Selection of T cell receptor expression mutants through the functionally linked Ly-6A

Ly-6A is a glycosyl-phosphatidylinositol (GPI)-anchored molecule that participates in murine T cell activation. Activation of T cell hybridomas with anti-Ly-6A monoclonal antibody (mAb) leads to production of interleukin-2 (IL-2), but also to a paradoxical growth inhibition, which was used to select for signaling mutants. Fifteen subclones derived from two independent mutageneses and anti-Ly-6A selection were characterized. Thirteen subclones responded poorly or not at all to soluble anti-Ly-6A mAb. Although the selective pressure was exerted through Ly-6A, only one mutant did not express the Ly-6A antigen. Interestingly, 10 of the 15 subclones expressed either nondetectable or a very low level of T cell receptor/CD3 complex (TCR/CD3). Preferential expansion of TCR/CD3 expression mutants following anti-Ly-6A selection further established functional linkage between Ly-6A and TCR/CD3 complex. The mechanism of the functional coupling was investigated by analyzing the hydrolysis of phosphatidylinositol 4,5-bisphosphate (PIP2), one of the early events in T cell activation. We showed that PIP2 was not hydrolyzed in response to anti-Ly-6A in TCR/CD3-negative mutants. Aluminum fluoride, which activates G protein directly, did induce PIP2 hydrolysis in these cells. These data suggest that activation signals originated from Ly-6A must be transmitted first to TCR/CD3 complex, which then couples to the G protein/phospholipase C system. A similar requirement also applies to the Thy-1 protein and lectin receptors. Thus, the TCR/CD3 complex plays a central role in the integration and transmission of activation signals that originated from several T cell surface molecules.     

Down-regulation of IL-2 production by activation of T cells through Ly-6A/E

Ly-6A/E molecules are expressed on the surface of T cells and have been shown to function in activation by the capacity of anti-Ly-6A/E mAb to induce T cell hybridomas or normal T cells to produce IL-2. Recent evidence suggests that activation through Ly-6A/E may be linked to the TCR signaling pathway. To further investigate the relationship between Ly-6- and TCR-induced T cell activation, we have examined whether an anti-Ly-6A/E mAb (D7) modulates TCR signaling in vitro. We now report that mAb D7 specifically inhibited IL-2 production by T cells also activated through TCR. Such inhibition was noted for normal T cells stimulated by soluble anti-CD3 or alloantigen and for T hybridomas stimulated by soluble anti-CD3. The ability of D7 to inhibit IL-2 production by T hybridomas was dependent on the nature of the TCR activating signal because IL-2 production was not inhibited when T hybridomas were stimulated with Ag or immobilized anti-CD3. Inhibition of IL-2 production by D7 apparently required cross-linking of the mAb because D7 F(ab')2 fragments were not effective for inhibition of IL-2 production. Similar to its ability to enhance anti-Ly-6A/E-induced activation of T and B cells, IFN-gamma enhanced the D7-induced inhibition of IL-2 production by alloantigen-activated normal T cells. These data further support the notion that Ly-6 and TCR signaling pathways are interrelated.     

Regulation of B lymphocyte responses to IL-4 and IFN-gamma by activation through Ly-6A/E molecules

The Ly-6 family of cell surface molecules has previously been shown to participate in T cell activation. We show that Ly-6A/E proteins also modulated the response of normal B lymphocytes in three separate in vitro assays. First, unfractionated or small resting B cells proliferated when cultured with IFN-gamma, IL-4, and an anti-Ly-6A/E mAb. Second, this anti-Ly-6A/E mAb restored B cell proliferation responses that were inhibited when coculturing the B cells in IFN-gamma, IL-4, and anti-IgM. Third, anti-Ly-6A/E specifically up-regulated the cell surface expression of its own Ag, and this response was dependent upon co-stimulation with IFN-gamma. Mixing of T and B cells in culture suggested that T cells did not contribute substantially to the B cell proliferative response. Moreover, up-regulation of Ly-6A/E was observed for one B cell lymphoma, WEHI-231. Therefore, it appeared that modulation of B cell function by anti-Ly-6A/E was due to a direct effect of the mAb binding to the B cells. Taken together, these data suggest Ly-6A/E proteins are functional on B cells and may play a regulatory role in B cell activation.     

