Immunoglobulin-specific T-B cell interaction. I. Presentation of self immunoglobulin determinants by B lymphocytes

The Autophagy Receptor TAX1BP1 (T6BP) improves antigen presentation by MHC-II molecules

CD4⁺ T lymphocytes play a major role in the establishment and maintenance of immunity. They are activated by antigenic peptides derived from extracellular or newly synthesized (endogenous) proteins presented by the MHC-II molecules. The pathways leading to endogenous MHC-II presentation remain poorly characterized. We demonstrate here that the autophagy receptor, T6BP, influences both autophagy-dependent and -independent endogenous presentation of HIV- and HCMV-derived peptides. By studying the immunopeptidome of MHC-II molecules, we show that T6BP affects both the quantity and quality of peptides presented. T6BP silencing induces the mislocalization of the MHC-II-loading compartments and rapid degradation of the invariant chain (CD74) without altering the expression and internalization kinetics of MHC-II molecules. Defining the interactome of T6BP, we identify calnexin as a T6BP partner. We show that the calnexin cytosolic tail is required for this interaction. Remarkably, calnexin silencing replicates the functional consequences of T6BP silencing: decreased CD4⁺ T cell activation and exacerbated CD74 degradation. Altogether, we unravel T6BP as a key player of the MHC-II-restricted endogenous presentation pathway, and we propose one potential mechanism of action.

Somatic mutagenesis in autoimmunity

Our laboratory investigates systemic autoimmune disease in the context of mouse models of systemic lupus erythematosus (SLE). SLE is associated with high titers of serum autoantibodies of the IgG class that are predominantly directed against nuclear antigens, with pathological manifestations that are considered by many to be characteristic of an immune-complex mediated disease. In this review, we focus on the known and potential roles of somatic mutagenesis in SLE. We will argue that anti-nuclear antibodies (ANA) arise predominantly from nonautoreactive B cells that are transformed into autoreactive cells by the process of somatic hypermutation (SHM), which is normally associated with affinity maturation during the germinal center reaction. We will also discuss the role of SHM in creating antigenic peptides in the V region of the B cell receptor (BCR) and its potential to open an avenue of unregulated T cell help to autoreactive B cells. Finally, we will end this review with new experimental evidence suggesting that spontaneous somatic mutagenesis of genes that regulate B cell survival and activation is a rate-limiting causative factor in the development of ANA.

The human G1m1 allotype associates with CD4+ T-cell responsiveness to a highly conserved IgG1 constant region peptide and confers an asparaginyl endopeptidase cleavage site

The human G1m1 allotype comprises two amino acids, D12 and L14, in the CH3 domain of IGHG1. Although the G1m1 allotype is prevalent in human populations, ∼40% of Caucasiods are homozygous for the nG1m1 allotype corresponding to E12 and M14. Peptides derived from the G1m1 region were tested for their ability to induce CD4+ T-cell proliferative responses in vitro. A peptide immediately downstream from the G1m1 sequence was recognized by CD4+ T cells in a large percentage of donors (peptide CH3₁₅₋₂₉). CD4+ T-cell proliferative responses to CH3₁₅₋₂₉ were found at an increased frequency in nG1m1 homozygous donors. Homozygous nG1m1 donors possessing the HLA-DRB1^*07 allele displayed the highest magnitudes of proliferation. CD4+ T cells from donors homozygous for nG1m1 proliferated to G1m1-carrying Fc-fragment proteins, whereas CD4+ T cells from G1m1 homozygous donors did not. The G1m1 sequence creates an enzymatic cleavage site for asparaginyl endopeptidase in vitro. Proteolytic activity at D12 may allow the presentation of the CH3₁₅₋₂₉ peptide, which in turn may result in the establishment of tolerance to this peptide in G1m1-positive donors. Homozygous nG1m1 patients may be more likely to develop CD4+ T-cell-mediated immune responses to therapeutic antibodies carrying the G1m1 allotype.

Cerebrospinal fluid T cell clones from patients with multiple sclerosis: recognition of idiotopes on monoclonal IgG secreted by autologous cerebrospinal fluid B cells

Due to somatic recombination and hypermutation, Ig variable heavy (V(H)) and light (V(L)) regions contain unique immunogenic determinants, idiotopes (Id), which can stimulate T cells. To address the relevance of this in a human disease, monoclonal IgG (mAb)-secreting B cell clones were established from the cerebrospinal fluid (CSF) of two patients with multiple sclerosis (MS). HLA-DR-restricted CD4(+) T cell lines and clones from CSF of both patients specifically recognized autologous CSF mAb. The CSF T cell clones produced IFN-gamma; some also produced TNF-alpha, IL-10 and IL-5. V(H) and V(L) on the monoclonal IgG derived from CSF B cells expressed amino acid replacements due to somatic mutations. A T cell epitope was mapped to a V(H) framework region, where an amino acid replacement was critical for the T cell recognition. The finding of Id-specific T cells and Id-bearing B cells in the CSF indicates that they coexist within the diseased organ, and provide a basis for the study of Id-driven T-B cell collaboration in a human autoimmune disease.

