Activation of Mouse Tcrb: Uncoupling RUNX1 Function from Its Cooperative Binding with ETS1.

T lineage commitment requires the coordination of key transcription factors (TFs) in multipotent progenitors that transition them away from other lineages and cement T cell identity. Two important TFs for the multipotent progenitors to T lineage transition are RUNX1 and ETS1, which bind cooperatively to composite sites throughout the genome, especially in regulatory elements for genes involved in T lymphopoiesis. Activation of the TCR ß (Tcrb) locus in committed thymocytes is a critical process for continued development of these cells, and is mediated by an enhancer, Eß, which harbors two RUNX-ETS composite sites. An outstanding issue in understanding T cell gene expression programs is whether RUNX1 and ETS1 have independent functions in enhancer activation that can be dissected from cooperative binding. We now show that RUNX1 is sufficient to activate the endogenous mouse Eß element and its neighboring 25 kb region by independently tethering this TF without coincidental ETS1 binding. Moreover, RUNX1 is sufficient for long-range promoter-Eß looping, nucleosome clearance, and robust transcription throughout the Tcrb recombination center, spanning both DßJß clusters. We also find that a RUNX1 domain, termed the negative regulatory domain for DNA binding, can compensate for the loss of ETS1 binding at adjacent sites. Thus, we have defined independent roles for RUNX1 in the activation of a T cell developmental enhancer, as well as its ability to mediate specific changes in chromatin landscapes that accompany long-range induction of recombination center promoters.

Regulation of antigen receptor gene assembly by genetic-epigenetic crosstalk.

Many aspects of gene function are coordinated by changes in the epigenome, which include dynamic revisions of chromatin modifications, genome packaging, subnuclear localization, and chromosome conformation. All of these mechanisms are used by developing lymphocytes to regulate the assembly of functional antigen receptor genes by V(D)J recombination. This somatic rearrangement of the genome must be tightly regulated to ensure proper B and T cell development and to avoid chromosomal translocations that cause lymphoid tumors. V(D)J recombination is controlled by a complex interplay between cis-acting regulatory elements that use transcription factors as liaisons to communicate with epigenetic pathways. Genetic-epigenetic crosstalk is a key strategy employed by precursor lymphocytes to modulate chromatin configurations at Ig and Tcr loci and thereby permit or deny access to a single V(D)J recombinase complex. This article describes our current knowledge of how genetic elements orchestrate crosstalk with epigenetic mechanisms to regulate recombinase accessibility via localized, regional, or long-range changes in chromatin.

Transcription-dependent mobilization of nucleosomes at accessible TCR gene segments in vivo.

Accessibility of chromosomal recombination signal sequences to the RAG protein complex is known to be essential for V(D)J recombination at Ag receptor loci in vivo. Previous studies have addressed the roles of cis-acting regulatory elements and germline transcription in the covalent modification of nucleosomes at Ag receptor loci. However, a detailed picture of nucleosome organization at accessible and inaccessible recombination signal sequences has been lacking. In this study, we have analyzed the nucleosome organization of accessible and inaccessible Tcrb and Tcra alleles in primary murine thymocytes in vivo. We identified highly positioned arrays of nucleosomes at Dbeta, Jbeta, and Jalpha segments and obtained evidence indicating that positioning is established at least in part by the regional DNA sequence. However, we found no consistent positioning of nucleosomes with respect to recombination signal sequences, which could be nucleosomal or internucleosomal even in their inaccessible configurations. Enhancer- and promoter-dependent accessibility was characterized by diminished abundance of certain nucleosomes and repositioning of others. Moreover, some changes in nucleosome positioning and abundance at Jalpha61 were shown to be a direct consequence of germline transcription. We suggest that enhancer- and promoter-dependent transcription generates optimal recombinase substrates in which some nucleosomes are missing and others are covalently modified.

Cutting edge: SWI/SNF mediates antisense Igh transcription and locus-wide accessibility in B cell precursors.

The stepwise process of Ag receptor gene assembly, termed V(D)J recombination, is coordinated during lymphocyte development by sweeping changes in chromatin that permit or deny access to a single recombinase enzyme. We now show that switching/sucrose nonfermenting (SWI/SNF) chromatin remodeling complexes are recruited to the Igh locus by an enhancer-dependent process and that these complexes are essential for generating recombinase accessibility throughout the locus. Depletion of SWI/SNF in pro-B cells also inhibits antisense transcription through all clusters of Igh gene segments, a pioneering process that has been implicated in the initial opening of chromatin. We conclude that SWI/SNF complexes play multiple roles in Igh gene assembly, ranging from initial locus activation to the spreading and maintenance of chromatin accessibility over large V(H), D(H), and J(H) domains.

Accessibility control of V(D)J recombination.

