SUMMARY
During the humoral immune response B-cells undergo a dramatic change in phenotype to enable antibody affinity maturation in germinal centers (GCs). Using genome-wide chromosomal conformation capture (Hi-C), we found that GCB-cells undergo massive reorganization of the genomic architecture that encodes the GCB-cell transcriptome. Coordinate expression of genes that specify the GCB-cell phenotype – most prominently, BCL6 – was achieved through a multilayered chromatin reorganization process involving i) increased promoter connectivity, ii) formation of enhancer networks, iii) 5’ to 3’ gene looping, and iv) merging of gene neighborhoods that share active epigenetic marks. BCL6, was an anchor point for the formation of GC-specific gene and enhancer loops on chromosome 3. Deletion of a GC specific, highly interactive locus control region, upstream of Bcl6 abrogated GC formation in mice. Thus, large-scale and multi-tiered genomic three-dimensional reorganization is required for coordinate expression of phenotype-driving gene sets that determine the unique characteristics of GCB-cells.
Graphical Abstract
INTRODUCTION
Production of high affinity, antibody-secreting B-cells is essential for the establishment of humoral immunity (reviewed in (Victora and Nussenzweig, 2012)). During the immune response, T-cell-dependent antigen activation induces naïve B-cells to form germinal centers (GCs) within lymphoid follicles wherein they undergo rapid proliferation. At the same time, these cells endure somatic hypermutation, during which their immunoglobulin genes are progressively mutated. The end result of this process is the emergence of B-cell clones that express new, high-affinity antibodies against specific antigens. The dramatic transition in phenotype of naive B-cells to GCB-cells requires rapid and coordinate epigenetic regulation and expression of multiple genes regulating the cell cycle, DNA damage checkpoints, metabolic pathways, and is crucially dependent on the GC master transcriptional regulator, BCL6 (Hatzi and Menick, 2014). Precisely how the GCB-cell transcriptional program is coordinated efficiently at the genome-wide level is unknown.
The establishment of distinct cellular phenotypes during development and differentiation in multicellular organisms requires coordinated and large-scale changes in transcriptional programming (Cantone and Fisher, 2013; Natoli, 2010; Spitz and Furlong, 2012). Alterations in histone modifications are one example of mechanisms that regulate the transcriptional state of individual genes (Zhou et al., 2011). However, the genomes of higher organisms are large and highly complex, and in a single cell, the chromatin status and transcription of many thousands of genes must be altered simultaneously in a highly efficient and coordinated manner to enable phenotypic change. One way that the genome overcomes this complexity is by large-scale folding and looping. Recent studies using chromosome conformation capture (3C) techniques and three-dimensional (3D) DNA-fluorescence in situ hybridization (FISH) provide evidence that the genomes of higher organisms are physically organized and compartmentalized, and that the 3D folding of specific loci in terminally differentiated cells can help to control gene expression (Bickmore and van Steensel, 2013; Cavalli and Misteli, 2013; Fabre et al., 2015). Genome-wide 3C approaches have further shown that genome compartmentalization and folding are crucial to the way that genes are reprogrammed in Drosophila, and mammalian cells (Sexton et al., 2012, Dixon et al., 2012; Lieberman-Aiden et al., 2009; Sanyal et al., 2012; Dixon et al., 2015; Baù et al., 2011). Here we examined whether physical reorganization of the B-cell genome is linked to and required to enable the dramatic and coordinated changes in expression and epigenetic regulation of genes that drive the phenotypic transition of resting B-cells into GCB-cells.
RESULTS
Extensive reorganization of the genome of GCB-cells is linked to cell morphology and specific chromosomal territories
The GC reaction involves a profound phenotypic shift from resting, antigen-naïve B-cells to highly proliferative GCB-cells (Figure 1A) a process that requires large-scale transcriptional and epigenetic changes. To examine the three-dimensional organization of the B-cell genome during the GC reaction we performed genome-wide chromosomal conformation capture (Hi-C) in purified primary human tonsillar naïve B-cells (IgD+CD38lo; naive B) and GCB-cells (CD77+CD38hi; GCB) (Figure S1A and B, Table S1). Naïve B and GCB-cell Hi-C biological replicates showed high reproducibility (Spearman correlation 0.97 and 0.88 respectively; Figure S1C). Examination of intra-chromosome DNA:DNA interaction maps by principal component analysis (PCA) revealed a significant loss of interactions between the short (p) and long (q) arms of the longest chromosomes in GCB-cells (e.g. Figure 1B; p<10−300; Fisher’s exact test). This large scale remodeling of chromosomal arm contacts revealed the architectural basis of chromosomal de-compaction in GCB-cells, reflecting the increased size and chromatic laxity of GCB-cell nuclei, compared to the smaller and denser morphology of naïve B-cells (Figure S1D). Closer examination uncovered 135,156 chromatin interactions connecting 1 megabase (Mb) blocks of DNA that were significantly different between naïve B and GCB-cells, of which 84,684 interactions were gained in GCB-cells (FDR=0.05; BH corrected Fisher’s exact test; Figure S1E). For example, a region from chromosome 3, 3q27, which encodes the GC master regulator gene, BCL6, showed substantially higher numbers of chromatin interactions in GCB-cells compared to naïve B-cells (Figure 1C; p<0.005; binomial exact test).
