Expression and localization of p80 and p68 interleukin-1 receptor proteins in the brain of adult mice.

The biological effects of interleukin-1 (IL-1) are mediated by two distinct receptors, the p80 type I IL-1 and p68 type II IL-1 receptor proteins (IL-1RI and IL-1RII, respectively), both of which have been recently co-localized to the growth hormone synthesizing cells of the adenohypophysis. Previous studies have shown that IL-1 can bind to specific structures in the central nervous system, but the distribution of IL-1RI and IL-1RII proteins in the adult mouse brain has not been reported. Here we have used immunohistochemistry to study the expression, distribution and cellular localization of both isoforms of the IL-1 receptor proteins in the adult mouse brain. Using a combination of processing techniques (AMeX fixation and cryosectioning), we have immunolabeled brain sections for each isoform of the IL-1R. Both isoforms are expressed in the CNS, particularly in neuronal soma of the granular layer of the dentate gyrus and pyramidal cells of fields CA1-CA4 of Ammon's horn of the hippocampus, in epithelial cells of the choroid plexus and ependymal layer, and in neuronal soma of Purkinje cells of the cerebellum. The IL-1RII isoform, but not IL-1RI, is expressed in specific neuronal soma and proximal cell processes of neurons of the paraventricular gray matter of the hypothalamus. These immunohistochemical data directly demonstrate the neuronal expression of both IL-1R proteins in situ. The distribution and cellular localization of IL-1R proteins in the CNS provide a molecular basis for understanding reciprocal interactions between the immune system and the brain.

IL-1 receptor accessory protein is an essential component of the IL-1 receptor.

The recently described IL-1R accessory protein (IL-1R AcP) interacts with IL-1beta and the IL-1 type-IR (IL-1RI), but an essential requirement for IL-1R AcP in IL-1 signaling in vitro has not been established and its role in vivo has not been examined. In this study, IL-1R AcP-deficient mice and fibroblasts were produced and characterized. All IL-1 agonists bound to IL-1R AcP-deficient cells through the type I IL-1R, but failed to activate gene expression through either the nuclear factor-kappaB or AP-1-dependent signaling pathways. Absence of IL-1R AcP differentially affected the affinity for IL-1 ligands. IL-1R AcP-deficient fibroblasts bound murine IL-1alpha and human IL-1R antagonist protein (IL-1Ra) with only moderately reduced affinity when compared with wild-type cells, whereas murine IL-1beta affinity was reduced by 70-fold. IL-1 also failed to produce a biologic response in vivo in IL-1R AcP-deficient mice. These data demonstrate that a type I IL-1R/IL-1R AcP complex is required for signaling by all IL-1 agonists and for high affinity binding by IL-1beta. Finally, IL-1R AcP is an essential signal transducing component of the functional IL-1R and should represent a novel target for blocking IL-1 function in human disease.

Analysis of the multiple interactions between IL-12 and the high affinity IL-12 receptor complex.

IL-12 is a heterodimeric cytokine, composed of a p40 and a p35 subunit, that exerts its biological effects by binding to specific cell surface receptors. Two IL-12R proteins, designated human IL-12 (huIL-12) receptor beta1 (huIL-12Rbeta1) and huIL-12Rbeta2, have been previously identified. These IL-12R individually bind huIL-12 with low affinity and in combination bind huIL-12 with high affinity and confer IL-12 responsiveness. In this study the interactions of hulL-12 with these two identified human IL-12R protein subunits are examined. The heterodimer-specific anti-huIL-12 mAb 20C2, which neutralizes huIL-12 bioactivity but does not block 125I-huIL-12 binding to huIL-12Rbeta1, blocked binding of huIL-12 to huIL-12Rbeta2. In contrast, anti-huIL-12Rbeta1 mAb 2B10 and mouse IL-12 p40 subunit homodimer (mo(p40)2) blocked 125I-huIL-12 binding to huIL-12Rbeta1, but not to huIL-12Rbeta2. Therefore, two classes of IL-12 inhibitors can be identified that differ in their ability to block huIL-12 interaction with either huIL-12Rbeta1 or huIL-12Rbeta2. Both mo(p40)2 and 20C2 blocked high affinity binding to huIL-12Rbeta1/beta2-cotransfected COS-7 cells, although, as previously reported, mo(p40)2 does not block high affinity binding to IL-12R on PHA-activated human lymphoblasts. Furthermore, these two classes of IL-12 inhibitors synergistically decreased hulL-12-stimulated proliferation and IFN-gamma production. Therefore, IL-12, in binding to the high affinity IL-12R, interacts with IL-12Rbeta1 primarily via regions on the IL-12 p40 subunit and with IL-12Rbeta2 via 20C2-reactive, heterodimer-specific regions of IL-12 to which the p35 and p40 subunits both contribute.

