Cell cycle progression is intricately controlled by coordinated expression and ubiquitin-dependent degradation of key regulatory proteins. Ubiquitylation of target substrates requires the concerted activity of an Ub-activating enzyme (E1), recruitment of an Ub-conjugating enzyme (E2), and an E3 ubiquitin ligase. Although some E3 ubiquitin ligases directly mediate transfer of ubiquitin, for example, the HECT-domain family of E3 ligases, many E3 ligases function as multi-subunit complexes that bridge the charged E2 enzyme with a given substrate (20). The Skp1-Cul1-F-box (SCF) family of E3 ubiquitin ligases is an example of the latter and promotes polyubiquitylation of mainly phosphorylated substrates, including G 1 /S regulatory proteins (11,12,27,32,43). Specificity of SCF ligases is conferred by the F-box protein, which bridges substrate molecules with the core ligase machinery. F-box proteins contain a conserved F-box domain, required for Skp1 binding and recruitment of core ligase components Cul1, Rbx1, and E2, as well as a substrate-recognition domain within the C terminus (39, 43, 51).The F-box protein, Fbx4, regulates ubiquitylation of cyclin D1, following the G 1 /S transition (32). Similar to Fbw7, a ubiquitin ligase for targets such as cyclin E, c-Myc, and Notch (27, 47-50, 54, 55), and -TrCP, an E3 ligase for targets including IB, -catenin, Cdc25A, and Emi1 (10,16,18,24,26,28,36,38,45,46,52), Fbx4 undergoes dimerization; however, in contrast to either Fbw7 or -TrCP, Fbx4 dimerization occurs in a cell cycle-dependent manner (5,17,44,46). Fbx4 dimerization requires glycogen synthase kinase 3 (GSK3)-dependent phosphorylation at serine 12, which triggers ligase activation at the G 1 /S transition (5, 32). Critically, mutations that stabilize cyclin D1 and thereby trigger nuclear accumulation of active cyclin D1/CDK4 drive cell transformation (1-3). While cyclin D1 overexpression occurs in multiple human malignancies (4, 6-8, 14, 19, 21-23, 25), overexpression of wild-type cyclin D1 in an Fbx4-proficient system is insufficient to drive spontaneous transformation (3, 5), supporting a model wherein cytoplasmic recognition of phosphorylated cyclin D1 by Fbx4 is sufficient to maintain cellular integrity.Cyclin D1 mutations that impede degradation and trigger nuclear accumulation promote neoplastic growth (1,3,5,9,35,37); however, such mutations are rare in human cancer. Recent work identified inactivating Fbx4 mutations in human cancers that impair ligase phosphorylation and dimerization. Such tumors exhibit marked cyclin D1 nuclear accumulation, highlighting a novel mechanism for cyclin D1 deregulation in cancer (5). Taken together, these findings suggest that Fbx4 is a tumor suppressor, preventing aberrant cyclin D1 accumulation.To investigate the tumor suppressor function of Fbx4, we ablated the murine Fbx4 gene. Fbx4 Ϫ/Ϫ mice are viable and lack major developmental defects. However, Fbx4Ϫ/Ϫ murine embryonic fibroblasts (MEFs) exhibit cyclin D1 stabilization and subsequent nuclear localization, with con...
