DNA-mediated transfer of major histocompatibility class II I-Ab and I-Abm12 genes into B lymphoma cells: molecular and functional analysis of introduced antigens

A20.2J B lymphoma cells have been co-transfected with the A alpha b, A beta b or with the A alpha b, A beta bm12 and neomycin resistance genes. The transfected cell lines constitutively express the I-Ab or I-Abm12 class II molecules at a level comparable with that of the endogenous I-Ad antigen. The I-Ab antigens expressed on three independently transfected B cell clones (A20.Ab.1, A20.Ab.2, and A20.Ab.3) are serologically and functionally indistinguishable from the I-Ab molecules expressed by control H-2bxd B hybridoma cells (LB cells). These transfected cell lines were potent I region-restricted antigen-presenting cells to a large panel of antigen-specific, autoreactive and alloreactive T cell hybridomas, as well as normal T cell clones. There were not significant differences in the efficiency of antigen presentation by the Ia molecules encoded by the transfected, as compared with the endogenous, I-A genes. The expression of a functional I-Ab antigen on the surface of cells transfected with A beta bm12 and A alpha b genes is consistent with previous work that implicated the A beta-chain alone in the bm 12 mutation. Furthermore, because the transfected A20.Ab and A20.Abm12 cells display the serologic and functional properties of normal spleen cells from the wild-type and mutant mouse strains, respectively, it is clear that class II genes do not undergo unexpected and unpredictable alterations after transfection in this system. This system permits us to investigate the structural requirements for interactions between class II major histocompatibility complex antigens, a foreign antigen, and the T cell receptor by in vitro site-directed mutagenesis coupled with DNA-mediated gene transfer.     

Receptor diversity of insulin-specific T cell lines from C57BL (H-2b) mice

To characterize the T cell receptor repertoire in an immune response in which the Ia and nominal antigenic determinants are defined and limited, we have cloned and sequenced the expressed receptors from four independent, beef insulin-specific T cell lines from C57BL mice. Each of these lines responded to beef but not to the pork insulin, thus defining the nominal antigenic determinant recognized. Furthermore, each of these lines could only be presented antigen by B6 but not mutant B6.C-H-2bm12 antigen-presenting cells, thus defining the requisite Ia recognition or antigen-association site. In spite of this functional similarity in ligand specificity, each of these T cell lines was found to use different V alpha and V beta gene segments. Moreover, structural comparisons of implied protein sequences of each of these receptors showed no stretches of conserved amino acid residues that could be implicated in ligand interaction. However, the V alpha genes used by these four clones appeared considerably more homologous to each other than were their V beta genes.     

Rearrangement and expression of T-cell antigen receptor genes in human T-lymphocyte tumor lines and normal human T-cell clones: evidence for allelic exclusion of Ti beta gene expression and preferential use of a J beta 2 gene segment.

The gene encoding the beta chain of the human T-cell receptor for antigen is composed of variable (V), diversity (D), joining (J), and constant (C) gene segments which undergo specific rearrangements during T-lymphocyte ontogeny. Southern blot analyses of seven human T-cell tumor lines and normal human T-lymphocyte clones revealed that most of these T-cell lines rearrange their Ti beta genes differently. The T-cell tumor line HPB-MLT rearranges and transcribes both of its Ti beta genes. Cloning and sequencing of the Ti beta cDNAs corresponding to these rearrangements revealed that one of the rearranged Ti beta genes is defective, while the other is functional and corresponds to the Ti beta protein expressed on the surface of these cells. Thus, this cell line displays a pattern of allelic exclusion of Ti beta gene expression. A comparison of four C beta 2-containing Ti beta cDNAs from three different cell lines revealed that three of the four utilize the same J beta 2.5 gene segment joined to different D beta and V beta genes, suggesting that there may be preferential use of this J gene during J beta 2 rearrangements. Hybridization analyses with probes for the alpha and beta genes of the T-cell receptor and the T-cell-specific T gamma gene revealed that HPB-MLT cells appear to express approximately equivalent amounts of RNA corresponding to each of the rearranged Ti alpha and Ti beta genes. However, they express a much lower level of T gamma RNA.     