Comparison of the effects of interleukin-1 alpha, interleukin-1 beta and interferon-gamma-inducing factor on the production of interferon-gamma by natural killer.

Interferon-gamma inducing factor (IGIF) is a recently identified cytokine which stimulates the production of interferon-gamma (IFN-gamma) by T cells and enhances natural killer (NK) cell cytolytic activity. Protein fold recognition, structure prediction and comparative modeling have revealed that IGIF is a member of the interleukin (IL)-1 cytokine family and has prompted the designation IL-1 gamma. Here we report functional similarities between members of the IL-1 family by comparing the effects of IL-1 alpha, IL-1 beta and IGIF on NK cell production of IFN-gamma. All three IL-1 types enhanced NK cell production of IFN-gamma when induced by IL-2 or IL-12, although at high concentrations (> 10 ng/ml), IGIF was five- to tenfold more potent than IL-1 alpha or IL-1 beta. This effect correlated with enhanced levels of mRNA for IFN-gamma when NK cells were stimulated with IGIF plus IL-12. In contrast to IL-12 and IL-2, the ability of IGIF to stimulate NK cell production of IFN-gamma was not increased by IL-1 alpha or IL-1 beta. The ability of IGIF to enhance IFN-gamma production was independent of the type I and type II IL-1 receptors or the IL-1R accessory protein. Together, these results identify IGIF as a potent stimulator of NK cell production of IFN-gamma and demonstrate that the effect of IGIF on NK cell production of IFN-gamma is similar to that of IL-1 alpha and IL-1 beta but distinct from that of IL-12.

Absence of IL-1 signaling and reduced inflammatory response in IL-1 type I receptor-deficient mice.

IL-1alpha and IL-1beta are potent inflammatory cytokines that contribute to a number of normal physiologic processes and to the development of a number of inflammatory diseases. Two IL-1R, the type I and type II receptors, have been identified. This work describes the derivation and characterization of mice deficient in expression of the type I IL-1R (IL-1RI). IL-1RI-deficient mice were viable and fertile, but failed to respond to IL-1 in a variety of assays, including IL-1-induced IL-6 and E-selectin expression and IL-1-induced fever. Similar to IL-1beta-deficient mice, IL-1RI-deficient mice had a reduced acute phase response to turpentine. In contrast, IL-1RI-deficient mice had a reduced delayed-type hypersensitivity response and were highly susceptible to infection by Listeria monocytogenes. These data demonstrate that the IL-1RI is essential for all IL-1-mediated signaling events examined, and that both IL-1alpha and IL-1beta are critical to the animals' response to injury and infection. These data also demonstrate that IL-1 function is not required for normal development or homeostasis.

Preferential localization of systemically administered radiolabeled interleukin 1alpha in experimental inflammation in mice by binding to the type II receptor.

