Serologic and functional characterization of a panel of antigen-presenting cell lines expressing mutant I-A class II molecules

HLA associations in fibrotic disease

HLA antigens have been associated with a wide variety of human diseases. In general these associations are not absolute in the way that classical genetic disorders are. Thus although the association between ankylosing spondylitis and HLA-B27 has been known for 11 years we are not able to define a closer genetic marker for the disease or indeed to define the mechanism by which B27 is involved with the disease process. This paper indicates the major disease associations with HLA antigens and compares them with those found in fibrotic disease. Some attempt is made to localize the position in the disease process where HLA might play a role. The aim of studies of HLA associations often includes the identification of at-risk groups in the hope of being able to apply selective preventive measures. Some progress along this path has been made and is outlined.

CD73 and Ly-6A/E distinguish in vivo primed but uncommitted mouse CD4 T cells from type 1 or type 2 effector cells

Primed CD4 T cells may develop into effector T cells such as Th1 and Th2, or remain uncommitted as Th primed precursor (Thpp) cells that can subsequently differentiate into Th1 and Th2 cells. Although mouse Thpp-like cells have also been identified among spleen and particularly lymph node cells, further characterization of these cells has been difficult without a defining cell surface marker. Using Affymetrix GeneChips followed by FACS analysis, we found that in vitro-derived Thpp cells expressed CD73 but not Ly-6A/E, whereas Th1 and Th2 cells showed the reciprocal pattern. CD73+ Ly6A/E- memory CD4 T cells were identified in normal C57BL/6 mice, and the proportion of these cells was highest in lymph nodes, lower in spleens, and lowest in the lungs. These cells produced IL-2 and MIP-1alpha, but much less IL-4 and IFN-gamma than CD73- Ly6A/E+ cells. Similar results were obtained with additional Ly-6.2 mouse strains, but not Ly-6.1 strains. Restimulation of Thpp-like CD73+ Ly-6A/E- cells in Th1- or Th2-polarizing conditions induced differentiation into populations producing mainly IFN-gamma or mainly IL-4, respectively. In contrast, the effector-like CD73- Ly-6A/E+ population was more committed, and continued to produce both IL-4 and IFN-gamma in both conditions. CD73 and Ly-6A/E expression therefore identify a population of Thpp-like cells in C57BL/6 mice and at least some other Ly-6.2 mice.

Perforin and Fas killing by CD8+ T cells limits their cytokine synthesis and proliferation

During an immune response, effector CD8+ T cells can kill infected cells by the perforin-dependent pathway. In comparison to CD4+ T cells, which are major sources of cytokines, normal CD8+ T cells produced less interleukin 2 and interferon gamma, and proliferated less vigorously after antigenic stimulation. Killing of target cells was a major cause of these reduced responses, since perforin-deficient CD8+ T cells showed substantially increased cytokine synthesis and proliferation. Cytotoxicity by the alternate Fas pathway also resulted in self-limitation of CD8+ T cell cytokine synthesis. This relationship between cytotoxicity and cytokine synthesis may regulate CD8+ T function in different phases of an immune response.

Interleukin (IL) 4, in the absence of antigen stimulation, induces an anergy-like state in differentiated CD8+ TC1 cells: loss of IL-2 synthesis and autonomous proliferation but retention of cytotoxicity and synthesis of other cytokines

Naive T cells in the periphery mainly secrete interleukin (IL) 2 upon activation. After stimulation in the presence of appropriate costimulators, both CD4+ and CD8+ T cells differentiate into effector cells secreting distinct T helper (Th) 1- and Th2-like cytokine patterns. Subsequent to differentiation, both CD4+ (Th1 and Th2) and CD8+ (TC1 and TC2) cells are stable and cannot be induced to differentiate into the opposite pattern or revert to the naive cytokine secretion pattern. We now show that IL-4 caused committed TC1 bulk populations or clones to lose the ability to synthesize IL-2. The cells retained the ability to secrete interferon (IFN) gamma, granulocyte/macrophage colony-stimulating factor, and tumor necrosis factor, did not synthesize any Th2 cytokines, and did not alter cell surface marker expression. IL-4 rapidly inhibited IL-2-synthesizing ability in the absence or presence of antigen-presenting cells, thus demonstrating that IL-4 acted directly on TC1 cells. The defect in IL-2 synthesis could not be reversed by subsequent stimulation with potent antigen-presenting cells in the presence of IL-2 and anti-IL-4, or with anti-CD3 plus anti-CD28 antibodies. Both IL-2+ and IL-2- TC1 cells were strongly cytotoxic toward allogeneic but not syngeneic targets. However, IL-2- TC1 cells were unable to proliferate unless exogenous IL-2 was provided. TC1 cells that lose IL-2 synthesis but retain IFN-gamma synthesis and cytotoxicity may be similar to the "anergic" cells induced by stimulation of CD4+ or CD8+ cells in the absence of costimulators. These results suggest that during a mixed type 1/type 2 response in vivo, IL-4 may induce the IL-2+ TC1-->IL-2-TC1 conversion, and thus curtail the expansion of the TC1 response without impairing short-term effector function.

