A complex of RAG-1 and RAG-2 proteins persists on DNA after single-strand cleavage at V(D)J recombination signal sequences

Sequence-dependent dynamics of synthetic and endogenous RSSs in V(D)J recombination

Developing lymphocytes of jawed vertebrates cleave and combine distinct gene segments to assemble antigen-receptor genes. This process called V(D)J recombination that involves the RAG recombinase binding and cutting recombination signal sequences (RSSs) composed of conserved heptamer and nonamer sequences flanking less well-conserved 12- or 23-bp spacers. Little quantitative information is known about the contributions of individual RSS positions over the course of the RAG-RSS interaction. We employ a single-molecule method known as tethered particle motion to track the formation, lifetime and cleavage of individual RAG-12RSS-23RSS paired complexes (PCs) for numerous synthetic and endogenous 12RSSs. We reveal that single-bp changes, including in the 12RSS spacer, can significantly and selectively alter PC formation or the probability of RAG-mediated cleavage in the PC. We find that some rarely used endogenous gene segments can be mapped directly to poor RAG binding on their adjacent 12RSSs. Finally, we find that while abrogating RSS nicking with Ca2+ leads to substantially shorter PC lifetimes, analysis of the complete lifetime distributions of any 12RSS even on this reduced system reveals that the process of exiting the PC involves unidentified molecular details whose involvement in RAG-RSS dynamics are crucial to quantitatively capture kinetics in V(D)J recombination.

CRISPR-Cas9 genome editing induces megabase-scale chromosomal truncations

CRISPR-Cas9 is a promising technology for genome editing. Here we use Cas9 nuclease-induced double-strand break DNA (DSB) at the UROS locus to model and correct congenital erythropoietic porphyria. We demonstrate that homology-directed repair is rare compared with NHEJ pathway leading to on-target indels and causing unwanted dysfunctional protein. Moreover, we describe unexpected chromosomal truncations resulting from only one Cas9 nuclease-induced DSB in cell lines and primary cells by a p53-dependent mechanism. Altogether, these side effects may limit the promising perspectives of the CRISPR-Cas9 nuclease system for disease modeling and gene therapy. We show that the single nickase approach could be safer since it prevents on- and off-target indels and chromosomal truncations. These results demonstrate that the single nickase and not the nuclease approach is preferable, not only for modeling disease but also and more importantly for the safe management of future CRISPR-Cas9-mediated gene therapies.

DNA melting initiates the RAG catalytic pathway

The mechanism for initiating DNA cleavage by DDE-family enzymes, including the RAG endonuclease, which initiates V(D)J recombination, is not well understood. Here we report six cryo-EM structures of zebrafish RAG in complex with one or two intact recombination signal sequences (RSSs), at up to 3.9-Å resolution. Unexpectedly, these structures reveal DNA melting at the heptamer of the RSSs, thus resulting in a corkscrew-like rotation of coding-flank DNA and the positioning of the scissile phosphate in the active site. Substrate binding is associated with dimer opening and a piston-like movement in RAG1, first outward to accommodate unmelted DNA and then inward to wedge melted DNA. These precleavage complexes show limited base-specific contacts of RAG at the conserved terminal CAC/GTG sequence of the heptamer, thus suggesting conservation based on a propensity to unwind. CA and TG overwhelmingly dominate terminal sequences in transposons and retrotransposons, thereby implicating a universal mechanism for DNA melting during the initiation of retroviral integration and DNA transposition.

Modeling altered T-cell development with induced pluripotent stem cells from patients with RAG1-dependent immune deficiencies

Primary immunodeficiency diseases comprise a group of heterogeneous genetic defects that affect immune system development and/or function. Here we use in vitro differentiation of human induced pluripotent stem cells (iPSCs) generated from patients with different recombination-activating gene 1 (RAG1) mutations to assess T-cell development and T-cell receptor (TCR) V(D)J recombination. RAG1-mutants from severe combined immunodeficient (SCID) patient cells showed a failure to sustain progression beyond the CD3(--)CD4(-)CD8(-)CD7(+)CD5(+)CD38(-)CD31(-/lo)CD45RA(+) stage of T-cell development to reach the CD3(-/+)CD4(+)CD8(+)CD7(+)CD5(+)CD38(+)CD31(+)CD45RA(-) stage. Despite residual mutant RAG1 recombination activity from an Omenn syndrome (OS) patient, similar impaired T-cell differentiation was observed, due to increased single-strand DNA breaks that likely occur due to heterodimers consisting of both an N-terminal truncated and a catalytically dead RAG1. Furthermore, deep-sequencing analysis of TCR-β (TRB) and TCR-α (TRA) rearrangements of CD3(-)CD4(+)CD8(-) immature single-positive and CD3(+)CD4(+)CD8(+) double-positive cells showed severe restriction of repertoire diversity with preferential usage of few Variable, Diversity, and Joining genes, and skewed length distribution of the TRB and TRA complementary determining region 3 sequences from SCID and OS iPSC-derived cells, whereas control iPSCs yielded T-cell progenitors with a broadly diversified repertoire. Finally, no TRA/δ excision circles (TRECs), a marker of TRA/δ locus rearrangements, were detected in SCID and OS-derived T-lineage cells, consistent with a pre-TCR block in T-cell development. This study compares human T-cell development of SCID vs OS patients, and elucidates important differences that help to explain the wide range of immunologic phenotypes that result from different mutations within the same gene of various patients.

