The antigen-specific, major histocompatibility complex-restricted receptor on T cells. VI. An antibody to a receptor allotype

Serological characterization of macrophage hybridomas: identification of an interferon-gamma-inducible surface marker

Macrophage hybridoma clones prepared by fusion of splenic adherent cells with P388D1 tumor cells have previously been shown to be heterogeneous with respect to function at the clonal level. In this study the macrophage clones were phenotypically characterized by indirect RIA using a battery of rat MAbs to murine myeloid and lymphoid cell surface markers. All macrophage clones expressed the common leukocyte antigen T200 and the Mac-1 alpha and beta chains. Markers which were differentially expressed among the clones included class II antigens and the antigens detected by MAbs MIV 55, MIV 38, and 14G8. The antigens detected by the latter three MAbs were referred to as MBR-1, -2 and -3, respectively. Functional heterogeneity did not correlate with phenotypic heterogeneity among the macrophage clones. Treatment of macrophage clones with IFN-gamma resulted in a significant increase in the expression of class II antigens and induced the expression of MBR antigens on some clones which were constitutively negative for these markers. The clonal distribution and induction patterns of class II antigen as compared to MBR antigen indicated that regulation of expression of these markers was independent. In addition, the clonal distribution and induction pattern of MBR antigens, along with competitive binding studies using radiolabeled MIV 38 and 14G8 MAbs, suggested that the three MBR antigens were similar or closely associated molecules.

Growth-dependent variation of major histocompatibility complex (MHC) restriction and expression of Ly-2 and CD3/alpha/beta T cell receptor in cloned cytotoxic T cells

The specificity of major histocompatibility complex (MHC)-restricted antigen recognition by cytotoxic T cells (CTL) has been clearly correlated to the alpha/beta T cell receptor (TcR) complex on the T cell surface. Occasional changes in the specificity of in vitro cultivated CTL clones, therefore, have been suspected to result from alterations of the genes coding for the TcR alpha and/or beta chain. Here we demonstrate that pronounced variations in the stringency of MHC restriction, previously reported to occur during long-term culture of 2,4,6-trinitrophenyl (TNP)-specific CTL clones, may occur rapidly in a growth-dependent, reversible manner, i.e. without structural TcR variation. Several H-2b TNP-specific CTL clones were shown to possess strong cross-reactivity for H-2k TNP target cells when seeded at low cell numbers, but exhibit reduced or undetectable cross-reaction to H-2k TNP in high-density cultures. Another clone revealed "heteroclitic" properties with significantly stronger cytotoxic activity towards allogeneic (H-2k) than syngeneic (H-2b) TNP-modified target cells. In this case dilute cultures appeared as exclusively allo-MHC restricted, whereas dense cultures were allo/self cross-restricted. In all instances these phenomena were accompanied by cell density-dependent quantitative changes in the expression of Ly-2 and T cell antigen receptor. CTL from dilute cultures had at least 2-fold higher surface concentrations of Ly-2 and CD3 antigens than cells from dense cultures while other surface markers such as Thy-1 or LFA-1 were completely identical. No such effects were observed for CTL clones exhibiting cell density-independent specificity patterns. We conclude from these findings that (a) the stringency of MHC restriction specificity may be significantly affected by the amount of expressed TcR and/or Ly-2 molecules, (b) CTL possess mechanisms to regulate Ly-2 and TcR expression and, hence, their MHC-restricted antigen recognition, and (c) the ability to regulate Ly-2 and TcR expression may be altered during prolonged culture of a CTL clone.

Quantitation of surface antigens on cultured murine epidermal Langerhans cells: rapid and selective increase in the level of surface MHC products

It was recently discovered that murine epidermal Langerhans cells (LC) changed significantly in function and phenotype when maintained in culture. Notably, accessory cell function for primary immune responses increased while cytologic markers like ATPase, nonspecific esterase, and Birbeck granules were lost. To further analyze LC differentiation, we used flow cytometry and a panel of 22 monoclonal antibodies to quantitate changes in surface antigens at the single-cell level. A striking change was a fivefold increase in the amount of Ia antigens (which are expressed on class II MHC products) during the first day of culture. The increase was evident within 3 h and reached a plateau at 15-24 h. Both I-A and I-E products behaved similarly. The increase in Ia was blocked by 1 microgram/ml cycloheximide. Expression of other surface antigens was then monitored on Ia+ LC by two-color flow cytometry. Low levels of class I (H-2D and H-2K) MHC products were detected on freshly isolated LC, and these antigens also increased severalfold during the first day of culture. Fc receptors (identified with the 2.4G2 mAb) and the F4/80 macrophage antigen decreased, as reported previously. Three antigens that were detected in fresh suspensions were expressed at constant levels in culture. These were the C3bi receptor and the pan leukocyte and interdigitating cell antigens. Several leukocyte antigens that were not found initially on LCs did not appear, including B220 anti-B cell, 33D1 anti-dendritic cell, and CD4, CD5, CD8 T-cell specificities. We conclude that the surface of cultured LCs undergoes selective changes in culture. As a result, the cells are rich in Ia and H-2 and have detectable C3bi receptors, but have little or no LFA-1, Ti, CD4, 5, and 8, 33D1, 2.4G2, F4/80, and B220 antigens.

Alpha/beta T-cell antigen receptor gene and protein expression occurs at early stages of thymocyte differentiation

Alterations in gene expression that orchestrate eukaryotic cellular differentiation often require appropriate interactions between differentiating cells and a specialized microenvironment. During T-lymphocyte differentiation, immature thymocytes undergo a stringent intrathymic selection process that requires intimate contact with thymic stromal elements. Since this selection process generates T cells that are self-tolerant and recognize nominal antigen only within the context of self-major histocompatibility antigen complex molecules, it is possible that thymocyte/stromal cell interactions are mediated, in part, by antigen-specific receptors expressed on differentiating thymocytes. However, the developmental stage at which alpha/beta antigen-specific receptors are expressed during T-cell maturation has been a matter of debate. To address this issue, we have studied alpha/beta T-cell antigen receptor gene and protein expression on normal thymocyte subsets of AKR/J mice, as well as on a panel of AKR/J primary thymic lymphomas characterized for CD4 (L3T4) and CD8 (Lyt-2) differentiation antigen expression. The data unequivocally demonstrate that alpha/beta heterodimers are expressed not only on phenotypically mature thymocytes but also on the majority of CD4+8+ double-positive cells that comprise the predominant nonmature thymocyte subset. Furthermore, a fraction of thymocytes in the CD4-8- double-negative compartment, known to contain progenitor cells, also expresses readily detectable cell-surface alpha/beta receptors. Therefore, during the process of intrathymic selection, interactions between nonmature thymocytes and stromal cells via the antigen-receptor complex may play a pivotal role in T-cell differentiation and should be considered in formulating schemes for functional T-cell selection.