Stimulation of human Jurkat cells by monoclonal antibody crosslinking of transfected-Ly-6A.2 (TAP) molecules.

Monoclonal antibody crosslinking of phosphatidylinositol-anchored Ly-6A.2 molecules on the surface of murine T lymphocytes leads to cell activation and secretion of IL-2. To examine the potential activity of these molecules in human T cells we transfected the Ly-6A.2 gene into Jurkat cells. Transfection of Jurkat cells with genomic Ly-6A.2 sequences results in low levels of Ly-6A.2 on the cell surface. However, linking the Ly-6A.2 sequences to the enhancer from the human CD2 gene results in greatly increased expression of Ly-6A.2. These molecules are anchored to the membrane via a phosphatidylinositol linkage. Crosslinking of Ly-6A.2 molecules with soluble mAb stimulates the transfected Jurkat cells to produce IL-2. This stimulation is abrogated by treatment with phosphatidylinositol-specific phospholipase C. The transfected human T cells displayed the same unusual crosslinking requirements for stimulation with anti-Ly-6A.2 mAbs as previously observed for murine T cells. Crosslinking of Ly-6A.2 with soluble antibodies is stimulatory, whereas immobilized antibodies are inactive. The crosslinking requirements for antiCD3 mAb stimulation display a reciprocal pattern. These data demonstrate that the Ly-6A.2 pathway for T cell activation is conserved between human and murine T cells.     

Role of Ly-6A/E and T cell receptor-zeta for IL-2 production. Phosphatidylinositol-anchored Ly-6A/E antagonizes T cell receptor-mediated IL-2 production by a zeta-independent pathway.

Ly-6A/E molecules were originally implicated in regulation of T cell activation because anti-Ly-6A/E mAb induce IL-2 production. More recently we have shown that anti-Ly-6A/E also inhibits IL-2 production induced by anti-CD3. In the present study we used mutant and transfected cell lines that varied in expression of Ly-6A/E or TCR-zeta to test whether the positive and negative modulations of IL-2 production by anti-Ly-6A/E occur by distinct mechanisms. Anti-Ly-6A/E inhibited anti-CD3-induced IL-2 production for Ly-6E.1-transfected EL4J cells, but did not affect IL-2 production of the parental Ly-6A/E-negative EL4J cells. These results indicate that TCR-mediated IL-2 production can occur in the absence of Ly-6A/E expression and establish that anti-Ly-6A/E-induced inhibition of IL-2 production was the result of antibody binding to Ly-6A/E. As expected, MA5.8 (zeta-negative) or CT108 (zeta-truncated) variants of the 2B4.11 T cell hybridoma did not produce IL-2 when stimulated with anti-Thy-1 or anti-Ly-6A/E mAb. In contrast, anti-Ly-6A/E inhibited anti-CD3-induced IL-2 production by MA5.8 and CT108. Furthermore, anti-Ly-6A/E-induced IL-2 production was restored for zeta-transfected MA5.8. Thus, although induction of IL-2 by anti-Ly-6A/E depends on zeta expression, inhibition of IL-2 by anti-Ly-6A/E occurs by a zeta-independent mechanism. Interestingly, anti-Ly-6A/E, but not anti-Thy-1, inhibited anti-CD3-induced IL-2 production by MA5.8 and Ly-6E.1-transfected EL4J. Therefore, inhibition of IL-2 production by anti-Ly-6A/E was not a general property of a mAb binding to a phosphatidylinositol-linked molecule, as has been suggested for induction of IL-2 production. Taken together these data suggest that the molecular mechanisms of induction and inhibition of IL-2 production by anti-Ly-6A/E are separable and expression of TCR-zeta is one variable that distinguishes these two pathways.     

