Analysis of regions of RAG-2 important for V(D)J recombination.

The recombinase activating genes RAG-1 and RAG-2 operate together to activate V(D)J recombination, and thus play an essential role in the generation of immune system diversity. As a first step in understanding the function of the RAG-2 protein, we have tested a series of deletion and insertion mutations for their ability to induce V(D)J joining of a variety of model substrates. Mutants were assayed for their ability to induce deletional and inversional V(D)J joining, thereby testing their proficiency at forming both signal and coding joints, and, in some cases, for their ability to carry out recombination of both extrachromosomal and integrated recombination substrates. All these reactions were affected similarly by any one mutation. Although the RAG-2 protein shows extensive evolutionary conservation across its length, we found that the carboxy-terminal portion of RAG-2, including an acidic region, is dispensable for all forms of recombination tested. In contrast, all mutations we created in the N-terminal region severely decreased recombination. Thus, the core active region required for V(D)J recombination is confined to the first three-quarters of the RAG-2 protein.     

A RAG-1/RAG-2 tetramer supports 12/23-regulated synapsis,cleavage, and transposition of V(D)J recombination signals

Initiation of V(D)J recombination involves the synapsis and cleavage of a 12/23 pair of recombination signal sequences by RAG-1 and RAG-2. Ubiquitous nonspecific DNA-bending factors of the HMG box family, such as HMG-1, are known to assist in these processes. After cleavage, the RAG proteins remain bound to the cut signal ends and, at least in vitro, support the integration of these ends into unrelated target DNA via a transposition-like mechanism. To investigate whether the protein complex supporting synapsis, cleavage, and transposition of V(D)J recombination signals utilized the same complement of RAG and HMG proteins, I compared the RAG protein stoichiometries and activities of discrete protein-DNA complexes assembled on intact, prenicked, or precleaved recombination signal sequence (RSS) substrates in the absence and presence of HMG-1. In the absence of HMG-1, I found that two discrete RAG-1/RAG-2 complexes are detected by mobility shift assay on all RSS substrates tested. Both contain dimeric RAG-1 and either one or two RAG-2 subunits. The addition of HMG-1 supershifts both complexes without altering the RAG protein stoichiometry. I find that 12/23-regulated recombination signal synapsis and cleavage are only supported in a protein-DNA complex containing HMG-1 and a RAG-1/RAG-2 tetramer. Interestingly, the RAG-1/RAG-2 tetramer also supports transposition, but HMG-1 is dispensable for its activity.     

The DDE motif in RAG-1 is contributed in trans to a single active site that catalyzes the nicking and transesterification steps of V(D)J recombination

The process of assembling immunoglobulin and T-cell receptor genes from variable (V), diversity (D), and joining (J) gene segments, called V(D)J recombination, involves the introduction of DNA breaks at recombination signals. DNA cleavage is catalyzed by RAG-1 and RAG-2 in two chemical steps: first-strand nicking, followed by hairpin formation via direct transesterification. In vitro, these reactions minimally proceed in discrete protein-DNA complexes containing dimeric RAG-1 and one or two RAG-2 monomers bound to a single recombination signal sequence. Recently, a DDE triad of carboxylate residues essential for catalysis was identified in RAG-1. This catalytic triad resembles the DDE motif often associated with transposase and retroviral integrase active sites. To investigate which RAG-1 subunit contributes the residues of the DDE triad to the recombinase active site, cleavage of intact or prenicked DNA substrates was analyzed in situ in complexes containing RAG-2 and a RAG-1 heterodimer that carried an active-site mutation targeted to the same or opposite RAG-1 subunit mutated to be incompetent for DNA binding. The results show that the DDE triad is contributed to a single recombinase active site, which catalyzes the nicking and transesterification steps of V(D)J recombination by a single RAG-1 subunit opposite the one bound to the nonamer of the recombination signal undergoing cleavage (cleavage in trans). The implications of a trans cleavage mode observed in these complexes on the organization of the V(D)J synaptic complex are discussed.     

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.     