Induction of promoter interactivity is coordinated with activated chromatin and transcription in GCB-cells
We next performed an unbiased, gene-centered analysis of chromatin interactions in naïve B and GCB-cells. We discovered that DNA:DNA interactions involving gene promoters were highly enriched in GCB-cells, compared with naïve B-cells (p<10−16; Fisher’s exact test; Figure 1D) as was the fraction of Hi-C interactions corresponding to promoter–promoter interactions (p<10−15; χ2 test; Figure 1E. Interactive promoters were associated with increased transcription, as determined by RNA-seq in the same specimens (p<10−34; Wilcoxon test; Figure 1F). Promoter interactions were highly correlated with active chromatin marks, as determined by ChIP-seq for H3K4me3, H3K4me2, H3K27Ac in primary human naïve B and GCB-cells (p<10−47, <10−59, <10−39, respectively; Figure S1F). The most highly interactive promoters in GCB-cells were specifically enriched for genes linked to the GCB-cell transcriptional program. These included transcriptional regulators BCL6, MTA3, LMO2 and BCL7A, and components of the B-cell receptor signaling pathway, TEC, PIK3CG and CAMK2B (Figure S1G and H). Enrichment of GCB-cell phenotype-driving gene sets among highly interactive promoters in GCB-cells was confirmed using gene set enrichment analysis (GSEA, FDR=0.10; Figure S1I).
To further explore how gene promoter interactions and epigenetic marks might be linked to the GCB transcriptional program, we performed an unbiased, multidimensional principal component analysis (PCA). This approach identified a set of highly interactive gene promoters in GCB-cells (principal component 1) with increased H3K4me3 and H3K27Ac activating marks in GCB-cells and reduced H3K27me3 (Figure 1G). These promoters showed diametrically opposite features in naïve B-cells: low numbers of interactions, depletion of active and enrichment of repressive chromatin (Figure 1G). Only this specific combination of promoter interactions and epigenetic marks was associated with significant gene upregulation in GCB vs. naïve B-cells (p<10−7; Figure 1H and data not shown). These promoters were enriched in gene sets corresponding to the GCB-cells, GCB-type diffuse large B-cell lymphomas (DLBCLs), cellular proliferation and cell cycle genes (FDR=0.001), and were depleted in gene sets linked with resting B-cells and non-GCB DLBCLs (FDR=0.01; Figure 1I). Hence, differential expression of GC phenotype-driving genes requires an increase in both promoter interactions and active epigenetic marks.
Integrating Hi-C and ChIP-seq we observed that the most highly interactive promoters in GCB-cells but not naïve B-cells (Figure 1J and S1J) were strongly linked to binding by the EP300 histone acetyl-transferase (p<10−8), as well as transcription factors, PU.1 and SPIB (p<10−33 and <10−14, respectively; Mann-Whitney’s test). These factors play important regulatory roles in GCs (Klein and Dalla-Favera, 2008) and interact with EP300 (Bai et al., 2005; Yamamoto et al., 2002). IRF8, which plays an important role in GC formation (Lee et al., 2006), was associated with promoters engaged in interactions in both GCB and naïve B-cells (p<10−32 and <10−105 respectively; Figure 1J and S1J). CTCF and RAD21 (cohesin), which are linked to formation of cis-interacting chromatin (Merkenschlager and Odom, 2013), were significantly associated with highly interactive promoters in GCB-cells (p<10−17 and <10−3, respectively; Figure 1J)
Spatial reorganization and coordination of a GCB-cell specific enhancer network
Cell-type specific gene expression patterns are governed in large part through tissue specific gene enhancer elements, which contact and positively regulate distally located gene promoters (Chepelev et al., 2012; Sanyal et al., 2012; Shen et al., 2012). Using ChIP-seq, each cell type was observed to have 20,173 and 21,807 H3K4me2posH3K4me3neg enhancer elements, respectively. Naïve B-cells contained 5,167 enhancers <50 Kb away from genes; of which 2,818 were unique to naïve B-cells and linked to genes involved in immune homeostasis and lymph nodes (p<10−2; Figure 2A and B). GCB-cells contained 5,339 enhancers <50 Kb from genes, among which 2,990 were unique to GCB-cells and enriched for GCB-cell differentiation, proliferation and GCB-type DLBCL genes, including BCL6, CKS2, MCM2 and 5, RFC3, SPRED2, PRC1 and TIAM2 (p<10−2; Figure 2A and B). Genes associated with active enhancers (H3K4me2posH3K27Acpos) in GCB-cells manifested higher expression than genes associated with poised enhancers (p<10−90; Mann-Whitney test; Figure 2C). Enhancers were significantly more interactive in GCB compared to naïve B-cells (p<10−300; Figure S2A), with active GCB-cell enhancers being significantly more interactive than poised GCB-cell enhancers (p=2.1×10−32, Mann Whitney’s test; Figure 2D). Likewise, enhancers bound by PU1, SPIB, and EP300 (which mediates H3K27 acetylation) were more highly interactive with other loci in GCB-cells (p<10−3, <10−4, and <10−7; respectively, Mann Whitney’s test; Figure 2E). CTCF and RAD21 were also enriched at highly interactive enhancers in GCB-cells (p<10−2 and <10−3, respectively; Figure 2E). The fraction of Hi-C interactions corresponding to enhancer–promoter and enhancer–enhancer interactions was highly increased in GCB-cells versus naïve B-cells (p<10−15; χ2 test; Figure 2F). In contrast interactions between non-regulatory loci were not enriched in GCB-cells, suggesting that interaction of DNA that encodes regulatory information is most relevant to the re-programming of these cells.