Activation of murine T lymphocytes with monoclonal antibodies: detection on Lyt-2+ cells of an antigen not associated with the T cell receptor complex but involved in T cell activation

A new T cell molecule defined by the mAb 143-4-2 has been identified that is involved in T cell activation. The expression of the 143-4-2-defined epitope is linked to the previously characterized Ly-6 locus and restricted to bone marrow cells and to a subset of peripheral Lyt-2+ cells. In comparison to other anti-Ly-6.2 mAb, the 143-4-2 mAb appears to be directed at an allogeneic determinant of the Ly-6.2C molecule. The anti-Ly-6.2C antibody can promote the lysis of antigen-non-bearing target cells by alloreactive CTL clones, and in the presence of cofactors (PMA or IL 2) induces a subset of Lyt-2+ cells to proliferate, perhaps through an autocrine pathway. Although the antibody described has antigen-like effects as described for anti-TcR complex reagents, studies performed with a recently derived anti-murine T3 mAb suggest that the Ly-6.2C molecule is not associated on the cell surface with components of the TcR complex. Nevertheless, cell surface expression of the TcR complex is required for optimal triggering of T cells via the Ly-6.2C molecule. Because Ly-6.2C determinants are expressed in bone marrow and not in the thymus, the possibility is considered that expression of this molecule identifies a distinct subset of extrathymically derived T cells.     

sgp-60, a signal-transducing glycoprotein concerned with T cell activation through the T cell receptor/CD3 complex

T cell activation depends not only on the expression of a TCR, but also on that of accessory molecules that function in cell-cell adhesion and/or signal transduction. The subject of this report is the biochemical and functional characterization of what appears to be a novel murine lymphocyte cell surface antigen, provisionally termed sgp-60. Extensive, higher-order cross-linking of this glycoprotein with an anti-sgp-60 mAb and a second-step antibody reagent results in the activation of resting CD4+ T cells in the presence of a second signal. Monovalent or bivalent engagement of sgp-60 by the anti-sgp-60 antibody results in profound and direct inhibition of anti-CD3- or Con A-driven T cell activation, whereas alternative T cell activation via the phosphatidylinositol-linked proteins Thy-1 and TAP/Ly-6A is not affected. These findings raise the possibility that the sgp-60 molecule may be specifically involved in signal transduction through the TCR/CD3 complex and thus point to an important physiologic role for this protein in CD4+ T cells.     

Characterization of an anti-Ly-6 monoclonal antibody which defines and activates cytolytic T lymphocytes

HK1.4 mAb was identified based on its ability to stimulate proliferation of cloned murine CTL. Within the lymphoid lineage, mAb HK1.4 bound exclusively to CTL, regardless of the expression of Lyt-2 or MHC restriction. HK1.4 mAb also bound to 40% of bone marrow cells and less than 5% of thymocytes from all mouse strains tested. Based on the tissue distribution of the determinant with which it reacted and the ability to cross-block binding of the anti-Ly-6 mAb H9/25, mAb HK1.4 appeared to react with a product of the Ly-6 locus. However, significant differences were observed between the properties of mAb HK1.4 and other, previously described anti-Ly-6 mAb. Cell proliferation and lymphokine release by cloned CTL were stimulated by culture with mAb HK1.4 alone or in the presence of non-stimulatory levels of IL-2. This proliferation and lymphokine release were not blocked by the addition of soluble anti-Lyt-2 or anti-IL-2R mAb. Activation induced by HK1.4 mAb proceeds in the absence of accessory cells, of cross-linking of the TCR, or the addition of mitogens or PMA. Stimulation of cells by anti-TCR mAb was not blocked by the addition of soluble HK1.4 mAb, and the stimulatory effects of HK1.4 and anti-TCR mAb were not additive. However, IL-2-driven proliferation of CTL clones was dramatically inhibited by the addition of HK1.4 mAb.HK1.4 mAb had no effect on Ag-specific or lectin-facilitated cytolysis. Taken together, these data indicate that mAb HK1.4 operates via an IL-2-independent pathway of activation that is also independent of the TCR.     

Absence of cross-reactivity between murine Ly-6C and Ly-6G.

