Interaction of MYC with host cell factor-1 is mediated by the evolutionarily conserved Myc box IV motif.

The MYC family of oncogenes encodes a set of three related transcription factors that are overexpressed in many human tumors and contribute to the cancer-related deaths of more than 70,000 Americans every year. MYC proteins drive tumorigenesis by interacting with co-factors that enable them to regulate the expression of thousands of genes linked to cell growth, proliferation, metabolism and genome stability. One effective way to identify critical co-factors required for MYC function has been to focus on sequence motifs within MYC that are conserved throughout evolution, on the assumption that their conservation is driven by protein-protein interactions that are vital for MYC activity. In addition to their DNA-binding domains, MYC proteins carry five regions of high sequence conservation known as Myc boxes (Mb). To date, four of the Mb motifs (MbI, MbII, MbIIIa and MbIIIb) have had a molecular function assigned to them, but the precise role of the remaining Mb, MbIV, and the reason for its preservation in vertebrate Myc proteins, is unknown. Here, we show that MbIV is required for the association of MYC with the abundant transcriptional coregulator host cell factor-1 (HCF-1). We show that the invariant core of MbIV resembles the tetrapeptide HCF-binding motif (HBM) found in many HCF-interaction partners, and demonstrate that MYC interacts with HCF-1 in a manner indistinguishable from the prototypical HBM-containing protein VP16. Finally, we show that rationalized point mutations in MYC that disrupt interaction with HCF-1 attenuate the ability of MYC to drive tumorigenesis in mice. Together, these data expose a molecular function for MbIV and indicate that HCF-1 is an important co-factor for MYC.

A deficiency in Mdm2 binding protein inhibits Myc-induced B-cell proliferation and lymphomagenesis.

Mdm2 binding protein (MTBP) has been implicated in cell-cycle arrest and the Mdm2/p53 tumor suppressor pathway through its interaction with Mdm2. To determine the function of MTBP in tumorigenesis and its potential role in the Mdm2/p53 pathway, we crossed Mtbp-deficient mice to Emu-myc transgenic mice, in which overexpression of the oncogene c-Myc induces B-cell lymphomas primarily through inactivation of the Mdm2/p53 pathway. We report that Myc-induced B-cell lymphoma development in Mtbp heterozygous mice was profoundly delayed. Surprisingly, reduced levels of Mtbp did not lead to an increase in B-cell apoptosis or affect Mdm2. Instead, an Mtbp deficiency inhibited Myc-induced proliferation and the upregulation of Myc target genes necessary for cell growth. Consistent with a role in proliferation, Mtbp expression was induced by Myc and other factors that promote cell-cycle progression and was elevated in lymphomas from humans and mice. Therefore, Mtbp functioned independent of Mdm2 and was a limiting factor for the proliferative and transforming functions of Myc. Thus, Mtbp is a previously unrecognized regulator of Myc-induced tumorigenesis.