Identification and characterization of a gain-of-function RAG-1 mutant

RAG-1 and RAG-2 initiate V(D)J recombination by cleaving DNA at recombination signal sequences through sequential nicking and transesterification reactions to yield blunt signal ends and coding ends terminating in a DNA hairpin structure. Ubiquitous DNA repair factors then mediate the rejoining of broken DNA. V(D)J recombination adheres to the 12/23 rule, which limits rearrangement to signal sequences bearing different lengths of DNA (12 or 23 base pairs) between the conserved heptamer and nonamer sequences to which the RAG proteins bind. Both RAG proteins have been subjected to extensive mutagenesis, revealing residues required for one or both cleavage steps or involved in the DNA end-joining process. Gain-of-function RAG mutants remain unidentified. Here, we report a novel RAG-1 mutation, E649A, that supports elevated cleavage activity in vitro by preferentially enhancing hairpin formation. DNA binding activity and the catalysis of other DNA strand transfer reactions, such as transposition, are not substantially affected by the RAG-1 mutation. However, 12/23-regulated synapsis does not strongly stimulate the cleavage activity of a RAG complex containing E649A RAG-1, unlike its wild-type counterpart. Interestingly, wild-type and E649A RAG-1 support similar levels of cleavage and recombination of plasmid substrates containing a 12/23 pair of signal sequences in cell culture; however, E649A RAG-1 supports about threefold more cleavage and recombination than wild-type RAG-1 on 12/12 plasmid substrates. These data suggest that the E649A RAG-1 mutation may interfere with the RAG proteins' ability to sense 12/23-regulated synapsis.     

Selective expression of RAG-2 in chicken B cells undergoing immunoglobulin gene conversion

Chickens create their immunoglobulin (Ig) repertoires during B cell development in the bursa of Fabricius by intrachromosomal gene conversion. Recent evidence has suggested that Ig gene conversion may involve cis-acting DNA elements related to those involved in V(D)J recombination. Therefore, we have examined the potential role of the V(D)J recombination activating genes, RAG-1 and RAG-2, in regulating chicken Ig gene conversion. In contrast to the coexpression of RAG-1 and RAG-2 observed in mammalian B cells that undergo V(D)J recombination, chicken B cells isolated from the bursa of Fabricius express high levels of the RAG-2 mRNA but do not express RAG-1 mRNA. The developmental and phenotypic characteristics of the bursal lymphocytes and chicken B cell lines that express RAG-2 mRNA demonstrate that selective RAG-2 expression occurs specifically in B cells undergoing Ig diversification by gene conversion. These data suggest that RAG-2 plays a fundamental role in Ig-specific gene conversion.     

RAG-1-deficient mice have no mature B and T lymphocytes.

The V(D)J recombination activation gene RAG-1 was isolated on the basis of its ability to activate V(D)J recombination on an artificial substrate in fibroblasts. This property and the expression pattern in tissues and cell lines indicate that RAG-1 either activates or catalyzes the V(D)J recombination reaction of immunoglobulin and T cell receptor genes. We here describe the introduction of a mutation in RAG-1 into the germline of mice via gene targeting in embryonic stem cells. RAG-1-deficient mice have small lymphoid organs that do not contain mature B and T lymphocytes. The arrest of B and T cell differentiation occurs at an early stage and correlates with the inability to perform V(D)J recombination. The immune system of the RAG-1 mutant mice can be described as that of nonleaky scid mice. Although RAG-1 expression has been reported in the central nervous system of the mouse, no obvious neuroanatomical or behavioral abnormalities have been found in the RAG-1-deficient mice.     

Fine structure and activity of discrete RAG-HMG complexes on V(D)J recombination signals