Previously, we have shown that systemically administered radiolabeled interleukin 1alpha (IL-1alpha) accumulates preferentially in inflammatory foci in mice. Since inflammation is characterized by influx of leukocytes, which represent IL-1 receptor (IL-1R) positive cells, radiolabeled IL-1 may specifically localize in inflammation by binding to its receptors on infiltrated leukocytes. This hypothesis was tested in a series of studies in mice with acute focal inflammations. Evidence for specific IL-1-IL-1R interaction in induced inflammation was found: microscopic autoradiography revealed that 125I-IL-1alpha localized at the site of inflammatory cells with time; 125I-myoglobin, a similar-sized protein with no known interactions in vivo, was not retained in the inflammation. Furthermore, the uptake 125I-IL-1alpha in inflammatory tissue was significantly lower in neutropenic mice than in immunocompetent mice (0.05+/-0.004 vs. 0.65+/-0.06% ID/g at 48 h after injection, P < 0.0007). Moreover, the uptake of 125I-IL-1alpha at the inflammatory site could be blocked with the anti-IL-1R type II antibody 4E2. At 48 h after injection, the uptake with and without blocking the type II IL-1R was 0.13+/-0.01 and 0. 65+/-0.05% ID/g, respectively (P < 0.0001). These in vivo studies provide evidence that systemically administered radiolabeled IL-1alpha localizes in inflammatory tissue by specific receptor binding, predominantly by binding to the type II IL-1R.

Evidence for multiple sites of interaction between IL-12 and its receptor.

We have previously described the identification of a protein, now designated IL-12R beta 1, that binds 125I-huIL-12 with a Kd of about 10 nM, corresponding to the low affinity 125I-huIL-12 binding sites seen on PHA-activated human lymphoblasts. Using expression cloning techniques, we have recently identified an additional IL-12-binding protein subunit, IL-12R beta 2, which binds 125I-huIL-12 with a Kd of about 5 nM when expressed alone in COS-7 cells. Coexpression of IL-12R beta 1 and IL-12R beta 2 in COS-7 cells results in formation of two classes of 125 I-huIL-12-binding sites with Kds of about 50 pM and 5 nM. Mouse IL-12 p40 subunit homodimer (mo(p40)2) blocked 125I-huIL-12 binding to human IL-12R beta 1, but did not inhibit binding to human IL-12R beta 2. In contrast, anti-huIL-12 monoclonal antibody 20C2, which does not block 125I-huIL-12 binding to human IL-12R beta 1, completely blocked binding to human IL-12R beta 2. These results demonstrate that two classes of IL-12 inhibitors, one that primarily blocks IL-12/IL-12R beta 1 interaction (e.g., mo(p40)2), and one that primarily blocks IL-12/IL-12R beta 2 interaction (e.g., 20C2), can be identified.

Interaction of phosphorylated FcepsilonRIgamma immunoglobulin receptor tyrosine activation motif-based peptides with dual and single SH2 domains of p72syk. Assessment of binding parameters and real time binding kinetics.

To examine the characteristics of the interaction of the FcepsilonRIgamma ITAM with the SH2 domains of p72(syk), the binding of an 125I-labeled dual phosphorylated FcepsilonRIgamma ITAM-based peptide to the p72(syk) SH2 domains was monitored utilizing a novel scintillation proximity based assay. The Kd for this interaction, determined from the saturation binding isotherm, was 1.4 nM. This high affinity binding was reflected in the rapid rate of association for the peptide binding to the SH2 domains. Competition studies utilizing a soluble C-terminal SH2 domain knockout and N-terminal SH2 domain knockouts revealed that both domains contribute cooperatively to the high affinity binding. Unlabeled dual phosphorylated peptide competed with the 125I-labeled peptide for binding to the dual p72(syk) SH2 domains with an IC50 value of 4.8 nM. Monophosphorylated 24-mer FcepsilonRIgamma ITAM peptides, and phosphotyrosine also competed for binding, but with substantially higher IC50 values. This, and other data discussed, suggest that high affinity binding requires both tyrosine residues to be phosphorylated and that the preferred binding orientation of the ITAM is such that the N-terminal phosphotyrosine occupies the C-terminal SH2 domain and the C-terminal phosphotyrosine occupies the N-terminal SH2 domain.

Dual expression of p80 type I and p68 type II interleukin-I receptors on anterior pituitary cells synthesizing growth hormone.

