B-cell- and myocyte-specific E2-box-binding factors contain E12/E47-like subunits.

Recent studies have identified a family of DNA-binding proteins that share a common DNA-binding and dimerization domain with the potential to form a helix-loop-helix (HLH) structure. Various HLH proteins can form heterodimers that bind to a common DNA sequence, termed the E2-box. We demonstrate here that E2-box-binding B-cell- and myocyte-specific nuclear factors contain subunits which are identical or closely related to ubiquitously expressed (E12/E47) HLH proteins. These biochemical function for E12/E47-like molecules in mammalian differentiation, similar to the genetically defined function of daughterless in Drosophila development.     

B-lymphocyte development is regulated by the combined dosage of three basic helix-loop-helix genes, E2A, E2-2, and HEB.

B-lymphocyte development requires the basic helix-loop-helix proteins encoded by the E2A gene. In this study, the control mechanism of E2A was further explored by disruption of the E2A-related genes, E2-2 and HEB. In contrast to E2A, E2-2 and HEB are not essential for the establishment of the B-cell lineage. However, both E2-2 and HEB are required for the generation of the normal numbers of pro-B cells in mouse embryos. Breeding tests among mice carrying different mutations revealed that E2-2 and HEB interact with E2A in many developmental processes including generation of B cells. Specifically, mice transheterozygous for any two mutations of these three genes produced fewer pro-B cells than the singly heterozygous littermates. This study indicates that B-cell development is dependent not only on an essential function provided by the E2A gene but also on a combined dosage set by E2A, E2-2, and HEB.     

Regulation of Id1 and its association with basic helix-loop-helix proteins during nerve growth factor-induced differentiation of PC12 cells.

Cell differentiation in the nervous system is dictated by specific patterns of gene expression. We have investigated the role of helix-loop-helix (HLH) proteins during differentiation of PC12 pheochromocytoma cells in response to nerve growth factor. Gel mobility shift assays using PC12 cell nuclear extracts demonstrated that active basic HLH complexes exist throughout differentiation. Addition of exogeneous Id1 protein, a negative regulator of basic HLH proteins, disrupted specific complexes formed by PC12 cell nuclear extracts on a CANNTG consensus oligonucleotide. To identify possible novel basic HLH proteins in these complexes, a glutathione S-transferase-Id1 fusion protein was used to screen a PC12 cell cDNA expression library. A single clone representing the rat E2-2 gene was identified. Sequential immunoprecipitations with antibodies to each HLH protein revealed an association between Id1 and E2-2 that could be detected in both untreated and nerve growth factor-treated PC12 cell lysates. These experiments define a new HLH interaction between Id1 and E2-2 in neuronal cells and suggest that neuronal differentiation may be regulated by HLH proteins in a distinctive manner.     

HEB, a helix-loop-helix protein related to E2A and ITF2 that can modulate the DNA-binding ability of myogenic regulatory factors.

Proteins containing the basic-helix-loop-helix (B-HLH) domain have been shown to be important in regulating cellular differentiation. We have isolated a cDNA for a human B-HLH factor, denoted HEB, that shares nearly complete identity in the B-HLH domain with the immunoglobulin enhancer binding proteins encoded by the E2A and ITF2 genes (E proteins). Functional characterization of the protein expressed from this cDNA indicates that HEB is a third member of the E-protein class of B-HLH factors. HEB mRNA was found to be expressed in several tissues and cell types, including skeletal muscle, thymus, and a B-cell line. HEB, ITF2, and the E12 product of the E2A gene all bound to a similar spectrum of E-box sequences as homo-oligomers. All three factors also formed hetero-oligomers with myogenin, and the DNA-binding specificity and binding off-rates (dissociation rates) were modulated after hetero-oligomerization. Both homo- and hetero-oligomers of these proteins were able to distinguish between very closely related E-box sequences. In addition, HEB was shown to form hetero-oligomers with the E12 and ITF2 proteins. Finally, HEB was able to activate gene expression. These data demonstrate that HEB shares characteristics with other E proteins and show that HEB can interact with members of both the myogenic regulatory class and the E-protein class of B-HLH factors. HEB is therefore likely to play an important role in regulating lineage-specific gene expression.