An interdomain boundary in RAG1 facilitates cooperative binding to RAG2 in formation of the V(D)J recombinase complex

V(D)J recombination assembles functional antigen receptor genes during lymphocyte development. Formation of the recombination complex containing the recombination activating proteins, RAG1 and RAG2, is essential for the site-specific DNA cleavage steps in V(D)J recombination. However, little is known concerning how complex formation leads to a catalytically-active complex. Here, we combined limited proteolysis and mass spectrometry methods to identify regions of RAG1 that are sequestered upon association with RAG2. These results show that RAG2 bridges an interdomain boundary in the catalytic region of RAG1. In a second approach, mutation of RAG1 residues within the interdomain boundary were tested for disruption of RAG1:RAG2 complex formation using fluorescence-based pull down assays. The core RAG1 mutants demonstrated varying effects on complex formation with RAG2. Interestingly, two mutants showed opposing results for the ability to interact with core versus full length RAG2, indicating that the non-core region of RAG2 participates in binding to core RAG1. Significantly, all of the RAG1 interdomain mutants demonstrated altered stoichiometries of the RAG complexes, with an increased number of RAG2 per RAG1 subunit compared to the wild type complex. Based on our results, we propose that interaction of RAG2 with RAG1 induces cooperative interactions of multiple binding sites, induced through conformational changes at the RAG1 interdomain boundary, and resulting in formation of the DNA cleavage active site.     

ATP-dependent remodeling by SWI/SNF and ISWI proteins stimulates V(D)J cleavage of 5 S arrays

Control of V(D)J recombination is critical for the generation of a fully developed immune repertoire. The molecular mechanisms underlying the regulation of antigen receptor gene assembly are beginning to be revealed. Here we studied the influence of chromatin modifications on V(D)J cleavage of a polynucleosomal substrate, in which V(D)J cleavage is greatly reduced compared with naked DNA. ATP-dependent remodeling by human SWI/SNF (hSWI/SNF) in the presence of HMG1 led to a substantial increase of cleavage by the recombination activation gene (RAG) proteins. Either BRG1, the ATPase subunit of hSWI/SNF, or SNF2h, the ATPase of human ISWI complexes, was capable of stimulating V(D)J cleavage of the array, although these remodelers act by different mechanisms. No effect of histone hyperacetylation was detectable in this system. As is observed on naked DNA, in the presence of core RAG1, the full-length RAG2 protein proved to be more active than core RAG2 on these polynucleosomal arrays, reinforcing the importance of the RAG2 C-terminal domain for efficient recombination. Comparison of 5 S array cleavage by the RAG proteins or by the restriction enzyme HhaI after remodeling by hSWI/SNF suggested that RAG proteins and HhaI might have different requirements for maximal accessibility of the substrate.     

VprBP binds full-length RAG1 and is required for B-cell development and V(D)J recombination fidelity

The N-terminus of full-length RAG1, though dispensable for RAG1/2 cleavage activity, is required for efficient V(D)J recombination. This region supports RING E3 ubiquitin ligase activity in vitro, but whether full-length RAG1 functions as a single subunit or a multi-subunit E3 ligase in vivo is unclear. We show the multi-subunit cullin RING E3 ligase complex VprBP/DDB1/Cul4A/Roc1 associates with full-length RAG1 through VprBP. This complex is assembled into RAG protein-DNA complexes, and supports in-vitro ubiquitylation activity that is insensitive to RAG1 RING domain mutations. Conditional B lineage-specific VprBP disruption arrests B-cell development at the pro-B-to-pre-B cell transition, but this block is bypassed by expressing rearranged immunoglobulin transgenes. Mice with a conditional VprBP disruption show modest reduction of D-J(H) rearrangement, whereas V(H)-DJ(H) and V(κ)-J(κ) rearrangements are severely impaired. D-J(H) coding joints from VprBP-insufficent mice show longer junctional nucleotide insertions and a higher mutation frequency in D and J segments than normal. These data suggest full-length RAG1 recruits a cullin RING E3 ligase complex to ubiquitylate an unknown protein(s) to limit error-prone repair during V(D)J recombination.     

