human IL-6 (hIL-6) is that vIL-6, uniquely, is largely retained and can signal intracellularly. While vIL-6 is generally considered to be a lytic gene, several reports have noted its low-level expression in latently infected primary effusion lymphoma (PEL) cultures, in the absence of other lytic gene expression. Thus, intracellular autocrine signal transduction by the viral cytokine may be of particular relevance to the growth and survival of latently infected cells and to pathogenesis. Here we report that most intracellular vIL-6 is located in the endoplasmic reticulum (ER), signals via the gp130 signal transducer in this compartment, and does so independently of the gp80 α-subunit of the IL-6 receptor, required for hIL-6 signal transduction. Signaling and biological assays incorporating ER-retained vIL-6 and hIL-6 confirmed vIL-6 activity, specifically, in this compartment. Knockdown of vIL-6 expression in PEL cells led to markedly reduced cell growth in normal culture, independently of extracellular cytokines. This could be reversed by reintroduction via virus vector of exclusively ER-retained vIL-6. These data indicate that in virus biology vIL-6 may act to support the growth and survival of cells latently infected with HHV-8 in an autocrine manner via intracrine signaling and that these activities may contribute to the maintenance of latently infected cells and to virus-induced neoplasia.     

Generation of interleukin-6 receptor antagonists by molecular-modeling guided mutagenesis of residues important for gp130 activation.

Interleukin-6 (IL-6) drives the sequential assembly of a receptor complex formed by the IL-6 receptor (IL-6R alpha) and the signal transducing subunit, gp130. A model of human IL-6 (hIL-6) was constructed by homology using the structure of bovine granulocyte colony stimulating factor. The modeled cytokine was predicted to interact sequentially with the cytokine binding domains of IL-6R alpha and gp130 bridging them in a way similar to that of the interaction between growth hormone and its homodimeric receptor. Several residues on helices A and C which were predicted as contact points between IL-6 and gp130 and therefore essential for IL-6 signal transduction, were subjected to site-directed mutagenesis individually or in combined form. Interestingly, while single amino acid changes never produced major alterations in IL-6 bioactivity, a subset of double mutants of Y31 and G35 showed a considerable reduction of biological activity and were selectively impaired from associating with gp130 in binding assays in vitro, while they maintained wild-type affinity towards hIL-6-R alpha. More importantly, we demonstrated the antagonistic effect of mutant Y31D/G35F versus wild-type IL-6.     

Purification of receptor complexes of interleukin-10 stoichiometry and the importance of deglycosylation in their crystallization.

Interleukin-10 (IL-10) is a pleiotropic immunosuppressive cytokine that has a wide range of effects in controlling inflammatory responses. Viral IL-10 (vIL-10) is a homologue of human IL-10 (hIL-10) produced by Epstein-Barr virus (EBV). Both hIL-10 and vIL-10 bind to the soluble extracellular fragment of the cytokine receptor IL-10R1 (shIL-10R1). The stoichiometry of the vIL-10 : shIL-10R1 complex has been found to be the same as hIL-10 : shIL-10R1, with two vIL-10 dimers binding to four shIL-10R1 monomers. Complexes of both hIL-10 and vIL-10 with glycosylated shIL-10R1 could not be crystallized. Controlled deglycosylation using peptide : N-glycosidase F and endo-beta-N-acetylglucosaminidase F3 resulted in the formation of crystals of both hIL-10 : shIL-10R1 and vIL-10 : shIL-10R1 complexes, indicating that the difficulty in the crystal formation was largely due to the presence of complex carbohydrate side chains. The availability of the structure of the ligand-receptor complexes should facilitate our understanding of the basis of the interaction between IL-10 and the IL-10 receptor.     

In vitro reconstitution of recognition and activation complexes between interleukin-6 and gp130.

Gp130 is a shared signal-transducing receptor for a family of four-helix cytokines, of which interleukin-6 is a prototypic member. IL-6-type cytokines activate gp130 to elicit downstream intracellular JAK/STAT signaling cascades through formation of hetero-oligomeric receptor complexes. Interleukin-6 must first complex with its specific alpha-receptor (Ralpha) in order to bind and activate gp130. We have dissected the extracellular activation pathway of human gp130 by human IL-6 through reconstitution of soluble complexes representing intermediate and final states in the hierarchical assembly of the IL-6/IL-6Ralpha/gp130 signaling complex. To isolate these hetero-complexes, we have applied a protein engineering strategy of covalently linking IL-6 to its Ralpha, which results in a "hyperactive" single-chain complex (hyper-IL-6) which we express in both Escherichia coli and insect cells. We have determined that IL-6/IL-Ralpha and the cytokine-binding homology region (CHR) of gp130 (D2D3) form a stable trimolecular "recognition" complex (trimer) consisting of 1IL-6,1 IL-6Ralpha, and 1 gp130-CHR. Addition of the N-terminal (D1) Ig-like domain (IGD) of gp130 to the CHR results in a transition to a hexameric "activation" complex containing 2 IL-6, 2IL-6Ralpha, and 2 gp130. These results clearly demonstrate that the recognition and activation complexes are disparate hetero-oligomeric molecular species linked by the recruitment of the gp130 IGD by the unique site III epitope present on all gp130-class cytokines. The results of these studies are relevant to other members of the IL-6 family of gp130-cytokines and address a longstanding question concerning the respective roles of the gp130 CHR and IGD in assembly of the active signaling oligomer.