UMLS:C0033036 - FACTA Search

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Query: UMLS:C0033036 (APC)
10,214 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have directly compared the signals required for: induction of the [Ca+2]i response, expression of Tac antigen, and proliferation in antigen-specific human T cell clones. We have previously shown that antigen-specific activation of cloned T cells under conditions leading to proliferation is accompanied by a rapid increase in [Ca+2]i. Cloned T cells showed increased [Ca+2]i, enhanced Tac expression, and proliferated in response to specific antigen in the presence of viable, genetically appropriate antigen-presenting cells. Paraformaldehyde fixation of antigen-presenting cells after "pulsing" with antigen prevented proliferation, but did not affect MHC-restricted [Ca+2]i or Tac responses. Treatment of cloned T cells with monoclonal anti-T3 antibody also increased [Ca+2]i and Tac expression but did not induce proliferation. Proliferation was restored by viable autologous or allogenic APC or exogenous IL 2, but not by IL 1. In contrast to resting T cells, T cell clones were insensitive to the mitogenic effects of lectins or of ionophores and phorbol esters. These results suggest that activation of antigen-specific T cells requires the sequential action of at least two signals. The first is MHC restricted and is mediated by interaction of antigen + MHC class II products with the T cell receptor (T3-Ti) complex. This leads to Tac expression and increased [Ca+2]i, but is not sufficient for proliferation. This signal can be bypassed by anti-T3 monoclonal antibodies. Proliferation requires a second, nonantigen-specific, non-MHC-restricted antigen-presenting cell signal, which cannot be replaced by IL 1 in our system. This signal can be bypassed, however, by the addition of exogenous IL 2 to cells that have received the first signal and express Tac, suggesting that it is required for IL 2 synthesis and secretion. T cell clones therefore provide a useful model for studying antigen-dependent and -independent events in cell activation.
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PMID:Antigen-specific and -nonspecific mitogenic signals in the activation of human T cell clones. 295 89

Lymph node cells from 4-wk-old MRL/Mp-lpr/lpr mice, but not from MRL/Mp-+/+ mice, when cultured in vitro for 5 to 7 days, will spontaneously proliferate and produce IL-2. We examined the expression of several cell surface Ag on lymph node cells from MRL/Mp-lpr/lpr mice before and after in vitro culture. There is an increase in the expression of Thy-1, L3T4, IL-2R, T cell activating protein, T cell receptor, and T3 complex on the surface of cultured cells. Cultured cells produced IL-3, IFN-gamma, and small but detectable amounts of IL-1 in addition to IL-2. Gamma irradiation of APC from young MRL/Mp-lpr/lpr mice or treatment of APC with a mAb (J11D) and C, completely abrogated their stimulatory capacity. These experiments suggest that B cells are the predominant APC responsible in the activation of autoreactive T cells in MRL/Mp-lpr/lpr mice. Lymph node cells from C57BL/6-lpr/lpr or C3H-lpr/lpr mice were unable to spontaneously proliferate or produce IL-2. Lymph node cells from (MRL/Mp-lpr/lpr x C57BL/6-lpr/lpr) F1 mice or (C3H-lpr/lpr x MRL/Mp-lpr/lpr) F1 mice did proliferate and produced IL-2 after in vitro culture. Using T cells from these F1 animals and APC from each parental haplotype, we found that APC from MRL/Mp-lpr/lpr mice induced more proliferation and greater amounts of IL-2, when compared to APC from F1 animals. APC from C57BL6-lpr/lpr mice or C3H-lpr/lpr were unable to induce spontaneous proliferation and IL-2 production. Therefore, B cells from MRL/Mp-lpr/lpr mice appear to possess unique features that enable them to activate autoreactive T cells more effectively than B cells from other mice bearing the lpr/lpr gene.
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PMID:Autoreactive T cells in MRL/Mpr-lpr/lpr mice. Characterization of the lymphokines produced and analysis of antigen-presenting cells required. 313 46

