Receptor editing in self-reactive bone marrow B cells

A central paradigm of immunology is clonal selection: lymphocytes displaying clonally distributed antigen receptors are generated and subsequently selected by antigen for growth or elimination. Here we show that in mice transgenic for anti-H-2Kk,b antibody genes, in which a homogeneous clone of developing B cells can be analyzed for the outcome of autoantigen encounter, surface immunoglobulin M+/idiotype+ immature B cells binding to self-antigens in the bone marrow are induced to alter the specificity of their antigen receptors. Transgenic bone marrow B cells encountering membrane-bound Kb or Kk proteins modify their receptors by expressing the V(D)J recombinase activator genes and assembling endogenously encoded immunoglobulin light chain variable genes. This (auto)antigen-directed change in the specificity of newly generated lymphocytes is termed receptor editing.     

Antibody response of murine B1 cells to hen eggwhite lysozyme

Cell transfer studies were performed to investigate the ability of murine peritoneal B1 cells to produce specific IgG antibody against the T-dependent protein antigen, hen eggwhite lysozyme (HEL). Peritoneal cells (PeC) from normal BALB/c mice were transferred into newborn, allotype-congenic, C.B-17 severe combined immunodeficient (SCID) mice alone or together with splenic T cells from HEL-primed C.B-17 mice. After immunization with HEL, only those mice that received both PeC and primed T cells produced HEL-specific IgG of the PeC donor allotype. To identify the B cell subset responsible for antibody production, PeC were sorted before transfer into B1 and conventional B (B2) cell populations. It was found that transfer of purified B1 cells plus primed T cells resulted in high levels of IgG1 anti-HEL in approximately half of the SCID recipients, while mice receiving B2 cells produced little detectable antibody. The responses consisted primarily of IgG1 kappa anti-HEL, with no significant IgM or lambda-bearing components. Seventeen HEL-specific hybridomas of BALB/c origin, i.e., derived from the B1 cell donor, were obtained from reconstituted SCID mice after various periods of immunization and analyzed for fine specificity using a panel of avian lysozymes. All but one of the B1 cell-derived mAbs recognized an HEL epitope not present on the closely related bobwhite quail lysozyme (differing from HEL at only 4 of 129 amino acid positions). While IEF analyses demonstrated the presence of extensive clonotypic diversity, the epitope specificity pattern, which is rare among B2-cell-derived antibodies, suggests that the B1 cell recognition repertoire for HEL is severely limited.     

The Epstein-Barr virus thymidine kinase does not phosphorylate ganciclovir or acyclovir and demonstrates a narrow substrate specificity compared to the herpes simplex virus type 1 thymidine kinase

The Epstein-Barr virus (EBV) thymidine kinase (TK) was expressed in mammalian 143B TK- cells to investigate its substrate specificity. The herpes simplex virus type 1 (HSV-1) TK was similarly expressed for comparison. Both viral TKs conferred a TK+ phenotype on 143B TK- cells. The nucleoside analog ganciclovir (GCV) did not affect the growth of 143B EBV TK or 143B TK- cells but effectively killed 143B HSV-1 TK cells. Furthermore, lysates of 143B EBV TK cells could not phosphorylate GCV, which was confirmed by high-performance liquid chromatography. EBV TK, HSV-1 TK, and EBV TK N-, a truncated EBV TK missing 243 N-terminal amino acids, were purified as fusion proteins expressed in bacteria, and all had TK activity. In addition, EBV TK was observed to have a thymidylate kinase activity but could not phosphorylate GCV, acyclovir, or 2'-deoxycytidine. In competition assays, only nucleoside analogs of thymidine significantly inhibited thymidine phosphorylation by EBV TK, with the following rank order: 5-bromodeoxyuridine > zidovudine > stavudine > sorivudine. These results demonstrate that EBV TK substrate specificity is narrower than those of alphaherpesvirus TKs and that thymidine analogs may be the most suitable nucleoside antivirals to target the enzyme. Clinical implications for gammaherpesviruses are discussed.     

T cells within germinal centers are specific for the immunizing antigen

A normal antibody response to T cell-dependent Ag requires physical contact between Ag-specific B and T cells. Because such Ag-specific cells are rare in vivo, we sought to identify an in vivo site where they physically contact each other. We examined the Ag specificity of T cells in germinal centers (GC) in lymph nodes, where it is known that Ag-specific B cells proliferate and mature. We investigated the Ag specificity of GC T cells in situ by examining two characteristics: 1) expression of certain V alpha and V beta TCR families; and 2) incorporation of bromodeoxyuridine into T cell DNA after exposure to Ag as an index of Ag-induced proliferation. When GC were induced in mice with cytochrome c and myelin basic protein, the GC T cells were found to preferentially express V alpha 11 and V beta 8 TCR families, which are, respectively, the dominant TCR families in these two responses. Furthermore, GC T cells have proliferated upon exposure to the Ag that induced GC formation. Taken together, these results demonstrate that GC must recruit and retain Ag-specific T cells, thus implicating the GC as an in vivo site where Ag-specific T and B cells interact.     

