Interleukin 2 functions through novel interleukin 2 binding molecules in T cells

In this report, we examined whether novel interleukin 2 (IL-2) binding molecules (p70/75) are responsible for signal transduction and internalization of IL-2 in T cells by using a monoclonal antibody H-31 to Tac antigens. We found that H-31 inhibited the binding of IL-2 to Tac antigens but not novel IL-2 binding molecules. Scatchard plot analysis revealed that in the presence of H-31, intermediate affinity sites (Kd = 1 to 1.5 nM) were detectable and the number of them was similar to that of high affinity IL-2 receptor (IL-2R) (Kd = 10 to 15 pM) in the absence of H-31. Furthermore, the kinetics of endocytosis of IL-2 via p70/75 showed the same pattern as via high affinity IL-2R. Finally, high doses of IL-2 (100 to 10,000 U/ml) are required for the proliferation of T cells in the presence of H-31, whereas in the absence of H-31, physiologic doses of IL-2 (1 to 100 U/ml) induced the proliferation. These results taken together suggest that novel IL-2 binding molecules are related to signal transduction of IL-2 and that Tac antigens are essential for constructing of high affinity IL-2R, although Tac antigens may not be responsible for signal transduction.     

Subunit structure of the high and low affinity human interleukin-15 receptors

Radio-iodinated cytokines and monoclonal antibodies directed at the IL-2R beta- and gamma-chains were used to analyze the structure of the cell-surface IL-15 and IL-2 receptors expressed by the human lymphoma cell clone YT-2C2. YT-2C2 cells are IL-2R alpha negative and express IL-2R gamma (15,000 molecules/cell) in excess of IL-2R beta (11,000 molecules/cell). Accordingly, they display a number of beta/gamma complexes of intermediate affinity for IL-2 and IL-15 which is equivalent to the number of beta-chains. Both cytokines compete for binding to this beta/gamma complex. There are about 800 high affinity IL-15 receptors, suggesting the presence of a similar number of IL-15R alpha-chains. Within the common intermediate affinity beta/gamma-complex, the anti-beta-chain A41 mAb defines an epitope which is similarly engaged in IL-2 and IL-15 binding, whereas the anti-beta-chain 284 mAb defines an epitope which does not display similar interaction with either cytokines. Thus, although IL-2 and IL-15 compete for binding to this beta/gamma-complex, they do not use similar binding areas. Cross-linking and immunoprecipitation experiments have shown that the high affinity IL-15 receptors comprises IL-2R beta/gamma, in association with IL-15R alpha and that the three chains can be efficiently cross-linked to IL-15 and co-immunoprecipitated. Contrary to the intermediate affinity situation, high affinity IL-15 binding and subunit cross-linking were not affected by excess amounts of IL-2, A41 or 284 mAb, suggesting that when engaged in the IL-15 high affinity complex, the beta- and gamma-chains adopt different conformations, at least with respect to IL-15 binding. Finally, we provide evidence for the participation of a novel 35 kDa component within the high affinity structure. This component is immunoprecipitated with anti-IL-2R gamma mAb but not with anti-IL-2R beta mAb and might correspond to a truncated form of IL-2R gamma-chain.     

Presence of a p70 IL-2-binding peptide on leukemic cells from various hemopoietic lineages

