Insulin-induced cell division is controlled by the adaptor Grb14 in a Chfr-dependent manner.

Beyond its key role in the control of energy metabolism, insulin is also an important regulator of cell division and neoplasia. However, the molecular events involved in insulin-driven cell proliferation are not fully elucidated. Here, we show that the ubiquitin ligase Chfr, a checkpoint protein involved in G2/M transition, is a new effector involved in the control of insulin-induced cell proliferation. Chfr is identified as a partner of the molecular adapter Grb14, an inhibitor of insulin signalling. Using mammalian cell lines and the Xenopus oocyte as a model of G2/M transition, we demonstrate that Chfr potentiates the inhibitory effect of Grb14 on insulin-induced cell division. Insulin stimulates Chfr binding to the T220 residue of Grb14. Both Chfr binding site and Grb14 C-ter BPS-SH2 domain, mediating IR binding and inhibition, are required to prevent insulin-induced cell division. Targeted mutagenesis revealed that Chfr ligase activity and phosphorylation of its T39 residue, a target of Akt, are required to potentiate Grb14 inhibitory activity. In the presence of insulin, the binding of Chfr to Grb14 activates its ligase activity, leading to Aurora A and Polo-like kinase degradation and blocking cell division. Collectively, our results show that Chfr and Grb14 collaborate in a negative feedback loop controlling insulin-stimulated cell division.

Grb14 inhibits FGF receptor signaling through the regulation of PLCγ recruitment and activation.

To decipher the mechanism involved in Grb14 binding to the activated fibroblast growth factor receptor (FGFR), we used the bioluminescence resonance energy transfer (BRET) technique and the Xenopus oocyte model. We showed that Grb14 was recruited to FGFR1 into a trimeric complex containing also phospholipase C gamma (PLCγ). The presence of Grb14 altered FGF-induced PLCγ phosphorylation and activation. Grb14-FGFR interaction involved the Grb14-SH2 domain and the FGFR pY766 residue, which is the PLCγ binding site. Our data led to a molecular model whereby Grb14 binding to the phosphorylated FGFR induces a conformational change that unmasks a PLCγ binding motif on Grb14, allowing trapping and inactivation of PLCγ.

Molecular determinants of Grb14-mediated inhibition of insulin signaling.

Grb14 belongs to the Grb7 family of molecular adapters and was identified as an inhibitor of insulin signaling. Grb14 binds to activated insulin receptors (IR) and inhibits their catalytic activity. To gain more insight into the Grb14 molecular mechanism of action, we generated various mutants and studied the Grb14-IR interaction using coimmunoprecipitation and bioluminescence resonance energy transfer (BRET) experiments. Biological activity was further analyzed using the Xenopus oocyte model and a functional complementation assay measuring cellular proliferation rate in Grb14 knockout mouse embryonic fibroblasts. These studies identified two important interaction sites, Grb14 L404-IR L1038 and Grb14 R385-IR K1168, involving the IR alphaC-helix and activation loop, respectively. Interestingly, the former involves residues that are likely to be crucial for the specificity of IR binding with regard to other members of the Grb7 family. In addition, mutation of the Grb14-S370 residue suggested that its phosphorylation status controlled the biological activity of the protein. We further demonstrated that insulin-induced Grb14-PDK1 interaction is required in addition to Grb14-IR binding to mediate maximal inhibition of insulin signaling. This study provides important insights into the molecular determinants of Grb14 action by demonstrating that Grb14 regulates insulin action at two levels, through IR binding and by interfering with downstream pathways. Indeed, a precise knowledge of the molecular mechanism of insulin signaling inhibition by Grb14 is a prerequisite for the development of insulin-sensitizing molecules to treat pathophysiological states such as obesity or type 2 diabetes.

Myristic acid increases the activity of dihydroceramide Delta4-desaturase 1 through its N-terminal myristoylation.

Dihydroceramide Delta4-desaturase (DES) catalyzes the desaturation of dihydroceramide into ceramide. In mammals, two gene isoforms named DES1 and DES2 have recently been identified. The regulation of these enzymes is still poorly understood. This study was designed to examine the possible N-myristoylation of DES1 and DES2 and the effect of this co-translational modification on dihydroceramide Delta4-desaturase activity. N-MyristoylTransferases (NMT) catalyze indeed the formation of a covalent linkage between myristoyl-CoA and the N-terminal glycine of candidate proteins, as found in the sequence of DES proteins. The expression of both rat DES in COS-7 cells evidenced first that DES1 but not DES2 was associated with an increased dihydroceramide Delta4-desaturase activity. Then, we showed that recombinant DES1 was myristoylated in vivo when expressed in COS-7 cells. In addition, in vitro myristoylation assay with a peptide substrate corresponding to the N-terminal sequence of the protein confirmed that NMT1 has a high affinity for DES1 myristoylation motif (apparent K(m)=3.92 microM). Compared to an unmyristoylable mutant form of DES1 (Gly replaced by an Ala), the dihydroceramide Delta4-desaturase activity of the myristoylable DES1-Gly was reproducibly and significantly higher. Finally, the activity of wild-type DES1 was also linearly increased in the presence of increased concentrations of myristic acid incubated with the cells. These results demonstrate that DES1 is a newly discovered myristoylated protein. This N-terminal modification has a great impact on dihydroceramide Delta4-desaturase activity. These results suggest therefore that myristic acid may play an important role in the biosynthesis of ceramide and in sphingolipid metabolism.