An ELISA method for detecting antibodies to the T cell antigen receptor

An ELISA method for the detection of monoclonal antibodies (MAb) to the T3-T cell antigen receptor (TCR) complex was devised. The T3-TCR complex was solubilised using digitonin and a rat anti-T3 MAb (Campath 3) was used to bind it to an ELISA plate. Normal rat serum was used to block cross-reactivity between the rat MAb and peroxidase-conjugated rabbit anti-mouse immunoglobulins. The assay was tested on four T cell tumour lines and successfully detected MAbs to TCR beta chain variable regions, as well as the anti-T3 MAb UCHT1. Other anti-T3 MAbs were not detected because Campath 3 blocked their binding. None of a panel of MAbs reacting with other T cell surface antigens reacted in the assay.

The generation and selection of the T cell repertoire: insights from studies of the molecular basis of T cell recognition

The molecular basis of T cell corecognition of antigen and products of the major histocompatibility complex (MHC) was examined using the technique of DNA-mediated gene transfer. Introduction of the genes encoding the alpha and beta chains of the clonotypic molecule (Ti) of the pigeon cytochrome c-specific, I-Ek-restricted murine T cell hybridoma 2B4 into the human leukemic T cell Jurkat or its T3- variants led to the surface expression of various dimeric combinations of human and mouse Ti chains. All alpha beta dimers were associated in a 1:1 ratio with the chains of the T3 complex and all Ti-T3 complexes could transmit effective transmembrane signals for IL2 gene activation following binding and cross-linking by anti-T3 or anti-clonotypic antibodies. However, only the reconstituted mouse 2B4 alpha beta dimer mediated functional responses to antigen-presenting cells bearing the appropriate combination of antigen and Ia molecules. The fine specificity of the antigen-MHC molecule responses precisely matched that of the 2B4 T cell gene donor, establishing that the alpha beta clonotypic molecule is both necessary and sufficient to fully define the dual specificity of a T cell. This result, together with similar data from other laboratories, provides direct evidence in favor of the "single receptor" model of T cell recognition. Analysis of past experiments looking for independent recognition of antigen vs. MHC molecules led us to conclude that limitations on either formation of mixed receptor dimers or of appropriate antigen peptide-Ia molecule pairs may have limited the utility of these studies in providing an answer to this question. Therefore, additional gene transfer experiments were carried out to investigate the role of the two chains of the alpha beta heterodimer in controlling antigen vs. MHC molecule specificity. Our results showed that under conditions in which it was assured that antigen-Ia complexes formed, one could produce a receptor molecule composed of the alpha chain of one T cell hybridoma (2H10) and the beta chain of a second hybridoma (2B4) with a mixed antigen and MHC molecule specificity that could be predicted based on the specificities of the parent T cells. We discuss at length the implication of this result for the issue of single- vs. dual-site recognition models of T cell receptor function. In addition to these results looking directly at specificity of receptor molecules, we have also analyzed expression of various combinations of Ti chains. For alpha and beta, clear asymmetries in the efficiency of surface receptor expression were observed for certain pairs of chains.(ABSTRACT TRUNCATED AT 400 WORDS)

What is known about blocking factors in renal allograft recipients

A variety of substances present in serum or plasma, either at the time of renal transplant or during stable graft function in long-term recipients, may interfere with cell-mediated immune functions. In several cases the presence of serum blocking factors has been correlated with decreased graft vulnerability to acute rejection. The question is: are serum blocking factors important for the induction or maintenance of allograft tolerance or, alternatively, are they merely by-products of the tolerant state? Perhaps the most compelling case for an essential role of serum blocking factors can be made in instances where vigorous cell-mediated immune responses can be demonstrated in vitro, but anergy (for example, absence of DTH response) is seen in vivo. However, in renal transplant recipients the majority of studies that show the presence of receptor blocking antibodies or other immunoregulatory serum factors also found a decreased cell-mediated immune response in vitro. Thus, allograft tolerance would appear to involve multiple mechanisms as suggested elsewhere. Due to the recent discovery of the molecular structure of the T cell receptor 33,34, it is now possible to identify determinants associated with the binding of T cell receptor blocking antibodies in renal transplant recipients; for example, one should be able to determine if families of V beta genes are involved. Alternatively, it may be possible to identify polymorphic structures on T cells other than the alpha, beta receptor complex as ligands for blocking antibodies.(ABSTRACT TRUNCATED AT 250 WORDS)

Phenotypic properties, interleukin 2 production, and developmental origin of a "mature" subpopulation of Lyt-2- L3T4- mouse thymocytes

Two-color flow microfluorometry using monoclonal antibodies to cell surface determinants has shown that a subpopulation of mouse Lyt-2- L3T4- thymocytes, comprising 18% of Lyt-2- L3T4- cells in adult C57BL/6 mice, appears in the thymus late during fetal development. These Lyt-2- L3T4- cells are characterized by lack of expression of determinants recognized by monoclonal antibody J11d, a phenotype characteristic of more "mature" functional T cells. This J11d- subpopulation of Lyt-2- L3T4- thymocytes has now been shown to produce significant quantities of interleukin 2 following mitogen stimulation and to express T-cell receptor molecules recognized by monoclonal antibodies KJ-16 and F23.1. Furthermore, culturing of fetal thymus lobes has shown that precursors of this subpopulation of Lyt-2- L3T4- thymocytes are already present in thymus at 14 days of embryonic development and are thus derived from an intrathymic precursor cell. So, within the mouse thymus, phenotypic changes and acquisition of mature T-cell characteristics occur within a subpopulation of cells originally thought of as exclusively "immature."

Molecular analysis of the antigen receptor of virus-specific cytotoxic T cells and identification of a new V alpha family

We have determined the primary structure of the alpha/beta-antigen receptor of a lymphocytic choriomeningitis virus (LCMV)-specific cytotoxic T cell clone (P14). The beta chain of the T cell receptor is composed of V beta 8.1, D beta and J beta 2.4 gene segments while the alpha chain uses a member of the V alpha 2 family and J alpha TA31. Southern blot analysis of a panel of six other independent LCMV-specific cytotoxic T cell clones did not reveal any preferential usage of the V alpha 2 or V beta 8 gene families in the cytotoxic LCMV response. Additionally, we have isolated and sequenced cDNA clones derived from the non-functionally rearranged alpha allele of P14. This transcript is composed of a unique V alpha gene segment which belongs to a new V alpha gene family.

