The murine interleukin 2 receptor. Irreversible cross-linking of radiolabeled interleukin 2 to high affinity interleukin 2 receptors reveals a noncovalently associated subunit

The murine interleukin 2 (IL-2) receptor is a 55- to 60-kDa glycoprotein (p58) that binds IL-2 at a high and low affinity. In this investigation, we have identified sublines of EL4 that vary in their capacity to express high affinity IL-2 receptors after transfection of the IL-2 receptor cDNA. These and other cell populations were used to determine whether unique membrane molecules were specifically associated with the high affinity IL-2 receptor. Irreversible chemical cross-linking of [125I]IL-2 to only high affinity IL-2 receptors resulted in detection of IL-2 cross-linked to p58 as a 70- to 75-kDa band and other complexes of 90 to 95 kDa, 115 kDa, 150 kDa, 170 to 190 kDa, and 245 kDa. Antibodies specific for p58 resulted in precipitation of each of these complexes. However, disruption of noncovalent interactions prior to immunoprecipitation resulted in an inability to detect the material at 90 to 95 kDa. Therefore, we conclude that this complex most likely represented IL-2 cross-linked to a 75- to 80-kDa subunit that was noncovalently associated with p58. The other complexes greater than 150 kDa may represent these subunits cross-linked to each other. The detection of all the cross-linked complexes larger than 75 kDa appeared to be directly related to formation of high affinity IL-2 receptors because IL-2 was cross-linked only to p58 for three cell lines that exclusively expressed low affinity IL-2 receptors. Thus, high affinity murine IL-2 receptors are comprised of at least one alpha (p58)- and beta (p75)-subunit. Our data also raise the possibility of a more complex subunit structure.     

Interleukin 2-induced tyrosine phosphorylation. Interleukin 2 receptor beta is tyrosine phosphorylated

Interaction of interleukin 2 (IL2) with its high affinity membrane receptor complex (IL2R) is sufficient to induce proliferation of T lymphocytes. However, the biochemical mechanisms by which IL2 induces this process remain unresolved. The IL2R complex consists of at least two distinct polypeptides that bind IL2, a 75-kDa intermediate affinity subunit (IL2R beta) and a 55-kDa low affinity subunit (IL2R alpha). As indicated by Western blotting with anti-phosphotyrosine-specific antibodies and confirmed by phosphoamino acid analysis, we now demonstrate that interaction of the T cell growth factor interleukin 2 (IL2) with its high affinity receptor on IL2-sensitive human peripheral blood lymphoblasts induces tyrosine phosphorylation of proteins of 92, 80, 78, 70-75, and 57 kDa. IL2 induced tyrosine phosphorylation in YT 2C2 cells which express only the 75-kDa intermediate affinity IL2 binding molecule (IL2R beta) but not in cells which either express only the 55-kDa low affinity IL2 receptor molecule (IL2R alpha) or no IL2-binding sites. Therefore, IL2R beta, in the absence of IL2R alpha, appears sufficient to transduce the transmembrane signal leading to tyrosine phosphorylation. Two different antibodies reactive with phosphotyrosine specifically immunoprecipitated IL2R beta cross-linked to radiolabeled IL2. These findings suggest that IL2R beta is a substrate for the tyrosine kinase which is activated by IL2 binding to its receptor. Thus, like several other growth factor receptors, activation of the IL2R results in an increase in tyrosine phosphorylation with the receptor itself serving as one substrate.     

Endocytosis of interleukin 2 receptors in human T lymphocytes: distinct intracellular localization and fate of the receptor alpha, beta, and gamma chains