Mammals contend with a universe of evolving pathogens by generating an enormous diversity of antigen receptors during lymphocyte development. Precursor B and T cells assemble functional immunoglobulin (Ig) and T cell receptor (TCR) genes via recombination of numerous variable (V), diversity (D), and joining (J) gene segments. Although this combinatorial process generates significant diversity, genetic reorganization is inherently dangerous. Thus, V(D)J recombination must be tightly regulated to ensure proper lymphocyte development and avoid chromosomal translocations that cause lymphoid tumors. Each genomic rearrangement is mediated by a common V(D)J recombinase that recognizes sequences flanking all antigen receptor gene segments. The specificity of V(D)J recombination is due, in large part, to changes in the accessibility of chromatin at target gene segments, which either permits or restricts access to recombinase. The chromatin configuration of antigen receptor loci is governed by the concerted action of enhancers and promoters, which function as accessibility control elements (ACEs). In general, ACEs act as conduits for transcription factors, which in turn recruit enzymes that covalently modify or remodel nucleosomes. These ACE-mediated alterations are critical for activation of gene segment transcription and for opening chromatin associated with recombinase target sequences. In this chapter, we describe advances in understanding the mechanisms that control V(D)J recombination at the level of chromatin accessibility. The discussion will focus on cis-acting regulation by ACEs, the nuclear factors that control ACE function, and the epigenetic modifications that establish recombinase accessibility.

Functional intersection of ATM and DNA-dependent protein kinase catalytic subunit in coding end joining during V(D)J recombination.

V(D)J recombination is initiated by the RAG endonuclease, which introduces DNA double-strand breaks (DSBs) at the border between two recombining gene segments, generating two hairpin-sealed coding ends and two blunt signal ends. ATM and DNA-dependent protein kinase catalytic subunit (DNA-PKcs) are serine-threonine kinases that orchestrate the cellular responses to DNA DSBs. During V(D)J recombination, ATM and DNA-PKcs have unique functions in the repair of coding DNA ends. ATM deficiency leads to instability of postcleavage complexes and the loss of coding ends from these complexes. DNA-PKcs deficiency leads to a nearly complete block in coding join formation, as DNA-PKcs is required to activate Artemis, the endonuclease that opens hairpin-sealed coding ends. In contrast to loss of DNA-PKcs protein, here we show that inhibition of DNA-PKcs kinase activity has no effect on coding join formation when ATM is present and its kinase activity is intact. The ability of ATM to compensate for DNA-PKcs kinase activity depends on the integrity of three threonines in DNA-PKcs that are phosphorylation targets of ATM, suggesting that ATM can modulate DNA-PKcs activity through direct phosphorylation of DNA-PKcs. Mutation of these threonine residues to alanine (DNA-PKcs(3A)) renders DNA-PKcs dependent on its intrinsic kinase activity during coding end joining, at a step downstream of opening hairpin-sealed coding ends. Thus, DNA-PKcs has critical functions in coding end joining beyond promoting Artemis endonuclease activity, and these functions can be regulated redundantly by the kinase activity of either ATM or DNA-PKcs.

Targeting V(D)J recombinase: putting a PHD to work.

In this issue of Immunity, Liu et al. (2007) show that V(D)J recombinase binds chromatin marked by H3K4 trimethylation. Because this mark associates with active promoters, the finding forges a new link between transcription, epigenetics, and recombinase targeting during lymphocyte development.

Essential function for SWI-SNF chromatin-remodeling complexes in the promoter-directed assembly of Tcrb genes.

The assembly of genes encoding antigen receptors is regulated by developmental changes in chromatin that either permit or deny access to a single variable-(diversity)-joining recombinase. These changes are guided by transcriptional promoters and enhancers, which serve as accessibility-control elements in antigen-receptor loci. The function of each accessibility-control element and the factors they recruit to remodel chromatin remain obscure. Here we show that the recruitment of SWI-SNF chromatin-remodeling complexes compensated for the accessibility-control element function of a promoter but not an enhancer of the T cell receptor-beta locus (Tcrb). Loss of SWI-SNF function in thymocytes inactivated recombinase targets at the endogenous Tcrb locus. Thus, initiation of Tcrb gene assembly and T cell development is contingent on the recruitment of SWI-SNF to promoters, which exposes gene segments to variable-(diversity)-joining recombinase.

Targeted inhibition of V(D)J recombination by a histone methyltransferase.

The tissue- and stage-specific assembly of antigen receptor genes by V(D)J recombination is regulated by changes in the chromatin accessibility of target gene segments. This dynamic remodeling process is coordinated by cis-acting promoters and enhancers, which function as accessibility control elements. The basic epigenetic mechanisms that activate or repress chromatin accessibility to V(D)J recombinase remain unclear. We now demonstrate that a histone methyltransferase overrides accessibility control element function and cripples V(D)J recombination of chromosomal gene segments. The recruited histone methyltransferase induces extensive revisions in the local chromatin environment, including altered histone modifications and de novo methylation of DNA. These findings indicate a key function for histone methyltransferases in the tissue- and stage-specific suppression of antigen receptor gene assembly during lymphocyte development.