RAG1/2 re-expression causes receptor revision in a model B cell line.

The expression of RAG1 and RAG2 is essential for V(D)J rearrangement of the immunoglobulin (Ig) locus in developing B cells. In mature B cells further V(D)J rearrangement is suppressed and RAG1/2 proteins decline to undetectable levels. However, there is evidence that mature B cells in the periphery may re-express RAG1/2. In humans evidence of RAG1/2 re-expression is often linked with an autoimmune state, indicating that further understanding of re-expression may be crucial to understanding immune disorders. We have investigated the molecular consequences of RAG1/2 expression in mature lymphocytes using a cell culture system (M12 and DR3). M12 (IgG+, Igkappa+ and RAG-) is a mouse B cell lymphoma. DR3 is a RAG1+/RAG2+ line derived from M12 by introduction of stable plasmids carrying RAG1 and RAG2 cDNAs. RAG1/2 mediated receptor revision occurs in the DR3 line, as evidenced by both the deletion of the endogenous rearranged Igkappa gene segment (present in the parent M12 lines) and the presence of a new Iglambda rearrangement. Gene expression profiles obtained through microarray analysis and RT-PCR found differences in expression levels between the two lines for: fibronectin, lysyl oxidase, TAP2, B220, Igkappa, TIS11B, HMG2 and DNAPKcs. Thus, the expression of RAG1/2 in a previously RAG- cell line results in multiple changes to the gene expression profile as well as receptor revision. The significance of the changes found in this model of RAG re-expression is discussed.

The recombination difference between mouse kappa and lambda segments is mediated by a pair-wise regulation mechanism.

In mice, kappa light chains dominate over lambda in the immunoglobulin repertoire by as much as 20-fold. Although a major contributor to this difference is the recombination signal sequences (RSS), the mechanism by which RSS cause differential representation has not been determined. To elucidate the mechanism, we tested kappa and lambda RSS flanked by their natural 5' and 3' flanks in three systems that monitor V(D)J recombination. Using extra-chromosomal recombination substrates, we established that a kappa RSS and its flanks support six- to nine-fold higher levels of recombination than a lambda counterpart. In vitro cleavage assays with these same sequences demonstrated that single cleavage at individual kappa or lambda RSS (plus flanks) occurs with comparable frequencies, but that a pair of kappa RSS (plus flanks) support significantly higher levels of double cleavage than a pair of lambda RSS (plus flanks). Using EMSA with double stranded oligonucleotides containing the same kappa or lambda RSS and their respective flanks, we examined RAG/DNA complex formation. We report that, surprisingly, RAG-1/2 form only modestly higher levels of complexes on individual 12 and 23 kappa RSS (plus natural flanks) as compared to their lambda counterparts. We conclude that the overuse of kappa compared to lambda segments cannot be accounted for by differences in RAG-1/2 binding nor by cleavage at individual RSS but rather could be accounted for by enhanced pair-wise cleavage of kappa RSS by RAG-1/2. Based on the data presented, we suggest that the biased usage of light chain segments is imposed at the level of synaptic RSS pairs.

Rapid, stabilizing palindrome rearrangements in somatic cells by the center-break mechanism.

DNA palindromes are associated with rearrangement in a variety of organisms. A unique opportunity to examine the impact of a long palindrome in mammals is afforded by the Line 78 strain of mice. Previously it was found that the transgene in Line 78 is likely to be palindromic and that the symmetry of the transgene was responsible for a high level of germ line instability. Here we prove that Line 78 mice harbor a true 15.4-kb palindrome, and through the establishment of cell lines from Line 78 mice we have shown that the palindrome rearranges at the impressive rate of about 0.5% per population doubling. The rearrangements observed to arise from rapid palindrome modification are consistent with a center-break mechanism where double-strand breaks, created through hairpin nicking of an extruded cruciform, are imprecisely rejoined, thus introducing deletions at the palindrome center. Significantly, palindrome rearrangements in somatic tissue culture cells almost completely mirrored the structures generated in vivo in the mouse germ line. The close correspondence between germ line and somatic events indicates the possibility that center-break modification of palindromes is an important mechanism for preventing mutation in both contexts. Permanent cell lines carrying a verified palindrome provide an essential tool for future mechanistic analyses into the consequences of palindromy in the mammalian genome.