Eph receptors transduce short-range repulsive signals for axon guidance by modulating actin dynamics within growth cones. We report the cloning and characterization of ephexin, a novel Eph receptor-interacting protein that is a member of the Dbl family of guanine nucleotide exchange factors (GEFs) for Rho GTPases. Ephrin-A stimulation of EphA receptors modulates the activity of ephexin leading to RhoA activation, Cdc42 and Rac1 inhibition, and cell morphology changes. In addition, expression of a mutant form of ephexin in primary neurons interferes with ephrin-A-induced growth cone collapse. The association of ephexin with Eph receptors constitutes a molecular link between Eph receptors and the actin cytoskeleton and provides a novel mechanism for achieving highly localized regulation of growth cone motility.
The ras-like GTP binding proteins cdc42, rac, and rho regulate diverse cellular processes including cell growth and actin remodeling associated with changes in cell morphology, growth, adhesion, and motility (1-4). In fibroblasts, cdc42 regulates actin polymerization and focal complexes necessary for filopodia formation, rac mediates actin polymerization and focal complex assembly within lamellipodia and membrane ruffles, and rho induces actin stress fiber and focal adhesion (FA) complex formation (5). A hierarchical relationship exists among cdc42, rac, and rho, whereby cdc42 regulates rac activity and rac regulates rho activity, suggesting that these proteins may orchestrate the spatial and temporal changes in the actin cytoskeleton necessary for cell movement (5, 6). cdc42 and rac also regulate activation of the c-Jun N-terminal kinase/stressactivated kinase via a mitogen-activated protein (MAP) kinase pathway (7-9), and rac and rho are essential for ras transformation (10, 11). cdc42, rho, and rac all appear to stimulate c-fos transcription (12), as well as cell cycle progression through GI and subsequent DNA synthesis (9). The activation state of ras-like GTP binding proteins is positively regulated by guanine nucleotide exchange factors (GEFs) that promote the exchange of GDP for GTP, and negatively by GTPase activating proteins (2). A number of putative GEFs for rho-like GTPases have been identified by sequence comparison (2), and several of these demonstrate GEF activity in vitro. The dbl and ost oncogene products have cdc42 and rho GEF activity (13-15); the lbc oncogene product has rho GEF activity (16); the invasion-inducing Tiaml gene product has cdc42, rho, and rac GEF activity (17); and the yeast CDC24 gene product has cdc42 GEF activity (18). LAR is a broadly expressed transmembrane protein tyrosine phosphatase (PTPase) comprised of a cell adhesion-like extracellular region and two intracellular PTPase domains (19)(20)(21)(22). A role for LAR in regulating cell-matrix interactions was proposed, as LAR colocalizes with a coiled-coil protein, termed LAR interacting protein 1 (LIP.1) at the ends of FAs (23), and LAR expression was observed at regions of association between cells and basement membrane in various tissues (19). To identify putative substrates and other proteins involved in LAR-mediated signal transduction, we screened for proteins that bind the LAR PTPase domains using the interaction-trap assay and coimmunoprecipitation studies. A protein thus isolated is a novel multidomain GEF we have named Trio because it contains three enzyme domains: two GEF domains, one of which has racl GEF activity and the other has rhoA GEF activity, and a serine/threonine kinase (PSK) domain. In addition, Trio contains four N-terminal spectrinlike domains, two pleckstrin-like domains, and an Ig-like domain. Because proteins with cdc42, rac, or rho GEF activity are generally involved in regulating cytoskeletal organization (1), it is likely that Trio in conjunction with LAR plays a key role in coordinating the ...
