The gene encoding the mouse T cell differentiation antigen L3T4 is located on chromosome 6

We have used Southern blot analysis of DNA from somatic cell hybrids to map the chromosomal location of the mouse L3T4 T cell differentiation antigen gene to chromosome 6. This finding is of interest because both L3T4 and the alternative T cell differentiation antigen Lyt-2 are homologous to kappa-immunoglobulin light chain-variable regions, and the genes encoding kappa and Lyt-2 are also located on mouse chromosome 6.     

Role of the L3T4 antigen in T-cell activation. I. Description of a monoclonal IgM antibody to a distinct epitope (L3T4b) of the L3T4 antigen and its effect on interleukin 1-induced thymocyte proliferation

This report describes a new rat monoclonal IgM/k antibody, monoclonal antibody (MAb) 2B6, which reacts with a cell surface antigen present on a subpopulation of both thymocytes (85%) and peripheral T lymphocytes (55-60%). The antigen recognized by MAb 2B6 has multiple properties in common with the L3T4 antigen, as defined by the recently described MAb GK1.5. Thus, MAb 2B6 and MAb GK1.5 give very similar flow cytometry staining patterns on thymocytes, purified spleen T cells and all tested T-cell hybridomas. Depletion of MAb 2B6-positive cells with antibody and complement led to simultaneous depletion of MAb GK1.5-positive cells, and vice versa. Depletion of Lyt 2-positive cells led to enrichment of both MAb 2B6- and MAb GK1.5-positive cells. Both MAb 2B6 and MAb GK1.5 immunoprecipitate the same pattern of cell surface molecules from detergent extracts of radiolabeled thymocytes, the main components being a 55-kDa and a 115-kDa band. We therefore conclude that MAb 2B6 reacts with the L3T4 antigen. Interestingly, MAb 2B6 and MAb GK1.5 do not cross-block and therefore most probably react with distinct epitopes on the L3T4 molecule. The determinant recognized by MAb GK1.5 is called L3T4a. We suggest that the determinant recognized by MAb 2B6 be named L3T4b. As MAb 2B6 was selected for its ability to inhibit the action of interleukin 1 (IL-1) in the thymocyte costimulator assay, it is likely that the L3T4 molecule is functionally involved in the events taking place during IL-1 induction of thymocyte proliferation.     

Antibodies to the L3T4 and Lyt-2 molecules interfere with antigen receptor-driven activation of cloned murine T cells

When L3T4+ cloned murine helper T lymphocytes (HTL) are stimulated with antigen or immobilized anti-T cell receptor (TCR) monoclonal antibodies (mAb) at concentrations which are optimal for proliferation, anti-L3T4 mAb inhibits activation as measured by proliferation and lymphokine production. Under similar conditions, IL 2-independent proliferation of Lyt-2+ cloned murine cytolytic T lymphocytes (CTL) stimulated by anti-TCR mAb is inhibited by anti-Lyt-2 antibodies. Proliferation of cloned HTL and CTL cells stimulated by IL 2 is not affected by the anti-L3T4 and anti-Lyt-2 mAb. The inhibition of TCR-induced activation of the T cell clones is not due to interference with the binding of the anti-TCR mAb. Stimulation of the TCR has been proposed to induce lymphokine secretion and proliferation by T cells through a pathway involving the activation of protein kinase C and the stimulation of an increase in the concentration of intracellular free calcium. However, proliferation of T cells stimulated by PMA (which activates protein kinase C) plus the calcium ionophore A23187 (which increases the concentration of intracellular free calcium) is not affected by mAb reactive with the Lyt-2 or L3T4 structures. If TCR stimulation does indeed activate T cells by activating protein kinase and increasing intracellular free calcium, then our data suggest that anti-L3T4 and anti-Lyt-2 mAb inhibit TCR-driven proliferation at some step before the activation of protein kinase C and the stimulation of a rise in intracellular free calcium concentration. Our results suggest that anti-L3T4 and anti-Lyt-2 mAb interfere with early biochemical processes induced by stimulation of the TCR. In HTL, which proliferate via an autocrine pathway, anti-L3T4 mAb appears to inhibit proliferation by interfering with signaling events involved in lymphokine production. Inhibition of IL 2-independent proliferation of Lyt-2+ cells by anti-Lyt-2 mAb appears to occur by a different mechanism. The precise molecular basis for the interference of each cell type has not yet been characterized.     