Differential reaction kinetics, cleavage complex formation, and nonamer binding domain dependence dictate the structure-specific and sequence-specific nuclease activity of RAGs

During V(D)J recombination, RAG (recombination-activating gene) complex cleaves DNA based on sequence specificity. Besides its physiological function, RAG has been shown to act as a structure-specific nuclease. Recently, we showed that the presence of cytosine within the single-stranded region of heteroduplex DNA is important when RAGs cleave on DNA structures. In the present study, we report that heteroduplex DNA containing a bubble region can be cleaved efficiently when present along with a recombination signal sequence (RSS) in cis or trans configuration. The sequence of the bubble region influences RAG cleavage at RSS when present in cis. We also find that the kinetics of RAG cleavage differs between RSS and bubble, wherein RSS cleavage reaches maximum efficiency faster than bubble cleavage. In addition, unlike RSS, RAG cleavage at bubbles does not lead to cleavage complex formation. Finally, we show that the "nonamer binding region," which regulates RAG cleavage on RSS, is not important during RAG activity in non-B DNA structures. Therefore, in the current study, we identify the possible mechanism by which RAG cleavage is regulated when it acts as a structure-specific nuclease.

How does DNA break during chromosomal translocations?

Chromosomal translocations are one of the most common types of genetic rearrangements and are molecular signatures for many types of cancers. They are considered as primary causes for cancers, especially lymphoma and leukemia. Although many translocations have been reported in the last four decades, the mechanism by which chromosomes break during a translocation remains largely unknown. In this review, we summarize recent advances made in understanding the molecular mechanism of chromosomal translocations.

Cytosines, but not purines, determine recombination activating gene (RAG)-induced breaks on heteroduplex DNA structures: implications for genomic instability

The sequence specificity of the recombination activating gene (RAG) complex during V(D)J recombination has been well studied. RAGs can also act as structure-specific nuclease; however, little is known about the mechanism of its action. Here, we show that in addition to DNA structure, sequence dictates the pattern and efficiency of RAG cleavage on altered DNA structures. Cytosine nucleotides are preferentially nicked by RAGs when present at single-stranded regions of heteroduplex DNA. Although unpaired thymine nucleotides are also nicked, the efficiency is many fold weaker. Induction of single- or double-strand breaks by RAGs depends on the position of cytosines and whether it is present on one or both of the strands. Interestingly, RAGs are unable to induce breaks when adenine or guanine nucleotides are present at single-strand regions. The nucleotide present immediately next to the bubble sequence could also affect RAG cleavage. Hence, we propose "C((d))C((S))C((S))" (d, double-stranded; s, single-stranded) as a consensus sequence for RAG-induced breaks at single-/double-strand DNA transitions. Such a consensus sequence motif is useful for explaining RAG cleavage on other types of DNA structures described in the literature. Therefore, the mechanism of RAG cleavage described here could explain facets of chromosomal rearrangements specific to lymphoid tissues leading to genomic instability.

Accessibility of chromosomal recombination breaks in nuclei of wild-type and DNA-PKcs-deficient cells

V(D)J recombination is a highly regulated process, proceeding from a site-specific cleavage to an imprecise end joining. After the DNA excision catalyzed by the recombinase encoded by recombination activating genes 1 and 2 (RAG1/2), newly generated recombination ends are believed held by a post-cleavage complex (PC) consisting of RAG1/2 proteins, and are subsequently resolved by non-homologous end joining (NHEJ) machinery. The relay of these ends from PC to NHEJ remains elusive. It has been speculated that NHEJ factors modify the RAG1/2-PC to gain access to the ends or act on free ends after the disassembly of the PC. Thus, recombination ends may either be retained in a complex throughout the recombination process or left as unprotected free ends after cleavage, a condition that may permit an alternative, non-classical NHEJ end joining pathway. To directly test these scenarios on recombination induced chromosomal breaks, we have developed a recombination end protection assay to monitor the accessibility of recombination ends to exonuclease-V in intact nuclei. We demonstrate that these ends are well protected in the nuclei of wild-type cells, suggesting a seamless cleavage-joining reaction. However, divergent end protection of coding versus signal ends was found in cells derived from severe combined immunodeficient (scid) mice that are defective in the catalytic subunit of DNA-dependent protein kinase (DNA-PKcs). While signal ends are resistant, opened coding ends are susceptible to enzymatic modification. Our data suggests a role of DNA-PKcs in protecting chromosomal coding ends. Furthermore, using recombination inducible scid cell lines, we demonstrate that conditional protection of coding ends is inversely correlated with the level of their resolution, i.e., the greater the accessibility of the coding ends, the higher level of coding joints formed. Taken together, our findings provide important insights into the resolution of recombination ends by error-prone alternative NHEJ pathways.

