The relationship between immune interferon production and proliferation in antigen-specific, MHC-restricted T cell lines and clones

The release of immune or gamma interferon (IFN-gamma) by major histocompatibility complex (MHC)-restricted pigeon cytochrome c-specific Lyt 1+2-, interleukin 2 (IL 2)-producing proliferative T cell clones when cultured with antigen and antigen-presenting cells (APC) is a sensitive measure of the state of activation of the cell. In general, the fine specificity of T cell activation was similar when activation was measured either by IFN-gamma production or by proliferation. In response to antigen and the correct Ia molecule, the T cell clones produced both high titered IFN-gamma and a strong proliferative response. However, IFN-gamma production and the degree of proliferation of the T cell clones differed at high antigen concentrations. As antigen concentration increased, the magnitude of proliferation became submaximal whereas the IFN-gamma response became maximal suggesting that IFN-gamma produced by the cells might act as an autoregulatory molecule inhibiting the proliferative response. Stimulating the T cell to divide via its IL 2 receptor by adding exogenous IL 2 produced high levels of proliferation but only low titers of IFN-gamma activity. In addition, irradiation of the clone eliminated the IFN-gamma release induced by IL 2 but did not affect the IFN-gamma release induced by antigen and Ia. Thus proliferation is not essential for IFN-gamma production and unlike antigen and Ia, IL 2 functions predominantly as a proliferative signal and not as a signal for factor release. Two T cell clones showed a dissociation of IFN-gamma production and proliferation. In one case, a clone that proliferated in response to both allogeneic and antigenic stimuli released IFN-gamma in response to antigen but failed to produce IFN-gamma in response to the allogeneic stimulus. A second clone that showed a strong proliferative response to pigeon cytochrome c but no proliferative response to a species variant of cytochrome c, tobacco hornworm moth (THWM) cytochrome c, produced IFN-gamma when stimulated with either of these antigens. Thus, the sensitivity of detecting activation of T cell clones as measured by the release of an individual lymphokine varies from one clone to another.     

Two distinct mechanisms account for the immune response (Ir) gene control of the T cell response to pigeon cytochrome c

Previous experiments have demonstrated that the immune response of MHC congenic mice to pigeon cytochrome c is under Ir gene control. Expression of I-E-encoded gene products influences both the magnitude and fine specificity of the Th cell response to pigeon cytochrome c and phylogenetic derivatives. Results of those experiments implicate both determinant selection and repertoire selection as mechanisms of Ir gene control in this system. In this report we have compared the TCR expressed in pigeon cytochrome c-reactive Th cells from B10.A(I-Ek), B10.A(5R) (I-Eb), and B10.S(9R) (I-Es) mice. The B10.A(5R) strain is a low responder to pigeon cytochrome c, but in response to moth cytochrome c this strain produces T cells which respond to pigeon or moth cytochrome c on B10.A APC. These cells are phenotypically identical to the predominant clonal phenotype seen in the B10.A response to pigeon cytochrome c. In this report, we show that the B10.A and B10.A(5R) pigeon cytochrome c-reactive T cells express essentially identical T cell receptors. These results, coupled with recent studies reporting a relatively low affinity for I-Eb molecules by pigeon cytochrome c peptides compared with moth cytochrome c peptides, strongly argue that the immune response defect in the B10.A(5R) strain is due to a defect in Ag presentation (determinant selection). In contrast, B10.A and B10.S(9R) strains are high responders to pigeon cytochrome c. Both strains produce T cell clones which are capable of responding to cytochrome c presented by either B10.A or B10.S(9R) APC in vitro. We show that, even in T cells with this MHC restriction degeneracy, the TCR expressed in the two strains are different. Because the APC of both strains can clearly present the cytochrome c Ag, we conclude that the differential expression of the TCR in the responses is due to a T cell repertoire selection difference in the two strains. Thus, for the response to one Ag in three MHC congenic strains, there exists evidence that both determinant selection and repertoire selection can be mechanisms of Ir gene control of an immune response.     

