Zamal Ahmed

APS, AN ADAPTER PROTEIN WITH A PH AND SH2 DOMAIN, IS A SUBSTRATE FOR THE INSULIN RECEPTOR KINASE

APS (adapter protein with a PH and SH2 domain) is the newest member of a family of tyrosine kinase adapter proteins including SH2-B and Lnk. We previously identified SH2-B as an insulin-receptor-binding protein and substrate [Kotani, Wilden and Pillay (1998) Biochem J. 335, 103-109]. Here we show that APS interacts with the insulin receptor kinase activation loop through its SH2 domain and insulin stimulates the tyrosine-phosphorylation of APS. Furthermore, the phosphorylation of activation-loop tyrosine residues 1158 and 1162 are required for this interaction.

Adapter protein with a pleckstrin homology (PH) and an Src homology 2 (SH2) domain (APS) and SH2-B enhance insulin-receptor autophosphorylation, extracellular-signal-regulated kinase and phosphoinositide 3-kinase-dependent signalling

Adapter protein with a pleckstrin homology (PH) and an Src homology 2 (SH2) domain (APS) and SH2-B are adapter proteins and substrates that interact with the activation loop of the insulin-receptor (IR) kinase. These proteins are homologous and share substantial sequence similarity. We previously showed [Ahmed, Smith and Pillay, FEBS Lett. 475, 31-34], for the first time, that insulin-stimulated phosphorylation of APS led to interaction with c-Cbl in 3T3-L1 adipocytes and in transfected Chinese-hamster ovary (CHO) cells. In the present study, we find that insulin stimulates the membrane translocation and phosphorylation of APS to a much greater extent than SH2-B, despite the structural similarity of these proteins. Expression of APS or SH2-B delays IR tyrosine and IR substrate (IRS) dephosphorylation. This enhancement of signalling is also observed downsteam of the receptor. In control cells that lack APS, following insulin stimulation, extracellular-signal-regulated kinase (ERK) and Akt kinase reach maximal activation and then decline to basal levels by 60 min. In contrast, in APS- and SH2-B-expressing cells, ERK and Akt kinase activation remains at peak levels at 60 min. These effects may occur because these proteins either stabilize the active conformation or prevent dephosphorylation of the IR. We therefore conclude that, despite the ability to couple to c-Cbl, APS functions as a positive regulator of IR signalling and, although SH2-B is a poor substrate for the IR, its association with the IR allows it to regulate pathways downstream of the receptor independently of its phosphorylation.

Extracellular point mutations in FGFR2 elicit unexpected changes in intracellular signalling

An understanding of cellular signalling from a systems-based approach has to be robust to assess the effects of point mutations in component proteins. Outcomes of these perturbations should be predictable in terms of downstream response, otherwise a holistic interpretation of biological processes or disease states cannot be obtained. Two single, proximal point mutations (S252W and P253R) in the extracellular region of FGFR2 (fibroblast growth factor receptor 2) prolong growth factor engagement resulting in dramatically different intracellular phenotypes. Following ligand stimulation, the wild-type receptor undergoes rapid endocytosis into lysosomes, whereas (SW)FGFR2 (the S252W FGFR2 point mutation) and (PR)FGFR2 (the P253R FGFR2 point mutation) remain on the cell membrane for an extended period of time, modifying protein recruitment and elevating downstream ERK (extracellular-signal-regulated kinase) phosphorylation. FLIM (fluorescent lifetime imaging microscopy) reveals that direct interaction of FRS2 (FGFR substrate 2) with wild-type receptor occurs primarily at the vesicular membrane, whereas the interaction with the P253R receptor occurs exclusively at the plasma membrane. These observations suggest that the altered FRS2 recruitment by the mutant receptors results in an abnormal cellular signalling mechanism. In the present study these profound intracellular phenotypes resulting from extracellular receptor modification reveal a new level of complexity which will challenge a systems biology interpretation.

Grb2 controls phosphorylation of FGFR2 by inhibiting receptor kinase and Shp2 phosphatase activity

Grb2 inhibits the kinase activity of FGFR2 and the phosphatase activity of Shp2 to maintain homeostasis of receptor phosphorylation in the nonstimulated state.

Competition between Grb2 and Plcγ1 for FGFR2 regulates basal phospholipase activity and invasion

FGFR2-expressing human cancer cells with low concentrations of the adaptor protein Grb2 show high prevalence for metastatic outcome. In nonstimulated cells, the SH3 domain (and not the SH2 domains) of Plcγ1 directly competes for a binding site at the very C terminus of FGFR2 with the C-terminal SH3 domain of Grb2. Reduction of Grb2 concentration permits Plcγ1 access to the receptor. Recruitment of Plcγ1 in this way is sufficient to upregulate phospholipase activity. This results in elevated phosphatidylinositol 4,5-bisphosphate turnover and intracellular calcium levels, thus leading to increased cell motility and promotion of cell-invasive behavior in the absence of extracellular receptor stimulation. Therefore, metastatic outcome can be dictated by the constitutive competition between Grb2 and Plcγ1 for the phosphorylation-independent binding site on FGFR2.

Direct binding of Grb2 SH3 domain to FGFR2 regulates SHP2 function

The adaptor protein Grb2 is recruited to intracellular early signalling complexes of many receptor tyrosine kinases and plays an important role transducing signals leading to MAP kinase activation. To date the SH2 domain of Grb2 has been shown to mediate receptor interactions with phosphorylated tyrosine residues sited directly on the receptor or on auxiliary docking proteins. Here we report that FGFR2 recruits Grb2 through its C-terminal SH3 domain. The binding site of this domain was mapped to the proline-rich C-terminus of the receptor. Deletion of the last 10 amino acids of FGFR2 abrogates interaction with Grb2. Synthetic peptides based on the C-terminus of FGFR2 bind to full length Grb2 with low micromolar affinity. The function of this novel mode of Grb2 binding provides resistance to site-specific Shp2-mediated receptor dephosphorylation.

