A regulatory network of microRNAs confers lineage commitment during early developmental trajectories of B and T lymphocytes.

The commitment of hematopoietic multipotent progenitors (MPPs) toward a particular lineage involves activation of cell type-specific genes and silencing of genes that promote alternate cell fates. Although the gene expression programs of early-B and early-T lymphocyte development are mutually exclusive, we show that these cell types exhibit significantly correlated microRNA (miRNA) profiles. However, their corresponding miRNA targetomes are distinct and predominated by transcripts associated with natural killer, dendritic cell, and myeloid lineages, suggesting that miRNAs function in a cell-autonomous manner. The combinatorial expression of miRNAs miR-186-5p, miR-128-3p, and miR-330-5p in MPPs significantly attenuates their myeloid differentiation potential due to repression of myeloid-associated transcripts. Depletion of these miRNAs caused a pronounced de-repression of myeloid lineage targets in differentiating early-B and early-T cells, resulting in a mixed-lineage gene expression pattern. De novo motif analysis combined with an assay of promoter activities indicates that B as well as T lineage determinants drive the expression of these miRNAs in lymphoid lineages. Collectively, we present a paradigm that miRNAs are conserved between developing B and T lymphocytes, yet they target distinct sets of promiscuously expressed lineage-inappropriate genes to suppress the alternate cell-fate options. Thus, our studies provide a comprehensive compendium of miRNAs with functional implications for B and T lymphocyte development.

Transcription factor EBF restricts alternative lineage options and promotes B cell fate commitment independently of Pax5.

Alternative lineage restriction and B cell fate commitment require the transcription factor Pax5, but the function of early B cell factor (EBF) in these processes remains mostly unexplored. Here we show that in the absence of EBF, 'expandable' and clonal lymphoid progenitor cells retained considerable myeloid potential. Conversely, ectopic expression of EBF in multipotential progenitor cells directed B cell generation at the expense of myeloid cell fates. EBF induced Pax5 and antagonized expression of genes encoding the transcription factors C/EBPalpha, PU.1 and Id2. Notably, sustained expression of EBF in Pax5-/- hematopoietic progenitor cells was sufficient to block their myeloid and T lineage potential in vivo. Furthermore, in Pax5-/- pro-B cells, higher EBF expression repressed alternative lineage genes. Thus, EBF can restrict alternative lineage 'choice' and promote commitment to the B cell fate independently of Pax5.

Developmentally regulated higher-order chromatin interactions orchestrate B cell fate commitment.

Genome organization in 3D nuclear-space is important for regulation of gene expression. However, the alterations of chromatin architecture that impinge on the B cell-fate choice of multi-potent progenitors are still unclear. By integrating in situ Hi-C analyses with epigenetic landscapes and genome-wide expression profiles, we tracked the changes in genome architecture as the cells transit from a progenitor to a committed state. We identified the genomic loci that undergo developmental switch between A and B compartments during B-cell fate determination. Furthermore, although, topologically associating domains (TADs) are stable, a significant number of TADs display structural alterations that are associated with changes in cis-regulatory interaction landscape. Finally, we demonstrate the potential roles for Ebf1 and its downstream factor, Pax5, in chromatin reorganization and transcription regulation. Collectively, our studies provide a general paradigm of the dynamic relationship between chromatin reorganization and lineage-specific gene expression pattern that dictates cell-fate determination.

Regulation of immunoglobulin light-chain recombination by the transcription factor IRF-4 and the attenuation of interleukin-7 signaling.

Productive rearrangement of the immunoglobulin heavy-chain locus triggers a major developmental checkpoint that promotes limited clonal expansion of pre-B cells, thereby culminating in cell-cycle arrest and rearrangement of light-chain loci. By using Irf4-/-Irf8-/- pre-B cells, we demonstrated that two pathways converge to synergistically drive light-chain rearrangement, but not simply as a consequence of cell-cycle exit. One pathway was directly dependent on transcription factor IRF-4, whose expression was elevated by pre-B cell receptor signaling. IRF-4 targeted the immunoglobulin 3'Ekappa and Elambda enhancers and positioned a kappa allele away from pericentromeric heterochromatin. The other pathway was triggered by attenuation of IL-7 signaling and activated the iEkappa enhancer via binding of the transcription factor E2A. IRF-4 also regulated expression of chemokine receptor Cxcr4 and promoted migration of pre-B cells in response to the chemokine ligand CXCL12. We propose that IRF-4 coordinates the two pathways regulating light-chain recombination by positioning pre-B cells away from IL-7-expressing stromal cells.

Spatial Organization of Chromatin: Transcriptional Control of Adaptive Immune Cell Development.

Higher-order spatial organization of the genome into chromatin compartments (permissive and repressive), self-associating domains (TADs), and regulatory loops provides structural integrity and offers diverse gene regulatory controls. In particular, chromatin regulatory loops, which bring enhancer and associated transcription factors in close spatial proximity to target gene promoters, play essential roles in regulating gene expression. The establishment and maintenance of such chromatin loops are predominantly mediated involving CTCF and the cohesin machinery. In recent years, significant progress has been made in revealing how loops are assembled and how they modulate patterns of gene expression. Here we will discuss the mechanistic principles that underpin the establishment of three-dimensional (3D) chromatin structure and how changes in chromatin structure relate to alterations in gene programs that establish immune cell fate.