Enhanced antigen-presenting capacity of cultured Langerhans' cells is associated with markedly increased expression of Ia antigen

Recent studies indicate that when epidermal Langerhans' cells (LC) are cultured for 2 to 3 days they, in comparison to freshly prepared LC, exhibit markedly enhanced ability to stimulate T cell proliferative responses in oxidative mitogenesis and in the mixed epidermal-leukocyte reaction. In this study, we determined whether cultured LC enhance antigen-specific T cell responses, and whether such enhanced stimulatory capacity correlates with the level of Ia antigen expressed on LC. We used C3H/He (Iak) epidermal cells as stimulators and, as responder cells, both the trinitrophenyl-specific clones D8 and SE4, which were assayed for [3H]dThd incorporation, and the pigeon cytochrome c specific hybridoma 2C2, which was assayed for interleukin 2 production. Cultured LC induced 10 to 100 times greater proliferation or interleukin 2 production by responder cells than did freshly prepared LC. The intensity of I-Ak and I-Ek, expressed on cultured LC as assessed by immunofluorescence and flow cytometry, was found to be 10 to 36 times greater on a per cell basis than that on freshly prepared LC. Depletion of LC from fresh epidermal cell suspensions by anti-Iak and complement or treatment with 50 mJ/cm2 medium range ultraviolet light or cycloheximide before culture abrogated both the increase in Ia expression and antigen-specific clonal proliferation. The results suggest that when LC are removed from their usual epidermal milieu, they express increased amounts of Ia and become more potent stimulators of T cell responses.     

The fine specificity of antigen and Ia determinant recognition by T cell hybridoma clones specific for pigeon cytochrome c

The activation of proliferative T lymphocytes normally involves the simultaneous recognition of a particular foreign antigen and a particular Ia molecule on the surface of antigen-presenting cells, the phenomenon of major histocompatibility complex (MHC) restriction. An analysis of T cell clones specific for pigeon cytochrome c, from B10.A and B10.S(9R) strains of mice, revealed the unusual finding that several of the clones could respond to antigen in association with Ia molecules from either strain. Using these cross-reactive clones, we performed experiments which demonstrated that both the Ia molecule and the T cell receptor contribute to the specificity of antigen recognition; however, MHC-linked low responsiveness to tuna cytochrome c (an immune response gene defect) could not be attributed solely to the efficacy with which the Ia molecules associated with the antigen. These results imply that antigen and Ia molecules are not recognized independently, but must interact at least during the process of T cell activation.     

The B10.A mouse B cell response to pigeon cytochrome c is directed against the same area of the protein that is recognized by B10.A T cells in association with the Ek beta:Ek alpha Ia molecule

An analysis of the fine specificities of the primary and hyperimmune antibody responses of B10.A mice to pigeon cytochrome c showed that both were qualitatively very similar. Small amounts of antibody appeared to be directed against the regions of serine 15 and/or glutamic acid 44. The remaining antibodies (greater than 70%) bound to the same complex topographic determinant (including residues 3, 103, and 104) on the back surface of pigeon cytochrome c which had been found to dominate the rabbit antibody response to this protein, and to be involved in Ia-restricted T cell stimulation. The mouse antibodies reacted very poorly with fragmented forms of the immunogen or with tobacco hornworm moth cytochrome c, even though both of these antigens had been shown previously to strongly stimulate pigeon cytochrome c-primed T cells. The specificities of the primary IgG responses of seven other mouse strains were found to be very similar, but not identical, to that of B10.A mice. The cytochrome c-specific antibodies in the hyperimmune serum were shown to bind to determinants involving residues that vary between pigeon and mouse cytochromes c. Comparison of the binding of the antibodies to the immunogen and to the corresponding host protein enabled the calculation of the proportion of the overall binding energy contributed by the variant residues. This was as low as 19 to 35% for the primary response, rose to 25 to 46% for the hyperimmune mouse antibodies, and reached 40 to 63% for hyperimmune rabbit antibodies. The remaining energy of interaction (37 to 81%) was necessarily contributed by the surface of the protein surrounding the variant residues, which is the same for the immunogen and the host protein. These results illustrate the relatively subtle differences in binding affinities which can distinguish self from non-self recognition by antibody molecules.     