BACKGROUND: The Ly-6 family has many members, including Ly-6C and Ly-6G. A previous study suggested that the anti-Ly-6G antibody, RB6-8C5, may react with Ly-6Chi murine bone marrow (BM) cells. This finding has been interpreted as cross-reactivity of RB6-8C5 with the Ly-6C antigen, and has been generalized to many hematopoietic cell types, using the terminology Ly-6G/C. The present study was undertaken to determine whether anti-Ly-6G antibodies truly cross-react with the Ly-6C antigen on multiple hematopoietic cell types. METHODS: Splenocytes, thymocytes, and BM cells obtained from Ly-6.1 and Ly-6.2 strains of mice were stained with a variety of antibodies to Ly-6C and Ly-6G. Flow cytometric analysis was performed on these populations. RESULTS: Evaluation of anti-Ly-6C and anti-Ly-6G staining showed only Ly-6C expression and no Ly-6G expression on subsets of splenic T and B cells and thymocytes from Ly-6.1 and Ly-6.2 mice. Bone marrow cells were identified that express both Ly-6G and Ly-6C; no Ly-6G+Ly-6C- populations were seen. CONCLUSIONS: Multiple Ly-6C+ hematopoietic cell populations were identified that do not stain with anti-Ly-6G antibodies. This calls into question the use of the Ly-6G/C nomenclature and suggests that epitopes recognized by anti-Ly-6G antibodies should simply be designated Ly-6G.     

A monoclonal antibody against the 66-kDa protein expressed in mouse spleen and thymus inhibits Ly-6A.2-dependent cell-cell adhesion

The Ly-6 locus encodes several cell surface proteins of 10-12 kDa. Some members of this multigene family may function in cell signaling and/or cell adhesion processes. T lymphocytes overexpressing Ly-6A.2 (one member of the Ly-6 gene family) protein homotypically aggregate when cultured in vitro. Further analysis of this homotypic aggregation suggests that Ly-6A.2 participates in cell-cell adhesion. These observations indicated the presence of a Ly-6 ligand(s) on the surface of lymphoid cells. In this study we report generation of a hamster mAb, 9AB2, that blocks Ly-6A.2-dependent cell-cell adhesion. The 9AB2 Ab recognizes a 66-kDa glycoprotein with unique tissue expression. The 9AB2 mAb does not bind Ly-6A.2, but coimmunoprecipitates Ly-6A.2 molecule. Moreover, 9AB2 Ag-expressing thymocytes specifically bind to Chinese hamster ovary cells overexpressing Ly-6A.2 protein, and this binding is specifically blocked by 9AB2 and anti-Ly-6A.2 Abs. These results suggest that the 66-kDa protein recognized by 9AB2 mAb is the putative ligand for Ly-6A.2.     

Ly-6A.2 expression regulates antigen-specific CD4+ T cell proliferation and cytokine production.

Ly-6 proteins appear to serve cell adhesion and cell signaling function, but the precise role of Ly-6A.2 in CD4+ T lymphocytes is still unclear. Overexpression of Ly-6A.2 in T lymphocytes has allowed us to analyze the influence of elevated Ly-6A.2 expression on T cell function. In this study we report reduced proliferation of CD4+ T cells overexpressing Ly-6A.2 in response to a peptide Ag. Moreover, the Ly-6A.2-overexpressing CD4+ cells generated elevated levels of IL-4, a key factor that propels the differentiation of naive CD4+ T cells into Th2 subset. The hyporesponsiveness of Ly-6A.2 transgenic CD4+ T cells is dependent on the interaction of Ly-6A.2 T cells with the APCs and can be reversed by blocking the interaction between Ly-6A.2 and a recently reported candidate ligand. Overexpression of Ly-6A.2 in CD4+ T cells reduced their Ca(2+) responses to TCR stimulation, therefore suggesting effects of Ly-6A.2 signaling on membrane proximal activation events. In contrast to the observed Ag-specific hyporesponsiveness, the Ly-6A.2 transgenic CD4+ T cells produced IL-4 independent of the interactions between Ly-6A.2 and the candidate Ly-6A.2 ligand. Our results suggest that 1) interaction of Ly-6A.2 with a candidate ligand regulates clonal expansion of CD4+ Th cells in response to an Ag (these results also provide further functional evidence for presence of Ly-6A.2 ligand on APC); and 2) Ly-6A.2 expression on CD4+ T cells promotes production of IL-4, a Th2 differentiation factor.     

Characterization of T cell proliferative responses induced by anti-Qa-2 monoclonal antibodies.