Restricted V-segment usage in T-cell receptors from cytotoxic T lymphocytes specific for a major epitope of lymphocytic choriomeningitis virus.

Cytotoxic T lymphocytes (CTL) play an important role in recovery from a number of viral infections. They are also implicated in virus-induced immunopathology as best demonstrated in lymphocytic choriomeningitis virus (LCMV) infection of adult immunocompetent mice. In the present study, the structure of the T-cell receptor (TCR) in LCMV-specific CTL in C57BL/6 (B6) mice was investigated. Spleen T cells obtained from LCMV-infected mice were cultured in vitro with virus-infected stimulator cells and then stained with anti-TCR V beta antibodies. A skewing of V beta usage was noticeable in T cells enriched for their reactivity to LCMV, suggesting that particular V segments are important for the recognition of LCMV T-cell epitopes in B6 mice. To gain more detailed information on the structure of the TCR specific for LCMV epitopes, we studied CTL clones. It has been shown that approximately 90% of LCMV-reactive CTL clones generated in H-2b mice are specific for a short peptide fragment of the LCMV glycoprotein, residues 278 to 286, recognized in the context of the class I major histocompatibility complex molecule, Db. Four CTL clones possessing the specificity were randomly selected from a collection of clones, and their TCR genes were isolated by cDNA cloning or by the anchored polymerase chain reaction. All four clones were found to use V alpha gene segments belonging to the V alpha 4 subfamily. By RNA blot analysis, two more clones with the same specificity were also shown to express the V alpha 4 mRNA. In contrast, three different V beta gene segments were used among the four clones examined. J beta 2.1 was used by three of the clones. Although amino acid sequences in the V(D)J junctional regions were dissimilar, aspartic acid was found in the V alpha J alpha and/or V beta D beta J beta junctions of all four of these clones, suggesting that this residue is involved in binding the LCMV fragment. Restricted usage of V alpha and possibly J beta segments in the CTL response to a major T-cell epitope of LCMV raises the possibility that immunopathology in LCMV infection can be treated with antibodies directed against such TCR segments. Thus, similar analysis of the TCR in other virus infections is warranted and may lead to therapeutic strategies for immunopathology due to virus infections.     

Preferential use of a T cell receptor V beta gene by acetylcholine receptor reactive T cells from myasthenia gravis-susceptible mice.

Experimental autoimmune myasthenia gravis (EAMG) is an important model for testing current concepts in autoimmunity and novel immunotherapies for autoimmune diseases. The EAMG autoantigen, acethylcholine receptor (AChR), is structurally and immunologically complex, a potential obstacle to the application of therapeutic strategies aimed at oligoclonal T cell populations. Inasmuch as we had previously shown that the clonal heterogeneity of T cell epitope recognition in EAMG was unexpectedly limited, we examined TCR V beta expression. AChR primed lymph node T cells and established AChR reactive T cell clones from EAMG-susceptible C57BL/6 (B6; H-2b, Mls-1b) mice showed preferential utilization of the TCR V beta 6 segment of the TCR. After in vivo priming and in vitro restimulation for 7 days with AChR or a synthetic peptide bearing an immunodominant epitope, V beta 6 expressing lymph node cells (LNC) were expanded several-fold, accounting for up to 75% of recovered viable CD4+ cells. The LNC of B6.C-H-2bm12 (bm12; H-2bm12, Mls-1b) mice, which proliferated in response to AChR but not to the B6 immunodominant peptide, failed to expand V beta 6+ cells. Inasmuch as nonimmune bm12 and B6 animals had similar numbers of V beta 6+ LNC (4-5%), this suggested that structural requirements for TCR recognition of Ag/MHC complexes dictated V beta usage. Results concerning peptide reactivity and V beta 6 expression among T cells from (B6 x bm12)F1 animals also suggested that structure-function relationships, rather than negative selection or tolerance, accounted for the strain differences between B6 and bm12. To examine the potential effects of thymic negative selection of V beta 6+ cells on the T cell response to AChR, CB6F1 (H-2bxd, Mls-1b; V beta 6-expressing) and B6D2F1 (H-2bxd, Mls-1axb; V beta 6-deleting) strains were analyzed for AChR and peptide reactivity and V beta 6 expression. Both F1 strains responded well to AChR but the response of B6D2F1 mice to peptide was significantly reduced compared to CB6F1. Short and long term cultures of peptide-reactive B6D2F1 LNC showed no expansion of residual V beta 6+ cells, although similar cultures of CB6F1 LNC were composed of more than 60% V beta 6+ cells. The results from the F1 strains further indicated that the T cell repertoire for peptide was highly constrained and that non-V beta 6 expressing cells could only partially overcome Mls-mediated negative selection of V beta 6+ TCR capable of recognizing peptide.(ABSTRACT TRUNCATED AT 400 WORDS)     

