ATM-dependent Phosphorylation of Nemo SQ Motifs Is Dispensable for Nemo-mediated Gene Expression Changes in Response to DNA Double-Strand Breaks.

In response to DNA double-strand breaks (DSBs), the ATM kinase activates NF-κB factors to stimulate gene expression changes that promote survival and allow time for cells to repair damage. In cell lines, ATM can activate NF-κB transcription factors via two independent, convergent mechanisms. One is ATM-mediated phosphorylation of nuclear NF-κB essential modulator (Nemo) protein, which leads to monoubiquitylation and export of Nemo to the cytoplasm where it engages the IκB kinase (IKK) complex to activate NF-κB. Another is DSB-triggered migration of ATM into the cytoplasm, where it promotes monoubiquitylation of Nemo and the resulting IKK-mediated activation of NF-κB. ATM has many other functions in the DSB response beyond activation of NF-κB, and Nemo activates NF-κB downstream of diverse stimuli, including developmental or proinflammatory stimuli such as LPSs. To elucidate the in vivo role of DSB-induced, ATM-dependent changes in expression of NF-κB-responsive genes, we generated mice expressing phosphomutant Nemo protein lacking consensus SQ sites for phosphorylation by ATM or related kinases. We demonstrate that these mice are viable/healthy and fertile and exhibit overall normal B and T lymphocyte development. Moreover, treatment of their B lineage cells with LPS induces normal NF-κB-regulated gene expression changes. Furthermore, in marked contrast to results from a pre-B cell line, primary B lineage cells expressing phosphomutant Nemo treated with the genotoxic drug etoposide induce normal ATM- and Nemo-dependent changes in expression of NF-κB-regulated genes. Our data demonstrate that ATM-dependent phosphorylation of Nemo SQ motifs in vivo is dispensable for DSB-signaled changes in expression of NF-κB-regulated genes.

The Cyclin D3 Protein Enforces Monogenic TCRß Expression by Mediating TCRß Protein-Signaled Feedback Inhibition of Vß Recombination.

In jawed vertebrates, adaptive immunity depends on the process of V(D)J recombination creating vast numbers of T and B lymphocytes that each expresses unique Ag receptors of uniform specificity. The asynchronous initiation of V-to-(D)J rearrangement between alleles and the resulting protein from one allele signaling feedback inhibition of V recombination on the other allele ensures homogeneous receptor specificity of individual cells. Upon productive Vß-to-DßJß rearrangements in noncycling double-negative thymocytes, TCRß protein signals induction of the cyclin D3 protein to accelerate cell cycle entry, thereby driving proliferative expansion of developing αß T cells. Through undetermined mechanisms, the inactivation of cyclin D3 in mice causes an increased frequency of αß T cells that express TCRß proteins from both alleles, producing lymphocytes of heterogeneous specificities. To determine how cyclin D3 enforces monogenic TCRß expression, we used our mouse lines with enhanced rearrangement of specific Vß segments due to replacement of their poor-quality recombination signal sequence (RSS) DNA elements with a better RSS. We show that cyclin D3 inactivation in these mice elevates the frequencies of αß T cells that display proteins from RSS-augmented Vß segments on both alleles. By assaying mature αß T cells, we find that cyclin D3 deficiency increases the levels of Vß rearrangements that occur within developing thymocytes. Our data demonstrate that a component of the cell cycle machinery mediates TCRß protein-signaled feedback inhibition in thymocytes to achieve monogenic TCRß expression and resulting uniform specificity of individual αß T cells.

Monogenic TCRß Assembly and Expression Are Paramount for Uniform Antigen Receptor Specificity of Individual αß T Lymphocytes.

The ability of individual T and B cells to display Ag receptors of unique uniform specificity is the molecular basis of adaptive immunity. Most αß T cells achieve uniform specificity by assembling in-frame genes on only one allelic copy of TCRß and TCRα loci, while others prevent incorporation of TCRα protein from both alleles into TCRs. Analysis of mice expressing TCR proteins from a restricted combination of transgenes showed that TCR protein pairing restrictions achieve uniform specificity of cells expressing two types of TCRß protein. However, whether this mechanism operates in the physiological context where each dual-TCRß cell expresses one set of a vast number of different TCRß proteins remains an open question, largely because there is a low, but significant, portion of cells carrying two in-frame TCRß genes. To resolve this issue, we inactivated one allelic copy of the TCRα locus in a new mouse strain that assembles two in-frame TCRß genes in an elevated fraction of cells. This genetic manipulation has no effect on the frequency of cells that display multiple types of αß TCR, yet increases the representation of cells displaying TCRß proteins that generate more highly expressed TCRs. Our data demonstrate that some TCRß proteins exhibit differential functional pairing with TCRα proteins, but these restrictions have negligible contribution for ensuring uniform specificity of cells that express two types of TCRß protein. Therefore, we conclude that mechanisms governing monogenic assembly and expression of TCRß genes in individual cells are paramount for uniform specificity of αß T lymphocytes.

