The protein Id: a negative regulator of helix-loop-helix DNA binding proteins

We have isolated a cDNA clone encoding a novel helix-loop-helix (HLH) protein, Id. Id is missing the basic region adjacent to the HLH domain that is essential for specific DNA binding in another HLH protein, MyoD. An in vitro translation product of Id can associate specifically with at least three HLH proteins (MyoD, E12, and E47) and attenuate their ability to bind DNA as homodimeric or heterodimeric complexes. Id is expressed at varying levels in all cell lines tested. In three cell lines that can be induced to undergo terminal differentiation, Id RNA levels decrease upon induction. Transfection experiments indicate that over-expression of Id inhibits the trans-activation of the muscle creatine kinase enhancer by MyoD. Based on these findings, we propose that HLH proteins lacking a basic region may negatively regulate other HLH proteins through the formation of nonfunctional heterodimeric complexes.     

The loop region of the helix-loop-helix protein Id1 is critical for its dominant negative activity.

Id1, a helix-loop-helix (HLH) protein which lacks a DNA binding domain, has been shown to negatively regulate other members of the HLH family by direct protein-protein interactions, both in vitro and in vivo. In this study, we report the results of site-directed mutagenesis experiments aimed at defining the regions of Id1 which are important for its activity. We have found that the HLH domain of Id1 is necessary and nearly sufficient for its activity. In addition, we show that two amino acid residues at the amino terminus of the Id1 loop are critical for its activity, perhaps by specifying the correct dimerization partners. In this regard, replacing the first four amino acids of the loops of the basic HLH proteins E12 and E47 with the corresponding amino acids of Id1 confers Id1 dimerization specificity. These studies point to the loop region as an important structural and functional element of the Id subfamily of HLH proteins.     

The E12 inhibitory domain prevents homodimer formation and facilitates selective heterodimerization with the MyoD family of gene regulatory factors.

Although the ubiquitous helix-loop-helix (HLH) protein E12 does not homodimerize efficiently, the myogenic factor MyoD forms an avid DNA-binding heterodimer with E12 through the conserved HLH dimerization domain. However, the mechanism which ensures this selective dimerization is not understood at present. In our functional studies of various amino acid changes in the E12 HLH domain, we found that a single substitution in E12 helix 1 can abolish the effect of the E12 inhibitory domain and results in the efficient DNA binding of the E12 homodimer. Competition experiments revealed that the inhibitory domain, in fact, blocks the dimerization of E12 rather than DNA binding. MyoD contains two glutamic residues in helix 2 that are required for efficient dimerization with E12. More importantly, these residues were not essential for dimerization with E12 mutants in which the dimerization inhibitory domain had been relaxed, or for dimerization with E47 which does not contain the inhibitory domain owing to the use of an alternative exon. The positions of these glutamic residues are conserved among the four myogenic factors. Thus, members of the MyoD family of gene regulatory proteins can overcome the E12 dimerization inhibitory domain through a mechanism involving, in part, the negatively charged amino acid residues in helix 2. This result describes a novel mechanism facilitating the selective formation of the MyoD(MRF)-E12 heterodimer that enhances dimerization specificity and may apply to other members of the E-protein family.     

Inhibition of muscle-specific gene expression by Id3: requirement of the C-terminal region of the protein for stable expression and function.

We have examined the role of an Id-like protein, Id3 (also known as HLH462), in the regulation of muscle-specific gene expression. Id proteins are believed to block expression of muscle-specific genes by preventing the dimerization between ubiquitous bHLH proteins (E proteins) and myogenic bHLH proteins such as MyoD. Consistent with its putative role as an inhibitor of differentiation, Id3 mRNA was detected in proliferating skeletal muscle cells, was further induced by basic fibroblast growth factor (bFGF) and was down-regulated in differentiated muscle cultures. Overexpression of Id3 efficiently inhibited the MyoD-mediated activation of the muscle-specific creatine kinase (MCK) reporter gene. Deletion analysis indicated that the C-terminal 15 amino acids of Id3 are critical for the full inhibitory activity while deleting up to 42 residues from the C-terminus of the related protein, Id2, did not affect its ability to inhibit the MCK reporter gene. Chimeric protein containing the N-terminal region of Id3 and the C-terminus of Id2 was also non-functional in transfected cells. In contrast, wild-type Id3, the C-terminal mutants, and the Id3/Id2 chimera could all interact with the E-protein E47in vitro. Additional studies indicated that truncation of the Id3 C-terminus might have adversely affected the expression level of the mutant proteins but the Id3/Id2 chimera was stably expressed. Taken together, our results revealed a more complex requirement for the expression and proper function of the Id family proteins than was hitherto expected.     