Activation and tolerance in CD4(+) T cells reactive to an immunoglobulin variable region

Antibody diversity creates an immunoregulatory challenge for T cells that must cooperate with B cells, yet discriminate between self and nonself. To examine the consequences of T cell reactions to the B cell receptor (BCR), we generated a transgenic (Tg) line of mice expressing a T cell receptor (TCR) specific for a κ variable region peptide in monoclonal antibody (mAb) 36-71. The κ epitope was originally generated by a pair of somatic mutations that arose naturally during an immune response. By crossing this TCR Tg mouse with mice expressing the κ chain of mAb 36-71, we found that κ-specific T cells were centrally deleted in thymi of progeny that inherited the κTg. Maternally derived κTg antibody also induced central deletion. In marked contrast, adoptive transfer of TCR Tg T cells into κTg recipients resulted in T and B cell activation, lymphadenopathy, splenomegaly, and the production of IgG antichromatin antibodies by day 14. In most recipients, autoantibody levels increased with time, Tg T cells persisted for months, and a state of lupus nephritis developed. Despite this, Tg T cells appeared to be tolerant as assessed by severely diminished proliferative responses to the Vκ peptide. These results reveal the importance of attaining central and peripheral T cell tolerance to BCR V regions. They suggest that nondeletional forms of T tolerance in BCR-reactive T cells may be insufficient to preclude helper activity for chromatin-reactive B cells.

Generalization of single immunological experiences by idiotypically mediated clonal connections

Clonal interactions of B cells by idiotope-specific mutual recognition of their antigen receptors with the participation of T cells were assumed to form a web of unknown density, referred to as the idiotypic network. Although these clonal connections were proposed to fulfill important internal regulatory functions, their biological significance, especially in relation to antigen-induced immune responses, remained a mystery. In view of this, we postulate that the basic function of the idiotypic internal connection between B and T cell antigen receptors is to transform antigen-induced cellular activations, by idiotypic crossreactivity, into the regulation of cell clones with different antigen specificities. This process leads not only to the suppression of major clones but also to the activation of minor ones. The latter activating property may allow the generalization of single antigenic experiences, so that the immune system in its entirety benefits in its battle against environmental microbes. Such idiotypic clonal interactions are particularly effective in early ontogeny. During a short neonatal imprinting period, maternal immunological knowledge in the form of somatically mutated, high-affinity IgG antibodies, acquired through a continuous encounter with external antigens, guides the initial ontogenetic development of the immune system and so exerts long-lasting transgenerational advantageous effects in the offspring.

Negligible class II MHC presentation of B cell receptor-derived peptides by high density resting B cells

Resting B lymphocytes have been credited with inducing T cell tolerance to Ig-derived and monovalent self-Ags that are internalized via the B cell receptor (BCR). These conclusions are predicated upon the assumptions that resting B cells display BCR-associated peptides in class II MHC and that the cells remain quiescent during the course of experimental manipulation. To determine whether resting B cells display BCR-associated epitopes in class II MHC, we devised a sensitive assay that averted potential activation of B cells by Ag and minimized activation by prolonged culture. Ex vivo, Percoll-fractionated B cells expressing a kappa transgene encoding a T cell epitope were cultured with a reactive T cell hybridoma for 12 h. Whereas low density, LPS-activated, and BCR-activated B cells elicited significant IL-2 from the T cell hybridoma, resting high density B cells did not. Parallel results were obtained with normal B cells expressing a second epitope encoded by an endogenous V(H) gene. Anergic B cells, which are uniformly low density, also significantly stimulated the T cell hybridoma. Finally, longer culture periods with normal B cells resulted in a higher degree of B cell activation and significant stimulation of reactive T cell hybridomas. Our results provide evidence that activation of B cells profoundly enhances the processing and presentation of BCR-associated Ags.