Thymocytes with the predicted properties of pre-T cells

T cell receptor synthesis in thymocytes was examined by the differential immunoprecipitation of receptors from the surfaces and interiors of metabolically labeled newborn and adult thymocytes. Precipitated molecules were then analyzed for size, charge, and state of glycosylation. Our experiments identified cells within the thymic cortex that contained a large pool of cytoplasmic-free receptor beta chain. The beta chain in this pool was synthesized and degraded rapidly and bore only high-mannose N-linked oligosaccharides. This pool was found predominantly in cells that lacked surface alpha/beta receptors and appeared in ontogeny before cells expressing surface alpha/beta. These results are consistent with a model in which the progenitor of cells with surface alpha/beta expression is the T cell equivalent of the pre-B cell, which has rearranged and expressed beta chain, but not alpha chain.

Characterization of Lyt-2-, L3T4- class I-specific cytolytic clones in C3H-gld/gld mice. Implications for functions of accessory molecules and programmed development

We report the first demonstration of Thy-1+, Lyt-2-, L3T4- MHC-specific CTL clones derived from the Lyt-2-, L3T4- subset of lymph node cells of C3H-gld/gld mice. These clones express alpha/beta heterodimeric TCRs on the cell surface and specifically recognize class I molecules on target cells. Lyt-2 and L3T4 molecules are therefore not essential for the induction, recognition, and killing of antigen-specific CTL. In addition, these studies suggest that antigen specificity development for class I structures may occur before Lyt-2 gene activation in the differentiation of T cells.

Reconstitution of MHC class I specificity by transfer of the T cell receptor and Lyt-2 genes

The T cell receptor alpha and beta chain genes donated by an H-2 class I-specific, CD8-dependent cytotoxic T cell clone were transferred, alone or in combination with the Lyt-2 gene, into a class II-restricted, CD4+ T cell hybridoma. Two important points emerged. First, the alpha and beta T cell receptor genes endowed the recipient with the H-2 class I specificity of the donor only if the same cell had also been transfected with the Lyt-2 gene. Second, the functional Lyt-2 molecule was expressed on the transfected cells in the absence of the Lyt-3 polypeptide. These results demonstrate that, besides the T cell receptor, the Lyt-2 polypeptide is the only subset-specific molecule required to retarget a class II-reactive, CD4+ T cell line toward H-2 class I molecules.

Developmentally regulated expression of T cell receptor beta chain variable domains in immature thymocytes

A minor subset of immature (CD4-,8-) thymocytes that lack expression of the B2A2 antigen was found to express low levels of surface TCR protein as detected by mAbs F23.1 and KJ16 (reacting with protein products of the V beta 8 gene family). Interestingly, F23.1/KJ16 determinants were expressed on a two- to three-fold higher proportion of B2A2- thymocytes than mature lymph node T cells in four independent haplotypes. When expanded in short-term culture with PMA and calcium ionophore, B2A2- thymocytes retained their overexpression of F23.1/KJ16 determinants and showed a fivefold elevated level (relative to lymph node) of V beta 8-specific mRNA. Taken together, these findings suggest that expression of TCR V beta genes, like Ig genes, is developmentally regulated.

Coclustering of CD4 (L3T4) molecule with the T-cell receptor is induced by specific direct interaction of helper T cells and antigen-presenting cells

Blocking studies with monoclonal antibodies have suggested that helper T cell recognition and triggering involve the CD4 (L3T4) accessory molecule as well as the T-cell receptor (TCR) that is linked to the T3 complex. We have investigated the surface distribution of L3T4 and TCR during the direct interaction of a cloned murine helper T-cell line with an antigen-presenting B-cell line. Using immunofluorescence microscopy, we show that in 1:1 cell couples formed between the two cells, in which a specific interaction can be demonstrated, the L3T4 and the TCR become redistributed on the T-cell surface so that they are concentrated in the cell-cell contact region. This coclustering of L3T4 with TCR occurs only when the relevant antigen and appropriate major histocompatibility class II molecules are presented to the T cell, and it therefore requires the specific interaction of the TCR with its complex ligand on the antigen-presenting cell.

Correlation of T cell receptor V beta gene family with MHC restriction

We have studied a panel of DBA/2 T cell clones specific for sperm whale myoglobin (SpW Mb) for TCR (T cell receptor) beta chain gene expression by FACS analysis using the monoclonal antibodies F23.1 and KJ16 specific for the V beta 8 family of the TCR beta chain genes. Within any given specificity group, all the clones tested came from different mice. 10 of 11 I-Ed-restricted SpW Mb-specific T cell clones were F23.1+; 8 of these were also KJ16+. Only one of the three I-Ad-restricted clones tested was F23.1+; this clone was KJ16 negative. This study has demonstrated that I-Ed-restricted T cell clones from DBA/2 mice express members of the TCR V beta 8 family irrespective of the epitopes of SpW Mb recognized. These data suggest an apparent correlation between TCR V beta expression and MHC restriction.

T-cell receptor genes in autoimmune mice: T-cell subsets have unexpected T-cell receptor gene programs

Two unique cell subsets have been identified in the autoimmune-prone MRL/MP lpr/lpr and C3H/HeJ gld/gld murine strains that have the Lyt-2-,L3T4-,Thy-1+, and Lyt-2-,L3T4-,Ia-,Thy-1- phenotypes, respectively. We have now found that these cells express T-cell receptor proteins on their surface. Our observations further indicate that the expression of the Thy-1 antigen does not correlate with the expression of alpha-chain and beta-chain T-cell receptor polypeptides. Interestingly, T-cell receptor gamma-chain RNA expression may be influenced or correlate with Thy-1 molecular expression. These studies indicate unusual relationships of different cell-surface structures that may reflect unexpected developmental programs.