The molecular basis of alloreactivity in antigen-specific, major histocompatibility complex-restricted T cell clones

We have studied the relationship between major histocompatibility complex (MHC)-restricted antigen recognition and alloreactivity by examining T cell receptor (TCR) alpha and beta gene expression in cytochrome c-specific, Ek alpha:Ek beta (Ek)-restricted helper T cell clones derived from B10.A mice. The clones could be segregated on the basis of four distinct alloreactivity patterns. Clones cross-reactive for three different allogeneic la molecules (As alpha:As beta [As], Ab alpha:Ab beta [Ab], Ek alpha: Eb beta [Eb]) expressed the same V alpha and V beta gene segments, generating the distinct alloreactive specificities via unique V alpha-J alpha and V beta-D beta-J beta joining events. Ek alpha:Es beta (Es)-alloreactive B10.A clones expressed the same V alpha, J alpha, and V beta segments as an Es-restricted, Ek-alloreactive, cytochrome c-specific, H-2-congenic B10.S(9R) clone. This homology between TCRs mediating allorecognition of la molecules and recognition of the same la molecules as restriction elements associated with nominal antigen suggests that MHC-restricted recognition and allorecognition represent differences in the affinity of the TCR-MHC molecule interaction.     

Predominant use of a T-cell receptor V beta gene family in simian immunodeficiency virus Gag-specific cytotoxic T lymphocytes in a rhesus monkey.

To explore the structural basis for AIDS virus recognition by CD8+ lymphocytes, we sought to determine whether there is a diverse or restricted usage of T-cell receptors (TCR) by simian immunodeficiency virus of macaques (SIVmac) Gag-specific cytotoxic T lymphocytes (CTL) in the rhesus monkey. Six Gag-specific CTL clones were independently generated from an SIVmac-infected rhesus monkey. All six CTL clones recognized a single SIVmac Gag peptide in association with a single major histocompatibility complex class I gene product, Mamu-A*01. TCR alpha-chain sequences from these six CTL clones employed four different V alpha families and five different J alpha gene segments. In contrast, five of the six CTL clones expressed V beta genes that were members of the same family, a human V beta 23 homolog. Furthermore, only one J beta gene was expressed by four of the six CTL clones. These results indicate that TCR of SIVmac Gag-specific CTL from a rhesus monkey can exhibit a restricted usage of V beta gene families and J beta genes.     

Characterization of diverse primary herpes simplex virus type 1 gB-specific cytotoxic T-cell response showing a preferential V beta bias.

The glycoprotein B (gB) from herpes simplex virus type I is a major target of cytotoxic T lymphocytes (CTL) in C57BL/6 mice. The majority of these T cells are directed to a single Kb-restricted determinant, gB498-505. We have analyzed the T-cell receptor (TCR) usage in gB-specific CTL lines derived shortly after virus infection. The CTL populations preferentially used two V beta regions, a dominant V beta 10 element and a subdominant V beta 8 element. Detailed sequence analysis revealed considerable TCR beta-chain heterogeneity despite a striking level of predicted amino acid conservation at the V beta-D beta junction. This junction forms part of the third hypervariable loop of the TCR thought to directly contact the major histocompatibility complex-bound antigenic peptide. The results reveal considerable diversity within the primary T cells responding to a single viral determinant while still maintaining a high degree of TCR V beta bias and sequence conservation at the V-D-J junction.     

