Genetic control of peripheral TCRAV usage by representation in the preselection repertoire and MHC allele-specific overselection.

TCRAV segments contribute significantly to MHC restriction as illustrated by their general preference for either the CD4 or CD8 T cell subset and additional, MHC allele-specific overselection during T cell differentiation. The 10-fold over-representation of the TCRAV8S2 (VA8S2) segment in CD8 over CD4 T cells by the RT1(f) haplotype of LEW.1F rats provides the most striking example of MHC allele-specific overselection of a VA segment reported so far. Also in alloreactivity, VA8S2(+) CD8 cells from RT1(f-) rats are preferentially expanded by RT1(f+) stimulators. We have identified the class I molecule, A(f), mediating VA8S2 overselection and report that it differs only in four amino acids at the MHC-TCR interface from the class I molecule A(a), which is neutral with regard to selection of VA8S2. We also provide an extensive survey of the TCRAV8 family and show that among 14 functional VA8 segments in LEW rats, the dramatic A(f)-dependent overselection is unique for VA8S2. Surprisingly, VA8S2 expression in CD8 T cells of RT1(f+) rats derived from a Sprague-Dawley stock was only 3% as compared to the 12% observed in LEW.1F. The VA8S2 segment of Sprague-Dawley (VA8S2(SD)) differs from VA8S2 of the LEW background (VA8S2(l)) in only two amino acids, one of which is located in CDR2 and could thus participate in allele-specific recognition of A(f). However, analysis of the pre- and postselection thymic repertoires of Sprague-Dawley and LEW.1F rats and of the repertoire of CD8 cells from both strains expanded in the alloreactive response to RT1(f) revealed that the difference in VA8S2 representation between the two backgrounds is explained by differential availability in the preselection repertoires and not by a difference in overselection. Sequence comparisons of A(f) and A(a) and of both VA8S2 segments suggest a predominant role of CDR1 in hyper-reactivity to A(f). Thus, the VA composition of the mature TCR repertoire is influenced by TCRA: locus polymorphisms at two levels: the regulation of VA usage in the preselection repertoire and the composition of structural elements which contribute to specific VA-MHC interactions during thymic selection.

Thymic development and repertoire selection: the rat perspective.

This review summarizes our current knowledge of T-cell maturation and repertoire selection in the rat thymus. Some unique features of early thymocyte development and of CD4/CD8 lineage decision are described. A detailed analysis of lineage progression through the CD4, CD8 "double positive" compartment and T-cell receptor-induced CD8 T-cell maturation in cell culture is provided. A second emphasis is placed on interactions between germline-encoded T-cell receptor elements with MHC molecules in thymic repertoire selection and alloreactivity

Opposite CD4/CD8 lineage decisions of CD4+8+ mouse and rat thymocytes to equivalent triggering signals: correlation with thymic expression of a truncated CD8 alpha chain in mice but not rats.

Unselected CD4+8+ rat thymocytes, generated in vitro from their direct precursors, are readily converted to functional TCRhigh T cells by stimulation with immobilized TCR-specific mAb plus IL-2. Lineage decision invariably occurs toward CD4-8+, regardless of the timing of TCR stimulation after entry into the CD4+8+ compartment or the concentration of TCR-specific mAb used for stimulation. CD4-specific mAb synergizes with suboptimal TCR-specific mAb in inducing T cell maturation, but lineage decision remains exclusively CD4-8+. These results contrast with those obtained in mice, in which Abs to the TCR complex were shown to promote CD4+8- T cell maturation from CD4+8+ thymocytes. Surprisingly, when rat and mouse CD4+8+ thymocytes were stimulated with PMA/ionomycin under identical conditions, the opposite lineage commitment was observed, i.e., mouse thymocytes responded with the generation of CD4+8- and rat thymocytes with the generation of CD4-8+ cells. It thus seems that CD4+8+ thymocytes of the two species respond with opposite lineage decisions to strong activating signals such as given by TCR-specific mAb or PMA/ionomycin. A possible key to this difference lies in the availability of p56lck for coreceptor. supported signaling. We show that in contrast to mouse CD4+8+ thymocytes, which express both a complete and a truncated CD8 alpha-chain (CD8 alpha') unable to bind p56lck, rat thymocytes only express full-length CD8 alpha molecules. Mice, but not rats, therefore may use CD8 alpha' as a "dominant negative" coreceptor chain to attenuate the CD8 signal, thereby facilitating MHC class II recognition through the higher amount of p56lck delivered, and rats may use a different mechanism for MHC class distinction during positive selection.

