Targeted transposition by the V(D)J recombinase

Cleavage by the V(D)J recombinase at a pair of recombination signal sequences creates two coding ends and two signal ends. The RAG proteins can integrate these signal ends, without sequence specificity, into an unrelated target DNA molecule. Here we demonstrate that such transposition events are greatly stimulated by--and specifically targeted to--hairpins and other distorted DNA structures. The mechanism of target selection by the RAG proteins thus appears to involve recognition of distorted DNA. These data also suggest a novel mechanism for the formation of alternative recombination products termed hybrid joints, in which a signal end is joined to a hairpin coding end. We suggest that hybrid joints may arise by transposition in vivo and propose a new model to account for some recurrent chromosome translocations found in human lymphomas. According to this model, transposition can join antigen receptor loci to partner sites that lack recombination signal sequence elements but bear particular structural features. The RAG proteins are capable of mediating all necessary breakage and joining events on both partner chromosomes; thus, the V(D)J recombinase may be far more culpable for oncogenic translocations than has been suspected.     

Restraining the V(D)J recombinase

Chromosome breakage--a dangerous event that has triggered the evolution of several double-strand break repair pathways--has been co-opted by the immune system as an integral part of B- and T-cell development. This is a daring strategy, as improper repair can be deadly for the cell, if not for the whole organism. Even more daring, however, is the choice of a promiscuous transposase as the nuclease responsible for chromosome breakage, as the possibility of transposition brings an entirely new set of risks. What mechanisms constrain the dangerous potential of the recombinase and preserve genomic integrity during immune-system development?     

From lymphocytes to sharks: V(D)J recombinase moves to the germline

The antigen-receptor genes of vertebrates are rearranged by a specialized somatic recombination mechanism in developing lymphocytes - and, unexpectedly, also in the germline of cartilaginous fishes. The recombination system that carries out these DNA rearrangements may thus be a significant evolutionary force, perhaps not limited to rearrangements at antigen-receptor loci.     

In vivo reinsertion of excised episomes by the V(D)J recombinase: a potential threat to genomic stability

It has long been thought that signal joints, the byproducts of V(D)J recombination, are not involved in the dynamics of the rearrangement process. Evidence has now started to accumulate that this is not the case, and that signal joints play unsuspected roles in events that might compromise genomic integrity. Here we show both ex vivo and in vivo that the episomal circles excised during the normal process of receptor gene rearrangement may be reintegrated into the genome through trans-V(D)J recombination occurring between the episomal signal joint and an immunoglobulin/T-cell receptor target. We further demonstrate that cryptic recombination sites involved in T-cell acute lymphoblastic leukemia-associated chromosomal translocations constitute hotspots of insertion. Eventually, the identification of two in vivo cases associating episomal reintegration and chromosomal translocation suggests that reintegration events are linked to genomic instability. Altogether, our data suggest that V(D)J-mediated reintegration of episomal circles, an event likely eluding classical cytogenetic screenings, might represent an additional potent source of genomic instability and lymphoid cancer.     

Understanding how the V(D)J recombinase catalyzes transesterification: distinctions between DNA cleavage and transposition

The Rag1 and Rag2 proteins initiate V(D)J recombination by introducing site-specific DNA double-strand breaks. Cleavage occurs by nicking one DNA strand, followed by a one-step transesterification reaction that forms a DNA hairpin structure. A similar reaction allows Rag transposition, in which the 3′-OH groups produced by Rag cleavage are joined to target DNA. The Rag1 active site DDE triad clearly plays a catalytic role in both cleavage and transposition, but no other residues in Rag1 responsible for transesterification have been identified. Furthermore, although Rag2 is essential for both cleavage and transposition, the nature of its involvement is unknown. Here, we identify basic amino acids in the catalytic core of Rag1 specifically important for transesterification. We also show that some Rag1 mutants with severe defects in hairpin formation nonetheless catalyze substantial levels of transposition. Lastly, we show that a catalytically defective Rag2 mutant is impaired in target capture and displays a novel form of coding flank sensitivity. These findings provide the first identification of components of Rag1 that are specifically required for transesterification and suggest an unexpected role for Rag2 in DNA cleavage and transposition.     