A non-sequence-specific DNA binding mode of RAG1 is inhibited by RAG2

RAG1 and RAG2 proteins catalyze site-specific DNA cleavage reactions in V(D)J recombination, a process that assembles antigen receptor genes from component gene segments during lymphocyte development. The first step towards the DNA cleavage reaction is the sequence-specific association of the RAG proteins with the conserved recombination signal sequence (RSS), which flanks each gene segment in the antigen receptor loci. Questions remain as to the contribution of each RAG protein to recognition of the RSS. For example, while RAG1 alone is capable of recognizing the conserved elements of the RSS, it is not clear if or how RAG2 may enhance sequence-specific associations with the RSS. To shed light on this issue, we examined the association of RAG1, with and without RAG2, with consensus RSS versus non-RSS substrates using fluorescence anisotropy and gel mobility shift assays. The results indicate that while RAG1 can recognize the RSS, the sequence-specific interaction under physiological conditions is masked by a high-affinity non-sequence-specific DNA binding mode. Significantly, addition of RAG2 effectively suppressed the association of RAG1 with non-sequence-specific DNA, resulting in a large differential in binding affinity for the RSS versus the non-RSS sites. We conclude that this represents a major means by which RAG2 contributes to the initial recognition of the RSS and that, therefore, association of RAG1 with RAG2 is required for effective interactions with the RSS in developing lymphocytes.

Quantitative analyses of RAG-RSS interactions and conformations revealed by atomic force microscopy

During V(D)J recombination, site specific DNA excision is dictated by the binding of RAG1/2 proteins to the conserved recombination signal sequence (RSS) within the genome. The interaction between RAG1/2 and RSS is thought to involve a large DNA distortion that is permissive for DNA cleavage. In this study, using atomic force microscopy imaging (AFM), we analyzed individual RAG-RSS complexes, in which the bending angle of RAG-associated RSS substrates could be visualized and quantified. We provided the quantitative measurement on the conformations of specific RAG-12RSS complexes. Previous data indicating the necessity of RAG2 for recombination implies a structural role in the RAG-RSS complex. Surprisingly, however, no significant difference was observed in conformational bending with AFM between RAG1-12RSS and RAG1/2-12RSS. RAG1 was found sufficient to induce DNA bending, and the addition of RAG2 did not change the bending profile. In addition, a prenicked 12RSS bound by RAG1/2 proteins displayed a conformation similar to the one observed with the intact 12RSS, implying that no greater DNA bending occurs after the nicking step in the signal complex. Taken together, the quantitative AFM results on the components of the recombinase emphasize a tightly held complex with a bend angle value near 60 degrees , which may be a prerequisite step for the site-specific nicking by the V(D)J recombinase.

The structure-specific nicking of small heteroduplexes by the RAG complex: implications for lymphoid chromosomal translocations

During V(D)J recombination, the RAG complex binds at recombination signal sequences and creates double-strand breaks. In addition to this sequence-specific recognition of the RSS, the RAG complex has been shown to be a structure-specific nuclease, cleaving 3' overhangs and 3' flaps, and, more recently, 10 nucleotides (nt) bubble (heteroduplex) structures. Here, we assess the smallest size heteroduplex that core and full-length RAGs can cleave. We also test whether bubbles adjacent to a partial RSS are nicked any differently or any more efficiently than bubbles that are surrounded by random sequence. These points are important in considering what types and what size of non-B DNA structure that the RAG complex can nick, and this helps assess the role of the RAG complex in mediating lymphoid chromosomal translocations. We find that the smallest bubble nicked by the RAG complex is 3nt, and proximity to a partial or full RSS sequence does not affect the nicking by RAGs. RAG nicking efficiency increases with the size of the heteroduplex and is only about two-fold less efficient than an RSS when the bubble is 6nt. We consider these findings in the context of RAG nicking at non-B DNA structures in lymphoid chromosomal translocations.