Recent studies have shown that IL-2R are composed of at least two polypeptide chains of 55 kDa (Tac or alpha-chain) and 70 to 75 kDa (p70 or beta-chain). The association of both chains forms high affinity IL-2R, whereas each chain alone binds IL-2 with a low (alpha-chain) or intermediate (beta-chain) affinity. So far, the p70 peptide has been found, in the absence of the Tac peptide, on the surface of lymphoid cells of T, B, or NK lineage. In this study, we investigated whether leukemic cells of various hemopoietic lineages expressed the p70 IL-2-binding protein. We found that both fresh leukemic cells obtained from patients, and cells from established leukemic lines of T cells, B cell, and myeloid origin constitutively expressed a p70 IL-2-binding protein on their surface, as detected by affinity cross-linking of radioiodinated IL-2. IL-2 binding and cross-linking to these cells was completely inhibited in the presence of an excess unlabeled rIL-2, but not with an anti-Tac mAb. Binding experiments on pre-B and myeloid cell lines revealed intermediate affinity IL-2R, whereas both high and intermediate affinity IL-2R were detected in T leukemic cells. The intermediate affinity binding of 125I-rIL-2 to the leukemic cell lines MOLT4 and Reh6 was inhibited by the TU27 mAb, which recognized the p75 chain of IL-2R. Moreover, the TU27 mAb could stain the K562, KM3, and MOLT4 (weakly) cell lines by indirect immunofluorescence. A high dose of rIL-2 (400 U/ml) enhanced the proliferation of cells from one out of three patients with acute myeloblastic leukemia, but it did not induce differentiation of the cells in any of three cases. Thus the finding of p70 IL-2-binding molecules on immature lymphoid and nonlymphoid hemopoietic cells should disclose new biologic functions for IL-2.     

IL-18 receptors, their role in ligand binding and function: anti-IL-1RAcPL antibody, a potent antagonist of IL-18

IL-18 is critical in eliciting IFN-gamma production from Th1 cells both in vitro and in vivo. Th1 cells have been implicated in the pathogenesis of autoimmune disorders, making antagonists of IL-18 promising therapeutics. However, specificity and binding characteristics of IL-18R components have only been superficially explored. In this study, we show that IL-1R related protein 1 (IL-1Rrp1) and IL-1R accessory protein-like (IL-1RAcPL) confer responsiveness to IL-18 in a highly specific (no response to other IL-1 ligands) and unique manner (no functional pairing with other IL-1Rs and IL-1R-like molecules). Cotransfection with both receptor components resulted in expression of both low and high affinity binding sites for IL-18 (K:(d) of 11 and 0.4 nM, respectively). We prepared anti-IL-1RAcPL mAb TC30-28E3, which, in contrast to soluble R proteins, effectively inhibited the IL-18-induced activation of NF-kappaB. Quantitative PCR showed that Th1 but not Th2 cells are unique in that they coexpress IL-1Rrp1 and IL-1RAcPL. mAb TC30-28E3 inhibited IL-18-induced production of IFN-gamma by Th1 cells, being at least 10-fold more potent than anti-IL-18 ligand mAb. This study shows that IL-1RAcPL is highly specific to IL-18, is required for high affinity binding of IL-18, and that the anti-IL-1RAcPL mAb TC30-28E3 potently antagonizes IL-18 responses in vitro, providing a rationale for the use of anti-IL-1RAcPL Abs to inhibit Th1-mediated inflammatory pathologies.     

Cooperation between an anti-T cell (anti-CD28) monoclonal antibody and monocyte-produced IL-6 in the induction of T cell responsiveness to IL-2

CD28 is an Ag of 44-kDa Mr that is expressed on the membrane of the majority of human T cells and that is recognized by mAb 9.3. The functional effects of mAb 9.3 on peripheral blood T cells were studied. mAb 9.3 was not mitogenic, unless it was combined with PMA. When CD28 was cross-linked after binding of mAb 9.3 to the T cell by immobilized or soluble anti-mouse IgG, T cells proliferated in response to rIL-2, provided that monocytes were also present. The additional signal required for IL-2 responsiveness after cross-linking of CD28 could also be delivered in cultures of purified T cells by a cellfree monocyte culture supernatant. Expression of IL-2R on about 10% of the T cells was demonstrated by staining with an anti-IL-2R mAb, and was found to be largely restricted to CD4+ cells. The active compound responsible for the helper signal in the monocyte culture supernatant was identified as IL-6 because purified IL-6 (but not IL-1 beta) had similar activity and because an antiserum to IL-6 (but not an antiserum to IL-1 beta) neutralized the activity of the monocyte supernatant and blocked T cell proliferation. An anti-IL-2R antibody also completely inhibited T cell proliferation induced by the combination of mAb 9.3, IL-2, and IL-6. Our results provide evidence that cross-linking of CD28 induces functional IL-2R and that this activity is dependent on a helper signal provided by monocytes, more specifically IL-6. Moreover, our results indicate that IL-6 (previously called B cell stimulatory factor-2) is active on T cells. If a natural ligand for CD28 can be identified, the mechanism of induction of IL-2 responsiveness described here might explain how T cells become nonspecifically involved in an ongoing cellular immune reaction.     