We next identified genes with substantial increase in interactions between their promoter and distal enhancer in GCB-cells (FDR=0.05; Fisher’s exact test with BH correction; Figure S2B) and differential expression. We identified 32 such genes; the majority of which (90%) were up-regulated in GCB-cells (p<10−3; Fisher’s exact test; Figure 2G) and corresponded to important GCB-cell regulators such as BCL6, CKS2, DGKG, ETV5, PVT1, SERPINA9, and SPP1. We validated GC-specific enhancer–promoter looping using the 3C assay at the BCL6 and CKS2 loci (Figure 2H and Figure S2C), which have enhancers located ~100–380 Kb away from their transcription start sites. Using their proximal promoter regions as anchors, we confirmed that interactions were significantly higher at distal enhancer regions (H3K4me2posH3K4me3neg), compared with nearby (<76 Kb) inter- and intragenic regions either lacking or with low-density enhancer marks (Figure 2H and Figure S2C). Establishment of the GC-specific transcriptional program is therefore linked to enhancer reorganization and connectivity, including direct looping to proximal promoters of critical GC genes such as BCL6.
GC genes feature gene looping linking promoters and downstream regions
Examination of interactions at gene regions showed enrichment not only at promoters, but also around the 3’ end of gene bodies in GCB-cells (Figure 1C), suggesting the potential for 5’ to 3’ gene loop formation. Accordingly we identified 70 individual genes with significantly increased 5’ to 3’ looping in GCB versus naïve B-cells (FDR=0.05; Fisher’s exact test with BH correction; Figure S3A). Notably, genes that showed looping had increased expression (≥1.5-fold) in GCB-cells (p<0.001; Fisher’s exact test; Figure 3A) and were linked to GCB-cell proliferation, cell cycle, stress responses and/or DLBCL survival (FGFR1, ECT2, RICH2, SGPP2, TIAM2, EPHA4, BCL6; Figure 3A and Figure S3A). We confirmed these observations using 3C with an anchor upstream of the BCL6 promoter (Upstream; Figure 3B), demonstrating increased interactions with three regions immediately downstream of the BCL6 transcript end in GCB-cells. In contrast, there were no differences in 3C enrichment at control regions within the BCL6 gene body (Figure 3B). Genes with increased 5’ to 3’ looping also exhibited significantly greater binding of CTCF and RAD21 to their up- and downstream regions, compared to genes without such interactions (p<0.05 and <0.01 for CTCF and RAD21, respectively; Fisher’s exact test; Figure 3C). CTCF binding, with or without RAD21, was evident by ChIP-seq at looped genes (Figure 3D). There was also enrichment of H3K4me3, H3K4me2 and H3K27Ac (p<0.05 for all marks; Fisher’s exact test) but not H3K27me3 (p=0.27) at the downstream regions of looped genes (Figure S3B), suggesting that activated chromatin is a marker for genes that engage in 5’ to 3’ looping. 5’ to 3’ gene looping, potentially mediated by CTCF and/or RAD21, represents a novel layer of mammalian gene reorganization that may facilitate transcription of GCB-cell-specific genes. We speculate that this could occur through efficient recycling of RNA polymerase II (Shandilya and Roberts, 2012), since, using ChIP, we detected RNA polymerase II binding to the 5’ and 3’ ends of looped genes, including BCL6 (Figure S3C).