Members of the cytokine receptor family are composed of several noncovalently linked chains with sequence and structure homologies in their extracellular domain. Receptor subfamily members share at least one component: thus the receptors for interleukin (IL) 2 and IL15 have common beta and gamma chains, while those for IL2, 4, 7, and 9 have a common gamma chain. The intracellular pathway followed by IL2 receptors after ligand binding and endocytosis was analyzed by immunofluorescence and confocal microscopy in a human T lymphocytic cell line. Surprisingly, the alpha, beta, and gamma chains had different intracellular localizations after being endocytosed together. The alpha chain was always in transferrin-positive compartments (early/recycling endosomes), both at early and late internalization times, but was never detected in rab7-positive compartments (late endosomes). On the other hand, at late internalization times, the beta and gamma chains were excluded from transferrin-positive organelles and did not colocalize with alpha. Furthermore, beta could be found in rab7-positive vesicles. These differences suggest that the alpha chain recycles to the plasma membrane, while the beta and gamma chains are sorted towards the degradation pathway. The half-lives of these three chains on the cell surface also reflect their different intracellular fates after endocytosis. The beta and gamma chains are very short-lived polypeptides since their half-life on the surface is only approximately 1 h, whereas alpha is a much more stable surface protein. This shows for the first time that components of a multimeric receptor can be sorted separately along the endocytic pathway.     

Two-chain structure of the interleukin 1 receptor

By crosslinking radioiodinated recombinant human IL1 alpha to mouse EL4 thymoma cells we have identified in addition to the known IL1-binding proteins of 80 kDa, a second IL1-binding protein of about 40 kDa. This second binding protein could be demonstrated most easily when crosslinking to higher protein complexes was inhibited. This finding suggests that the IL1 receptor, similar to the receptor for other cytokines such as interleukin 2, is composed of a heterodimer, of which both polypeptides contribute to ligand binding.     

The third molecule associated with interleukin 2 receptor alpha and beta chain.

It is known that the affinity cross-linking study of the human high-affinity Interleukin 2 (IL-2) receptor reveals triplet bands consisting of 70 kDa alpha chain(Tac)-IL-2 and the 90/80 kDa doublet. We found the cell lines lacking the lower band of the doublet in spite of the expression of both alpha and beta chains. No IL-2 binding was detectable in the presence of anti-Tac antibody in these cells. Immunoprecipitation from the cell extract of [125 I] IL-2-cross-linked T cells with anti-beta chain polyclonal IgG detected the upper band, but not lower band of the doublet. These data suggest that the lower band of the doublet represents an unknown IL-2-binding protein (p65) distinct from the beta chain and this molecule may be involved in the intermediate-affinity IL-2 binding together with the beta chain.     

Two-dimensional analysis of interleukin 2-regulated tyrosine kinase activation mediated by the p70-75 beta subunit of the interleukin 2 receptor

The proliferation of activated T lymphocytes is dependent on the interaction of the polypeptide growth factor interleukin 2 (IL 2) with its heterodimeric receptor, which consists of a p55 alpha subunit and a p70-75 beta subunit. Previously, it was shown that IL 2 stimulates rapid serine phosphorylation of several membrane and cytysolic proteins. Here, using anti-phosphotyrosine antibodies to purify phosphotyrosyl proteins and two-dimensional gel analysis, we show that IL 2 stimulates rapid tyrosine phosphorylation of a variety of cellular proteins, including pp180, pp92, and pp42 in activated human T lymphocytes. In addition, we have examined IL 2-induced tyrosine phosphorylation in the human cell line YT2C2 which expresses mostly the beta subunit of the IL 2 receptor and the gibbon cell line MLA-144 which expresses only the beta subunit. In both of these cell lines, IL 2 induced tyrosine phosphorylation of the same proteins phosphorylated in normal human T lymphocytes in response to IL 2. We conclude that the beta subunit is sufficient to induce tyrosine phosphorylation of the normal cellular target substrates involved in signal transduction.     

An exon 5-deleted mRNA encodes a functional interleukin 2 receptor alpha-subunit.

Two polypeptides are involved in interleukin 2 binding: a low-affinity receptor of 55 kD (IL2-R alpha) and an intermediate affinity component of 75 kD (IL2-R beta). We describe the cloning by the Polymerase Chain Reaction of the coding region of IL2-R alpha from a human T-cell lymphoma cell line. One clone presented a 72-bp deletion that precisely corresponds to exon 5. The deleted form and the normal IL2-R alpha cDNA were expressed CHO cells. Stable transfected cellular clones were compared for their immunoreactivity to monoclonal antibodies directed against IL2-R alpha and for their ability to bind radiolabeled IL2. The presence or absence of the protein region encoded by exon 5 did not modify the IL2-binding capacity of the receptor.     

