7 research outputs found

    Identification of the first Rho–GEF inhibitor, TRIPα, which targets the RhoA-specific GEF domain of Trio

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    AbstractThe Rho–guanine nucleotide exchange factors (Rho–GEFs) remodel the actin cytoskeleton via their Rho–GTPase targets and affect numerous physiological processes such as transformation and cell motility. They are therefore attractive targets to design specific inhibitors that may have therapeutic applications. Trio contains two Rho–GEF domains, GEFD1 and GEFD2, which activate the Rac and RhoA pathways, respectively. Here we have used a genetic screen in yeast to select in vivo peptides coupled to thioredoxin, called aptamers, that could inhibit GEFD2 activity. One aptamer, TRIAPα (TRio Inhibitory APtamer), specifically blocks GEFD2-exchange activity on RhoA in vitro. The corresponding peptide sequence, TRIPα, inhibits TrioGEFD2-mediated activation of RhoA in intact cells and specifically reverts the neurite retraction phenotype induced by TrioGEFD2 in PC12 cells. Thus TRIPα is the first Rho–GEF inhibitor isolated so far, and represents an important step in the design of inhibitors for the expanding family of Rho–GEFs

    The Human Rho-GEF Trio and Its Target GTPase RhoG Are Involved in the NGF Pathway, Leading to Neurite Outgrowth

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    International audienceRho-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

    Trio : Un facteur d’échange des GTPases Rho aux multiples facettes impliqué dans le guidage axonal

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    Les facteurs d’échanges nucléotidiques (GEF) des GTPases Rho remodèlent le cytosquelette d’actine en activant leurs cibles, les GTPases Rho, et sont ainsi impliqués dans de nombreux processus physiologiques. Trio est le premier membre dune famille de protéines multifonctionnelles possédant deux domaines fonctionnels d’échange dont la spécificité est différente, le premier activant Rac et le second RhoA. Trio possède aussi de nombreux domaines d’interaction protéine-protéine, et semble donc se situer à un carrefour de différentes voies de signalisation. La liaison de Trio avec des protéines qui lient l’actine, suggère en outre que l’activation des GTPases par Trio est contrôlée par sa localisation spécifique près du cytosquelette. De plus, l’identification d’orthologues de Trio chez les invertébrés a permis de proposer une fonction essentielle de Trio dans le guidage axonal

    Structural Organization and Chromosomal Localization of a Human Gene (HIP/PAP) Encoding a C-type Lectin Overexpressed in Primary Liver Cancer

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    International audienceWe previously identified, through differential screening of a human primary liver cancer library, a novel gene (named HIP) the expression of which is markedly increased in 25% of human primary liver cancers. HIP mRNA expression is tissue specific since it is restricted to pancreas and small intestine. HIP protein consists in a signal peptide linked to a carbohydrate-recognition domain (CRD), typical of C-type lectins without other binding domains. We have proposed that HIP and related proteins belong to a new family of C-type lectins. Drickamer [Drickamer, K. (1993) Curr. Opin. Struct. Biol. 3,393-400] included this group of proteins in his classification of C-type lectins as the free CRD (group VII) lectins. In the present report we describe the genomic organization and the chromosomal localization of HIP. We have shown that HIP is in fact the pancreatitis-associated protein (PAP) and provided a phylogenetic analysis of the free CRD lectins. Furthermore, the analysis of HIP/PAP gene indicates that the HIP/PAP CRD is encoded by four exons, a pattern shared with all members of this group of proteins. This common intron-exon organization indicates an ancient divergence of the free CRD-lectin group from other groups of C-type lectins. We provide evidence for the localization of HIP/PAP on chromosome 2, suggesting previous duplication of HIP/PAP and the related reg I alpha and reg I beta genes from the same ancestral gene. Finally, the sequence of the 5' upstream region of the HIP gene shows several potential regulatory elements which might account for the enhanced expression of the gene during pancreatic inflammation and liver carcinogenesis
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