The MHC class I Qa-2 Ag are attached to the cell surface by a glycanphosphatidylinositol (GPI) anchor. Crosslinking of Qa-2 and several other cell surface Ag attached by the GPI linkage has been shown to lead to cell activation. We have developed 10 new anti-Qa-2 mAb and characterized their capacity to induce proliferation of spleen cells. In the absence of anti-Ig-mediated crosslinking, none of the mAbs alone could induce activation. However, mAb 23.1 which reacts with the alpha 3 domain of Qa-2, when combined with most of the other mAbs (alpha 1, alpha 2 domain reactive), activated cells in the absence of anti-Ig crosslinking. The mAb pair 23.1 plus 24.16 was the most proficient and induced proliferation in the absence of any exogenous second signals. Responses were greatly enhanced and equivalent to those seen with anti-CD3 by the addition of phorbol myristate acetate (PMA). Ionomycin, rIL-2, or rIL-4 also potentiated anti-Qa-2 responses but less efficiently than PMA. Significant strain variation in the magnitude Qa-2-mediated proliferative responses was observed correlating with the levels of Qa-2 expressed on the cell surface. Crosslinking of Qa-2 molecules by the mAb combinations was required because monovalent Fab fragments failed to activate cells. F(ab')2 fragments of mAb 23.1 plus 24.16 induced vigorous proliferation indicating that accessory cell presentation of the mAb via Fc receptors was not required. Immobilized (plate bound) anti-Qa-2 mAb induced proliferation suggesting that the Qa-2 pathway may be distinct from that of other GPI molecules such as Thy-1 and Ly-6. Populations enriched for T cells (approximately 95%) responded as well as whole spleen cells, whereas B lymphocytes failed to proliferate to anti-Qa-2. Both CD4+ and CD8+ cells were activated following crosslinking of Qa-2. Finally, T cell activation mediated by Qa-2 induced elevation of [Ca2+]i, IL-2R expression, and the release of IL-2. These data demonstrate that crosslinking of Qa-2 on T lymphocytes represents a potent pathway for inducing cell activation.     

Accelerated programmed cell death of MRL-lpr/lpr T lymphocytes.

MRL-lpr/lpr (lpr) mice develop a polyclonal accumulation of abnormal peripheral T lymphocytes, which bear surface alpha beta TCR, CD3, and the B220 isoform of CD45, but lack CD4, CD8, and CD2. These T cells have a constitutively phosphorylated CD3 zeta chain and manifest a defect in signal transduction that results in a lack of IL-2 production and proliferation. We investigated whether this signaling abnormality might contribute to their accumulation via a defect in T cell elimination in the periphery. T cell deletion occurs through a process of programmed cell death with DNA degradation, or apoptosis. Viable lymphocytes from lpr mice were found to undergo rapid programmed cell death in culture within 4 h without additional activation, which was not observed in lymphocytes from normal MRL-+/+ or C57BL/6-+/+ mice. Both nonmature B220+ and mature B220- T lymphocytes from lpr mice display this accelerated programmed cell death, indicating that this is a defect affecting all peripheral T lymphocytes in lpr mice. In vitro apoptosis of lpr T cells could be inhibited with PMA, a stimulator of protein kinase C. Thus, the massive accumulation of T lymphocytes in the lymphoid tissue of lpr mice is not due to a defect in their ability to undergo programmed cell death in vitro. The activation state of lpr T cells may contribute to their rapid degradation of DNA in vitro.     

Role of Ly-6 in lymphocyte activation. I. Characterization of a monoclonal antibody to a nonpolymorphic Ly-6 specificity

In studies with alloantisera and monoclonal antibodies (mAb) a number of antigenic determinants have been defined that are the products of the Ly-6 locus on murine chromosome 2 and that are expressed primarily on B and T lymphoid cells. It remains controversial whether these antigenic determinants are encoded by a single gene or a multigene complex. We have characterized a new rat mAb, D7, which recognizes a cell surface antigen whose expression on nonactivated peripheral lymphocytes varies from strain to strain. The phenotype of the staining profile, i.e., high or low percentage of D7-positive cells, mapped to the Ly-6 locus as assayed by strain distribution studies, RI lines, and Ly-6 congenic strains. The binding of D7 to Ly-6.1-positive strains could be inhibited by mAb directed to the Ly-6E.1 specificity, whereas D7 could inhibit the binding of mAb specific for Ly-6A.2 to cells from Ly-6.2-positive strains. Coprecipitation studies followed by Western blot analysis confirmed that D7 reacts with both Ly-6E.1- and Ly-6A.2-bearing molecules. The most likely explanation for these findings is that Ly-6A.2 and Ly-6E.1 represent allelic specificities. Further dissection of the complexity of the Ly-6 antigen system and determination of its possible functional importance in lymphocyte activation should be greatly facilitated by the availability of xenogeneic mAb that recognize framework determinants on multiple Ly-6 products.     