Nemo-Dependent, ATM-Mediated Signals from RAG DNA Breaks at Igk Feedback Inhibit V κ Recombination to Enforce Igκ Allelic Exclusion.

Monoallelic AgR gene expression underlies specific adaptive immune responses. AgR allelic exclusion is achieved by sequential initiation of V(D)J recombination between alleles and resultant protein from one allele signaling to prevent recombination of the other. The ATM kinase, a regulator of the DNA double-strand break (DSB) response, helps enforce allelic exclusion through undetermined mechanisms. ATM promotes repair of RAG1/RAG2 (RAG) endonuclease-induced DSBs and transduces signals from RAG DSBs during Igk gene rearrangement on one allele to transiently inhibit RAG1 protein expression, Igk accessibility, and RAG cleavage of the other allele. Yet, the relative contributions of ATM functions in DSB repair versus signaling to enforce AgR allelic exclusion remain undetermined. In this study, we demonstrate that inactivation in mouse pre-B cells of the NF-κB essential modulator (Nemo) protein, an effector of ATM signaling, diminishes RAG DSB-triggered repression of Rag1/Rag2 transcription and Igk accessibility but does not result in aberrant repair of RAG DSBs like ATM inactivation. We show that Nemo deficiency increases simultaneous biallelic Igk cleavage in pre-B cells and raises the frequency of B cells expressing Igκ proteins from both alleles. In contrast, the incidence of biallelic Igκ expression is not elevated by inactivation of the SpiC transcriptional repressor, which is induced by RAG DSBs in an ATM-dependent manner and suppresses Igk accessibility. Thus, we conclude that Nemo-dependent, ATM-mediated DNA damage signals enforce Igκ allelic exclusion by orchestrating transient repression of RAG expression and feedback inhibition of additional Igk rearrangements in response to RAG cleavage on one Igk allele.

Poor-Quality Vß Recombination Signal Sequences and the DNA Damage Response ATM Kinase Collaborate to Establish TCRß Gene Repertoire and Allelic Exclusion.

The monoallelic expression (allelic exclusion) of diverse lymphocyte Ag receptor genes enables specific immune responses. Allelic exclusion is achieved by asynchronous initiation of V(D)J recombination between alleles and protein encoded by successful rearrangement on the first allele signaling permanent inhibition of V rearrangement on the other allele. The ATM kinase that guides DNA repair and transiently suppresses V(D)J recombination also helps impose allelic exclusion through undetermined mechanisms. At the TCRß locus, one Vß gene segment (V31) rearranges only by inversion, whereas all other Vß segments rearrange by deletion except for rare cases in which they rearrange through inversion following V31 rearrangement. The poor-quality recombination signal sequences (RSSs) of V31 and V2 help establish TCRß gene repertoire and allelic exclusion by stochastically limiting initiation of Vß rearrangements before TCRß protein-signaled permanent silencing of Vß recombination. We show in this study in mice that ATM functions with these RSSs and the weak V1 RSS to shape TCRß gene repertoire by restricting their Vß segments from initiating recombination and hindering aberrant nonfunctional Vß recombination products, especially during inversional V31 rearrangements. We find that ATM collaborates with the V1 and V2 RSSs to help enforce allelic exclusion by facilitating competition between alleles for initiation and functional completion of rearrangements of these Vß segments. Our data demonstrate that the fundamental genetic DNA elements that underlie inefficient Vß recombination cooperate with ATM-mediated rapid DNA damage responses to help establish diversity and allelic exclusion of TCRß genes.

The RAG1 Ubiquitin Ligase Domain Stimulates Recombination of TCRß and TCRα Genes and Influences Development of αß T Cell Lineages.

