Unique and redundant functions of ATM and DNA-PKcs during V(D)J recombination

Lymphocyte antigen receptor genes are assembled through the process of V(D)J recombination, during which pairwise DNA cleavage of gene segments results in the formation of four DNA ends that are resolved into a coding joint and a signal joint. The joining of these DNA ends occurs in G₁-phase lymphocytes and is mediated by the non-homologous end-joining (NHEJ) pathway of DNA double-strand break (DSB) repair. The ataxia telangiectasia mutated (ATM) and the DNA-dependent protein kinase catalytic subunit (DNA-PKcs), two related kinases, both function in the repair of DNA breaks generated during antigen receptor gene assembly. Although these proteins have unique functions during coding joint formation, their activities in signal joint formation, if any, have been less clear. However, two recent studies demonstrated that ATM and DNA-PKcs have overlapping activities important for signal joint formation. Here, we discuss the unique and shared activities of the ATM and DNA-PKcs kinases during V(D)J recombination, a process that is essential for lymphocyte development and the diversification of antigen receptors.Key words: ATM, V(D)J recombination, DNA-PKcs, Lymphocyte, DNA repair, RAG     

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.     

Joining mutants of RAG1 and RAG2 that demonstrate impaired interactions with the coding-end DNA

In V(D)J joining of antigen receptor genes, two recombination signal sequences (RSSs), 12- and 23-RSSs, form a complex with the protein products of recombination activating genes, RAG1 and RAG2. DNaseI footprinting demonstrates that the interaction of RAG proteins with substrate RSS DNA is not just limited to the signal region but involves the coding sequence as well. Joining mutants of RAG1 and RAG2 demonstrate impaired interactions with the coding region in both pre- and postcleavage type complexes. A possible role of this RAG coding region interaction is discussed in the context of V(D)J recombination.     

Joining-deficient RAG1 mutants block V(D)J recombination in vivo and hairpin opening in vitro

The RAG proteins cleave at V(D)J recombination signal sequences then form a postcleavage complex with the broken ends. The role of this complex in end processing and joining, if any, is undefined. We have identified two RAG1 mutants proficient for DNA cleavage but severely defective for coding and signal joint formation, providing direct evidence that RAG1 is critical for joining in vivo and strongly suggesting that the postcleavage complex is important in end joining. We have also identified a RAG1 mutant that is severely defective for both hairpin opening in vitro and coding joint formation in vivo. These data suggest that the hairpin opening activity of the RAG proteins plays an important physiological role in V(D)J recombination.     

Hybrid joint formation in human V(D)J recombination requires nonhomologous DNA end joining

In V(D)J recombination, the RAG proteins bind at a pair of signal sequences adjacent to the V, D, or J coding regions and cleave the DNA, resulting in two signal ends and two hairpinned coding ends. The two coding ends are joined to form a coding joint, and the two signal ends are joined to form a signal joint; this joining is done by the nonhomologous DNA end joining (NHEJ) pathway. A recombinational alternative in which a signal end is recombined with a coding end can also occur in a small percentage of the V(D)J recombination events in murine and human cells, and these are called hybrids (or hybrid joints). Two mechanisms have been proposed for the formation of these hybrids. One mechanism is via NHEJ, after initial cutting by RAGs. The second mechanism does not rely on NHEJ, but rather invokes that the RAGs can catalyze joining of the signal to the hairpinned coding end, by using the 3'OH of the signal end as a nucleophile to attack the phosphodiester bonds of the hairpinned coding end. In the present study, we addressed the question of which type of hybrid joining occurs in a physiological environment, where standard V(D)J recombination presumably occurs and normal RAG proteins are endogenously expressed. We find that all hybrids in vivo require DNA ligase IV in human cells, which is the final component of the NHEJ pathway. Hence, hybrid joints rely on NHEJ rather than on the RAG complex for joining.     

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.     