Interactions between heterologous helix-loop-helix proteins generate complexes that bind specifically to a common DNA sequence

A DNA binding and dimerization motif, with apparent amphipathic helices (the HLH motif), has recently been identified in various proteins, including two that bind to immunoglobulin enhancers (E12 and E47). We show here that various HLH proteins can bind as apparent heterodimers to a single DNA motif and also, albeit usually more weakly, as apparent homodimers. The HLH domain can mediate heterodimer formation between either daughterless, E12, or E47 (Class A) and achaete-scute T3 or MyoD (Class B) to form proteins with high affinity for the kappa E2 site in the immunoglobulin kappa chain enhancer. The achaete-scute T3 and MyoD proteins do not form kappa E2-binding heterodimers together, and no active complex with N-myc was evident. The formation of a heterodimer between the daughterless and achaete-scute T3 products may explain the similar phenotypes of mutants at these two loci and the genetic interactions between them. A role of E12 and E47 in mammalian development, analogous to that of daughterless in Drosophila, is likely.     

FHL2通过相互作用抑制分化抑制蛋白家族成员的转录抑制活性

目的：探讨FHL2与Id（分化抑制蛋白）家族蛋白之间的相互作用及FHL2对Id蛋白功能的调控效应。方法：用GST-pulldown与免疫共沉淀（CoIP）方法检测FHL2与Id家族蛋白成员之间在体内外的相互作用;用共转染与报告基因驱动的萤光素酶方法检测FHL2对Id蛋白介导转录抑制效应的调控作用。结果：FHL2与Id家族的4个蛋白均存在直接的相互作用关系,表位分析结果显示FHL2蛋白中的第2个LIM结构域在FHL2/Id相互作用中是必需的,Id蛋白N端结构域在介导FHL2/Id相互作用中是必需的,FHL2/Id相互作用不依赖于Id蛋白中的螺旋-环-螺旋结构;通过相互作用,FHL2阻止了Id蛋白对碱性螺旋-环-螺旋转录因子E47转录活性的抑制作用。结论：FHL2是一个新识别的Id蛋白广谱的相互作用因子,通过对Id蛋白功能活性的抑制效应,FHL2可能参与Id介导的多种生物学效应以及肿瘤发生与进展。     

Phospho-Ablated Id2 Is Growth Suppressive and Pro-Apoptotic in Proliferating Myoblasts

Inhibitor of differentiation protein-2 (Id2) is a dominant negative helix-loop-helix (HLH) protein, and a positive regulator of proliferation, in various cells. The N-terminal region of Id2 contains a consensus cdk2 phosphorylation sequence SPVR, which may be involved with the induction of apoptosis, at least in myeloid 32d.3 cells. However, the role of Id2 phosphorylation at serine 5 in skeletal muscle cells is unknown. The objective of this study was to determine if the phosphorylation of Id2 at serine 5 alters its cellular localization and its role in apoptosis in C2C12 myoblasts. Overexpression of wild type Id2 decreased MyoD protein expression, which corresponded to the increased binding of Id2 to basic HLH proteins E47 and E12. Bromodeoxyuridine incorporation was significantly decreased by the overexpression of phospho-ablated Id2 (S5A); conversely, overexpression of wild type Id2 increased cellular proliferation. The subcellular localization of Id2 and phospho-mimicking Id2 (S5D) were predominantly nuclear compared to S5A. The decreased nuclear localization of S5A corresponded to a decrease in cellular proliferation, and an increase in apoptosis. These data suggest that unphosphorylated Id2 is primarily localized in the cytosol, where it is growth suppressive and potentially pro-apoptotic. These results imply that reducing unphosphorylated Id2 may improve the pool of myoblasts available for differentiation by increasing proliferation and inhibiting apoptosis.