Chromatin remodeling at the Ig loci prior to V(D)J recombination

Clonally stable Vκ allelic choice instructs Igκ repertoire

Although much has been done to understand how rearrangement of the Igκ locus is regulated during B-cell development, little is known about the way the variable (V) segments themselves are selected. Here we show, using B6/Cast hybrid pre-B-cell clones, that a limited number of V segments on each allele is stochastically activated as characterized by the appearance of non-coding RNA and histone modifications. The activation states are clonally distinct, stable across cell division and developmentally important in directing the Ig repertoire upon differentiation. Using a new approach of allelic ATAC-seq, we demonstrate that the Igκ V alleles have differential chromatin accessibility, which may serve as the underlying basis of clonal maintenance at this locus, as well as other instances of monoallelic expression throughout the genome. These findings highlight a new level of immune system regulation that optimizes gene diversity.

B cell development involves sequential rearrangement of the immunoglobulin chains, but fine control over the selection process remains a mystery. Here the authors show that individual alleles in pre-B cells are clonally unique and result from stochastic activation of V gene segments to induce optimal generation of a diverse repertoire.

Regulated large-scale nucleosome density patterns and precise nucleosome positioning correlate with V(D)J recombination

We show that the physical distribution of nucleosomes at antigen receptor loci is subject to regulated cell type-specific and lineage-specific positioning and correlates with the accessibility of these gene segments to recombination. At the Ig heavy chain locus (IgH), a nucleosome in pro-B cells is generally positioned over each IgH variable (VH) coding segment, directly adjacent to the recombination signal sequence (RSS), placing the RSS in a position accessible to the recombination activating gene (RAG) recombinase. These changes result in establishment of a specific chromatin organization at the RSS that facilitates accessibility of the genomic DNA for the RAG recombinase. In contrast, in mouse embryonic fibroblasts the coding segment is depleted of nucleosomes, which instead cover the RSS, thereby rendering it inaccessible. Pro-T cells exhibit a pattern intermediate between pro-B cells and mouse embryonic fibroblasts. We also find large-scale variations of nucleosome density over hundreds of kilobases, delineating chromosomal domains within IgH, in a cell type-dependent manner. These findings suggest that developmentally regulated changes in nucleosome location and occupancy, in addition to the known chromatin modifications, play a fundamental role in regulating V(D)J recombination. Nucleosome positioning-which has previously been observed to vary locally at individual enhancers and promoters-may be a more general mechanism by which cells can regulate the accessibility of the genome during development, at scales ranging from several hundred base pairs to many kilobases.

Spatial Regulation of V-(D)J Recombination at Antigen Receptor Loci

Lymphocytes express a diverse repertoire of antigen receptors, which are able to recognize a large variety of foreign pathogens. Functional antigen receptor genes are assembled by V(D)J recombination in immature B cells (Igh and Igk) and T cells (Tcr b and Tcra/d). V(D)J recombination takes place in the 3' proximal domain containing the D, J, and C gene segments, whereas 31 (Tcrb) to 200 (Igh) V genes are spread over a large region of 0.67 (Tcrb) to 3 (Igk) megabase pairs. The spatial regulation of V(D)J recombination has been best studied for the Igh locus, which undergoes reversible contraction by long-range looping in pro-B cells. This large-scale contraction brings distantly located VH genes into close proximity of the DJH-rearranged gene segment, which facilitates VH-DJH recombination. The B-cell-specific Pax5, ubiquitous YY1, and architectural CTCF/cohesin proteins regulate Igh locus contraction in pro-B cells by binding to multiple sites in the VH gene cluster. These regulators also control the pro-B-cell-specific activity of the distally located PAIR elements, which may be involved in the regulation of VH-DJH recombination by promoting locus contraction. Moreover, the large VH gene cluster of the Igh locus undergoes flexible long-range looping, which guarantees similar participation of all VH genes in VH-DJH recombination to generate a diverse antibody repertoire. Importantly, long-range looping is a more general regulatory principle, as other antigen receptor loci also undergo reversible contraction at the developmental stage, where they engage in V-(D)J recombination.

Genetic and epigenetic determinants mediate proneness of oncogene breakpoint sites for involvement in TCR translocations

T-cell receptor (TCR) translocations are a genetic hallmark of T-cell acute lymphoblastic leukemia and lead to juxtaposition of oncogene and TCR loci. Oncogene loci become involved in translocations because they are accessible to the V(D)J recombination machinery. Such accessibility is predicted at cryptic recombination signal sequence (cRSS) sites ('Type 1') as well as other sites that are subject to DNA double-strand breaks (DSBs) ('Type 2') during early stages of thymocyte development. As chromatin accessibility markers have not been analyzed in the context of TCR-associated translocations, various genetic and epigenetic determinants of LMO2, TAL1 and TLX1 translocation breakpoint (BP) sites and BP cluster regions (BCRs) were examined in human thymocytes to establish DSB proneness and heterogeneity of BP site involvement in TCR translocations. Our data show that DSBs in BCRs are primarily induced in the presence of a genetic element of sequence vulnerability (cRSSs, transposable elements), whereas breaks at single BP sites lacking such elements are more likely induced by chance or perhaps because of patient-specific genetic vulnerability. Vulnerability to obtain DSBs is increased by features that determine chromatin organization, such as methylation status and nucleosome occupancy, although at different levels at different BP sites.

Breakpoint regions of ETO gene involved in (8; 21) leukemic translocations are enriched in acetylated histone H3

One of the most frequent chromosomal translocation found in patients with acute myeloid leukemia (AML) is the t(8;21). This translocation involves the RUNX1 and ETO genes. The breakpoints regions for t(8;21) are located at intron 5 and intron 1 of the RUNX1 and ETO gene respectively. To date, no homologous sequences have been found in these regions to explain their recombination. The breakpoint regions of RUNX1 gene are characterized by the presence of DNasaI hypersensitive sites and topoisomerase II cleavage sites, but no information exists about complementary regions of ETO gene. Here, we report analysis of chromatin structure of ETO breakpoint regions. Chromatin immunoprecipitation (ChIP) were performed with antibodies specific to acetylated histone H3, H4, and total histone H1. Nucleosomal distribution at the ETO locus was evaluated by determining total levels of histone H3. Our data show that in myeloid cells, the breakpoint regions at the ETO gene are enriched in hyperacetylated histone H3 compared to a control region of similar size where no translocations have been described. Moreover, acetylated H4 associates with both the whole ETO breakpoint regions as well as the control intron. Interestingly, we observed no H1 association either at the breakpoint regions or the control region of the ETO gene. Our data indicate that a common chromatin structure enriched in acetylated histones is present in breakpoint regions involved in formation of (8;21) leukemic translocation.