Complexity of T cell receptor recognition sites for defined alloantigens

Three monoclonal antibodies react with the T cell receptor on the tumor line HPB-ALL and in addition with 3 to 13% of human peripheral blood T cells of normal donors. These antibodies are shown to react with an epitope encoded by the V beta 5 family of T cell receptor beta-chain variable region gene segments. Cells expressing V beta 5 gene segments can have cytotoxic or helper function, be of the T4+ or T8+ phenotype, and have specificity for either class I or class II major histocompatibility complex alloantigens. Seven T cell clones were generated, which express V beta 5 and are specific for the HLA-A2 molecule. With the use of these clones, we illustrate how isoelectric focusing can be used to analyze T cell receptor alpha- and beta-chain structure. The seven clones recognize five distinct conformational determinants on HLA-A2. They procure different binding sites by the use of different alpha-chains, J beta sequences, or both.     

Delineation of Ia:nominal antigen complementary determinants recognized by T cells in studies of gene complementation in response to insulin

The immune response to beef insulin in mice is controlled by genes in the IA subregion. We have previously shown that B6.C-H-2bm12 (bm12) mice, an A beta gene mutation of B6, have a selective loss of responsiveness to beef insulin, whereas other IAb controlled responses such as (TG)AL and collagen are unchanged. F1 hybrid mice between two nonresponder genotypes Ik and Ibm12 were found to be good responders to beef insulin suggesting functional complementation. In this report, we define the cellular and molecular basis of this complementation by investigating the determinants on Ia molecules and nominal antigen that are recognized by (B10.A X bm12)F1 proliferating T cells. Genetic analyses demonstrated that the Ik region was the only nonresponder genotype that complemented Ibm12, thus restoring responsiveness to beef insulin. More precisely an IAk and not an IEk gene product was found to be responsible for this complementation. Antibody blocking studies furthermore showed that the A alpha b:A beta k hybrid Ia mediated the response to beef insulin in (B10.A X bm12)F1 mice. Clonal analyses of the response to beef insulin in these F1 mice confirmed these conclusions, because the insulin-specific response in all 21 F1-T cell clones studied thus far was found to be dependent upon presentation via the A alpha b:A beta k hybrid Ia molecule. Dissection of the antigenic specificity of the F1-T cell clones demonstrated recognition of at least two insulin determinants, one A-loop (A8-A10) associated and the other non-loop (A4 or B chain) associated. Therefore these studies identify the molecular and antigenic basis of the Ir gene complementation seen in the response to beef insulin of (B10.A X bm12)F1 hybrids.     

Presentation of an immunodominant T-cell epitope of hepatitis B surface antigen by the HLA-DPw4 molecule

Human T cells that recognize a major epitope of the hepatitis B surface antigen were studied for their ability to react with antigen when presented by mouse fibroblasts that express class II products of the human major histocompatibility gene complex after gene transfection. L cells expressing HLA-DPw4, but not those expressing HLA-DR4 or HLA-DR7, induced strong proliferative responses of antigen-specific T cells to either hepatitis B surface antigen or the synthetic peptide S1d, which bears the immunodominant T-cell epitope. These results identified a genetic restriction element of human helper T-lymphocyte responses to a major antigenic determinant of hepatitis B virus and might be important in the design of subunit vaccines to this pathogen. Peptides that induce T-cell responses that are restricted by a frequently encountered major histocompatibility complex molecule in the general population such as DPw4 would be ideal candidates as subunit vaccines.     

T cell responses to select Ia determinants using the I-A mutant mouse strain B6.C-H-2bm12

The T cell repertoire of B6.C-H-2bm12 mice (an I-A mutant mouse strain) to wild-type Iab antigens was investigated using both secondary proliferative cultures and cloned T cell lines. Because bm12 mice have a gain-loss mutation of their gene encoding the Ia beta-chain polypeptide, bm12 anti-B6 T cell responses are specific for the select component of Iab specificities that was lost as a result of the mutation. Although stimulator cells bearing Iab antigens elicited the strongest responses, Iaq, d, and s antigens also resulted in reproducible stimulations of these bm12 anti-B6-primed T cells. Cloned T cell lines isolated from bm12 anti-b6 cultures revealed similar findings, with most clones recognizing determinants unique for Iab antigens; however, clones showing cross-reactions with Iad and/or q were also selected. Using F1 hybrid responder T cells (mutant x cross-reactive strain), we further dissected this cross-reactivity into several distinct cross-reactive determinants. Because bm12 mice lack the serologically defined Ia differentiation antigen W39, T cell recognition of this determinant was investigated by using bm12 anti-B6-primed cells. Stimulation by Ia.W39+ cells was appreciably better than by Ia.W39- (Xid-defective) cells, suggesting that bm12 T cells recognize an Xid-regulated, W39-like Ia differentiation antigen.     