DNA-PKcs dependence of Artemis endonucleolytic activity, differences between hairpins and 5' or 3' overhangs

During V(D)J recombination, the RAG proteins create DNA hairpins at the V, D, or J coding ends, and the structure-specific nuclease Artemis is essential to open these hairpins prior to joining. Artemis also is an endonuclease for 5' and 3' overhangs at many DNA double strand breaks caused by ionizing radiation, and Artemis functions as part of the nonhomologous DNA end joining pathway in repairing these. All of these activities require activation of the Artemis protein by interaction with and phosphorylation by the DNA-dependent protein kinase catalytic subunit (DNA-PKcs). In this study, we have identified a region of the Artemis protein involved in the interaction with DNA-PKcs. Furthermore, the biochemical and functional analyses of C-terminally truncated Artemis variants indicate that the hair-pin opening and DNA overhang endonucleolytic features of Artemis are triggered by DNA-PKcs in two modes. First, autoinhibition mediated by the C-terminal tail of Artemis is relieved by phosphorylation of this tail by DNA-PKcs. Thus, C-terminally truncated Artemis derivatives imitate DNA-PKcs-activated wild type Artemis protein and exhibit intrinsic hairpin opening activity. Second, DNA-PKcs may optimally configure 5' and 3' overhang substrates for the endonucleolytic function of Artemis.     

Functional and biochemical dissection of the structure-specific nuclease ARTEMIS

During V(D)J recombination, the RAG1 and RAG2 proteins form a complex and initiate the process of rearrangement by cleaving between the coding and signal segments and generating hairpins at the coding ends. Prior to ligation of the coding ends by DNA ligase IV/XRCC4, these hairpins are opened by the ARTEMIS/DNA-PKcs complex. ARTEMIS, a member of the metallo-beta-lactamase superfamily, shares several features with other family members that act on nucleic acids. ARTEMIS exhibits exonuclease and, in concert with DNA-PKcs, endonuclease activities. To characterize amino acids essential for its catalytic activities, we mutated nine evolutionary conserved histidine and aspartic acid residues within ARTEMIS. Biochemical analyses and a novel in vivo V(D)J recombination assay allowed the identification of eight mutants that were defective in both overhang endonucleolytic and hairpin-opening activities; the 5' to 3' exonuclease activity of ARTEMIS, however, was not impaired by these mutations. These results indicate that the hairpin-opening activity of ARTEMIS and/or its overhang endonucleolytic activity are necessary but its exonuclease activity is not sufficient for the process of V(D)J recombination.     

ATM prevents the persistence and propagation of chromosome breaks in lymphocytes

DNA double-strand breaks (DSBs) induce a signal transmitted by the ataxia-telangiectasia mutated (ATM) kinase, which suppresses illegitimate joining of DSBs and activates cell-cycle checkpoints. Here we show that a significant fraction of mature ATM-deficient lymphocytes contain telomere-deleted ends produced by failed end joining during V(D)J recombination. These RAG-1/2 endonuclease-dependent, terminally deleted chromosomes persist in peripheral lymphocytes for at least 2 weeks in vivo and are stable over several generations in vitro. Restoration of ATM kinase activity in mature lymphocytes that have transiently lost ATM function leads to loss of cells with terminally deleted chromosomes. Thus, maintenance of genomic stability in lymphocytes requires faithful end joining as well a checkpoint that prevents the long-term persistence and transmission of DSBs. Silencing this checkpoint permits DNA ends produced by V(D)J recombination in a lymphoid precursor to serve as substrates for translocations with chromosomes subsequently damaged by other means in mature cells.     

A biochemically defined system for coding joint formation in V(D)J recombination

V(D)J recombination is one of the most complex DNA transactions in biology. The RAG complex makes double-stranded breaks adjacent to signal sequences and creates hairpin coding ends. Here, we find that the kinase activity of the Artemis:DNA-PKcs complex can be activated by hairpin DNA ends in cis, thereby allowing the hairpins to be nicked and then to undergo processing and joining by nonhomologous DNA end joining. Based on these insights, we have reconstituted many aspects of the antigen receptor diversification of V(D)J recombination by using 13 highly purified polypeptides, thereby permitting variable domain exon assembly by using this fully defined system in accord with the 12/23 rule for this process. The features of the recombination sites created by this system include all of the features observed in vivo (nucleolytic resection, P nucleotides, and N nucleotide addition), indicating that most, if not all, of the end modification enzymes have been identified.     