Rapid elimination of mature autoreactive B cells demonstrated by Cre-induced change in B cell antigen receptor specificity in vivo

Developing autoreactive B cells edit their B cell antigen receptor (BCR) in the bone marrow and are clonally deleted when they fail to reexpress an innocent BCR. Here, inducible Cre-loxP-mediated gene inversion is used to change the specificity of the BCR on mature IgM+ IgD+ B cells in vivo to address the fate of lymphocytes encountering self-antigens at this developmental stage. Expression of an autoreactive BCR on mature B cells leads to their rapid elimination from the periphery, a process that is inhibited by constitutive bcl-2 transgene expression in an antigen dose-dependent manner. Thus, selection of mature B cells into the long-lived peripheral pool does not prevent their deletion upon encounter of self-antigens.     

Clonal selection and learning in the antibody system

Each antibody-producing B cell makes antibodies of unique specificity, reflecting a series of ordered gene rearrangements which must be successfully performed if the cell is to survive. A second selection process occurs during immune responses in which a new antibody repertoire is generated through somatic hypermutation. Here only mutants binding antigen with high affinity survive to become memory cells. Cells expressing autoreactive receptors are counter-selected at both stages. This stringent positive and negative selection allows the generation and diversification of cells while rigorously controlling their specificity.     

Analysis of human T cell and B cell responses against U small nuclear ribonucleoprotein 70-kd, B, and D polypeptides among patients with systemic lupus erythematosus and mixed connective tissue disease

OBJECTIVE: To analyze T and B cell reactivity with U small nuclear RNP (snRNP) 70-kd, B, and D polypeptides among patients with connective tissue disease (CTD) and to examine the functional characteristics of snRNP-reactive T cell clones. METHODS: We used an snRNP enzyme-linked immunosorbent assay and immunoblotting to characterize antibodies in patients' sera. We used human recombinant fusion proteins 70 kd, B, and D to stimulate and clone snRNP-reactive T cells from CTD patients. We analyzed the cell surface phenotype, antigenic specificity, and cytokine profiles of T cell clones. RESULTS: Patients showed T cell responsiveness to snRNP polypeptides that paralleled their autoantibody reactivities. A total of 256 clones were generated, and clones were identified which were specific for the 70-kd, B, or D polypeptides. Clones expressed a T helper cell phenotype, and were found to produce substantial quantities of both interleukin-4 (IL-4) and interferon-gamma, and lesser quantities of IL-2 and IL-6. CONCLUSION: These results show that CTD patients have clonable circulating snRNP-reactive T cells that parallel the specificity of snRNP-reactive antibodies in their sera. The snRNP-reactive T cells exhibit a helper cell phenotype and produce cytokines which are important in B cell help and differentiation.     

Persistence of functionally compromised anti-double-stranded DNA B cells in the periphery of non-autoimmune mice

Both anti-single-stranded (ss) and anti-double-stranded (ds) DNA antibodies are associated with the autoimmune disease systemic lupus erythematosus (SLE), but only anti-dsDNA antibodies are considered one of the diagnostic criteria. Using Ig transgenes coding for anti-DNA we have determined the fate of anti-dsDNA B cells in a non-autoimmune environment. In a Rag-2 wild-type background, B cells expressing the anti-dsDNA Ig transgenes are present in the spleen but dsDNA specificity is disrupted due to expression of endogenous L chains. In a Rag-2-deficient background where co-expression of endogenous Ig is blocked, splenic B cells expressing only the anti-dsDNA transgene Ig are present, indicating that endogenous Ig expression is not required for bone marrow export. The anti-dsDNA B cells that persist are profoundly crippled in that they are unable to proliferate to lipopolysaccharide or anti-Ig stimulation. Furthermore, these anti-dsDNA Ig transgene B cells show a decreased lifespan relative to non-transgene BALB/c B cells. Persistence of anti-dsDNA B cells in the periphery of non-autoimmune mice raises the possibility that their appearance in the context of SLE is due to their reactivation by T cell help.     