Cytokine-induced differentiation of precursor mouse CD8+ T cells into cytotoxic CD8+ T cells secreting Th1 or Th2 cytokines

Alloantigen-stimulated CD8+ mouse spleen cells, either spontaneously or in the presence of IL-12 or IFN gamma plus anti-IL-4, differentiate into CD8+ T cells secreting a Th1-like cytokine pattern (IL-2 and IFN gamma). IL-4 induced differentiation into CD8+ T cells secreting Th2 cytokines (IL-4, IL-5, IL-6, and IL-10), whereas anti-IFN gamma suppressed the development of CD8+ cells secreting IFN gamma. Clones of IL-4- or IFN gamma-producing CD8+ T cells were relatively stable, as IL-4 or IFN gamma did not cause interconversion of committed CD8+ T cells. Both CD8+ subsets were cytotoxic, failed to provide cognate help for B cell antibody production, and remained CD4-, CD8 alpha+ CD8 beta+. We propose the names TC1 and TC2 for cytotoxic CD8+ T cells secreting Th1-like and Th2-like cytokines, respectively.

Cytolytic T lymphocytes: an overview of their characteristics

Cloned T cells have been useful for assessing the lytic potential of distinct T cell subsets and for determining the relative contribution of different effector mechanism involved in the lytic process. Alloreactive CD8+ murine T cell clones and cloned murine CD4+ TH1 and TH2 T cells reactive with nominal antigen (ovalbumin) lysed nucleated target cells bearing antigen or coated with anti-CD3 monoclonal antibody in a short term 51Cr-release assay. These clones were also evaluated for their ability to lyse efficiently sheep erythrocyte (SRBC) target cells coated with anti-CD3 mAb by a mechanism (presumably involving membrane damage) that does not involve nuclear degradation. Three patterns of lysis were observed: CD8+ and some CD4+ TH2 effector cells lysed efficiently nucleated target cells and anucleated SRBC coated with anti-CD3 mAb. However, CD4+ TH1 (and a few TH2) T cells which lysed nucleated target cells bearing antigen or coated with anti-CD3 mAb did not lyse efficiently the SRBC coated with anti-CD3 mAb. One CD4 bearing TH2 cell failed to lyse efficiently either nucleated target cells or anucleated SRBC coated with anti-CD3 mAb. These results indicate that both TH1 and TH2 clones have lytic capabilities. Furthermore, they suggest that some but not all TH2 murine T cell clones have lytic characteristics similar to those of conventional CD8+ CTL. However, it is not certain how these patterns of lysis of target cells in vitro relates to the capacity of CTL to lyse such target cells in vivo.

Differential regulation of T helper phenotype development by interleukins 4 and 10 in an alpha beta T-cell-receptor transgenic system

To address the mechanisms controlling T helper (Th) phenotype development, we used DO10, a transgenic mouse line that expresses the alpha beta T-cell receptor from an ovalbumin-reactive T hybridoma, as a source of naive T cells that can be stimulated in vitro with ovalbumin peptide presented by defined antigen-presenting cells (APCs). We have examined the role of cytokines and APCs in the regulation of Th phenotype development. Interleukin 4 (IL-4) directs development toward the Th2 phenotype, stimulating IL-4 and silencing IL-2 and interferon gamma production in developing T cells. Splenic APCs direct development toward the Th1 phenotype when endogenous IL-10 is neutralized with anti-IL-10 antibody. The splenic APCs mediating these effects are probably macrophages or dendritic cells and not B cells, since IL-10 is incapable of affecting Th phenotype development when the B-cell hybridoma TA3 is used as the APC. These results suggest that early regulation of IL-4 and IL-10 in a developing immune response and the identity of the initiating APCs are critical in determining the Th phenotype of the developing T cells.