Focal adhesions are sites of cell‐extracellular matrix interactions that function in anchoring stress fibers to the plasma membrane and in adhesion‐mediated signal transduction. Both focal adhesion structure and signaling ability involve protein tyrosine phosphorylation. LAR is a broadly expressed transmembrane protein tyrosine phosphatase comprised of a cell adhesion‐like ectodomain and two intracellular protein tyrosine phosphatase domains. We have identified a novel cytoplasmic 160 kDa phosphoserine protein termed LAR‐interacting protein 1 (LIP.1), which binds to the LAR membrane‐distal D2 protein tyrosine phosphatase domain and appears to localize LAR to focal adhesions. Both LAR and LIP.1 decorate the ends of focal adhesions most proximal to the cell nucleus and are excluded from the distal ends of focal adhesions, thus localizing to regions of focal adhesions presumably undergoing disassembly. We propose that LAR and LIP.1 may regulate the disassembly of focal adhesions and thus help orchestrate cell‐matrix interactions.
Correct pathfinding by Drosophila photoreceptor axons requires recruitment of p21-activated kinase (Pak) to the membrane by the SH2-SH3 adaptor Dock. Here, we identify the guanine nucleotide exchange factor (GEF) Trio as another essential component in photoreceptor axon guidance. Regulated exchange activity of one of the two Trio GEF domains is critical for accurate pathfinding. This GEF domain activates Rac, which in turn activates Pak. Mutations in trio result in projection defects similar to those observed in both Pak and dock mutants, and trio interacts genetically with Rac, Pak, and dock. These data define a signaling pathway from Trio to Rac to Pak that links guidance receptors to the growth cone cytoskeleton. We propose that distinct signals transduced via Trio and Dock act combinatorially to activate Pak in spatially restricted domains within the growth cone, thereby controlling the direction of axon extension.
Ephs regulate growth cone repulsion, a process controlled by the actin cytoskeleton. The guanine nucleotide exchange factor (GEF) ephexin1 interacts with EphA4 and has been suggested to mediate the effect of EphA on the activity of Rho GTPases, key regulators of the cytoskeleton and axon guidance. Using cultured ephexin1-/- mouse neurons and RNA interference in the chick, we report that ephexin1 is required for normal axon outgrowth and ephrin-dependent axon repulsion. Ephexin1 becomes tyrosine phosphorylated in response to EphA signaling in neurons, and this phosphorylation event is required for growth cone collapse. Tyrosine phosphorylation of ephexin1 enhances ephexin1's GEF activity toward RhoA while not altering its activity toward Rac1 or Cdc42, thus changing the balance of GTPase activities. These findings reveal that ephexin1 plays a role in axon guidance and is regulated by a switch mechanism that is specifically tailored to control Eph-mediated growth cone collapse.
Rho-GTPases control a wide range of physiological processes by regulating actin cytoskeleton dynamics. Numerous studies on neuronal cell lines have established that Rac, Cdc42, and RhoG activate neurite extension, while RhoA mediates neurite retraction. Guanine nucleotide exchange factors (GEFs) activate Rho-GTPases by accelerating GDP/GTP exchange. Trio displays two Rho-GEF domains, GEFD1, activating the Rac pathway via RhoG, and GEFD2, acting on RhoA, and contains numerous signaling motifs whose contribution to Trio function has not yet been investigated. Genetic analyses in Drosophila and in Caenorhabditis elegans indicate that Trio is involved in axon guidance and cell motility via a GEFD1-dependent process, suggesting that the activity of its Rho-GEFs is strictly regulated. Here, we show that human Trio induces neurite outgrowth in PC12 cells in a GEFD1-dependent manner. Interestingly, the spectrin repeats and the SH3-1 domain of Trio are essential for GEFD1-mediated neurite outgrowth, revealing an unexpected role for these motifs in Trio function. Moreover, we demonstrate that Trio-induced neurite outgrowth is mediated by the GEFD1-dependent activation of RhoG, previously shown to be part of the NGF (nerve growth factor) pathway. The expression of different Trio mutants interferes with NGF-induced neurite outgrowth, suggesting that Trio may be an upstream regulator of RhoG in this pathway. In addition, we show that Trio protein accumulates under NGF stimulation. Thus, Trio is the first identified Rho-GEF involved in the NGF-differentiation signaling.