Alternative pathways for the repair of RAG-induced DNA breaks

RAG1 and RAG2 cleave DNA to generate blunt signal ends and hairpin coding ends at antigen receptor loci in lymphoid cells. During V(D)J recombination, repair of these RAG-generated double-strand breaks (DSBs) by the nonhomologous end-joining (NHEJ) pathway contributes substantially to the antigen receptor diversity necessary for immune system function, although recent evidence also supports the ability of RAG-generated breaks to undergo homology-directed repair (HDR). We have determined that RAG-generated chromosomal breaks can be repaired by pathways other than NHEJ in mouse embryonic stem (ES) cells, although repair by these pathways occurs at a significantly lower frequency than NHEJ. HDR frequency was estimated to be >or=40-fold lower than NHEJ frequency for both coding end and signal end reporters. Repair by single-strand annealing was estimated to occur at a comparable or lower frequency than HDR. As expected, V(D)J recombination was substantially impaired in cells deficient for the NHEJ components Ku70, XRCC4, and DNA-PKcs. Concomitant with decreased NHEJ, RAG-induced HDR was increased in each of the mutants, including cells lacking DNA-PKcs, which has been implicated in hairpin opening. HDR was increased to the largest extent in Ku70-/- cells, implicating the Ku70/80 DNA end-binding protein in regulating pathway choice. Thus, RAG-generated DSBs are typically repaired by the NHEJ pathway in ES cells, but in the absence of NHEJ components, a substantial fraction of breaks can be efficiently channeled into alternative pathways in these cells.     

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.     

The beyond 12/23 restriction is imposed at the nicking and pairing steps of DNA cleavage during V(D)J recombination

The beyond 12/23 (B12/23) rule ensures inclusion of a Dbeta gene segment in the assembled T-cell receptor (TCR) beta variable region exon and is manifest by a failure of direct Vbeta-to-Jbeta gene segment joining. The restriction is enforced during the DNA cleavage step of V(D)J recombination by the recombination-activating gene 1 and 2 (RAG1/2) proteins and the recombination signal sequences (RSSs) flanking the TCRbeta gene segments. Nothing is known about the step(s) at which DNA cleavage is defective or how TCRbeta locus sequences contribute to these defects. To address this, we examined the steps of DNA cleavage by the RAG proteins using TCRbeta locus V, D, and J RSS oligonucleotide substrates. The results demonstrate that the B12/23 rule is enforced through slow nicking of Jbeta substrates and to some extent through poor synapsis of Vbeta and Jbeta substrates. Nicking is controlled largely by the coding flank and, unexpectedly, the RSS spacer, while synapsis is controlled primarily by the RSS nonamer. The results demonstrate that different Jbeta substrates are crippled at different steps of cleavage by distinct combinations of defects in the various DNA elements and strongly suggest that the DNA nicking step of V(D)J recombination can be rate limiting in vivo.     

Extent to which hairpin opening by the Artemis:DNA-PKcs complex can contribute to junctional diversity in V(D)J recombination

V(D)J recombination events are initiated by cleavage at gene segments by the RAG1:RAG2 complex, which results in hairpin formation at the coding ends. The hairpins are opened by the Artemis:DNA-PKcs complex, and then joined via the nonhomologous DNA end joining (NHEJ) process. Here we examine the opening of the hairpinned coding ends from all of the 39 functional human V_H elements. We find that there is some sequence-dependent variation in the efficiency and even the position of hairpin opening by Artemis:DNA-PKcs. The hairpin opening efficiency varies over a 7-fold range. The hairpin opening position varies over the region from 1 to 4 nt 3′ of the hairpin tip, leading to a 2–8 nt single-stranded 3′ overhang at each coding end. This information provides greater clarity on the extent to which the hairpin opening position contributes to junctional diversification in V(D)J recombination.     