A receptor presentation hypothesis for T cell help that recruits autoreactive B cells

To uncover mechanisms that drive spontaneous expansions of autoreactive B cells in systemic lupus erythematosus, we analyzed somatic mutations in variable region genes expressed by a panel of (NZB x SWR)F(1) hybridomas representing a large, spontaneously arising clone with specificity for chromatin. A single mutation within the Jkappa intron that was shared by all members of the lineage indicated that the clone emanated from a single mutated precursor cell and led to the prediction that a somatic mutation producing a functionally decisive amino acid change in the coding region would also be universally shared. Upon cloning and sequencing the corresponding germline V(H) gene, we found that two replacement somatic mutations in FR1 and CDR2 were indeed shared by all seven clone members. Surprisingly, neither mutation influenced Ab binding to chromatin; however, one of them produced a nonconservative amino acid replacement in a mutationally "cold" region of FR1 and created an immunodominant epitope for class II MHC-restricted T cells. The epitope was restricted by IA(q) (SWR), and the SWR MHC locus is associated with systemic lupus erythematosus in (NZB x SWR)F(1) mice. These, and related findings, provoke the hypothesis that autoreactive B cells may be recruited by a "receptor presentation" mechanism involving cognate interactions between T cells and somatically generated V region peptides that are self-presented by B cells.

Central tolerance induction in natural immunoglobulin-allotype-specific T cells

While self toleance is induced to IgG(b)(2a) in Igh(b / b) mice, an anti-IgG(b)(2a) T cell activity emerges in their Igh(a / a) congenic counterparts. This activity is revealed by postnatal transfer of Igh(a / a) T splenocytes into Igh(a / b) F(1), in which total suppression of IgG(2a)(b) expression is established. Here, we sought to determine whether the natural T cell unresponsiveness to IgG(2a)(b) in Igh(b / b) mice involved a central tolerance. Based on the kinetics of postnatal thymic C(gamma2a)(b) gene expression in Igh(b / b) mice, we transplanted thymi from Igh(b / b) donors of diverse ages into tolerogen-free Igh(a / a) nu / nu recipients. The state of T cell tolerance or responsiveness to IgG(2a)(b) in these reconstituted nu / nu hosts was determined by monitoring the capacity of their splenocytes to induce suppression in Igh(a / b) F(1). These experiments demonstrated that: (i) in the Igh(a / a) nu / nu recipients of adult Igh(b / b) thymi, 33 to 65 % T splenocytes were from nu / nu recipient origin, but these peripheral Igh(a / a) T cells were rendered tolerant to IgG(2a)(b) during their differentiation through the adult Igh(b / b) thymi, (ii) circulating IgG(2a)(b) was not a prerequisite for this tolerance induction, (iii) Igh(b / b) thymic epithelium was unable to induce tolerance to IgG(2a)(b) and (iv) IgG(2a)(b)-producing / presenting cells, colonizing the Igh(b / b) thymi, were certainly responsible of full tolerance induction to IgG(2a)(b).

Disruption of T cell tolerance to self-immunoglobulin causes polyclonal B cell stimulation followed by inactivation of responding autoreactive T cells

Scavenger receptor (SR)-specific delivery by maleylation of a ubiquitous self-protein, Ig, to SR-bearing APCs results in self-limiting induction of autoimmune effects in vivo. Immunization with maleyl-Ig breaks T cell tolerance to self-Ig and causes hypergammaglobulinemia, with increases in spleen weight and cellularity. The majority of splenic B cells show an activated phenotype upon maleyl-Ig immunization, leading to large-scale conversion to a CD138+ phenotype and to significant increases in CD138-expressing splenic plasma cells. The polyclonal B cell activation, hypergammaglobulinemia, and autoreactive Ig-specific T cell responses decline over a 2-mo period postimmunization. Following adoptive transfer, T cells from maleyl-Ig-immune mice taken at 2 wk postimmunization can induce hypergammaglobulinemia in the recipients, but those taken at 10 wk postimmunization cannot. Hypergammaglobulinemia in the adoptive transfer recipients is also transient and is followed by an inability to respond to fresh maleyl-Ig immunization, suggesting that the autoreactive Ig-specific T cells are inactivated peripherally following disruption of tolerance. Thus, although autoreactive T cell responses to a ubiquitous self-Ag, Ig, are induced by SR-mediated delivery to professional APCs in vivo resulting in autoimmune pathophysiological effects, they are effectively and rapidly turned off by inactivation of these activated Ig-specific T cells in vivo.

