Receptor revision in peripheral T cells creates a diverse V beta repertoire.

In Vbeta5 transgenic mice, the age-dependent accumulation of Vbeta5(-)CD4(+) T cells expressing endogenous Vss elements represents an exception to the rule of strict allelic exclusion at the TCRbeta locus. The appearance of these cells is limited to the lymphoid periphery and is driven by a peripherally expressed tolerogen. Expression of the lymphoid-specific components of the recombinase machinery and the presence of recombination intermediates strongly suggest that TCR revision rescues tolerogen-reactive peripheral T cells from deletion. Here, we report that the appearance of Vbeta5(-)CD4(+) T cells is CD28-dependent. In addition, we find that the TCR repertoire of this unusual population of T cells in individual Vbeta5 transgenic mice is surprisingly diverse, both at the level of surface protein and at the nucleotide level within a given family of V(D)Jbeta rearrangements. This faithful recreation of the nontransgenic repertoire suggests that endogenous Vbeta-expressing populations do not arise from expansion of an initially rare subset. Furthermore, the undersized N regions in revised TCR genes distinguish these sequences from those generated in the adult thymus. The diversity of the revised TCRs, the minimal mouse-to-mouse variation in the expressed endogenous Vbeta repertoire, the atypical length of junctional sequences, and the CD28 dependence of the accumulation of Vbeta5(-)CD4(+) T cells all point to their extrathymic origin. Thus, tolerogen-driven receptor revision in peripheral T cells can expand the TCR repertoire extrathymically, thereby contributing to the flexibility of the immune repertoire.

Lymphocytes rearrange, edit and revise their antigen receptors to be useful yet safe.

Pamela Fink and Catherine McMahan discuss how B and T cells test for useful antigen receptors and weed out potentially harmful ones, with special attention paid to T-cell receptor revision, a newly described mechanism by which mature T cells can maintain self tolerance.

RAG reexpression and DNA recombination at T cell receptor loci in peripheral CD4+ T cells.

Under most circumstances, allelic exclusion at the T cell receptor (TCR)beta locus is tightly regulated. Here, we describe a system in which TCRbeta allelic exclusion is overcome as a result of V(D)J recombination in peripheral CD4+ T cells. In TCRbeta chain transgenic mice, tolerogen-mediated chronic peripheral selection against cells expressing the transgene leads to surface expression of endogenous TCRbeta chains. Peripheral CD4+ T cells reexpress the recombination activating genes, RAG1 and RAG2, and contain signal end intermediates indicative of ongoing V(D)J recombination. The rescue from deletion of mature T cells expressing newly generated TCRbeta chains suggests that receptor revision plays a role in the maintenance of peripheral T cell tolerance.

A basic motif in the N-terminal region of RAG1 enhances V(D)J recombination activity.

The variable portions of antigen receptor genes are assembled from component gene segments by a site-specific recombination reaction known as V(D)J recombination. The RAG1 and RAG2 proteins are the critical lymphoid cell-specific components of the recombination enzymatic machinery and are responsible for site-specific DNA recognition and cleavage. Previous studies had defined a minimal, recombinationally active core region of murine RAG1 consisting of amino acids 384 to 1008 of the 1,040-residue RAG1 protein. No recombination function has heretofore been ascribed to any portion of the 383-amino-acid N-terminal region that is missing from the core, but it seems likely to be of functional significance, based on its evolutionary conservation. Using extrachromosomal recombination substrates, we demonstrate here that the N-terminal region enhances the recombination activity of RAG1 by up to an order of magnitude in a variety of cell lines. Deletion analysis localized a region of the N terminus critical for this effect to amino acids 216 to 238, and further mutagenesis demonstrated that a small basic amino acid motif (BIIa) in this region is essential for enhancing the activity of RAG1. Despite the fact that BIIa is important for the interaction of RAG1 with the nuclear localization factor Srp-1, it does not appear to enhance recombination by facilitating nuclear transport of RAG1. A variety of models for how this region stimulates the recombination activity of RAG1 are considered.