L3T4 but not LFA-1 participates in antigen presentation by Ak-positive L-Cell transformants

Genomic DNA was isolated from 29 t strains and 4 congenic lines of mice, digested with restriction endonucleases, and hybridized with a probe representing the complement component 4 (C4) gene. All but one of the enzymes revealed restriction fragment length polymorphism in this sample of C4-related genes. Double digestion analysis suggested the presence of three C4 gene copies in some of the t chromosomes and two copies in others. The enzymes distinguished 16 different haplotypes among the 33 strains tested. Based on their restriction fragment length patterns, the t strains could be divided into four groups with strains in each group more closely related to each other with respect to their C4-region genes than strains belonging to different groups. At least three of these four groups represent different branches of the evolutionary tree constructed for the t chromosomes. The C4-related genes of the chromosomes are in strong linkage disequilibrium with the class II genes of the H-2 complex. Typing for the Ss and Slp allotypes of C4 has revealed the presence of the Ss¹ phenotype in two t strains and of the Slp^a phenotype in one strain.     

Cell growth and tRNA-lys4 synthesis in mouse 3T3 cells

The RPC-5 chromatographic profiles of lys-tRNA were analyzed during the growth of 3T3 cells in culture. An inverse relationship was seen between tRNA₂^lys and tRNA₄^lys which was markedly influenced by medium changes. This interchange of tRNA₂^lys and tRNA₄^lys could be controlled by altering the levels of serum in the medium, or more precisely by altering the serum to cell ratio. A different change in lys-tRNA distribution was seen when the cells reached confluency. The amounts of tRNA₂^lys, tRNA₃^lys and tRNA₄^lys all decreased with a corresponding increase in either tRNA₅^lys or tRNA₆^lys. An identical change in lys-tRNA could be produced by shifting sparse cells into a medium containing 10% calf plasma instead of 10% serum. Both tRNA^lys profiles and cell growth were returned to normal when the cells were returned to medium with 10% fetal calf serum (FCS) or 10% calf plasma and fibroblast growth factor (FGF). A third alteration in tRNA^lys profiles was seen by the addition of cAMP to the cultures. A decrease in tRNA₅^lys and a corresponding increase in tRNA₆^lys was seen upon the addition of 10^?3 M db-cAMP and was accentuated by the simultaneous addition of 10^?3 M methyl isobutylxanthine.These data are consistent with an ordered sequence of tRNA^lys modification involving tRNA₂^lys, tRNA₃^lys, tRNA₄^lys, tRNA_5B^lys and tRNA₆^lys. Several of the factors which control proliferation appear to control the activity of different tRNA-modifying enzymes in this tRNA^lys pathway thereby controlling the levels of tRNA₄^lys, a tRNA previously shown to correlate directly with the proliferative rate of cells.     

Lys-tRNA4 levels and cell division in mouse 3T3 cells

tRNA₄^lys is an isoaccepting tRNA^lys which has been proposed as a necessary requirement for cell division in mammalian cells. We have measured the levels of this tRNA^lys during the growth cycle of mouse 3T3 fibroblasts. High levels of tRNA₄^lys were seen throughout exponential growth. However, a marked decrease in tRNA₄^lys occurred 24 h before the cells became confluent. This decrease was observed in three different 3T3 cell lines, but was not seen in a transformed 3T3 cell line. Trypsinization and replating of contact-inhibited cells returned tRNA₄^lys to the levels characteristic of exponential cells. Data from these and other cell lines show a direct relationship between the levels of tRNA₄^lys and the growth rate of cells in culture.     