Resting small B cells present endogenous immunoglobulin variable-region determinants to idiotope-specific CD4(+) T cells in vivo

Antigenic determinants localized within the highly diversified V-regions of Ig are called idiotopes (Id). Processed Id-peptides can be presented on MHC class II molecules to CD4(+) T cells. If B cells present their endogenous Id-peptides, T cell activation could occur in the absence of nominal antigen, a potentially important process in T-B cooperation and immune regulation. To test this idea, we used mice made transgenic for a lambda2 L-chain (Id(+) mice). Another transgenic mouse strain expresses TCR transgenes with specificity for the Id (lambda2), presented on MHC class II molecules. When highly purified sorted Id(+) B cells and Id-specific T cells were sequentially injected into MHC syngeneic SCID host, T cell became blastoid, CD69(+) and proliferated. To exclude any role of host APC, MHC incompatible Rag2(- / -) mice (H-2(b)) were used as recipients for the Id(+) B and Id-specific T cells, with similar results. Exposure to extracellular Id(+) immunoglobulin (Ig) was not sufficient for Id priming of B cells in vivo, highlighting the preferential presentation of Id peptides derived from endogenous Ig, by B cells. The results suggest that B cells presenting Id self-peptides generated by V(D)J recombinations or somatic mutations may directly stimulate T cell in vivo in the absence of conventional antigen.

Somatic origin of T-cell epitopes within antibody variable regions: significance to monoclonal therapy and genesis of systemic autoimmune disease

During an immune response, specific antibody variable region genes are diversified by a somatic point mutation process that generates de novo "foreign" V-region sequences. This creates an interesting problem in immune regulation because B cells are highly proficient at self-presenting V-region peptides in the context of class II MHC. Though our studies indicate that the corresponding T-cell repertoire attains a state of tolerance to germline-encoded antibody V-region diversity, it is presently unknown whether the same is true of mutationally generated diversity. On the basis of immunoregulatory considerations, we hypothesize that contact exclusion or tolerance normally precludes T cells from helping B cells via self-presented mutant V-region peptides. The lack of recurrent somatic mutations that create known T-cell epitopes in antibody V regions lends some support to this idea. In contrast, our studies of spontaneously autoreactive B cells in systemic autoimmune disease strongly suggest that precursors of such cells are recruited by T-cell help directed to self-presented mutant idiopeptides. Failures in tolerance or contact exclusion mechanisms may be responsible for this apparently abnormal event. In addition to their importance in immune regulation, somatic mutations or other differences from germline-encoded V-region sequence may be largely responsible for undesirable patient responses to therapeutic monoclonal antibodies. These reactions might be averted or diminished by inducing tolerance in the T-cell repertoire with synthetic peptide correlates of non-germline-encoded V-region sequences in humanized antibodies.

Suppression of Immune Responses by CD8 Cells. II. Qa-1 on Activated B Cells Stimulates CD8 Cell Suppression of T Helper 2 Responses

We have investigated the role of MHC class I products and CD8 T cells in regulating Ab responses using β2-microglobulin deficient (β2m−/−) mice. β2m−/− mice produced stronger IgM and IgG responses than did control β2m+/+ mice to both cellular and viral Ags. These Ab responses could be suppressed by infusion of activated B cells from β2m+/+ mice. Further investigation showed that the β2m-associated molecule on activated B cells that induced CD8 suppression was Qa-1 and that the Th2 component of CD4 cells was most affected by CD8-suppressive activity. Our findings suggest a novel pathway of Th inhibition in which B cell presentation of Qa-1-associated peptides stimulates CD8 suppressive activity.

The T/B cell interaction involved in induction of the mouse IgG2ab suppression is restricted by major histocompatibility complex class I, but not class II molecules

To determine the major histocompatibility complex (MHC) restriction of the T/ B cell interaction involved in a negative regulation of Ig production, we used mouse model of T cell-induced IgG2ab suppression in vivo. Normal or specifically triggered T splenocytes from mice of the Igha haplotype, when neonatally transferred into histocompatible Igha/b heterozygotes, are able to induce a specific and total suppression of the IgG2ab allotype. Nevertheless, only transfer of IgG2ab-primed Igha T splenocytes induces this suppression in Ighb/b homozygous congenic mice in which the whole IgG2a isotype production is inhibited. This suppression is chronically maintained by CD8+ T cells, but can be experimentally reversed. We have established that the suppression induction required a CD4+CD8+ T cell cooperation and operated via the recognition by the involved TCR of C gamma 2ab-derived peptides presented by the target B cells in an MHC haplotype-restricted manner. Here, by using Ighb mice genetically deficient for MHC class I (beta 2-microglobulin%, or beta 2m%) or class II (I-A beta%) molecules, we demonstrate functionally that the suppression induction implicates an MHC class I-, but not class II-restricted interaction. Indeed, the anti-IgG2ab T cells transferred into Ighb H-2b I-A beta% mice carry out the suppression process normally, while in Ighb H-2b beta 2m% recipients, their suppression induction capacity is significantly inhibited. Moreover, the C gamma 2ab 103-118 peptide, identified as the sole C gamma 2ab-derived peptide able to amplify the anti-IgG2ab T cell reactivity in Igha H-2b mice, is also able to stabilize the H-2Db, but not the H-2Kb class I molecules at the surface of RMA-S (TAP2-, H-2b) cells. These results indicate that, despite the CD4+/CD8+ T cell cooperation during the induction phase of suppression only MHC class I molecule expression is required at the surface of IgG2ab+ B cells for suppression establishment.