Interleukin-1 alpha (IL-1 alpha) and IL-1 beta bind to either the p80 type I IL-1 receptor (IL-1RI) or the p68 type II IL-1R (IL-1RII) on both T and B lymphocytes. We and others have previously shown that the anterior pituitary gland also has specific high affinity binding sites for IL-1 alpha (Kd = approximately 1 nM) and expresses transcripts for both isoforms of the IL-1R. However, the identity of cells in the anterior pituitary gland that express the IL-1R and whether different populations of adenohypophyseal cells express different isoforms of the IL-1R remain unknown. Here we have used a combination of immunohistochemistry and histochemistry to localize IL-1RI and IL-1RII to specific target cells in the mouse anterior pituitary gland. Perfusion-fixed, paraffin-embedded sections of anterior pituitary gland were immunolabeled with well characterized monoclonal antibodies to either IL-1RI or IL-1RII and counterstained using a modified Gomori's method to document acidophils and basophils. Immunolabeling demonstrated that both IL-1RI and IL-1RII were abundantly expressed on a single population of anterior pituitary gland cells and that these cells could be classified on the basis of histochemical staining as a subpopulation of acidophils. The distribution, morphology, and proportion of cells immunolabeled for IL-1RI and IL-1RII were consistent with GH-synthesizing cells. To confirm this hypothesis, a modified indirect avidin-biotin complex, sequential peroxidase/alkaline phosphatase technique was used to label anterior pituitary gland cells with antibodies to IL-1RI followed by antibodies to IL-1RII, GH, PRL, or ACTH. The IL-1RI-positive cells predominately coexpressed IL-1RII and GH, but very little, if any, PRL or ACTH. These data establish that the predominant cell population in the murine anterior pituitary gland that constitutively expresses IL-1R stain as acidophils histochemically, is round to oval with dense granular cytoplasm and eccentric nuclei, synthesizes GH, and simultaneously expresses IL-1RI and IL-1RII isoforms.

Visceral ischemia-reperfusion injury promotes tumor necrosis factor (TNF) and interleukin-1 (IL-1) dependent organ injury in the mouse.

Acute visceral ischemia and subsequent reperfusion injury, which accompanies the surgical repair of a thoracoabdominal aorta aneurysm, is associated with high rates of morbidity and mortality. The purpose of the present study was to determine whether endogenous tumor necrosis factor-alpha (TNF-alpha) and interleukin-1 (IL-1) production contributes to organ dysfunction in animals subjected to visceral ischemia secondary to 30 min of supraceliac aortic occlusion. C57BL6/j mice were treated with either a TNF binding protein (TNF-bp-10 mg/kg) or an anti-IL-1 receptor type 1 antibody (150 micrograms) 2 h prior to 30 min of supraceliac aortic occlusion. An additional group of mice received 30 min of infrarenal aortic occlusion to determine the contribution of lower torso ischemia-reperfusion injury to the changes seen following supraceliac aortic occlusion. Visceral organ ischemia for 30 min produced by supraceliac aortic occlusion followed by 2 h of reperfusion produced measurable TNF-alpha in 38% of untreated mice, but TNF-alpha was undetectable in both sham-operated mice and following infrarenal aortic occlusion. After 2 h of reperfusion, lung myeloperoxidase levels were significantly elevated in the mice experiencing visceral ischemia-reperfusion compared with either a sham operation or infrarenal ischemia-reperfusion (11.6 +/- 1.3 U/g vs. 3.4 +/- .2 U/g and 3.7 +/- 1.0 U/g, respectively, p < .05). Pretreatment with TNF-bp and anti-IL-1 antibody decreased lung neutrophil recruitment (7.2 +/- 1.2 U/g and 4.6 +/- 1.1 U/g) and capillary membrane permeability changes in mice following visceral ischemia-reperfusion. The present study demonstrates that brief (30 min) clinically relevant visceral ischemia produces TNF-alpha and IL-1 dependent lung injury.

Biological function and distribution of human interleukin-12 receptor beta chain.

