Pan/E2A expression precedes immunoglobulin heavy-chain expression during B lymphopoiesis in nontransformed cells, and Pan/E2A proteins are not detected in myeloid cells

Id proteins negatively regulate basic helix-loop-helix transcription factor function by disrupting subnuclear compartmentalization

Id helix-loop-helix (HLH) proteins act as global regulators of metazoan cell fate, cell growth, and differentiation. They heterodimerize with and inhibit the DNA-binding function of members of the basic helix-loop-helix (bHLH) family of transcription factors. Using real time fluorescence microscopy techniques in single living cells, we show here that nuclear pools of chromatin-associated bHLH transcription factor are freely exchangeable and in constant flux. The existence of a dynamic equilibrium between DNA-bound and free bHLH protein is also directly demonstrable in vitro. By contrast, Id protein is not associated with any subcellular, macromolecular structures and displays a more highly mobile, diffuse nuclear-cytoplasmic distribution. When co-expressed with antagonist Id protein, the chromatin-associated sublocalization of bHLH protein is abolished, and there is an accompanying 100-fold increase in its nuclear mobility to a level expected for freely diffusible Id-bHLH heterodimer. These results suggest that nuclear Id protein acts by sequestering pools of transiently diffusing bHLH protein to prevent reassociation with chromatin domains. Such a mechanism would explain how Id proteins are able to overcome the large DNA-binding free energy of bHLH proteins that is necessary to accomplish their inhibitory effect.

Regulation of early lymphocyte development by E2A family proteins

Lymphocytes develop from hematopoietic stem cells through a series of highly regulated differentiation events in the bone marrow and thymus. A number of transcription factors are known to collaborate in controlling the timing and specificity of gene expression required for these developmental processes to occur. The basic helix-loop-helix (bHLH) proteins encoded by the E2A gene have been shown to play particularly important roles in the initiation and progression of lymphocyte differentiation. Gene targeting experiments in mice have demonstrated a requirement for E2A proteins at the onset of B lymphocyte development. More recent studies have broadened our view on the function of E2A proteins at multiple stages of lymphopoiesis and in the regulation of lymphoid-specific gene expression. Here we review the mammalian E2A proteins and the accumulated evidence demonstrating central roles for E2A throughout early B and T lymphocyte development. We also speculate on the direction of future research on the mechanisms underlying the lineage and stage-specific functions of E2A in lymphopoiesis.

Enhancer-specific modulation of E protein activity

Homodimeric complexes of members of the E protein family of basic helix-loop-helix (bHLH) transcription factors are important for tissue-specific activation of genes in B lymphocytes (Bain, G., Gruenwald, S., and Murre, C. (1993) Mol. Cell Biol. 13, 3522-3529; Shen, C. P., and Kadesch, T. (1995) Mol. Cell Biol. 15, 4518-4524; Jacobs, Y., et al. (1994) Mol. Cell Biol. 14, 4087-4096; Wilson, R. B., et al. (1991) Mol. Cell Biol. 11, 6185-6191). These homodimers, however, have little activity on myogenic enhancers (Weintraub, H., Genetta, T., and Kadesch, T. (1994) Genes Dev. 8, 2203-2211). We report here the identification of a novel cis-acting transcriptional repression domain in the E protein family of bHLH transcription factors. This domain, the Rep domain, is present in each of the known vertebrate E proteins. Extensive mapping analysis demonstrates that this domain is an acidic region of 30 amino acids with a predicted loop structure. Fusion studies indicate that the Rep domain can repress both of the E protein transactivation domains (AD1 and AD2). Physiologically, the Rep domain plays a key role in maintaining E protein homodimers in an inactive state on myogenic enhancers. In addition, we demonstrate that Rep domain mediated repression of AD1 is a necessary for the function of MyoD-E protein heterodimeric complexes. These studies demonstrate that the Rep domain is important for modulating the transcriptional activity of E proteins and provide key insights into both the selectivity and mechanism of action of E protein containing bHLH protein complexes.

B cell development pathways

B cell development is a highly regulated process whereby functional peripheral subsets are produced from hematopoietic stem cells, in the fetal liver before birth and in the bone marrow afterward. Here we review progress in understanding some aspects of this process in the mouse bone marrow, focusing on delineation of the earliest stages of commitment, on pre-B cell receptor selection, and B cell tolerance during the immature-to-mature B cell transition. Then we note some of the distinctions in hematopoiesis and pre-B selection between fetal liver and adult bone marrow, drawing a connection from fetal development to B-1/CD5(+) B cells. Finally, focusing on CD5(+) cells, we consider the forces that influence the generation and maintenance of this distinctive peripheral B cell population, enriched for natural autoreactive specificities that are encoded by particular germline V(H)-V(L) combinations.