Identification of the second subunit of the murine interleukin-5 receptor: interleukin-3 receptor-like protein, AIC2B is a component of the high affinity interleukin-5 receptor.

Murine interleukin-5 (IL-5) binds to its receptor with high and low affinity. It has been shown that the high affinity IL-5 receptor (IL-5-R) is composed of at least two membrane protein subunits and is responsible for IL-5-mediated signal transduction. One subunit of the high affinity IL-5-R is a 60 kDa membrane protein (p60 IL-5-R) whose cDNA was isolated using the anti-IL-5-R monoclonal antibody (mAb), H7. This subunit alone binds IL-5 with low affinity. The second subunit does not bind IL-5 by itself, and is expressed not only on IL-5-dependent cell lines but also on an IL-3-dependent cell line, FDC-P1. Expression of the p60 IL-5-R cDNA in FDC-P1 cells, which do not bind IL-5, reconstituted the high affinity IL-5-R. We have characterized the second subunit of the IL-5-R by using another anti-IL-5-R mAb, R52.120, and the anti-IL-3-R mAb, anti-Aic-2. The anti-Aic-2 mAb down-regulated binding of IL-5 to an IL-5-dependent cell line, Y16. Both R52.120 and anti-Aic-2 mAbs recognized membrane proteins of 130-140 kDa expressed on FDC-P1 and Y16 cells. The R52.120 mAb recognized both murine IL-3-R (AIC2A) and its homologue (AIC2B) expressed on L cells transfected with suitable cDNAs. The high affinity IL-5-R was reconstituted on an L cell transfectant co-expressing AIC2B and p60 IL-5-R, whereas only the low affinity IL-5-R was detected on a transfectant co-expressing AIC2A and p60 IL-5-R.(ABSTRACT TRUNCATED AT 250 WORDS)     

The IL-2 receptor alpha-chain alters the binding of IL-2 to the beta-chain

The binding of IL-2 to its high affinity receptor results in the formation of the ternary complex consisting of IL-2, alpha-chain (p55, Tac) and beta-chain (p75). We studied the role of alpha-chain in IL-2 binding to the high affinity receptor using IL-2 analog Lys20 which was made by the substitution of Lys for Asp20 of wild-type rIL-2. Lys20 bound to MT-1 cells solely expressing alpha-chain at low affinity, but did not bind to YT-2C2 cells which solely expressed beta-chain. However, direct binding of radiolabeled Lys20 to ED515-D cells, an HTLV-I-infected and IL-2-dependent T cell line, revealed both high affinity and low affinity binding although the Kd value of high affinity binding was 50 to 100 times higher than that of the high affinity binding of wild-type rIL-2. High affinity binding of Lys20 was completely blocked by 2R-B mAb recognizing IL-2R beta-chain. Anti-Tac mAb recognizing IL-2R alpha-chain abolished all of the specific Lys20 bindings. In contrast to the replacement of cell bound 2R-B mAb with wild-type rIL-2 at 37 degrees C, the addition of an excess of Lys20 did not cause the detachment of cell-bound radiolabeled or FITC-labeled 2R-B mAb. Consistent with the results of binding studies, Lys20 induced the proliferation of ED515-D cells, but not large granular lymphocyte leukemic cells. The growth of ED-515D cells was completely suppressed by either anti-Tac mAb or 2R-B mAb. These results strongly suggest that coexpression of the IL-2R alpha- and beta-chains alters the binding affinity of Lys20 and that the interaction between IL-2 and the alpha-chain is a key event in the formation of the IL-2/IL-2R ternary complex.     