RAG1/RAG2 (RAG) endonuclease-mediated assembly of diverse lymphocyte Ag receptor genes by V(D)J recombination is critical for the development and immune function of T and B cells. The RAG1 protein contains a ubiquitin ligase domain that stabilizes RAG1 and stimulates RAG endonuclease activity in vitro. We report in this study that mice with a mutation that inactivates the Rag1 ubiquitin ligase in vitro exhibit decreased rearrangements and altered repertoires of TCRß and TCRα genes in thymocytes and impaired thymocyte developmental transitions that require the assembly and selection of functional TCRß and/or TCRα genes. These Rag1 mutant mice present diminished positive selection and superantigen-mediated negative selection of conventional αß T cells, decreased genesis of invariant NK T lineage αß T cells, and mature CD4+ αß T cells with elevated autoimmune potential. Our findings reveal that the Rag1 ubiquitin ligase domain functions in vivo to stimulate TCRß and TCRα gene recombination and influence differentiation of αß T lineage cells, thereby establishing replete diversity of αß TCRs and populations of αß T cells while restraining generation of potentially autoreactive conventional αß T cells.

Inefficient V(D)J recombination underlies monogenic T cell receptor ß expression.

The assembly of T cell receptor (TCR) and immunoglobulin (Ig) genes by V(D)J recombination generates the antigen receptor (AgR) diversity that is vital for adaptive immunity. At most AgR loci, V(D)J recombination is regulated so that only one allele assembles a functional gene, ensuring that nearly every T and B cell expresses a single type, or specificity, of AgR. The genomic organizations of some AgR loci permit the assembly and expression of two distinct genes on each allele; however, this is prevented by undetermined mechanisms. We show that the poor qualities of recombination signal sequences (RSSs) flanking Vß gene segments suppress the assembly and expression of two distinct TCRß genes from a single allele. Our data demonstrate that an intrinsic genetic mechanism that stochastically limits Vß recombination efficiency governs monogenic TCRß expression, thereby restraining the expression of multiple AgRs on αß T cells.

Two Successive Inversional Vß Rearrangements on a Single Tcrb Allele Can Contribute to the TCRß Repertoire.

Mammalian TCRß loci contain 30 Vß gene segments upstream and in the same transcriptional orientation as two DJCß clusters, and a downstream Vß (TRBV31) in the opposite orientation. The textbook view is upstream Vßs rearrange only by deletion and TRBV31 rearranges only by inversion to create VßDJCß genes. In this study, we show in mice that upstream Vßs recombine through inversion to the DJCß2 cluster on alleles carrying a preassembled Trbv31-DJCß1 gene. When this gene is in-frame, Trbv5 evades TCRß-signaled feedback inhibition and recombines by inversion to the DJCß2 cluster, creating αß T cells that express assembled Trbv5-DJCß2 genes. On alleles with an out-of-frame Trbv31-DJCß1 gene, most upstream Vßs recombine at low levels and promote αß T cell development, albeit with preferential expansion of Trbv1-DJß2 rearrangements. Finally, we show wild-type Tcrb alleles produce mature αß T cells that express upstream Vß peptides in surface TCRs and carry Trbv31-DJß2 rearrangements. Our study indicates two successive inversional Vß-to-DJß rearrangements on the same allele can contribute to the TCRß repertoire.

Genome Topology Control of Antigen Receptor Gene Assembly.

The past decade has increased our understanding of how genome topology controls RAG endonuclease-mediated assembly of lymphocyte AgR genes. New technologies have illuminated how the large IgH, Igκ, TCRα/δ, and TCRß loci fold into compact structures that place their numerous V gene segments in similar three-dimensional proximity to their distal recombination center composed of RAG-bound (D)J gene segments. Many studies have shown that CTCF and cohesin protein-mediated chromosome looping have fundamental roles in lymphocyte lineage- and developmental stage-specific locus compaction as well as broad usage of V segments. CTCF/cohesin-dependent loops have also been shown to direct and restrict RAG activity within chromosome domains. We summarize recent work in elucidating molecular mechanisms that govern three-dimensional chromosome organization and in investigating how these dynamic mechanisms control V(D)J recombination. We also introduce remaining questions for how CTCF/cohesin-dependent and -independent genome architectural mechanisms might regulate compaction and recombination of AgR loci.

RAG-1 and ATM coordinate monoallelic recombination and nuclear positioning of immunoglobulin loci.