T cell antigen receptor expression in athymic (nu/nu) mice. Evidence for an oligoclonal beta chain repertoire

The expression of T cell antigen receptors (TCR) in congenitally athymic (nude) mice has been investigated. Lymph node T cells from 4-5-mo-old athymic mice expressed full-length transcripts for the TCR alpha and beta chains at a level two-to three-fold lower than normal littermate (nu/+) controls. Low levels of expression of TCR protein at the surface of a proportion of nude T cells was demonstrated by staining with monoclonal antibodies KJ16-133 and F23.1 (directed against protein products of a family of TCR beta chain variable region genes known as V beta 8). Immunoprecipitation studies confirmed that F23.1 reacted with a similar molecular species on nude and nu/+ T cells. Studies with individual nude mice revealed a striking heterogeneity in the proportion of T cells expressing KJ16/F23.1 that was not seen in normal animals. This heterogeneity correlated with the expression of mRNA specific for V beta 8 but not with total expression of full-length beta chain transcripts. Analysis of Lyt-2+ and L3T4+ T cell subsets in individual nude mice further demonstrated that F23.1 expression was frequently associated with only one subset, and several cases were seen in which all L3T4+ cells expressed F23.1. In contrast, a similar (and constant) proportion of Lyt-2+ or L3T4+ T cells expressed F23.1 in control mice. Southern blotting of Hind III-digested DNA from nude T cells with a C beta probe revealed a more restricted pattern of TCR beta chain rearrangements than was seen for normal T cells. Taken together, these data provide compelling evidence that TCR gene rearrangement and expression can occur extrathymically. Furthermore, they suggest a model according to which the restricted functional repertoire of T cells previously observed in individual nude mice results from an oligoclonal expansion of T cells that have randomly rearranged and expressed TCR beta chain genes.

Phenotype of stromal cell-associated thymocytes in situ is compatible with selection of the T cell repertoire at an "immature" stage of thymic T cell differentiation

Murine thymocytes interacting with cortical macrophages, cortical epithelial cells and medullary dendritic cells in situ express T cell receptors at low to intermediate density. They co-express the lineage markers Lyt-2 and L3T4 and are not enriched for cells expressing high-density interleukin 2 and lymph node homing receptors. Thus, recognition of stromal cells in situ in distinct thymic microenvironments occurs at a common stage of T cell maturation which is phenotypically intermediate between intrathymic precursor cells and mature medullary-type thymocytes. The surface phenotype of dendritic cell-associated thymocytes indicates the presence of thymocytes with a "cortical" phenotype within the antigen-exposed ("nonsterile") phase of T cell maturation in the medulla.

An antigen-independent physiological activation pathway for L3T4+ T lymphocytes

The data presented in this report describe an antigen-independent activation pathway leading to reinduction of proliferation of class II major histocompatibility complex (MHC)-restricted murine T cell lines that after previous antigen-specific stimulation reverted to a resting state. Antigen-independent proliferation and interleukin 2 (IL2)-receptor expression occur in the presence of splenic accessory cells, exogenous IL2 and a soluble factor(s) provisionally termed T cell-stimulating factor(s) (TSF). Each of these components is essential for inducing growth. TSF is found in the supernatant of an autoreactive T cell line upon stimulation with syngeneic accessory cells. Neither TSF nor accessory cells can be replaced by IL1 and by some other cytokines. Monoclonal antibodies against class II MHC molecules, the T cell receptor and L3T4 do not block this antigen-independent stimulation. This demonstrates that the function of the accessory cell in this system is not MHC restricted and that the T cell receptor is also not involved. Furthermore, it is suggested that the blocking of L3T4 molecules by antibody will mediate a negative signal only if T cells are triggered via their antigen receptors.

Monoclonal antibodies to LFA-1 and to CD4 inhibit the mixed leukocyte reaction after the antigen-dependent clustering of dendritic cells and T lymphocytes

T cell proliferation in response to many stimuli is known to occur in discrete clusters of dendritic cells (DC) and CD4+ helper lymphocytes. The role of lymphocyte function-associated antigen (LFA-1) and CD4 in the formation and function of these clusters has been evaluated in the mixed leukocyte reaction (MLR). By day 1 of the control MLR, most of the DC and responsive T cells are associated in discrete aggregates. Addition of anti-LFA-1 and CD4 reagents does not block DC-T aggregation but reduces the subsequent proliferative response by 80-90%. Anti-LFA-1 disassembles newly formed DC-T cell aggregates, whereas anti-CD4 inhibits blastogenesis without disrupting the cluster. Binding of DC to sensitized, antigen-specific CD4+ cells has been studied using lymphoblasts isolated at day 4 of the MLR. It has been shown previously that greater than 80% blasts rebind to DC in an antigen-specific fashion in rapid (10 min) binding assays. Antigen-dependent DC-T binding is blocked by anti-Ia but not by mAb to LFA-1 or CD4. However, the bound anti-CD4-coated lymphocytes are unable to release IL-2. Anti-LFA-1-coated T cells release IL-2 but are easily disaggregated after binding to DC. These findings lead to two conclusions. LFA-1 and CD4 are not involved in the initial steps whereby DC bind to T cells but exert an independent and subsequent role. LFA-1 acts to stabilize the DC-T cluster, while CD4 contributes to lymphocyte blastogenesis and IL-2 release. Because DC but not other presenting cells cluster unprimed lymphocytes, it seems likely that an antigen-independent mechanism distinct from LFA-1 and CD4 mediates aggregate formation at the onset of cell-mediated immunity.

Selective activation of helper and cytolytic T-cell functions of L3T4+ clones with either antireceptor antibody or phorbol ester and ionophore

After activation with specific antigen and antigen presenting cells (APC) L3T4+ inducer T-cell clones can lyse Ia+ APC. The present study characterizes the mechanism of activation and specificity of L3T4+ inducer cell-mediated cytolytic function. Two methods that bypass the physiological stimulus of antigen presented on Ia+ APC were used to activate L3T4+ clones. The first method utilized an antireceptor monoclonal antibody (MAb), KJ16.133, to activate KJ16.133+ clones. The activated clones expressed nonspecific cytolytic activity, killing target cells irrespective of their H-2 haplotype or their ability to express cell surface Ia molecules. The crosslinking of bound KJ16.133 antibody greatly enhanced cytolytic activity. This activation is receptor specific because KJ16.133- clones were not activated under identical conditions. The second method of activation was provided by a synergistic action of phorbol-12-myristate-13-acetate (PMA) and ionophore A23187. These agents nonspecifically activated all L3T4+ clones tested. The simultaneous presence of the two agents is required for maximal activation. Again, the activated clones expressed potent nonspecific cytolytic activity. These observations demonstrated that L3T4+ inducer T-cell-mediated killing can be separated into two stages: an activation step, which can be specifically and nonspecifically triggered and an effector phase which causes nonspecific lysis of bystander targets. The induction of nonspecific cytolytic activity by antireceptor MAb was inhibited by anti-L3T4 MAb (GK1.5). In contrast, activation of nonspecific cytolytic activity by treatment with PMA plus A23187 was not inhibited by anti-L3T4 MAb. Under the above activation conditions, antireceptor MAb selectively induced the secretion of IL-3 and expression of nonspecific cytolytic activity. However, there was little or no concomitant proliferation and production of IL-2. In contrast, activation by PMA plus A23187 coordinately induces expression of nonspecific cytolytic activity, secretion of lymphokines (IL-3 and IL-2), and cell proliferation. Thus, the anticlonotypic activation preferentially induces certain functions whereas activation with PMA plus A23187 is not selective.