Two lymphoid cell-specific proteins, RAG-1 and RAG-2, initiate V(D)J recombination by introducing DNA breaks at recombination signal sequences (RSSs). Although the RAG proteins themselves bind and cleave DNA substrates containing either a 12-RSS or a 23-RSS, DNA-bending proteins HMG-1 and HMG-2 are known to promote these processes, particularly with 23-RSS substrates. Using in-gel cleavage assays and DNA footprinting techniques, I analyzed the catalytic activity and protein-DNA contacts in discrete 12-RSS and 23-RSS complexes containing the RAG proteins and either HMG-1 or HMG-2. I found that both the cleavage activity and the pattern of protein-DNA contacts in RAG-HMG complexes assembled on 12-RSS substrates closely resembled those obtained from analogous 12-RSS complexes lacking HMG protein. In contrast, 23-RSS complexes containing both RAG proteins and either HMG-1 or HMG-2 exhibited enhanced cleavage activity and displayed an altered distribution of cleavage products compared to 23-RSS complexes containing only RAG-1 and RAG-2. Moreover, HMG-dependent heptamer contacts in 23-RSS complexes were observed. The protein-DNA contacts in RAG-RSS-HMG complexes assembled on 12-RSS or 23-RSS substrates were strikingly similar at comparable positions, suggesting that the RAG proteins mediate HMG-dependent heptamer contacts in 23-RSS complexes. Results of ethylation interference experiments suggest that the HMG protein is positioned 5' of the nonamer in 23-RSS complexes, interacting largely with the side of the duplex opposite the one contacting the RAG proteins. Thus, HMG protein plays the dual role of bringing critical elements of the 23-RSS heptamer into the same phase as the 12-RSS to promote RAG binding and assisting in the catalysis of 23-RSS cleavage.     

The V(D)J recombination activating gene, RAG-1

The RAG-1 (recombination activating gene-1) genomic locus, which activates V(D)J recombination when introduced into NIH 3T3 fibroblasts, was isolated by serial genomic transfections of oligonucleotide-tagged DNA. A genomic walk spanning 55 kb yielded a RAG-1 genomic probe that detects a single 6.6-7.0 kb mRNA species in transfectants and pre-B and pre-T cells. RAG-1 genomic and cDNA clones were biologically active when introduced into NIH 3T3 cells. Nucleotide sequencing of human and mouse RAG-1 cDNA clones predicts 119 kd proteins of 1043 and 1040 amino acids, respectively, with 90% sequence identity. RAG-1 has been conserved between species that carry out V(D)J recombination, and its pattern of expression correlates exactly with the pattern of expression of V(D)J recombinase activity. RAG-1 may activate V(D)J recombination indirectly, or it may encode the V(D)J recombinase itself.     

抗原受体基因重组的表观遗传学调控研究新进展

淋巴细胞是哺乳动物唯一能发生体细胞基因组变化的一类细胞,淋巴细胞在发育过程中通过V(D)J重组获得成熟的特异的抗原受体基因,实现了免疫细胞抗原识别惊人的多样性.关于V(D)J重组的调控机制一直是免疫学研究的重要问题,然而直到将表观遗传学研究引入这一领域,综合遗传学和表观遗传学的研究才真正揭示V(D)J重组精细的调控机制.综述了新近发现的V(D)J重组过程中重要的表观遗传学调控机制,如CpG甲基化,组蛋白修饰,核小体重塑及核拓扑学变化.     

Regulation of RAG-2 protein expression in avian thymocytes.

The recombinase-activating genes, RAG-1 and RAG-2, have been shown to be necessary to initiate the process of V(D)J recombination during the ontogeny of lymphocytes. While much is known about the end products of this rearrangement process, little is known about the function or regulation of the components of the recombinase system. To this end, we have generated a monoclonal antibody to the chicken RAG-2 protein. Chicken thymocytes were found to express high levels of RAG-2, part of which is phosphorylated. Within thymocytes, RAG-2 is expressed primarily within the nucleus. RAG-2 protein levels are high in the CD4- CD8- and CD4+ CD8+ immature thymocytes but absent at the single-positive CD4+ CD8- or CD4- CD8+ stage of thymocyte development. Mitogenic stimulation of thymocytes with phorbol myristate acetate and ionomycin results in down-regulation of RAG-2 expression. Consistent with these data, in vivo levels of RAG-2 are markedly lower in proliferating thymocytes than in smaller, G0/G1 cells. Down-regulation of RAG-2 expression appears to occur before cells enter S phase, suggesting that RAG-2 function may be limited to noncycling cells.     