Differential presentation of hepatitis B S-preS(2) particles and peptides by macrophages and B-cell like antigen-presenting cells

Different cell types, including dendritic cells, macrophages and Ia+ B cells, have been described to present soluble antigen (Ag) to T-cell hybridomas. However, it is still not clear whether these different cell types can act as antigen-presenting cells (APC) for complex and insoluble Ag such as viral particles. Using yeast recombinant hepatitis B S-preS(2)-containing particles, T-cell hybridomas were generated and used as a tool to study processing and presentation of antigen. Different types of APC were compared in regard to their capacity to process and present the protein-lipid composed S-preS(2) particles and the thereof derived T-cell epitope containing peptides by different types of APC. While a S-preS(2)-derived T-cell epitope containing peptide, which does not require processing, could be presented both by macrophage and B-cell like APC, the presentation of S-preS(2) particles required the presence of macrophages. The fact that B-cell like APC and macrophages behave differently with regard to the presentation of S-preS(2) particles suggest that the uptake and/or processing of this type of Ag by B-cell like APC and macrophages is different.

Correlation of presentation of insulin with surface I-Ad and A alpha and A beta mRNA expression by cloned B lymphoma hybridoma variants

We investigated the relationship between Ia expression and antigen presentation in cloned B cells, using variants of TA3 antigen presenting cells. Two TA3 subclones were selected as high presenters and 5 as low presenters of insulin to pork insulin/I-Ad restricted T cells. All TA3 subclones express the surface I-Ak, I-Ek, I-Ad and I-Ed Ia antigens characteristic of the parental cell line. However, surface I-Ad levels correlated best with the ability to present insulin, since high presenters express 2- to 4-fold more I-Ad than low presenters. High presenters possess 2- to 4-times more A alpha and A beta Ia mRNA than low presenters and also transcribe these mRNAs 2- to 5-fold faster than most low presenters. Thus, the correlation noted between I-Ad surface density and capacity to present insulin by our panel of TA3 variants is regulated at the level of transcription and not translation of I-Ad specific mRNAs.

Cytoplasmic domain affects membrane expression and function of an Ia molecule

The association of foreign antigen with Ia molecules on the surface of antigen-presenting cells is necessary for the interaction with the clonally distributed antigen receptor on T cells and is therefore critical in the initiation and regulation of immune responses. Ia polypeptides (alpha and beta) are composed of two extracellular domains, a transmembrane domain and a cytoplasmic domain. Although exon-shuffling experiments have demonstrated that antigen associates with the NH2-terminal alpha 1 and beta 1 domains, the roles that the other domains play in Ia function are still poorly understood. The B-hybridoma cell line 2B1 was selected in a series of positive and negative immunoselection steps for a mutation in the Ek alpha polypeptide. It was found to fortuitously contain a mutation in the Ak alpha polypeptide as well. Sequence analysis of the Ak alpha gene showed that a single base transition (C----T) resulted in a stop codon at amino acid residue 222. This caused the loss of 12 amino acids from the cytoplasmic domain of the mature polypeptide. This mutation results in a decreased level of Ak alpha polypeptide expression on the cell surface (50% of wild-type levels), an increased half-life of Ak alpha polypeptide in the cell, and a specific limited defect in antigen presentation.

The role of autoreactive T-cell hybridomas from autoimmune model mice

Autoreactive IL-2-producing T-cell hybridomas were established from New Zealand Black and White (B/W) F1 and MRL/1 mice. In B/WF1 mice the frequency of IL-2-producing hybridomas increased with age. It is necessary for the cells to recognize autologous MHC molecules in order to release IL-2. Inoculation of hybridoma cells into several mouse strains via the footpad produced significant swelling responses in an H-2-restricted manner. Finally, several autoimmune abnormalities were induced in naive H-2-compatible mice by i.v. inoculation of certain hybridoma cells. These results demonstrate that self-MHC molecule recognition by T cells plays an important role in the development of autoimmunity.