The T cell surface molecules Lyt-2 and L3T4 are strongly correlated with the class of MHC gene product recognized by the T cell bearing them. The L3T4 molecule has been proposed to play a role in enhancing recognition of antigen:Ia by specific T cells. In the present experiments, we have explored the role of L3T4 in T cell activation by examining the effects of the L3T4-specific monoclonal antibody GK1.5 on T cell responses in the presence or absence of class II-MHC gene products. Our studies show that GK1.5 inhibits T cell activation in the absence of class II-MHC gene products, while antibodies to other T cell surface molecules do not transduce negative signals to the same cells. We interpret our results as suggesting a signaling role for L3T4 and, by inference, for Lyt-2 as well. We would propose that L3T4 molecules on the class II-restricted T cell initiate the interaction between the L3T4+ T cell and its class II-MHC gene product bearing target cell (B cell, APC). This initial contact is important in allowing a finite time for antigen, Ia, and the T cell receptor to form an activating complex, which in turn transduces a dominant on signal to the cell. In the absence of specific antigen, or if the class II-bearing cell is of the wrong MHC genotype, so that the antigen:Ia receptor is not aggregated, then the association of L3T4 with class II molecules transduces a net negative signal to the T cell. We suggest that this negative signal is responsible for T cell:target cell deconjugation under these circumstances. Thus, we would propose that L3T4 initiates T cell:Ia-bearing cell interactions and, a finite time later, signals the T cell to discontinue the interaction unless a stimulating level of the antigen:Ia complexes for which the T cell's receptor is specific is present.
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PMID:The role of L3T4 in T cell activation: L3T4 may be both an Ia-binding protein and a receptor that transduces a negative signal. 350 16

Previous study has shown that reduced T cell response to peptide alpha 146-162 of Torpedo californica acetylcholine receptor (tAChR) in B6.C-H-2bm12 (bm12) mice, a mutant of C57BL/6 (B6) mice, correlated with its nonsusceptiblity to experimental autoimmune myasthenia gravis. There are three amino acid differences between the I-A beta b of the two strains (positions 67, 70, and 71). We synthesized peptides I-A beta b62-76 (peptide b6), I-A beta bm1262-76 (peptide bm), and three additional peptides, b6(67F), b6(70Q), and b6(71K), and determined their ability to bind peptide alpha 146-162 and the dissociation constants (Kd) of the binding. Peptide alpha 146-162 bound with a significantly higher affinity to peptide b6 than to peptides bm or b6(71K), suggesting that the lower affinity of peptide alpha 146-162 to I-Abm12 is a factor in the reduced response to this peptide by bm12 T cells. This was confirmed by measurement of the Kd values of the binding of peptide alpha 146-162 to the I-A molecules of B6 and bm12. Furthermore, APC of bm12 presented the peptide, or tAChR, poorly to peptide-specific or to tAChR-specific B6 T cells. The major effect is caused by the change of Thr-71 in I-A beta b to lysine in I-A beta bm12. However, APC of B6 also presented peptide alpha 146-162 much less efficiently to peptide-specific T cells of bm12. This demonstrated that these three amino acid changes also influence the T cell receptor recognition of peptide-MHC complex and that both B6 and bm12 T cells recognizing peptide alpha 146-162 or tAChR are under a high H-2 restriction.
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PMID:Effect of amino acid substitutions within the region 62-76 of I-A beta b on binding with and antigen presentation of Torpedo acetylcholine receptor alpha-chain peptide 146-162. 753 3

According to some models of T cell education, tolerance, and autoimmunity, recognition of MHC molecules by T cells may depend on the nature of the APC expressing the MHC/Ag complex. To examine this, a panel of 23 I-Ad-restricted, alloreactive T cells were used to probe MHC class II molecules expressed on established lines representing different lineages. Surprisingly, we observed cell type-specific reactivity in the majority of the T cells. In all, 18 different reactivity patterns were identified. The patterns observed suggests that MHC reactivity can be organized into a hierarchical pattern for both the APC and the T cells. Experiments assessing T cells' avidities for allogeneic targets, ability to produce lymphokines, and expression of accessory molecules revealed no predictive correlation with the hierarchical reactivity pattern, nor did experiments measuring allogeneic target cells' expression of known accessory molecules and ability to stimulate Ag-specific hybridomas. These results suggest that the differential reactivity cannot be accounted for by accessory molecule discrepancies among the APC, but rather might reflect deficiencies in the ability of the various APC to engage the Ag-specific T cell receptor. Collectively, these data indicate that a significant fraction of allorecognition of MHC class II is cell-type dependent and that cell-type-specific recognition may relate to peptide-specific recognition requirements by the Ag receptor of alloreactive T cells.
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PMID:T cell receptor recognition of MHC class II alloantigens is highly cell type dependent. 790 4