Control of TCR V alpha-mediated positive repertoire selection and alloreactivity by differential J alpha usage and CDR3 alpha composition.

In rats expressing the f allele of the rat MHC (RT1f), CD8 T cells utilizing the V alpha 8.2 segment are 10-fold overselected during thymic development, resulting in V alpha 8.2 expression by 14% of mature CD8 T cells as compared to 1-2% in MHC congenic strains. In the alloreactive responses of CD8 T cells from RT1f-negative rats against RT1f, V alpha 8.2+ CD8 T cells are also preferentially expanded. Neither overselection nor alloreactivity of V alpha 8.2+ TCR require selective V beta pairing. However, RT1f alloreactive V alpha 8.2+ TCR preferentially use a related set of J alpha segments which contribute short homogeneous CDR3 alpha loops, with features suggesting peptide promiscuity, and little N additions. In contrast, only few overselected V alpha 8.2+ CD8 T cells showed an imprint of positive selection on J usage or CDR3 composition. The results demonstrate that a single V alpha segment can promote both MHC allele-specific positive selection and alloreactivity, and that the latter is more dependent on an additional contribution of CDR3 alpha, possibly by promoting reactivity with a diverse set of MHC-bound peptides or by providing additional MHC contacts.

The canonical T cell receptor of dendritic epidermal gamma delta T cells is highly conserved between rats and mice.

Two monoclonal antibodies with specificity for rat gammadelta T cell receptor (TCR) were generated. One, called V65, reacts with all CD3+ alphabeta TCR- rat Tcells and thus recognizes a constant determinant of the rat gammadelta TCR (Kühnlein et al., Journal of Immunology 1994, 153: 979). The other, called V45, reacts with approximately 80% of gammadelta T cells in peripheral lymphoid organs. In rat epidermis, V65 but not V45 detects a dense network of the dendritic epidermal Tcells (DETC). Analysis of epidermal RNA by polymerase chain reaction (PCR) indicated that Vgamma3 and Vdelta1 are the predominant, if not exclusive TCR V transcripts present at this site. Sequence analysis of cDNA clones obtained by reverse transcription-PCR with Vgamma3- and Vdelta1-specific primers revealed that the variable domains of rat DETC gamma and delta chains are very homologous to those described in mice (92% and 95% identity at the protein level). The complete conservation between the two species of the amino acid sequences at the V-(D)-J transitions of this monomorphic receptor indicates that the interaction of the DETC TCR with its as yet unknown ligand must be of central importance for DETC function.

Prevention and treatment of Lewis rat experimental allergic encephalomyelitis with a monoclonal antibody to the T cell receptor V beta 8.2 segment.

The predominance of T cell receptor (TCR) V beta 8.2 utilization by encephalitogenic T cells induced in Lewis rats by immunization with myelin basic protein (MBP) is controversial. Thus, both an almost exclusive usage of V beta 8.2 [Burns, F. R., Li, X., Shen, N., Offner, H., Chou, Y. K., Vandenbark, A. A. and Heber-Katz, E., J. Exp. Med. 1989, 169: 27; Chluba, J., Steeg, C., Becker, A., Wekerle, H. and Epplen, J. T., Eur. J. Immunol. 1989. 19: 279] and a quite diverse V beta composition of CD4 T cells causing experimental autoimmune encephalomyelitis (EAE) [Sun, D., Gold, P. D., Smith, L., Brostoff, S. and Coleclough, C., Eur. J. Immunol, 1992. 22: 591; Sun, D., Le, J. and Coleclough, C., Eur. J. Immunol. 1993. 23: 494] have been reported. Using a recently developed monoclonal antibody (mAb) specific for TCR V beta 8.2, we show that postnatal treatment effectively eliminates V beta 8.2-bearing cells and prevents MBP-induced EAE in the majority of Lewis rats. Moreover, treatment of adult Lewis rats with V beta 8.2-specific mAb as late as on day 12 after MBP immunization suppressed the development of neurological symptoms. Thus, V beta 8.2-bearing cells do play a decisive role in Lewis rat EAE, and suppression of the small (5%) V beta 8.2-expressing T cell subset provides an effective therapeutic strategy.