Ig-specific T cell receptor-transgenic T cells are not deleted in the thymus and are functional in vivo

The mechanisms that induce T cell tolerance to circulating self-proteins are still controversial, and both the deletion and selection of autoreactive T cells have been observed in the thymus of transgenic mouse models. To address the question of the induction of tolerance to circulating self-constituents, a T cell receptor-transgenic mouse specific for the serum protein immunoglobulin (Ig) gamma and (IgG2ab) was generated. The choice of an allotype-specific T cell also allowed the generation of transgenic control mice not expressing the self-antigen. It was found that the transgenic T cells were not deleted in the thymus, did not become tolerant in the periphery, and regulated the function of gamma 2ab-positive B cells as shown by the lack of IgG2ab protein in the serum of the transgenic mice. In spite of this activity in vivo, the transgenic T cells did not proliferate in vitro in response to the allotype-specific peptide. Interestingly, antigen-specific T cell proliferation could be restored if the transgenic mice were previously challenged to induce IgG2ab responses. After this challenge, IgG2ab protein in the serum of the transgenic mice could be partially restored, although still remaining much lower than in control mice. In addition, there was a dramatic increase in serum IgE levels, suggesting that newly generated gamma 2ab-secreting B cells can be induced to switch to IgE in the presence of allotype-specific T cells. These results indicate that Ig-specific T cells may represent a late-acting form of T cell help for the regulation of the IgG2a-to-IgE class switch.

On the maternal transmission of immunity: a 'molecular attention' hypothesis

Maternally-derived antibodies can provide passive protection to their offspring. More subtle phenomena associated with maternal antibodies concern their influence in shaping the immune repertoire and priming the neonatal immune response. These phenomena suggest that maternal antibodies play a role in the education of the neonatal immune system. The educational effects are thought to be mediated by idiotypic interactions among antibodies and B cells in the context of an idiotypic network. This paper proposes that maternal antibodies trigger localized idiotypic network activity that serves to amplify and translate information concerning the molecular shapes of potential antigens. The triggering molecular signals are contained in the binding regions of the antibody molecules. These antibodies form complexes and are taken up by antigen presenting cells or retained by follicular dendritic cells and thereby incorporated into more traditional cellular immune memory mechanisms. This mechanism for maternal transmission of immunity is termed the molecular attention hypothesis and is contrasted to the dynamic memory hypothesis. Experiments are proposed that may help indicate which models are more appropriate and will further our understanding of these intriguing natural phenomena. Finally, analogies are drawn to attention in neural systems.

Intracellular assembly and transport of endogenous peptide-MHC class II complexes

To define the intracellular site of assembly of endogenous peptide-MHC class II complexes, an immunochemical approach was undertaken employing a monoclonal antibody specific for an endogenous peptide-class II complex in combination with subcellular fractionation. Here, we show that newly synthesized MHC class II molecules, upon exit from the Golgi, are delivered into a dense endocytic compartment (MIIC) distinct from late endosomes and lysosomes. Endogenous peptide-class II complexes are initially formed in this compartment and subsequently traffic through late endosomal vesicles prior to cell surface expression. Exogenous antigen delivered via immunoglobulin receptors is targeted to MIIC en route to lysosomes after passing through early and late endosomes. Processing of an endocytosed antigen was observed in this compartment. Our results suggest a specific role for MIIC in the processing of endogenous and exogenous proteins as well as the assembly of peptide-MHC class II complexes.

