WASP family members and formin proteins coordinate regulation of cell protrusions in carcinoma cells

Sarmiento, Corina; Wang, Weigang; Dovas, Athanassios; Yamaguchi, Hideki; Sidani, Mazen; El‐Sibai, Mirvat; DesMarais, Vera; Holman, Holly A.; Kitchen, Susan M.; Backer, Jonathan M.; Alberts, Art; Condeelis, John S.

doi:10.1083/jcb.200708123

Cited by 124 publications

(130 citation statements)

References 53 publications

(106 reference statements)

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“…Furthermore, if the convergent elongation model was physiologically relevant, one would expect an interference with the process by removal of lamellipodia, as previously proposed (Biyasheva et al, 2004). Although a more recent study has reaffirmed this conclusion in neurons (Korobova and Svitkina, 2008), several independent studies have continuously failed to establish a defect in filopodia initiation and protrusion effected by suppression of lamellipodia (Gomez et al, 2007, Nicholson-Dykstra and Higgs, 2008, Nobes and Hall, 1995, Sarmiento et al, 2008, Vidali et al, 2006. These and similar conflicting observations have prompted researchers to propose different "types" of filopodia, or distinct, cell-type-dependent mechanisms of filopodium formation (see e.g.…”

Section: Models For Filament Generation In Filopodia: Convergent Elonmentioning

confidence: 84%

“…However, more recent observations indicated that this assumption was preliminary . For instance, neither N-WASP, a direct Cdc42-effector and activator of the actin nucleating machine Arp2/3-complex (Stradal et al, 2004) nor Arp2/3-complex itself turned out to be essential for filopodia formation (Gomez et al, 2007, Lommel et al, 2001, Nicholson-Dykstra and Higgs, 2008, Sarmiento et al, 2008. However, conflicting studies reported filopodia reduction (but not removal) upon Arp2/3-complex silencing (Korobova and Svitkina, 2008) or N-WASP deletion (Snapper et al, 2001).…”

Section: Rho-gtpasesmentioning

confidence: 91%

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Filopodia: Complex models for simple rods

Faix

Breitsprecher

Stradal

et al. 2009

The International Journal of Biochemistry & Cell Biology

153

148

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CitationFilopodia: Complex models for simple rods., 41 (8- AbstractFilopodia are prominent cell surface protrusions filled with bundles of linear actin filaments that drive their protrusion. These structures are considered important sensory organelles, for instance in neuronal growth cones or during the fusion of sheets of epithelial tissues. In addition, they can serve a precursor function in adhesion site or stress fibre formation. Actin filament assembly is essential for filopodia formation and turnover, yet the precise molecular mechanisms of filament nucleation and/or elongation are controversial. Indeed, conflicting reports on the molecular requirements of filopodia initiation have prompted researchers to propose different types and/or alternative or redundant mechanisms mediating this process.However, recent data shed new light on these questions, and they indicate that the balance of a limited set of biochemical activities can determine the structural outcome of a given filopodium. Here we focus on discussing our current view of the relevance of these activities, and attempt to propose a molecular mechanism of filopodia assembly based on a single core machinery.2

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Section: Models For Filament Generation In Filopodia: Convergent Elonmentioning

confidence: 84%

Section: Rho-gtpasesmentioning

confidence: 91%

Filopodia: Complex models for simple rods

Faix

Breitsprecher

Stradal

et al. 2009

The International Journal of Biochemistry & Cell Biology

153

148

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“…In neuronal cells, RhoA activity is necessary for the formation of filopodial protrusion induced by RhoA/ROCK signaling (Chen et al, 2006;Kim et al, 2010). Furthermore, activation of mammalian diaphanous-related formin (mDia), which is known as an effector of RhoA, localizes at the filopodia, promotes actin filament assembly and contributes to filopodia formation (Faix and Grosse, 2006;Carramusa et al, 2007;Sarmiento et al, 2008). Therefore, ARAP3 may suppress the cell adhesion, migration and invasion of cancer cells by inhibiting RhoA signaling through its Rho-GAP domain.…”

Section: Discussionmentioning

confidence: 99%

ARAP3 inhibits peritoneal dissemination of scirrhous gastric carcinoma cells by regulating cell adhesion and invasion

Yagi¹,

Tanaka

Sasaki

et al. 2010

Oncogene

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During the analysis of phosphotyrosine-containing proteins in scirrhous gastric carcinoma cell lines, we observed an unusual expression of Arf-GAP with Rho-GAP domain, ankyrin repeat and PH domain 3 (ARAP3), a multimodular signaling protein that is a substrate of Src family kinases. Unlike other phosphotyrosine proteins, such as CUB domain-containing protein 1 (CDCP1) and Homo sapiens chromosome 9 open reading frame 10/ oxidative stress-associated Src activator (C9orf10/Ossa), which are overexpressed and hyperphosphorylated in scirrhous gastric carcinoma cell lines, ARAP3 was underexpressed in cancerous human gastric tissues. In this study, we found that overexpression of ARAP3 in the scirrhous gastric carcinoma cell lines significantly reduced peritoneal dissemination. In vitro studies also showed that ARAP3 regulated cell attachment to the extracellular matrix, as well as invasive activities. These effects were suppressed by mutations in the Rho-GTPase-activating protein (GAP) domain or in the C-terminal two tyrosine residues that are phosphorylated by Src. Thus, the expression and phosphorylation state of ARAP3 may affect the invasiveness of cancer by modulating cell adhesion and motility. Our results suggest that ARAP3 is a unique Src substrate that suppresses peritoneal dissemination of scirrhous gastric carcinoma cells.