We previously described the cloning of a cDNA encoding an interleukin-12 receptor (IL-12R) subunit, designated beta, that bound IL-12 with low affinity when expressed in COS cells. We now report that a pair of monoclonal antibodies (mAb), 2B10 and 2.4E6, directed against different epitopes on the IL-12R beta chain, when used in combination, strongly inhibited IL-12-induced proliferation of activated T cells, IL-12-induced secretion of interferon-gamma by resting peripheral blood mononuclear cells (PBMC), and IL-12-mediated lymphokine-activated killer cell activation. The mAb had no effect on lymphoblast proliferation induced by IL-2, -4, or -7. Thus, the IL-12R beta chain appears to be an essential component of the functional IL-12R on both T and natural killer (NK) cells. We previously observed that high affinity IL-12R were expressed on activated T and NK cells, but not B cells. Studies using flow cytometry and reverse transcription-polymerase chain reaction analysis showed that IL-12R beta chain was expressed on several human T, NK, and (surprisingly) B cell lines, but not on non-lymphohematopoietic cell lines. The Kit225/K6 (T cell) and SKW6.4 (B cell) lines were found to express the greatest amounts of IL-12R beta chain (800-2500 sites/cell); however, Kit225/K6 but not SKW6.4 cells bound IL-12. Similar to SKW6.4 B cells, activated tonsillar B lymphocytes expressed IL-12R beta chain but, consistent with previous results, did not display detectable IL-12 binding. Likewise, up to 72% of resting PBMC from normal volunteer donors expressed IL-12R beta, but did not bind measurable amounts of IL-12. These results indicate that expression of IL-12R beta is essential, but not sufficient, for expression of functional IL-12R. We speculate that expression of functional, high-affinity IL-12R may require the presence of a second subunit that is more restricted in its expression than IL-12R beta.

IL-1 beta is required for IL-12 to induce production of IFN-gamma by NK cells. A role for IL-1 beta in the T cell-independent mechanism of resistance against intracellular pathogens.

Mice with the severe combined immunodeficiency (SCID) possess an IFN-gamma-dependent mechanism of resistance to the intracellular pathogens Toxoplasma gondii and Listeria monocytogenes that is dependent on IL-12-induced production of IFN-gamma by NK cells. In this report we demonstrate that IL-1 beta is required for IL-12 to stimulate production of IFN-gamma by NK cells, and that IL-1 is important in IL-12-mediated resistance to T. gondii in vivo. Stimulation of SCID mouse splenocytes with tachyzoites of T. gondii resulted in production of IFN-gamma. Addition of neutralizing Ab specific for IL-1 beta to these cultures inhibited completely the production of IFN-gamma. Similar results were obtained when LPS or L. monocytogenes were used to stimulate production of IFN-gamma by SCID mouse splenocytes. Addition of a neutralizing Ab to IL-1 alpha did not affect production of IFN-gamma by SCID mouse splenocytes stimulated with T. gondii, L. monocytogenes, or LPS. Stimulation of SCID mouse splenocytes with IL-1 beta or IL-1 alpha did not result in production of IFN-gamma but enhanced remarkably the ability of T. gondii or IL-12 to stimulate production of IFN-gamma. Furthermore, production of IFN-gamma by SCID mouse splenocytes stimulated with IL-12 plus TNF-alpha was completely ablated by anti-IL-1 beta, but not by anti-IL-1 alpha. Analysis of the culture supernatants of spleen cells from SCID mice stimulated with T. gondii or IL-12 plus TNF-alpha detected low levels of IL-1 beta; addition of a neutralizing Ab to IFN-gamma resulted in a 5- to 10-fold increase in levels of IL-1 beta. Furthermore, stimulation of SCID mouse splenocytes with IL-12, in the presence of anti-IFN-gamma, resulted in an increase in detectable levels of IL-1 beta. To determine the in vivo relevance of our in vitro data, SCID mice were infected with T. gondii and treated with IL-12 alone or IL-12 in combination with an Ab specific for the type I IL-1 receptor. This Ab reduced production of IFN-gamma by SCID mouse splenocytes stimulated with either T. gondii, LPS, L. monocytogenes, or IL-12 plus IL-1 beta. In vivo administration of this Ab antagonized significantly the ability of exogenous IL-12 to delay the time to death of SCID mice infected with T. gondii.(ABSTRACT TRUNCATED AT 400 WORDS)

Interleukin 1 binding to its type I, but not type II receptor, modulates the in vivo acute phase response.