Roles of the "dispensable" portions of RAG-1 and RAG-2 in V(D)J recombination

V(D)J recombination is initiated by introduction of site-specific double-stranded DNA breaks by the RAG-1 and RAG-2 proteins. The broken DNA ends are then joined by the cellular double-strand break repair machinery. Previous work has shown that truncated (core) versions of the RAG proteins can catalyze V(D)J recombination, although less efficiently than their full-length counterparts. It is not known whether truncating RAG-1 and/or RAG-2 affects the cleavage step or the joining step of recombination. Here we examine the effects of truncated RAG proteins on recombination intermediates and products. We found that while truncated RAG proteins generate lower levels of recombination products than their full-length counterparts, they consistently generate 10-fold higher levels of one class of recombination intermediates, termed signal ends. Our results suggest that this increase in signal ends does not result from increased cleavage, since levels of the corresponding intermediates, coding ends, are not elevated. Thus, removal of the "dispensable" regions of the RAG proteins impairs proper processing of recombination intermediates. Furthermore, we found that removal of portions of the dispensable regions of RAG-1 and RAG-2 affects the efficiency of product formation without altering the levels of recombination intermediates. Thus, these evolutionarily conserved sequences play multiple, important roles in V(D)J recombination.     

Full-length RAG-2, and not full-length RAG-1, specifically suppresses RAG-mediated transposition but not hybrid joint formation or disintegration

RAG-1 and RAG-2 initiate V(D)J recombination by introducing DNA breaks at recombination signal sequences flanking a pair of antigen receptor gene segments. Occasionally, the RAG proteins mediate two other alternative DNA rearrangements in vivo: the rejoining of signal and coding ends and the transposition of signal ends into unrelated DNA. In contrast, truncated, catalytically active "core" RAG proteins readily catalyze these reactions in vitro, suggesting that full-length RAG proteins directly or indirectly suppress these undesired reactions in vivo. To discriminate between direct and indirect suppression models, full-length RAG proteins were purified and characterized in vitro. From mammalian cells, full-length RAG-1 is readily purified with core RAG-2 but not full-length RAG-2 and vice versa. Despite differences in DNA binding activity, recombinase containing either core or full-length RAG-1 or RAG-2 possess comparable cleavage, rejoining, and end-processing activity, as well as similar usage preferences for canonical versus cryptic recombination signals. However, recombinase containing full-length RAG-2, but not full-length RAG-1, exhibits dramatically reduced transposition activity in vitro. These data suggest RAG-mediated transposition and rejoining are differentially regulated by the full-length RAG proteins in vivo (the former directly by RAG-2 and the latter indirectly through other factors) and argue that noncore portions of the RAG proteins have little or no direct influence over V(D)J recombinase site specificity.     

RAG-2-deficient mice lack mature lymphocytes owing to inability to initiate V(D)J rearrangement.

We have generated mice that carry a germline mutation in which a large portion of the RAG-2 coding region is deleted. Homozygous mutants are viable but fail to produce mature B or T lymphocytes. Very immature lymphoid cells were present in primary lymphoid organs of mutant animals as defined by surface marker analyses and Abelson murine leukemia virus (A-MuLV) transformation assays. However, these cells did not rearrange their immunoglobulin or T cell receptor loci. Lack of V(D)J recombination activity in mutant pre-B cell lines could be restored by introduction of a functional RAG-2 expression vector. Therefore, loss of RAG-2 function in vivo results in total inability to initiate V(D)J rearrangement, leading to a novel severe combined immune deficient (SCID) phenotype. Because the SCID phenotype was the only obvious abnormality detected in RAG-2 mutant mice, RAG-2 function and V(D)J recombinase activity, per se, are not required for development of cells other than lymphocytes.     

V(D)J recombination intermediates and non-standard products in XRCC4-deficient cells.