CD59 functions as a signal-transducing molecule for human T cell activation.

The CD59 Ag is a 20-kDa protein that is widely expressed on most leukocytes and RBC, is coupled to the membrane by a phosphatidylinositol-glycan anchoring structure, plays a role in cell interaction between monocytes and T cells, and also functions as an inhibitor of cytolysis by the terminal C components C5b-9. Because this molecule is structurally related to the murine Ly-6 family of Ag, we have investigated whether anti-CD59 mAb might be capable of activating human T lymphocytes in a manner similar to that described for antibodies to the murine Ly-6 Ag. In the presence of the appropriate co-stimulators, mAb to one of the two epitopes on CD59 were capable of inducing both a rise in intracytoplasmic free Ca2+, inositol phosphate production, IL-2 production, and T cell proliferation. Anti-CD59-induced inositol phosphate turnover and IL-2 production were dependent on co-expression of the CD3/TCR complex. CD59-loss mutants of the Jurkat cell line were completely responsive to stimulation by anti-CD3 thereby demonstrating that CD59 does not play a role as a signal transducer downstream from the TCR. Taken together, these results demonstrate that the CD59 Ag can play multiple distinct roles in the regulation of the immune response.     

The augmentation of surface Ly-6A/E molecules in activated T cells is mediated by endogenous interferon-gamma

The murine Ly-6A.2 and Ly-6E.1 antigens, which can transduce triggering signals in T cells, have been shown to become highly expressed after mitogenic stimulation. It has recently been found that enhanced expression of Ly-6A/E antigens is also induced by interferon-gamma (IFN-gamma) in resting T cells. Here, the possibility is investigated that Ly-6A/E induction on activated T cells may be due to the IFN-gamma known to be secreted by these cells. A potent neutralizing anti-IFN-gamma monoclonal antibody (mAb) (H-22.10) was used. This mAb was found to abrogate the augmentation of Ly-6A/E antigens produced in resting T cells by supernatants from T cells stimulated with concanavalin A. When added directly into cultures of T cells stimulated with concanavalin A or by the combination of ionomycin with the protein kinase C activator phorbol myristate acetate (PMA), the H-22.10 mAb inhibited Ly-6A/E enhancement without affecting the blastogenesis or the emergence of interleukin 2 receptors and transferrin receptors. Such a selective effect of the anti-IFN-gamma mAb indicated that IFN-gamma is involved in the up-regulation of Ly-6A/E antigens during T cell activation. In determining whether other activation signals, in addition to IFN-gamma receptor occupancy, may contribute to Ly-6A/E enhancement, it was found that suboptimal stimulation of BALB/c T cells provided by a 3-hr pulse with ionomycin plus PMA or by culture with PMA alone potentiated by about twofold the increase of Ly-6E.1 induced by exogenous IFN-gamma. Therefore, Ly-6A/E augmentation in activated T cells reflects primarily an action of endogenous IFN-gamma that is amplified (in BALB/c mice) by a protein kinase C-dependent step.     

Coordinate regulation of T cell activation by CD2 and CD28

T cell activation requires co-engagement of the TCR with accessory and costimulatory molecules. However, the exact mechanism of costimulatory function is unknown. Mice lacking CD2 or CD28 show only mild deficits, demonstrating that neither protein is essential for T cell activation. In this paper we have generated mice lacking both CD2 and CD28. T cells from the double-deficient mice have a profound defect in activation by soluble anti-CD3 Ab and Ag, yet remain responsive to immobilized anti-CD3. This suggests that CD2 and CD28 may function together to facilitate interactions of the T cell and APC, allowing for efficient signal transduction through the TCR.     