Encephalitogenic, myelin basic protein-specific T cells from naive rat thymus: preferential use of the T cell receptor gene V beta 8.2 and expression of the CD4-CD8- phenotype.

Using a primary limiting dilution approach to generate T cell lines, we compared myelin basic protein (MBP)-specific T cell clones from naive unprimed Lewis rat thymuses with the corresponding T cell repertoire of primed rats. We found that in the native thymus repertoire MBP-specific, encephalitogenic T cell clones preferentially use T cell receptor V beta 8.2 genes, along with CDR3 sequences typical for the primed Lewis anti-MBP response. In contrast to T cells from primed immune organs, which all display the CD4+CD8- phenotype, the majority of naive thymus-derived T cell clones expressed reduced levels of the CD4 co-receptor. Some clones were completely CD4-CD8-, while others included CD4-CD8- subpopulations along with CD4+CD8- T cells. In the one mixed population examined in detail, the CD4-CD8- and CD4+CD8-T cell subpopulations used a T cell receptor with identical beta chain sequence. The data suggest that in the Lewis rat the biased T cell receptor gene usage by encephalitogenic T cells is a property of the natural thymic T cell repertoire, possibly as a consequence of positive selection. The unusually low expression of CD4 in the major histocompatibility complex class II-restricted autoreactive T cells could be related to their escape from negative selection within the thymus.

Structural analysis of the rat T-cell receptor Tcra V4 gene family.

The rat Tcra V gene locus is only poorly characterized, although rats are widely used in a variety of T-cell-mediated experimental animal models. Recently, we described the first monoclonal antibody, G99, directed against a rat Tcra V4 segment. We examined cDNA transcripts of G99-positively sorted T cells and show that the monoclonal antibody G99 most likely recognizes at least two members of the Tcra V4 family. Moreover, we analyzed the genomic repertoire of this VA family and report 15 novel Tcra V4 DNA sequences. Based on sequence and Southern blot analysis, the Tcra V4 family could be divided into four subgroups, which were also detected in mice. These findings corroborate previous findings of a similar genetic organization of the Tcra V loci in both species.

Preferential TCR V usage in rat repertoire selection: V alpha 8 imparts both positive thymic selection by and alloreactivity to RT1f.

Using a panel of newly developed mAb to two rat TCR V alpha and four TCR V beta segments, TCR V usage in CD4 and CD8 T cells of eight RT1 congenic strains sharing the LEW background was analyzed by flow cytometry. While no striking effects on V beta 8.2 and 8.5 usage were observed, a 3- to 4-fold over-representation of V beta 10 in the CD4 as compared with the CD8 subset in all strains suggested a preference of V beta 10 for MHC class II products. The degree of 'overselection' was mapped to the RT1.B/D region. In addition, an allele-specific overselection of V alpha 4+ CD4 T cells was mapped to RT1.B/Du and of V beta 16+ CD8 T cells to RT1.Au. Finally, a dramatic overselection of V alpha 8+ CD8 T cells by RT1f (14% in RT1f versus 1-2% in other haplotypes) provides the most striking case yet for an intrinsic affinity of a TCR V segment for an MHC product. V alpha 8+ CD8 T cells are not only overselected by RT1f in the thymus, but also during the alloreactive response of peripheral CD8 T cells to RT1f. The implications of these findings for the contribution of TCR V segments to TCR-MHC interactions in repertoire selection and alloreactivity are discussed.

Control of the rat T cell response to retroviral and bacterial superantigens by class II MHC products and Tcrb-V8.2 alleles.

The in vitro response of unprimed rat T cells to retroviral and bacterial superantigens (SAg) was analyzed with TCR V beta 8.2-, 8.5-, 10-, and 16-specific mAbs. Specific stimulation of V beta 8.2 and 8.5 CD4 cells was observed in the response to Mls1a, the retroviral SAg encoded by integrated provirus Mtv-7 (Mtv-7 SAg), which was presented by mouse B cells or mouse fibroblasts transfected with DR1 genes and the Mtv-7 SAg. Additionally, a strong response of V beta 16 CD4 cells to an as yet unidentified mouse SAg was found. Only some of the bacterial SAg known to stimulate mouse and human T cells also activated rat lymph node cells. SEA, SEE, and TSST-1 stimulated rat T cells well; SEB, SEC1, and SED did not. This defect was apparently a result of weak binding to rat MHC class II molecules because presentation by human MHC class II molecules restored T cell activation. Under these conditions, SEB stimulated V beta 8.2+ and 8.5+ CD4 and CD8 cells from Lewis rats. A comparison of several rat strains revealed an unresponsiveness to SEB or Mtv-7 SAg for V beta 8.2 cells from F344 and DA rats. Determination of the nucleotide sequences of the Tcrb-V8.2 of these strains revealed differences between SAg-responsive and SAg-unresponsive Tcrb-V8.2 in seven amino acids, four of them located in the putative SAg contact site. The significance of these findings for the evolution of TCR-SAg interactions is discussed.