Remodeling of gene neighborhoods enables coordinated expression of GC-specific gene sets
Groups of genes are separated into boundary-delimited “neighborhoods” that are highly conserved between cell types and mammalian species (Dixon et al., 2012; Vietri Rudan et al., 2015). Using the Hi-C data and a Hidden Markov Model to infer the domain structure of chromosomes down to 100 Kb resolution (Dixon et al, 2012), we identified many cohorts of genes organized into discrete “3D gene neighborhoods” (n=1,525 and 1,587 in naïve B and GCB-cells respectively; 1.35 Mb average size), the majority of which (76.4%) were conserved between naïve B and GCB-cells and enriched for CTCF and cohesin binding at their boundaries (p<10−9; Mann Whitney’s test; Figure S4A). By definition, genes within these 3D neighborhoods displayed abundant interactions with each other. Expression of genes residing within 3D gene neighborhoods was more coordinated (i.e. similarly expressed) in both naïve B and GCB-cells, compared to randomly positioned sets of genes (p=0.001 and <10−9, respectively; Fisher’s exact test; Figure 4A and Figure S4B). Gene promoters within 3D neighborhoods showed greater epigenetic coordination in their enrichment of active (H3K4me3, H3K4me2, H3K27Ac) or repressive (H3K27me3) chromatin marks (p<10−5; Fisher’s exact test; Figure 4A and Figure S4B). 3D gene neighborhoods in B-cells thus correspond to spatially determined regulatory units where genes tend to share regulatory and epigenetic information (Figure S4C).
We observed many instances (n=171) where adjacent 3D gene neighborhoods in naïve B-cells merged together to form larger, de novo 3D gene “cities” in GCB-cells. This is exemplified by a 6 Mb region on chromosome 3, comprised of four individual 3D gene neighborhoods that were physically partitioned in naïve B-cells, but merge together in GCB-cells (Figure 4B). The genes newly connected to one another across former neighborhood boundaries included genes specifically up-regulated in GCB-cells, share common chromatin marks and play important roles in GCB-cell specification, such as BCL6, LPP, DGKG, TP63 and ETV5 (Figure 4B). At the chromosome-wide level, the formation of 3D gene cities in GCB-cells was accompanied by the de novo acquisition of coordinated gene expression between groups of genes that were formerly isolated from each other in naïve B-cells (p=0.009; Spearman correlation). This was also true of epigenetic marks, such as H3K4me3 (p<10−6; Mann-Whitney’s test; Figure 4C). Furthermore, genes within these newly formed 3D gene cities were significantly enriched for GCB-cell phenotype-driving processes, including proliferation, MHC class II-mediated antigen presentation and metabolic stress, and have hypomethylated DNA at their promoter regions in GCB versus naïve B-cells (Shaknovich et al., 2011) (p<10−2; >80% increase in interactions; Figure 4D). 3D gene neighborhood expansion in GCB-cells is thus a chromosome-wide phenomenon that enables regulatory coordination between genes that were formerly isolated and disparately regulated in naïve B-cells, and was consistent with the observed increase in connectivity between promoters and enhancers in GCB-cells. At the macro scale, this was reflected by a genome-wide expansion of chromosomal territories (Hi-C compartments) associated with active chromatin in GCB-cells (e.g. Chr3, including the BCL6 gene; Figure S4D; p<10−10; Mann-Whitney’s test). Indeed, 7.4% of all RefSeq genes shifted from a repressive chromatin compartment in naïve B-cells to an active compartment in GCB-cells (compared with 2.3% of genes that shifted to a repressive compartment in GCB-cells). Notably, these genes play key roles in cell proliferation, cell cycle regulation and chromosome organization, including, PCNA, MCM4, E2F7, CENPN, and CTCFL, and have up-regulated expression in GCB-cells. Hence, remodeling of gene neighborhoods may enable more efficient coordination between sets of genes that play key roles in mediating the GCB-phenotype.
BCL6, the GC master regulator, is the centerpiece of a GCB-specific promoter-enhancer network
The BCL6 gene was subject to multiple layers of physical reorganization, suggesting that it might play a key role in organizing the topology of the GCB-cell genome. To explore the BCL6 gene interactome in more detail, we employed a targeted 4C-seq approach in naïve B and GCB-cells. First, using 4C bait primers specific for the BCL6 gene promoter region we uncovered ~3,000 intra-chromosomal interactions that were significantly gained in GCB compared with naïve B-cells (p<0.05, Fisher’s exact test with Bonferroni correction; Table S2), the majority of which localized to the GCB-specific 3D gene city identified in Figure 4B (Figure 5A). Enriched BCL6 promoter contacts included interactions with two distal enhancer regions, and between the 5’ and 3’ ends of the BCL6 gene (Figure 5B and S5A). Using GSEA, we discovered significant association between genes that gained contacts with the BCL6 promoter in GCB-cells on chromosome 3 and their up-regulated expression in GCB-cells (FDR<0.015 for both replicates; Figure 5C). The BCL6 interactome on chromosome 3 was also significantly enriched with genes that specify the GCB-cell phenotype and survival of GCB-DLBCLs (p=0.0014), including GCET2, LPP, CADPS, MME, PRKCD, CD80 and MED12L (Figure S5B).