Impaired expression of high affinity interleukin 2 receptor on activated lymphocytes from patients with systemic lupus erythematosus

Peripheral lymphocytes stimulated with phytohemagglutinin (PHA-blasts) were examined for their responsiveness to exogenous interleukin 2 (IL-2). The proliferative response of PHA-blasts to IL-2 was significantly lower in patients with systemic lupus erythematosus (SLE) than in normal subjects. To clarify the reason for this defect, the expression of IL-2 receptor (IL-2R) on PHA-blasts was investigated using anti-Tac antibody and purified IL-2. Cytofluorometric analysis showed no statistical differences in the Tac positivity of PHA-blasts among normal subjects and patients with active and inactive SLE. Scatchard analysis using 125I-labeled anti-Tac monoclonal antibody revealed that the number of Tac epitopes on PHA-blasts was also not different among them. Next, the affinity of IL-2R expressed on PHA-blasts was determined by Scatchard analysis using radiolabeled IL-2 as a ligand. The number of high affinity IL-2R on the PHA-blasts was significantly decreased in patients with active and inactive SLE, as compared with normal subjects. The responsiveness of PHA-blasts to exogenous IL-2 was well correlated to the number of high affinity IL-2R, but not to the number of Tac epitopes or total IL-2R. Inasmuch as high affinity components of IL-2R are functionally active, the defective expression of high affinity IL-2R may be responsible for the T cell dysfunctions in SLE.     

Differential regulation of the low affinity Fc receptor for IgE (Fc epsilon R2/CD23) and the IL-2 receptor (Tac/p55) on eosinophilic leukemia cell line (EoL-1 and EoL-3)

Two types of activation Ag, low affinity FcR for IgE (Fc epsilon R2)/CD23 and IL-2R (Tac/p55), were expressed and differently regulated on human eosinophilic leukemia cell lines (EoL-1 and EoL-3). Because the binding of IgE on EoL-3 cells was completely inhibited by H107 (anti-Fc epsilon R2/CD23 mAb) but not by irrelevant mAb, essentially all the low affinity Fc epsilon R2 on EoL-3 seemed to be the Fc epsilon R2/CD23 molecules. Both IL-4 and IFN-gamma enhanced the surface expression of Fc epsilon R2, whereas IL-1, IL-2, and IL-5 showed no effects, as determined by surface staining with anti-Fc epsilon R2 antibody (H107). In contrast to Fc epsilon R2 up-regulation, IL-4 and IFN-gamma showed a differential effect on the regulation of IL-2R (Tac/p55). Whereas IFN-gamma up-regulated the receptor expression of IL-2R/Tac, IL-4 did not. The result suggests that these lymphokines are involved in the different aspects of the activation pathway of the eosinophils. The possible role of Fc epsilon R2 and IL-2R on the function of eosinophils in allergic reaction is discussed.     

Expression and characterization of a des-methionine mutant interleukin-2 receptor (Tac protein) with interleukin-2 binding affinity

A gene coding for the Tac protein (interleukin-2 receptor alpha-subunit, IL-2R alpha) of the interleukin-2 receptor was constructed by chemoenzymatic gene synthesis. The gene designed for mutagenesis codes for a receptor protein where all 10 methionines are substituted by alanine, valine, leucine, and isoleucine. In addition, aspartate at position 6 is substituted by glutamate. This desmethionine IL-2R alpha and the wild-type IL-2R alpha genes were integrated into a eukaryotic expression vector and transferred into different cell lines. The recipient cell lines express both wild-type and mutant receptor proteins on their cell surfaces which are recognized equally by different monoclonal antibodies. It was possible to establish cell lines with high level IL-2R alpha chain expression by fluorescence-activated cell sorting. The wild-type IL-2R alpha expressed in LTK- cells is a glycoprotein with an apparent molecular size of about 60 kDa and a typical low interleukin-2 binding affinity of KD = 12 nM. Despite the fact that 11 amino acids are altered, no significant difference in the mutant IL-2R alpha is observed, exhibiting the same molecular size and a low interleukin-2 binding affinity of KD = 26 nM.     