IA mutant functional antigen-presenting cell lines

We describe a protocol for the selection of mutant cells with an altered pattern of Ia antigenic determinants and antigen-presenting properties from a homogeneous population of functional antigen-presenting cells (APC). The APC line used in this work was obtained by fusing lipopolysaccharide-stimulated B cells from (BALB/c x A/J)F1 donors with cells from the M12.4.1 BALB/c B lymphoma cell line. The resulting hybridomas, including TA3, retained the potent antigen-presenting activity of the parental B lymphoma line and expressed Ia antigens and immune response gene-determined antigen-presenting properties of the A/J type. Mutants of TA3 were obtained by subjecting the cells to negative immunoselection with one monoclonal anti-(alpha) 1-Ak antibody and complement followed by positive immunoselection via electronic cell sorting with a second monoclonal alpha I-Ak or alpha I-Ek antibody. Two types of mutants were obtained. One, A8, appeared to have undergone a fairly limited alteration, since it lost only some of the I-Ak antigenic determinants; the second type appeared to have lost the entire I-Ak molecule but to have retained the I-E molecule. Functional studies with the A8 mutant demonstrated that the loss of a limited number of I-Ak determinants correlated with the loss of a specific I-Ak-encoded restriction element, since A8 failed to present a specific antigen, hen egg lysozyme (HEL), to a HEL-specific I-Ak-restricted T cell hybridoma but retained some capacity to present a second antigen, poly(Glu60Ala30Tyr10) (GAT), to a GAT-specific I-Ak-restricted T cell hybridoma. These results indicate that Ia antigens are the products of immune response gene loci. The availability of such mutants should allow an examination of the relationship between the structure of an Ia molecule and the antigens with which it is co-recognized by T cells.     

Functional studies on the role of I-A molecules expressed by the antigen-specific T suppressor cell clone HF1

The antigen-specific T suppressor (Ts) cell clone HF1 (Thy-1.2+, I-Ak+, I-Ek+) was isolated from a CBA/J mouse tolerized to low doses of bovine serum albumin (BSA), and a subclone was adapted to grow in the absence of antigen-presenting cells. The functional role of the I-Ak molecules endogenously expressed by HF1 Ts cells was analyzed by using anti-I-Ak monoclonal antibodies (mAb) in attempts to block the antigen-induced proliferation of these cells. Among a panel of anti-I-Ak mAb tested, only the H118-49 mAb directed against the private determinant Ia.m1 blocked BSA-induced proliferation. The data presented here suggest a selective regulatory role of membrane-bound I-Ak molecules in the antigen-induced signal transmission.     

Cutting edge: dueling TCRs: peptide antagonism of CD4+ T cells with dual antigen specificities.

T cells expressing two different TCRs were generated by interbreeding 3A9 and AND CD4+ TCR transgenic mice specific for the hen egg lysozyme (HEL) peptide 48-62:I-Ak and moth cytochrome c (MCC) peptide 88-103:I-Ek peptide:MHC ligands, respectively. Peripheral T cells in the offspring express two TCR V beta-chains and respond to HEL and MCC. We observed minimal or no additive effects upon simultaneous suboptimal stimulation with both agonist peptides; however, an antagonist peptide for the 3A9 TCR was able to inhibit the response of the dual receptor T cells to MCC, the AND TCR agonist. This HEL antagonist peptide did not affect AND single transgenic T cells, indicating that the antagonism observed in the dual TCR cells is dependent on the presence of the HEL-specific 3A9 TCR. In contrast, anti-TCR Abs mediate receptor-specific antagonism. These results demonstrate that peptide antagonism exerts a dominant effect.     