Our Hi-C, 3C and ChIP-seq data revealed a large (~114 Kb) GCB-specific, active enhancer region (H3K4me2posH3K27Acpos) distal to, and in contact with the BCL6 gene promoter as shown in Figure 2. We hypothesized that this region could be a locus control region (LCR) for other GC-specifying genes on chromosome 3. We performed 4C using an anchor within this putative BCL6 LCR, which identified between 2,000 and 3,000 intra-chromosomal interactions gained in GCB compared with naïve B-cells (p<0.05, Fisher’s exact test with Bonferroni correction; Figure 6A, Table S2). The BCL6 promoter was among the loci that gained interactions with the LCR. The BCL6 LCR was also physically connected to 400–600 other genes on chromosome 3 (Table S2). These genes were significantly up-regulated in GCB-cells (p=0.012; Fisher’s exact test), and were significantly enriched for GC signature genes (p<10−4). Notably, the BCL6 LCR was connected to 120 other GCB-cell-specific enhancers on chromosome 3 (Figure 6C). These looped enhancers were in close proximity (< 50 Kb) to genes that are enriched in GC and DLBCL survival pathways, including CADPS, LRCH3, LPP and MME (p<0.002; Figure 6B). A signature feature of these looped enhancers was active chromatin, marked by H3K27Ac (Figure 6C). Indeed, we saw a trend toward increased expression of genes proximal to enhancers looped to the BCL6 enhancer (p<0.09; Fisher’s exact test). Hence the BCL6 enhancer functions as an LCR controlling a large network of GC enhancers and genes.
The LCR upstream of BCL6 is required for formation of GCs
To determine whether activation of this BCL6 LCR is specific to GCB-cells we compared its H3K27Ac profiles with multiple tissues that express BCL6 including T-follicular helper cells using available human H3K27Ac ChIP-seq. This analysis showed that the LCR is exclusively highly H3K27 acetylated only in GCB-cells but not other tissues (Figure S6A). To evaluate whether this LCR might be evolutionarily conserved we mapped the syntenic region in mice and observed that it localized at chromosome 16, 130.4 Kb upstream from the transcriptional start site of the murine Bcl6 locus. Using H3K27Ac ChIP-seq we demonstrated massive enrichment of H3K27Ac in the syntenic LCR in murine GC derived B-cells, upstream of the Bcl6 locus (shaded green; Figure 7A). In contrast, other murine tissues lacked H3K27Ac enrichment at this region (Yue et al., 2014).
To investigate the functionality of the putative LCR, we used CRISPR-mediated DNA editing in murine oocytes to delete the syntenic 165 Kb region upstream of the Bcl6 gene in mice (Figure 7A) and generated independent founder lines that were bred into the C57BL/6 strain. We immunized LCR-deficient and wild-type (WT) littermate control mice with T-cell dependent antigen and examined lymphoid tissues ten days later to assess GC formation. Immunohistochemical (IHC) analysis of spleen sections using peanut agglutinin (a GCB marker), BCL6 and Ki-67 revealed a profound defect in the formation of GCs in LCR-deficient mice compared to WT mice (p=0.0013; two tailed, unpaired t-test, Figure 7B and C), whereas total B-cells were unchanged between the LCR-deficient and WT mice (Figure S6B). Flow cytometry confirmed the loss of B220+, FAS+, GL7+ (along with B220+, FAS+, CD38−) GCB-cells (p=0.0007; two tailed, unpaired t-test, Figure 7D and S6C). There was no significant difference in naïve B-cell numbers (Figure 7E). Additionally, marginal zone B-cell (B220+, CD21high), follicular zone B-cell (B220+, CD23high) and monocyte (B220−, CD3−, CD11b+, GR1+) numbers were normal (Figure 7F and S6D). These results were confirmed in an independent founder strain (data not shown).
Constitutive BCL6 deficiency causes a severe and lethal phenotype in addition to loss of GCs. Bcl6−/− pups either die in utero or are born runted and die shortly after due to a severe inflammatory syndrome due to BCL6 loss of function in T-cells and macrophages (Dent et al., 1997). In addition, BCL6 plays a role in cortical neuronal differentiation in mice (Tiberi et al., 2012). Compared to Bcl6−/− mice, LCR-deficient mice were born at Mendelian ratios, did not demonstrate any discernible health problems, nor any evidence of inflammation (Figure 7G, 7H and 7I). Notably, Bcl6 nuclear staining in the neurons of the subiculum (a BCL6 expressing region next to the hippocampus) was comparable in LCR-deficient and WT mice (Figure S6E). Altogether, these results support the notion that this GC-specific highly interactive region is required for GC formation and functions as a GC-specific LCR. These results provide evidence of a role for a non-coding region in the regulation of the GC program during B-cell affinity maturation.