Coordinated recombination of homologous antigen receptor loci is thought to be important for allelic exclusion. Here we show that homologous immunoglobulin alleles pair in a stage-specific way that mirrors the recombination patterns of these loci. The frequency of homologous immunoglobulin pairing was much lower in the absence of the RAG-1-RAG-2 recombinase and was restored in Rag1-/- developing B cells with a transgene expressing a RAG-1 active-site mutant that supported DNA binding but not cleavage. The introduction of DNA breaks on one immunoglobulin allele induced ATM-dependent repositioning of the other allele to pericentromeric heterochromatin. ATM activated by the cleaved allele acts in trans on the uncleaved allele to prevent biallelic recombination and chromosome breaks or translocations.

V(D)J Recombination Exploits DNA Damage Responses to Promote Immunity.

It has been recognized for 40 years that the variable (diversity) joining [V(D)J] recombination-mediated assembly of diverse B and T lymphocyte antigen receptor (AgR) genes is not only essential for adaptive immunity, but also a risk for autoimmunity and lymphoid malignancies. Over the past few years, several studies have revealed that recombination-activating gene (RAG) endonuclease-induced DNA double-strand breaks (DSBs) transcend hazardous intermediates during antigen receptor gene assembly. RAG cleavage within the genomes of lymphocyte progenitors and immature lymphocytes regulates the expression of ubiquitous and lymphocyte-specific gene transcripts to control the differentiation and function of both adaptive and innate immune cell lineages. These unexpected discoveries raise important new questions that have broad implications for basic immunology research and the screening, diagnosis, and treatment of human immunological disease.

Immature Lymphocytes Inhibit Rag1 and Rag2 Transcription and V(D)J Recombination in Response to DNA Double-Strand Breaks.

Mammalian cells have evolved a common DNA damage response (DDR) that sustains cellular function, maintains genomic integrity, and suppresses malignant transformation. In pre-B cells, DNA double-strand breaks (DSBs) induced at Igκ loci by the Rag1/Rag2 (RAG) endonuclease engage this DDR to modulate transcription of genes that regulate lymphocyte-specific processes. We previously reported that RAG DSBs induced at one Igκ allele signal through the ataxia telangiectasia mutated (ATM) kinase to feedback-inhibit RAG expression and RAG cleavage of the other Igκ allele. In this article, we show that DSBs induced by ionizing radiation, etoposide, or bleomycin suppress Rag1 and Rag2 mRNA levels in primary pre-B cells, pro-B cells, and pro-T cells, indicating that inhibition of Rag1 and Rag2 expression is a prevalent DSB response among immature lymphocytes. DSBs induced in pre-B cells signal rapid transcriptional repression of Rag1 and Rag2, causing downregulation of both Rag1 and Rag2 mRNA, but only Rag1 protein. This transcriptional inhibition requires the ATM kinase and the NF-κB essential modulator protein, implicating a role for ATM-mediated activation of canonical NF-κB transcription factors. Finally, we demonstrate that DSBs induced in pre-B cells by etoposide or bleomycin inhibit recombination of Igκ loci and a chromosomally integrated substrate. Our data indicate that immature lymphocytes exploit a common DDR signaling pathway to limit DSBs at multiple genomic locations within developmental stages wherein monoallelic Ag receptor locus recombination is enforced. We discuss the implications of our findings for mechanisms that orchestrate the differentiation of monospecific lymphocytes while suppressing oncogenic Ag receptor locus translocations.

B Cell-Intrinsic Expression of the HuR RNA-Binding Protein Is Required for the T Cell-Dependent Immune Response In Vivo.

The HuR RNA-binding protein posttranscriptionally controls expression of genes involved in cellular survival, proliferation, and differentiation. To determine roles of HuR in B cell development and function, we analyzed mice with B lineage-specific deletion of the HuR gene. These HuRΔ/Δ mice have reduced numbers of immature bone marrow and mature splenic B cells, with only the former rescued by p53 inactivation, indicating that HuR supports B lineage cells through developmental stage-specific mechanisms. Upon in vitro activation, HuRΔ/Δ B cells have a mild proliferation defect and impaired ability to produce mRNAs that encode IgH chains of secreted Abs, but no deficiencies in survival, isotype switching, or expression of germinal center (GC) markers. In contrast, HuRΔ/Δ mice have minimal serum titers of all Ab isotypes, decreased numbers of GC and plasma B cells, and few peritoneal B-1 B cells. Moreover, HuRΔ/Δ mice have severely decreased GCs, T follicular helper cells, and high-affinity Abs after immunization with a T cell-dependent Ag. This failure of HuRΔ/Δ mice to mount a T cell-dependent Ab response contrasts with the ability of HuRΔ/Δ B cells to become GC-like in vitro, indicating that HuR is essential for aspects of B cell activation unique to the in vivo environment. Consistent with this notion, we find in vitro stimulated HuRΔ/Δ B cells exhibit modestly reduced surface expression of costimulatory molecules whose expression is similarly decreased in humans with common variable immunodeficiency. HuRΔ/Δ mice provide a model to identify B cell-intrinsic factors that promote T cell-dependent immune responses in vivo.