Characterization of alloreactive T cell hybridomas

Four T cell hybridoma clones were established and characterized from 250 hybridoma cell lines and characterized. All clones were strongly positive for Thy-1 and H-2 antigens. The Lyt-1 and L3T4 determinants were weakly but significantly positive, whereas I-A antigens and surface immunoglobulin were negative. Three of the clones secreted IL-2 upon stimulation with H-2Kk cells, whereas the remaining clone did not. This IL-2 secretion was stimulated not only by macrophage-dendritic cells, but also by B cells. All clones produced significant footpad swelling following injection into the footpads of H-2k mice. The time course and histology of the footpad swelling suggested that the reaction might be a delayed type hypersensitivity (DTH)-like response.

Asialo GM1 as an accessory molecule determining the function and reactivity of cytotoxic T lymphocytes

The expression and function of asialo-GM1 (AsGM1) in alloreactive cytotoxic T lymphocytes (CTL) was studied. We have shown previously that the cytotoxic reactions mediated by AsGM1+-cloned CTL were blocked by anti-AsGM1 or by purified AsGM1. To further determine the role of AsGM1 in CTL-mediated cytotoxicity, we examined the correlation between this blocking effect and the expression of AsGM1 on effector and target cells. Now we found that the blocking by anti-AsGM1 was largely dependent on the expression of AsGM1 on the effector cells in a dose-dependent fashion. The expression of AsGM1 on target cells had only little effect on the blocking of cytotoxic reactions by anti-AsGM1 or AsGM1. A threefold difference was seen in the blocking of AsGM1+ and AsGM1- targets. The observation was in sharp contrast to the effectors as no blocking was ever seen with AsGM1- CTL. Similar to CTL effectors, we found that the expression of AsGM1 and L3T4 were mutually excluded on mitogen-activated T cells, despite the fact that they could coexpress in resting T cells. The expression of AsGM1 on CTL effectors was associated with the antigen-nonspecific natural killer (NK)-like or lymphokine-activated killer (LAK)-like activity exerted by the alloreactive CTL. All AsGM1+ CTL possessed LAK activity against antigen-unrelated tumor targets, and the AsGM1- CTL only displayed antigen-specific alloreactivity. The LAK activity was associated with the expression of AsGM1 on effectors, and was not related to the AsGM1 expression on target cells. These findings indicate that the AsGM1 expressed on alloreactive CTL may function as an accessory molecule for T-cell receptors in the antigen-specific alloreactive cytotoxicity mediated by AsGM1+ CTL. The expression of AsGM1 may also be related to the activation of an NK-like apparatus in these CTL. Therefore, AsGM1 not only may be involved in cytotoxic reactions mediated by AsGM1+ CTL, it may also modulate the specificity of the CTL cytotoxicity.

Structural mutation affecting intracellular transport and cell surface expression of murine class II molecules

We have selected Ia variants from the Ia+ (H-2d) M12.4.1 B cell lymphoma that are negative on the cell surface for one or both Ia isotypes. The molecular analysis of two such independently selected cell lines, M12.A2 and M12.C3, is reported here. This analysis revealed that the genes encoding Ad beta (M12.A2) and Ed beta (M12.C3) contained identical single-nucleotide transitions that resulted in the substitution of Ser (mutant) for Asn (wild-type) at residue 82/83 of the extracellular NH2-terminal (membrane distal) beta 1 domain. This conservative substitution caused a cytoplasmic accumulation of I-A or I-E molecules in the respective cell line although predicted secondary-structure analysis suggests a minimal effect on protein conformation. Thus, the mutation appears to have either created a negative signal that stops transport or eliminated a positive signal that is required for transport and targeting to the cell surface.

Functional diversity of Ia epitopes on macrophages

A panel of monoclonal antibodies directed against various epitopes of mouse Iak was used to block functions mediated by Iak on CBA/J macrophages in two different assay systems. The first system was the recently described proliferation inhibition of an H-2k T cell clone (8.1.11.2) by a combination of CBA/J (nonactivated) macrophages and anti-Iak (Kedar, I. et al. J. Immunol. 1986. 136: 3166). The second system was the well known macrophage cytotoxicity induced by interferon against various transformed cells. We found that anti-Iak antibodies directed against serological specificity number 2 (on the alpha chain of IA) blocked the proliferative stimulus of the macrophage Iak for the 8.1.11.2 T cell clone. Both an IgG and an IgM antibody with this specificity were effective, whereas seven other anti-Iak (including several for other specificities on the alpha chain of IA) were not. Conversely, two different monoclonal anti-Iak antibodies directed against serological specificity number 17 (on the beta chain of IA) inhibited the cytolytic activity of the activated macrophages for the 8.1.11.2 T cell clone as well as the P815 (H-2d) mastocytoma as target, whereas four other antibodies were ineffective in this regard. In addition to providing evidence that Ia may participate in the cytolytic activity of activated macrophages, these studies demonstrate that different epitopes of Iak on macrophages are differentially involved in different biological functions.