Separation of the immune response genes for LDH-B and MOPC-173. II. Description of an immune response defect in B10.ASR7

By using the intra-I region recombinant mouse strain B10.ASR7 (H-2as3), the immune response (Ir) genes for LDH-B and MOPC-173 were genetically and serologically separated, as assayed by T cell proliferation. Previous work demonstrated that H-2s and H-2b strains respond to LDH-B and MOPC-173 whereas H-2a and H-2k strains failed to respond due to haplotype-specific suppression of I-Ak molecule-activated T helper cells by I-Ek molecule-activated T suppressor cells. In the experiments reported here, B10.ASR7 mice, which lack I-Ek expression, mounted a significant T cell proliferative response to LDH-B but not to MOPC-173. Separation of the Ia determinants used in restricting these two antigen responses was further confirmed when pretreatment of B10.S(9R) (A beta sA alpha sE beta sE alpha k) macrophages with A.TL anti-B10.HTT serum (anti-As beta Es beta Js) adsorbed with B10.ASR7 spleen cells blocked the MOPC-173 response but not the LDH-B response. Unadsorbed serum blocked both antigen responses. The B10.ASR7 E beta allele was determined to be s due to the ability of (A.TL X B10.ASR7)F1 hybrids to mount a T cell proliferative response to the terpolymer GLPhe. Monoclonal antibody blocking of the B10.ASR7 T cell proliferative response to LDH-B demonstrated that the Ia.2 and Ia.17, and not the Ia.15 epitopes are spatially related to the Ia epitopes involved in the restriction of the B10.ASR7 LDH-B T cell proliferative response. In addition, B10.ASR7 helper T cells generated in response to LDH-B were suppressed in a haplotype-specific manner by I-Ek molecule-restricted suppressor T cells in that (A.TL X B10.ASR7)F1 hybrids failed to respond to LDH-B. This nonresponsiveness was eliminated by treatment with monoclonal antibodies directed against the I-Ek molecule. These results suggest the possibility that the immune response defect in B10.ASR7 could be related to the site of recombination.     

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.     

The molecular basis of the requirement for antigen processing of pigeon cytochrome c prior to T cell activation

Antigen-induced activation of T lymphocytes that co-recognize Ia molecules has been shown to require an antigen-processing step by the presenting cell before T cell stimulation can occur. In this report, we demonstrate that antigen presentation of pigeon cytochrome c to an E kappa beta:E kappa alpha-restricted T cell hybridoma, 2C2, is inhibited by pretreatment of the antigen-presenting cells (APC) either with chloroquine or with fixation by paraformaldehyde. The chloroquine effect was partially reversible after 22 hr; the paraformaldehyde effect was not. In contrast, these treatments had little or no effect on the presentation of the carboxy-terminal cyanogen bromide cleavage fragment of pigeon cytochrome c, residues 81 to 104. There was at least a 50-fold greater potency of the fragment, as compared to that of the intact molecule, when paraformaldehyde-fixed APC were used. In addition, the fixed cells did not present synthetic fragments of the cytochrome c that were nonstimulatory when presented by unfixed cells. This observation showed that the loss of potency, demonstrated previously for analogs of pigeon cytochrome c with single amino acid substitutions at positions such as 99, was not a consequence of an alteration in the rate of antigen-processing. This result is consistent with our earlier hypothesis that these residues are contact amino acids with the antigen-specific T cell receptor or the Ia molecule. The major goal of these experiments was to define the molecular transition that occurred as a result of antigen processing. To achieve this end, we tested a variety of pigeon cytochrome c molecules and fragments for their ability to be presented by paraformaldehyde-fixed APC. Apocytochrome c, the denatured form of the molecule with the heme removed, could not be presented by the fixed cells, nor could the fragment 60-104, derived by acid cleavage of the tryptophan at position 59. Both molecules stimulated an IL 2 response from the T cell hybridoma when unfixed APC were utilized, demonstrating that the conditions used to prepare these two molecules did not destroy their antigenic determinant. In contrast, carboxy-terminal fragments, both native and synthetic, ranging in size from 16 to 39 amino acids, were capable of stimulating in the presence of paraformaldehyde-fixed APC. In particular, the partial-digest cyanogen bromide fragment, residues 66 to 104, was only twofold less potent than the pigeon fragment 81-104.(ABSTRACT TRUNCATED AT 400 WORDS)     