Domain-Specific and Stage-Intrinsic Changes in Tcrb Conformation during Thymocyte Development.

Considerable cross-talk exists between mechanisms controlling genome architecture and gene expression. AgR loci are excellent models for these processes because they are regulated at both conformational and transcriptional levels to facilitate their assembly by V(D)J recombination. Upon commitment to the double-negative stage of T cell development, Tcrb adopts a compact conformation that promotes long-range recombination between Vß gene segments (Trbvs) and their DßJß targets. Formation of a functional VßDßJß join signals for robust proliferation of double-negative thymocytes and their differentiation into double-positive (DP) cells, where Trbv recombination is squelched (allelic exclusion). DP differentiation also is accompanied by decontraction of Tcrb, which has been thought to separate the entire Trbv cluster from DßJß segments (spatial segregation-based model for allelic exclusion). However, DP cells also repress transcription of unrearranged Trbvs, which may contribute to allelic exclusion. We performed a more detailed study of developmental changes in Tcrb topology and found that only the most distal portion of the Trbv cluster separates from DßJß segments in DP thymocytes, leaving most Trbvs spatially available for rearrangement. Preferential dissociation of distal Trbvs is independent of robust proliferation or changes in transcription, chromatin, or architectural factors, which are coordinately regulated across the entire Trbv cluster. Segregation of distal Trbvs also occurs on alleles harboring a functional VßDßJß join, suggesting that this process is independent of rearrangement status and is DP intrinsic. Our finding that most Trbvs remain associated with DßJß targets in DP cells revises allelic exclusion models from their current conformation-dominant to a transcription-dominant formulation.

H2AX prevents CtIP-mediated DNA end resection and aberrant repair in G1-phase lymphocytes.

DNA double-strand breaks (DSBs) are generated by the recombination activating gene (RAG) endonuclease in all developing lymphocytes as they assemble antigen receptor genes. DNA cleavage by RAG occurs only at the G1 phase of the cell cycle and generates two hairpin-sealed DNA (coding) ends that require nucleolytic opening before their repair by classical non-homologous end-joining (NHEJ). Although there are several cellular nucleases that could perform this function, only the Artemis nuclease is able to do so efficiently. Here, in vivo, we show that in murine cells the histone protein H2AX prevents nucleases other than Artemis from processing hairpin-sealed coding ends; in the absence of H2AX, CtIP can efficiently promote the hairpin opening and resection of DNA ends generated by RAG cleavage. This CtIP-mediated resection is inhibited by γ-H2AX and by MDC-1 (mediator of DNA damage checkpoint 1), which binds to γ-H2AX in chromatin flanking DNA DSBs. Moreover, the ataxia telangiectasia mutated (ATM) kinase activates antagonistic pathways that modulate this resection. CtIP DNA end resection activity is normally limited to cells at post-replicative stages of the cell cycle, in which it is essential for homology-mediated repair. In G1-phase lymphocytes, DNA ends that are processed by CtIP are not efficiently joined by classical NHEJ and the joints that do form frequently use micro-homologies and show significant chromosomal deletions. Thus, H2AX preserves the structural integrity of broken DNA ends in G1-phase lymphocytes, thereby preventing these DNA ends from accessing repair pathways that promote genomic instability.

Formation of dynamic gamma-H2AX domains along broken DNA strands is distinctly regulated by ATM and MDC1 and dependent upon H2AX densities in chromatin.