Dissection of H-2Db-restricted cytotoxic T-lymphocyte epitopes on simian virus 40 T antigen by the use of synthetic peptides and H-2Dbm mutants.

Five distinct cytotoxic T-lymphocyte (CTL) recognition sites were identified in the simian virus 40 (SV40) T antigen by using H-2b cells that express the truncated T antigen or antigens carrying internal deletions of various sizes. Four of the CTL recognition determinants, designated sites I, II, III, and V, are H-2Db restricted, while site IV is H-2Kb restricted. The boundaries of CTL recognition sites I, II, and III, clustered in the amino-terminal half of the T antigen, were further defined by use of overlapping synthetic peptides containing amino acid sequences previously determined to be required for recognition by T-antigen site-specific CTL clones by using SV40 deletion mutants. CTL clone Y-1, which recognizes epitope I and whose reactivity is affected by deletion of residues 193 to 211 of the T antigen, responded positively to B6/PY cells preincubated with a synthetic peptide corresponding to T-antigen amino acids 205 to 219. CTL clones Y-2 and Y-3 lysed B6/PY cells preincubated with large-T peptide LT220-233. To distinguish further between epitopes II and III, Y-2 and Y-3 CTL clones were reacted with SV40-transformed cells bearing mutations in the major histocompatibility complex class I antigen. Y-2 CTL clones lysed SV40-transformed H-2Dbm13 cells (bm13SV) which carry several amino acid substitutions in the putative antigen-binding site in the alpha 2 domain of the H-2Db antigen but not bm14SV cells, which contain a single amino acid substitution in the alpha 1 domain. Y-3 CTL clones lysed both mutant transformants. Y-1 and Y-5 CTL clones failed to lyse bm13SV and bm14SV cells; however, these cells could present synthetic peptide LT205-219 to CTL clone Y-1 and peptide SV26(489-503) to CTL clone Y-5, suggesting that the endogenously processed T antigen yields fragments of sizes or sequences different from those of synthetic peptides LT205-219 and SV26(489-503).     

Specificity for molecules of the major histocompatibility complex mediated by a hybrid immunoglobulin-T cell receptor.

A chimeric T-cell receptor (TCR) alpha-chain gene was produced by shuffling the immunoglobulin VDJH from a 40-140 digoxin-specific hybridoma onto alpha-chain constant region (C alpha) exons. This hybrid immunoglobulin-TCR gene was used to produce transgenic mice. Previous results indicated that this chimeric gene encoded a polypeptide that associated with endogenously encoded beta chains to form a hybrid TCR. T cells expressing this receptor could be stimulated with antibodies specific for CD3 or the 40-140 idiotype (Id40-140), and also with digoxin coupled to bovine serum albumin (digoxin-BSA). We were interested in determining whether a hybrid receptor such as this could also recognize the natural ligand of T cells, namely allelic variants of major histocompatibility complex (MHC) molecules. A T-cell hybridoma was produced that expressed a hybrid receptor with specificity for an IAk-encoded determinant, digoxin-BSA, or staphyloccocal enterotoxin B. Transfection experiments showed that the specificity for MHC determinants was dependent on both the hybrid alpha chain and a particular beta chain. These results indicate that a V beta domain combined with a VH domain can produce a receptor capable of reacting with MHC molecules, and at the same time retain specificities mediated by the beta chain and alpha chain alone. A conclusion is that the pervasive MHC specificity of the TCR is not unique to the family of TCR heterodimers, but is selected, and can be mediated by immunoglobulin domains.     