Checkpoints of B cell differentiation: visualizing Ig-centric processes

The generation of antibody responses and B cell memory can only take place following multiple steps of differentiation. Key molecular processes during precursor B cell differentiation in bone marrow generate unique antibodies. These antibodies are further optimized via molecular modifications during immune responses in peripheral lymphoid organs. Multiple checkpoints ensure proper differentiation of precursor and mature B lymphocytes. Many of these checkpoints have been found disrupted in patients with a primary immunodeficiency. Based on studies in these patients and in mouse models, new insights have been generated in B cell differentiation and antibody responses. Still, in many patients with impaired antibody formation, it remains unclear how B cells are affected. In this perspective, we present 11 critical processes in B cell differentiation. We discuss how defects in these processes can result in impaired checkpoint selection and how they can be visualized in healthy subjects and patients with immunodeficiency or other immunological disease.

Two forms of loops generate the chromatin conformation of the immunoglobulin heavy-chain gene locus

The immunoglobulin heavy-chain (IgH) gene locus undergoes radial repositioning within the nucleus and locus contraction in preparation for gene recombination. We demonstrate that IgH locus conformation involves two levels of chromosomal compaction. At the first level, the locus folds into several multilooped domains. One such domain at the 3' end of the locus requires an enhancer, Eμ; two other domains at the 5' end are Eμ independent. At the second level, these domains are brought into spatial proximity by Eμ-dependent interactions with specific sites within the V(H) region. Eμ is also required for radial repositioning of IgH alleles, indicating its essential role in large-scale chromosomal movements in developing lymphocytes. Our observations provide a comprehensive view of the conformation of IgH alleles in pro-B cells and the mechanisms by which it is established.

Control of V(D)J Recombination through Transcriptional Elongation and Changes in Locus Chromatin Structure and Nuclear Organization

V(D)J recombination is the assembly of gene segments at the antigen receptor loci to generate antigen receptor diversity in T and B lymphocytes. This process is regulated, according to defined developmental programs, by the action of a single specific recombinase complex formed by the recombination antigen gene (RAG-1/2) proteins that are expressed in immature lymphocytes. V(D)J recombination is strictly controlled by RAG-1/2 accessibility to specific recombination signal sequences in chromatin at several levels: cellular lineage, temporal regulation, gene segment order, and allelic exclusion. DNA cleavage by RAG-1/2 is regulated by the chromatin structure, transcriptional elongation, and three-dimensional architecture and position of the antigen receptor loci in the nucleus. Cis-elements specifically direct transcription and V(D)J recombination at these loci through interactions with transacting factors that form molecular machines that mediate a sequence of structural events. These events open chromatin to activate transcriptional elongation and to permit the access of RAG-1/2 to their recombination signal sequences to drive the juxtaposition of the V, D, and J segments and the recombination reaction itself. This chapter summarizes the advances in this area and the important role of the structure and position of antigen receptor loci within the nucleus to control this process.

Epigenetics of haematopoietic cell development

Cells of the immune system are generated through a developmental cascade that begins in haematopoietic stem cells. During this process, gene expression patterns are programmed in a series of stages that bring about the restriction of cell potential, ultimately leading to the formation of specialized innate immune cells and mature lymphocytes that express antigen receptors. These events involve the regulation of both gene expression and DNA recombination, mainly through the control of chromatin accessibility. In this Review, we describe the epigenetic changes that mediate this complex differentiation process and try to understand the logic of the programming mechanism.

Local and global epigenetic regulation of V(D)J recombination

Despite using the same Rag recombinase machinery expressed in both lymphocyte lineages, V(D)J recombination of immunoglobulins only occurs in B cells and T cell receptor recombination is confined to T cells. This vital segregation of recombination targets is governed by the coordinated efforts of several epigenetic mechanisms that control both the general chromatin accessibility of these loci to the Rag recombinase, and the movement and synapsis of distal gene segments in these enormous multigene AgR loci, in a lineage and developmental stage-specific manner. These mechanisms operate both locally at individual gene segments and AgR domains, and globally over large distances in the nucleus. Here we will discuss the roles of several epigenetic components that regulate V(D)J recombination of the immunoglobulin heavy chain locus in B cells, both in the context of the locus itself, and of its 3D nuclear organization, focusing in particular on non-coding RNA transcription. We will also speculate about how several newly described epigenetic mechanisms might impact on AgR regulation.

Epigenetic control of recombination in the immune system

Immune receptor gene expression is regulated by a series of developmental events that modify their accessibility in a locus, cell type, stage and allele-specific manner. This is carried out by a programmed combination of many different molecular mechanisms, including region-wide replication timing, changes in nuclear localization, chromatin contraction, histone modification, nucleosome positioning and DNA methylation. These modalities ultimately work by controlling steric interactions between receptor loci and the recombination machinery.

[Heterochromatin compartments and gene silencing: human hematopoietic differentiation as a model study]

In order to accomplish its differentiation program, the nucleus of a multipotent cell must be sequentially reprogrammed to acquire and maintain new gene expression patterns. When a stem cell is committed to differentiate towards a given lineage, global genome reprogramming involves both repression of non-affiliated genes and selective activation of genes involved in the establishment of the lineage. Accumulating evidence indicates that lineage specific gene expression is determined not only by the availability of specific transcription factors, but also by epigenetic modifications including both local modifications of DNA and chromatin structure, as well as global topological changes in chromosomes and genes positioning in the nucleus. Combined, these different levels of gene regulation allow for fine controls that integrate environmental and intracellular signals to establish appropriate gene expression programs, and hence ultimately determine the identity of the cell. Therefore, epigenetic modifications most likely precede gene activation and play a critical role in the choices of a stem cell to continue to self-renew or to differentiate. However, the cause-effect relationship between chromatin structure, nuclear architecture and cell-fate decisions is still a matter of debate. The pericentromeric heterochromatin compartment will be presented as one of the best studied examples to understand the impact of and positioning of a gene on its transcription. We will set the influence of heterochromatin compartments in the context of hematopoietic differentiation of human multipotent progenitors.