Murine interleukin-1 receptor: differences in binding properties between fibroblastic and thymoma cells and evidence for a two-chain receptor model

The concentration of porcine interleukin-1 beta (pIL1 beta) required to elicit half-maximal IL2 production from NOB-1, a subline of murine thymoma EL4, was 100-fold greater than for p1L alpha. In contrast, similar doses of each type of IL1 stimulated increased lactate production by Balb/C 3T3 fibroblasts. Receptor-bound 125I-IL 1 alpha was displaced with equal efficiency by both unlabelled forms from 3T3 cells, but a 20-fold lower affinity for p1L1 beta was observed using NOB-1. Crosslinking experiments suggested that the IL1 receptors on each line consisted of two polypeptides of 80 and 100 kDa. The results provide the first evidence for a multiple-component IL1 receptor within which IL1 alpha and IL1 beta may bind at different loci, and suggest the receptors may have evolved differently in the two lines.     

Expression of interleukin 1 receptors on human peripheral T cells

The expression of interleukin 1 receptors (IL 1R) on human peripheral T cells was studied by the binding assay with 125I-labeled recombinant human interleukin 1 (IL 1) alpha and IL 1 beta and by the flow cytofluorometry with the fluorescein isothiocyanate (FITC)-conjugated IL 1 alpha. Peripheral blood lymphocytes expressed only few IL 1R without any stimulations. When they were stimulated with concanavalin A (Con A), IL 1R-positive cells began to increase by 4 hr, reached the maximum level at 48 hr, and then gradually decreased. The kinetics of the expression of IL 1 alpha R and IL 1 beta R showed the same pattern. Furthermore the binding of 125I-labeled IL 1 alpha to IL 1R on T cells was inhibited by the addition of either cold IL 1 alpha or IL beta, but not by interleukin 2 or interferons. The similar results were observed in the binding of 125I-labeled IL 1 beta. These results suggest that IL 1R on human peripheral T cells reactive for IL 1 alpha and IL 1 beta were identical. By Scatchard plot analysis, the numbers of IL 1R were estimated as 40 and 350 molecules per cell before and after Con A stimulation, respectively, and their Kd values were 3.1 X 10(-10) M and 2.8 X 10(-10) M. When purified T cells alone were stimulated with Con A, IL 1R were only marginally expressed. However, by the addition of monocytes, IL 1R were expressed on T cells in a dose-dependent manner. The maximum response was induced in the presence of 10% monocytes. The maximum IL 1R-positive T cells were approximately 30% by the detection of the flow cytofluorometry with FITC-conjugated IL 1 alpha. This enhancing activity of IL 1R expression on T cells by monocytes was inhibited by the addition of an anti-HLA-DR antibody or by the treatment of monocytes with the anti-HLA-DR antibody and complement. Furthermore T cell proliferative responses induced with IL 1 and Con A were also enhanced by the addition of HLA-DR-positive monocytes. These results suggest that IL 1R are expressed as the result of monocyte-T cell interaction in the early stage of T cell activation, and the expression of IL 1R on T cells and the responsiveness of T cells for IL 1 require the accessory function of HLA-DR-positive monocytes.     

Characterization of the two heavy chains of the T3 complex on the surface of human T lymphocytes

The T3 complex has been defined by a group of monoclonal antibodies which react with all human peripheral blood T lymphocytes and a subpopulation of thymocytes. This membrane structure includes glycoproteins of 44 (alpha), 37 (beta), 25 (gamma), and 20 kDa (delta) as well as a nonglycosylated polypeptide of 20 kDa (epsilon). The characterization of the alpha and beta chains has been of particular interest because they may constitute the T cell receptor for antigen. Here we show that the T3 complex prepared by immunoprecipitation from T lymphocytes of a leukemic patient (Sezary syndrome) displays an unusually strong association of the alpha and beta chains with the 20/25-kDa T3 proteins. The alpha and beta chains (48 and 44 kDa) were co-precipitated by anti-20-kDa T3 monoclonal antibodies as a disulfide-linked 90-kDa heterodimer. A minor 220-kDa multimer composed of proteins similar to the alpha and beta chains was also present in these immunoprecipitates. This multimer could be independently precipitated with a new monoclonal antibody WT-31, which detects the larger polypeptide chains of the T3 complex on all human T lymphocytes. After removal of N-linked oligosaccharides, both the alpha and beta chain were found to have 33-kDa peptide backbones with distinct isoelectric points. Using a monoclonal reagent T40/25, a 90-kDa heterodimer, consisting of 40- and 49-kDa chains with peptide backbones of 34 kDa was found to be T3-associated on the T leukemic cell line HPB-ALL. When the alpha and beta chains from the Sezary patient were compared with the corresponding chains from HPB-ALL by peptide mapping, large differences were observed. Taken together, the data presented here provide strong evidence that the T cell receptor for antigen is part of the T3 complex on the surface of human T lymphocytes.     