Definition of a large region of RAG1 that is important for coimmunoprecipitation of RAG2.

Interaction between the RAG1 and RAG2 proteins is probably critical for V(D)J recombination. Using a coimmunoprecipitation assay, we define a large region of RAG1 (amino acids 504-1008) that is sufficient for interaction with RAG2. This region comprises the C-terminal half of the RAG1 protein, and is within the region defined as the recombinationally active core. Deletion of either of two regions of RAG1 (amino acids 504-570 or 850-1008) causes a loss of interaction with RAG2. Loss of coimmunoprecipitation is also seen with RAG1 core proteins containing deletions of smaller stretches of amino acids (amino acids 506-511 or 545-550), emphasizing the importance of this region of RAG1 in forming a complex with RAG2. A variety of other small deletion mutations within the amino acid region 504-1008 also decrease coimmunoprecipitation of RAG2 with RAG1, indicating that much or all of this region is important for complex formation.

RAG1 mediates signal sequence recognition and recruitment of RAG2 in V(D)J recombination.

Recent studies have demonstrated that DNA cleavage during V(D)J recombination is mediated by the RAG1 and RAG2 proteins. These proteins must therefore bind to the recombination signals, but the specific binding interaction has been difficult to study in vitro. Here, we use an in vivo one-hybrid DNA binding assay to demonstrate that RAG1, in the absence of RAG2, can mediate signal recognition via the nonamer, with the heptamer acting to enhance its binding. A region of RAG1 with sequence similarity to bacterial invertases is essential for DNA binding. Localization of RAG2 to the signal is dependent upon the presence of RAG1 and is substantially more efficient with a 12 bp spacer signal than with a 23 bp spacer signal.

Independent binding of interleukin-1 alpha and interleukin-1 beta to type I and type II interleukin-1 receptors.

Interleukin (IL)-1 refers to a group of three polypeptide hormones with a wide range of cellular targets. Two types of IL-1 receptor have been identified and characterized by cDNA cloning. Both human type I and type II IL-1 receptors contain extracellular domains of approximately 310 residues and a single membrane-spanning region. The type I receptor contains a cytoplasmic domain of 213 residues. The cytoplasmic region of the type II receptor is 29 residues in length. It has been found recently that a number of cells express both forms of receptor. By analogy with other cytokine receptor systems, the two IL-1 receptors might be expected to form a heterodimeric complex, the type II receptor being an alpha-chain-like structure, functioning only to bind ligand, and associating with the type I receptor (a beta-chain-like structure) which would transduce signals. In this report we show that this is not the case, but rather that IL-1, when complexed to type II receptor, cannot bind type I receptors, and vice versa. These data show that the complex patterns often observed for IL-1 binding to cells cannot be accounted for by the same type of mechanism that underlies the behavior of, for example, the IL-2 system.

Molecular characterization of the interleukin-1 receptor (IL-1R) on monocytes and polymorphonuclear cells.

Primary human monocytes and monocytic cells express an interleukin 1 receptor (IL-1R) which is similar in molecular weight and IL-1 binding characteristics to the IL-1R expressed on B lymphocytes (type II). Northern blot analysis of monocytic cells using a cDNA probe from the recently isolated type II IL-1R indicates that this mRNA is detectable by 4 h and accumulates for at least 24 h following treatment with IL-1R inducing drugs. The time course of induction of this mRNA is slower than that of the type I IL-1R mRNA which is also transcribed in monocytic cells but does not appear to be translated. Sequence analysis of a monocyte-derived cDNA corresponding to the type II IL-1R mRNA shows that the monocyte and B-cell mRNAs are identical. Comparison of monocyte IL-1R peptide maps with those of the type II IL-1R suggests that the two surface IL-1R are identical. This was confirmed serologically using a polyclonal antiserum raised against the type II IL-1R. Data are presented which indicate that primary human neutrophils can also be induced to express abundant type II IL-1R.