Murine B lymphoma cell lines release functionally active interleukin 2 after stimulation with Staphylococcus aureus

In this study it is shown that an IL-2-like functional lymphokine activity derived from the murine B cell lines 2PK-3 and L10A2J after stimulation with Staphylococcus aureus can be blocked with anti-IL-2 mAb such as 9B11, DMS-1, and S4B6. Experiments demonstrate that the stimulation of the IL-2-sensitive cell line CTLL-2 by the IL-2-like functional activity derived from murine B cell tumors can also be blocked with the anti-IL-2R mAb PC61. Additionally, in RNA-RNA hybridization experiments with radiolabeled SP6-derived ssRNA probes developed from murine IL-2 genomic DNA sequences and specific for IL-2 mRNA, quantitatively significant amounts of IL-2-specific mRNA in both 2PK-3 and L10A2J are shown subsequent to stimulating the cells with S. aureus. These results suggest the murine B cell tumor lines 2PK-3 and L10A2J synthesize and release IL-2 after stimulation with selected polyclonal activators such as S. aureus.     

Synergistic action of monoclonal antibodies directed at p55 and p75 chains of the human IL-2-receptor

TU27, a mouse IgG1 mAb directed at the p75 chain of the human IL-2R, was analyzed for its ability to interact with IL-2 binding on isolated p75 chains (YT-2C2 cells) and high affinity p55/p75 receptors (human alloreactive T cell clone 4AS), to inhibit IL-2-induced proliferation (4AS cells) and to cooperate with an anti-p55 chain mAb (33B3.1) for inhibiting IL-2 binding and proliferation. TU27 and IL-2 bound to the isolated p75 chain expressed by YT-2C2 cells with respective dissociation constants (Kd) of 1.3 and 1 nM. They cross-inhibited each other for binding with inhibition constants (Ki) in agreement with their respective Kd values. The nature of the interaction was, however, not purely competitive and suggested nonidentical epitopes for the two ligands on the p75 chain. On 4AS cells, IL-2 bound with high affinity (Kd = 50 pM) and TU27 with an affinity similar to that found on YT-2C2 cells. The binding of TU27 and IL-2 were also mutually exclusive on 4AS cells. However, the mechanism of interaction of TU27 with IL-2 was complex since the inhibitory potency of the antibody depended on temperature, antibody preincubation and time of assay. Data obtained at 4 degrees C in the presence of suboptimal, tracer-like concentrations of IL-2 indicated that the intrinsic affinity of TU27 for the high affinity configuration was 15-fold lower than for the isolated p75 chain and argued in favor of the affinity-conversion model (as opposed to the preformed complex model) in which p55 and p75 are dissociated in the absence of IL-2. At 37 degrees C, TU27 inhibited IL-2 binding only on short time assays (6 min). Longer time (30 min) of IL-2 binding resulted in an almost complete disappearance of the effect of TU27, suggesting that internalization of the high affinity p55/p75/IL2 complex enables the cells to escape from the inhibitory effect of TU27. In the presence of the 33B3.1 mAb, the interaction of TU27 with IL-2 resembled the one observed on YT-2C2 cells, suggesting that 33B3.1 is able to inhibit the IL-2-induced association of p55 and p75. Both antibody were found to synergize on 4AS cells, as a result of a cooperative mechanism in which 33B3.1 blocks the formation of the high affinity complex hence allowing TU27 to bind with higher affinity, and TU27 blocks IL-2 binding to the p75 chain. Proliferation studies corroborated the binding experiments.(ABSTRACT TRUNCATED AT 400 WORDS)     

