Kerstin Kiefer

Murine B Cell Response to TLR7 Ligands Depends on an IFN-β Feedback Loop

Type I IFNs play an important, yet poorly characterized, role in systemic lupus erythematosus. To better understand the interplay between type I IFNs and the activation of autoreactive B cells, we evaluated the effect of type I IFN receptor (IFNAR) deficiency in murine B cell responses to common TLR ligands. In comparison to wild-type B cells, TLR7-stimulated IFNAR−/− B cells proliferated significantly less well and did not up-regulate costimulatory molecules. By contrast, IFNAR1−/− B cells did not produce cytokines, but did proliferate and up-regulate activation markers in response to other TLR ligands. These defects were not due to a difference in the distribution of B cell populations or a failure to produce a soluble factor other than a type I IFN. Instead, the compromised response pattern reflected the disruption of an IFN-β feedback loop and constitutively low expression of TLR7 in the IFNAR1−/− B cells. These results highlight subtle differences in the IFN dependence of TLR7 responses compared with other TLR-mediated B cell responses.

The catalytic subunit of DNA-protein kinase (DNA-PKcs) is not required for ig class-switch recombination

The joining of DNA ends during Ig class-switch recombination (CSR) is thought to involve the same nonhomologous end-joining pathway as used in V(D)J recombination. However, we reported earlier that CSR can readily occur in Ig transgenic SCID mice lacking DNA-dependent protein kinase (DNA-PK) activity, a critical enzymatic activity for V(D)J recombination. We were thus led to question whether the catalytic subunit of DNA-PK (DNA-PKcs) is essential for CSR. To address this issue, we asked whether class switching to different Ig isotypes could occur in a line of Ig transgenic mice lacking detectable DNA-PKcs protein. The answer was affirmative. We conclude that joining of DNA ends during CSR does not require DNA-PKcs and can occur by an alternative repair pathway to that used for V(D)J recombination.

Antigen Receptor Editing in Anti-DNA Transitional B Cells Deficient for Surface IgM

In response to encounter with self-Ag, autoreactive B cells may undergo secondary L chain gene rearrangement (receptor editing) and change the specificity of their Ag receptor. Knowing at what differentiative stage(s) developing B cells undergo receptor editing is important for understanding how self-reactive B cells are regulated. In this study, in mice with Ig transgenes coding for anti-self (DNA) Ab, we report dsDNA breaks indicative of ongoing secondary L chain rearrangement not only in bone marrow cells with a pre-B/B cell phenotype but also in immature/transitional splenic B cells with little or no surface IgM (sIgM−/low). L chain-edited transgenic B cells were detectable in spleen but not bone marrow and were still found to produce Ab specific for DNA (and apoptotic cells), albeit with lower affinity for DNA than the unedited transgenic Ab. We conclude that L chain editing in anti-DNA-transgenic B cells is not only ongoing in bone marrow but also in spleen. Indeed, transfer of sIgM−/low anti-DNA splenic B cells into SCID mice resulted in the appearance of a L chain editor (Vλx) in the serum of engrafted recipients. Finally, we also report evidence for ongoing L chain editing in sIgMlow transitional splenic B cells of wild-type mice.

Two distinct populations of H chain-edited B cells show differential surrogate L chain dependence.

Developing autoreactive B cells may edit (change) their specificity by secondary H or L chain gene rearrangement. Recently, using mice hemizygous for a site-directed VDJH and VJκ transgene (tg) encoding an autoreactive Ab, we reported ongoing L chain editing not only in bone marrow cells with a pre-B/immature B cell phenotype but also in immature/transitional splenic B cells. Using the same transgenic model, we report here that editing at the H chain locus appears to occur exclusively in bone marrow cells with a pro-B phenotype. H chain editing is shown to involve VH replacement at the tg allele or VH rearrangement at the wild-type (wt) allele when the tg is inactivated by nonproductive VH replacement. VH replacement/rearrangement at the tg/wt alleles was found to entail diverse usage of VH genes. Whereas the development of edited B cells expressing the wt allele was dependent on the λ5 component of the surrogate L chain, the development of B cells expressing the tg allele, including those with VH replacement, appeared to be λ5 independent. We suggest that the unique CDR3 region of the tg-encoded μH chain is responsible for the λ5 independence of tg-expressing B cells.

Development of Functional B Cells in a Line of SCID Mice with Transgenes Coding for Anti-Double-Stranded DNA Antibody

Deletion or inactivation of anti-self (DNA) B cells has been reported in non-autoimmune mice bearing Ig transgenes that code for Abs with specificity for dsDNA or ssDNA. However, we report a case in which anti-dsDNA B cells appear to escape both deletion and inactivation. We show that B cells (B220+IgM+) can develop in non-autoimmune SCID mice bearing two site-directed transgenes, 3H9(56R) and Vκ8, that together code for an anti-dsDNA Ab. The B cells appear inactive, because the mice (56RVκ8 SCID mice) generally lack serum Ig. However, 56RVκ8 SCID mice are able to produce IgG Ab with specificity for dsDNA when they become “leaky” for T cells or are reconstituted with exogenous T cells from B cell-deficient JH−/− donors. Thus, anti-dsDNA B cells that escape deletion in 56RVκ8 SCID mice appear fully functional and can differentiate, class switch, and give rise to IgG-producing cells in the presence of T cells and self-Ag.