DNA structures at chromosomal translocation sites

It has been unclear why certain defined DNA regions are consistently sites of chromosomal translocations. Some of these are simply sequences of recognition by endogenous recombination enzymes, but most are not. Recent progress indicates that some of the most common fragile sites in human neoplasm assume non-B DNA structures, namely deviations from the Watson-Crick helix. Because of the single strandedness within these non-B structures, they are vulnerable to structure-specific nucleases. Here we summarize these findings and integrate them with other recent data for non-B structures at sites of consistent constitutional chromosomal translocations.

Coding joint diversity in mature and immature B-cell lines

Antigen receptor gene rearrangement is regulated by many factors in B and T lymphocytes. The sequences of the gene segments themselves, their associated recombination signal sequences (RSS), expression of the RAG genes and the chromatin accessibility of the particular gene segments to be rearranged all influence the outcome of recombination and thus antigen receptor diversity. In the present study, we have evaluated the effect of variations in RAG activity level on the junctional diversity of coding joint sequences. Using the pre-B-like 204-1-8 and the mature B DR3 cell lines under different transfection conditions, we were able to investigate recombination activity levels that varied 100-fold. We evaluated the sequences of the coding joints for junctional diversity resulting from nucleotide addition or deletion. Surprisingly, we found that the sequence of coding joints of these recombinants did not exhibit significant variation despite the large difference in recombination frequency. Our results indicate that the fidelity of the joining phase of V(D)J recombination is not jeopardized by varying RAG activity.

Double-strand break formation by the RAG complex at the bcl-2 major breakpoint region and at other non-B DNA structures in vitro

The most common chromosomal translocation in cancer, t(14;18) at the 150-bp bcl-2 major breakpoint region (Mbr), occurs in follicular lymphomas. The bcl-2 Mbr assumes a non-B DNA conformation, thus explaining its distinctive fragility. This non-B DNA structure is a target of the RAG complex in vivo, but not because of its primary sequence. Here we report that the RAG complex generates at least two independent nicks that lead to double-strand breaks in vitro, and this requires the non-B DNA structure at the bcl-2 Mbr. A 3-bp mutation is capable of abolishing the non-B structure formation and the double-strand breaks. The observations on the bcl-2 Mbr reflect more general properties of the RAG complex, which can bind and nick at duplex-single-strand transitions of other non-B DNA structures, resulting in double-strand breaks in vitro. Hence, the present study reveals novel insight into a third mechanism of action of RAGs on DNA, besides the standard heptamer/nonamer-mediated cleavage in V(D)J recombination and the in vitro transposase activity.

Putting the pieces together: identification and characterization of structural domains in the V(D)J recombination protein RAG1

V(D)J recombination generates functional immunoglobulin and T-cell receptor genes in developing lymphocytes. The recombination-activating gene 1 (RAG1) and RAG2 proteins catalyze site-specific DNA cleavage in this recombination process. Biochemical studies have identified catalytically active regions of each protein, referred to as the core regions. Here, we review our progress in the identification and characterization, in biophysical and biochemical terms, of topologically independent domains within both the non-core and core regions of RAG1. Previous characterizations of a structural domain identified in the non-core region of RAG1 from residues 265-380, referred to as the zinc-binding dimerization domain, are discussed. This domain contains two zinc-binding motifs, a RING finger and a C2H2 zinc finger. Core RAG1 also consists of multiple domains, each of which functions individually in one or more of the essential macromolecular interactions formed by the intact core protein. Two structural domains referred to as the central and the C-terminal domains that include residues 528-760 and 761-979 of RAG1, respectively, have been identified. The interactions of the central and C-terminal domains in core RAG1 with the recombination signal sequence (RSS) have contributed additional insight to a developing model for the RAG1-RSS complex.

Synapsis of recombination signal sequences located in cis and DNA underwinding in V(D)J recombination

V(D)J recombination requires binding and synapsis of a complementary (12/23) pair of recombination signal sequences (RSSs) by the RAG1 and RAG2 proteins, aided by a high-mobility group protein, HMG1 or HMG2. Double-strand DNA cleavage within this synaptic, or paired, complex is thought to involve DNA distortion or melting near the site of cleavage. Although V(D)J recombination normally occurs between RSSs located on the same DNA molecule (in cis), all previous studies that directly assessed RSS synapsis were performed with the two DNA substrates in trans. To overcome this limitation, we have developed a facilitated circularization assay using DNA substrates of reduced length to assess synapsis of RSSs in cis. We show that a 12/23 pair of RSSs is the preferred substrate for synapsis of cis RSSs and that the efficiency of pairing is dependent upon RAG1-RAG2 stoichiometry. Synapsis in cis occurs rapidly and is kinetically favored over synapsis of RSSs located in trans. This experimental system also allowed the generation of underwound DNA substrates containing pairs of RSSs in cis. Importantly, we found that the RAG proteins cleave such substrates substantially more efficiently than relaxed substrates and that underwinding may enhance RSS synapsis as well as RAG1/2-mediated catalysis. The energy stored in such underwound substrates may be used in the generation of DNA distortion and/or protein conformational changes needed for synapsis and cleavage. We propose that this unwinding is uniquely sensed during synapsis of an appropriate 12/23 pair of RSSs.