A novel IL-1 receptor, cloned from B cells by mammalian expression, is expressed in many cell types.

cDNA clones corresponding to an Mr approximately 80,000 receptor (type I receptor) for interleukin-1 (IL-1) have been isolated previously by mammalian expression. Here, we report the use of an improved expression cloning method to isolate human and murine cDNA clones encoding a second type (Mr approximately 60,000) of IL-1 receptor (type II receptor). The mature type II IL-1 receptor consists of (i) a ligand binding portion comprised of three immunoglobulin-like domains; (ii) a single transmembrane region; and (iii) a short cytoplasmic domain of 29 amino acids. This last contrasts with the approximately 215 amino acid cytoplasmic domain of the type I receptor, and suggests that the two IL-1 receptors may interact with different signal transduction pathways. The type II receptor is expressed in a number of different tissues, including both B and T lymphocytes, and can be induced in several cell types by treatment with phorbol ester. Both IL-1 receptors appear to be well conserved in evolution, and map to the same chromosomal location. Like the type I receptor, the human type II IL-1 receptor can bind all three forms of IL-1 (IL-1 alpha, IL-1 beta and IL-1ra). Vaccinia virus contains an open reading frame bearing strong resemblance to the type II IL-1 receptor.

Molecular heterogeneity of interleukin-1 receptors.

Previous studies have shown that binding of IL-1 to its receptor and intracellular processing of the IL-1/IL-1 receptor complex appear to be different in B- and T-cells. The current report summarizes recent studies from our laboratory that show that the murine and human IL-1 receptors present on T-cells and fibroblasts are identical in primary sequence within each species, and highly similar even when the two species are compared. At present no cDNA clones have been isolated for IL-1 receptors present on B-cells. However, a monoclonal antibody raised to the receptor on murine T-lineage cells did not bind to a pre-B-lymphoma cell line that displays IL-1 binding sites, nor would cDNA probes derived from a T-cell IL-1 receptor clone cross hybridize at high stringency to mRNA prepared from these cells. In addition the two receptors differ substantially in size, as determined by affinity crosslinking with radiolabeled IL-1 alpha. Taken together, these observations show that major structural differences exist between the IL-1 receptors on B and T lymphocytes, while the receptors on T-cells and fibroblasts are identical polypeptides. We propose that the T-cell/fibroblast receptor be called IL-1RI and the B-cell type IL-1RII.

Cloning the interleukin 1 receptor from human T cells.

cDNA clones of the interleukin 1 (IL-1) receptor expressed in a human T-cell clone have been isolated by using a murine IL-1 receptor cDNA as a probe. The human and mouse receptors show a high degree of sequence conservation. Both are integral membrane proteins possessing a single membrane-spanning segment. Similar to the mouse receptor, the human IL-1 receptor contains a large cytoplasmic region and an extracellular, IL-1 binding portion composed of three immunoglobulin-like domains. When transfected into COS cells, the human IL-1 receptor cDNA clone leads to expression of two different affinity classes of receptors, with Ka values indistinguishable from those determined for IL-1 receptors in the original T-cell clone. An IL-1 receptor expressed in human dermal fibroblasts has also been cloned and sequenced and found to be identical to the IL-1 receptor expressed in T cells.

Evidence for different interleukin 1 receptors in murine B- and T-cell lines.