The genomic structure and promoter analysis of the human ABF-1 gene

The human ABF-1 gene is expressed in activated B-cells and Epstein-Barr virus-immortalized lymphoblastoid cell lines. ABF-1 represents the only member belonging to the basic helix-loop-helix (bHLH) family of transcription factors whose expression pattern is restricted to B-cells. ABF-1 forms heterodimeric complexes with E2A to modulate gene transcription. We report the cloning and characterization of the human ABF-1 gene and the promoter region. The gene spans more than 3 kb and contains two exons. Exon 1 contains 274 bp of a 5'-untranslated sequence (UTR) while exon 2 contains 1097 bp of 3'-UTR. Promoter analysis of the 5'-flanking region revealed no apparent B-cell-restricted control elements within approximately 700 bp, but clearly demonstrated the presence of a functional minimal promoter residing immediately upstream of the transcription start site. Analysis of the region containing the minimal promoter activity identified no CCAAT or TATA sequence. Lastly, we have assigned the ABF-1 gene to human chromosome 8q21.1 using fluorescence in situ hybridization (FISH). The cloning of the human ABF-1 gene will facilitate further biochemical and genetic studies of its function in the regulation of B-cell differentiation.

Coordinate regulation of B cell differentiation by the transcription factors EBF and E2A

The transcription factors EBF and E2A are required at a similar step in early B cell differentiation. EBF and E2A synergistically upregulate transcription of endogenous B cell-specific genes in a non-B cell line. Here, we examine a genetic collaboration between these factors in regulating B lymphopoiesis. We find that Ebf+/- E2a+/- mice display a marked defect in pro-B cell differentiation at a stage later than observed in the single homozygous mutant mice. Pro-B cells from Ebf+/- E2a+/- mice show reduced expression of lymphoid-specific transcripts, including Pax5, Rag1, Rag2, and mb-1. We also show that EBF directly binds and activates the Pax5 promoter. Together, these data show collaboration between EBF and E2A and provide insight into the hierarchy of transcription factors that regulate B lymphocyte differentiation.

Two isoforms of protein disulfide isomerase alter the dimerization status of E2A proteins by a redox mechanism

We have shown previously that E2A helix-loop-helix proteins spontaneously form an intermolecular disulfide cross-link that is required for stable homodimer binding to DNA (Benezra, R. (1994) Cell 79, 1057-1067). These homodimers are important for the development of B lymphocytes but are not present in other cell lineages. We have purified two proteins that are capable of regulating the formation of this disulfide bond and found them to be members of the protein disulfide isomerase (PDI) family. By regulating the formation of the disulfide cross-link, these proteins are capable of regulating the dimerization state of E proteins. PDI-mediated reduction appears to dissociate E protein homodimers and favors heterodimer formation with other basic helix-loop-helix proteins in both a purified protein system and in cellular extracts. These studies suggest that PDI may play an important role in the regulation of E2A transcription factor dimerization and the development of the B lymphocyte lineage.

Induction of early B cell factor (EBF) and multiple B lineage genes by the basic helix-loop-helix transcription factor E12

The transcription factors encoded by the E2A and early B cell factor (EBF) genes are required for the proper development of B lymphocytes. However, the absence of B lineage cells in E2A- and EBF-deficient mice has made it difficult to determine the function or relationship between these proteins. We report the identification of a novel model system in which the role of E2A and EBF in the regulation of multiple B lineage traits can be studied. We found that the conversion of 70Z/3 pre-B lymphocytes to cells with a macrophage-like phenotype is associated with the loss of E2A and EBF. Moreover, we show that ectopic expression of the E2A protein E12 in this macrophage line results in the induction of many B lineage genes, including EBF, IL7Ralpha, lambda5, and Rag-1, and the ability to induce kappa light chain in response to mitogen. Activation of EBF may be one of the critical functions of E12 in regulating the B lineage phenotype since expression of EBF alone leads to the activation of a subset of E12-inducible traits. Our data demonstrate that, in the context of this macrophage line, E12 induces expression of EBF and together these transcription factors coordinately regulate numerous B lineage-associated genes.