DISCUSSION
Our integrative study comparing 3D chromosomal organization in human naïve B-cells and GCB-cells, reveals a number of mechanisms through which reorganization of chromosomal architecture may accommodate and coordinate changes in transcriptional programs. The loss of inter-arm chromosomal looping in GCB-cells reveals a topological basis for nuclear decompaction in GCB-cells. At higher resolution we observed a process whereby 3D gene neighborhoods merge to form interconnected “cities”. Merging of 3D gene neighborhoods in GCB-cells is accompanied by the sharing of information in the form of chromatin epigenetic marks, and de novo coordination of transcription between genes in interacting units. This represents a potentially economical manner through which cells can control, or mix and match, cohorts of genes to more efficiently coordinate changes in their transcriptional programs. For example, BCL6, which represses cell cycle checkpoint genes and is specifically up-regulated in GC GCB-cells, becomes coordinately expressed with genes that facilitate proliferation through the merging of 3D gene neighborhoods on chromosome 3. Similarly, 3D gene neighborhoods encompassing the Hoxd gene cluster undergo a conformational switch to control limb development in mouse embryos (Andery, et al., 2013).
An overarching mechanism described herein is the de novo increase of interactions and connectivity between promoters in activated B-cells, linked to binding of B-cell transcriptional activators (PU.1, SPIB and IRF8), activated chromatin (H3K4me3, H3K4me2 and H3K27Ac) and recruitment of the architectural remodelers CTCF and cohesin, whose long-range actions have been documented during immunoglobulin V(D)J recombination and MHC II gene selection in B-cells (Degner et al., 2011; Guo et al., 2011; Majumder and Boss, 2011). Importantly the differential expression of genes in GCB-cells was most strongly associated with both increased promoter interactivity and coordinated activating and repressing histone marks. Hence the GCB-cell transcriptional program is synchronized through de novo assembly of cell type-specific promoter networks, thereby facilitating an efficient exchange of regulatory information. This is consistent with models proposed in the literature (Sutherland and Bickmore, 2009), and recent genome-wide studies of interactions in cancer cell lines, ESCs, differentiating T helper cells and during pre to pro-B-cell transition (Apostolou et al., 2013; Lin et al., 2012; Hakim et al., 2013; Li et al., 2012). Activated genes in GCB-cells more extensively utilize distal enhancer regions marked by H3K27Ac and binding of EP300, PU.1 and SPIB, whereas genome-wide interactions less frequently engage poised enhancers. Active enhancers became connected to promoters in GCB-cells for cell type-specific gene expression. Finally, our high-resolution analysis has enabled the identification of a genome-wide role for 5’ to 3’ gene looping in the regulation of cell type-specific transcription. This may aid the re-loading of RNA polymerase II to the promoters of genes that are highly expressed, as postulated in studies of gene loops in yeast and in mammalian cell lines (Laine et al., 2009; Tan-Wong et al., 2008; Tan-Wong et al., 2009), and may require activated chromatin, as well as CTCF and RAD21 binding, to direct 5’ to 3’ gene folding.
The requirement for such mechanisms to efficiently coordinate transcription is consistent with the profound phenotypic change that B-cells undergo as they transition from the resting state to the GC reaction. The master regulator of GCB-cell differentiation, BCL6, which is subject to remodeling by each of these different architectural layers exemplifies this model and supports the functional importance of synchronous 3D conformational changes in the control of cell type specification. The most prominent feature of the BCL6-centric changes in chromatin organization was identification of a GCB-cell-specific LCR upstream of the BCL6 gene, which displayed all of the hallmark features of a cell-specifying regulatory element: (i) GCB-cell-specific enrichment for H3K27Ac, (ii) looping to connect the promoters and enhancers of GC-specifying genes, and (iii) is specifically required for the formation of functional GCs. Loss of this LCR likely results in failure to induce and coordinate expression of multiple GC related genes including BCL6.
Altogether, these different layers of architectural reorganization fit into a dynamic and cooperative model of cellular activation whereby genes that require fast and efficient transcription in GCB-cells, such as those required for BCR signaling, cell proliferation and repression of DNA repair checkpoints, undergo coordinated structural remodeling upon differentiation signals in the GC. Chromatin tethering at an enhancer region upstream of the BCL6 gene represents a mechanism by which GC-specific genes are looped together for coordinate expression on chromosome 3. Although this study was conducted in mature human B-cells, we propose that the architecture of the genome is also likely to be critical for specification of other cellular phenotypes, especially when major shifts in transcriptional programming are required, and that epigenetic and transcriptional reprogramming is in this way functionally linked to the structural organization of genes in the nucleus.
EXPERIMENTAL PROCEDURES
Chromatin immunoprecipitation (ChIP)
ChIP was performed in 1% formaldehyde-fixed naïve B and GCB-cells, or a mature B-cell line, OCI-Ly1, as previously described (Ci et al., 2009), using the following antibodies: H3K4me3 (Abcam, catalogue no. ab8580), H3K4me2 (Abcam, ab32356), H3K27Ac (Abcam, ab4729), H3K27me3 (Millipore, 17-622), PU.1 (Santa Cruz, sc-352), EP300 (Santa Cruz, sc-585x), CTCF (Millipore, 07-729), RAD21 (Abcam, ab992), RNA polymerase II (Santa Cruz, sc-899). Quantitative ChIP was performed using SYBER Green-based QPCR and the primer sequences in Table S3.