The epigenetic role of non-coding RNA transcription and nuclear organization in immunoglobulin repertoire generation

Within the lymphocyte lineages, restriction of immunoglobulin V(D)J recombination to B cells and T cell receptor (TCR) recombination to T cells is governed by a myriad of epigenetic mechanisms that control the chromatin accessibility of these loci to the Rag recombinase machinery in a lineage and developmental stage-specific manner. These mechanisms operate both locally at individual gene segments, and globally over large chromatin domains in these enormous multigene loci. In this review we will explore the established and emerging roles of three aspects of epigenetic regulation that contribute to large-scale control of the immunoglobulin heavy chain locus in B cells: non-coding RNA transcription, regulatory elements, and nuclear organization. Recent conceptual and technological advances have produced a paradigm shift in our thinking about how these components regulate gene expression in general and V(D)J recombination in particular.

Epigenetic regulation of V(D)J recombination

Chromosome breaks are dangerous business, carrying the risk of loss of genetic information or, even worse, misrepair of the break, leading to outcomes such as dicentric chromosomes or oncogenic translocations. Yet V(D)J recombination, a process that breaks, rearranges and repairs chromosomes, is crucial to the development of the adaptive immune system, for it gives B- and T-cells the capacity to generate a virtually unlimited repertoire of antigen receptor proteins to combat an equally vast array of antigens. To minimize the risks inherent in chromosomal breakage, V(D)J recombination is carefully orchestrated at multiple levels, ranging from DNA sequence requirements all the way up to chromatin conformation and nuclear architecture. In the present chapter we introduce various regulatory controls, with an emphasis on epigenetic mechanisms and recent work that has begun to elucidate their interdependence.

Allelic exclusion of immunoglobulin genes: models and mechanisms

The allelic exclusion of immunoglobulin (Ig) genes is one of the most evolutionarily conserved features of the adaptive immune system and underlies the monospecificity of B cells. While much has been learned about how Ig allelic exclusion is established during B-cell development, the relevance of monospecificity to B-cell function remains enigmatic. Here, we review the theoretical models that have been proposed to explain the establishment of Ig allelic exclusion and focus on the molecular mechanisms utilized by developing B cells to ensure the monoallelic expression of Ig kappa and Ig lambda light chain genes. We also discuss the physiological consequences of Ig allelic exclusion and speculate on the importance of monospecificity of B cells for immune recognition.

Long noncoding RNAs: implications for antigen receptor diversification

Noncoding RNAs (ncRNAs), both small and large, have recently risen to prominence as surprisingly versatile regulators of gene expression. In fact, eukaryotic transcriptomes are rife with RNAs that do not code for protein, though the majority of these species remains wholly uncharacterized. The functional diversity among the mere handful of validated ncRNAs hints at the vast regulatory potential of these silent biomolecules. Though the act of noncoding transcription and the resultant ncRNAs do not directly produce proteins, they represent powerful means of gene control. Here we survey the accumulating literature on the myriad functions of long ncRNAs and emphasize one curious case of noncoding transcription at antigen receptor loci in lymphocytes.

Cis-regulatory elements and epigenetic changes control genomic rearrangements of the IgH locus

Immunoglobulin variable region exons are assembled from discontinuous variable (V), diversity (D), and joining (J) segments by the process of V(D)J recombination. V(D)J rearrangements of the immunoglobulin heavy chain (IgH) locus are tightly controlled in a tissue-specific, ordered and allele-specific manner by regulating accessibility of V, D, and J segments to the recombination activating gene proteins which are the specific components of the V(D)J recombinase. In this review we discuss recent advances and established models brought forward to explain the mechanisms underlying accessibility control of V(D)J recombination, including research on germline transcripts, spatial organization, and chromatin modifications of the immunoglobulin heavy chain (IgH) locus. Furthermore, we review the functions of well-described and potential new cis-regulatory elements with regard to processes such as V(D)J recombination, allelic exclusion, and IgH class switch recombination.

A 220-nucleotide deletion of the intronic enhancer reveals an epigenetic hierarchy in immunoglobulin heavy chain locus activation

A tissue-specific transcriptional enhancer, Eμ, has been implicated in developmentally regulated recombination and transcription of the immunoglobulin heavy chain (IgH) gene locus. We demonstrate that deleting 220 nucleotides that constitute the core Eμ results in partially active locus, characterized by reduced histone acetylation, chromatin remodeling, transcription, and recombination, whereas other hallmarks of tissue-specific locus activation, such as loss of H3K9 dimethylation or gain of H3K4 dimethylation, are less affected. These observations define Eμ-independent and Eμ-dependent phases of locus activation that reveal an unappreciated epigenetic hierarchy in tissue-specific gene expression.

Replication timing as an epigenetic mark

Although early replication has long been associated with accessible chromatin, replication timing is not included in most discussions of epigenetic marks. This is partly due to a lack of understanding of the mechanisms behind this association but the issue has also been confounded by studies concluding that there are very few changes in replication timing during development. Recently, the first genome-wide study of replication timing during the course of differentiation revealed extensive changes that were strongly associated with changes in transcriptional activity and subnuclear organization. Domains of temporally coordinate replication delineate discrete units of chromosome structure and function that are characteristic of particular differentiation states. Hence, although we are still a long way from understanding the functional significance of replication timing, it is clear that replication timing is a distinct epigenetic signature of cell differentiation state.

An activation-induced cytidine deaminase-independent mechanism of secondary VH gene rearrangement in preimmune human B cells

V(H) replacement is a form of IgH chain receptor editing that is believed to be mediated by recombinase cleavage at cryptic recombination signal sequences (cRSS) embedded in V(H) genes. Whereas there are several reports of V(H) replacement in primary and transformed human B cells and murine models, it remains unclear whether V(H) replacement contributes to the normal human B cell repertoire. We identified V(H)-->V(H)(D)J(H) compound rearrangements from fetal liver, fetal bone marrow, and naive peripheral blood, all of which involved invading and recipient V(H)4 genes that contain a cryptic heptamer, a 13-bp spacer, and nonamer in the 5' portion of framework region 3. Surprisingly, all pseudohybrid joins lacked the molecular processing associated with typical V(H)(D)J(H) recombination or nonhomologous end joining. Although inefficient compared with a canonical recombination signal sequences, the V(H)4 cRSS was a significantly better substrate for in vitro RAG-mediated cleavage than the V(H)3 cRSS. It has been suggested that activation-induced cytidine deamination (AICDA) may contribute to V(H) replacement. However, we found similar secondary rearrangements using V(H)4 genes in AICDA-deficient human B cells. The data suggest that V(H)4 replacement in preimmune human B cells is mediated by an AICDA-independent mechanism resulting from inefficient but selective RAG activity.