V(D)J recombination assembles immunoglobulin (Ig) and T cell receptor (TCR) gene segments during lymphocyte development. Recombination is initiated by the RAG-1 and RAG-2 proteins, which introduce double-stranded DNA breaks (DSB) adjacent to the Ig and TCR gene segments. The broken ends are joined by the DSB repair machinery, which includes the XRCC4 protein. While XRCC4 is essential for both DSB repair and V(D)J recombination, the functions of this protein remain enigmatic. Because the rare V(D)J recombination products isolated from XRCC4-deficient cells generally show evidence of excessive nucleotide loss, it was hypothesized that XRCC4 may function to protect broken DNA ends. Here we report the first examination of V(D)J recombination intermediates in XRCC4-deficient cells. We found that both types of intermediates, signal ends and coding ends, are abundant in the absence of XRCC4. Furthermore, the signal ends are full length. We also showed that alternative V(D)J recombination products, hybrid joints, form with normal efficiency and without excessive deletion in XRCC4-deficient cells. These data indicate that impaired formation of V(D)J recombination products in XRCC4-deficient cells does not result from excessive degradation of recombination intermediates. Potential roles of XRCC4 in the joining reaction are discussed.     

Rag-1 mutations associated with B-cell-negative scid dissociate the nicking and transesterification steps of V(D)J recombination

Some patients with B-cell-negative severe combined immune deficiency (SCID) carry mutations in RAG-1 or RAG-2 that impair V(D)J recombination. Two recessive RAG-1 mutations responsible for B-cell-negative SCID, R621H and E719K, impair V(D)J recombination without affecting formation of single-site recombination signal sequence complexes, specific DNA contacts, or perturbation of DNA structure at the heptamer-coding junction. The E719K mutation impairs DNA cleavage by the RAG complex, with a greater effect on nicking than on transesterification; a conservative glutamine substitution exhibits a similar effect. When cysteine is substituted for E719, RAG-1 activity is enhanced in Mn(2+) but remains impaired in Mg(2+), suggesting an interaction between this residue and an essential metal ion. The R621H mutation partially impairs nicking, with little effect on transesterification. The residual nicking activity of the R621H mutant is reduced at least 10-fold upon a change from pH 7.0 to pH 8.4. Site-specific nicking is severely impaired by an alanine substitution at R621 but is spared by substitution with lysine. These observations are consistent with involvement of a positively charged residue at position 621 in the nicking step of the RAG-mediated cleavage reaction. Our data provide a mechanistic explanation for one form of hereditary SCID. Moreover, while RAG-1 is directly involved in catalysis of both nicking and transesterification, our observations indicate that these two steps have distinct catalytic requirements.     

Paleo-Immunology: Evidence Consistent with Insertion of a Primordial Herpes Virus-Like Element in the Origins of Acquired Immunity

Background

The RAG encoded proteins, RAG-1 and RAG-2 regulate site-specific recombination events in somatic immune B- and T-lymphocytes to generate the acquired immune repertoire. Catalytic activities of the RAG proteins are related to the recombinase functions of a pre-existing mobile DNA element in the DDE recombinase/RNAse H family, sometimes termed the “RAG transposon”.

Methodology/Principal Findings

Novel to this work is the suggestion that the DDE recombinase responsible for the origins of acquired immunity was encoded by a primordial herpes virus, rather than a “RAG transposon.” A subsequent “arms race” between immunity to herpes infection and the immune system obscured primary amino acid similarities between herpes and immune system proteins but preserved regulatory, structural and functional similarities between the respective recombinase proteins. In support of this hypothesis, evidence is reviewed from previous published data that a modern herpes virus protein family with properties of a viral recombinase is co-regulated with both RAG-1 and RAG-2 by closely linked cis-acting co-regulatory sequences. Structural and functional similarity is also reviewed between the putative herpes recombinase and both DDE site of the RAG-1 protein and another DDE/RNAse H family nuclease, the Argonaute protein component of RISC (RNA induced silencing complex).

Conclusions/Significance

A “co-regulatory” model of the origins of V(D)J recombination and the acquired immune system can account for the observed linked genomic structure of RAG-1 and RAG-2 in non-vertebrate organisms such as the sea urchin that lack an acquired immune system and V(D)J recombination. Initially the regulated expression of a viral recombinase in immune cells may have been positively selected by its ability to stimulate innate immunity to herpes virus infection rather than V(D)J recombination Unlike the “RAG-transposon” hypothesis, the proposed model can be readily tested by comparative functional analysis of herpes virus replication and V(D)J recombination.