An α-Helical Signal in the Cytosolic Domain of the Interleukin 2 Receptor β Chain Mediates Sorting Towards Degradation after Endocytosis

High-affinity IL2 receptors consist of three components, the α, β, and γ chains that are associated in a noncovalent manner. Both the β and γ chains belong to the cytokine receptor superfamily. Interleukin 2 (IL2) binds to high-affinity receptors on the cell surface and IL2-receptor complexes are internalized. After endocytosis, the components of this multimolecular receptor have different intracellular fates: one of the chains, α, recycles to the plasma membrane, while the others, β and γ, are routed towards late endocytic compartments and are degraded. We show here that the cytosolic domain of the β chain contains a 10–amino acid sequence which codes for a sorting signal. When transferred to a normally recycling receptor, this sequence diverts it from recycling. The structure of a 17–amino acid segment of the β chain including this sequence has been studied by nuclear magnetic resonance and circular dichroism spectroscopy, which revealed that the 10 amino acids corresponding to the sorting signal form an amphipathic α helix. This work thus describes a novel, highly structured signal, which is sufficient for sorting towards degradation compartments after endocytosis.     

IL-2 regulation of tyrosine kinase activity is mediated through the p70-75 beta-subunit of the IL-2 receptor

The stimulation of activated human T lymphocytes with IL-2 results in increased tyrosine kinase activity. IL-2 treatment of Tac+ T cells stimulates the rapid phosphorylation of multiple protein substrates at M of 116, 100, 92, 70 to 75, 60, 56, 55, 33, and 32 kDa. Phosphorylation on tyrosine residues was detected by immunoaffinity purification of protein substrates with Sepharose linked antiphosphotyrosine mAb, 1G2. Although phorbol ester stimulated serine phosphorylation of the IL-2R alpha (p55) subunit recognized by alpha TAC mAb, IL-2 did not stimulate any detectable phosphorylation of IL-2R alpha or associated coimmune precipitated proteins. In fact, the tyrosine phosphorylated proteins did not coprecipitate with alpha Tac antibody and similar phosphoproteins were stimulated by IL-2 in IL-2R alpha- human large granular lymphocytes which express only the 70 to 75 kDa IL-2R beta subunit of the high affinity IL-2R. Anti-Tac mAb could inhibit IL-2-stimulated tyrosine phosphorylation in activated T cells, which express both IL-2R subunits that together form the high affinity receptor complex, but not in large granular lymphocytes expressing only the IL-2R beta subunit. The data suggest that IL-2 stimulation of tyrosine kinase activities requires only the IL-2R beta subunit.     

Receptor-mediated endocytosis of interleukin 2 in a human tumor T cell line. Degradation of interleukin 2 and evidence for the absence of recycling of interleukin receptors

We have previously described a human tumor T cell line, IARC 301, which constitutively expresses biologically functional interleukin 2 (IL2) receptors. The fate of IL2 after binding to surface high affinity receptors was investigated. After a few minutes, IL2 is internalized at 37 degrees C and is subsequently degraded and released in the medium. The half-life for surface high affinity IL2 receptors, as measured in the presence of cycloheximide, is about 1 h and does not depend upon the presence of IL2. After trypsin digestion of cell surface high affinity receptors in the absence of protein biosynthesis, we could not detect any receptor reappearance on the cell membrane, whether IL2 was added or not. Taken together these results show that IL2 receptors are constantly internalized in these cells in the presence or absence of IL2 and that they do not recycle to the plasma membrane after receptor-mediated endocytosis.     