Previous studies have shown that binding of interleukin 1 (IL-1) to its receptor and intracellular processing of the IL-1/IL-1 receptor complex appear to be different in B- and T-lymphocyte cell lines. In this study we used a B-lymphoid cell line, 70Z/3, and T-lymphoid cell line, EL-4 6.1 C10, to explore further the differences that exist between IL-1 receptors on cells of B and T lineage. We show that a monoclonal antibody against the IL-1 receptor on EL-4 cells does not bind to the IL-1 receptor on 70Z/3 cells. This finding suggests that there are structural differences in the extracellular domains of the IL-1 receptors on the two cell lines. Furthermore, affinity crosslinking showed that the molecular mass of the IL-1 receptor on EL-4 is 87 kDa, whereas that of 70Z/3 is significantly lower (66 kDa). Activation of phospholipid/Ca2+-dependent protein kinase, protein kinase C, by phorbol 12-myristate 13-acetate (PMA) greatly reduced the number of IL-1 binding sites on 70Z/3. But, in sharp contrast, PMA had no effect on surface IL-1 receptor expression on EL-4 cells despite having an equally potent effect in activating protein kinase C. The different effects of protein kinase C suggest that the cytoplasmic domains of the IL-1 receptors in 70Z/3 and EL-4 may also be different. Lastly, a probe containing the entire coding region of the murine T-cell IL-1 receptor hybridized under high stringency conditions with mRNA from EL-4 cells but not with mRNA from 70Z/3 cells. Taken together, the observations made in this study suggest that major structural differences exist between the IL-1 receptors on B and T lymphocytes.

Retention of ligand binding activity by the extracellular domain of the IL-1 receptor.

The IL-1R on murine T cells is an 80-kDa cell surface glycoprotein which binds both IL-1 alpha and IL-1 beta. We have recently isolated a cDNA clone encoding this molecule. From the primary sequence mature receptor is predicted to be a 557 residue integral membrane protein with a 319 residue carbohydrate-rich extracellular region. We have constructed a cDNA clone encoding this region of the protein (residues 1 to 316). Expression of this cDNA in HeLa cells leads to secretion of a soluble IL-1 alpha binding protein into the culture medium. Quantitative binding experiments with the truncated receptor show that it possesses IL-1 binding properties which are indistinguishable from those of full length IL-1R. Gel filtration chromatography experiments show that a complex can be formed between a single truncated receptor molecule and a single IL-1 alpha molecule.

T-cell interleukin 1 receptor cDNA expressed in Chinese hamster ovary cells regulates functional responses to interleukin 1.

We have cloned a cDNA encoding a receptor identical to the native Mr 80,000 glycoprotein that binds interleukin (IL) 1 alpha and -beta in murine T cells. Chinese hamster ovary (CHO) cells transfected with this T-cell IL-1 receptor (IL-1R) [CHO(IL-1R)] cDNA express approximately 100,000 IL-1Rs per cell, compared to the less than 100 receptors present on control CHO cells. For two functional responses to IL-1, prostaglandin synthesis and cytokine secretion, CHO(IL-1R) cells were 1000 times more sensitive to IL-1 alpha than were control CHO cells. Northern blot analysis and antibody precipitation demonstrated that one of the cytokines induced was granulocyte colony-stimulating factor and that mRNA levels for this cytokine were increased in CHO(IL-1R) cells by IL-1 alpha concentrations that had no effect on control cells. To establish the role of the recombinant receptors in signal transduction, an IL-1R cDNA modified by deletion of the predicted cytoplasmic domain was expressed in the CHO cell line termed CHO(IL-1R delta CT). CHO(IL-1R delta CT) cells expressed approximately 100,000 high-affinity IL-1 binding sites per cell, but these cells were less sensitive than control lines to IL-1, as measured by prostaglandin and cytokine release. These results show that the IL-1R cDNA encodes the entire functional receptor and that the cytoplasmic domain is required for signal transduction but not ligand binding.

cDNA expression cloning of the IL-1 receptor, a member of the immunoglobulin superfamily.

Interleukin-1 alpha and -1 beta (IL-1 alpha and IL-1 beta) are cytokines that participate in the regulation of immune responses, inflammatory reactions, and hematopoiesis. A direct expression strategy was used to clone the receptor for IL-1 from mouse T cells. The product of the cloned complementary DNA binds both IL-1 alpha and IL-1 beta in a manner indistinguishable from that of the native T cell IL-1 receptor. The extracellular, IL-1 binding portion of the receptor is 319 amino acids in length and is composed of three immunoglobulin-like domains. The cytoplasmic portion of the receptor is 217 amino acids long.