Secretion of a chimeric T-cell receptor-immunoglobulin protein

To produce sufficient quantities of soluble T-cell receptor protein for detailed biochemical and biophysical analyses we have explored the use of immunoglobulin--T-cell receptor gene fusions. In this report we describe a chimeric gene construct containing a T-cell receptor alpha-chain variable (V) domain and the constant (C) region coding sequences of an immunoglobulin gamma 2a molecule. Cells transfected with the chimeric gene synthesize a stable protein product that expresses immunoglobulin and T-cell receptor antigenic determinants as well as protein A binding sites. We show that the determinant recognized by the anticlonotypic antibody A2B4.2 resides on the V alpha domain of the T-cell receptor. The chimeric protein associates with a normal lambda light chain to form an apparently normal tetrameric (H2L2, where H = heavy and L = light) immunoglobulin molecule that is secreted. Also of potential significance is the fact that a T-cell receptor V beta gene in the same construct is neither assembled nor secreted with the lambda light chain, and when expressed with a C kappa region it does not assemble with the chimeric V alpha C gamma 2a protein mentioned above. This indicates that not all T-cell receptor V regions are similar enough to immunoglobulin V regions for them to be completely interchangeable.

Effective activation of resting mouse T lymphocytes by cross-linking submitogenic concentrations of the T cell antigen receptor with either Lyt-2 or L3T4

We studied the activation of small resting mouse T lymphocytes by antibodies to the T cell antigen receptor in combination with antibodies to other T cell surface antigens. Solid-phase but not soluble antibodies KJ16-133 and F23.1, both directed to beta chains of the V beta 8 family, activate T cells to proliferate in the presence of growth factors, in a dose-dependent fashion. Antibodies to Lyt-2 and to L3T4 had no activating effect at any concentration. However, submitogenic concentrations of KJ16-133 and of F23.1 synergized with a wide range of concentrations of anti-Lyt-2 and anti-L3T4 to cause T cell proliferation similar or greater in magnitude to that caused by high concentrations of anti-T cell receptor antibody. Synergistic activation was also observed with antibodies to Lyt-1, LFA-1 and H-2 class I antigens but to a significantly lower degree. This was particularly clear in limiting dilution experiments in which the corrected frequencies of T cells proliferating in response to low amounts of anti-T cell receptor antibody together with anti-Lyt-2 were 1/4 to 1/7 for BALB/c T cells. The frequencies of BALB/c T cells responding to high concentrations of anti-T cell receptor antibody alone were between 1/14 and 1/126 and still lower frequencies of T cells proliferated in synergistic responses with anti-LFA-1 or anti-Lyt-1. Synergistic activation leads to the induction of functional cytotoxic cells. We interpret these data as suggestive that cross-linking of the T cell antigen receptor with either Lyt-2 (CD8) or L3T4 (CD4) represents an optimal activating signal for resting T cells. We think that, in physiological T cell activation, cross-linking of the T cell receptor to CD8 or CD4 is induced by their simultaneous binding to major histocompatibility complex (MHC) class I (for CD8) or MHC class II (for CD4) molecules on stimulator cells. We consider the possibility that similar cross-linking requirements may also exist during T cell repertoire selection in ontogeny, thus accounting for the strict coexpression of MHC class I and class II-restricted T cell receptors with CD8 and CD4 molecules, respectively.

A T cell receptor V beta segment that imparts reactivity to a class II major histocompatibility complex product

We have identified in mice an allele of a new T cell receptor V beta gene, V beta 17a, whose product is bound by the monoclonal antibody KJ23a. Over 90% of T cell hybridomas prepared from V beta 17a+ T cells of SWR mice respond to allogeneic forms of the IE class II MHC protein, indicating that V beta 17a has an appreciable affinity for IE regardless of the other components of the T cell receptor. These results suggest a bias in the germ-line T cell receptor repertoire toward recognition of MHC proteins and indicate that the V beta portion of the receptor may form the most important contact points with MHC ligands.

T cell tolerance by clonal elimination in the thymus

The monoclonal antibody KJ23a reacts with T cell receptors utilizing the V beta segment V beta 17a. T cells bearing V beta 17a+ receptors react with very high frequency with the MHC class II protein, IE. In this paper we show that T cells expressing V beta 17a are selectively eliminated from the peripheral T cell and mature thymocyte pool of mice expressing IE, but are present in expected numbers in the immature thymocyte population of such animals. These results show that in normal animals tolerance to self-MHC is due to clonal elimination rather than suppression. In addition, they indicate that tolerance induction may occur in the thymus at the time immature thymocytes are selected to move into the mature thymocyte pool.

Specificity repertoire of splenic Lyt-2+/F23+ cytotoxic lymphocyte precursors from B6 mice

As revealed by flow cytometric analysis, about 30% of nylon wool nonadherent Lyt-2+ B6 spleen cells were F23+, i.e., were stained with the monoclonal antibody F23.1 directed against an allotypic T-cell receptor determinant. The specificity repertoire of splenic Lyt-2+/F23+ cytotoxic lymphocyte precursors (CLP) from B6 mice was investigated in a limiting dilution (LD) system designed to support clonal expansion in vitro of a representative fraction of this T-cell subset: in highly purified Lyt-2+ responder cells cocultured with mitomycin-treated F23 hybridoma cells in the presence of (recombinant) interleukin 2 under LD conditions, one out of three Lyt-2+/F23+ CLP gave rise to a functional cytotoxic T lymphocyte (CTL) clone. The split-well analysis of individual CTL populations demonstrated a clear-cut segregation of the lytic reactivities toward different allogeneic Con A blast targets. A large fraction of B6-derived CTL clones (3-10%) specifically lysed fully H-2 allogeneic (H-2k, H-2d), or H-2K mutant (bm1) targets. Self-reactive and allorestricted lytic patterns were not found.