V(D)J recombinase activity in a subset of germinal center B lymphocytes

Reexpression of the V(D)J recombinase-activating genes RAG1 and RAG2 in germinal center B cells creates the potential for immunoglobulin gene rearrangement and the generation of new antigen receptor specificities. Intermediate products of V(D)J recombination are abundant in a subset of germinal center B cells, demonstrating that the kappa immunoglobulin light-chain locus becomes a substrate for renewed V(D)J recombinase activity. This recombinationally active cell compartment contains many heavy-chain VDJ rearrangements that encode low-affinity or nonfunctional antibody. In germinal centers, secondary V(D)J recombination may be induced by diminished binding to antigen ligands, thereby limiting abrupt changes in receptor specificity to B cells that are usually eliminated from the germinal center reaction. This restriction preserves efficient antigen-driven selection in germinal centers while allowing for saltations in the somatic evolution of B cells.     

T cell targeting of TAG72+ tumor cells by a chimeric receptor with antibody-like specificity for a carbohydrate epitope

BACKGROUND & AIMS: Chimeric receptors with specificity for defined tumor antigens are valuable tools for targeting cytolytic T cells specifically to tumor cells. The aim of this study, for the situation of gastrointestinal cancer, was to investigate the generation of a chimeric T cell receptor that specifically binds the tumor antigen TAG72 (CA72-4) and transmits a signal for cellular activation. METHODS: A single-chain antibody (scFv) was derived from the monoclonal anti-TAG72 antibody B72.3 by phage display techniques (B72.3-scFv) and fused to the signaling unit of the Fc epsilon-RI receptor gamma chain, resulting in a chimeric signaling receptor, B72.3-scFv-gamma. RESULTS: The B72.3-scFv and the chimeric B72.3-scFv-gamma receptor bound specifically to the TAG72 antigen. After transfection, T cells expressing the chimeric B72.3-scFv-gamma specifically recognized TAG72 positive cells. Cross-linking of the chimeric receptor with antigen resulted in interleukin 2 release and cytolytic activity against TAG72 positive tumor cells in vitro. CONCLUSIONS: T cells equipped with the chimeric anti-TAG72 receptor can be specifically activated to target and lyse TAG72 positive gastrointestinal tumor cells.     

Deletion and editing of B cells that express antibodies to DNA

We previously demonstrated that in mice transgenic for genes coding for an anti-ssDNA autoantibody B cells were functionally inactivated but not physically deleted. We have now extended this model by introducing an arginine into the CDR2 of the heavy chain transgene. This change alters the specificity of the Ab from anti-ssDNA to anti-dsDNA and increases the affinity for ssDNA. Mice carrying this transgene displayed a significant reduction of peripheral B cells and anti-dsDNA B cells were not recovered from the spleens. The remaining B cells escape deletion by revising their Ag receptors in several ways: 1) elimination of the transgenic heavy chain gene via intrachromosomal recombination, followed by rearrangement and expression of endogenous VH genes; 2) ongoing rearrangement of endogenous kappa light chain genes to generate a non-dsDNA-binding Ab; and 3) expression of a rare V lambda gene, V lambda x, to generate a non-DNA-binding Ab.     

Accumulation of somatic hypermutation and antigen-driven selection in rapidly cycling surface Ig+ germinal center (GC) B cells which occupy GC at a high frequency during the primary anti-hapten response in mice

Well-developed germinal centers (GC) contain rapidly dividing surface immunoglobulin-negative (sIg-) B cells (centroblasts), and most of their progeny are sIg+ B cells (centrocytes) in a resting state. It has been predicted that somatic hypermutation occurs in centroblasts, whereas antigen-driven selection takes place in centrocytes. The present analysis indicates that murine GC B cells bearing sIg with specificity for an immunizing antigen are in a rapidly cycling state and increase exponentially in number to occupy spleen GC at high frequency during the 1st week after primary immunization; however, the number of these cells is significantly reduced in the 2nd week of immunization. During that period, these proliferating sIg+ GC B cells accumulate somatic hypermutations with nucleotide exchanges indicative of affinity maturation. These sIg+ GC B cells co-express B7-2, ICAM-1, and LFA-1, and have potent antigen-presenting activity which results in T cell activation in vitro. These observations indicate that the sIg+ GC B cells accumulate somatic hypermutations and undergo antigen-driven selection through proliferation, probably upon activation by T cells. This sIg+ GC B cell population may represent cell cycling centrocytes; however, the possibility that these may represent centroblasts undergoing re-expression of sIg could not be excluded.     