Superantigens interact with specific V beta elements of the T cell receptor and consequently activate all T cells bearing those elements. The ability of superantigens to stimulate T cells depends on the presence of APC that express MHC class II molecules on their surface. The question we are addressing is: do superantigens have to be seen in context of MHC class II molecules, or can they be recognized directly by T cell-receptor elements? We have previously shown that the APC requirement for the stimulation of T cells by the streptococcal superantigen, pep M5, can be bypassed by the addition of PMA and cytokines or by crosslinking CD28 molecules. Here we asked if the response of APC-depleted T cells to this superantigen is V beta-restricted and whether in the presence of PMA and cytokines the specificity of pep M5 to V beta elements is altered. We provide evidence that in the absence of APC, but in the presence of PMA and cytokines, the specificity of pep M5 to V beta elements is identical to that observed when APC are present, with V beta 2, V beta 4, and V beta 8 being significantly expanded. In addition, we ruled out the possibility that the response is due to a minor contamination with APC or to the expression of DR molecules on T cells because anti-HLA class II monoclonal antibodies did not block the reconstituted response, whereas they totally abrogated the response in the presence of APC. We conclude that pep M5 does not have to complex with MHC class II molecules in order to interact with specific V beta elements. In addition, we propose that the inhibitory effects of the anti-class II antibodies when APC are present may be due to preventing pep M5 from binding and activating APC, thereby blocking the production of costimulatory molecules necessary for T cell activation by this superantigen.
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PMID:Preservation of the specificity of superantigen to T cell receptor V beta elements in the absence of MHC class II molecules. 825 43

Complexes of antigen analogues and major histocompatibility complexes have been demonstrated to function as effective antagonists of the T cell receptor (TCR). It was observed that modification of any of the major T cell contact residues can create powerful TCR antagonists. Increasing similarity of antagonist to antigen structure resulted in increased capacity to act as a TCR antagonist up to a point beyond which the analogues themselves showed antigenicity. These data strongly suggested that peptide: TCR interaction with a certain low affinity may still be sufficient for engagement of the receptor but not for signalling, thus resulting in antagonism. It was found that the presentation of antagonistic peptides alone did not induce the formation of stable conjugates between antigen presenting cells and T cells, but rather that presentation of antigen was required to induce the initial interaction of APC with T cells in cell:cell conjugates. This antigen-dependent conjugate formation was not affected by the antagonist, while very early intracellular biochemical events such as PI turnover and CA2+ flux were inhibited.
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PMID:Antigen analogues as antagonists of the T cell receptor. 832 51

Carbohydrates are T cell independent antigens because they do not bind to MHC molecules. However, glycopeptides might potentially bind to MHC molecules via their peptide component for presentation to T cells. We have conjugated the disaccharide galabiose [Gal alpha (1-4)Gal beta] to the amino terminus of a T cell peptide determinant from hen egg-white lysozyme [HEL(52-61)]. The resulting glycopeptide (Gal2-52-61) and a nonglycosylated analogue containing tyrosine and glutamic acid at the amino-terminus (YE-52-61) bound equally well to purified I-Ak. T cell hybridomas were produced after immunization with Gal2-52-61. Many of the T cell hybridomas were glycopeptide-specific and responded to Gal2-52-61 but not to nonglycosylated synthetic peptides or to HEL presented by APC, indicating that the carbohydrate moiety influenced T cell recognition. Recognition was lost with the amino terminal attachment of the disaccharide to a peptide six amino acids longer at the amino terminus than HEL(52-61). Recognition also was lost with peptides containing only a single galactosyl residue or with galabiose bound to a different I-Ak binding peptide. T cells directed to Gal2-52-61 recognized glycopeptides having significant variation in the disaccharide structure, such as HEL(52-61) glycopeptides carrying lactose, cellobiose, or hepta-o-acetylated galabiose. Peptide residues were important features of the T cell epitope; Ala substitutions of two critical T cell contact residues of HEL(52-61) (Tyr53 and Leu56) abrogated T cell reactivity to the glycopeptides without affecting binding to I-Ak. In conclusion, we propose that these T cells recognize a peptide conformation specific to glycopeptide-I-Ak complexes and that this recognition does not involve specific interaction between the carbohydrate moiety and the T cell receptor.
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PMID:Glycopeptides bind MHC molecules and elicit specific T cell responses. 836 Apr 71