RAG proteins shepherd double-strand breaks to a specific pathway, suppressing error-prone repair, but RAG nicking initiates homologous recombination

The two major pathways for repairing double-strand breaks (DSBs), homologous recombination and nonhomologous end joining (NHEJ), have traditionally been thought to operate in different stages of the cell cycle. This division of labor is not absolute, however, and precisely what governs the choice of pathway to repair a given DSB has remained enigmatic. We pursued this question by studying the site-specific DSBs created during V(D)J recombination, which relies on classical NHEJ to repair the broken ends. We show that mutations that form unstable RAG postcleavage complexes allow DNA ends to participate in both homologous recombination and the error-prone alternative NHEJ pathway. By abrogating a key function of the complex, these mutations reveal it to be a molecular shepherd that guides DSBs to the proper pathway. We also find that RAG-mediated nicks efficiently stimulate homologous recombination and discuss the implications of these findings for oncogenic chromosomal rearrangements, evolution, and gene targeting.

The central domain of core RAG1 preferentially recognizes single-stranded recombination signal sequence heptamer

RAG1 and RAG2 initiate V(D)J recombination by introducing DNA double strand breaks between each selected gene segment and its bordering recombination signal sequence (RSS) in a two-step mechanism in which the DNA is first nicked, followed by hairpin formation. The RSS consists of a conserved nonamer and heptamer sequence, in which the latter borders the site of DNA cleavage. A region within RAG1, referred to as the central domain (residues 528-760 of 1040 in the full-length protein), has been shown previously to bind specifically to the double-stranded (ds) RSS heptamer, but with both weak specificity and affinity. However, additional investigations into the RAG1-RSS heptamer interaction are required because the DNA substrate forms intermediate conformations during the V(D)J recombination reaction. These include the nicked and hairpin products, as well as likely base unpairing to produce single-stranded (ss) DNA near the cleavage site. Here, it was determined that although the central domain showed substantially higher binding affinity for ss and nicked versus ds substrate, the interaction with ss RSS was particularly robust. In addition, the central domain bound with greater sequence specificity to the ss RSS heptamer than to the ds form. This study provides important insight into the V(D)J recombination reaction, specifically that significant interaction of the RSS heptamer with RAG1 occurs only after the induction of conformational changes at the RSS heptamer.

A modified digestion-circularization PCR (DC-PCR) approach to detect hypermutation-associated DNA double-strand breaks

Hypermutation of immunoglobulin variable region genes occurs in B cells during an immune response, and is vital for the development of high-affinity antibodies. The molecular mechanism of the hypermutation reaction is unknown, but it seems to correlate with the generation of locus-specific, double-strand breaks. These DNA breaks have been measured by ligation-mediated polymerase chain reaction (LM-PCR), a technique that relies upon the ligation of a small linker to DNA breaks followed by the specific amplification of such breaks using combinations of locus- and linker-specific primers. Here, we describe a modified version of the digestion-circularization PCR (DC-PCR) technique, which can be used to amplify and measure DNA breaks directly.

Binding of inositol hexakisphosphate (IP6) to Ku but not to DNA-PKcs

The nonhomologous DNA end joining (NHEJ) pathway is responsible for repairing a major fraction of double strand DNA breaks in somatic cells of all multicellular eukaryotes. As an indispensable protein in the NHEJ pathway, Ku has been hypothesized to be the first protein to bind at the DNA ends generated at a double strand break being repaired by this pathway. When bound to a DNA end, Ku improves the affinity of another DNA end-binding protein, DNA-PK(cs), to that end. The Ku.DNA-PK(cs) complex is often termed the DNA-PK holoenzyme. It was recently shown that myo-inositol hexakisphosphate (IP(6)) stimulates the joining of complementary DNA ends in a cell free system. Moreover, the binding data suggested that IP(6) bound to DNA-PK(cs) (not to Ku). Here we clearly show that, in fact, IP(6) associates not with DNA-PK(cs), but rather with Ku. Furthermore, the binding of DNA ends and IP(6) to Ku are independent of each other. The possible relationship between inositol phosphate metabolism and DNA repair is discussed in light of these findings.

The RAG proteins in V(D)J recombination: more than just a nuclease

V(D)J recombination is the process that generates the diversity among T cell receptors and is one of three mechanisms that contribute to the diversity of antibodies in the vertebrate immune system. The mechanism requires precise cutting of the DNA at segment boundaries followed by rejoining of particular pairs of the resulting termini. The imprecision of aspects of the joining reaction contributes significantly to increasing the variability of the resulting functional genes. Signal sequences target DNA recombination and must participate in a highly ordered protein-DNA complex in order to limit recombination to appropriate partners. Two proteins, RAG1 and RAG2, together form the nuclease that cleaves the DNA at the border of the signal sequences. Additional roles of these proteins in organizing the reaction complex for subsequent steps are explored.