A hallmark of the cellular response to DNA double-strand breaks (DSBs) is histone H2AX phosphorylation in chromatin to generate gamma-H2AX. Here, we demonstrate that gamma-H2AX densities increase transiently along DNA strands as they are broken and repaired in G1 phase cells. The region across which gamma-H2AX forms does not spread as DSBs persist; rather, gamma-H2AX densities equilibrate at distinct levels within a fixed distance from DNA ends. Although both ATM and DNA-PKcs generate gamma-H2AX, only ATM promotes gamma-H2AX formation to maximal distance and maintains gamma-H2AX densities. MDC1 is essential for gamma-H2AX formation at high densities near DSBs, but not for generation of gamma-H2AX over distal sequences. Reduced H2AX levels in chromatin impair the density, but not the distance, of gamma-H2AX formed. Our data suggest that H2AX fuels a gamma-H2AX self-reinforcing mechanism that retains MDC1 and activated ATM in chromatin near DSBs and promotes continued local phosphorylation of H2AX.

Noncore RAG1 regions promote Vß rearrangements and αß T cell development by overcoming inherent inefficiency of Vß recombination signal sequences.

The RAG proteins are comprised of core endonuclease domains and noncore regions that modulate endonuclease activity. Mutation or deletion of noncore RAG regions in humans causes immunodeficiency and altered TCR repertoire, and mice expressing core but not full-length Rag1 (Rag1(C/C)) or Rag2 (Rag2(C/C)) exhibit lymphopenia, reflecting impaired V(D)J recombination and lymphocyte development. Rag1(C/C) mice display reduced D-to-J and V-to-DJ rearrangements of TCRß and IgH loci, whereas Rag2(C/C) mice show decreased V-to-DJ rearrangements and altered Vß/VH repertoire. Because Vßs/VHs only recombine to DJ complexes, the Rag1(C/C) phenotype could reflect roles for noncore RAG1 regions in promoting recombination during only the D-to-J step or during both steps. In this study, we demonstrate that a preassembled TCRß gene, but not a preassembled DßJß complex or the prosurvival BCL2 protein, completely rescues αß T cell development in Rag1(C/C) mice. We find that Rag1(C/C) mice exhibit altered Vß utilization in Vß-to-DJß rearrangements, increased usage of 3'Jα gene segments in Vα-to-Jα rearrangements, and abnormal changes in Vß repertoire during αß TCR selection. Inefficient Vß/VH recombination signal sequences (RSSs) have been hypothesized to cause impaired V-to-DJ recombination on the background of a defective recombinase as in core-Rag mice. We show that replacement of the Vß14 RSS with a more efficient RSS increases Vß14 recombination and rescues αß T cell development in Rag1(C/C) mice. Our data indicate that noncore RAG1 regions establish a diverse TCR repertoire by overcoming Vß RSS inefficiency to promote Vß recombination and αß T cell development, and by modulating TCRß and TCRα gene segment utilization.

The ataxia telangiectasia mutated and cyclin D3 proteins cooperate to help enforce TCRß and IgH allelic exclusion.

Coordination of V rearrangements between loci on homologous chromosomes is critical for Ig and TCR allelic exclusion. The Ataxia Telangietasia mutated (ATM) protein kinase promotes DNA repair and activates checkpoints to suppress aberrant Ig and TCR rearrangements. In response to RAG cleavage of Igκ loci, ATM inhibits RAG expression and suppresses further Vκ-to-Jκ rearrangements to enforce Igκ allelic exclusion. Because V recombination between alleles is more strictly regulated for TCRß and IgH loci, we evaluated the ability of ATM to restrict biallelic expression and V-to-DJ recombination of TCRß and IgH genes. We detected greater frequencies of lymphocytes with biallelic expression or aberrant V-to-DJ rearrangement of TCRß or IgH loci in mice lacking ATM. A preassembled DJß complex that decreases the number of TCRß rearrangements needed for a productive TCRß gene further increased frequencies of ATM-deficient cells with biallelic TCRß expression. IgH and TCRß proteins drive proliferation of prolymphocytes through cyclin D3 (Ccnd3), which also inhibits VH transcription. We show that inactivation of Ccnd3 leads to increased frequencies of lymphocytes with biallelic expression of IgH or TCRß genes. We also show that Ccnd3 inactivation cooperates with ATM deficiency to increase the frequencies of cells with biallelic TCRß or IgH expression while decreasing the frequency of ATM-deficient lymphocytes with aberrant V-to-DJ recombination. Our data demonstrate that core components of the DNA damage response and cell cycle machinery cooperate to help enforce IgH and TCRß allelic exclusion and indicate that control of V-to-DJ rearrangements between alleles is important to maintain genomic stability.