Global analysis of B cell selection using an immunoglobulin light chain-mediated model of autoreactivity.

The important subtleties of B cell tolerance are best understood in a diverse immunoglobulin (Ig) repertoire context encoding a full spectrum of autoreactivity. To achieve this, we used mice expressing Igκ transgenes that confer varying degrees of autoreactivity within a diverse heavy chain (HC) repertoire. These transgenes, coupled with a biomarker to identify receptor-edited cells and combined with expression cloning of B cell receptors, allowed us to analyze tolerance throughout B cell development. We found that both the nature of the autoantigen and the Ig HC versus light chain (LC) contribution to autoreactivity dictate the developmental stage and mechanism of tolerance. Furthermore, although selection begins in the bone marrow, over one third of primary tolerance occurs in the periphery at the late transitional developmental stage. Notably, we demonstrate that the LC has profound effects on tolerance and can lead to exacerbated autoantibody production.

B cell receptor light chain repertoires show signs of selection with differences between groups of healthy individuals and SLE patients.

We have developed a microarray to study the expression of L-chain V genes (V(L) genes) in healthy and SLE patient peripheral κ- and λ-sorted B cells. In all repertoires tested, one V(L) gene accounts for over 10% of all gene V(L) expression, consistent with positive selection acting on L-chains. While a few V(L) genes were highly expressed in all individuals, most V(L) genes were expressed at different levels. Some V(L) genes (5 out of a total of 78) were not detected. We attribute their absence from the repertoire to negative selection. Positive selection and negative selection were also found in SLE repertoires, but expression of V(L) genes was different; the differences point to less regulation of V(L) gene repertoires in SLE. Our data shows that V(L) gene expression is variable and supports a model where the L-chain repertoire is generated by both positive and negative selection on L-chains.

Anti-DNA B cells in MRL/lpr mice show altered differentiation and editing pattern.

We have studied the regulation of anti-DNA B cells in transgenic mice with a heavy chain transgene (3H9H/56R). This transgene codes for a heavy chain that forms anti-double-stranded DNA (dsDNA) antibody when paired with most members of the endogenous Vkappa repertoire, but certain L chains, referred to as Vkappa editors, do not sustain dsDNA binding in combination with 3H9H/56R. In the nonautoimmune 3H9H/56R BALB/c, most B cells generated do not bind DNA because the transgene itself is edited or is associated with a Vkappa editor. A minor population of B cells (30%) bind dsDNA and express the lambda1 light chain (known to sustain 3H9H/56R DNA binding). These 3H9/56R/lambda1 B cells coexpress a kappa editor, and we propose that the down-regulation of the anti-DNA BCR caused by the dual L chain expression may prevent activation of this kappa/lambda population. These kappa/lambda B cells are sequestered in the marginal zone. Here, we studied the influence of autoimmunity on expression and regulation of 3H9H/56R. In 3H9H/56R MRL/lpr mice, the expression of anti-dsDNA is vastly accelerated. Anti-dsDNA B cells use noneditor kappas but, in addition, most anti-dsDNA B cells have edited the heavy chain transgene. lambda1 B cells (without the coexpression of a kappa editor) are found and the kappa/lambda1 MZ population is absent. Our results suggest that improper editing and failure to sequester autoreactive B cells may contribute to the breakdown of tolerance in MRL/lpr mice.