In vivo and in vitro studies of immunoglobulin gene somatic hypermutation

Following antigen encounter, two distinct processes modify immunoglobulin genes. The variable region is diversified by somatic hypermutation while the constant region may be changed by class-switch recombination. Although both genetic events can occur concurrently within germinal centre B cells, there are examples of each occurring independently of the other. Here we compare the contributions of class-switch recombination and somatic hypermutation to the diversification of the serum immunoglobulin repertoire and review evidence that suggests that, despite clear differences, the two processes may share some aspects of their mechanism in common.

The nicking step in V(D)J recombination is independent of synapsis: implications for the immune repertoire

In all of the transposition reactions that have been characterized thus far, synapsis of two transposon ends is required before any catalytic steps (strand nicking or strand transfer) occur. In V(D)J recombination, there have been inconclusive data concerning the role of synapsis in nicking. Synapsis between two 12-substrates or between two 23-substrates has not been ruled out in any studies thus far. Here we provide the first direct tests of this issue. We find that immobilization of signals does not affect their nicking, even though hairpinning is affected in a manner reflecting its known synaptic requirement. We also find that nicking is kinetically a unireactant enzyme-catalyzed reaction. Time courses are no different between nicking seen for a 12-substrate alone and a reaction involving both a 12- and a 23-substrate. Hence, synapsis is neither a requirement nor an effector of the rate of nicking. These results establish V(D)J recombination as the first example of a DNA transposition-type reaction in which catalytic steps begin prior to synapsis, and the results have direct implications for the order of the steps in V(D)J recombination, for the contribution of V(D)J recombination nicks to genomic instability, and for the diversification of the immune repertoire.

Activation of V(D)J recombination induces the formation of interlocus joints and hybrid joints in scid pre-B-cell lines

V(D)J recombination is the mechanism by which antigen receptor genes are assembled. The site-specific cleavage mediated by RAG1 and RAG2 proteins generates two types of double-strand DNA breaks: blunt signal ends and covalently sealed hairpin coding ends. Although these DNA breaks are mainly resolved into coding joints and signal joints, they can participate in a nonstandard joining process, forming hybrid and open/shut joints that link coding ends to signal ends. In addition, the broken DNA molecules excised from different receptor gene loci could potentially be joined to generate interlocus joints. The interlocus recombination process may contribute to the translocation between antigen receptor genes and oncogenes, leading to malignant transformation of lymphocytes. To investigate the underlying mechanisms of these nonstandard recombination events, we took advantage of recombination-inducible cell lines derived from scid homozygous (s/s) and scid heterozygous (s/+) mice by transforming B-cell precursors with a temperature-sensitive Abelson murine leukemia virus mutant (ts-Ab-MLV). We can manipulate the level of recombination cleavage and end resolution by altering the cell culture temperature. By analyzing various recombination products in scid and s/+ ts-Ab-MLV transformants, we report in this study that scid cells make higher levels of interlocus and hybrid joints than their normal counterparts. These joints arise concurrently with the formation of intralocus joints, as well as with the appearance of opened coding ends. The junctions of these joining products exhibit excessive nucleotide deletions, a characteristic of scid coding joints. These data suggest that an inability of scid cells to promptly resolve their recombination ends exposes the ends to a random joining process, which can conceivably lead to chromosomal translocations.

Postcleavage sequence specificity in V(D)J recombination

Unintended DNA rearrangements in a differentiating lymphocyte can have severe, oncogenic consequences, but the mechanisms for avoiding pathogenic outcomes in V(D)J recombination are not well understood. The first level at which fidelity is instituted is in discrimination by the recombination proteins between authentic and inauthentic recombination signal sequences. Nevertheless, this discrimination is not absolute and cannot fully eliminate targeting errors. To learn more about the basis of specificity during V(D)J recombination, we have investigated whether it is possible for the recombination machinery to detect an inaccurately targeted sequence subsequent to cleavage. These studies indicate that even postcleavage steps in V(D)J recombination are sequence specific and that noncanonical sequences will not efficiently support the resolution of recombination intermediates in vivo. Accordingly, interventions after a mistargeting event conceivably occur at a late stage in the joining process and the likelihood may well be crucial to enforcing fidelity during antigen receptor gene rearrangement.