Chromosome conformation capture (3C), Hi-C and 4C
3C DNA templates were generated as previously described (van Berkum and Dekker, 2009) using HindIII digestion. 3C enrichment was determined using 50 ng of 3C DNA and SYBR Green-based QPCR and the 3C primer sequences in Table S4 and S5. Primer pairs were normalized to enrichment at adjacent HindIII fragments within the promoters of each gene. BAC plasmids encompassing the genomic regions of interest and used as controls for primer efficiency were as follows: RP11-632M13, CTD-2527P7, RP11-464D9 (BCL6 region); CTD-3120O5, RP11-1066F16 (CKS2 region). Hi-C DNA templates were generated as previously described (Lieberman-Aiden et al., 2009). 4C DNA templates were generated from 50 µg of HindIII-digested and ligated 3C DNA templates using a 4 basepair (bp) cutter, NlaIII, according to a previously published protocol (Gheldof et al., 2012).
ChIP-seq, RNA-seq, Hi-C and 4C-seq Library Preparation and Illumina Sequencing Processing
ChIP-seq and RNA-seq libraries were prepared using the Illumina ChIP-Seq and TruSeq RNA sample kits, respectively. 4C-seq libraries were generated using a set of 16 uniquely indexed, Illumina sequencing-based bait primers anchored at a NlaIII-HindIII fragment encompassing exon 1 and the promoter region of the BCL6 gene, or at a region within the distal enhancer region (enhancer 1) upstream of the BCL6 gene (see Table S7 for 4C-seq primer sequences). Hi-C DNA sequencing libraries were generated as previously described (Lieberman-Aiden et al., 2009) with 20–50 µg of Hi-C DNA template. Libraries were validated using the Agilent Technologies 2100 Bioanalyzer and Quant-iT™ dsDNA HS Assay (Life Technologies), and 8–10 pM sequenced on an Illumina GAIIx or HiSeq2000 sequencer as follows: ChIP-seq, 1 × 36; RNA-seq, 2 × 50; Hi-C, 2 × 50 cycles. 6.5 pM of the 4C-seq libraries were sequenced on an Illumina HiSeq2000 sequencer using 1 × 75 cycles, with 20–30% of a PhiX control library spiked into each lane, to account for low sample complexity. ChIP-seq data was aligned to the hg18 genome using BWA (Li and Durbin, 2009), clonal reads discarded, and regions of enrichment (peaks) identified using ChIPseeqer (Giannopoulou and Elemento, 2011). RNA-seq data was aligned to transcripts using TopHat (Trapnell et al., 2009), gene expression quantified in RPKM (Mortazavi et al., 2008) and differentially expressed genes identified (Wang et al., 2012). Hi-C reads were aligned to the hg18 genome using BWA and ambiguous reads and clonal reads discarded. Hi-C interactions were derived from read-pairs with consistent placement relative to HindIII sites (<500 bp away). Accordingly, read-pairs were filtered to remove background ligation products (non-ligated, self-ligated, non-digested or re-ligated DNA). The raw numbers of Hi-C read-pairs that were sequenced on each lane, uniquely aligned, and which represent intra-chromosomal interactions post-filtering, are summarized for each of the naïve B and GCB-cell replicates in Table S1. 4C-seq reads that contained the BCL6 promoter bait sequence or either of the BCL6 enhancer bait sequences (A, B or C) (>95% of total reads) were filtered using FASTX (http://hannonlab.cshl.edu/fastx_toolkit), aligned to the hg18 genome using BWA and ambiguous reads discarded. The numbers of uniquely aligned 4C-seq reads that were sequenced for each cell type and replicate are summarized in Table S2.
Generation of LCR-deficient mice using CRISPR mediated genome editing
Guide RNA sequences targeting the regions flanking the 165 Kb LCR in mice were selected with the CRISPR design tool at http://crispr.mit.edu/. Complementary oligos were ordered from integrated DNA technologies (Table S6), annealed and cloned into the BbsI restriction enzyme digestion site of the pX330-U6-Chimeric_BB-CBh-hSpCas9 plasmid. PCR was performed to amplify template DNA coding for the sgRNA sequence with an upstream T7 promoter sequence (Table S6). In-vitro transcription was performed using the Ambion MEGAshortscript T7 Transcription kit (Life Technologies). The sgRNA was subsequently purified using the Ambion MEGAclear kit (Life Technologies). The embryonic microinjection of the sgRNA pair along with Cas9 mRNA was in F1 hybrid zygotes from FVB/NJ and B6(Cg)-Tyrc-26/J mice. Microinjections were performed as described in (Singh, Schimenti, & Bolcun-filas, 2014). 81 of the 117 one-cell embryos progressed to the two-cell stage and were transferred into 4 pseudo-pregnant mice. A total of 15 pups were born from the resulting pregnancy. Pups were transferred to the animal facility at Weill Cornell Medical College where they were bred and all experiments were performed with the approval of the institutional animal care and use committee.