Identification and distribution of two forms of the interleukin 1 receptor

Using affinity crosslinking techniques, we have biochemically characterized the interleukin-1 (IL1) receptor and investigated its distribution on a range of murine and human cell lines. We show that two forms of IL1 receptor can be identified on the basis of specific crosslinking with 125I-IL1 alpha and 125I-IL1 beta. The two receptor forms have an approximate molecular mass of approximately 80 and approximately 60 kDa, and were found on both murine and human cells. Their relative distribution shows no clear cell lineage restriction and does not correlate with preferential binding of IL1 alpha or IL1 beta. Some cells, such as the T helper cell line D10.G4.1, express both forms of the receptor. Iodine 125-IL1 was crosslinked to the two receptor forms and a partial peptide map analysis of the two receptor/ligand complexes was performed. Comigration of the major partial peptide fragments suggests that the approximately 80 and approximately 60 kDa forms of the receptor may be differentially processed forms of the same protein. Treatment of the approximately 60 kDa IL1 receptor on Raji cells with N-glycanase reduced its molecular mass by 12 kDa, showing that this lower molecular mass form is a glycoprotein; glycosylation differences alone probably do not account for the difference in mass between the two forms.     

Pathways of human T lymphocyte development and activation

The T lymphocyte receptor for antigen, which operates in conjunction with gene products of the major histocompatibility complex (MHC), is a molecular complex comprised of five polypeptide chains. Both the 49 kDa alpha and 43 kDa beta chains are immunoglobulin-like and thus contain variable domains responsible for ligand binding. In contrast, the 20–25 kDa T3 gamma, delta and epsilon chains are monomorphic structures presumably involved in transmembrane signalling. The alpha and beta subunits are disulfide bonded to each other and held in noncovalent association with the T3 chains. T3-Ti receptor crosslinking leads to conformational modification of a second T lineage specific molecule, termed the 50 kDa T11 structure which in turn leads to protein kinase C activation, elevation in intracytoplasmic free calcium and Na⁺/H⁺ antiport stimulation.     

Modulation of interleukin 2 internalization and interleukin 2-dependent cell growth by antireceptor antibodies

The growth factor interleukin 2 (IL2) binds to and is internalized together with high-affinity surface receptors present on lymphoid cells. This endocytosis thus results in down-regulation of the receptors. However, it is not known if the internalization is relevant to the induction of cell growth. In the present study a rat monoclonal antibody to the P55 chain of the IL2 receptor was used to examine the role of receptor internalization in the IL2-dependent autocrine human tumor T cell line IARC 301. When given alone, this antibody did not inhibit IL2 binding, internalization, or IL2-dependent cell proliferation. However, crosslinking by anti-rat immunoglobulins, which did not affect binding of the growth factor, inhibited both IL2 internalization and cell proliferation. Besides offering a novel means for the specific inhibition of the uptake of IL2 bound to IL2 high-affinity receptors, the results are compatible with the association of this receptor-ligand uptake to the growth stimulation by IL2.     

Human interleukin-3 (IL-3) induces disulfide-linked IL-3 receptor alpha- and beta-chain heterodimerization, which is required for receptor activation but not high-affinity binding.