Altered chromatin modifications in AML1/RUNX1 breakpoint regions involved in (8;21) translocation

The RUNX1/AML1 gene is the most frequent target for chromosomal translocation, and often identified as a site for reciprocal rearrangement of chromosomes 8 and 21 in patients with acute myelogenous leukemia. Virtually all chromosome translocations in leukemia show no consistent homologous sequences at the breakpoint regions. However, specific chromatin elements (DNase I and topoisomerase II cleavage) have been found at the breakpoints of some genes suggesting that structural motifs are determinant for the double strand DNA-breaks. We analyzed the chromatin organization at intron 5 of the RUNX1 gene where all the sequenced breakpoints involved in t(8;21) have been mapped. Using chromatin immunoprecipitation assays we show that chromatin organization at intron 5 of the RUNX1 gene is different in HL-60 and HeLa cells. Two distinct features mark the intron 5 in cells expressing RUNX1: a complete lack or significantly reduced levels of Histone H1 and enrichment of hyperacetylated histone H3. Strikingly, induction of DNA damage resulted in formation of t(8;21) in HL-60 but not in HeLa cells. Taken together, our results suggest that H1 depletion and/or histone H3 hyperacetylation may have a linkage with an increase susceptibility of specific chromosomal regions to undergo translocations.

How chromatin remodelling allows shuffling of immunoglobulin heavy chain genes

Cellular identity is determined by the switching on and off of lineage-specific genes. This dynamic process is regulated by a highly co-ordinated series of chromatin remodelling mechanisms that control DNA accessibility to facilitate transcription, replication and recombination. The identity of an individual B-lymphocyte is defined by the expression of a unique antibody protein, composed of two identical immunoglobulin heavy and two identical light chain polypeptides, which recognize a single foreign antigen with high specificity. However, the mammalian adaptive immune system requires an enormous variety of antibody-expressing B cells to combat the millions of foreign antigens it may encounter. This diversity is generated primarily at the multigene immunoglobulin loci by V(D)J recombination, a specialised form of DNA recombination in which numerous variable (V), diversity (D) and joining (J) genes are cut and pasted together in a strict order to allow shuffling of immunoglobulin genes. The mouse immunoglobulin heavy chain (Igh) locus is the largest known multigene locus. It spans approximately 3 Mb and comprises more than 200 genes. Its size and complexity pose an enormous logistic challenge to the chromatin remodelling machinery, but recent major advances in our understanding of how the 200 genes are shuffled have begun to reveal an exquisitely co-ordinated set of chromatin remodelling mechanisms which exploit every aspect of nuclear dynamics, and provide a global view of multigene regulation. This review will explore the numerous processes implicated in opening up and positioning of the locus to enable shuffling of the Igh locus genes, including non-coding RNA transcription, histone modifications, transcription factors, nuclear relocation and locus contraction.

Dynamic changes in accessibility, nuclear positioning, recombination, and transcription at the Ig kappa locus

The 3-megabase Igkappa locus undergoes differentially controlled nuclear positioning events and chromatin structural changes during the course of B cell development. The temporal association of chromatin structural changes, transcription, and recombination at the Igkappa locus was determined in a murine pre-B cell line that can be induced to recombine at the Igkappa locus and in ex vivo-cultured murine pre-B cells. Additionally, the timing of nuclear positioning relative to the temporal order of chromatin structural changes and recombination and transcription was determined. We demonstrate that before induction, the Igkappa locus was poised for recombination; both alleles were in a contracted state, and the enrichment of histone modifications and germline transcripts of specific Vkappa genes were observed. Histone modifications of the Vkappa genes did not vary upon induction but the levels of modifications correlated with the levels of germline Vkappa gene transcripts and recombination. Upon induction, but before VkappaJkappa recombination, centromeric recruitment of single Igkappa alleles occurred. DNase I sensitivity of the entire locus increased gradually over the course of differentiation while the enrichment of histone modifications downstream of the Vkappa genes was increased in the silencer regions upstream of Jkappa1, within the Igkappa sterile transcript, the kappa constant region, the Ekappai and Ekappa3' enhancers, and the recombining sequence. The ex vivo pre-B cells showed similar patterns of histone modifications across the locus except at the Vkappa genes. In this study, H3 acetylation correlated with levels of germline transcripts while H3 methylation correlated with levels of recombination.

Transcription of a productively rearranged Ig VDJC alpha does not require the presence of HS4 in the IgH 3' regulatory region

V gene assembly, class switch recombination, and somatic hypermutation are gene-modifying processes essential to the development of an effective Ab response. If inappropriately applied, however, these processes can mediate genetic changes that lead to disease (e.g., lymphoma). A series of control elements within the Ig H chain (Igh) locus has been implicated in regulating these processes as well as in regulating IgH gene transcription. These include the intronic enhancer (Emu) and several elements at the 3' end of the locus (hs1,2, hs3a, hs3b, and hs4) known collectively as the 3' regulatory region. Although it is clear that the Emu plays a unique role in V gene assembly, it has not been established whether there are unique functions for each element within the 3' regulatory region. In earlier studies in mice and in mouse cell lines, pairwise deletion of hs3b and hs4 had a dramatic effect on both class switch recombination and IgH gene transcription; deletion of an element almost identical with hs3b (hs3a), however, yielded no discernible phenotype. To test the resulting hypothesis that hs4 is uniquely required for these processes, we induced the deletion of hs4 within a bacterial artificial chromosome transgene designed to closely approximate the 3' end of the natural Igh locus. When introduced into an Ig-secreting cell line, an Igalpha transcription unit within the bacterial artificial chromosome was expressed efficiently and the subsequent deletion of hs4 only moderately affected Igalpha expression. Thus, hs4 does not play a uniquely essential role in the transcription of a productively rearranged Ig VDJCalpha transcription unit.