Antigen/MHC-specific T cells are preferentially exported from the thymus in the presence of their MHC ligand

Transgenic mice expressing a T cell receptor heterodimer specific for a fragment of pigeon cytochrome c plus an MHC class II molecule (I-Ek) have been made. We find that H-2k alpha beta transgenic mice have an overall increase in the number of T cells and express a 10-fold higher fraction of cytochrome c-reactive cells than H-2b mice. Surface staining of thymocytes indicates that in H-2b mice, T cell development is arrested at an intermediate stage of differentiation (CD4+8+, CD310). Analyses of mice carrying these T cell receptor genes and MHC class II I-E alpha constructs indicate that his developmental block can be reversed in H-2b mice by I-E expression on cortical epithelial cells of the thymus. These data suggest that a direct T cell receptor-MHC interaction occurs in the thymus in the absence of nominal antigen and results in the enhanced export of T cells, consistent with the concept of "positive selection".     

Modulation of macrophage Ia-expression by lipopolysaccharide. I. Induction of Ia expression in vivo

Experiments were performed to analyze the modulation of macrophage Ia expression and biosynthesis by Salmonella minnesota-derived lipopolysaccharide (LPS) in vivo. The i.p. injection of LPS into LPS-responder mice caused a dramatic increase in the Ia expression of the peritoneal macrophage population harvested 1 wk after injection. As little as 1 ng of lipid-rich Re595 LPS per mouse caused a significant I-Ak increase, and 1 microgram was optimal; wild-type S. minnesota LPS was less active. No I-Ak induction by LPS was observed in the LPS-nonresponder strain C3H/HeJ. LPS-induced macrophages showed a 6- to 16-fold increase in I-Ak expression by radioimmunoassay (RIA), a 3- to 10-fold increase in the proportion of I-Ak-positive cells, and a 10- to 15-fold increase in I-Ak biosynthetic capacity. The magnitude of this induction by LPS was comparable to increases observed after injection of live Listeria monocytogenes. The kinetics of I-Ak induction by LPS and by L. monocytogenes were different: LPS caused an initial decrease in I-Ak expression 1 day after injection, and I-Ak induction by LPS occurred more slowly and maintained heightened expression longer. Several H-2 gene products (H-2Kk, I-Ak, and I-Ek) were augmented in LPS-induced macrophages. In keeping with increased I-A and I-E expression, LPS-induced macrophages were more effective than normal macrophages in presenting antigen to T lymphocytes. We suggest that the modulation of macrophage Ia expression is one important mechanism contributing to the immunoregulatory activity of LPS.     

The activation of pigeon cytochrome c-specific T cell hybridomas by antigenic peptides is influenced by non-native sequences at the amino terminus of the determinant

We recently demonstrated that the sequence 95-104 contains all the residues necessary for direct recognition of the I-Ek restricted pigeon cytochrome c determinant but that residues located in sequences to the amino-terminal side of residue 95 improve the ability of peptides containing the sequence 95-104 to stimulate Ag-specific T cell clones. In this study we use synthetic peptides with amino-terminal leader sequences containing residues that differ with respect to their conformational stabilizing effects, charge, and hydrophilicity to examine the mechanism by which they modulate T cell recognition. Our findings indicate that the role of these residues in T cell stimulation is not related to their ability to stabilize alpha-helical secondary structure, nor do they appear to be processed differently. The leader sequences do not differentially influence the ability of the peptides to be presented by APC displaying Ia molecules of related haplotype, i.e., E alpha kE beta k, E alpha kE beta b, and E alpha kE beta s, to T cells which recognize the pigeon cytochrome c determinant on such presenting cells. Because antigenic potency correlates with the inclusion of hydrophobic residues and positively charged residues in the leader sequences, we discuss our findings with reference to the possibility that they non-specifically enhance the interaction of the antigenic peptides with the APC membrane.     