Functional alpha and beta T cell chain receptor messages can be detected in old but not in young athymic mice

The expression and sequences of T cell antigen receptor (TcR) alpha and beta-chain genes were investigated in the spleens from congenitally athymic (nude) mice. A small number of Thy-1+ cells (approximately 7.0%) was found in nylon wool-enriched spleen cells from young (8 weeks old) nude mice but no L3T4 or Lyt-2 surface antigens were detected. These nude mice expressed only a low level of 1.0-kb beta-chain mRNA and little or no alpha-gene transcripts. On the other hand the number of Thy-1+ spleen cells increased slightly (to 24%) in old (20 weeks old) nude mice and a small number of L3T4+ (10%) and/or Lyt-2+ (5%) cells were detectable. "Full length" 1.7-kb alpha-chain and 1.3-kb beta-chain messages could be found in nylon wool-enriched spleen cells from old nude mice. Sequence analysis of the cDNA revealed that no functional alpha and beta-chain genes can be detected in the spleen cells of young athymic mice while some of the old mice with nu/nu genotype are composed of completely rearranged V-(D)-J-C-gene segments which encode potentially functional proteins. Interestingly, two of three independent cDNA clones encoding the alpha chain used the same V alpha and J alpha-gene segments. These results suggest that extrathymic TcR alpha and beta-chain gene rearrangements do occur, though slowly, to some extent, in nude mice and may be responsible for the limited antigen and/or H-2-related T cell functions in these old athymic mice. The data further suggests that the TcR repertoire in athymic mice may also be limited.

Hybrid antibody-mediated lysis of virus-infected cells

Previously, cytotoxic T lymphocytes (CTL) had only been focused by hybrid antibodies to normal, cell-surface proteins and haptenated surface structures. In this report, we extend the application of this technology to mediate lysing of virus-infected cells by nonspecific CTL. Heteroconjugated antibodies between the anti-T cell antigen receptor antibody, F23.1, and monoclonal antibodies against either the hemagglutinin or nucleoprotein of the influenza virus PR/8 were constructed. We show in the present report that these bispecific constructs can target virus-infected cells for lysis according to the specificity of the virus-protein reactive monoclonal antibodies. Furthermore, even a virus protein that is only expressed in small quantities on the cell surface, such as nucleoprotein, can be exploited as target structure for heteroconjugated antibodies. These studies show that hybrid antibodies can focus a CTL response on virus-infected cells which might in the future be used to mount an immune response in situations without sufficient normal cellular defense.

Antigen-specific helper factor reacts with antibody to the T-cell receptor

Antigen-specific helper factor (ASHF), a soluble product of T helper (Th) cells, binds antigen and can induce B-cell and cytotoxic T-lymphocyte (CTL) differentiation. Its relationship to the T-cell surface antigen receptor (TcR) is unknown. Both have MHC-restricted recognition of nominal antigen, thus they may share very similar combining sites. Using monoclonal anti-TcR to immunoprecipitate partially purified ASHF, we have obtained evidence for shared determinants between ASHF and the TcR. Antigen affinity-enriched supernatants of a Th clone, LB19, are functionally active in antigen-specific, help-dependent CTL assays. FPLC anion exchange salt fractions of these supernatants were 125I-labelled and immunoprecipitated with KJ16.133 monoclonal anti-TcR coupled to Sepharose 4B. Precipitates were analysed by SDS-PAGE. We have obtained clear evidence that functionally active Th culture supernatants contain molecules specifically precipitable by anti-TcR antibody.

Sequences and repertoire of the human T cell receptor alpha and beta chain variable region genes in thymocytes

To compare and contrast the human T cell antigen receptor (TcR) alpha and beta chain messages found in human thymocytes to those previously isolated from human peripheral blood T lymphocytes and other nonthymic sources, 13 TcR alpha and 13 TcR beta cDNA were isolated from a human thymocyte library and the nucleotide sequences were determined. The data indicate that, as was found in the peripheral T lymphocytes, the majority of the TcR alpha and TcR beta chain thymocyte cDNA were derived from potentially functional messages. Although the thymocyte-derived TcR cDNA do not contain any unique structural features when compared to TcR cDNA from mature T lymphocytes, 4 new J alpha segments, 17 new V-gene segments (9 V alpha; 8 V beta) and 7 additional V-gene families (4 V alpha and 3 V beta) and sequences had been identified. The exon C beta O, found in many murine thymocyte TcR beta messages, was not found in over 75 human beta chain messages. Based on these new data, a revised estimate of human TcR V alpha, J alpha and V beta repertoires is calculated. The most significant change has been the increase in the estimated number of human TcR V beta-gene segments to a total of about 100 distributed among about 18 families. The V alpha families are now revised upward to 16, with a total number of V alpha segments of 50. The estimate of the J alpha segments in humans remains between 50-100.

Accessory molecules and T cell activation. II. Antibody binding to L3T4a inhibits Ia-independent mouse T cell proliferation

Monoclonal antibody (mAb) blocking assays using L3T4- and lymphocyte function-associated antigen-1 (LFA-1)-specific reagents were used as an approach to investigate the involvement of these accessory molecules in various T cell activation pathways. As previously reported, rat mAb to L3T4a and LFA-1A functional epitopes efficiently blocked antigen-driven T helper cell proliferation. In contrast, antigen- and Ia-independent T cell triggering induced by appropriate mAb to the Thy-1 or the T cell receptor molecules were found to be inhibitable by L3T4a- but not LFA-1A-specific mAb, although the extent of inhibition varied, depending on the cell type and the activating signal examined. These results provide further evidence that the inhibiting effects of L3T4-specific mAb on T cell responses may be due, in addition to an impairment of L3T4-class II major histocompatibility complex molecular interaction, to a down regulatory signal possibly transmitted by the L3T4 molecule itself.