Restricted expression of E2A protein in primary human tissues correlates with proliferation and differentiation

E2A is a basic helix-loop-helix (bHLH) transcription factor required for B cell lymphopoiesis and implicated in myogenesis and the regulation of insulin expression. As E2A is expressed widely in tissues, tissue-specific downstream effects are thought to result primarily from dimerization with other bHLH proteins. To investigate the degree to which regulation of E2A protein abundance may serve to regulate E2A function, expression of E2A was evaluated using immunohistochemistry on histological sections of primary human tissues. Somewhat surprisingly, nuclear staining for E2A was restricted in all tissues examined, often to a small subpopulation of cells. In some tissues, such as adult liver, expression was absent or limited to rare infiltrating lymphocytes. E2A-expressing cells were most abundant in lymphoid tissues. In tonsil, lymph node, and spleen, expression appeared most abundant and prevalent among rapidly proliferating centroblasts of the germinal center dark zone. Scattered E2A-expressing thymocytes were more numerous in the thymic cortex than medulla. In developing skeletal muscle, E2A was detectable in striated myotubes but not in more primitive mononucleated progenitors or mature muscle. Differential E2A expression was also noted in proliferating periventricular neuroepithelial cells in the developing brain. These results suggest that regulation of E2A abundance complements protein-protein interactions in modulating E2A function.

EBF and E47 collaborate to induce expression of the endogenous immunoglobulin surrogate light chain genes

Early B cell factor (EBF) and E47 participate in the transcriptional control of early B lymphocyte differentiation. With the aim of identifying genetic targets for these transcription factors, we stably transfected cDNAs encoding EBF or a covalent homodimer of E47, individually or together, into immature hematopoietic Ba/F3 cells, which lack both factors. In combination, EBF and E47 induce efficient expression of the endogenous immunoglobulin surrogate light chain genes, lambda5 and VpreB, whereas other pre-B cell-specific genes remain silent. Multiple functionally important EBF and E47 binding sites were identified in the lambda5 promoter/enhancer region, indicating that lambda5 is a direct genetic target for these transcription factors. Taken together, these data suggest that EBF and E47 synergize to activate expression of a subset of genes that define an early stage of the B cell lineage.

Involvement of the E2A basic helix-loop-helix protein in immunoglobulin heavy chain class switching

The basic helix-loop-helix (bHLH) transcriptional factor E2A has previously been shown to play a critical role in early B cell development, with E2A knockout mice and Id1 transgenic mice showing an arrest at the pro-B cell stage of development. More recent data suggest that E2A, through an interaction with the immunoglobulin heavy chain 3' enhancer, might also regulate later events in B cell development such as heavy chain class switching. The patterns of E2A protein expression in secondary lymphoid tissues support a role in later stages of B cell maturation. In particular, immunostaining reveals upregulation of E2A protein in cells of the dark zone of the germinal center, the site of immunoglobulin heavy chain class switching. To examine the role of E2A in class switching, the inhibitory HLH protein Id1 was expressed in B cell lines which normally undergo spontaneous and inducible switching from IgM to IgA. The forced expression of Id1 in these cell lines effectively blocked class switching. This Id1 blockade of class switching did not occur via downregulation of immunoglobulin heavy chain germline transcription or through inhibition of cell cycling. Furthermore, Id1 inhibited spontaneous and, to a lesser degree, cytokine inducible class switching. From these data, we conclude that E2A plays an important role in the class switching process.

Regulation of gene expression at early stages of B-cell and T-cell differentiation

The expression of distinct sets of genes at different stages of B-lymphocyte and T-lymphocyte differentiation is controlled at the level of transcription. A number of recent studies have described interactions between transcription factors in lymphocytes that provide new insights into mechanisms regulating gene expression. These mechanisms include the assembly of higher order nucleoprotein complexes and other protein-protein interactions that enhance the functional specificity of transcriptional regulators in lymphocytes.

Immunoglobulin heavy chain germ-line JH-C mu transcription in human precursor B lymphocytes initiates in a unique region upstream of DQ52

From human precursor B cells which had both immunoglobulin (Ig) heavy (H) chain loci in germ-line configuration, various IgH chain germ-line transcripts were isolated and sequenced. These transcripts were shown to contain sequences derived from the JH region, the IgH chain enhancer element or the Ig switch region. A number of isolated cDNA clones contained sequences at their 5' end that were derived from a single exon located just upstream of DQ52, designated the mu o' element. Sequence analysis of a 920-bp genomic DNA segment, containing the mu o' exon and its 5' flanking region, revealed the presence of various conserved motifs for DNA-binding proteins, such as E2A, Ets, NF-kappa B and AP-2, which have previously been found in the IgH and L chain enhancers. We propose that the activity of the mu o' element, resulting in germ-line transcription of the DQ52-JH gene segment, is required to generate full accessibility for the V(D)J recombinase.