Immunohistochemistry
Mouse organs were fixed in 4% formaldehyde and embedded in paraffin. Sections were dewaxed in xylene and hydrated into graded alcohols. Endogenous peroxidase activity was blocked with 1% hydrogen peroxide in PBS for 15 minutes. Pretreatment was performed in a steamer using 10mM citrate buffer, pH6.0 for 30 minutes. Sections were incubated overnight with primary antibodies Bcl-6 (Rabbit polyclonal antibody from Santa Cruz Biotechnology, Cat. No. sc-858) diluted at 1:750; Biotinylated PNA (Vector Laboratories, Cat. No. B1075) diluted at 1:1000. Sections were washed with PBS and incubated with the appropriate secondary antibody followed by avidin-biotin complexes (Vector Laboratories, Burlingame, CA, Cat. No. PK-6100). Antibody reaction was visualized with 3-3’ Diaminobenzidine (Sigma, Cat. No. D8001) and counterstained with hematoxylin. Tissue sections were dehydrated in graded alcohols, cleared in xylene and mounted. Immunohistochemistry of the formalin or PFA-fixed paraffin-embedded sections for CD3, Ki67 and B220 was performed on a Leica Bond™ RX using the Bond™ Polymer Refine Detection Kit (Cat. No. DS9800). The sections were pre-treated using heat mediated antigen retrieval with EDTA pH9, (Leica Biosystem Epitope Retrieval Solution 2, Cat. No. AR9640) for 20mins. The sections were then incubated with CD3 (Abcam, Cat. No. ab16669) diluted at 1:100; Ki67 (Abcam, Cat. No. ab16667) diluted at 1:100; and B220 (BD Bioscience, Cat. No. 550286) diluted at 1:200 for 30mins. DAB was used as the chromogen. The sections were then counterstained with hematoxylin and mounted.. ImageJ 1.44o software (NIH) was used for IHC quantification. H&E and IHC stained sections were examined by a board certified veterinary pathologists.
Germinal center formation analysis using flow cytometry
For assessment of GC formation defects, LCR-deficient mice were intraperitoneally injected with 500ul of 1:10 diluted (in D-PBS) sheep red blood cells. On day 10 post-immunization mice were euthanized with CO2 to collect spleens. The splenic mononuclear cells were separated using Fico/Lite-LM (Atlanta Biologicals). Cells were stained for GCB-cells, naïve B-cells, follicular zone B-cells, marginal zone B-cells and monocytes and analyzed on a BD FACS Canto II flow cytometer.
Supplementary Material
Acknowledgments
We thank the Epigenomics Core Facility (WCMC); the Dekker lab and Nynke van-Berkum, for advice on Hi-C; Jiao Maria and Dr. Sebastien Monette from the WCMC and MSKCC lab of comparative pathology; Dr. John Schimenti from Cornell University (Ithaca); the Cornell Stem Cell and Transgenic Core facility, and Hao Shen. A.M.M. and O.E. are funded through NCI R01 CA104348. O.E. is funded by a US National Science Foundation CAREER grant 1054964 and NCI R01 CA194547. K.L.B. was supported by an American Society of Hematology Scholar Award.
Footnotes
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Author Contributions
K.L.B., A.M.M. and O.E. designed the studies and interpreted the data with T.D.S. and R.S. Experiments were performed as follows: K.L.B., D.W.P. and B.L.S., B-cell isolation, flow cytometry, microscopy, 3C; K.L.B. and D.W.P., 4C-seq; K.L.B., Hi-C-seq, RNA-seq, H3K27me3 and RAD21 ChIP-seq; R.S., design, generation and analysis of LCR-deficient mice; Y.J., H3K4me2, H3K4me3, H3K27Ac, CTCF, and PU.1 ChIP-seq; K.H., EP300 ChIP-seq; R.S., RNA PolII QChIP; W.R., surgical isolation of tonsil specimens; W.B. flow cytometry and IHC for LCR-deficient mice; T.D.S. developed Hi-C data algorithms and integrated computational analyses, with input from O.E.; K.L.B. contributed to development of the Hi-C data filtering pipeline and analyzed 4C-seq data, with input from O.E. M.T. contributed to data interpretation. K.L.B. wrote and prepared the manuscript with A.M.M., O.E., T.D.S., and R.S.
Accession Number
The Gene Expression Omnibus (GEO) accession number for the Hi-C and RNA-seq data sets reported in this paper is GSE84022.
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