DNA Hairpin Opening Mediated by the RAG1 and RAG2 Proteins

The lymphoid cell-specific proteins RAG1 and RAG2 initiate V(D)J recombination by cleaving DNA adjacent to recombination signals, generating blunt signal ends and covalently sealed, hairpin coding ends. A critical next step in the reaction is opening of the hairpins, but the factor(s) responsible has not been identified and had been thought to be a ubiquitous component(s) of the DNA repair machinery. Here we demonstrate that RAG1 and RAG2 possess an intrinsic single-stranded nuclease activity capable of nicking hairpin coding ends at or near the hairpin tip. In Mn2+, a synthetic hairpin is nicked 5 nucleotides (nt) 5' of the hairpin tip, with more distant sites of nicking suppressed by HMG2. In Mg2+, hairpins generated by V(D)J cleavage are nicked whereas synthetic hairpins are not. Cleavage-generated hairpins are nicked at the tip and predominantly 1 to 2 nt 5' of the tip. RAG1 and RAG2 may therefore be responsible for initiating the processing of coding ends and for the generation of P nucleotides during V(D)J recombination.     

Dynamics of the PI3K-like protein kinase members ATM and DNA-PKcs at DNA double strand breaks

The protein kinases ATM and DNA-PKcs play critical roles in the cellular response to DNA double strand breaks (DSBs). ATM and DNA-PKcs are activated in response to DSBs and play several important roles in propagation of the damage signal and for the repair of DNA damage. Recent work from several groups, including ours, has focused on studying the dynamics of each of these proteins at DSBs and the requirements and factors which play a role(s) in this process. The use of live cell imaging of fluorescently-tagged ATM and DNA-PKcs has allowed us to study the real-time response of these proteins to laser-generated DNA damage in vivo. Here, we will extensively discuss the behavior of the ATM and DNA-PKcs proteins at DSB sites.     

Dynamics of the PI3K-like protein kinase members ATM and DNA-PKcs at DNA double strand breaks

The protein kinases ATM and DNA-PKcs play critical roles in the cellular response to DNA double strand breaks (DSBs). ATM and DNA-PKcs are activated in response to DSBs and play several important roles in propagation of the damage signal and for the repair of DNA damage. Recent work from several groups, including ours, has focused on studying the dynamics of each of these proteins at DSBs and the requirements and factors which play a role(s) in this process. The use of live cell imaging of fluorescently-tagged ATM and DNA-PKcs has allowed us to study the real-time response of these proteins to laser-generated DNA damage in vivo. Here, we will extensively discuss the behavior of the ATM and DNA-PKcs proteins at DSB sites.Key words: ATM, DNA-PKcs, DNA double strand breaks, autophosphorylation, live cell imaging     

SCID in Jack Russell terriers: a new animal model of DNA-PKcs deficiency

We recently described the incidence of a SCID disease in a litter of Jack Russell terriers. In this study, we show that the molecular defect in these animals is faulty V(D)J recombination. Furthermore, we document a complete deficit in DNA-dependent protein kinase activity that can be explained by a marked diminution in the expression of the catalytic subunit DNA-dependent protein kinase catalytic subunit (DNA-PKcs). We conclude that as is the case in C.B-17 SCID mice and in Arabian SCID foals, the defective factor in these SCID puppies is DNA-PKcs. In mice, it has been clearly established that DNA-PKcs deficiency produces an incomplete block in V(D)J recombination, resulting in "leaky" coding joint formation and only a modest defect in signal end ligation. In contrast, DNA-PKcs deficiency in horses profoundly blocks both coding and signal end joining. Here, we show that although DNA-PKcs deficiency in canine lymphocytes results in a block in both coding and signal end joining, the deficit in both is intermediate between that seen in SCID mice and SCID foals. These data demonstrate significant species variation in the absolute necessity for DNA-PKcs during V(D)J recombination. Furthermore, the severity of the V(D)J recombination deficits in these three examples of genetic DNA-PKcs deficiency inversely correlates with the relative DNA-PK enzymatic activity expressed in normal fibroblasts derived from these three species.