Antisense intergenic transcription precedes Igh D-to-J recombination and is controlled by the intronic enhancer Emu

V(D)J recombination is believed to be regulated by alterations in chromatin accessibility to the recombinase machinery, but the mechanisms responsible remain unclear. We previously proposed that antisense intergenic transcription, activated throughout the mouse Igh VH region in pro-B cells, remodels chromatin for VH-to-DJH recombination. Using RNA fluorescence in situ hybridization, we now show that antisense intergenic transcription occurs throughout the Igh DHJH region before D-to-J recombination, indicating that this is a widespread process in V(D)J recombination. Transcription initiates near the Igh intronic enhancer Emu and is abrogated in mice lacking this enhancer, indicating that Emu regulates DH antisense transcription. Emu was recently demonstrated to regulate DH-to-JH recombination of the Igh locus. Together, these data suggest that Emu controls DH-to-JH recombination by activating this form of germ line Igh transcription, thus providing a long-range, processive mechanism by which Emu can regulate chromatin accessibility throughout the DH region. In contrast, Emu deletion has no effect on VH antisense intergenic transcription, which is rarely associated with DH antisense transcription, suggesting differential regulation and separate roles for these processes at sequential stages of V(D)J recombination. These results support a directive role for antisense intergenic transcription in enabling access to the recombination machinery.

Transcriptional regulation in early B cell development

Transcription factors and signalling molecules are important for both lineage commitment and lineage-specific regulation. The B cell specification factor Pax5 plays a dual role in B lineage commitment. Simultaneously, it potentiates and limits lineage choice by activating genes that are required for the B cell program while repressing lineage-inappropriate genes; more than 100 of the latter have now been identified. In this context, repression of the tyrosine kinase Flt3 has been shown to be essential for B lineage commitment. Regulation of antigen receptor recombination constitutes another level at which lineage specificity is determined, and the identification of two factors, E47 and FOXP1, which regulate the activity of the recombinase enzymes in B lineage cells, provides insight into the mechanisms that determine this. New information regarding the control of ordered recombination and allelic exclusion comes from studies of cis-acting elements within the Ig loci.

Chromatin accessibility and epigenetic modifications differ between frequently and infrequently rearranging VH genes

The molecular mechanisms that control the temporal and lineage-specific accessibility, as well as the rearrangement frequency of V(H) genes for V(H)-to-DJ(H) recombination, are not fully understood. We previously found a positive correlation between the extent of histone acetylation and the differential rearrangement frequency of individual V(H) genes. Here, we demonstrated that poorly rearranging V(H) genes are more highly associated with histone H3 dimethylated at lysine 9, a marker of repressive chromatin, than frequently rearranging V(H) genes. We also observed a positive relationship between the differential binding of Pax5 to individual V(H)S107 genes and rearrangement frequency. Furthermore, we showed that accessibility of the regions flanking the Pax5 binding site and the recombination signal sequence (RSS) to restriction enzyme cleavage correspond with the differential rearrangement frequency of the V(H)S107 family members. In addition, we found that the CpG sites located in the coding regions of V(H) genes are methylated in general, while the extent of DNA methylation drops dramatically near the RSS. For the V(H)S107 family, one CpG site located 101bp upstream of the RSS showed variable methylation that correlates with rearrangement frequency, and the methylation status of a CpG site located 34bp downstream of the RSS could also favor the rearrangement of V1 over V11. These findings suggest that the extent of histone modifications, chromatin accessibility, DNA methylation, as well as the differential binding of Pax5 to V(H) coding regions, could all influence the rearrangement frequency of individual V(H) genes, although some of these mechanisms are not strictly B cell specific.

Immunoglobulin kappa enhancers are differentially regulated at the level of chromatin structure

The kappa intronic and the kappa 3' enhancers synergize to regulate recombination and transcription of the Ig kappa locus. Although these enhancers have overlapping functions, the kappa i enhancer appears to predominate during receptor editing, while the kappa 3' enhancer may be more important for initiating Ig kappa germline transcription to target locus recombination and, later in development, somatic hypermutation. Changes in chromatin structure appear to regulate both enhancers, and previous reports suggest that both enhancers are packaged into an accessible chromatin structure only in B lineage cells. Why these enhancers cannot activate the demethylated, accessible, protein-associated Ig kappa allele in pro-B cells is not known. Furthermore, how the enhancers function to reactivate the locus for receptor editing or to quantitatively promote hypermutation in B cells is vague. Quantitative analysis of Ig enhancer chromatin structure in murine pro-, pre-and splenic B cells demonstrated that the kappa i enhancer maintains a highly accessible chromatin structure under a variety of conditions. This stable chromatin structure mirrored the highly accessible structure characterizing the Ig mu intronic enhancer, despite the fact that Ig mu is activated prior to Ig kappa during B cell development. Surprisingly, parallel analysis of the kappa 3' enhancer demonstrated its accessible chromatin structure is markedly unstable, as characterized by sensitivity to changes in environmental conditions. These data unexpectedly suggest that kappa locus regulation is compartmentalized along the gene in B lineage cells. Furthermore, these findings raise the possibility that environmentally dependent regulation of kappa 3' enhancer structure underlies changes in kappa activation during B cell development.

Epigenetic histone modifications do not control Igkappa locus contraction and intranuclear localization in cells with dual B cell-macrophage potential

Somatic rearrangement of the Ig genes during B cell development is believed to be controlled, at least in part, by accessibility of the loci to the recombinational machinery. Accessibility is poorly understood, but appears to be controlled by a combination of histone posttranslational modifications, large scale Ig locus contractions, and changes in intranuclear localization of the loci. These changes are regulated by developmental stage-specific as well as tissue-specific mechanisms. We previously isolated a murine B cell lymphoma line, Myc5, that can oscillate between the B cell and macrophage lineages depending upon growth conditions. This line provides an opportunity to study tissue-specific regulation of epigenetic mechanisms operating on the Ig loci. We found that when Myc5 cells are induced to differentiate from B cells into macrophages, expression of macrophage-specific transcripts was induced (M-CSFR, F4/80, and CD14), whereas B cell-specific transcripts decreased dramatically (mb-1, E47, IRF4, Pax5, and Igkappa). Loss of Igkappa transcription was associated with reduced Igkappa locus contraction, as well as increased association with heterochromatin protein-1 and association of the Igkappa locus with the nuclear periphery. Surprisingly, however, we found that histone modifications at the Igkappa locus remained largely unchanged whether the cells were grown in vivo as B cells, or in vitro as macrophages. These results mechanistically uncouple histone modifications at the Igkappa locus from changes in locus contraction and intranuclear localization.