A Dual Interaction between the DNA Damage Response Protein MDC1 and the RAG1 Subunit of the V(D)J Recombinase

The first step in V(D)J recombination is the formation of specific DNA double-strand breaks (DSBs) by the RAG1 and RAG2 proteins, which form the RAG recombinase. DSBs activate a complex network of proteins termed the DNA damage response (DDR). A key early event in the DDR is the phosphorylation of histone H2AX around DSBs, which forms a binding site for the tandem BRCA1 C-terminal (tBRCT) domain of MDC1. This event is required for subsequent signal amplification and recruitment of additional DDR proteins to the break site. RAG1 bears a histone H2AX-like motif at its C terminus (R1Ct), making it a putative MDC1-binding protein. In this work we show that the tBRCT domain of MDC1 binds the R1Ct motif of RAG1. Surprisingly, we also observed a second binding interface between the two proteins that involves the Proline-Serine-Threonine rich (PST) repeats of MDC1 and the N-terminal non-core region of RAG1 (R1Nt). The repeats-R1Nt interaction is constitutive, whereas the tBRCT-R1Ct interaction likely requires phosphorylation of the R1Ct motif of RAG1. As the C terminus of RAG1 has been implicated in inhibition of RAG activity, we propose a model in which phosphorylation of the R1Ct motif of RAG1 functions as a self-initiated regulatory signal.     

Stimulation of V(D)J recombination by histone acetylation

V(D)J recombination assembles functional immunoglobulin and T cell receptor genes from individual gene segments [1]. A common recombination mechanism, initiated by the proteins RAG1 and RAG2 at conserved recombination signal sequences (RSSs), operates at all rearranging loci [2] [3]. It has been proposed that the key regulator of the reaction is 'accessibility' of the RSS within chromatin [4]. Recently, the packaging of RSSs into nucleosomes was shown to inhibit initiation of V(D)J recombination [5] [6]. Nevertheless, the tight tissue specificity of regulation cannot be explained by nucleosome-mediated repression alone because a significant fraction of RSSs would be predicted to lie in linker regions between nucleosomes. Therefore, some aspect of the regulation of the recombination reaction must rely on the disruption of higher-order chromatin structure. Here, we report that histone acetylation directly stimulates the recombination reaction in vivo in the correct cell- and stage-specific manner. Neither expression of RAG genes nor activity of RAG proteins was increased by acetylation. Furthermore, histone acetylation failed to overcome nucleosome-mediated repression of RSS recognition and cleavage in vitro. Our data suggest a role for histone acetylation in stimulating recombination in vivo through disruption of higher-order chromatin structures.     

RAG2's non-core domain contributes to the ordered regulation of V(D)J recombination

Variable (diversity) joining [V(D)J] recombination of immune gene loci proceeds in an ordered manner with D to J portions recombining first and then an upstream V joins that recombinant. We present evidence that the non-core domain of recombination activating gene (RAG) protein 2 is involved in the regulation of recombinatorial order. In mice lacking the non-core domain of RAG2 the ordered rearrangement is disturbed and direct V to D rearrangements are 10- to 1000-times increased in tri-partite immune gene loci. Some forms of inter-chromosomal translocations between TCRbeta and TCRdelta D gene segments are also increased in the core RAG2 animals as compared with their wild-type (WT) counterparts. In addition, the concise use of proper recombination signal sequences (RSSs) appears to be disturbed in the core RAG2 mice as compared with WT RAG2 animals.     

A PHD finger motif in the C terminus of RAG2 modulates recombination activity

The RAG1 and RAG2 proteins catalyze V(D)J recombination and are essential for generation of the diverse repertoire of antigen receptor genes and effective immune responses. RAG2 is composed of a "core" domain that is required for the recombination reaction and a C-terminal nonessential or "non-core" region. Recent evidence has emerged arguing that the non-core region plays a critical regulatory role in the recombination reaction, and mutations in this region have been identified in patients with immunodeficiencies. Here we present the first structural data for the RAG2 protein, using NMR spectroscopy to demonstrate that the C terminus of RAG2 contains a noncanonical PHD finger. All of the non-core mutations of RAG2 that are implicated in the development of immunodeficiencies are located within the PHD finger, at either zinc-coordinating residues or residues adjacent to an alpha-helix on the surface of the domain that participates in binding to the signaling molecules, phosphoinositides. Functional analysis of disease and phosphoinositide-binding mutations reveals novel intramolecular interactions within the non-core region and suggests that the PHD finger adopts two distinct states. We propose a model in which the equilibrium between these states modulates recombination activity. Together, these data identify the PHD finger as a novel and functionally important domain of RAG2.     