Evidence that terminal deoxynucleotidyltransferase expression plays a role in Ig heavy chain gene segment utilization

TdT is a nuclear enzyme that catalyzes the addition of random nucleotides at Ig and TCR V(D)J junctions. In this paper we analyze human IgH rearrangements generated from transgenic minilocus mice in the presence or absence of TdT. In the absence of TdT, the pseudo-VH gene segment present in the minilocus is rearranged dramatically more frequently. Additionally, JH6 gene segment utilization is increased as well as the number of rearrangements involving only VH and JH gene segments. Thus, the recombination of IgH gene segments that are flanked by 23-nt spacer recombination signal sequences may be influenced by TdT expression. Extensive analysis indicates that these changes are independent of antigenic selection and cannot be explained by homology-mediated recombination. Thus, the role played by TdT may be more extensive than previously thought.

Metabolism of recombination coding ends in scid cells

V(D)J recombination cleavage generates two types of dsDNA breaks: blunt signal ends and covalently sealed hairpin coding ends. Although signal ends can be directly ligated to form signal joints, hairpin coding ends need to be opened and subsequently processed before being joined. However, the underlying mechanism of coding end resolution remains undefined. The current study attempts to delineate this process by analyzing various structures of coding ends made in situ from recombination-inducible pre-B cell lines of both normal and scid mice. These cell lines were derived by transformation of B cell precursors with the temperature-sensitive Abelson murine leukemia virus. Our kinetic analysis revealed that under conditions permissive to scid transformants, hairpin coding ends could be nicked to generate 3' overhangs and then processed into blunt ends. The final joining of these blunt ends followed the same kinetics as signal joint formation. The course of this process is in sharp contrast to coding end resolution in scid heterozygous transformants that express the catalytic subunit of DNA-dependent protein kinase, in which hairpin end opening, processing, and joining proceeded very rapidly and appeared to be closely linked. Furthermore, we demonstrated that the opening of hairpin ends in scid cells could be manipulated by different culture conditions, which ultimately influenced not only the level and integrity of the newly formed coding joints, but also the extent of microhomology at the coding junctions. These results are discussed in the context of scid leaky recombination.

Intermolecular V(D)J recombination

V(D)J recombination plays a prominent role in the generation of the antigen receptor repertoires of B and T lymphocytes. It is also likely to be involved in the formation of chromosomal translocations, some of which may result from interchromosomal recombination. We have investigated the potential of the V(D)J recombination machinery to perform intermolecular recombination between two plasmids, either unlinked or linked by catenation. In either case, recombination occurs in trans to yield signal and coding joints, and the results do not support the existence of a mechanistic block to the formation of coding joints in trans. Instead, we observe that linearization of the substrate, which does not alter the cis or trans status of the recombination signals, causes a specific and dramatic reduction in coding joint formation. This unexpected result leads us to propose a "release and recapture" model for V(D)J recombination in which coding ends are frequently released from the postcleavage complex and the efficiency of coding joint formation is influenced by the efficiency with which such ends are recaptured by the complex. This implies the existence of mechanisms, operative during recombination of chromosomal substrates, that act to prevent coding end release or to facilitate coding end recapture.

RAG1 and RAG2 cooperate in specific binding to the recombination signal sequence in vitro

An essential step in the development of the vertebrate immune system is the DNA level rearrangement of the antigen receptor genes. This process, termed "V(D)J recombination," begins with DNA cleavage at the appropriate sites mediated by the two proteins RAG1 and RAG2. We report here that the two proteins cooperate to bind DNA with significantly higher specificity than either protein alone. Gel purification of the triple complex is performed in the absence of any cross-linking agents. Both proteins remain present in the complex, and UV cross-linking using iodouridine-containing probes shows that RAG1 makes close contacts in both the heptamer and nonamer motifs. The two proteins are also shown to associate with each other in the absence of any DNA. These findings refine our understanding of the protein-DNA interactions that accompany cleavage at the recombination signals.

Formation of coding joints in V(D)J recombination-inducible severe combined immune deficient pre-B cell lines

Characterization of the severe combined immune deficient (scid) defect in the recombination process has provided many insights into the underlying mechanisms of variable (diversity) joining recombination. By using recombination-inducible scid pre-B cell lines transformed with the temperature-sensitive Abelson-murine leukemia virus, we show that large quantities of recombination intermediates can be generated, and their resolution can be followed during further cell culture. In this study, we demonstrate that the ability of these scid pre-B cell lines to resolve coding ends depends on the cell culture temperature. At the nonpermissive temperature of 39 degreesC, scid pre-B cell lines fail to form coding joints and contain mostly unresolved hairpin-coding ends. Once the cell culture is returned to the permissive temperature of 33 degreesC, these same cells make a significant amount of coding joints concomitant with the disappearance of hairpin-coding ends. Thus, the scid cells are capable of resolving coding ends under certain culture conditions. However, the majority of the recovered coding joints contains extensive deletions, indicating that the temperature-dependent resolution of coding ends is still scid-like. Our results suggest that the inability of scid cells to promptly nick hairpin-coding ends may lead to aberrant joining in these cells.