The stem cell continuum

Hematopoietic stem cells have been felt to exist in a hierarchical structure with a relatively fixed phenotype at each stage of differentiation. Recent studies on the phenotype of the marrow hematopoietic stem cell indicate that it is not a fixed entity, but rather that it fluctuates and shows marked heterogeneity. Past studies have shown that stem cell engraftment characteristics, adhesion protein, and gene expression varies with the phase of the cell cycle. More recently, we demonstrated that progenitor numbers and differentiation potential also vary reversibly during one cytokine-induced cell cycle transit. We have also shown high levels of conversion of marrow cells to skeletal muscle and lung cells, indicating a different level of plasticity. Recently, we demonstrated that homing to lung and conversion to lung cells in a mouse transplant model also fluctuates reversibly with cell cycle transit. This could be considered plasticity squared. These data indicate that marrow stem cells are regulated on a continuum related to the cell cycle both as to hematopoietic and to nonhematopoietic differentiation.

Variability and Exclusion in Host and Parasite: Epigenetic Regulation of Ig and var Expression

The immune system generates highly diverse AgRs of different specificities from a pool of designated genomic loci, each containing large arrays of genes. Ultimately, each B or T cell expresses a receptor of a single type on its surface. Immune evasion by the malaria parasite Plasmodium falciparum is mediated by the mutually exclusive expression of a single member of the var family of genes, which encodes variant surface Ags. In this review, we discuss the similarities as well as the unique characteristics of the epigenetic mechanisms involved in the establishment of mutually exclusive expression in the immune and parasite systems.

Identification of a candidate regulatory element within the 5' flanking region of the mouse Igh locus defined by pro-B cell-specific hypersensitivity associated with binding of PU.1, Pax5, and E2A

The Igh locus is controlled by cis-acting elements, including Emu and the 3' IgH regulatory region which flank the C region genes within the well-studied 3' part of the locus. Although the presence of additional control elements has been postulated to regulate rearrangements of the VH gene array that extends to the 5' end of the locus, the 5' border of Igh and its flanking region have not been characterized. To facilitate the analysis of this unexplored region and to identify potential novel control elements, we physically mapped the most D-distal VH segments and scanned 46 kb of the immediate 5' flanking region for DNase I hypersensitive sites. Our studies revealed a cluster of hypersensitive sites 30 kb upstream of the most 5' VH gene. Detection of one site, HS1, is restricted to pro-B cell lines and HS1 is accessible to restriction enzyme digestion exclusively in normal pro-B cells, the stage defined by actively rearranging Igh-V loci. Sequence motifs within HS1 for PU.1, Pax5, and E2A bind these proteins in vitro and these factors are recruited to HS1 sequence only in pro-B cells. Transient transfection assays indicate that the Pax5 binding site is required for the repression of transcriptional activity of HS1-containing constructs. Thus, our characterization of the region 5' of the VH gene cluster demonstrated the presence of a single cluster of DNase I hypersensitive sites within the 5' flanking region, and identified a candidate Igh regulatory region defined by pro-B cell-specific hypersensitivity and interaction with factors implicated in regulating VDJ recombination.

Critical roles of the immunoglobulin intronic enhancers in maintaining the sequential rearrangement of IgH and Igk loci

V(D)J recombination of immunoglobulin (Ig) heavy (IgH) and light chain genes occurs sequentially in the pro– and pre–B cells. To identify cis-elements that dictate this order of rearrangement, we replaced the endogenous matrix attachment region/Igk intronic enhancer (MiE_κ) with its heavy chain counterpart (Eμ) in mice. This replacement, denoted EμR, substantially increases the accessibility of both V_κ and J_κ loci to V(D)J recombinase in pro–B cells and induces Igk rearrangement in these cells. However, EμR does not support Igk rearrangement in pre–B cells. Similar to that in MiE_κ^−/− pre–B cells, the accessibility of V_κ segments to V(D)J recombinase is considerably reduced in EμR pre–B cells when compared with wild-type pre–B cells. Therefore, Eμ and MiE_κ play developmental stage-specific roles in maintaining the sequential rearrangement of IgH and Igk loci by promoting the accessibility of V, D, and J loci to the V(D)J recombinase.

Activation of V(D)J recombination at the IgH chain JH locus occurs within a 6-kilobase chromatin domain and is associated with nucleosomal remodeling

IgH genes are assembled during early B cell development by a series of regulated DNA recombination reactions in which DH and JH segments are first joined followed by V(H) to DJH rearrangement. Recent studies have highlighted the role of chromatin structure in the control of V(D)J recombination. In this study, we show that, in murine pro-B cell precursors, the JH segments are located within a 6-kb DNase I-sensitive chromatin domain containing acetylated histones H3 and H4, which is delimited 5' by the DQ52 promoter element and 3' by the intronic enhancer. Within this domain, the JH segments are covered by phased nucleosomes. High-resolution mapping of nucleosomes reveals that, in pro-B cells, unlike recombination refractory nonlymphoid cells, the recombination signal sequences flanking the four JH segments are located in regions of enhanced micrococcal nuclease and restriction enzyme accessibility, corresponding to either nucleosome-free regions or DNA rendered accessible within a nucleosome. These results support the idea that nucleosome remodeling provides an additional level of control in the regulation of Ig locus accessibility to recombination factors in B cell precursors.

Hypothesis: a biological role for germline transcription in the mechanism of V(D)J recombination--implications for initiation of allelic exclusion

The sequences that encode the antigen-binding sites of IgH and IgL chains - variable (V), diversity (D, H chain loci only) and joining (J) sequences - are configured as separate DNA segments at the germline level. Expression of an Ig molecule requires V(D)J assembly. Productive V(D)J recombination is monoallelic. How rearrangement is initiated differentially at maternal and paternal alleles is unclear. The products of recombination activating gene (RAG)1 and RAG2 mediate rearrangement by cleaving the DNA between an unrearranged gene segment and adjacent recombination signal sequences (RSS). It is proposed that supercoiling generated during germline transcription at Ig loci (which occurs concomitantly with rearrangement) is required at RSS for RAG1/2 recognition. Rearrangement might hence initiate sequentially at maternal and paternal alleles where deregulated germline transcription causes RAG1/2 recognition of RSS to become stochastic.

Turning T-cell receptor ? recombination on and off: more questions than answers

Successful V(D)J recombination at the T-cell receptor beta (Tcrb) locus is critical for early thymocyte development. The locus is subject to a host of regulatory mechanisms that impart a strict developmental order to Tcrb recombination events and that insure that Tcrb recombination occurs in an allelically excluded fashion. Progress has been made in the understanding of the cis-acting control of Tcrb locus chromatin structure and the extent to which such accessibility control can account for the developmental regulation of Tcrb recombination. However, recent studies in our laboratory and elsewhere have made it abundantly clear that accessibility control is only part of the story, and multiple additional mechanisms impact both the developmental activation and inactivation of locus recombination events. Here we evaluate our current understanding of developmental regulation at the Tcrb locus. We highlight the many unresolved issues and we discuss how recent concepts emerging from studies of other antigen receptor loci may (or may not) help to resolve these issues.