Recombination activating gene 1 product alone possesses endonucleolytic activity

Two lymphoid-specific proteins, RAG1 and RAG2, are required for the initiation of the V(D)J recombination in vitro. The V(D)J cleavage that is mediated by RAG proteins at the border between the coding and signal sequences results in the production of a hairpin at the coding end and a double-stranded break at the signal end. Two hairpin coding ends are re-opened, modified, and sealed; whereas, the signal ends are directly ligated. Here I report that only RAG1 can carry out a distinct endonucleolytic activity in vitro using an oligonucleotide substrate that is tethered by a short single-stranded DNA. The purified RAG1 protein alone formed a nick at the near position to the recombination signal sequence. This endonucleolytic activity was eliminated by immunoprecipitation using the RAG1-specific antibody, and required the 3'-hydroxy group. All of the RAG1 mutants that were incapable of the nick and hairpin formation in the V(D)J cleavage analysis also showed this new endonucleolytic activity. This suggests that the nicking activity that was observed might be functionally different from the nick formation in the V(D)J cleavage.     

Effect of CpG methylation on RAG1/RAG2 reactivity: implications of direct and indirect mechanisms for controlling V(D)J cleavage

It has been suggested that DNA methylation/demethylation is involved in regulating V(D)J rearrangement. Although methylated DNA is thought to induce an inaccessible chromatin structure, it is unclear whether DNA methylation can directly control V(D)J recombination independently of chromatin structure. In this study, we tested whether DNA methylation directly affects the reactivity of the RAG1/RAG2 complex. Specific methylation within the heptamer of the recombination signal sequences (RSS) markedly reduced V(D)J cleavage without inhibiting RAG1/RAG2–DNA complex formation. By contrast, methylation at other positions around the RSS did not affect the reactivity of the RAG proteins. The presence of a methyl-CpG binding-domain protein inhibited the binding of the RAG1/RAG2 complex to all the methylated CpG sites that were tested. Our findings suggest that DNA methylation around the RSS may have a previously unexpected function in regulating V(D)J recombination by directly inhibiting V(D)J cleavage, in addition to its general function of inducing an inaccessible chromatin configuration.     

Identification of basic residues in RAG2 critical for DNA binding by the RAG1-RAG2 complex.

In V(D)J recombination, the RAG1 and RAG2 proteins are the essential components of the complex that catalyzes DNA cleavage. RAG1 has been shown to play a central role in DNA binding and catalysis. In contrast, the molecular roles of RAG2 in V(D)J recombination are unknown. To address this, we individually mutated 36 evolutionarily conserved basic and hydroxy group containing residues within RAG2. Biochemical analysis of the recombinant RAG2 proteins led to the identification of a number of basic residue mutants defective in catalysis in vitro and V(D)J recombination in vivo. Five of these were deficient in binding of the RAG1-RAG2 complex to its cognate DNA target sequence while interacting normally with RAG1. Our findings provide support for the direct involvement of RAG2 in DNA binding during all steps of the cleavage reaction.     

V(D)J recombination: site-specific cleavage and repair

V(D)J recombination is a site-specific gene rearrangement process that contributes to the diversity of antigen receptor repertoires. Two lymphoid-specific proteins, RAG1 and RAG2, initiate this process at two recombination signal sequences. Due to the recent development of an in vitro assay for V(D)J cleavage, the mechanism of cleavage has been elucidated clearly. The RAG complex recognizes a recombination signal sequence, makes a nick at the border between signal and coding sequence, and carries out a transesterification reaction, resulting in the production of a hairpin structure at the coding sequence and DNA double-strand breaks at the signal ends. RAG1 possesses the active site of the V(D)J recombinase although RAG2 is essential for signal binding and cleavage. After DNA cleavage by the RAG complex, the broken DNA ends are rejoined by the coordinated action of DNA double-strand break repair proteins as well as the RAG complex. The junctional variability resulting from imprecise joining of the coding sequences contributes additional diversity to the antigen receptors.     

Modulation of RAG/DNA complex by HSP70 in V(D)J recombination

V(D)J recombination, a site-specific gene rearrangement process, requires two RAG1 and RAG2 proteins specifically recognizing recombination signal sequences and forming DNA double-strand breaks. The broken DNA ends tightly bound to RAG proteins are joined by repair proteins. Here, we found that heat shock protein 70 was associated with RAG2 following two-step affinity chromatography purification. It was also co-immunoprecipitated with RAG2 in pro-B cells. Purified HSP70 protein disrupted RAG/DNA complexes assembled in vitro and also inhibited the V(D)J cleavage (both nick and hairpin formation) in a dose-dependent manner. This HSP70 action required ATP energy. These data suggest that HSP70 might play a crucial role in disassembling RAG/DNA complexes stably formed during V(D)J recombination.     