A novel dual kinase function of the RET proto-oncogene negatively regulates activating transcription factor 4-mediated apoptosis.

Background: Activating mutations of the receptor tyrosine kinase RET are associated with oncogenic function in medullary thyroid cancer. Results: RET is a dual specificity kinase, phosphorylates ATF4, and inhibits expression of the ATF4 target proapoptotic genes. Conclusion: RET prevents apoptosis through inhibition of ATF4 activity. Significance: Simultaneous targeting of RET and ATF4 may provide clinical benefit in cancers with RET abnormalities. The RET proto-oncogene, a tyrosine kinase receptor, is widely known for its essential role in cell survival. Germ line missense mutations, which give rise to constitutively active oncogenic RET, were found to cause multiple endocrine neoplasia type 2, a dominant inherited cancer syndrome that affects neuroendocrine organs. However, the mechanisms by which RET promotes cell survival and prevents cell death remain elusive. We demonstrate that in addition to cytoplasmic localization, RET is localized in the nucleus and functions as a tyrosine-threonine dual specificity kinase. Knockdown of RET by shRNA in medullary thyroid cancer-derived cells stimulated expression of activating transcription factor 4 (ATF4), a master transcription factor for stress-induced apoptosis, through activation of its target proapoptotic genes NOXA and PUMA. RET knockdown also increased sensitivity to cisplatin-induced apoptosis. We observed that RET physically interacted with and phosphorylated ATF4 at tyrosine and threonine residues. Indeed, RET kinase activity was required to inhibit the ATF4-dependent activation of the NOXA gene because the site-specific substitution mutations that block threonine phosphorylation increased ATF4 stability and activated its targets NOXA and PUMA. Moreover, chromatin immunoprecipitation assays revealed that ATF4 occupancy increased at the NOXA promoter in TT cells treated with tyrosine kinase inhibitors or the ATF4 inducer eeyarestatin as well as in RET-depleted TT cells. Together these findings reveal RET as a novel dual kinase with nuclear localization and provide mechanisms by which RET represses the proapoptotic genes through direct interaction with and phosphorylation-dependent inactivation of ATF4 during the pathogenesis of medullary thyroid cancer.

Extracellular point mutations in FGFR2 result in elevated ERK1/2 activation and perturbation of neuronal differentiation

Two independent gain-of-function point mutations (S252W and P253R) in the extracellular region of the FGFR2 (fibroblast growth factor receptor 2) increase the binding affinity for the growth factor. The effect of this enhanced growth factor binding by these mutants is expected to be an increase in activation of regular signalling pathways from FGFR2 as a result of more receptors being engaged by ligand at any given time. Using PC12 (pheochromocytoma) cells as a model cell system we investigated the effect of these mutations on protein phosphorylation including the receptor, the activation of downstream signalling pathways and cell differentiation. Our results show that the effects of both of these extracellular mutations have unexpected intracellular phenotypes and cellular responses. Receptor phosphorylation was altered in both the ligand-stimulated and unstimulated states. The mutants also resulted in differential phosphorylation of a number of intracellular proteins. Both mutations resulted in enhanced ERK1/2 (extracellular-signalregulated kinase1/2) activation. Although ERK1/2 activation is believed to transduce signals resulting in cell differentiation, this response was abrogated in the cells expressing the mutant receptors. The results of the present study demonstrate that single extracellular point mutations in the FGFR2 have a profound effect on intracellular signalling and ultimately on cell fate.

Interaction with Shc prevents aberrant Erk activation in the absence of extracellular stimuli.

Control mechanisms that prevent aberrant signaling are necessary to maintain cellular homeostasis. We describe a new mechanism by which the adaptor protein Shc directly binds the MAP kinase Erk, thus preventing its activation in the absence of extracellular stimuli. The Shc–Erk complex restricts Erk nuclear translocation, restraining Erk-dependent transcription of genes, including those responsible for oncogenic growth. The complex forms through unique binding sites on both the Shc PTB domain and the N-terminal lobe of Erk. Upon receptor tyrosine kinase stimulation, a conformational change within Shc—induced through interaction with the phosphorylated receptor—releases Erk, allowing it to fulfill its role in signaling. Thus, in addition to its established role in promoting MAP kinase signaling in stimulated cells, Shc negatively regulates Erk activation in the absence of growth factors and thus could be considered a tumor suppressor in human cells.

Grb2 monomer–dimer equilibrium determines normal versus oncogenic function

The adaptor protein growth factor receptor-bound protein 2 (Grb2) is ubiquitously expressed in eukaryotic cells and involved in a multitude of intracellular protein interactions. Grb2 plays a pivotal role in tyrosine kinase-mediated signal transduction including linking receptor tyrosine kinases to the Ras/mitogen-activated protein (MAP) kinase pathway, which is implicated in oncogenic outcome. Grb2 exists in a constitutive equilibrium between monomeric and dimeric states. Here we show that only monomeric Grb2 is capable of binding to SOS and upregulating MAP kinase signalling and that the dimeric state is inhibitory to this process. Phosphorylation of tyrosine 160 (Y160) on Grb2, or binding of a tyrosylphosphate-containing ligand to the SH2 domain of Grb2, results in dimer dissociation. Phosphorylation of Y160 on Grb2 is readily detectable in the malignant forms of human prostate, colon and breast cancers. The self-association/dissociation of Grb2 represents a switch that regulates MAP kinase activity and hence controls cancer progression.