Receptor-mediated B cell antigen processing. Increased antigenicity of a globular protein covalently coupled to antibodies specific for B cell surface structures

Helper T cell recognition of globular protein antigens requires the intracellular processing of the native molecule by an antigen-presenting cell and subsequent presentation of a peptide fragment, containing the antigenic determinant, on the cell surface where it is recognized by the specific T cell in conjunction with Ia. B lymphocytes can function as antigen-presenting cells and, when antigen is bound by their surface Ig, are greatly enhanced in this capacity. In this report it is demonstrated that pigeon cytochrome c covalently coupled to antibodies directed toward either B cell surface immunoglobulin, class I or class II are effectively processed and presented by B cells to cytochrome c-specific T cells, requiring up to 1000-fold less cytochrome c as compared with cytochrome c alone or cytochrome c coupled to nonspecific immunoglobulin. The potent activity of the cytochrome c-antibody conjugates appears to be due to the ability of B cells to concentrate the antigen when the process becomes receptor mediated rather than to a signal provided to the B cell by the conjugate binding, because cytochrome c was not more effectively presented in the presence of unconjugated antibodies as compared with cytochrome c alone. Furthermore, the binding of the native antigen to B cell surfaces is not alone sufficient for T cell activation, in that the cytochrome c-antibody conjugates require processing and are major histocompatibility complex restricted. The results presented here indicate that surface immunoglobulin is not unique in its ability to facilitate antigen processing and/or presentation and that Ig, class I and class II are capable of transporting the cytochrome c to a cytoplasmic vesicle where proteolysis occurs yielding the required peptide, minimally of 10 amino acids. Cytochrome c coupled to monovalent fragments of anti-Ig-antibodies was nearly as effectively presented as cytochrome c coupled to bivalent antibodies, indicating that phenomena mediated by bivalent binding, such as patching and capping of the surface Ig, were not required for effective antigen presentation. The cytochrome c-antibody conjugates, which allow antigen processing to be initiated by receptor-mediated endocytosis, may provide the necessary tools to unravel the intracellular processes by which protein antigens are processed and presented by B lymphocytes.     

The T lymphocyte response to cytochrome c. IV. Distinguishable sites on a peptide antigen which affect antigenic strength and memory

The murine T cell proliferative response to the carboxyl terminal cyanogen bromide cleavage fragment 81-104 of pigeon cytochrome c (cyt) has been studied. Two interesting properties of this response have been previously described. First, T cells from B10.A mice primed with pigeon cyt 81-104 show more vigorous proliferation when restimulated with moth cyt 81-103 than when stimulated with pigeon cyt 81-104; that is, the B10.A T cell response to pigeon shows heteroclitic restimulation by moth. Second, T cells primed with the acetimidyl derivative (Am) of pigeon cyt 81-104 did not cross-react with the unmodified cyt fragments, but Am-moth cyt 81-103 still stimulated Am-pigeon cyt 81-104 primed T cells better than the Am-pigeon cyt 81-104 fragment. These results raised the issue of whether the antigenic sites on the fragments responsible for the specificity of T cell priming in vivo differed from the residues that contributed to the heteroclitic response of pigeon (or Am pigeon)-primed T cells to moth cyt c fragments. In this paper, synthetic peptide antigens were tested in order to identify which residues caused the heterocliticity of the moth fragment and which residues were involved in the antigenic differentiation of native and derivatized fragments. The heterocliticity of the T cell response to moth fragment 81-103 was found to be due to the deletion of the penultimate residue (Ala103) from the pigeon fragment. However, the ability to cause heterocliticity was not uniquely a property of this deletion. T cells from animals primed with peptides containing substitutions at positions 100 or 102 were also heteroclitically stimulated by the moth-like antigen. The observation that T cells could not be primed for recognition of the changes in peptide sequence that caused heteroclitic stimulation suggests that T cells do not directly recognize determinants in this region. The antigenically significant site of derivatization for T cell priming was found to be Lys99. Furthermore, substitution of a Gln at position 99 also resulted in elicitation of yet a third set of T cell clones specific for the presence of that residue. That is, the specificity of the primed T cell population was found to be altered by changes at residue-99, but no such alterations in specificity were demonstrable when T cells primed with peptides altered at residue-103, residue-102, or residue-100 were compared. Overall, the results demonstrate that the antigen can be divided into two functionally distinct sites that are in close physical proximity.     

