Abstract
The interaction of helix-loop-helix (HLH) proteins is known to regulate the differentiation of several different tissues, including mammalian muscle and the insect peripheral nervous system. In myoblasts, the products of myogenic HLH genes such as MyoD and ubiquitous HLH proteins such as E12 are present at constant levels throughout development. An E12 monomer and a MyoD monomer form a DNA binding heterodimer that activates muscle-specific genes. These two proteins are unable to dimerize in proliferating myoblasts because a negative regulator HLH protein, Id, is present. We now report the sequence and structure of a human HLH gene related to Id, which has been designated Id-2. Two prominent Id-2 RNA molecules of 2.5 and 1.3 kilobases were found in a number of different human normal and neoplastic tissues. We believe the larger RNA is a precursor of the 1.3-kilobase mRNA that encodes an Id-2 protein of 134 amino acids. The HLH region of the Id-2 protein is 90% homologous to that of myogenic Id, but the homology is much less extensive outside the HLH region. The Id-2 gene is highly expressed during early fetal development in several tissues, including those of the central nervous system, but is not expressed in the corresponding mature tissues. Id-2 expression is modulated in association with retinoic acid-induced ganglionic differentiation of the neuroblastoma cell line SMS-KCNR. These findings suggest that Id-2 is an inhibitor of tissue-specific gene expression, although its distinctive pattern of expression during development suggests a role different from that of Id.
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