The T cell receptor beta chain genes are located on chromosome 6 in mice and chromosome 7 in humans

Homologous clones that encode the beta chain of the T cell antigen receptor have been isolated recently from both murine and human cDNA libraries. These cDNA clones have been used in connection with interspecies hybrid cell lines to determine that the murine T cell receptor gene is located on chromosome 6 and the human gene on chromosome 7. In situ hybridization confirms these data and further localizes these genes to band B of chromosome 6 in the mouse and bands 7p13-21 in the human genome. The organization of the T cell antigen receptor J beta gene segments and C beta genes appears to be conserved, since very few intraspecies polymorphisms of restriction fragment length have been detected in either mouse or human DNA.     

Antigen-specific T-cell factor in cell cooperation and genetic control of the immune response.

Cell interactions between thymus-derived (T) and bone marrow-derived (B) lymphocytes in the antibody response appear to involve soluble T-cell mediators known as 'factors.' This paper describes the properties of a T-cell factor that has specificity for the inducing antigen, a synthetic polypeptide (T, G)-A--L, and is able to replace T cells in the thymus-dependent antibody response to (T, G)-A--L. Besides antigen specificity, the main features of the molecule are that it is nonimmunoglobulin; it has a molecular weight of about 50,000; and it is a product of the I-A subregion of the H-2 complex (the mouse major histocompatibility complex). These properties suggest that the factor is closely related to the T-cell receptor, which may, by inference, also be a product of the H-2 complex. The factor cooperates well with allogeneic B cells. It can also be absorbed by bone marrow cells and B cells. Studies on the genetic control of the immune response to (T, G)-A--L using the T-cell factor indicate that two immune response genes in the H-2 complex are involved in genetic control, one expressed in T cells and the other in B cells. This two gene hypothesis has been confirmed by showing that an F1 between two low responders to (T, G)-A--L can be a high responder.     

Induction of host gene expression following infection of chicken embryo fibroblasts with oncogenic Marek's disease virus

Microarrays containing 1,126 nonredundant cDNAs selected from a chicken activated T-cell expressed sequence tag database (http://chickest.udel.edu) were used to examine changes in host cell gene expression that accompany infection of chicken embryo fibroblasts (CEF) with Marek's disease virus (MDV). Host genes that were reproducibly induced by infection of CEF with the oncogenic RB1B strain of MDV included macrophage inflammatory protein, interferon response factor 1, interferon-inducible protein, quiescence-specific protein, thymic shared antigen 1, major histocompatibility complex (MHC) class I, MHC class II, beta(2)-microglobulin, clusterin, interleukin-13 receptor alpha chain, ovotransferrin, a serine/threonine kinase, and avian leukosis virus subgroup J glycoprotein.     

Generation of the alloreactive T cell repertoire: K region homology between H-2b T cell precursors and T cell maturation environment is required for the generation of the Kbm6-specific cytotoxic T cell repertoire

The influence of T cell genotype and T cell maturation environment on the generation of the T cell alloreactive repertoire was evaluated in the H-2b cytotoxic T lymphocyte response to Kb mutant determinants expressed by the strain B6-H-2bm6. Specifically, by constructing radiation bone marrow chimeras with B6 or B10 (H-2b) donor cells and B10.BR, B10.A(4R), B10.MBR, and B6.C-H-2bm1 irradiated mice as recipients, it was possible to investigate the major histocompatibility complex (MHC)-encoded gene products of the host environment required for the generation of a bm6-specific H-2b CTL response. The results of such experiments confirmed the previous finding that the alloreactive T cell repertoire is influenced both by T cell MHC genotype and by the MHC gene products of the T cell maturation environment. In addition, the results of the present study further demonstrated that in the chimeric donor and host genetic combinations used, it was both necessary and sufficient that there be a homology of K region-encoded determinants for the generation of a bm6-specific CTL response. Experiments utilizing a mixed responder population of unresponsive B6----B10.D2 spleen cells and responsive Lyt-2 congenic B6.Lyt-2.1 spleen cell suggested that the cellular defect(s) underlying the unresponsiveness of the chimeric cells to bm6-encoded determinants was at the level of the CTL precursor. Together, these findings indicate that an interaction of the K region-encoded gene products of the T cell and its maturation environment play a critical role in the generation of the CTL repertoire specific for bm6 mutant determinants. We discuss here the possibility that this interaction may reflect a requirement that T cells recognize such mutant allodeterminants in association with self restriction elements present on the same mutant K region-encoded molecule.