V(D)J recombination and RAG-mediated transposition in yeast

Antigen receptor genes are assembled during lymphoid development by a specialized recombination reaction normally observed only in cells of the vertebrate immune system. Here, we show that expression in Saccharomyces cerevisiae of murine RAG1 and RAG2, the lymphoid-specific components of the V(D)J recombinase, is sufficient to induce V(D)J cleavage and rejoining in this lower eukaryote. The RAG proteins cleave recombination substrates introduced into yeast cells, generating signal ends that can be joined to form signal joints. These signal joints are precise, as in mammalian cells, and their formation is dependent on a yeast nonhomologous end-joining protein, the XRCC4 homolog LIF1. Moreover, joining of SmaI-generated blunt ends is generally imprecise in the yeast strain used here, suggesting that the RAG proteins influence signal-end joining. Cleaved signal ends are also transposed into new sites in DNA, allowing RAG-induced transposition to be studied in vivo.     

Nucleosome structure completely inhibits in vitro cleavage by the V(D)J recombinase.

Lineage specificity and temporal ordering of immunoglobulin (Ig) and T-cell receptor (TCR) gene rearrangement are reflected in the accessibility of recombination signal sequences (RSSs) within chromatin to in vitro cleavage by the V(D)J recombinase. In this report, we investigated the basis of this regulation by testing the ability of purified RAG1 and RAG2 proteins to initiate cleavage on positioned nucleosomes containing RSS substrates. We found that nicking and double-strand DNA cleavage of RSSs positioned on the face of an unmodified nucleosome are entirely inhibited. This inhibition was independent of translational position or rotational phase and could not be overcome either by addition of the DNA-bending protein HMG-1 or by the use of hyperacetylated histones. We suggest that the nucleosome could act as the stable unit of chromatin which limits recombinase accessibility to potential RSS targets, and that actively rearranging gene segments might be packaged in a modified or disrupted nucleosome structure.     

Stable expression of immunoglobulin gene V(D)J recombinase activity by gene transfer into 3T3 fibroblasts

Using retroviral recombination substrates, we investigated the developmental stage of expression of V(D)J recombinase activity and the activation of recombinase activity in nonlymphoid cells. V(D)J recombinase activity was detected only in pre-B cells, but a DNA transfer protocol successfully activated V(D)J recombination in an NIH 3T3 cell line. The V(D)J recombinase activity was transferred in a second round of transfection and was then stably expressed in fibroblasts at a level comparable to that of a recombinationally active pre-B cell. It is likely that expression of a single, lymphoid-specific gene in a fibroblast is sufficient to confer V(D)J recombinase activity on that cell.     

Thymic nuclear matrix associated activity is not V(D)J recombinase

It was previously reported that nuclear matrix isolated from young rat thymus contained an activity that supported V(D)J recombination at a high efficiency (Dave et al., BIOCHEMISTRY 30: 4763-4767, 1991). A similar type of activity is also detected in the matrix prepared from fetal calf thymus. However, restriction enzyme mapping analyses of the recombined product clearly suggest that the double antibiotic resistance exhibited by the matrix treated plasmid substrate is not a consequence of V(D)J signal sequence recombination.     

The V(D)J recombinase efficiently cleaves and transposes signal joints

V(D)J recombination generates two types of products: coding joints, which constitute the rearranged variable regions of antigen receptor genes, and signal joints, which often form on immunologically irrelevant, excised circular molecules that are lost during cell division. It has been widely believed that signal joints simply convert reactive broken DNA ends into safe, inert products. Yet two curious in vivo observations made us question this assumption: signal ends are far more abundant than coding ends, and signal joints form only after RAG expression is downregulated. In fact, we find that signal joints are not at all inert; they are cleaved quite efficiently in vivo and in vitro by a nick-nick mechanism and form an excellent substrate for RAG-mediated transposition in vitro, possibly explaining how genomic stability in lymphocytes may be compromised.     

Cutting edge: targeting of V beta to D beta rearrangement by RSSs can be mediated by the V(D)J recombinase in the absence of additional lymphoid-specific factors

Assembly of TCRbeta variable region genes is ordered during thymocyte development with Dbeta to Jbeta rearrangement preceding Vbeta to DJbeta rearrangement. The 5'Dbeta 12-RSS is required to precisely and efficiently target Vbeta rearrangement beyond simply enforcing the 12/23 rule. By prohibiting direct Vbeta to Jbeta rearrangement, this restriction ensures Dbeta gene segment use in the assembly of essentially all TCRbeta variable region genes. In this study, we show that rearrangement of Vbeta 23-RSSs is significantly biased to the Dbeta 12-RSS over Jbeta 12-RSSs on extrachromosomal recombination substrates in nonlymphoid cells that express the recombinase-activating gene-1/2 proteins. These findings demonstrate that targeting of Vbeta to Dbeta rearrangement can be enforced by the V(D)J recombinase in the absence of lymphoid-specific factors other than the recombinase-activating gene-1/2 proteins.     