Warner-Lambert/Parke-Davis Award Lecture. Pathological and physiological double-strand breaks: roles in cancer, aging, and the immune system

Pathological agents such as ionizing radiation and oxidative free radicals can cause breaks in both strands of the DNA at a given site (double-strand break). This is the most serious type of DNA damage because neither strand is able to provide physical integrity or information content, as would be the case for single-strand DNA damage where one strand of the duplex remains intact. The repair of such breaks usually results in an irreversible alteration of the DNA. Two physiological forms of intentional double-strand (ds) DNA breakage and rejoining occur during lymphoid differentiation. One is V(D)J recombination occurring during early B and T cell development, and the other is class switch recombination, occurring exclusively in mature B cells. The manner in which physiological and most pathological double-strand DNA breaks are rejoined to restore chromosomal integrity are the same. Defects during the phases in which pathological or physiological breaks are generated or in which they are joined can result in chromosomal translocations or loss of genetic information at the site of breakage. Such events are the first step in some cancers and may be a key contributor to changes in DNA with age. Inherited defects in this process can result in severe combined immune deficiency. Hence, pathological and physiological DNA double-strand breaks are related to immune defects and cancer and may be one of the key ways in which DNA is damaged during aging.

The RAG-HMG1 complex enforces the 12/23 rule of V(D)J recombination specifically at the double-hairpin formation step

A central unanswered question concerning the initial phases of V(D)J recombination has been at which step the 12/23 rule applies. This rule, which governs which variable (V), diversity (D), and joining (J) segments are able to pair during recombination, could operate at the level of signal sequence synapsis after RAG-HMG1 complex binding, signal nicking, or signal hairpin formation. It has also been unclear whether additional proteins are required to achieve adherence to the 12/23 rule. We developed a novel system for the detailed biochemical analysis of the 12/23 rule by using an oligonucleotide-based substrate that can include two signals. Under physiologic conditions, we found that the complex of RAG1, RAG2, and HMG1 can successfully recapitulate the 12/23 rule with the same specificity as that seen intracellularly and in crude extracts. The cleavage complex can bind and nick 12x12 and 23x23 substrates as well as 12x23 substrates. However, hairpin formation occurs at both of the signals only on 12x23 substrates. Moreover, under physiologic conditions, the presence of a partner 23-bp spacer suppresses single-site hairpin formation at a 12-bp spacer and vice versa. Hence, this study illustrates that synapsis suppresses single-site reactions, thereby explaining the high physiologic ratio of paired versus unpaired V(D)J recombination events in lymphoid cells.

Distinct roles of RAG1 and RAG2 in binding the V(D)J recombination signal sequences

The RAG1 and RAG2 proteins initiate V(D)J recombination by introducing double-strand breaks at the border between a recombination signal sequence (RSS) and a coding segment. To understand the distinct functions of RAG1 and RAG2 in signal recognition, we have compared the DNA binding activities of RAG1 alone and RAG1 plus RAG2 by gel retardation and footprinting analyses. RAG1 exhibits only a three- to fivefold preference for binding DNA containing an RSS over random sequence DNA. Although direct binding of RAG2 by itself was not detected, the presence of both RAG1 and RAG2 results in the formation of a RAG1-RAG2-DNA complex which is more stable and more specific than the RAG1-DNA complex and is active in V(D)J cleavage. These results suggest that biologically effective discrimination between an RSS and nonspecific sequences requires both RAG1 and RAG2. Unlike the binding of RAG1 plus RAG2, RAG1 can bind to DNA in the absence of a divalent metal ion and does not require the presence of coding flank sequence. Footprinting of the RAG1-RAG2 complex with 1, 10-phenanthroline-copper and dimethyl sulfate protection reveal that both the heptamer and the nonamer are involved. The nonamer is protected, with extensive protein contacts within the minor groove. Conversely, the heptamer is rendered more accessible to chemical attack, suggesting that binding of RAG1 plus RAG2 distorts the DNA near the coding/signal border.

Antigen receptor gene rearrangement

Two specialized forms of site-directed double-strand (ds) DNA breakage and rejoining are part of the physiologic program of lymphocytes. One is recombination of the V, D and J gene sequences, termed V(D)J recombination, occurring during early B- and T-cell development, and the other is class-switch recombination occurring exclusively in mature B cells. For V(D)J recombination significant progress has been made recently elucidating the biochemistry of the reaction. In particular our understanding of how DNA ds breaks are both generated and rejoined has increased. For class-switch recombination no definitive information is known about the nucleases required for making the ds breaks, but recent evidence suggests that the joining phase shares activities also required for V(D)J recombination and general DNA ds break repair.