Progressive activation of DNA replication initiation in large domains of the immunoglobulin heavy chain locus during B cell development

In mammalian cells, the replication of tissue-specific gene loci is believed to be under developmental control. Here, we provide direct evidence of the existence of developmentally regulated origins of replication in both cell lines and primary cells. By using single-molecule analysis of replicated DNA (SMARD), we identified various groups of coregulated origins that are activated within the Igh locus. These origin clusters can span hundreds of kilobases and are activated sequentially during B cell development, concomitantly with developmentally regulated changes in chromatin structure and transcriptional activity. Finally, we show that the changes in DNA replication initiation that take place during B cell development, within the D-J-C-3'RR region, occur on both alleles (expressed and nonexpressed).

The extent of histone acetylation correlates with the differential rearrangement frequency of individual VH genes in pro-B cells

During B lymphocyte development, Ig heavy and L chain genes are assembled by V(D)J recombination. Individual V, D, and J genes rearrange at very different frequencies in vivo, and the natural variation in recombination signal sequence does not account for all of these differences. Because a permissive chromatin structure is necessary for the accessibility of VH genes for VH to DJH recombination, we hypothesized that gene rearrangement frequency might be influenced by the extent of histone modifications. Indeed, we found in freshly isolated pro-B cells from muMT mice a positive correlation between the level of enrichment of VHS107 genes in the acetylated histone fractions as assayed by chromatin immunoprecipitation, and their relative rearrangement frequency in vivo. In the VH7183 family, the very frequently rearranging VH81X gene showed the highest association with acetylated histones, especially in the newborn. Together, our data show that the extent of histone modifications in pro-B cells should be considered as a mechanism by which accessibility and the rearrangement level of individual VH genes is regulated.

The recombination difference between mouse kappa and lambda segments is mediated by a pair-wise regulation mechanism

In mice, kappa light chains dominate over lambda in the immunoglobulin repertoire by as much as 20-fold. Although a major contributor to this difference is the recombination signal sequences (RSS), the mechanism by which RSS cause differential representation has not been determined. To elucidate the mechanism, we tested kappa and lambda RSS flanked by their natural 5' and 3' flanks in three systems that monitor V(D)J recombination. Using extra-chromosomal recombination substrates, we established that a kappa RSS and its flanks support six- to nine-fold higher levels of recombination than a lambda counterpart. In vitro cleavage assays with these same sequences demonstrated that single cleavage at individual kappa or lambda RSS (plus flanks) occurs with comparable frequencies, but that a pair of kappa RSS (plus flanks) support significantly higher levels of double cleavage than a pair of lambda RSS (plus flanks). Using EMSA with double stranded oligonucleotides containing the same kappa or lambda RSS and their respective flanks, we examined RAG/DNA complex formation. We report that, surprisingly, RAG-1/2 form only modestly higher levels of complexes on individual 12 and 23 kappa RSS (plus natural flanks) as compared to their lambda counterparts. We conclude that the overuse of kappa compared to lambda segments cannot be accounted for by differences in RAG-1/2 binding nor by cleavage at individual RSS but rather could be accounted for by enhanced pair-wise cleavage of kappa RSS by RAG-1/2. Based on the data presented, we suggest that the biased usage of light chain segments is imposed at the level of synaptic RSS pairs.

Tails and cuts: the role of histone post-translational modifications in the formation of programmed double-strand breaks

In eukaryotic organisms, various DNA recombination mechanisms have been described that are an integral part of nuclear differentiation processes. In several places, the recombination is initiated by one or more double-strand breaks that result from the action of specific endonucleolytic activities. The importance of chromatin in controlling susceptibility of DNA to various DNA transactions has been recognized for long. Recent literature links post-transcriptional modifications of the amino-terminal part of histones (the tails) to the formation of developmentally regulated DNA double-strand break (the cuts). In this review, I compare the existing data in three different DNA rearrangement-based processes, i.e., genetic recombination associated to meiosis, lymphoid-specific V(D)J recombination and excision of DNA fragments in the nucleus of ciliates. Inspired by some of the concepts established in the field of transcription, models are proposed for molecular mechanisms that sustain the epigenetic control of programmed double-strand break formation.

Regulatory events in early and late B-cell differentiation

We are studying transcriptional control of critical developmental decision points in B lymphocytes. Commitment to the B-lymphocyte lineage is dependent on the transcriptional regulator Pax5 and committed B lymphocytes represent the first developmental stage when V(H)-to-DJ recombination occurs in the immunoglobulin (Ig) heavy chain locus. We summarize our recent studies showing that methylation of histone H3 lysine 9, a heterochromatic chromatin modification, is present in the Ig V(H) region in hematopoietic progenitors and in non-B lineage hematopoietic cells. Pax5 is both necessary and sufficient to remove this heterochromatic mark in B cells. Using genetically altered mice, we have shown that terminal differentiation of B cells to memory and Ig-secreting plasma cells depends on the transcriptional repressor Blimp-1. Recent studies demonstrating a requirement for Blimp-1 in the formation of pre-plasma memory B cells, Ig-secreting plasma cells as well as preliminary data suggesting a requirement for Blimp-1 in the maintenance of long-lived plasma cells are summarized. We also summarize our recent studies on the regulation of Blimp-1, showing direct repression by Bcl-6 and providing evidence for activation by NF-kappaB following toll-like receptor signaling.

The Ig kappa 3' enhancer is activated by gradients of chromatin accessibility and protein association

The Igkappa locus is recombined following initiation of a signaling cascade during the early pre-B stage of B cell development. The Ig kappa3' enhancer plays an important role in normal B cell development by regulating kappa locus activation. Quantitative analyses of kappa3' enhancer chromatin structure by restriction endonuclease accessibility and protein association by chromatin immunoprecipitation in a developmental series of primary murine B cells and murine B cell lines demonstrate that the enhancer is activated progressively through multiple steps as cells mature. Moderate kappa3' chromatin accessibility and low levels of protein association in pro-B cells are increased substantially as the cells progress from pro- to pre-B, then eventually mature B cell stages. Chromatin immunoprecipitation assays suggest transcriptional regulators of the kappa3' enhancer, specifically PU.1 and IFN regulatory factor-4, exploit enhanced accessibility by increasing association as cells mature. Characterization of histone acetylation patterns at the kappa3' enhancer and experimental inhibition of histone deacetylation suggest changes therein may determine changes in enzyme and transcription factor accessibility. This analysis demonstrates kappa activation is a multistep process initiated in early B cell precursors before Igmu recombination and finalized only after the pre-B cell stage.

