Poor quality Vß recombination signal sequences stochastically enforce TCRß allelic exclusion.

The monoallelic expression of antigen receptor (AgR) genes, called allelic exclusion, is fundamental for highly specific immune responses to pathogens. This cardinal feature of adaptive immunity is achieved by the assembly of a functional AgR gene on one allele, with subsequent feedback inhibition of V(D)J recombination on the other allele. A range of epigenetic mechanisms have been implicated in sequential recombination of AgR alleles; however, we now demonstrate that a genetic mechanism controls this process for Tcrb. Replacement of V(D)J recombinase targets at two different mouse Vß gene segments with a higher quality target elevates Vß rearrangement frequency before feedback inhibition, dramatically increasing the frequency of T cells with TCRß chains derived from both Tcrb alleles. Thus, TCRß allelic exclusion is enforced genetically by the low quality of Vß recombinase targets that stochastically restrict the production of two functional rearrangements before feedback inhibition silences one allele.

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.

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.

The ataxia telangiectasia mutated kinase controls Igκ allelic exclusion by inhibiting secondary Vκ-to-Jκ rearrangements.

Allelic exclusion is enforced through the ability of antigen receptor chains expressed from one allele to signal feedback inhibition of V-to-(D)J recombination on the other allele. To achieve allelic exclusion by such means, only one allele can initiate V-to-(D)J recombination within the time required to signal feedback inhibition. DNA double-strand breaks (DSBs) induced by the RAG endonuclease during V(D)J recombination activate the Ataxia Telangiectasia mutated (ATM) and DNA-dependent protein kinase (DNA-PK) kinases. We demonstrate that ATM enforces Igκ allelic exclusion, and that RAG DSBs induced during Igκ recombination in primary pre-B cells signal through ATM, but not DNA-PK, to suppress initiation of additional Igκ rearrangements. ATM promotes high-density histone H2AX phosphorylation to create binding sites for MDC1, which functions with H2AX to amplify a subset of ATM-dependent signals. However, neither H2AX nor MDC1 is required for ATM to enforce Igκ allelic exclusion and suppress Igκ rearrangements. Upon activation in response to RAG Igκ cleavage, ATM signals down-regulation of Gadd45α with concomitant repression of the Gadd45α targets Rag1 and Rag2. Our data indicate that ATM kinases activated by RAG DSBs during Igκ recombination transduce transient H2AX/MDC1-independent signals that suppress initiation of further Igκ rearrangements to control Igκ allelic exclusion.

Redundant and nonredundant functions of ATM and H2AX in αß T-lineage lymphocytes.

The ataxia telangiectasia mutated (ATM) kinase and H2AX histone tumor suppressor proteins are each critical for maintenance of cellular genomic stability and suppression of lymphomas harboring clonal translocations. ATM is the predominant kinase that phosphorylates H2AX in chromatin around DNA double-strand breaks, including along lymphocyte Ag receptor loci cleaved during V(D)J recombination. However, combined germline inactivation of Atm and H2ax in mice causes early embryonic lethality associated with substantial cellular genomic instability, indicating that ATM and H2AX exhibit nonredundant functions in embryonic cells. To evaluate potential nonredundant roles of ATM and H2AX in somatic cells, we generated and analyzed Atm-deficient mice with conditional deletion of H2ax in αß T-lineage lymphocytes. Combined Atm/H2ax inactivation starting in early-stage CD4(-)/CD8(-) thymocytes resulted in lower numbers of later-stage CD4(+)/CD8(+) thymocytes, but led to no discernible V(D)J recombination defect in G1 phase cells beyond that observed in Atm-deficient cells. H2ax deletion in Atm-deficient thymocytes also did not affect the incidence or mortality of mice from thymic lymphomas with clonal chromosome 14 (TCRα/δ) translocations. Yet, in vitro-stimulated Atm/H2ax-deficient splenic αß T cells exhibited a higher frequency of genomic instability, including radial chromosome translocations and TCRß translocations, compared with cells lacking Atm or H2ax. Collectively, our data demonstrate that both redundant and nonredundant functions of ATM and H2AX are required for normal recombination of TCR loci, proliferative expansion of developing thymocytes, and maintenance of genomic stability in cycling αß T-lineage cells.

Cellular context-dependent effects of H2ax and p53 deletion on the development of thymic lymphoma.