Role of the L3T4+ T cell in allograft rejection

Pancreatic islet and fetal pancreas allotransplantation has been used to examine the role of the L3T4+ T cell in allograft rejection. Tissues were grafted into recipient animals depleted of peripheral L3T4+ T cells by in vivo administration of GK1.5 (anti-L3T4) monoclonal antibody to ask the question: is there a requirement for the L3T4+ T cell in graft rejection? Data show that the requirement for the L3T4+ T cell depends on either the type of tissue transplanted or type of the antigenic disparity between donor and recipient. Data also indicate that islet allograft acceptance achieved after GK1.5 treatment of the recipient is not due to tolerance induction. We therefore conclude that the cellular requirements for allograft rejection are determined by the type of tissue transplanted and the genetic disparity between donor and recipient.     

Distinct roles for L3T4 in T cell activation

The mutually exclusive expression of L3T4 and Lyt-2 on murine T cells and the correlation of their expression to the major histocompatibility complex (MHC) restriction of the T cell antigen receptor (Ti) have led to the hypothesis that these surface molecules are related to recognition of class II and class I MHC antigens, respectively. It has been suggested that these T cell surface molecules interact with nonpolymorphic determinants on MHC antigens. We have studied the role of L3T4 in activation of an H-2Dd-specific T cell hybridoma. This novel hybridoma allowed the separate evaluation of the specificities of Ti and L3T4 and the examination of their roles in T cell activation. Antibody-blocking experiments have demonstrated that L3T4 was involved in triggering this T cell hybridoma only if the antigen-bearing cell expressed Ia. The apparent requirement for an L3T4-Ia interaction reflected the amount of available H-2Dd antigen. It appears that the L3T4-Ia interaction influences T cell activation during suboptimal antigenic stimulation. We have begun to examine the role of L3T4 in lectin and anti-Ti monoclonal antibody stimulation of the same T cell hybridoma. These experiments have suggested a distinct role for L3T4 in the absence of Ia, as a mediator of a negative signal for activation.     

Human T lymphocytes and monocytes bear the same Leu-3(T4) antigen

An analysis of the cellular distribution, biosynthesis, and structure of the human T lymphocyte antigen Leu-3(T4) was performed. By using a sensitive ELISA as well as FACS analysis, relative quantities of the Leu-3(T4) antigen from whole cell lysates and from cell surfaces of six cell lines were determined. The T-T hybrid cell line 255.88, and the monocyte/macrophage cell line U937, proved to be high producers of the antigen and were chosen for additional investigation. The Leu-3(T4) antigens from the T lymphocyte cell line and the monocyte/macrophage cell were shown to be identical by SDS-PAGE. Leu-3(T4) was a polypeptide of 55,000 AMW under reducing conditions, and 63,000 AMW under nonreducing conditions. In the 255.88 cell line, a second band of 41,000 AMW was associated with the true Leu-3(T4) molecule. The 55,000 AMW Leu-3(T4) molecule was shown to possess a high mannose sugar side chain, and to contain few accessible tyrosine residues. These studies demonstrate that human T lymphocytes and monocytes produce and process similar molecules that react with the anti-Leu-3(T4) monoclonal antibody. They also characterize this important associative antigen recognition structure and suggest that cells other than the T lymphocyte may be targets for the retrovirus HTLV-III.     

The role of the L3T4 molecule in mitogen and antigen-activated signal transduction