Analysis of mutagenic V(D)J recombinase mediated mutations at the HPRT locus as an in vivo model for studying rearrangements with leukemogenic potential in children

Pediatric acute lymphocytic leukemia (ALL) is a multifactorial malignancy with many distinctive developmentally specific features that include age specific acquisition of deletions, insertions and chromosomal translocations. The analysis of breakpoint regions involved in these leukemogenic genomic rearrangements has provided evidence that many are the consequence of V(D)J recombinase mediated events at both immune and non-immune loci. Hence, the direct investigation of in vivo genetic and epigenetic features in human peripheral lymphocytes is necessary to fully understand the mechanisms responsible for the specificity and frequency of these leukemogenic non-immune V(D)J recombinase events. In this review, I will present the utility of analyzing mutagenic V(D)J recombinase mediated genomic rearrangements at the HPRT locus in humans as an in vivo model system for understanding the mechanisms responsible for leukemogenic genetic alterations observed in children with leukemia.     

How DNA loop extrusion mediated by cohesin enables V(D)J recombination

‘Structural maintenance of chromosomes’ (SMC) complexes are required for the folding of genomic DNA into loops. Theoretical considerations and single-molecule experiments performed with the SMC complexes cohesin and condensin indicate that DNA folding occurs via loop extrusion. Recent work indicates that this process is essential for the assembly of antigen receptor genes by V(D)J recombination in developing B and T cells of the vertebrate immune system. Here, I review how recent studies of the mouse immunoglobulin heavy chain locus Igh have provided evidence for this hypothesis and how the formation of chromatin loops by cohesin and regulation of this process by CTCF and Wapl might ensure that all variable gene segments in this locus (V_H segments) participate in recombination with a re-arranged DJ_H segment, to ensure generation of a maximally diverse repertoire of B-cell receptors and antibodies.     

Assessing the pathogenic potential of the V(D)J recombinase by interlocus immunoglobulin light-chain gene rearrangement.

Chromosomal translocations involving antigen receptor genes and oncogenes have been observed in several forms of lymphoid malignancy. Observations of their lymphocyte-restricted occurrence and a molecular analysis of some translocation breakpoints have suggested that some of these rearrangements are generated by V(D)J recombinase activity. However, a direct correlation between this activity and the generation of such rearrangements has never been established. In addition, because these aberrant rearrangements are usually detected only after a tumor has been formed, the frequency with which the recombinase machinery generates translocations has never been assessed directly. To approach these issues, immunoglobulin light-chain gene rearrangements were induced in pre-B cells transformed by temperature-sensitive mutants of Abelson murine leukemia virus and PCR was used to identify interlocus recombinants. Vlambda Jkappa and Vkappa Jlambda rearrangements as well as signal joints resulting from the recombination of Vlambda and Jkappa coding elements were recovered and were found to be similar in structure to conventional intrachromosomal joints. Because these products were detected only when the cells were undergoing active intralocus rearrangement, they provide direct evidence that translocations can be generated by the V(D)J recombinase machinery. Dilution analyses revealed that interlocus rearrangements occur about 1,000 times less frequently than conventional intralocus rearrangements. Considering the large numbers of lymphocytes generated throughout life, aberrant rearrangements generated by the V(D)J recombinase may be relatively common.     

VDJSeq-Solver: In Silico V(D)J Recombination Detection Tool

In this paper we present VDJSeq-Solver, a methodology and tool to identify clonal lymphocyte populations from paired-end RNA Sequencing reads derived from the sequencing of mRNA neoplastic cells. The tool detects the main clone that characterises the tissue of interest by recognizing the most abundant V(D)J rearrangement among the existing ones in the sample under study. The exact sequence of the clone identified is capable of accounting for the modifications introduced by the enzymatic processes. The proposed tool overcomes limitations of currently available lymphocyte rearrangements recognition methods, working on a single sequence at a time, that are not applicable to high-throughput sequencing data. In this work, VDJSeq-Solver has been applied to correctly detect the main clone and identify its sequence on five Mantle Cell Lymphoma samples; then the tool has been tested on twelve Diffuse Large B-Cell Lymphoma samples. In order to comply with the privacy, ethics and intellectual property policies of the University Hospital and the University of Verona, data is available upon request to ti.rvinu.oeneta@itnetu.otroppus after signing a mandatory Materials Transfer Agreement. VDJSeq-Solver JAVA/Perl/Bash software implementation is free and available at http://eda.polito.it/VDJSeq-Solver/.