A single base mutation in an I-A alpha-chain gene alters T-cell recognition

The interaction between the clonally selected T-cell antigen receptor, antigen, and Ia molecule is poorly understood at the molecular level. A cell line bearing an altered I-Ak alpha-chain (Ak alpha) molecule has been examined in order to provide more information about the relationship between Ia structure and function. The cell line, 3J9, was derived from the TA3 B-cell hybridoma through a series of negative and positive immunoselection steps. The 3J9 mutant lacked the binding site recognized by the Ak alpha-specific monoclonal antibody 39J and failed to present antigen to two T-cell hybridomas out of a large panel of I-Ak-restricted T-cell hybridomas examined. Sequence analysis of the mutant Ak alpha gene showed a single base transition (G----A) that resulted in a glutamic acid to lysine substitution at amino acid 75 of the alpha 1 domain. This mutation confirms the importance of amino acid 75 in the expression of the Ia.19 epitope, demonstrates the involvement of this region in the presentation of antigen to specific T cells, and provides a further example of the multiple functional domains on the Ia molecule that are involved in antigen presentation.

Mutations of class II MHC molecules

It remains unclear how the tertiary interaction of T-cell receptor, la molecule and foreign antigen results in the extensive diversity of the helper T cell repertoire. Here Laurie Glimcher and Irwin Griffith focus on what has been learned about the relationship between structure and function of the la molecule from the use of mouse strains with mutations in the genes coding for these glycoproteins.

Cell receptors for the mammalian reovirus: reovirus-specific T-cell hybridomas can become persistently infected and undergo autoimmune stimulation

We have previously described the development of virus-specific helper T cell hybridomas which recognize structural determinants shared by type 1 and type 3 reoviruses that have been exposed to UV radiation. We have found that T-cell hybridomas become persistently infected with live type 3 reovirus used for the immunization. Persistently infected T-hybridoma cells were found to spontaneously produce interleukin 2 (IL-2). To analyze the mechanism of induction of IL-2 secretion of persistently infected T-cell hybridomas, we exposed T-cell hybridomas specific for UV-treated virus to replicating type 3 reovirus. The T-cell hybridomas became infected but did not produce IL-2 unless simultaneously exposed to syngeneic I-A+ antigen-presenting cells. In this situation, the persistently infected T-cell hybridomas produced IL-2 without being reexposed to virus. This process was not a consequence of nonspecific IL-2 gene activation, which occurs in cells persistently infected with reovirus, because reovirus infection did not activate IL-2 secretion in T-cell hybridomas with other antigenic specificities. Reovirus exposure also resulted in persistent infection of certain antigen-presenting B-cell tumor lines. The persistently infected B-cell tumor lines could stimulate reovirus-specific helper T cells but not T-cell hybridomas of other specificities. The data support the thesis that persistent infection of reovirus-specific T cells creates a mechanism in which the virus released from these cells is processed and then reexpressed by I-A+ antigen-presenting cells. The IA antigen and reovirus structures on the antigen-presenting cells then restimulate the T cells through their specific receptors, resulting in IL-2 synthesis and release. These observations may be relevant to mechanisms of autoimmunity induced by virus.

I-A-restricted T cell antigen recognition. Analysis of the roles of A alpha and A beta using DNA-mediated gene transfer

