BackgroundReceptor tyrosine kinases (RTKs) participate in a multitude of signaling pathways, some of them via the small G-protein Ras. An important component in the activation of Ras is Son of sevenless (SOS), which catalyzes the nucleotide exchange on Ras.Principal FindingsWe can now demonstrate that the activation of Ras requires, in addition, the essential participation of ezrin, radixin and/or moesin (ERM), a family of actin-binding proteins, and of actin. Disrupting either the interaction of the ERM proteins with co-receptors, down-regulation of ERM proteins by siRNA, expression of dominant-negative mutants of the ERM proteins or disruption of F-actin, abolishes growth factor-induced Ras activation. Ezrin/actin catalyzes the formation of a multiprotein complex consisting of RTK, co-receptor, Grb2, SOS and Ras. We also identify binding sites for both Ras and SOS on ezrin; mutations of these binding sites destroy the interactions and inhibit Ras activation. Finally, we show that the formation of the ezrin-dependent complex is necessary to enhance the catalytic activity of SOS and thereby Ras activation.ConclusionsTaking these findings together, we propose that the ERM proteins are novel scaffolds at the level of SOS activity control, which is relevant for both normal Ras function and dysfunction known to occur in several human cancers.
Spinal cord injury (SCI) results in a pathophysiology characterized by multiple locomotor and sensory deficits, resulting in altered nociception and hyperalgesia. SCI triggers an early and prolonged inflammatory response, with increased interleukin-1beta levels. Transient changes are observed in subunit populations of the transcription factor nuclear factor-kappaB (NF-kappaB). There were decreases in neuronal c-Rel levels and inverse increases in p65 and p50 levels. There were no changes in neuronal p52 or RelB subunits after SCI at any time point tested. Similarly, SCI had no effect on oligodendroglial levels of any NF-kappaB subunit. There were significant early increases in COX-2 and inducible nitric oxide synthase mRNA and protein levels after SCI. We used synthetic double-stranded "decoy" deoxyoligonucleotides containing selective NF-kappaB protein dimer binding consensus sequences. Decoys targeting the p65/p50 binding site on the COX-2 promoter decreased SCI-induced cell losses, NF-kappaB p65/p50 DNA-binding activity, and COX-2 and iNOS protein levels. NF-kappaB p65/p50 targeted decoys improved early locomotor recovery after moderate but not severe SCI, yet ameliorated SCI-induced hypersensitization after both moderate and severe SCI. To determine whether changes in GABA activity played a role in decreased hypersensitivity after SCI and p65/p50 targeted decoy, we counted gamma-aminobutyric acid (GABA)-containing neurons in laminae 1-3. There were significantly more GABAergic neurons in the p65/p50 targeted decoy-treated group at the level of injury.
The neurofibromatosis type 2 gene product merlin is known to provoke gliogenic tumors as a result of its mutagenic loss. Merlin's physiological anti-mitogenic function makes it unique among its ezrin-radixin-moesin (ERM) family members. Although ERM proteins and merlin are known to be expressed in glial cells of the peripheral nervous system and CNS, the neuronal expression pattern and function of merlin have been less well investigated. We report here expression of merlin in developing and mature neurons of the murine CNS. Within cerebellar Purkinje cells (PCs), merlin was localized in the soma, sprouting dendrites and axons. Merlin expression in PCs was high during the period of initial dendrite regression and declined during later phases of dendrite elongation. Consistently, merlin expression in vivo was increased in Engrailed-2-overexpressing PCs, which are characterized by a reduced dendritic extension. Furthermore, overexpression of merlin in dissociated cerebellar cultures and in neurogenic P19 cells caused a significant decline in neurite outgrowth, while, conversely, inhibition of merlin expression increased process formation. This effect was dependent on phosphorylation of serine 518 and involved the inactivation of the growth-promoting GTPase Rac. We thus provide evidence that merlin plays a pivotal role in controlling the neuronal wiring in the developing CNS.
Regulation of Son of sevenless by the membrane-actin linker protein ezrin
Receptor tyrosine kinases participate in several signaling pathways through small G proteins such as Ras (rat sarcoma). An important component in the activation of these G proteins is Son of sevenless (SOS), which catalyzes the nucleotide exchange on Ras. For optimal activity, a second Ras molecule acts as an allosteric activator by binding to a second Ras-binding site within SOS. This allosteric Ras-binding site is blocked by autoinhibitory domains of SOS. We have reported recently that Ras activation also requires the actin-binding proteins ezrin, radixin, and moesin. Here we report the mechanism by which ezrin modulates SOS activity and thereby Ras activation. Active ezrin enhances Ras/MAPK signaling and interacts with both SOS and Ras in vivo and in vitro. Moreover, in vitro kinetic assays with recombinant proteins show that ezrin also is important for the activity of SOS itself. Ezrin interacts with GDP-Ras and with the Dbl homology (DH)/pleckstrin homology (PH) domains of SOS, bringing GDP-Ras to the proximity of the allosteric site of SOS. These actions of ezrin are antagonized by the neurofibromatosis type 2 tumor-suppressor protein merlin. We propose an additional essential step in SOS/Ras control that is relevant for human cancer as well as all physiological processes involving Ras.ERM proteins | autoinhibition | GEF regulation T he small GTPase Ras (rat sarcoma) regulates essential cellular processes such as proliferation, motility, and differentiation. Activation of Ras by receptor tyrosine kinases (RTKs) is mediated by the guanine nucleotide-exchange factor (GEF) Son of sevenless (SOS). SOS is recruited by activated RTKs and subsequently engages Ras. In recent years, however, it has been recognized that this simple activation process is subject to a complex regulation. A number of regulatory motifs on SOS have been identified: the C-terminal catalytic Ras-binding domain for nucleotide exchange (1), the N-terminal half that carries histone-like sequences rich in positively charged amino acids, a Dbl homology (DH) domain, and a pleckstrin homology (PH) domain (1, 2). The DH/PH domains decrease the catalytic activity of SOS by folding back on the catalytic domain, thereby restricting accessibility to a second Ras-binding site that is distinct from the catalytic site (2). This allosteric Ras-binding site is important for the activation of SOS. Thus, Ras itself is an essential determinant of SOS regulation (2). Finally, lipid interaction contributes to the activation of SOS: The positively charged histonelike sequences interact with the negatively charged plasma membrane (3, 4). Moreover, binding of both phosphoinositides to the PH domain (5) and phosphatidic acid (PA) to the histone-like domain enhances SOS activity by relieving autoinhibition and exposing the allosteric Ras-binding site (6-8).Our interest in small GTPases was triggered originally by the observation that members of a family of actin-binding proteinsezrin, radixin, and moesin (ERM)-appear to enhance Ras activity (9). We showed that in re...
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