B cells carrying surrogate receptors in their membranes process and present antigen to specific murine T cells

A palmitate-conjugate derivative of ovalbumin which can be inserted into the membrane of B cells has been prepared. The ability of these cells to act as antigen-presenting cells for specific T lymphocytes obtained from immunized mice was tested. It was found that the conjugates were more efficiently processed and presented than the naive form of the antigen. Palmitate-conjugated antibodies specific to ovalbumin were also inserted into the cell membrane of normal B lymphocytes. These cells were pulsed with the antigen and tested as antigen-presenting cells for T cells obtained from immunized mice. The antibody-decorated B cells presented ovalbumin more efficiently than non-decorated controls. Whether antibody-decorated, antigen-pulsed B cells could prime T cells in vivo was investigated. Some priming activity was found.

Th1 clones that suppress IgG2ab specifically recognize an allopeptide determinant comprising residues 435-451 of gamma 2ab

We have previously reported that gamma 2ab/I-A(d)-specific Th1 clones from BALB/c mice (gamma 2aa, H-2d) mediated a long-lasting, selective suppression of serum IgG2ab levels when transferred to newborn (BALB/c x B10.D2)F1 (gamma 2a/b, H-2d) mice (Bartnes, K. and Hannestad, K. Eur. J. Immunol. 1991. 21: 2365). We here analyze the peptide specificity of hybridomas derived from two suppressive T cell clones. The shortest synthetic peptide with optimal antigenicity comprises gamma 2ab residues 435-451 (Kabat numbering). The determinant core encompasses the gamma 2ab 440-446 (KLRVQKS) sequence which contains an I-A(d) allele-specific motif. Challenge with single amino acid-substituted gamma 2ab 435-447 analogs revealed that residues K440, R442 and K445 which are shared by the autologous and allogeneic gamma 2a, as well as residues Q444 and S446 which represent allogeneic differences, are critical for recognition. We obtained evidence that K440, R442 and Q444 are epitope residues, while K445 and S446 contribute to anchoring of the peptide to I-A(d). Amino acids located outside of the core also influence antigenicity, the most striking effect being a 340-870-fold augmentation of potency when gamma 2ab 437-451 is extended by F436. IgG2ab required processing in order to stimulate the hybridomas. The data support the contention that the Th1 clones specific for Fc of gamma 2ab mediated IgG2ab suppression by cognate interaction with sIgG2ab+ B cells that presented a C gamma 2ab peptide(s) derived from their endogenous Ig on major histocompatibility complex class II. The T cells cross-reacted weakly with peptide 435-451 of the autologous gamma 2aa allotype. This opens the possibility that self-peptides from Ig C regions can target B cells for regulatory interactions with autologous Th cells.

Processing and presentation of idiotypes to MHC-restricted T cells

Among the self antigens, immunoglobulins, and in particular idiotypes, are of special interest because of their extreme sequence heterogeneity and their postulated involvement in regulatory interactions in the immune system. We have therefore studied antigen processing and presentation of variable region peptides, processed idiotypes, to MHC class II molecule-restricted T cells. The immunoglobulin used has been the lambda 2(315) light chain produced by the BALB/c MOPC 315 plasmacytoma (alpha, lambda 2). The minimum length of a stimulatory synthetic idiotypic peptide comprises residues 91-101 of lambda 2(315) and is presented by the I-E(d) molecule to CD4+ T cells. T cell clones with specificity for the 91-101(lambda 2(315))/I-E(d) complex utilize a limited TCR repertoire and are of both Th1 and Th2 type. For presentation, extracellular lambda 2(315) requires endocytosis and processing, as previously described for conventional exogenous antigens. In addition, a B lymphoma cell can process and present its own endogenous lambda 2(315). This was shown by transfecting manipulated lambda 2(315) gene variants into B lymphoma cells, followed by evaluation of the APC function of the transfectants. These studies demonstrated that surface expression or secretion of lambda 2(315) is not necessary for presentation and suggested that the endoplasmic reticulum may be a processing compartment. To extend our findings to naive Id+ B cells and anti-Id T cells, we have generated lambda 2(315)-transgenic as well as TCR-transgenic mice. A model is presented for a T-B cell interaction based on presentation of processed idiotypes.

Truncation variants of peptides isolated from MHC class II molecules suggest sequence motifs

T cells recognize foreign protein antigens in the form of peptide fragments bound tightly to the outer aspect of molecules encoded by the major histocompatibility complex (MHC). Most of the amino-acid differences that distinguish MHC allelic variants line the peptide-binding cleft, and different allelic forms of MHC molecules bind distinct peptides. It has been demonstrated that peptide-binding to MHC class I involves anchor residues in certain positions and that antigenic peptides associated with MHC class I exhibit allele-specific structural motifs. We have previously reported an analysis of MHC class II-associated peptide sequences. Here we extend this analysis and show that certain amino-acid residues occur at particular positions in the sequence of peptides binding to a given MHC class II molecule. These sequence motifs require the amino terminus to be shifted one or two positions to obtain alignment; such shifts occur naturally for a single peptide sequence without qualitatively altering CD4 T-cell recognition.