Immunoglobulin locus silencing and allelic exclusion

Lymphocytes are characterised by monoclonal expression of antigen receptors. This is achieved by silencing of one of two homologous antigen receptor alleles, a process known as allelic exclusion. This process is regulated both before and after V(D)J recombination, by a variety of mechanisms. These include nuclear localisation, changes in chromatin structure and histone modifications, non-coding sense and antisense RNA transcription, epigenetic alterations at the DNA level, feedback signalling from expressed alleles, locus contraction and decontraction, recruitment to heterochromatin. This review will focus on recent advances in the immunoglobulin heavy and kappa light chain loci. The current picture is of a complex, temporally ordered sequence of events, in which these loci share many contributory mechanisms, but clear and intriguing differences are emerging.

Chromatin architecture near a potential 3' end of the igh locus involves modular regulation of histone modifications during B-Cell development and in vivo occupancy at CTCF sites

The murine Igh locus has a 3' regulatory region (3' RR) containing four enhancers (hs3A, hs1,2, hs3B, and hs4) at DNase I-hypersensitive sites. The 3' RR exerts long-range effects on class switch recombination (CSR) to several isotypes through its control of germ line transcription. By measuring levels of acetylated histones H3 and H4 and of dimethylated H3 (K4) with chromatin immunoprecipitation assays, we found that early in B-cell development, chromatin encompassing the enhancers of the 3' RR began to attain stepwise modifications typical of an open conformation. The hs4 enhancer was associated with active chromatin initially in pro- and pre-B cells and then together with hs3A, hs1,2, and hs3B in B and plasma cells. Histone modifications were similar in resting splenic B cells and in splenic B cells induced by lipopolysaccharide to undergo CSR. From the pro-B-cell stage onward, the approximately 11-kb region immediately downstream of hs4 displayed H3 and H4 modifications indicative of open chromatin. This region contained newly identified DNase I-hypersensitive sites and several CTCF target sites, some of which were occupied in vivo in a developmentally regulated manner. The open chromatin environment of the extended 3' RR in mature B cells was flanked by regions associated with dimethylated K9 of histone H3. Together, these data suggest that 3' RR elements are located within a specific chromatin subdomain that contains CTCF binding sites and developmentally regulated modules.

Monoallelic gene expression: a repertoire of recurrent themes

The development of mature B and T cells in the lymphoid system involves a series of molecular decisions that culminate in the expression of a single antigen receptor on the cell surface, a phenomenon termed allelic exclusion. While feedback inhibition of the recombinase-activation gene proteins evidently plays an important role in the maintenance of allelic exclusion, the initial restriction of rearrangement to only one allele in each cell seems to be achieved through monoallelic epigenetic changes. Epigenetic mechanisms involved in the establishment of allelic exclusion also play a central role in other types of monoallelic expression, including X-chromosome inactivation in female cells, and parental imprinting. In all three systems, the inequality of the two alleles seems to be achieved mainly by differential DNA methylation, asynchronous DNA replication, differential chromatin modifications, unequal nuclear localization, and non-coding RNA. In this review, we discuss the unifying features among these monoallelically expressed systems and the unique characteristics displayed by each of them.

How to keep V(D)J recombination under control

Breaking apart chromosomes is not a matter to be taken lightly. The possible negative outcomes are obvious: loss of information, unstable chromosomes, chromosomal translocations, tumorigenesis, or cell death. Utilizing DNA rearrangement to generate the desired diversity in the antigen receptor loci is a risky business, and it must be carefully controlled. In general, the regulation is so precise that the negative consequences are minimal or not apparent. They are visible only when the process of V(D)J recombination goes awry, as for example in some chromosomal translocations associated with lymphoid tumors. Regulation is imposed not only to prevent the generation of random breaks in the DNA, but also to direct rearrangement to the appropriate locus or subregion of a locus in the appropriate cell at the appropriate time. Antigen receptor rearrangement is regulated essentially at four different levels: expression of the RAG1/2 recombinase, intrinsic biochemical properties of the recombinase and the cleavage reaction, the post-cleavage /DNA repair stage of the process, and accessibility of the substrate to the recombinase. Within each of these broad categories, multiple mechanisms are used to achieve the desired aims. The major focus of this review is on accessibility control and the role of chromatin and nuclear architecture in achieving this regulation, although other issues are touched upon.

Regulation of activation and recombination of the murine Igkappa locus

The murine immunoglobulin (Ig) kappa locus has been intensively studied in an attempt to understand its developmentally regulated activation for both transcription and V(D)J recombination. A variety of signaling proteins, cis-acting DNA elements, and trans-acting DNA-binding proteins have been discovered and shown to be involved in the regulated changes in chromatin structure, which are associated with recombinase accessibility. In addition, key roles have been suggested for DNA methylation and replication in kappa-locus expression and rearrangement. This review summarizes data in this area and considers what studies of the murine kappa locus have revealed about the lineage specificity, order, and allelic exclusion of lymphoid V(D)J recombination.

Regulation of immunoglobulin heavy-chain gene rearrangements

Regulated assembly of antigen receptor gene segments to produce functional genes is a hallmark of B- and T-lymphocyte development. The immunoglobulin heavy-chain (IgH) and T-cell receptor beta-chain genes rearrange first in B and T lineages, respectively. Both loci require two recombination events to assemble functional genes; D-to-J recombination occurs first followed by V-to-DJ recombination. Despite similarities in overall rearrangement patterns, each locus has unique regulatory features. Here, we review the characteristics of IgH gene rearrangements such as developmental timing, deletion versus inversion, DH gene segment utilization, ordered recombination of VH gene segments, and feedback inhibition of rearrangement in pre-B cells. We summarize chromatin structural features of the locus before and during recombination and, wherever possible, incorporate these into working hypotheses for understanding regulation of IgH gene recombination. The picture emerges that the IgH locus is activated in discrete, independently regulated domains. A domain encompassing DH and JH gene segments is activated first, within which recombination is initiated. VH genes are activated subsequently and, in part, by interleukin-7. These observations lead to a model for feedback inhibition of IgH rearrangements.