Cross-reactive memory T cells for Epstein-Barr virus augment the alloresponse to common human leukocyte antigens: degenerate recognition of major histocompatibility complex-bound peptide by T cells and its role in alloreactivity

In the present report, cytotoxic T lymphocyte (CTL) clones are described that display dual specificity for one of two common human leukocyte antigens (HLA B14 or B35) as alloantigens, and an immunodominant epitope (FLRGRAYGL) from Epstein-Barr virus (EBV) that binds to HLA B8. These T cell clonotypes were isolated from several unrelated HLA B8+, EBV-exposed individuals, and each distinct cross-reactivity pattern was associated with a common, public T cell receptor (TCR). In some individuals, CTL cross-reactive with these alloantigens completely dominated the memory response to this EBV epitope. Moreover, these memory T cells to EBV could be reactivated as a significant component of the repertoire of CTL responding to allogeneic stimulator cells expressing either HLA B14 or B35. These data illustrate how a history of infection with an immunogenic virus such as EBV can augment responsiveness to particular alloantigens; such influences may underlie the observed clinical association between herpesvirus infection and both allograft rejection and graft-versus-host disease. We have also explored the molecular basis for T cell cross-reactivity with alloantigens using the HLA B35 allo-reactive CTL clonotype. To elucidate the structural features of peptides that may be cross-recognized by these T cells, mono-substituted analogs of the viral epitope were screened for recognition, revealing broad specificity for major histocompatibility complex (MHC)-bound peptide. Based on the particular amino acid changes tolerated by the CTL at each peptide position, the human protein sequence database was searched for possible sequences that were recognized in association with HLA B35. Four peptides were identified (MPEATVYGL, IPIAPVYGM, KPSPPYFGL, and KPIVVLHGY) that were powerful activating ligands for the CTL when presented on HLA B35 but not B8. Thus, equivalent epitopes, capable of fully activating a single TCR, were formed by peptides with minimal obvious sequence homology bound to either HLA B8 or B35. These data indicate that degenerate peptide recognition by TCR may play an important role in the vigorous response of self-MHC-restricted T cells to alloantigens.     

An EDTA-associated anti-B agglutinin: the role of ionized calcium

BACKGROUND: It is believed that EDTA-dependent panagglutination is associated with free carboxylic acids that support reactions of rare autoagglutinins. CASE REPORT: An ABO typing discrepancy occurred in an 88-year-old patient. The specificity of his autoagglutinin was demonstrated by panel cell study and absorption tests using normal donors' red cells or immunoadsorbents coated with A, B, or O substances. Inhibition assays were performed to determine whether the autoagglutinin was inhibited by ionized calcium or carboxylic acids. The autoagglutinin had anti-B specificity when tested in the presence of EDTA. It was neutralized by group B secretor saliva and adsorbed by crystalline silica coated with simple B substances with or without EDTA, although it was absorbed by group B red cells only in the presence of EDTA. The agglutinating activity was stronger at 25 degrees C (titer 64) than at 37 degrees C (titer 16) and was destroyed by treatment of the serum with dithiothreitol, which suggests that the autoagglutinin is IgM. This activity also appeared in the patient's serum after dialysis and in an eluate obtained after adsorption with simple B substances, and it was inhibited by the addition of CaCl2 at 0.5 mM or higher concentrations. This suggests that the agglutination is not dependent on EDTA but, rather, on the concentration of ionized calcium. The autoagglutinin failed to react with group B red cells treated with glutaraldehyde for 10 minutes. CONCLUSION: An anti-B autoagglutinin was shown to have caused an ABO typing discrepancy in the presence of EDTA. These results suggest that autoagglutination requires an environment with low levels of ionized calcium, but not the presence of carboxyl groups.     

Selection of T cells reactive against autologous B lymphoblastoid cells during chronic rheumatoid arthritis

The repertoire and Ag specificity of T cells infiltrating inflamed joints from a chronic rheumatoid arthritis (RA) patient were studied in detail. Repertoire analysis demonstrated a reduced clonality of joint-infiltrating lymphocytes (JIL) as compared with patient's PBL, which was presumably due to an intra-articular expansion of T cell clones with recurrent TCR features. Strikingly, a large fraction of these JIL T cell clones, which were predominantly CD8+, proliferated in vitro when exposed to autologous B lymphoblastoid cells (BLC), unlike randomly chosen PBL clones derived from the same patient. This proliferative response was HLA-restricted, which confirmed a classical TCR-mediated recognition of BLC and was not observed against autologous PHA blasts, suggesting recognition of either EBV or B cell-specific Ags. Finally, a preliminary analysis of synovial lymphocytes derived from another chronic RA patient demonstrated a similar enrichment for T cells reactive against autologous BLC within JILs as compared with patient's PBLs. Taken together, these results, which suggest frequent expansions of autologous BLC-reactive T cells within inflamed joints of chronic RA patients, provide a basis for future studies evaluating the fine specificity and pathogenicity of these lymphocytes.     

