Role of receptor editing and revision in shaping the B and T lymphocyte repertoire.

B and T lymphocytes that carry antigen receptors are able to change specificity through subsequent receptor gene rearrangements. Receptor editing and receptor revision are terms used to distinguish those rearrangements occurring, respectively, in central lymphoid organs and the periphery. Secondary rearrangement appears to be a major player at two levels in the life of B lymphocytes. First, editing preserves a diverse repertoire without compromising self-tolerance, and revision further increases this repertoire once B cells have been engaged in an immune response, most likely for a better interaction with microbes. Recent studies have likewise suggested a role for receptor editing and revision in shaping the T cell repertoire during development and tolerance.

B cell receptor expression level determines the fate of developing B lymphocytes: receptor editing versus selection.

During B lymphocyte development, antibody genes are assembled by DNA recombination. Successful cell surface expression of IgM promotes developmental progression. However, when antigen receptors bind autoantigen, development is blocked and ongoing antibody gene recombination occurs, which often alters antibody specificity in a process called receptor editing. We demonstrate here a significant role of developmental block and receptor editing in B cell receptor quality control. During development a functional, non-self-reactive receptor undergoes receptor editing if its expression is below a certain threshold. Doubling the receptor gene dose promotes development in the absence of autoantigen, but allows editing when autoantigen is present. Thus, both underexpressed and harmful B cell receptors can undergo correction by receptor editing.

T cell-independent rescue of B lymphocytes from peripheral immune tolerance.

Autoimmunity arises when immune tolerance to specific self-antigens is broken. The mechanisms leading to such a failure remain poorly understood. One hypothesis proposes that infectious agents or antigens can break B or T lymphocyte self-tolerance by expressing epitopes that mimic self. Using a transgenic immunoglobulin model, we show that challenge with self-mimicking foreign antigen rescues B cells from peripheral tolerance independent of T cell help, resulting in the accumulation of self-reactive cells in the lymph nodes and secretion of immunoglobulins that bind to a liver-expressed self-antigen. Therefore, our studies reveal a potentially important mechanism by which B lymphocytes can escape self-tolerance.

B-cell-receptor-dependent positive and negative selection in immature B cells.

This review touches on only a small part of the complex biology of B cells, but serves to illustrate the point that the antigen receptor is the most important of many cell-surface receptors affecting cell-fate decisions. Receptor expression is necessary, but not sufficient, for cell survival. It is also essential that a B cell's antigen-receptor specificity be appropriate for its environment. The need to balance reactivity with self tolerance has resulted in an intricate feedback control (affected by both the recombinase and cell survival) that regulates independent selection events at the level of the receptor and the cell.

Inhibition of thymocyte positive selection by natural MHC: peptide ligands.

The 3A9 transgenic mouse line carries the rearranged TCR genes from a T cell hybridoma that recognizes hen egg lysozyme peptide 46-61 in the context of MHC class II Ak molecules. As expected, positive selection of immature 3A9 thymocytes to become mature CD4+ 8- T cells was efficient on the "selecting" CBA (H-2k) genetic background but not on the "non-selecting" C57BL/6 (H-2b) background. Surprisingly, positive selection was also inefficient on the CBA x C57BL/6 F1 background (H-2kb). We present evidence that expression of A(beta)b molecules on thymus epithelium (in conjunction with A(alpha)b or A(alpha)k molecules) inhibits the positive selection of 3A9 thymocytes mediated by A(alpha)k:A(beta)k complexes, in a process evocative of peptide antagonism of mature T cells.

The arthritogenic T cell receptor and its ligand in a model of spontaneous arthritis.

OBJECTIVE: Spontaneous arthritis in the KRN transgenic mouse model is due to the autoreactivity of the transgenic T cell receptor (TCR) against Ag7 major histocompatibility complex (MHC) molecules, which leads to strong but incomplete clonal deletion. We sought to determine whether other stimuli triggering this receptor might provoke arthritis, whether the apparently systemic reactivity might have some joint-preferential component explaining the paradoxical arthritic phenotype, and whether the transgenic receptor was the only one required or whether other TCRs might be ferried along in a leaky tolerance process. METHODS: Crosses and radiation chimeras involving a panel of transgenic and knockout mouse lines were used. The reactivity of the KRN TCR was tested in carboxyfluorescein diacetate succinimidyl ester-transfer experiments and in crosses with transgenic or inbred mice expressing other molecules that stimulate the KRN receptor (the mls-1a superantigen, the Aalpha(k69)Abeta(k) mutant MHC molecule). The arthritogenic capacity of T cells expressing only the KRN TCR was tested by crossing to recombination-activating gene-knockout mice, and constructing bone marrow chimeras with precursors to these strictly monoclonal T cells. RESULTS: The data show that the KRN TCR itself is the only receptor needed. It needs to be triggered by the Ag7 molecule loaded with self-peptides in order to provoke arthritis, but there is no indication of preferential presentation of joint-derived peptides. CONCLUSION: Arthritis can be generated by systemic recognition of self-MHC-peptide complexes by autoreactive T cells. This triggers B lymphocytes to produce arthritogenic antibodies, without the involvement of joint-specific T cell targets.

Antigens varying in affinity for the B cell receptor induce differential B lymphocyte responses.