Neutralizing monoclonal antibodies against the murine interleukin 1 (IL-1) type I (mAb 35F5) and type II receptor (mAb 4E2) were used to passively immunize mice prior to exogenous murine IL-1 alpha administration or a sterile-turpentine induced abscess. When mice were passively immunized with 35F5, the anorexia, weight loss and increased plasma acute phase protein levels in response to exogenous IL-1 alpha administration or a turpentine abscess were significantly attenuated. In contrast, passive immunization with 4E2 had only variable effects on food intake, body weight and the hepatic acute phase response in mice administered IL-1 alpha. In mice following a turpentine abscess, type II receptor blockade (4E2) either had no effect, or in some cases, actually increased the plasma IL-6 and acute phase protein responses. We conclude that in response to a turpentine abscess, the anorexia, weight loss and the induction of several hepatic acute phase reactants result in part from IL-1 binding to its type I receptor. Binding of IL-1 to the type II IL-1 receptor does not appear to be involved in the induction of these host nonspecific responses to inflammation.

Molecular cloning and characterization of a second subunit of the interleukin 1 receptor complex.

A monoclonal antibody (mAb) was isolated that blocked the binding and bioactivity of both human and murine interleukin 1 beta (IL-1 beta) on murine IL-1 receptor-bearing cells. This mAb recognized a protein that was distinct from the Type I and Type II IL-1 receptors, suggesting that an additional protein exists that is involved in IL-1 biological responses. By expression cloning in COS-7 cells, we have isolated a cDNA from mouse 3T3-LI cells encoding this putative auxiliary molecule, which we term the IL-1 receptor accessory protein (IL-1R AcP). Sequence analysis of the cDNA predicts an open reading frame that encodes a 570-amino acid protein with a molecular mass of approximately 66 kDa. The IL-1R AcP is a member of the Ig superfamily by analysis of its putative extracellular domain and also bears limited homology throughout the protein to both Type I and Type II IL-1 receptors. Northern analysis reveals that murine IL-1R AcP mRNA is expressed in many tissues and appears to be regulated by IL-1. In mammalian cells expressing natural or recombinant Type I IL-1R and IL-1R AcP, the accessory protein forms a complex with the Type I IL-1R and either IL-1 alpha or IL-1 beta but not IL-1ra. The recombinant accessory protein also increases the binding affinity of the recombinant Type I IL-1R for IL-1 beta when the two receptor proteins are coexpressed. Therefore, the functional IL-1 receptor appears to be a complex composed of at least two subunits.

Biologic effects of recombinant human interleukin-12 in squirrel monkeys (Sciureus saimiri).

