Functional Domains of C-Myc Protein
Dang, Chi V.   
Johns Hopkins University, Baltimore, MD, United States

Altered expression of many 'cancer genes' or oncogenes have been implicated in the genesis of various cancers and hematologic neoplasms. The c-myc oncogene is prominent among these oncogenes for its involvement in lymphomas, leukemias, and in normal hematopoiesis. Despite the abundant knowledge of c-myc gene structure and expression, there is a relative paucity of information on the c-myc protein (c-Myc) domains and how c-Myc structure is related to function. We have a set of human c-myc mutants which was instrumental in delineating the domains of c-Myc which are involved in cell transformation, nuclear localization, non-specific DNA binding, and in c-Myc protein self-association. We were able to inhibit the wild-type c-Myc transforming activity with an inactive trans-dominant c-Myc mutant that can oligomerize with the wild-type Myc polypeptide to form inactive multimers. We hypothesize that c-Myc oligomerization, which occurs via its carboxyl-terminal domain containing repeats of leucines at every seventh amino acid ('leucine zipper'), is necessary for c-Myc to interact with nuclear targets such as DNA via a separate carboxyl-terminal basic region of c-Myc. An amino terminal region of c-Myc, which is required for transformation, is hypothesized to facilitate binding to other nuclear proteins which are necessary for c-Myc function. Using our available c-myc mutants, we propose to investigate the following: 1) the roles of different c-Myc regions in the proliferation and differentiation of a murine erythroleukemia (MEL) cell line and the use of the trans- dominant myc mutant to impede c-Myc activity in MEL and other cells; 2) the role of the c-Myc leucine residues in the 'leucine zipper' domain in c-Myc protein self-association; 3) the identification of proteins and specific DNA sequences which specifically interact with c-Myc. These studies will provide valuable information on the role of c-Myc in cell growth and differentiation and provide the basis to generate armamentarium for anti- oncogene manipulations and therapy using transdominant mutants. Structural studies on the c-Myc 'leucine zipper' domain will be crucial in our understanding of how this important motif affects protein-protein interactions in general. Identification of proteins and specific DNA sequences which associate with c-Myc will increase our understanding of c- Myc function and may allow recognition of additional genes involved in hematopoiesis.