Phenotypic and functional analysis of the cellular response in regional lymphoid tissue during an acute virus infection

A phenotypic and functional analysis has been made of the cellular response in regional lymphoid tissue of C57BL/6J mice infected with lymphocytic choriomeningitis virus. Massive recruitment of nondividing cells occurred from 3 days after infection, with total numbers of CD8+ T lymphocytes, B220+ B cells, and Thy-1- B220- null cells being high from day 4 to day 6. In contrast, the peak counts for CD4+ T cells were recorded on day 4 and declined dramatically thereafter. Enhanced expression of IL-2R and Ly-24, both of which can be regarded as T cell activation markers, was found for both the CD4+ and the CD8+ subsets, being most prominent for the CD8+ T cells on day 6. Evidence of T cell proliferation was not recognized until days 5 and 6, coincident with enhanced responsiveness of the lymphocytes to rIL-2 and the development of virus-specific cytotoxic activity. Elimination of the CD4+ T cells by treatment of mice with mAb did not modify either the pathogenesis of lymphocytic choriomeningitis, or the expression of activation markers on the CD8+ T cells which are known to be the key effectors in this disease. Thus, the pattern of responsiveness for the CD8+ population is of recruitment to the lymph node, progressive increase in the expression of activation markers and enhanced sensitivity to rIL-2, with late proliferation and generation of cytotoxic activity. This model provides a system for the rigorous in vivo analysis of parameters influencing lymphocyte differentiation and activation in a virus infection.     

Expression of an unusual T cell receptor (TCR)-V beta repertoire by Ly-6C+ subpopulations of CD4+ and/or CD8+ thymocytes. Evidence for a developmental relationship between Ly-6C+ thymocytes and CD4-CD8-TCR-alpha beta+ thymocytes.

A novel thymocyte subpopulation expressing an unusual TCR repertoire was identified by high surface expression of the Ly-6C Ag. Ly-6C+ thymocytes were distributed among all four CD4/CD8 thymocyte subsets, and represented a readily identifiable subpopulation within each one. Ly-6C+ thymocytes express TCR-alpha beta, arise late in ontogeny, and appear in the CD4/CD8 developmental pathway after birth in a sequence that resembles that followed by conventional Ly-6C- cells during fetal ontogeny. Most interestingly, adult Ly-6C+ thymocytes express an unusual TCR-V beta repertoire that is identical to that expressed by CD4-CD8-TCR-alpha beta+ thymocytes in its overexpression of TCR-V beta 8 and in its expression of some potentially autoreactive TCR-V beta specificities. This unusual TCR-V beta repertoire was even expressed by Ly-6C+ thymocytes contained within the CD4+ CD8- 'single positive' thymocyte subset. Thus, expression of this unusual TCR-V beta repertoire is not limited to CD4-CD8-thymocytes, and is unlikely to be a consequence of their double negative phenotype. Rather, we think that Ly-6C+TCR-alpha beta+ thymocytes and CD4-CD8-TCR-alpha beta+ are developmentally interrelated, a conclusion supported by several lines of evidence including the selective failure of both Ly-6C+ and CD4-CD8-TCR-alpha beta+ thymocyte subsets to appear in TCR-beta transgenic mice. In contrast, peripheral Ly-6C+ T cells are developmentally distinct from Ly-6C+ thymocytes in that peripheral Ly-6C+ T cells expressed a conventional TCR-V beta repertoire and developed normally in TCR-beta transgenic mice in which Ly-6C+ thymocytes failed to arise. We conclude that: 1) expression of a skewed TCR-V beta repertoire is a characteristic of Ly-6C+TCR-alpha beta+ thymocytes as well as CD4-CD8-TCR-alpha beta+ thymocytes, and is not unique to thymocytes expressing neither CD4 nor CD8 accessory molecules; and 2) Ly-6C+ thymocytes are developmentally linked to CD4-CD8-TCR-alpha beta+ thymocytes, but not to Ly-6C+ peripheral T cells. We suggest that Ly-6C+TCR-alpha beta+ thymocytes are not the developmental precursors of Ly-6C+ peripheral T cells, but rather may be the developmental precursors of CD4-CD8-TCR-alpha beta+ thymocytes.