Influence of accessory cell and T cell surface antigens on mitogen-induced IL 2 receptor expression

We have assessed the inhibitory effects of various monoclonal antibodies on the expression of the IL 2 receptor. Anti-LFA-1, but not anti-Ly-2, markedly inhibited the induction of the IL 2 receptor on the Ly-2+ subset. T-depleted spleen cells, L cells, and B lymphoma cells all functioned as potent accessory cells (AC) for the induction of the IL 2 receptor on L3T4+ T cells. Anti-LFA-1 inhibited the induction of the IL 2 receptor irrespective of the type of AC used. Anti-L3T4 only inhibited the induction of IL 2 receptor expression when L cells were the source of AC. The inhibitory capacity of anti-L3T4 was not related to the expression of Ia on the AC population, because the magnitude of inhibition was comparable in cultures containing either Ia+ or Ia- L cells, whereas no inhibition was seen with either Ia+ or Ia-B lymphoma cells. We conclude from these studies that LFA-1 plays a critical role in mitogen-induced activation of both T cell subsets by promoting both T-AC and T-T interactions. Although anti-L3T4 can inhibit T cell activation in the absence of the recognition of Ia, the mechanism of inhibition and the proposed target molecule for L3T4 on the AC or the T cell have not been determined in our studies. A number of different models for the function of this cell surface antigen are discussed.     

Participation of L3T4 in T cell activation in the absence of class II major histocompatibility complex antigens. Inhibition by anti-L3T4 antibodies is a function both of epitope density and mode of presentation of anti-receptor antibody

The recognition of many class II major histocompatibility complex (MHC)-associated antigens by T cells requires the participation of the L3T4 molecule. It has been proposed that this molecule acts to stabilize low affinity binding to antigen in association with MHC and thereby increases the avidity of T cell/antigen interactions. By using antibodies against the T cell antigen receptor (TCR) to activate T cells, thereby circumventing the requirement for antigen presenting cells and MHC-associated antigen, we have been able to study the function of L3T4 in the absence of class II MHC. We have used two monoclonal antibodies, KJ16-133.18 and F23.1, that recognize a determinant encoded by the T cell receptor V beta 8 gene family. These antibodies were used to select two clones of T cells with surface phenotype Thy-1.2+, L3T4+, Lyt-2-, KJ16-133.18+, F23.1+, IA-, IE-. One of these clones (E9.D4) was hapten-specific (anti-ABA + Iak), the other (4.35F2) was alloreactive (anti-Iak). Activation of these clones by antigen, concanavalin A (Con A) or by the F23.1 antibody was studied by assaying the production of interleukin 3 (IL 3). Both soluble and solid phase-coupled F23.1 induced T cell activation in the complete absence of class II MHC, immobilized antibody (either Sepharose-coupled or plastic-adsorbed) being more effective. The induction of IL 3 production by suboptimal doses of either Con A or plastic-adsorbed F23.1 was inhibited by the anti-L3T4 antibody GK1.5, as was the response to F23.1 coupled to Sepharose-4B beads. However, the responses to optimal or superoptimal doses of these stimuli were not inhibited. In contrast, weak responses to non-TCR cross-linking stimuli such as phorbol myristate acetate (PMA) or low concentrations of soluble F23.1 were not inhibited by GK1.5 (the latter response was usually slightly enhanced). These results show that anti-L3T4 antibodies are not inherently inhibitory, but require both ligation and cross-linking of the TCR for their effect. We propose a model whereby L3T4 interacts with the TCR during T cell activation. Anti-L3T4 antibodies sterically hinder the formation of TCR complexes and so prevent activation. However, by increasing the epitope density of the activating ligand, the avidity of the T cell/ligand interaction can be increased sufficiently to prevent this disruption.(ABSTRACT TRUNCATED AT 400 WORDS)