We investigated the role of the L3T4 molecule in mitogen and antigen-initiated signal transduction in the L3T4(+) murine T cell hybridoma, 3DT52.5.9 and an L3T4(-) variant, 3DT52.5.24. Both Concanavalin A (Con A) and specific antigen stimulated increases in cytosolic-free calcium ([Ca2+]i), phosphatidylinositol turnover, and interleukin-2 (IL-2) production in both cell lines. About 85% of the stimulated rise in [Ca2+]i was from an extracellular source. Anti-L3T4 monoclonal antibody (MAb) inhibited 90% of antigen- and 50% of Con A-stimulated increases in [Ca2+]i and IL-2 production but had no effect on the ability of either activation signal to stimulate phosphatidylinositol turnover in the parent L3T4(+) cells. Stimulus-response coupling in the L3T4(-) cells was unaffected by the MAb. The anti-L3T4-insensitive increase in [Ca2+]i induced by Con A was inhibited by EGTA, suggesting that this mitogen also stimulated an influx of Ca2+ via an additional transport mechanism distinct from that stimulated by antigen. The fact that anti-L3T4 antibodies inhibit antigen and Con A-stimulated Ca2+ transport and IL-2 production without affecting phosphatidylinositol turnover suggests that L3T4 may play a critical role in modulating the activation of the T cell receptor-associated Ca2+ transporter in T cell stimulus-response coupling.     

Primed T cell responses to chemokines are regulated by the immunoglobulin-like molecule CD31

CD31, an immunoglobulin-like molecule expressed by leukocytes and endothelial cells, is thought to contribute to the physiological regulation T cell homeostasis due to the presence of two immunotyrosine-based inhibitory motifs in its cytoplasmic tail. Indeed, loss of CD31 expression leads to uncontrolled T cell-mediated inflammation in a variety of experimental models of disease and certain CD31 polymorphisms correlate with increased disease severity in human graft-versus-host disease and atherosclerosis. The molecular mechanisms underlying CD31-mediated regulation of T cell responses have not yet been clarified. We here show that CD31-mediated signals attenuate T cell chemokinesis both in vitro and in vivo. This effect selectively affects activated/memory T lymphocytes, in which CD31 is clustered on the cell membrane where it segregates to the leading edge. We provide evidence that this molecular segregation, which does not occur in na?ve T lymphocytes, might lead to cis-CD31 engagement on the same membrane and subsequent interference with the chemokine-induced PI3K/Akt signalling pathway. We propose that CD31-mediated modulation of memory T cell chemokinesis is a key mechanism by which this molecule contributes to the homeostatic regulation of effector T cell immunity.     

Polyomavirus small T antigen enhances replication of viral genomes in 3T6 mouse fibroblasts.

Transfection of 3T6 cells with a cloned polyomavirus genome encoding only large T antigen resulted in DNA replication with only about 1/10 the efficiency of wild-type viral DNA coding for all three T antigens. This replication defect was at least in part overcome by the simultaneous transfections of polyomavirus genomes which allowed the expression of small T antigen. We conclude that polyomavirus small T antigen has a (probably indirect) role in replication.     

Both the Lyt-2+ and L3T4+ T cell subsets are required for the transfer of diabetes in nonobese diabetic mice

The nonobese diabetic mouse is a model of spontaneous type I diabetes mellitus. It is possible to induce diabetes in young, irradiated nonobese diabetic mice by using adoptive transfer of splenocytes or splenic T cells obtained from diabetic donors. This study demonstrates that the induction of diabetes in the adoptive transfer system is dependent on both the L3T4+ and Lyt-2+ subsets of T cells. Neither of these T cell subsets alone mediates the development of severe insulitis or diabetes when adoptively transferred to young, irradiated recipients. In addition, we show that both the L3T4+ and Lyt-2+ subsets must be obtained from diabetic donors in order to transfer diabetes; neither subset can be replaced with cells obtained from young, nondiabetic donors.     

Role of L3T4 antigen in the activation of various functions of Lyt-1+2- T cells against vaccinia virus