H2AX and Artemis each cooperate with p53 to suppress lymphoma. Germline H2ax(-/-)p53(-/-) mice die of T-cell receptor-ß(-) (TCR-ß(-)) thymic lymphomas with translocations and other lesions characteristic of human T-cell acute lymphoblastic leukemia. Here, we demonstrate that mice with inactivation of H2ax and p53 in thymocytes die at later ages to TCR-ß(-) or TCR-ß(+) thymic lymphomas containing a similar pattern of translocations as H2ax(-/-)p53(-/-) tumors. Germline Artemis(-/-) p53(-/-) mice die of lymphomas with antigen receptor locus translocations, whereas Artemis(-/-)H2ax(-/-)p53(-/-) mice die at earlier ages from multiple malignancies. We show here that Artemis(-/-) mice with p53 deletion in thymocytes die of TCR-ß(-) tumors containing Tcrα/δ translocations, other clonal translocations, or aneuploidy, as well as Notch1 mutations. Strikingly, Artemis(-/-) mice with H2ax and p53 deletion in thymocytes exhibited a lower rate of mortality from TCR-ß(-) tumors, which harbored significantly elevated levels of genomic instability. Our data reveal that the cellular origin of H2ax and p53 loss impacts the rate of mortality from and developmental stage of thymic lymphomas, and suggest that conditional deletion of tumor suppressor genes may provide more physiologic models for human lymphoid malignancies than germline inactivation.

Position-dependent silencing of germline Vß segments on TCRß alleles containing preassembled VßDJßCß1 genes.

The genomic organization of TCRbeta loci enables Vbeta-to-DJbeta2 rearrangements on alleles with assembled VbetaDJbetaCbeta1 genes, which could have deleterious physiologic consequences. To determine whether such Vbeta rearrangements occur and, if so, how they might be regulated, we analyzed mice with TCRbeta alleles containing preassembled functional VbetaDJbetaCbeta1 genes. Vbeta10 segments were transcribed, rearranged, and expressed in thymocytes when located immediately upstream of a Vbeta1DJbetaCbeta1 gene, but not on alleles with a Vbeta14DJbetaCbeta1 gene. Germline Vbeta10 transcription was silenced in mature alphabeta T cells. This allele-dependent and developmental stage-specific silencing of Vbeta10 correlated with increased CpG methylation and decreased histone acetylation over the Vbeta10 promoter and coding region. Transcription, rearrangement, and expression of the Vbeta4 and Vbeta16 segments located upstream of Vbeta10 were silenced on alleles containing either VbetaDJbetaCbeta1 gene; sequences within Vbeta4, Vbeta16, and the Vbeta4/Vbeta16-Vbeta10 intergenic region exhibited constitutive high CpG methylation and low histone acetylation. Collectively, our data indicate that the position of Vbeta segments relative to assembled VbetaDJbetaCbeta1 genes influences their rearrangement and suggest that DNA sequences between Vbeta segments may form boundaries between active and inactive Vbeta chromatin domains upstream of VbetaDJbetaCbeta genes.

Posttranscriptional silencing of VbetaDJbetaCbeta genes contributes to TCRbeta allelic exclusion in mammalian lymphocytes.

Feedback inhibition of V(D)J recombination enforces Ag receptor allelic exclusion in mammalian lymphocytes. Yet, in-frame VbetaDJbeta exons can assemble on both alleles in human and mouse alphabeta T lineage cells. To elucidate mechanisms that enforce TCRbeta allelic exclusion in such cells, we analyzed Vbeta expression and rearrangement in mice containing a functional Vbeta14DJbeta1.5Cbeta1 gene (Vbeta14(NT)) and/or Vbeta8.2DJbeta1.1Cbeta1 transgene (Vbeta8(Tg)). The majority of Vbeta14(NT) and Vbeta8(Tg) alphabeta T lineage cells expressed only Vbeta14(+) or Vbeta8(+) TCRbeta-chains, respectively, and lacked Vbeta rearrangements on wild-type TCRbeta loci. However, endogenous Vbeta rearrangements and alphabeta T lineage cells expressing endogenous Vbetas from wild-type alleles alone or with the prerearranged Vbeta in cell surface TCRbeta-chains were observed in Vbeta14(NT) and Vbeta8(Tg) mice. Although nearly all Vbeta8(Tg):Vbeta14(NT) thymocytes and splenic alphabeta T cells expressed Vbeta8(+) TCRbeta-chains, only half of these lymphocytes expressed Vbeta14(+) TCRbeta-chains, even though similar steady-state levels of Vbeta14(NT) mRNA were expressed in Vbeta8(+)Vbeta14(+) and Vbeta8(+)Vbeta14(-) populations. Our data demonstrated that posttranscriptional silencing of functionally assembled endogenous VbetaDJbetaCbeta genes can enforce TCRbeta allelic exclusion and reveal another mechanism that contributes to the development of lymphocytes with monospecific Ag receptors.

TCR beta feedback signals inhibit the coupling of recombinationally accessible V beta 14 segments with DJ beta complexes.