BACKGROUND: Interleukin-12 is a novel heterodimeric cytokine that stimulates the proliferation of activated T and NK cells and induces lymphokine-activated killer cell activity in vitro. To investigate the biological effects of recombinant human IL-12 (rHuIL-12) in vivo, two exploratory studies were conducted in squirrel monkeys (Sciureus saimiri), which have been shown to be pharmacologically responsive to rHuIL-12 in vitro. EXPERIMENTAL DESIGN: In the first study, 18 monkeys (3/sex/group) were given daily subcutaneous injections of 0 (vehicle control), 10, or 50 micrograms/kg/day rHuIL-12 for 14 days. In the second study, 18 monkeys were given 0, 0.1, or 1 micrograms/kg/day rHuIL-12 for 14 days The animals were monitored for clinical signs, hematology and clinical chemistry changes, and sacrificed on day 15 to evaluate gross and histopathologic changes. One monkey in the high dose group was sacrificed moribund on day 14. RESULTS: Monkeys given rHuIL-12 had dose-related hematologic changes characterized by mild to moderate anemia and leukocytosis. Serum chemistry changes included hypoproteinemia, hypoalbuminemia, hypophosphatemia, and hypocalcemia. Gross pathologic findings included generalized lymph node enlargement and splenomegaly with pulmonary edema and peritoneal effusions in two high dose monkeys. Dose-related histopathologic findings included thymic cortical atrophy, splenic lymphoid hyperplasia with histiocytic hyperplasia and extramedullary hematopoiesis of red pulp, Kupffer cell hypertrophy and hyperplasia, trilineage bone marrow hyperplasia, and reactive hyperplasia of lymph nodes. Animals in the 10 and 50 micrograms/kg/day dose groups developed high titers of anti-rHuIL-12 antibodies by day 15. CONCLUSIONS: These studies indicate that rHuIL-12 is bioactive over a wide dose range and induces prominent hyperplasia of hematopoietic and lymphohistiocytic tissues in squirrel monkeys. Moreover, positive immunomodulatory activity (enhanced lymphocyte lytic activity) was detected at a dose of rHuIL-12 that is 500-fold less than the dose causing severe toxicity.

Suramin blocks the binding of interleukin-1 to its receptor and neutralizes IL-1 biological activities.

This report demonstrates the ability of the anti-cancer drug suramin to interfere with the binding of interleukin (IL)-1 to its receptor and to inhibit IL-1-induced biological activities. In a radioreceptor cell based assay, suramin inhibits the binding of IL-1 alpha to several murine cell lines expressing predominantly type I and type II IL-1 receptors. Affinity cross-linking experiments using IL-1 alpha and EL-4.6.1 cells confirms that suramin inhibits the binding of the ligand to the 80 kDa IL-1 type I receptor. In contrast, suramin fails to displace significantly prebound IL-1. In a cell-free system, suramin prevents the binding of IL-1 alpha and IL-1 beta to murine and human recombinant soluble type I IL-1 receptors. For example, the IC50 for suramin inhibiting IL-1 alpha and IL-1 beta binding to soluble human IL-1 receptor were 204 microM and 186 microM, respectively. The suramin analogues, NF-058 and NF-103 (which bear the same number of sulfate groups as suramin), are between three- and ten-fold less active than suramin in inhibiting IL-1 binding to EL-4.6.1 cells, and to recombinant soluble IL-1 receptor. Furthermore, in a dose-dependent manner suramin prevents several IL-1 mediated biological responses, including thymocyte proliferation, PGE-2 synthesis and IL-6 production. The inhibitory effect of the drug can be significantly reversed by the addition of excess cytokine. Taken together, the results indicate that suramin is a competitive IL-1 receptor antagonist. Because IL-1 participates in a broad range of immunological and inflammatory functions, the data suggest that suramin administration may influence important activities beyond those associated strictly with tumor inhibition.

Interleukin 12, interferon gamma, and tumor necrosis factor alpha are the key cytokines of the generalized Shwartzman reaction.

The Shwartzman reaction is elicited by two injections of lipopolysaccharide (LPS) in mice. The priming LPS injection is given in the footpad, whereas the lethal LPS challenge is given intravenously 24 h later. The injection of interferon gamma (IFN-gamma) or interleukin 12 (IL-12) instead of the LPS priming injection induced the lethal reaction in mice further challenged with LPS. Antibodies against IFN-gamma when given together with the priming agent, prevented the lethal reaction in mice primed with either LPS, IL-12, or IFN-gamma. Antibodies against IL-12, when given together with the priming agent, prevented the lethal reaction in mice primed with either LPS or IL-12 but not with IFN-gamma. These results strongly suggest that LPS induces the release of IL-12, that IL-12 induces the production of IFN-gamma, and that IFN-gamma is the cytokine that primes macrophages and other cell types. Upon LPS challenge, the lethal Shwartzman reaction is induced by a massive production of inflammatory cytokines that act on the target sites already sensitized by IFN-gamma. If mixtures of TNF and IL-1 or mixtures of TNF and IFN-gamma are used to challenge mice previously primed with IFN-gamma or IL-12, mortality is induced. In the same conditions, the individual cytokines or a mixture of IL-1 and IFN-gamma do not replace the LPS challenge. When the mice are primed with LPS, the combination of TNF, IL-1, and IFN-gamma induced only a partial mortality incidence suggesting that the involvement of other LPS-induced factors.