The present study defines assay systems for vaccinia virus-reactive Lyt-1+2- T cells mediating various functions and investigates the positivity of L3T4 antigen on these Lyt-1+2- T cells as well as the role of L3T4 antigen in the activation of these T cells with respect to their functions. C3H/He mice were immunized against vaccinia virus by inoculating viable virus intraperitoneally (i.p.). Anti-vaccinia virus reactivity in lymphoid cells from these immunized mice was assessed by proliferative response, helper T cell activities involved in cytotoxic T lymphocyte (CTL) and B cell (antibody) responses, delayed type-hypersensitivity (DTH) response, and production of lymphokines such as interleukin 2 (IL2) and macrophage-activating factor (MAF). The results demonstrate that all of the above anti-vaccinia virus responses were mediated by Lyt-1+2- T cells and that these Lyt-1+2- T cells expressed L3T4 antigens on their cell surfaces. Moreover, such anti-vaccinia Lyt-1+2- T cell responses were inhibited in the presence of anti-L3T4 antigen antibody. These results indicate that there is a reciprocal relationship between Lyt-2 and L3T4 markers, and that L3T4 antigen is closely related to the activation of various functions of anti-vaccinia virus Lyt-1+2- T cells.     

L3T4+ T cells regulate Abelson virus-induced lymphomagenesis

To evaluate the role of T cells in regulation of lymphomagenesis, experiments were performed using Abelson murine leukemia virus (AMuLV). In vitro transformation of bone marrow target cells by this B lymphotropic retrovirus was inhibited by peripheral lymph node cells from naive mice. The inhibitory activity depended on Thy-1+ L3T4+ cells but did not require Lyt-2+ cells. In vivo depletion of L3T4+ T cells with a mAb (GK1.5) altered the course of AMuLV-induced lymphoma. L3T4 depletion of naturally resistant C57BL/6 mice resulted in dramatic susceptibility to lymphoma induction. Lymphoma cells from anti-L3T4-treated C57BL/6 mice infected with AMuLV displayed the B lineage transformation marker P1606C3. These studies reveal an important immunologic component of Abelson disease resistance involving L3T4+ T cells.     

Different phenotypic variants of the mouse B cell tumor A20/2J are selected by antigen- and mitogen-triggered cytotoxicity of L3T4-positive, I-A-restricted T cell clones

The L3T4+, Lyt-2-, cloned BALB/c T cell lines 5.9.24 and 5.8.6 are cytotoxic for the BALB/c B cell tumor line A20/2J. The T cell cytotoxicity against A20/2J cells could be triggered either by the specific antigen ovalbumin (OVA), which is recognized by the T cell clones in association with I-Ad determinants, or by the T cell mitogens Con A and rabbit anti-mouse brain (RaMBr) antiserum. Repeated exposure of A20/2J cells to 5.9.24 and 5.8.6 T cell cytotoxicity selected variant cell lines that had developed resistance to cytotoxicity. The variant lines could be classified into four different variant phenotypes of which three were stably maintained in vitro. The type of variant obtained appeared to be related to the nature of the ligand used to trigger T cell cytotoxicity during selection. Cytotoxicity triggered by the antigen OVA generated type 1 variants that expressed abnormally low levels of I-Ad determinants at the cell surface. Type 1 variants were resistant to OVA-triggered 5.9.24 T cell cytotoxicity, but were fully susceptible to cytotoxicity triggered by Con A or RaMBr antiserum. RaMBr-triggered cytotoxicity generated two unique types of variant cell lines: type 3 variants that were deficient in cell surface Fc receptors and resistant to 5.9.24 cytotoxicity only when triggered by RaMBr antiserum, and type 4 variants that were resistant to cytotoxicity triggered by all three ligands. One type 4 variant, the IC-1 cell line, appeared to be resistant to soluble cytotoxic factors released by 5.9.24 T cells after activation by antigen. All of these variant lines retained sensitivity to cytotoxicity by classic Lyt-2+ cytotoxic T lymphocytes (CTL), a finding that indicates that L3T4a+ T cells and Lyt-2+ CTL use different molecules to attack their target cells. The variant phenotypes were inherited by clones derived from the original cell lines. Because the variants were generated without mutagenesis, they are thought to have been derived by the immunoselection of pre-existing variant cells that arose spontaneously in the parental A20/2J cell line. It is postulated that inheritable variation of A20/2J cells may represent changes that normally occur during B cell differentiation in response to T cell signals. The variant A20/2J cell lines described here provide material for the investigation of B cell surface structures that may regulate T-B cell interactions.