Igh-1b-specific CD4+CD8- T cell clones of the Th1 subset selectively suppress the Igh-1b allotype in vivo

The demonstration of major histocompatibility complex (MHC)-restricted T helper (Th) cells specific for peptides from the variable (V) regions of syngeneic immunoglobulin (Ig) (idiopeptides) opens the possibility that Th cells regulate B cell functions via idiopeptide-based cognate T-B interactions. As a model for such interactions we investigated the influence of Ig allotype-specific T cells on the differentiation of H-2-syngeneic B cells expressing that particular Ig allotype. We established a BALB/c (H-2d, Iga) CD4+CD8- T cell line and clones of the Th1 subset (interleukin 2+, interleukin 4-, interferon-gamma+, tumor necrosis factor-alpha+) that recognized Igh-1 (IgG2a) of the b allotype (Igh-1b) together with I-Ad. These T cells specifically suppressed surface Igh-1b+ B cells in vitro and in vivo. In 12 out of 15 6-week-old (BALB/c X B10.D2)F1 mice neonatally injected with Igh-1b-specific T cells, the serum Igh-1b concentrations were less than 5% of the levels in the controls. Thus, allotype suppression can be accomplished solely by adoptive transfer of Igh-1b-specific CD4+ T cells. The in vivo suppression was specific for Igh-1b+ B cells as the recipients' levels of Igh-1a and Igh-4b (IgG1b) were unaffected. The V beta 14-specific anti-T cell receptor (TcR) monoclonal antibody 14-2 inhibited activation of hybridomas derived from two of the clones. Collectively the data indicate that suppression resulted from cognate interactions between allopeptide-specific TcR alpha/beta+ T cells and normal unmanipulated B lymphocytes presenting their endogenous Igh-1b in association with MHC class II molecules. The data support the possibility that normal B cells can be suppressed by idiopeptide-specific T cells in vivo.

Presentation of endogenous immunoglobulin determinant to immunoglobulin-recognizing T cell clones by the thymic cells

Using immunoglobulin (Ig)-recognizing T helper clones the expression of Ig peptide/major histocompatibility complex class II complexes derived by the processing of endogeneous Ig molecules in the thymus was demonstrated. It was found that thymic B cells but not "classic" thymic antigen-presenting cells and macrophages represent the major antigen-presenting cell type of determinants of endogenously synthesized surface Ig (Ig kappa-1b) and anti-surface Ig antibodies (IdC3B9). The Ig kappa-1b-presenting activity in the thymus appears relatively late, only after 3 weeks of postnatal life, while in the spleen an efficient presentation of endogenous Ig kappa-1b epitope is observed very early after birth. This difference between thymic and peripheral presentation of endogeneous Ig determinant could be important for understanding the mechanisms of T cell tolerance to self Ig and the role of self Ig in negative and positive selection of T cell repertoire.

Immunoglobulin-specific T-B cell interaction. IV. B cell presentation of idiotypic determinant(s) of monoclonal anti-surface immunoglobulin antibody to idiotope-recognizing helper T clones

Previously, we have demonstrated T-B cell interactions mediated by T cell recognition of immunoglobulin (Ig) peptide/major histocompatibility complex (MHC) class II complexes derived by the B cell processing of endogenously synthesized Ig molecules. In this report Ig-specific T-B cell interaction mediated by B cell presentation of idiotopes (Id) of anti-sIg antibodies to Id-specific T cell clones has been studied in Ig kappa-1-congenic rat strains. A panel of August (RT-1c; Ig kappa-1a) rat T helper clones specific for Id of syngeneic anti-Ig kappa-1b C3B9 monoclonal antibody (mAb) has been developed to study IdC3B9 presentation by Ig kappa-1b-bearing B cells from congenic August.1b (RT-1c; Ig kappa-1b) rats. Five of seven IdC3B9-specific T clones responded even at very low concentrations (100-200 pg/ml) of C3B9 mAb presented by Ig kappa-1b+ B cells. In contrast, the presentation of intact C3B9 mAb by nonspecific antigen-presenting cells (macrophages, Ig kappa-1a+ B cells, etc.) to IdC3B9-specific T cells was of low efficiency. The IdC3B9-specific T cell response to idiotopes of anti-Ig kappa-1b C3B9 mAb was found to be restricted by RT-1B molecule and required the processing of intact C3B9 molecule. IdC3B9 epitope recognized by C31 and C5 clones was mapped to the heavy chain of C3B9 mAb. Thus, B cells are able to present peptides related to the V region of anti-sIg Ab, i.e. Id peptide/MHC class II complexes, to Id-recognizing T cells. IdC3B9-presenting B cells are specifically activated both to proliferation and Ig production upon interaction with IdC3B9-specific T clones. Based on the results of our studies on B cell presentation of Ig epitopes to T cells a hypothetical model of Ig peptide-driven T-B cell interaction has been proposed.