The C-terminal portion of RAG2 protects against transposition in vitro

The assembly of antigen receptor genes by V(D)J recombination is initiated by the RAG1/RAG2 protein complex, which introduces double-strand breaks between recombination signal sequences and their coding DNA. Truncated forms of RAG1 and RAG2 are functional in vivo and have been used to study V(D)J cleavage, hybrid joint formation and transposition in vitro. Here we have characterized the activities of the full-length proteins. Unlike core RAG2, which supports robust transposition in vitro, full-length RAG2 blocks transposition of signal ends following V(D)J cleavage. Thus, one role of this non-catalytic domain may be to prevent transposition in developing lymphoid cells. Although full-length RAG1 and RAG2 proteins rarely form hybrid joints in vivo in the absence of non-homologous end-joining factors, we show that the full-length proteins alone can catalyze this reaction in vitro.     

V(D)J recombinase binding and cleavage of cryptic recombination signal sequences identified from lymphoid malignancies

V(D)J recombination is a process integral to lymphocyte development. However, this process is not always benign, since certain lymphoid malignancies exhibit recurrent chromosomal abnormalities, such as translocations and deletions, that harbor molecular signatures suggesting an origin from aberrant V(D)J recombination. Translocations involving LMO2, TAL1, Ttg-1, and Hox11, as well as a recurrent interstitial deletion at 1p32 involving SIL/SCL, are cited examples of illegitimate V(D)J recombination. Previous studies using extrachromosomal substrates reveal that cryptic recombination signal sequences (cRSSs) identified near the translocation breakpoint in these examples support V(D)J recombination with efficiencies ranging from about 30- to 20,000-fold less than bona fide V(D)J recombination signals. To understand the molecular basis for these large differences, we investigated the binding and cleavage of these cRSSs by the RAG1/2 proteins that initiate V(D)J recombination. We find that the RAG proteins comparably bind all cRSSs tested, albeit more poorly than a consensus RSS. We show that four cRSSs that support levels of V(D)J recombination above background levels in cell culture (LMO2, TAL1, Ttg-1, and SIL) are also cleaved by the RAG proteins in vitro with efficiencies ranging from 18 to 70% of a consensus RSS. Cleavage of LMO2 and Ttg-1 by the RAG proteins can also be detected in cell culture using ligation-mediated PCR. In contrast, Hox11 and SCL are nicked but not cleaved efficiently in vitro, and cleavage at other adventitious sites in plasmid substrates may also limit the ability to detect recombination activity at these cRSSs in cell culture.     

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.     

DNA cleavage activity of the V(D)J recombination protein RAG1 is autoregulated

RAG1 and RAG2 catalyze the first DNA cleavage steps in V(D)J recombination. We demonstrate that the isolated central domain of RAG1 has inherent single-stranded (ss) DNA cleavage activity, which does not require, but is enhanced by, RAG2. The central domain, therefore, contains the active-site residues necessary to perform hydrolysis of the DNA phosphodiester backbone. Furthermore, the catalytic activity of this domain on ss DNA is abolished by addition of the C-terminal domain of RAG1. The inhibitory effects of this latter domain are suppressed on substrates containing double-stranded (ds) DNA. Together, the activities of the reconstituted domains on ss versus mixed ds-ss DNA approximate the activity of intact RAG1 in the presence of RAG2. We propose how the combined actions of the RAG1 domains may function in V(D)J recombination and also in aberrant cleavage reactions that may lead to genomic instability in B and T lymphocytes.     

Cell cycle-dependent accumulation in vivo of transposition-competent complexes between recombination signal ends and full-length RAG proteins

V(D)J recombination is initiated by a specialized transposase consisting of RAG-1 and RAG-2. Because full-length RAG proteins are insoluble under physiologic conditions, most previous analyses of RAG activity in vitro have used truncated core RAG-1 and RAG-2 fragments. These studies identified an intermediate in V(D)J recombination, the signal end complex (SEC), in which core RAG proteins remain associated with recombination signal sequences at the cleaved signal ends. From transfected cells expressing affinity-tagged RAG proteins, we have isolated in vivo assembled SECs containing full-length RAG proteins and cleaved recombination substrates. SEC formation in vivo did not require the repair proteins DNA-dependent protein kinase, Ku80, or XRCC4. In the presence of full-length RAG-2, SEC formation in vivo was cell cycle-regulated and restricted to the G(0)/G(1) phases. In contrast, complexes accumulated throughout cell cycle in cells expressing a RAG-2 CDK2 phosphorylation site mutant. Both core and full-length SECs supported transposition in vitro with similar efficiencies. Intracellular SECs, which are likely to persist in the absence of coding ends, represent potential donors whose transposition is not suppressed by the non-core regions of the RAG proteins.