The contributions of A alpha and A beta chains, and of subregions of A beta, to Ia-restricted recognition of antigen by Th lymphocytes were analyzed using a panel of L cells transfected with various pairs of A alpha b,d, or k genes and recombinant or wild-type A beta b,d, or k genes. The A beta genes included all possible exchanges of the whole NH2-terminal (beta 1) domain or halves of the beta 1 domain among these three allelic A beta genes. The Ia+ L cells derived from such transfections were used as antigen-presenting cells with a 21 member panel of responding Ia-restricted T hybridoma cells of differing nominal antigen specificity and Ia-restriction. Special care was taken to account for quantitative variation in levels of Ia expression throughout the experiments. The results of this analysis reveal that (a) only 2 of the 21 Th cells recognized Ia molecules involving either a nonparental A alpha or a nonparental A beta chain, and in both cases the degeneracy extended to only one of the two other alleles tested. This suggests that allele specific contributions from both A alpha and A beta chains are important in restricted recognition for most, if not all I-A-restricted Th cells. (b) In no case did substitution of the A beta 2 domain from either of the alternative haplotypes lead to any functionally detectable effects, demonstrating that polymorphisms in the A beta 1 domain can entirely account for the restriction imposed on Th cell responses by the entire A beta chain. (c) For 90% of the cells tested, replacement of the NH2-terminal portion of the beta 1 domain with an allogeneic segment led to Ia molecules unable to elicit Th responses. Furthermore, of all the cells permissive of the substitution of one or other half of the beta 1 domain, only two permitted the substitution of sequence from both alternative haplotypes. Taken together, these data strongly suggest that antigen recognition by most, if not all, I-A-restricted Th cells involves contributions from both halves of the A beta 1 domain. These data suggest that the role of I-A molecules in restricted Th cell recognition of antigen depends on conformational determinants unique to a particular combination of polymorphic alpha and beta chains, and that multiple such sites exist on a single Ia molecule.(ABSTRACT TRUNCATED AT 400 WORDS)

Identification of functional regions on the I-Ab molecule by site-directed mutagenesis

Functional analysis of mutant class II major histocompatibility complex molecules has begun to identify regions important for antibody binding and for T-cell activation. By using in vitro mutagenesis directed at the beta 1 domain of the Ab beta gene we have constructed three structurally distinct mutant Ab beta genes. Each of these genes, as well as the wild-type Ab beta gene, was cotransfected together with the wild-type Ab alpha gene into the Ia-negative B-lymphoma cell line M12.C3. Transfection resulted in the successful synthesis and cell surface expression of three mutant class II antigens that showed serological and functional alterations as compared to the I-Ab antigens from the M12.C3 cell transfected with the wild-type gene. The variable patterns of both I-Ab-specific monoclonal antibody binding and activation of I-Ab-specific T-cell hybridomas show that the mutations result in the loss of structural epitopes required for both monoclonal antibody binding and for T-cell recognition. The data suggest that there are multiple sites on a single Ia molecule that are recognized by T helper cells and also that the tertiary conformation of the Ia molecule can be critical in the formation of such sites.

T-cell recognition of Ia molecules selectively altered by a single amino acid substitution

T lymphocytes recognize foreign antigen together with allele-specific determinants on membrane-bound class I and class II (Ia) gene products of the major histocompatibility complex. To identify amino acids of class II molecules critical to this recognition process, the genes encoding the beta chains of the I-Ak molecule were cloned from a wild-type B-cell hybridoma and from an immunoselected variant subline showing distinct serological and T-cell stimulatory properties. Nucleotide sequencing and DNA-mediated gene transfer established that a single base transition (G----A) encoding a change from glutamic acid to lysine at position 67 in the I-Ak beta molecule accounted for all the observed phenotypic changes of the variant cells. These results confirm the importance of residues 62 to 78 in the amino terminal domain of I-A beta for class II-restricted T-cell recognition of antigen and demonstrate the ability of a single substitution in this region to alter this recognition event.

Direct evidence that a class II molecule and a simple globular protein generate multiple determinants

We have examined the individual contributions of the I-A kappa alpha chain, the I-A kappa beta chain, and the foreign antigen hen egg-white lysozyme (HEL) in the formation of the determinant being recognized by the T cell receptor. As functional probes we have used (a) a panel of 10 HEL-specific T cell hybridomas, (b) a panel of antigen-presenting cells (APC) possessing mutations in either the I-A kappa alpha or I-A kappa beta chains, and (c) proteolytic fragment of HEL and related synthetic peptides. The ability of the I-A kappa beta and I-A kappa alpha mutant cell lines to present antigen to the 10 T cell hybridomas divided these T cells into six distinct groups. These HEL-specific T cells therefore appear to recognize several distinct domains on the I-A kappa molecule. The 10 T cell hybrids were then shown to recognize at least three distinct determinants on the HEL molecule, with 8 of the 10 hybrids recognizing one of two major determinants HEL(46-61) or HEL(34-45). Combining the response patterns to the panel of I-A kappa mutant APC lines with the antigen specificity revealed that the 10 T cell hybrids recognized at least eight unique determinants formed by the I-A kappa alpha chains, I-A kappa beta chains, and HEL peptides. This analysis provides direct evidence that a large number of different determinants or T cell receptor ligands can be generated from a single Ia molecule and a simple globular protein.