Immunoglobulin-specific T-B cell interaction. III. B cell activation by immunoglobulin-recognizing T cell clones

Immunoglobulin (Ig)-specific T-B cell interactions were studied in the model of T cell recognition of Ig kappa chain Ig kappa-1b allotype in Ig kappa-1-congenic rats. Using Ig kappa-1b-recognizing major histocompatibility complex (MHC)-restricted T helper clones from August rats we have shown that Ig kappa-1b+ B cells from congenic August.1b rats presented Ig kappa-1b epitope of the processed self-synthesized Ig to T clones. This interaction was found to be a bidirectional regulatory event inducing specific MHC-dependent proliferation of both interacting T cell and B cell as well as Ig(Ig kappa-1b) synthesis. Small Ig kappa-1b+ B cells were capable of inducing T clone proliferation and becoming activated in response to the same T clone. Limiting dilution analysis suggested that every tenth cell in Ig kappa-1b+ B cell population is involved in this interaction. The bystander activation of Ig kappa-1a+ B cells by T clones in the presence of irradiated Ig kappa-1b+ spleen cells, if observed, was less than the level of specific Ig kappa-1b+ B cell proliferation. In contrast to a 20-fold increase of Ig(Ig kappa-1b) levels upon stimulation of Ig kappa-1b+/1a+ B cell population from heterozygous (August x August.1b)F1 rats by T clones, a "nonspecific" increase of Ig(Ig kappa-1a) was not observed. This result demonstrates the requirement for direct T-B contact for B cell activation to occur. The data suggest a great functional potency of T-B interactions mediated by T cell recognition of Ig-derived peptide/MHC class II complexes on the B cell surface. The implication of the data for idiotypic regulation enables us to propose the existence of putative idiopeptidic network T-B cell interactions.

Immunoglobulin-specific T-B cell interaction. II. T cell clones recognize the processed form of B cells' own surface immunoglobulin in the context of the major histocompatibility complex class II molecule

In the preceding report (Eur. J. Immunol. 1989. 19: 1677) we have demonstrated that normal B cells, including small B cells, are capable of presenting Ig kappa-1b allotypic determinants of their endogeneously synthesized Ig+ to Ig kappa-1b-immune major histocompatibility complex (MHC) class II-restricted T cells. A panel of Ig kappa-1b allotype-specific T cell clones from August rats has been developed to study further the presentation of self surface Ig by B cells from Ig kappa-1-congeneic August.1b rats. All the clones studied were of the T helper/inducer phenotype (W3/25+,OX8-) and restricted by the RT-1Bc molecule. These clones responded both to the serum IgG(Ig kappa-1b) in the presence of irradiated spleen cells (SC) from August rats and to the Ig kappa-1b-bearing irradiated B cells from August.1b rats. SC presentation of secreted IgG was much less effective than B cell presentation of membrane Ig. Using CNBr cleavage of isolated C kappa (Ig kappa-1b) domain followed by high-performance liquid chromatography fractionation of the derived antigenic peptides, the kappa chain sequence between amino acids 176 and 214 has been identified as the T cell epitope recognized by all T cell clones in association with RT-1Bc. The fragment 176-214 of the Ig kappa-1b allotype differs from that of Ig kappa-1a allotype by three amino acid substitutions at positions 184, 185, 188. T cell recognition of pL kappa-1b(176-214) required no additional processing by the antigen-presenting cell: the efficient presentation of the peptide but not of intact IgG(Ig kappa-1b) by the paraformaldehyde-fixed SC was observed. These data provide clear-cut evidence for an absolute requirement of the processing of Ig molecules for T cell recognition to occur in our experimental system. Although the fixation of B cells from August.1b rats diminished their Ig kappa-1b-presenting ability, fixed Ig kappa-1b+ B cells were still able to induce Ig kappa-1b-specific T cell clone responses. Our results suggest that B cells can express the processed form of self-synthesized surface Ig in addition to intact surface Ig molecules. The former can be recognized by MHC-restricted T cell.