A novel monoclonal antibody against murine IL-2 receptor beta-chain. Characterization of receptor expression in normal lymphoid cells and EL-4 cells

A mAb specific for the murine IL-2R beta-chain (IL-2R beta) was produced by immunizing a rat with a rat transfectant cell line expressing a large number of cDNA-encoded murine IL-2R beta. The mAb, designated TM-beta 1, is specifically reactive with the murine IL-2R beta cDNA-transfectant but not with the recipient cell, and immunoprecipitates murine IL-2R beta of Mr 75 to 85 kDa. TM-beta 1 mAb completely abolished the high affinity IL-2 binding by inhibiting the ligand binding to IL-2R beta. Murine IL-2R beta was found to be constitutively expressed on a subpopulation of CD8+ T cells and almost all NK1.1+ NK cells in the spleen, whereas TM-beta 1 mAb inhibited the proliferation of spleen cells induced by 1 nM of IL-2. Interestingly, EL-4 cells that express murine IL-2R beta as detected by TM-beta 1 mAb can bind neither human nor murine IL-2 under the intermediate affinity conditions, although cDNA-directed human IL-2R beta expressed in the same EL-4 cells has been previously shown to manifest the intermediate affinity IL-2 binding. These results may imply that functional expression of IL-2R beta is differentially regulated between humans and mice. Finally, our neutralizing anti-IL-2R beta mAb TM-beta 1 will be useful not only for various in vitro studies but also for in vivo studies to directly investigate the possible involvement of the IL-2/IL-2R pathway in the generation and differentiation of T lymphocytes and NK cells.     

Biochemical study of a recombinant soluble interleukin-2 receptor. Evidence for a homodimeric structure

A truncated soluble form of the human interleukin-2 receptor p55 chain (T-S-IL-2R) was expressed to high levels in RODENT (mammalian) cells and affinity-purified. Its biochemical behavior was analyzed by polyacrylamide gel electrophoresis (PAGE), gel filtration, and sucrose gradient centrifugation. It migrated as a single 40-kDa band on sodium dodecyl sulfate-PAGE (reducing or nonreducing conditions), whereas it ran as a 80-kDa component on native PAGE or as a 86-kDa component on gel filtration. The combination of gel filtration and density gradient sedimentation gave a Stokes radius of 4.0 nm and a sedimentation coefficient of 3.72 S. The deduced molecular mass was 67 kDa, and the fractional ratio was 1.516. These data therefore indicated that the T-S-IL-2R was secreted as an homodimer of two noncovalently associated 40-kDa subunits. Cross-linking experiments using bifunctional reagents enabled the materialization of the dimeric structure on sodium dodecyl sulfate-PAGE. Stoichiometric binding studies using two monoclonal antibodies (mAbs 33B3.1 and 11H2) reacting with separate epitopes on the p55 chain also strongly supported the dimeric structure. Indeed, there was one binding site for the 33B3.1 mAb (and Fab fragment) per T-S-IL-2R 40-kDa subunit, whereas the 11H2 mAb (or Fab fragment) could bind only half a site per subunit, a result which could only be explained when assuming more than one subunit for the native T-S-IL-2R. Soluble interleukin-2 receptor species were also purified from culture supernatants of either L cells transfected with the full-length p55 cDNA or a normal alloreactive T cell clone. Similar biochemical behavior and reactivities with the two mAbs were found. Finally, cell-surface p55 chains expressed either by pgL21 or 4AS cells bound the 33B3.1 and 11H2 mAbs in a 2:1 ratio, suggesting that the p55 chains are also associated as homodimers when imbedded in the membrane.     