Interleukin-1 (IL-1) directly and indirectly promotes hematopoietic cell growth through type I IL-1 receptor.

Interleukin-1 (IL-1) has been shown to stimulate hematopoietic progenitor cell growth both in vitro and in vivo. Although IL-1 alone lacks the ability to promote hematopoietic progenitor growth in vitro, it is a potent synergistic factor in combination with other colony-stimulating factors (CSFs). Because it was unknown whether type I (p80), type II (p68), or other IL-1-binding proteins mediated the synergistic effects of IL-1 on purified progenitor cells, we used the difference in immunoreactivity between type I and type II IL-1 receptor (IL-1R) to better assess the role of these receptors in hematopoietic progenitor growth. Therefore, the synergistic effects of IL-1 alpha on IL-3-, CSF-1-, and granulocyte macrophage (GM)-CSF-induced progenitor growth, both in CFU-c and single-cell assays, were determined in the presence of monoclonal antibodies (MoAbs) 35F5 and 4E2 that block the binding of IL-1 alpha to type I and type II IL-1R, respectively. The synergistic effect of IL-1 alpha on IL-3 responsive Lin- and Lin(-)-Thy-1+ progenitors was indirectly mediated and could be inhibited by MoAb 35F5. In contrast, IL-1 alpha directly synergized with CSF-1 and GM-CSF to promote progenitor cell growth. The direct synergistic effect of IL-1 alpha on CSF-1-induced progenitor growth was observed in all progenitor populations examined (Lin-, Lin-Thy-1+, and Lin-Thy-1-) and was inhibited by MoAb 35F5. However, the direct synergistic effect of IL-1 alpha on GM-CSF-responsive progenitors. Lin- and Lin-Thy-1+, was partially inhibited by MoAb 35F5. In contrast, the MoAb antitype II IL-1R (MoAb 4E2) could not inhibit the direct synergistic effects of IL-1 alpha on CSF-1- or GM-CSF-induced progenitor growth. Thus, IL-1 alpha directly and indirectly stimulates the growth and differentiation of purified progenitors through the type I IL-1R but not the type II IL-1R.

Expression cloning of a human IL-12 receptor component. A new member of the cytokine receptor superfamily with strong homology to gp130.

A cDNA encoding a human IL-12R subunit was isolated by expression cloning. This subunit is a 662 amino acid type I transmembrane protein with an extracellular domain of 516 amino acids and a cytoplasmic domain of 91 amino acids. It is a member of the hemopoietin receptor superfamily and is most closely related over its entire length to gp130 and the receptors for granulocyte-CSF (G-CSF) and leukemia-inhibitory factor. When expressed in COS cells, this IL-12R subunit binds both human and murine IL-12 with an apparent affinity of 2 to 5 nM. The transfected COS cells express both monomers and disulfide-linked dimers or oligomers of the IL-12R subunit on their surface. However, unlike the IL-6-induced dimerization of gp130, the oligomerization of the IL-12R subunit is not dependent on binding of IL-12. Only the IL-12R subunit dimers/oligomers but not the monomers bind IL-12 with an affinity of 2 to 5 nM. A polyclonal antiserum raised against this receptor subunit specifically inhibits IL-12-induced proliferation of PHA-activated PBMC. The data are consistent with the hypotheses that 1) a dimer/oligomer of the cloned IL-12R subunit (IL-12R-beta) represents the low affinity IL-12 binding site identified on human lymphoblasts, 2) the cloned receptor subunit is involved in IL-12 signal transduction, and 3) an additional, as of yet unidentified subunit is required to generate a high affinity IL-12R complex.