T cell receptor ligation induces interleukin (IL) 2R beta chain expression in rat CD4,8 double positive thymocytes, initiating an IL-2-dependent differentiation pathway of CD8 alpha+/beta- T cells.

The role of interleukin (IL)2 in intrathymic T cell development is highly controversial, and nothing is known about IL-2R expression on thymocytes of the T cell receptor (TCR) alpha/beta lineage undergoing TCR-driven differentiation events. We analyze here IL-2R alpha and beta mRNA expression in an in vitro system where newly generated rat CD4,8 double positive (DP) thymocytes respond to TCR ligation plus IL-2 (but not to either stimulus alone) with rapid differentiation to functional CD8 single positive T cells (Hünig, T., and R. Mitnacht. 1991. J. Exp. Med. 173:561). TCR ligation induced expression of IL-2R beta (but not alpha) chain mRNA in DP thymocytes. Addition of IL-2 then lead to functional maturation and expression of the IL-2R alpha chain. To investigate if the CD8 T cells generated via this IL-2R beta-driven pathway in vitro correspond to the bulk of CD8 T cells seeding peripheral lymphoid organs in vivo, we compared their phenotype to that of lymph node CD8 T cells. Surprisingly, analysis of CD8 cell surface expression using a novel anti-CD8 monoclonal antibody specific for the alpha/beta heterodimeric isoform, and of CD8 alpha and beta chain mRNA revealed that T cells generated by TCR ligation plus IL-2 resemble thymus-independent rather than thymus-derived CD8 cells in that they express CD8 alpha without beta chains. These findings demonstrate that TCR crosslinking induces functional IL-2R on immature DP rat thymocytes. In addition, they show that at least in vitro, CD8 alpha/alpha T cells are generated from TCR-stimulated DP thymocytes (which express the CD8 alpha/beta in the heterodimeric isoform) along an IL-2-driven pathway of T cell differentiation.

Differential thymus dependence of rat CD8 isoform expression.

Expression of the rat CD8 molecule was studied using five novel monoclonal antibodies (mAb), four of which are specific for the V-like domain of CD8 alpha, whereas one reacts either with the beta chain or with a determinant only expressed on the CD8 alpha/beta heterodimer. mAb to both chains effectively blocked purified lymph node CD8 T cells in mixed lymphocyte reaction and in cell-mediated cytotoxicity. Flow cytometric analysis showed that CD8 T cells from lymph nodes or spleen of normal rats almost exclusively express the alpha/beta isoform, regardless of the T cell receptor isotype (alpha/beta or gamma/delta). In contrast, natural killer (NK) cells carry only CD8 alpha chains. This CD8 alpha + beta - phenotype was also prominent among CD8 T cells from athymic rats and from intestinal epithelium of normal rats. CD8 alpha homodimers can also be expressed as a result of activation, as shown by analysis of CD4 CD8 double-positive T cells obtained from highly purified lymph node CD4 T cells by in vitrok stimulation. Such CD4+CD8 alpha + beta - cells also represent a major subset among adult intestinal intraepithelial lymphocytes (IEL), suggesting local activation. Taken together, the difference in CD8 isoform expression among T cells from athymic rats, NK cells, and gut IEL versus CD8 T cells from peripheral lymphatic organs of euthymic animals suggests that like in mice, expression of the CD8 heterodimer is more dependent on intrathymic maturation than that of the homodimer. Since the more stringent thymus dependence of CD8 alpha + beta + T cells may be due to a requirement for thymic selection on self major histocompatibility complex class I antigens, the virtually exclusive CD8 alpha + beta + phenotype of peripheral rat gamma/delta T cells could mean that antigen recognition by this subset is also restricted by MHC class I molecules.