Stabilization and activation of p53 are regulated independently by different phosphorylation events

Rheumatoid factors (RF) recognize conformational determinants located within the Fc portion of IgG. By analyzing a panel of monoclonal rheumatoid arthritis (RA)-derived RFs, we previously demonstrated that the somatically generated light chain complementarity-determining region 3 (CDR3) contributes to RF specificity. We have now generated a panel of heavy chain mutants of the B'20 Ab, a high affinity RA-derived IgM RF. B'20 also binds avidly to protein A and weakly to ssDNA and tetanus toxoid. B9601, a RF negative Ab that is highly homologous to B'20 but does not bind any of the Ags tested, and RC1, a low affinity polyreactive RF, were used to generate heavy chain mutants with framework (FR) and CDR switches. The mutated heavy chains were cotransfected into a myeloma cell line with the germline counterpart of the B'20 light chain, and the expressed Ig tested for antigenic specificity. We show that both RF specificity and polyreactivity of B'20 is dependent on its unique heavy chain CDR3 region. Replacement with a B9601 CDR3 shortened to the same length as the B'20 CDR3, and with only 5 amino acid differences, did not restore Fc binding. Conversely, absence of protein A binding of B9601 is due to the presence of a serine residue at position 82a in the B9601 heavy chain FR3 region. Together, our data suggest that Ig gene recombination events can generate B cells with autoantibody specificities in the preimmune repertoire. Abnormal release, activation, expansion, or mutation of such cells might all contribute to the generation of a high titer RF response in patients with RA.     

Activation of interleukin 4- and interleukin 6-secreting cells by HIV-specific synthetic peptides

Peptides were synthesized in which the type-specific determinant of the V3 loop region of gp120 (SP10) was expressed C terminal to a conserved T helper epitope (T1) on the same molecule. These T1-SP10 peptides can stimulate both cell-mediated and humoral immune responses. The current work used a novel approach to study the nature and specificity of the response elicited by these peptides. Cytokine-specific ELIspot assays were used to examine the number, kinetics and fine specificity of cells induced to secrete IL-4 and IL-6 in mice immunized with T1-SP10 peptides. Results indicate that the peptides activated cytokine-secreting cells in a dose-dependent manner in vivo. In vitro restimulation experiments demonstrated that both the SP10 and T1 regions contributed to this activation. Consistent with previous studies, mice sequentially immunized with peptides expressing different V3 loop regions generated B cell responses that were larger and more cross-reactive than those induced by a single peptide. Sequential immunizations had less effect on the number or specificity of the cytokine-producing cells.     

Modification of parallel activity elicited by propagating bursts in developing networks of rat cortical neurones

The fine specificity of the cellular immune response to Candida albicans (i.e., recognition of different antigenic components) between normal controls and human immunodeficiency virus-infected patients in various stages of disease was compared. C. albicans-specific T cells, enriched by antigen stimulation and interleukin-2 expansion, were challenged with antigenic fractions of different molecular weight obtained by SDS-gel fractionation of C. albicans extracts in the presence of autologous mononuclear cells as antigen-presenting cells. Proliferative responses showed similar patterns of reactivity between controls and category A and B seropositive subjects. Category C patients with concurrent C. albicans infections did not give rise to C. albicans-specific T cell lines, confirming the T cell defect. Patients without clinically evident C. albicans infection had a low but broad reactivity pattern of C. albicans-specific T cells. These results suggest that depletion of C. albicans-specific T cells, independent of their fine specificity, occurs along with disease progression.     

Criminality in a sample of drug abusers in Greece

In order to produce mAbs directed specifically against HLA-DR10 molecule, transfected mouse L cells, expressing the DRB1*1001 allele, were used to immunize C3H mice over a period of 4 weeks. Two mAbs, 2C12 and 4B6, derived from this fusion were found to recognize, with different affinity, polymorphic epitopes of DR10 that are shared with DR1, 3, 7, and 9. These mAbs were screened on a large panel of homozygous B lymphoblastoid cell lines using microlymphocytotoxicity and the results were confirmed by flow cytometry. The reactive pattern of 2C12 and 4B6 was compared to that of MP10 human mAb also recognizing the DR10 specificity in addition to DR1, 2 and 9. Based on serologic specificity and cellular absorption experiments, we conclude that the epitopes the murine and human mAbs respectively recognize on the DR10 molecule, are probably different.