Complementary DNAs corresponding to the human receptor for interleukin 2 (IL-2) have been molecularly cloned, sequenced, and expressed in COS-1 cells. The human genome appears to contain a single structural gene for this receptor; however, when transcribed at least two messenger RNAs (mRNAs) are produced which vary in length due to the use of different polyadenylation signals. Sequence analysis of the cloned complementary DNAs indicates an alternate pathway of mRNA processing for this receptor. Splicing of a 216 base pairs segment contained within the protein coding region results in an mRNA unable to code for the IL-2 receptor. In contact complementary DNAs corresponding to unspliced mRNA encode membrane receptors which bind both IL-2 and anti-Tac (monoclonal anti-IL-2 receptor antibody). Analysis of the deduced amino acid sequence reveals that the receptor is composed of 272 amino acids including a signal peptide 21 amino acids in length. Hydrophobicity analysis suggests a single 19 amino acid transmembrane domain. A short intracytoplasmic domain composed of 13 amino acids is present at the carboxy terminus and contains three potential phosphate acceptor sites (serine and threonine but not tyrosine) and typical positively charged amino acids presumably involved in cytoplasmic anchoring. Two sites for N-linked glycosylation sites and numerous extracytoplasmic O-linked glycosylation sites are present.
Human interleukin 2 (IL-2) receptor cDNA derived from HUT 102B2 cells was stably expressed in murine L cells. These L cell transfectants (a) displayed surface receptors of the aberrant size of the IL-2 receptors on HUT 102B2 cells, (b) did not respond to exogenous IL-2 with augmented proliferation, and (c) expressed low affinity but not high affinity receptors for IL-2.
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The gene encoding the human interleukin-2 (IL-2) receptor consists of 8 exons spanning more than 25 kilobases on chromosome 10. Exons 2 and 4 were derived from a gene duplication event and unexpectedly also are homologous to the recognition domain of human complement factor B. Alternative messenger RNA (mRNA) splicing may delete exon 4 sequences, resulting in a mRNA that does not encode a functional IL-2 receptor. Leukemic T cells infected with HTLV-I and normal activated T cells express IL-2 receptors with identical deduced protein sequences. Receptor gene transcription is initiated at two principal sites in normal activated T cells. Adult T cell leukemia cells infected with HTLV-I show activity at both of these sites, but also at a third transcription initiation site.
Interleukin 2 (IL-2) receptors are expressed on activated T cells and in select T-cell leukemias. Recently, it has been demonstrated that at least two classes of receptor for IL-2 exist with markedly different affinities for ligand. All known biological actions of IL-2 have been correlated with occupancy of high-affinity sites; the function of the low-affinity sites remains unknown. Receptor-mediated endocytosis is the primary means of internalization of cell-surface receptors and their ligands. The internalization of IL-2 bound to high- and low-affinity receptor sites was studied in a human T-cell lymphotrophic virus type 1 (HTLV-1)-infected human T-cell leukemia cell line and in a cloned murine cytotoxic T-cell line (CTLL). Internalization of IL-2 occurred only when bound to high-affinity sites. In addition, an anti-receptor antibody (anti-Tac), which binds equally well to high- and low-affinity sites, demonstrated no detectable internalization. The implications of these findings as they relate to IL-2 receptor structure and function are discussed.
We have identified cDNAs encoding the human interleu- kin-2 (IL-2) receptor from a cDNA library constructed from HUT-102B2 cell mRNA, and have expressed them in eukaryotic cells. Based on the deduced amino acid sequence from the DNA sequence, the IL-2 receptor is initially synthesized as a preprotein of 272 amino acids and then processed to a mature form of 251 amino acids. The protein has a very short positively charged cytoplasmic region at the carboxy end of the molecule that contains potential phosphorylation sites. The protein has two potential N-linked carbohydrate addition sites and multiple potential 0-linked carbohydrate addition sites. Although the IL-2 receptor appears to be encoded by a single structural gene, there are two distinct mRNAs that encode the protein that differ in the polyaden- ylation signal used. Further, there is evidence that alternate mRNA splicing may also occur.
The DNA sequence encoding all of the putative intracytoplasmic domain and most of the trans-membrane domain of the human IL 2 receptor was deleted from a full length receptor cDNA. After expression in mouse L cells, the resultant "anchor minus" cDNA was found to direct the synthesis of a secreted rather than membrane-associated form of the IL 2 receptor. The secreted receptor protein (44,000 to 46,000 Mr) retained the capacity to bind both IL 2 and the monoclonal anti-Tac antibody, as evidenced by retention on IL 2 and anti-Tac affinity columns, inhibition of [3H]-anti-Tac binding to HUT 102B2 cells, and partial inhibition of IL 2-induced CTLL proliferation. Removal of these domains from the IL 2 receptor did not alter the posttranslational processing or rate of export of the truncated receptor protein. These data confirm the proposed membrane orientation of the IL 2 receptor (NH2 terminus out, COOH terminus in) and underscore the anchoring function of this carboxy terminal receptor segment. The availability of such anchor minus receptor cDNA constructs may facilitate purification of large quantities of receptor protein for further analysis of receptor structure, valency, and localization of the IL 2 binding site(s).
In general, the human acute T lymphocytic leukemias are composed of malignant expansions of immature T cells lacking membrane receptors for T cell growth factor (TCGF, interleukin 2) and significant immunoregulatory activity. We investigated whether cultured acute lymphocytic leukemic T cell lines can be induced to differentiate and express the Tac antigen, a cell surface protein that contains a TCGF-binding site, after exposure to phorbol 12-myristate 13-acetate (PMA) and/or phytohemagglutinin (PHA). Reactivity of anti-Tac with induced leukemic T cells was studied by three techniques, including: 1) flow microfluorometry; 2) specific binding of [3H]anti-Tac; and 3) receptor immunoprecipitation with anti-Tac and analysis by SDS-PAGE. After exposure to PMA with or without PHA, both JURKAT and HSB-2 acute lymphocytic leukemic T cells displayed Tac antigen within 6 to 8 hr. Induction of receptor expression was blocked by actinomycin D, suggesting a requirement for new mRNA transcription. Induced JURKAT cells contained approximately 7000 Tac molecules per cell, and the binding of anti-Tac to these cells was blocked in a dose-related manner by purified TCGF but not by insulin or purified recombinant interferon-alpha. SDS-PAGE analysis of anti-Tac immunoprecipitates demonstrated that receptors present on induced JURKAT cells were 2000 to 3000 daltons smaller than those present on PHA-activated normal lymphoblasts or induced HSB-2 cells. Induction of JURKAT cells with both PHA and PMA resulted in marked secretion of TCGF as well as the appearance of Tac antigen. After activation of these cells with PMA alone, Tac antigen was similarly expressed, but the level of TCGF synthesis was less than 1% of that obtained after dual induction with PHA and PMA. These data indicate that the signals required for TCGF synthesis and Tac expression are not identical, and furthermore that induction of Tac antigen and TCGF is not obligately linked in these cells.
The human T-lymphotropic viruses types I and II (HTLV-I and -II) have been etiologically linked with certain T-cell leukemias and lymphomas that characteristically display membrane receptors for interleukin-2. The relation of these viruses to this growth factor receptor has remained unexplained. It is demonstrated here that introduction of the trans-activator (tat) gene of HTLV-II into the Jurkat T-lymphoid cell line results in the induction of both interleukin-2 receptor and interleukin-2 gene expression. The coexpression of these cellular genes may play a role in the altering T-cell growth following retroviral infection.