Rho GTPases control actin reorganization and many other cellular functions. Guanine nucleotide-exchange factors (GEFs) activate Rho GTPases by promoting their exchange of GDP for GTP. Trio is a unique Rho GEF, because it has separate GEF domains, GEFD1 and GEFD2, that control the GTPases RhoG/Rac1 and RhoA, respectively. Dbl-homology (DH) domains that are common to GEFs catalyse nucleotide exchange, and pleckstrin-homology (PH) domains localize Rho GEFs near their downstream targets. Here we show that Trio GEFD1 interacts through its PH domain with the actin-filament-crosslinking protein filamin, and localizes with endogenous filamin in HeLa cells. Trio GEFD1 induces actin-based ruffling in filamin-expressing, but not filamin-deficient, cells and in cells transfected with a filamin construct that lacks the Trio-binding domain. In addition, Trio GEFD1 exchange activity is not affected by filamin binding. Our results indicate that filamin, as a molecular target of Trio, may be a scaffold for the spatial organization of Rho-GTPase-mediated signalling pathways.
The chemotropic guidance cue netrin-1 promotes neurite outgrowth through its receptor Deleted in Colorectal Cancer (DCC) via activation of Rac1. The guanine nucleotide exchange factor (GEF) linking netrin-1/ DCC to Rac1 activation has not yet been identified. Here, we show that the RhoGEF Trio mediates Rac1 activation in netrin-1 signaling. We found that Trio interacts with the netrin-1 receptor DCC in mouse embryonic brains and that netrin-1-induced Rac1 activation in brain is impaired in the absence of Trio. Trio ؊/؊ cortical neurons fail to extend neurites in response to netrin-1, while they are able to respond to glutamate. Accordingly, netrin-1-induced commissural axon outgrowth is reduced in Trio ؊/؊ spinal cord explants, and the guidance of commissural axons toward the floor plate is affected by the absence of Trio. The anterior commissure is absent in Trio-null embryos, and netrin-1/DCC-dependent axonal projections that form the internal capsule and the corpus callosum are defective in the mutants. Taken together, these findings establish Trio as a GEF that mediates netrin-1 signaling in axon outgrowth and guidance through its ability to activate Rac1.During the development of the central nervous system, axons are guided to their targets in response to molecular cues that can be either membrane-bound factors or secreted molecules, acting over short or long distances. The neuronal growth cone is a specialized structure found at the tip of the axon that integrates attractive and repulsive signals elicited by these extracellular cues and responds to them by triggering signaling pathways that regulate growth cone motility (16,18). Netrins are a family of secreted proteins that control axon outgrowth and guidance in multiple vertebrate and invertebrate species (3). Netrin-1 is a bifunctional molecule that attracts and repels different classes of axons. In vertebrates, netrin-1 was first shown to attract commissural axons of the developing spinal cord toward the ventral midline (21, 44). Since then, netrin-1 has been shown to promote outgrowth of a wide variety of axons, including growing cortical axons (30, 41). Two families of netrin-1 receptors in mammals have been identified: the Deleted in Colorectal Cancer (DCC) family, comprising DCC and neogenin, and the UNC-5 family of proteins (1,20,25). DCC mediates growth cone attraction induced by netrin-1 (1, 20, 25, 43) whereas the repulsive effect of netrin-1 is mediated by the UNC-5 family of netrin receptors, alone or in combination with DCC (17,22,35).DCC is a transmembrane protein without any obvious catalytic activity in its intracellular domain, and for this reason, it was unclear until recently how the intracellular signaling machinery leading to axon outgrowth was initiated. This process has begun to be elucidated with the identification in cortical and commissural neurons of different DCC-binding proteins, including the protein tyrosine kinases focal adhesion kinase, Src, and Fyn; the Nck adaptor protein; and phosphatidylinositol transfer protein ␣ (26...
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