Specific lysis of Listeria monocytogenes-infected macrophages by class II-restricted L3T4+ T cells

Mice were infected with the intracellular bacterium, Listeria monocytogenes, and T cell clones from spleens, lymph nodes and peritoneal exudates were established. The capacity of L3T4+, Lyt2- T-cell clones to specifically lyse L. monocytogenes-infected macrophages was analyzed. As a source of target cells, bone marrow macrophages (BMM phi) after 9 days of culture in hydrophobic teflon bags were used. These BMM phi were totally Ia-; however, significant Ia-expression could be induced by interferon-gamma (IFN-gamma). IFN-gamma-stimulated BMM phi, after priming with live or killed L. monocytogenes organisms were effectively lysed by the vast majority of L3T4+ T cell clones. In the absence of either IFN-gamma stimulation or antigen priming, no lysis occurred. Cytolysis was demonstrable in a conventional 4-h 51Cr-release assay and in an 18-h neutral red uptake assay and was antigen specific and class II restricted. Native T cells from L. monocytogenes-infected mice failed to lyse stimulated, L. monocytogenes-primed BMM phi and gained their cytolytic activity after antigenic restimulation in vitro. These data demonstrate that L. monocytogenes-specific L3T4+ T cells could lyse M phi presenting listerial antigens provided that Ia antigen expression had been induced. L3T4+ T cell clones produced IFN-phi after restimulation with antigen plus accessory cells in vitro and IFN-gamma secretion could be increased by costimulation with recombinant IL 2. These T cell clones conferred significant protection upon recipient mice which was more pronounced in the liver. The possible relevance of lysis by L3T4+ T cells of infected M phi to protection against and pathogenesis of intracellular bacterial infections is discussed.

Characterization of virus-specific cytotoxic T cell clones from allogeneic bone marrow chimeras

We established several H-2-restricted lymphocytic choriomeningitis virus (LCMV)-specific cytotoxic T cell clones from spleens of virus-primed C57BL/6 or C57BL/10 (H-2b) and B10.BR (H-2k) mice and from allogeneic C57BL/10----B10.BR and B10.BR----C57BL/10 bone marrow chimeras. Two T cell clones of H-2b origin and restricted to H-2b, 3 of H-2k origin and restricted to H-2k were compared with two clones each derived from the two types of chimeras. Their surface phenotype was found to be Lyt-2+, L3/T4- and KJ16-133+ (2 of 9). Clones from chimeras expressed bone marrow donor H-2 and are restricted to the recipient H-2. H-2k-restricted clones were all specific for Kk whereas all H-2b-restricted clones were specific for Db. These restriction specificities could be further defined by the blocking activity of various monoclonal anti-H-2 antibodies. Interestingly the anti-H-2Db antibodies blocked the restricted virus-specific killing activity of the clones derived B10.BR----C57BL/10 chimeras much more effectively than the activity of the clones derived from conventional H-2b mice. The various clones differed with respect to their fine specificity for LCMV strains. The 3 clones of conventional B10.BR origin only recognized LCMV-WE but not LCMV-Armstrong, Aggressive or Docile; H-2b-restricted conventional clones recognized target cells infected with all LCMV strains except LCMV-UBC-Docile; the T cell clones from the bone marrow chimeras recognized with one exception all LCMV strains tested.

Downregulation of T cell responses by antibodies to the T cell receptor

We have derived a T cell clone that recognizes and responds to three different types of antigen: self + X (fowl gamma globulin + H-2d), allo-H-2p,b, and minor lymphocyte-stimulating (Mlsa,d) determinants. Anti-TcR mAb and their F(ab')2 and Fab fragments were tested for their capacity to block the response of this clone. When responses were assayed on day 4 or later, addition of KJ16 or F23.1 mAb caused a marked inhibition of the response to each of the three antigens recognized by the clone. Responses measured at earlier time points however were unaffected or enhanced. This finding suggested that the inhibitory effects of anti-TcR mAb that followed the phase of enhancement might have reflected downregulation of the cells rather than simple blockade of TcR. In support of this possibility it was found that addition of anti-TcR mAb caused marked inhibition of the response of the clone to IL-2, i.e., a response that is not known to involve the TcR.

Expression of a murine polyclonal T cell receptor marker correlates with the use of specific members of the V beta 8 gene segment subfamily

A series of murine T lymphocyte clones were examined for reactivity with the KJ16-133 and F23.1 mAbs. Clones that were KJ16-133+,F23.1+ and KJ16-133-,F23.1+ were identified, but no KJ16-133+,F23.1- clones were observed. Within our panel of clones, therefore, the KJ16-133 antibody identifies a subset of F23.1+ cells. All F23.1+ clones examined express members of the V beta 8 subfamily of beta chain variable region genes; clones expressing V beta 8.1 or V beta 8.2 reacted with both KJ16-133 and F23.1, while clones expressing V beta 8.3 reacted only with F23.1. Thus, the differential reactivity of the KJ16-133 and F23.1 antibodies with cloned T cells correlates with the V beta gene expression of each clone. Reactivity with these antibodies should therefore be of utility for predicting the V beta gene expression in some T cell clones.

A family of T-cell receptor molecules expressed on T-cell clones with different specificities for allomajor histocompatibility antigens

A monoclonal antibody, 3D6, identifies a public idiotope or allotope on the human T-cell receptor for antigen, since it not only reacts with the tumor line HPB-ALL, against which it has been raised, but also with 3-13% of peripheral blood T lymphocytes of normal donors. 3D6+ cells have been isolated from an allogeneic mixed lymphocyte culture and cloned by limiting dilution. In this way, allospecific clones were obtained both of the T4+T8- and the T4-T8+ phenotype, which included proliferative as well as cytotoxic cells. Within a panel of 20 cytotoxic clones, different specificities for both class I and class II MHC antigens were found. The clones were tested for their reactivities with four additional anti-T-cell receptor antibodies raised against HPB-ALL. Two of these, 1C1 and 1C2, reacted with all 3D6+ clones. By means of two other antibodies, 2D4 and 65, the 3D6+ receptor family could be divided into four structurally distinct subfamilies. Biochemical analysis suggested that the 1C1, 1C2, 2D4, and 3D6 antibodies define epitopes on the beta chain of the receptor. Isoelectric focusing of receptor molecules isolated from cytotoxic clones with different specificites indicated that there are extensive structural differences in both alpha and beta chains of the receptors. No correlation could be found between the antigenic specificity of a clone and the structure of its receptor in this analysis. It is postulated that the 1C1, 1C2, and 3D6 epitopes may be encoded by a particular germline V beta segment, in analogy with similar, previously described findings in both the human and the murine system.