Expression of the T-cell-specific gamma gene is unnecessary in T cells recognizing class II MHC determinants

Subtractive complementary DNA cloning combined with partial protein sequencing has allowed identification of the genes encoding the alpha and beta subunits of T-cell receptors. The subtractive cDNA library prepared from the cytotoxic T lymphocyte (Tc) clone 2C has been found to contain a third type of clone encoding the gamma chain. The gamma gene shares several features with the alpha and beta genes: (1) assembly from gene segments resembling immunoglobulin V, J and C (respectively variable, joining and constant region) DNA segments; (2) rearrangement and expression in T cells and not in B cells; (3) sequences reminiscent of transmembrane and intracytoplasmic regions of integral membrane proteins; (4) a cysteine residue at the position expected for an interchain disulphide bond. The alpha and beta genes are expressed at equivalent levels in both Tc cells and helper T cells (TH). The gamma gene, obtained from 2C, has been found to be expressed in all Tc cells studied. Here we present evidence that strongly suggests that TH cells do not require gamma gene expression.

An Ia-positive mouse T-cell clone is functional in presenting antigen to other T cells

In this report we present data demonstrating the endogenous expression of I-region associated (Ia) antigens on a cloned line of mouse T cells, CTLL, as well as transcription of the invariant chain gene in these cells. We demonstrate further that this Ia-bearing T-cell clone, CTLL, can utilize the expressed Ia molecules to present antigen to Ia-restricted antigen-specific T cells.

Antigen presentation by hapten-specific B lymphocytes. I. Role of surface immunoglobulin receptors

The present study examines the ability of hapten-specific murine splenic B lymphocytes to present hapten-proteins to carrier-specific T cell hybridomas. BALB/cB cells specific for 2,4,6-trinitrophenyl (TNP) were isolated from spleens of immune mice by elution from TNP-gelatin-coated dishes. Such cells presented the TNP-modified terpolymer, GL phi, at concentrations as low as 0.1 microgram/ml, to a GL phi-specific, I-Ed-restricted, interleukin 2-producing T cell hybridoma. In contrast, the same B lymphocytes required 1,000-fold higher concentrations of unmodified GL phi to stimulate the same T cell hybridoma. The presentation of low concentrations of TNP-GL phi by TNP-specific B lymphocytes was significantly or completely blocked by anti-Ig antibody or TNP-proteins, indicating that surface Ig receptors were critically involved in this phenomenon. Finally, binding of TNP-proteins did not alter the ability of the B cells to present unrelated, unhaptenated proteins or to stimulate alloreactive T cells. These results suggest that surface Ig receptors serve to focus antigens onto specific B lymphocytes and that such cells are highly efficient at presenting linked antigenic determinants to T cells. The implications of these findings for the mechanisms of physiologic, histocompatibility-restricted T-B collaboration are discussed.

Efficiency of antigen presentation to T cell clones by (B cell X B cell lymphoma) hybridomas correlates quantitatively with cell surface ia antigen expression

A series of B cell hybridomas was used as a model system to assess quantitatively the role of Ia molecules in antigen presentation to allo- or soluble antigen-reactive T cell clones. These hybrid cell lines were established by fusion between the HGPRT-BALB/c B cell lymphoma M12.4.1 and LPS-stimulated spleen blasts from B10.BR (H-2k) mice. Quantitative cellular absorption of appropriate anti-Ia monoclonal antibodies and flow cytofluorometric analyses revealed that the B cell hybridomas examined herein expressed constitutively a number of surface I-Ak or I-Ek molecules that varied in an order of magnitude of 1 to 5. Such quantitative differences could be correlated precisely with (a) the capacity of B cell hybridomas to activate T cell clones to proliferate and/or to produce interleukin 2 in response to E beta k allodeterminant or to poly(Glu60Ala30Tyr10) presented in the context of I-Ak restriction element, and (b) the amount of monoclonal anti-I-Ak antibody required to inhibit antigen presentation to T cell clones. The possible implications of these data are discussed in the context of current models of regulation of Ia antigen expression by antigen-presenting cells.