The RAG1 N-terminal region regulates the efficiency and pathways of synapsis for V(D)J recombination.

Immunoglobulin and T cell receptor gene assembly depends on V(D)J recombination initiated by the RAG1-RAG2 recombinase. The RAG1 N-terminal region (NTR; aa 1-383) has been implicated in regulatory functions whose influence on V(D)J recombination and lymphocyte development in vivo is poorly understood. We generated mice in which RAG1 lacks ubiquitin ligase activity (P326G), the major site of autoubiquitination (K233R), or its first 215 residues (Δ215). While few abnormalities were detected in R1.K233R mice, R1.P326G mice exhibit multiple features indicative of reduced recombination efficiency, including an increased Igκ+:Igλ+ B cell ratio and decreased recombination of Igh, Igκ, Igλ, and Tcrb loci. Previous studies indicate that synapsis of recombining partners during Igh recombination occurs through two pathways: long-range scanning and short-range collision. We find that R1Δ215 mice exhibit reduced short-range Igh and Tcrb D-to-J recombination. Our findings indicate that the RAG1 NTR regulates V(D)J recombination and lymphocyte development by multiple pathways, including control of the balance between short- and long-range recombination.

Assembling a gene regulatory network for specification of the B cell fate.

The generation of B lymphocyte precursors is dependent on the combinatorial action of the transcription factors PU.1, Ikaros, E2A, EBF, and Pax-5. Loss of PU.1 results in a severe reduction in Flk2+, IL-7R+ lymphoid progenitors as well as impaired expression of EBF and Pax-5. Restoration of EBF expression facilitates rapid generation of pro-B cells from PU.1-/- progenitors. Molecular analysis suggests that PU.1 directly participates in regulation of the EBF gene. Although PU.1 is dispensable for expression of most early B lineage genes, it is required for CD45R/B220. Using EBF-/- mutant progenitors, we show that EBF induces Pax-5 and the early program of B lineage gene expression. Importantly, Pax-5 does not rescue B cell development from either PU.1-/- or EBF-/- progenitors. Pax-5 expression and function are contingent on EBF. Based on these results, we propose a hierarchical regulatory network for specification and commitment to the B cell fate.

Gene regulatory networks that orchestrate the development of B lymphocyte precursors.

The B cell developmental pathway represents a leading model within the hematopoietc system for the analysis of gene regulatory networks, which orchestrate cell fate specification and commitment. Considerable progress is being made in the characterization of regulatory components that comprise such networks and examining their connectivity. These components include the cytokine receptors Flk2 and IL-7R as well as the transcription factors PU.1, Ikaros, E2A, EBF and Pax-5. We review recent experimental evidence concerning the molecular functions of these regulatory components and attempt to connect them in sequentially acting and inter-dependent regulatory modules.

Gene regulatory networks directing myeloid and lymphoid cell fates within the immune system.

Considerable progress is being achieved in the analysis of gene regulatory networks that direct cell fate decisions within the hematopoietic system. In addition to transcription factors that are pivotal for cell fate specification and commitment, recent evidence suggests the involvement of microRNAs. In this review we attempt to integrate these two types of regulatory components into circuits that dictate cell fate choices leading to the generation of innate as well as adaptive immune cells. The developmental circuits are placed in the context of a revised scheme for hematopoiesis that suggests that both the innate (myeloid) and adaptive (lymphoid) lineages of the immune system arise from a common progenitor.

Contingent gene regulatory networks and B cell fate specification.

The B cell developmental pathway represents a leading system for the analysis of regulatory circuits that orchestrate cell fate specification and commitment. Considerable progress has been achieved within the past decade in the identification and genetic analysis of various regulatory components. These components include the transcription factors PU.1, Ikaros, Bcl11a, E2A, EBF, and Pax-5, as well as the cytokine receptors Flk2 and IL-7R. Experimental evidence of connectivity among the regulatory components is used to assemble sequentially acting and contingent gene regulatory networks. Transient signaling inputs, self-sustaining positive feedback loops, and cross-antagonism among alternate cell fate determinants are key features of the proposed networks that instruct the development of B lymphocyte precursors from hematopoietic stem cells.

Crystal structure of PU.1/IRF-4/DNA ternary complex.

The Ets and IRF transcription factor families contain structurally divergent members, PU.1, Spi-B and IRF-4 (Pip), IRF-8 (ICSBP), respectively, which have evolved to cooperatively assemble on composite DNA elements and regulate gene expression in the immune system. Whereas PU.1 recruits IRF-4 or IRF-8 to DNA, it exhibits an anticooperative interaction with IRF-1 and IRF-2. We report here the structure of the ternary complex formed with the DNA binding domains of PU.1 and IRF-4 on a composite DNA element. The DNA in the complex contorts into an unusual S shape that juxtaposes PU.1 and IRF-4 for selective electrostatic and hydrophobic interactions across the central minor groove. Together, the protein-protein and protein-DNA interactions provide insights into the stereochemical basis of cooperativity and anti-cooperativity between Ets and IRF factors.