Expression and the functional role of a p70/75 interleukin 2-binding molecule in human B cell

Expression of p70/75 IL-2-binding molecules and their functional roles in induction of Ig secretion by IL-2 were examined in human B cells. IL-2, at high concentrations induced higher levels of Ig secretion in Staphylococcus aureus strain Cowan I (SAC)-activated B cells than at low concentrations. About 50% of SAC-activated B cells, lacking Tac antigen, were also responsive to Ig secretion by IL-2, although the required dose of IL-2 was higher than that for Tac-positive B cells. H-31 antibody which recognizes Tac antigen did not inhibit the induction of Ig secretion by high concentrations of IL-2 in both Tac-negative and Tac-positive B cells, suggesting that IL-2 might induce Ig secretion through a receptor distinct from Tac antigens. In contrast, IL-2 was ineffective in the absence of SAC stimulation even at high concentrations. Upon analysis by SDS-PAGE, p70/75 IL-2-binding molecules were detected on Tac-negative SAC-activated B cells. Similar IL-2-binding molecules distinct from Tac antigen (p55) were detected in both Tac-positive B and T cells. However, neither p55 nor p70/75 IL-2-binding molecules could be detected in the absence of SAC stimulation. These observations suggest that p70/75 IL-2 binding molecules are induced in human B-cells in the presence or absence of Tac antigen by SAC stimulation and these determinants play an important function in the transduction of IL-2 associated signal for B cell differentiation.     

Cutting edge: mechanism of enhancement of in vivo cytokine effects by anti-cytokine monoclonal antibodies

Inhibitory anti-cytokine mAbs are used to treat cytokine-mediated disorders. Recently, however, S4B6, an anti-IL-2 mAb that blocks IL-2 binding to IL-2Ralpha, a receptor component that enhances affinity but is not required for signaling, was shown to enhance IL-2 agonist effects in vivo. We evaluated how S4B6 enhances IL-2 effects and whether a similar mechanism allows mAbs to IL-4 to enhance IL-4 effects. Induction of T cell proliferation by IL-2/S4B6 complexes did not require complex dissociation and was IL-2Ralpha independent. S4B6 increased IL-2 agonist effects by increasing in vivo half-life, not by focusing IL-2 onto cells through Fc receptors. In contrast to IL-2/S4B6 complexes, anti-IL-4 mAb enhancement of in vivo IL-4 effects required IL-4/anti-IL-4 mAb complex dissociation. Thus, agonist effects observed with high doses of anti-IL-2 mAb are most likely only applicable for mAbs that maintain cytokine half-life without blocking binding to receptor signaling components.     

Highly concentrated urine-purified Tac peptide fails to inhibit IL-2-dependent cell proliferation in vitro.

Tac peptide, i.e., the p55 chain of the human interleukin-2 receptor (IL-2R) complex, is detectable as a soluble from (sIL-2R) in normal sera and, at increased levels, in patients with different diseases. Since several immunological abnormalities are observed in most conditions associated with an increase in sIL-2R levels, a down-regulatory effect on IL-2-dependent functions has been postulated as a consequence of binding and functional block of IL-2 by the excess of sIL-2R. To test this hypothesis, we purified sIL-2R from the urine of a patient with hairy cell leukemia and investigated the possible inhibitory effect of this peptide on the in vitro IL-2-induced cell proliferation. The urine-purified molecule was detectable by the specific immunoassay utilized to measure the serum Tac peptide and was constructed by a single polypeptide of about 50 kDa which was able to bind IL-2. Experiments performed with the IL-2-dependent murine CTLL-2 cell line and with PHA-stimulated human peripheral blood mononuclear cells showed that the purified sIL-2R at concentrations up to about 300 nM was unable to block IL-2-dependent cell proliferation. According to these data, which can be explained by the low affinity for IL-2 of the p55 IL-2R chain, it seems unlikely that in vivo the soluble Tac peptide can exert a down regulatory effect on IL-2-induced phenomena through a functional block of IL-2.