A self-peptide containing amino acid residues 46-61 (NRGDQSTDYGIFQINSR) of mouse lysozyme (ML) (p46-61, which binds strongly to the A(k) molecule but does not bind to the E(k) molecule), can induce a strong proliferative T cell response in CBA/J mice (A[k], E[k]) but no response at all in B10.A(4R) and CBA/J mice. The critical residues within p46-59 are immunogenic in both B10.A(4R) and CBA/J mice. The critical residues within p46-61 reside between amino acid positions 51 and 59. T cells of B10.A(4R) mice primed with the truncated peptides in vivo cannot be restimulated by p46-61 in vitro. This suggests that T cell receptor (TCR) contact (epitopic) residue(s) flanking the minimal 51-59 determinant within p46-61 hinder the interaction of the p46-61/A(k) complex with the appropriate TCR(S), thereby causing a lack of proliferative T cell response in this mouse strain. Unlike B10.A(4R) mice, [B10.A(4R) x CBA/J]F1 mice responded vigorously to p46-61, suggesting that thymic APC of B10.A(4R) mice do not present a self ligand to T cells resulting in a p46-61-specific hole in the T cell repertoire in B10.A(4R) or the F1 mice. Moreover, APC from B10.A(4R) mice are capable of efficiently presenting p46-61 to peptide-specific T cell lines from CBA/J mice. The proliferative unresponsiveness of B10.A(4R) mice to p46-61 is not due to non-major histocompatibility complex genes because B10.A mice (A[k], E[k]) respond well to p46-61. Interestingly, B10.A(4R) mice can raise a good proliferative response to p46-61 (R61A) (in which the arginine residue at position 61 (R61L/F/N/K), indicating that R61 was indeed responsible for hindering the interaction of p46-61 with the appropriate TCR. Finally, chimeric mice [B10.A(4R)-->B10.A] responded vigorously to p46-61, suggesting that thymic antigen presentation environment of the B10.A mouse was critical for development of a p46-61-reactive T cell repertoire. Thus, we provide experimental demonstration of a novel mechanism for unresponsiveness to a self peptide, p46-61, in the B10.A(4R) mouse owing to hindrance: in this system it is the interaction between the available TCR and the A(k)/p46-61 complex, which is hindered by epitopic residue(s) within p46-61. We argue that besides possessing T cells that are hindered by R61 of p46-61, CBA/J and B10.A mice have developed an additional subset of T cells bearing TCRs which are not hinderable by R61, presumably through positive selection with peptides derived from class II E(k), or class I D(k)/D(d) molecules. These results have important implications in self tolerance, shaping of the T cell repertoire, and in defining susceptibility to autoimmunity.
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PMID:Unresponsiveness to a self-peptide of mouse lysozyme owing to hindrance of T cell receptor-major histocompatibility complex/peptide interaction caused by flanking epitopic residues. 862 65

T cell response to its antigen requires recognition by the T cell receptor together with a co-receptor molecule, either CD4 or CD8. Additional molecules have been identified that are capable of delivering the co-stimulatory signals provided by APC. Following T cell priming, a number of T cell activation antigens are expressed that may play a role in the inactivation phase of the T cell response. The lymphocyte activation gene (LAG)-3 protein and its counter-receptors, the major histocompatibility complex (MHC) class II molecules, are such activation antigens whose interaction may result in the down-regulation of the ongoing immune response. To investigate the role of LAG-3/class II molecule interaction, we produced a soluble form of LAG-3 by fusing the extracellular Ig domains of this membrane protein to the constant region of human IgG1 (LAG-3Ig). Here, we show a direct and specific binding of LAG-3Ig to class II molecules on the cell surface. In addition, we show that LAG-3/class II molecule interaction leads to the down-regulation of CD4+ Ag-specific T cell clone proliferation and cytokine secretion. This inhibitory effect is observed at the level of the effector cells and not the APC and is also found with anti-CD3 mAb, PHA + PMA or low-dose IL-2 driven stimulation in the absence of APC. These functional studies indicate that T cell MHC class II molecules down-regulate T cell proliferation following LAG-3 binding and suggest a role for LAG-3 in the control of the CD4+ T cell response.
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PMID:T cell major histocompatibility complex class II molecules down-regulate CD4+ T cell clone responses following LAG-3 binding. 864 85

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