Use of V beta.8 genes in splenic Lyt-2+ cytotoxic lymphocyte precursors reactive to bm1 or bm14 alloantigen in individual C57BL/6 mice

The cytotoxic response of cell sorter-purified small Lyt-2+ splenic cytotoxic lymphocyte precursors from 10 individual C57BL/6 mice to mutant class I H-2Kbm1 or H-2Dbm14 allodeterminants was analyzed under limiting dilution conditions. The cytotoxic activity of anti-bm1-specific or anti-bm14-specific cytotoxic T lymphocyte (CTL) populations (selected for a high probability of clonality) was tested against F23 hybridoma cells; F23+ CTL clones lysed F23 hybridoma targets but F23- CTL clones did not. In the C57BL/6 anti-bm1 mixed lymphocyte reaction, 36% (range 29-48%) of the generated CTL clones were F23+; in the B6-anti-bm14 mixed lymphocyte reaction, 45% (range 34-49%) of the generated CTL clones were F23+. Hence, a large fraction of the anti-bm1- or anti-bm14-reactive CTL clones from C57BL/6 mice use V beta.8 genes to construct these allospecific T cell receptor phenotypes, but no extensive variation in the use of V beta.8 genes in the construction of allospecific T cell receptor phenotypes of restricted heterogeneity is found in individual mice of the same strain.

The T cell repertoire may be biased in favor of MHC recognition

The receptors of two T cell hybridomas that recognize class I and class II major histocompatibility complex (MHC) molecules, respectively, have been compared. In both cases these receptors are hybrid molecules formed as a result of cellular fusion. The receptors contain the same alpha chain, contributed by the tumor cell fusion partner, and related beta chains, contributed by the normal T cell component. Thus, surprisingly, the same alpha chain can contribute to recognition of class I and class II MHC molecules. Moreover, the finding that in two independent examples hybrid receptor molecules created randomly by in vitro cell fusion recognize MHC supports the theory that the T cell repertoire has an intrinsic affinity for MHC.

Synthetic peptides and beta-chain gene rearrangements reveal a diversified T cell repertoire for a lambda light chain third hypervariable region

Twelve L3T4+ Ly-2.2- subclones, derived from 4 independent BALB/c T cell lines, responded to a combination of the I-Ed molecule and a synthetic peptide corresponding to residues 91-108 of the lambda light chain from BALB/c myeloma protein M315 (alpha, lambda 2). Peptide analogues in which the mutated residues Arg95 or Asn96 were exchanged with the corresponding germ-line-encoded Ser95 or Thr96 had an abolished or greatly reduced capacity to stimulate T cell clones. However, responses of subclones to an analogue where the mutated Phe94 was substituted with the germ-line-encoded Tyr94 revealed three specificity patterns: 5 clones reacted only with the lambda 2(315) peptide, 6 clones responded equally well to both peptides and a single clone reacted better with the Tyr94 analogue. Analysis of the T cell receptor beta-chain gene rearrangements disclosed 7 distinct rearrangements, identical rearrangements only being found for subclones originating from the same line. At least 3 different V beta genes were used. Subclones with identical or nearly identical peptide specificity, major histocompatibility complex-restriction and alloreactivity could differ in their V beta or J beta gene segment utilization.

The role of the T-cell receptor in thymocyte maturation: effects in vivo of anti-receptor antibody

The T-cell receptor, which recognizes antigen plus a product of the major histocompatibility complex, has been postulated to drive T-cell maturation in the thymus by engaging major histocompatibility complex proteins expressed on thymic stromal cells. We tested this idea by injecting neonatal animals with an anti-receptor antibody, KJ16, that binds to about 20% of T cells and is capable of blocking receptor function. In the presence of this antibody, mature T cells bearing the KJ16 epitope failed to develop. On the other hand, although the antibody could be shown to bind to receptors on cortical thymocytes, it did not prevent the rapid expansion or survival of the bulk of the KJ16+ cells in this population. These results are consistent with the hypothesis that most cortical thymocytes arise by a receptor-independent mechanism and that only a small proportion of these cells mature by a process dependent on receptor-major histocompatibility complex interactions.

Inherited polymorphism of the human T-cell antigen receptor detected by a monoclonal antibody

Three different murine monoclonal antibodies to the human clonotypic T-cell antigen receptor immunoprecipitate the alpha-beta chain heterodimer; induce comodulation of the clonotypic molecule with the T3 molecular complex; stain small populations of normal polyclonal T cells, suggesting that they react with variable or joining region determinants of the clonotypic receptor; and induce proliferation of resting T cells. While two of these antibodies detect the clonotypic receptor in all individuals studied, the third antibody (OT145), described herein, does not detect the T-cell antigen receptor on T cells of all individuals. By indirect immunofluorescence, three groups can be distinguished within a population of individuals (n = 138) by OT145. Individuals lacking T cells reactive with OT145 have a homozygous OT145-phenotype. T cells from such individuals fail to proliferate in the presence of OT145 in contrast to T cells from OT145+ individuals. Individuals with a relatively large percentage of OT145+ T cells, 4.5 +/- 1.54% (mean +/- 2 SEM) are homozygous OT145+, while those with an intermediate percentage, 2.04 +/- 0.9%, have a heterozygous phenotype. Family studies suggest autosomal codominant inheritance of the OT145 phenotype. The distribution of the three OT145-defined phenotypes varies considerably in populations of different ethnic background. Taken together these data suggest that the polymorphism detected by OT145 may represent a variable or joining region allotypic system of the human T-cell antigen receptor. In addition, our results indicate that allelic exclusion governs the expression of the clonotypic receptor by human T cells.

Induced differentiation of a transformed clone of Ly-1+ B cells by clonal T cells and antigen

The present study used cocultures of clonally derived B and T cells, together with an antigen reactive with the membrane Ig of the clonal B cells, to address the issue of B-cell differentiation requirements. The B cells were CH12.LX, an in vitro grown subclone of a murine B-cell lymphoma, which bears surface IgM reactive with sheep erythrocytes. The T cells were alloreactive T-helper-cell hybridomas. Very small numbers of T-helper cells could induce differentiation of cloned B cells without the presence of accessory cells, but such induction was dependent upon the presence of the antigen recognized by the B cell. Induced differentiation of the B cells did not depend on metabolic activity of the T cells, and metabolically active T cells could be replaced by fixed cells or by monoclonal antibody reactive with the class II molecule of the B cell to deliver an Ia-specific differentiative signal. T cells, or alloantibody that reacted with the I-E molecule, induced differentiation of the B cells; those that reacted with the I-A molecule did not. These results define the minimal requirements for major histocompatibility complex-restricted, T-cell-mediated induction of B-cell differentiation.