The human interleukin-3 receptor (IL-3R) is a heterodimer that comprises an IL-3 specific alpha chain (IL-3R alpha) and a common beta chain (beta C) that is shared with the receptors for granulocyte-macrophage colony-stimulating factor (GM-CSF) and IL-5. These receptors belong to the cytokine receptor superfamily, but they are structurally and functionally more related to each other and thus make up a distinct subfamily. Although activation of the normal receptor occurs only in the presence of ligand, the underlying mechanisms are not known. We show here that human IL-3 induces heterodimerization of IL-3R alpha and beta c and that disulfide linkage of these chains is involved in receptor activation but not high-affinity binding. Monoclonal antibodies (MAb) to IL-3R alpha and beta c were developed which immunoprecipitated, in the absence of IL-3, the respective chains from cells labelled with 125I on the cell surface. However, in the presence of IL-3, each MAb immunoprecipitated both IL-3R alpha and beta c. IL-3-induced receptor dimers were disulfide and nondisulfide linked and were dependent on IL-3 interacting with both IL-3R alpha and beta c. In the presence of IL-3 and under nonreducing conditions, MAb to either IL-3R alpha or beta c immunoprecipitated complexes with apparent molecular weights of 215,000 and 245,000 and IL-3R alpha and beta c monomers. Preincubation with iodoacetamide prevented the formation of the two high-molecular-weight complexes without affecting noncovalent dimer formation or high-affinity IL-3 binding. Two-dimensional gel electrophoresis and Western blotting (immunoblotting) demonstrated the presence of both IL-3R alpha and beta c in the disulfide-linked complexes. IL-3 could also be coimmunoprecipitated with anti-IL-3R alpha or anti-beta c MAB, but it was not covalently attached to the receptor. Following IL-3 stimulation, only the disulfide-linked heterodimers exhibited reactivity with antiphosphotyrosine antibodies, with beta c but not IL-3R alpha being the phosphorylated species. A model of IL-3R activation is proposed which may be also applicable to the related GM-CSF and IL-5 receptors.     

Receptor-mediated endocytosis and nuclear transport of human interleukin 1 alpha.

In this study we demonstrate that 125I-labelled interleukin (IL) 1 alpha binds specifically to its receptor on the surface of EL4 6.1 cells and is subsequently endocytosed and translocated from the cell membrane to the nucleus, where it progressively accumulates. Two-dimensional polyacrylamide-gel electrophoresis revealed that the internalized 125I-IL1 alpha associated with the nucleus was intact, with negligible breakdown products present. Specific and saturable binding of 125I-IL1 alpha was demonstrated on purified nuclei isolated from these cells. Binding of the radiolabelled ligand showed similar kinetics to that of the plasma-membrane receptor, and was inhibited by both unlabelled IL1 alpha and IL1 beta. Equilibrium binding studies on isolated nuclei revealed a single high-affinity binding site, with a Kd of 17 +/- 2 pM, and 79 +/- 12 binding sites per nucleus. These studies demonstrate that receptor-mediated endocytosis of IL1 results in its accumulation in the nucleus, and this mechanism may play an important role in mediating some of the actions of IL1.     

Interleukin 1 receptors on rabbit articular chondrocytes: relationship between biological activity and receptor binding kinetics

This study gives an account of the biologic and kinetic binding properties of interleukin 1 alpha (IL 1 alpha), interleukin 1 beta (IL 1 beta), and Glu-4 (an NH2-terminal mutant of IL 1 beta) to interleukin 1 (IL 1) receptors in rabbit articular chondrocytes. All three IL 1's demonstrated full agonist properties in their ability to stimulate prostaglandin E2 (PGE2) synthesis. IL 1 alpha was 23-fold more biologically active than IL 1 beta, which was around 110-fold more active than Glu-4 based on the concentration of IL 1 required for half-maximal stimulation of PGE2. The binding of all three ligands was concentration-dependent and saturable at 4 degrees C. Scatchard analysis of receptor binding data showed that the dissociation constant (KD) of IL 1 alpha was 46 +/- 12 pM, and the receptor density was 3120 sites/cell. The association of IL 1 alpha at 4 degrees C did not attain equilibrium until after 10 h at 100 pM of 125I-labeled IL 1 alpha. The dissociation of bound IL 1 alpha was very slow, t1/2 of 21 h, although only one class of high-affinity receptors was detected. The KD of IL 1 beta binding was 72 +/- 3 pM with a receptor density of 800 +/- 40 sites/cell. Dissociation of bound 125I-labeled IL 1 beta at 4 degrees C appeared to indicate the presence of two receptor subsets, a fast and a slower component with a t1/2 of 2 min and 5 h, respectively. The receptor binding affinity of Glu-4 was 324 +/- 3 pM, in line with its reduced biologic activity. Both IL 1 alpha and IL 1 beta are rapidly internalized in chondrocytes in a time- and temperature-dependent manner.