Conserved cryptic recombination signals in Vkappa gene segments are cleaved in small pre-B cells.

Abstract

BackgroundThe cleavage of recombination signals (RS) at the boundaries of immunoglobulin V, D, and J gene segments initiates the somatic generation of the antigen receptor genes expressed by B lymphocytes. RS contain a conserved heptamer and nonamer motif separated by non-conserved spacers of 12 or 23 nucleotides. Under physiologic conditions, V(D)J recombination follows the "12/23 rule" to assemble functional antigen-receptor genes, i.e., cleavage and recombination occur only between RS with dissimilar spacer types. Functional, cryptic RS (cRS) have been identified in VH gene segments; these VH cRS were hypothesized to facilitate self-tolerance by mediating VH → VHDJH replacements. At the Igκ locus, however, secondary, de novo rearrangements can delete autoreactive VκJκ joins. Thus, under the hypothesis that V-embedded cRS are conserved to facilitate self-tolerance by mediating V-replacement rearrangements, there would be little selection for Vκ cRS. Recent studies have demonstrated that VH cRS cleavage is only modestly more efficient than V(D)J recombination in violation of the 12/23 rule and first occurs in pro-B cells unable to interact with exogenous antigens. These results are inconsistent with a model of cRS cleavage during autoreactivity-induced VH gene replacement.ResultsTo test the hypothesis that cRS are absent from Vκ gene segments, a corollary of the hypothesis that the need for tolerizing VH replacements is responsible for the selection pressure to maintain VH cRS, we searched for cRS in mouse Vκ gene segments using a statistical model of RS. Scans of 135 mouse Vκ gene segments revealed highly conserved cRS that were shown to be cleaved in the 103/BCL2 cell line and mouse bone marrow B cells. Analogous to results for VH cRS, we find that Vκ cRS are conserved at multiple locations in Vκ gene segments and are cleaved in pre-B cells.ConclusionOur results, together with those for VH cRS, support a model of cRS cleavage in which cleavage is independent of BCR-specificity. Our results are inconsistent with the hypothesis that cRS are conserved solely to support receptor editing. The extent to which these sequences are conserved, and their pattern of conservation, suggest that they may serve an as yet unidentified purpose.