The B cell receptor (BCR) triggers a variety of biological responses that differ depending upon the properties of the antigen. A panel of M13 phage-displayed peptide ligands with varying affinity for the 3-83 antibody was generated to explore the role of antigen-BCR affinity in cell activation studies using primary 3-83 transgenic mouse B cells. Multiple parameters of activation were measured. T cell-independent B cell proliferation, antibody secretion, induction of germline immunoglobulin gamma1 transcripts, and B cell production of interleukin (IL) 2 and interferon gamma responses were better correlated with antigen-BCR affinity than with receptor occupancy. In contrast, other responses, such as upregulation of major histocompatibility complex class II and B7.2 (CD86), secretion of IL-6, and B cell proliferation in the context of CD40 signaling were only weakly dependent on antigen affinity. Biochemical analysis revealed that at saturating ligand concentrations the ability of phage to stimulate some early signaling responses, such as Ca++ mobilization and tyrosine phosphorylation of syk or Igalpha, was highly affinity dependent, whereas the ability to stimulate Lyn phosphorylation was less so. These data suggest that the BCR is capable of differential signaling. The possibility that differential BCR signaling by antigen determines whether an antibody response will be T independent or dependent is discussed.

V(D)J recombinase induction in splenic B lymphocytes is inhibited by antigen-receptor signalling.

In lymphocytes, DNA recombinations that generate the antigen-receptor genes can sometimes be reinduced in receptor-bearing cells in a process called receptor editing, which modifies the specificity of the receptor for antigen. In immature B lymphocytes, B-cell antigen receptor (BCR) signalling stimulates immune tolerance by receptor editing. More mature splenic B cells can also be induced to undergo V(D)J recombination, which generates diversity in the immune system, either by immunization with foreign proteins or by stimulation in vitro with interleukin-4 and lipopolysaccharides. Here we show that immune tolerance is unlikely to induce V(D)J recombination in mature B cells, because BCR ligation actively inhibits V(D)J recombination induced by interleukin-4 and lipopolysaccharide. Furthermore, immunization of immunoglobulin transgenic mice with ligands of varying avidities for the BCR showed that low-avidity antigen could induce strong V(D)J recombination, whereas non-binding or high-avidity ligands could not. These data suggest that V(D)J recombination induced during the immune response modifies the antigen receptors of B cells with weak, but not strong, reactivity to antigen, potentially rescuing cells with improved receptor affinity and promoting their contribution to the immune response. Thus BCR signalling regulates V(D)J recombination in both tolerance and immunity, but in strikingly different ways.

Organ-specific disease provoked by systemic autoimmunity.

Rheumatoid arthritis (RA) is a chronic joint disease characterized by leukocyte invasion and synoviocyte activation followed by cartilage and bone destruction. Its etiology and pathogenesis are poorly understood. We describe a spontaneous mouse model of this syndrome, generated fortuitously by crossing a T cell receptor (TCR) transgenic line with the NOD strain. All offspring develop a joint disease highly reminiscent of RA in man. The trigger for the murine disorder is chance recognition of a NOD-derived major histocompatibility complex (MHC) class II molecule by the transgenic TCR; progression to arthritis involves CD4+ T, B, and probably myeloid cells. Thus, a joint-specific disease need not arise from response to a joint-specific antigen but can be precipitated by a breakdown in general mechanisms of self-tolerance resulting in systemic self-reactivity. We suggest that human RA develops by an analogous mechanism.

Cassette vectors directing expression of T cell receptor genes in transgenic mice.

We describe a pair of cassette vectors that can be used to express rearranged T cell receptor genes in transgenic mice. Short DNA fragments containing rearranged V alpha and V beta segments are readily amplified from T cells and introduced between artificial cloning sites. Transgene-derived mRNAs are transcribed under the control of the natural TCR alpha and -beta promoter/enhancer elements. Using this vector, we have obtained transgenic mouse lines which display transgene-encoded TCR alpha and beta chains on a majority of T cells.

The influence of positive selection on RAG expression in thymocytes.

The expression of recombination activating gene (RAG) products, responsible for T cell receptor (TcR) gene rearrangement, is shut off during positive selection of thymocytes. The precise stage at which this down-regulation occurs remains somewhat controversial. We have analyzed RAG-1 expression in thymocytes of TcR transgenic mice carried on selecting versus non-selecting genetic backgrounds, both by in situ hybridization on thymus sections and by polymerase chain reaction amplification of RNA from sorted cells. The data from several transgenic lines indicate that RAG expression is already reduced in immature, cortical, CD4+CD8+ cells in the presence of positively selecting major histocompatibility complex molecules, although complete shut-off is not achieved until the mature, medullary, single-positive stage. This finding has practical and theoretical significance for studies on the mechanism of positive selection.

A vector driving the expression of foreign cDNAs in the MHC class II-positive cells of transgenic mice.

We describe a plasmid vector that drives the expression of foreign cDNAs in transgenic mice, according to the dictates of an MHC class II gene promoter. Using this vector, we have often obtained mRNA and protein synthesis with a tissue and cell-type specificity indistinguishable from that of the endogenous MHC class II genes.

NF-X, a transcription factor implicated in MHC class II gene regulation.

The X box has been shown in several assay systems to be a critical element of MHC class II gene promoters. Several X box-binding activities have been discovered in nuclear extracts from a variety of cell lines. The critical question is: which of these are responsible for mediating X box function? This report provides a further characterization of NF-X, a highly specific X box-binding activity we described previously. The cell-type distribution, structural features, and binding site characteristics of NF-X are analyzed in detail, to facilitate comparison with other reported activities. Most importantly, the functional relevance of NF-X is assessed by scanning mutagenesis, and the results indicate that this complex is indeed involved in regulating MHC class II gene expression. With these data in mind, the relationship between NF-X and RF-X, an X box-binding activity reported to be absent in patients with severe combined immunodeficiency, is discussed.