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“…45 For example, RhoA is required for mDIA1-induced filopodia at the front of N-WASP/WAVEdepleted carcinoma cells. 37 Whilst it is not possible to look at the formation of filopodia during TEM in RhoA-depleted T cells as these cells do not initiate TEM, it would be interesting to examine whether proteins involved in filopodium formation in other cell types, such as vasodilator-stimulated phospho-protein (VASP), fascin, insulin receptor substrate p53 (IRSp53) and myosin X, 47 localize to the structures we observe in transmigrating T cells. The mDIA proteins are likely…”

Section: A Possible Role Of Rhoa In Filopodia During T Cell Temmentioning

confidence: 99%

“…33,34 Interestingly WiskottAldrich syndrome protein (WASP) 35 and mDIA1 co-operate at the leading edge during neutrophil migration. 36 The balance of activity between N-WASP, WASP family Verprolin homologous (WAVE) proteins and formins has also been shown to regulate the type of actin filament structures that are formed at the leading edge of carcinoma cells, 37 suggesting a complex interplay between these different actin regulators. It is thus possible that RhoA and Rac2 activate different actin regulators at the front of T cells that act together to induce lamellipodial protrusion.…”

Section: Rhoa Is Required For Lamellipodium and Uropod Formation In Tmentioning

confidence: 99%

Multiple roles for RhoA during T cell transendothelial migration

Heasman

Ridley

2010

Small GTPases

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t cells need to cross endothelial barriers during immune surveillance and inflammation. this involves t-cell adhesion to the endothelium followed by polarization and crawling with a lamellipodium at the front and contractile uropod at the back. t cells subsequently extend lamellipodia and filopodia under the endothelium in order to transmigrate. rho Gtpases play key roles in cell migration by regulating cytoskeletal dynamics and cell adhesion. we have found that the rho Gtpase rhoa is required for efficient t-cell polarization and migration on endothelial cells as well as transendothelial migration. rhoa-depleted cells lack both lamellipodia and uropods, and instead have narrow protrusions extending from a rounded cell body. using a rhoa activity biosensor, we have shown that rhoa is active at the leading edge in lamellipodia and filopodia of crawling and transmigrating t cells, as well as in the uropod. in lamellipodia, its activity correlates with both protrusion and retraction. we predict that rhoa signals via the formin mdia1 during lamellipodial protrusion whereas it induces lamellipodial retraction via the kinase rocK and actomyosin contractility. we propose that different guanine-nucleotide exchange factors (GEfs) are responsible for coordinating rhoa activation and signaling in different regions of transmigrating t cells. IntroductionDuring inflammation leukocytes are recruited from the vasculature into tissues using a specialized migratory pathway. Rho GTPase family proteins are key regulators of cytoskeletal dynamics and cell migration, 3 and thus would be expected to contribute to the process of TEM. Most Rho GTPases cycle between an inactive, GDP-bound form and an active, GTP-bound form, which interacts with and activates downstream targets. Rho GTPases are stimulated by guanine nucleotide exchange factors (GEFs), which stimulate exchange of GDP for GTP and inactivated by GTPaseactivating proteins (GAPs), which stimulate GTP hydrolysis.In our recent paper we used an RNAi screen to identify which Rho GTPases are important for T cell TEM. 4 We found that knockdown of RhoA induced the strongest inhibition of this process and so subsequently examined the role of RhoA in detail during both T cell crawling on EC and subsequent TEM. Significantly, active RhoA was observed at both the front and back of polarized T cells as they crawled on EC and transmigrated, as well as in dynamic puncta in the basal membrane and filopodia extending beneath the endothelium of transmigrating cells ( fig. 1). Here we discuss the implications of these findings in the context of current understanding of RhoA signaling and the potential function of these cellular processes in T-cell migration. Extra View to: Heasman SJ, Carlin LM, Cox S, Ng T, Ridley AJ. Coordinated RhoA signaling at the leading edge and uropod is required for T cell transendothelial migration.

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WASP family members and formin proteins coordinate regulation of cell protrusions in carcinoma cells

Cited by 124 publications

References 53 publications

Filopodia: Complex models for simple rods

Filopodia: Complex models for simple rods

ARAP3 inhibits peritoneal dissemination of scirrhous gastric carcinoma cells by regulating cell adhesion and invasion

Multiple roles for RhoA during T cell transendothelial migration

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