Ag receptor allelic exclusion is thought to occur through monoallelic initiation and subsequent feedback inhibition of recombinational accessibility. However, our previous analysis of mice containing a V(D)J recombination reporter inserted into Vbeta14 (Vbeta14(Rep)) indicated that Vbeta14 chromatin accessibility is biallelic. To determine whether Vbeta14 recombinational accessibility is subject to feedback inhibition, we analyzed TCRbeta rearrangements in Vbeta14(Rep) mice containing a preassembled in-frame transgenic Vbeta8.2Dbeta1Jbeta1.1 or an endogenous Vbeta14Dbeta1Jbeta1.4 rearrangement on the homologous chromosome. Expression of either preassembled VbetaDJbetaC beta-chain accelerated thymocyte development because of enhanced cellular selection, demonstrating that the rate-limiting step in early alphabeta T cell development is the assembly of an in-frame VbetaDJbeta rearrangement. Expression of these preassembled VbetaDJbeta rearrangements inhibited endogenous Vbeta14-to-DJbeta rearrangements as expected. However, in contrast to results predicted by the accepted model of TCRbeta feedback inhibition, we found that expression of these preassembled TCR beta-chains did not downregulate recombinational accessibility of Vbeta14 chromatin. Our findings suggest that TCRbeta-mediated feedback inhibition of Vbeta14 rearrangements depends on inherent properties of Vbeta14, Dbeta, and Jbeta recombination signal sequences.

Histone H2AX stabilizes broken DNA strands to suppress chromosome breaks and translocations during V(D)J recombination.

The H2AX core histone variant is phosphorylated in chromatin around DNA double strand breaks (DSBs) and functions through unknown mechanisms to suppress antigen receptor locus translocations during V(D)J recombination. Formation of chromosomal coding joins and suppression of translocations involves the ataxia telangiectasia mutated and DNA-dependent protein kinase catalytic subunit serine/threonine kinases, each of which phosphorylates H2AX along cleaved antigen receptor loci. Using Abelson transformed pre-B cell lines, we find that H2AX is not required for coding join formation within chromosomal V(D)J recombination substrates. Yet we show that H2AX is phosphorylated along cleaved Igkappa DNA strands and prevents their separation in G1 phase cells and their progression into chromosome breaks and translocations after cellular proliferation. We also show that H2AX prevents chromosome breaks emanating from unrepaired RAG endonuclease-generated TCR-alpha/delta locus coding ends in primary thymocytes. Our data indicate that histone H2AX suppresses translocations during V(D)J recombination by creating chromatin modifications that stabilize disrupted antigen receptor locus DNA strands to prevent their irreversible dissociation. We propose that such H2AX-dependent mechanisms could function at additional chromosomal locations to facilitate the joining of DNA ends generated by other types of DSBs.

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.

Assembled DJ beta complexes influence TCR beta chain selection and peripheral V beta repertoire.

TCRbeta chain repertoire of peripheral alphabeta T cells is generated through the stepwise assembly and subsequent selection of TCRbeta V region exons during thymocyte development. To evaluate the influence of a two-step recombination process on Vbeta rearrangement and selection, we generated mice with a preassembled Dbeta1Jbeta1.1 complex on the Jbeta1(omega) allele, an endogenous TCRbeta allele that lacks the Dbeta2-Jbeta2 cluster, creating the Jbeta1(DJbeta) allele. As compared with Jbeta1(omega/omega) mice, both Jbeta1(DJbeta/omega) and Jbeta1(DJbeta/DJbeta) mice exhibited grossly normal thymocyte development and TCRbeta allelic exclusion. In addition, Vbeta rearrangements on Jbeta1(DJbeta) and Jbeta1(omega) alleles were similarly regulated by TCRbeta-mediated feedback regulation. However, in-frame VbetaDJbeta rearrangements were present at a higher level on the Jbeta1(DJbeta) alleles of Jbeta1(DJbeta/omega) alphabeta T cell hybridomas, as compared with on the Jbeta1(omega) alleles. This bias was most likely due to both an increased frequency of Vbeta-to-DJbeta rearrangements on Jbeta1(DJbeta) alleles and a preferential selection of cells with in-frame VbetaDJbeta exons assembled on Jbeta1(DJbeta) alleles during the development of Jbeta1(DJbeta/omega) alphabeta T cells. Consistent with the differential selection of in-frame VbetaDJbeta rearrangements on Jbeta1(DJbeta) alleles, the Vbeta repertoire of alphabeta T cells was significantly altered during alphabeta TCR selection in Jbeta1(DJbeta/omega) and Jbeta1(DJbeta/DJbeta) mice, as compared with in Jbeta1(omega/omega) mice. Our data indicate that the diversity of DJbeta complexes assembled during thymocyte development influences TCRbeta chain selection and peripheral Vbeta repertoire.