Literature DB >> 24509905

Cofilin drives cell-invasive and metastatic responses to TGF-β in prostate cancer.

Joanne Collazo1, Beibei Zhu, Spencer Larkin, Sarah K Martin, Hong Pu, Craig Horbinski, Shahriar Koochekpour, Natasha Kyprianou.   

Abstract

Cofilin (CFL) is an F-actin-severing protein required for the cytoskeleton reorganization and filopodia formation, which drives cell migration. CFL binding and severing of F-actin is controlled by Ser3 phosphorylation, but the contributions of this step to cell migration during invasion and metastasis of cancer cells are unclear. In this study, we addressed the question in prostate cancer cells, including the response to TGF-β, a critical regulator of migration. In cells expressing wild-type CFL, TGF-β treatment increased LIMK-2 activity and cofilin phosphorylation, decreasing filopodia formation. Conversely, constitutively active CFL (SerAla) promoted filipodia formation and cell migration mediated by TGF-β. Notably, in cocultures of prostate cancer epithelial cells and cancer-associated fibroblasts, active CFL promoted invasive migration in response to TGF-β in the microenvironment. Further, constitutively active CFL elevated the metastatic ability of prostate cancer cells in vivo. We found that levels of active CFL correlated with metastasis in a mouse model of prostate tumor and that in human prostate cancer, CFL expression was increased significantly in metastatic tumors. Our findings show that the actin-severing protein CFL coordinates responses to TGF-β that are needed for invasive cancer migration and metastasis. ©2014 AACR.

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Year:  2014        PMID: 24509905      PMCID: PMC4488067          DOI: 10.1158/0008-5472.CAN-13-3058

Source DB:  PubMed          Journal:  Cancer Res        ISSN: 0008-5472            Impact factor:   12.701


  49 in total

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Review 2.  Apoptosis evasion: the role of survival pathways in prostate cancer progression and therapeutic resistance.

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Review 3.  The great escape: when cancer cells hijack the genes for chemotaxis and motility.

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Journal:  Nat Med       Date:  1998-09       Impact factor: 53.440

6.  Actin-depolymerizing factor and cofilin-1 play overlapping roles in promoting rapid F-actin depolymerization in mammalian nonmuscle cells.

Authors:  Pirta Hotulainen; Eija Paunola; Maria K Vartiainen; Pekka Lappalainen
Journal:  Mol Biol Cell       Date:  2004-11-17       Impact factor: 4.138

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8.  Cofilin overexpression affects actin cytoskeleton organization and migration of human colon adenocarcinoma cells.

Authors:  Agnieszka Popow-Woźniak; Antonina Joanna Mazur; Hans Georg Mannherz; Maria Malicka-Błaszkiewicz; Dorota Nowak
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9.  The activity status of cofilin is directly related to invasion, intravasation, and metastasis of mammary tumors.

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10.  A co-clinical approach identifies mechanisms and potential therapies for androgen deprivation resistance in prostate cancer.

Authors:  Andrea Lunardi; Ugo Ala; Mirjam T Epping; Leonardo Salmena; John G Clohessy; Kaitlyn A Webster; Guocan Wang; Roberta Mazzucchelli; Maristella Bianconi; Edward C Stack; Rosina Lis; Akash Patnaik; Lewis C Cantley; Glenn Bubley; Carlos Cordon-Cardo; William L Gerald; Rodolfo Montironi; Sabina Signoretti; Massimo Loda; Caterina Nardella; Pier Paolo Pandolfi
Journal:  Nat Genet       Date:  2013-06-02       Impact factor: 38.330
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  41 in total

Review 1.  The role of phosphoinositide-regulated actin reorganization in chemotaxis and cell migration.

Authors:  C-Y Wu; M-W Lin; D-C Wu; Y-B Huang; H-T Huang; C-L Chen
Journal:  Br J Pharmacol       Date:  2014-11-24       Impact factor: 8.739

2.  Association of epithelial-mesenchymal transition and nuclear cofilin with advanced urothelial cancer.

Authors:  Patrick J Hensley; Daniel Zetter; Craig M Horbinski; Stephen E Strup; Natasha Kyprianou
Journal:  Hum Pathol       Date:  2016-07-08       Impact factor: 3.466

3.  Phosphorylation of cofilin-1 by ERK confers HDAC inhibitor resistance in hepatocellular carcinoma cells via decreased ROS-mediated mitochondria injury.

Authors:  P-H Liao; H-H Hsu; T-S Chen; M-C Chen; C-H Day; C-C Tu; Y-M Lin; F-J Tsai; W-W Kuo; C-Y Huang
Journal:  Oncogene       Date:  2016-10-17       Impact factor: 9.867

4.  TGFβ promotes mesenchymal phenotype of pancreatic cancer cells, in part, through epigenetic activation of VAV1.

Authors:  P-H Huang; P-J Lu; L-Y Ding; P-C Chu; W-Y Hsu; C-S Chen; C-C Tsao; B-H Chen; C-T Lee; Y-S Shan; C-S Chen
Journal:  Oncogene       Date:  2016-11-28       Impact factor: 9.867

5.  The Actin-Binding Protein Drebrin Inhibits Neointimal Hyperplasia.

Authors:  Jonathan A Stiber; Jiao-Hui Wu; Lisheng Zhang; Igor Nepliouev; Zhu-Shan Zhang; Victoria G Bryson; Leigh Brian; Rex C Bentley; Phillip R Gordon-Weeks; Paul B Rosenberg; Neil J Freedman
Journal:  Arterioscler Thromb Vasc Biol       Date:  2016-03-24       Impact factor: 8.311

6.  Aberrant TGF-β Signaling Drives Castration-Resistant Prostate Cancer in a Male Mouse Model of Prostate Tumorigenesis.

Authors:  Hong Pu; Diane E Begemann; Natasha Kyprianou
Journal:  Endocrinology       Date:  2017-06-01       Impact factor: 4.736

7.  Integrated Therapeutic Targeting of the Prostate Tumor Microenvironment.

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Review 8.  Synergistic immunologic targets for the treatment of prostate cancer.

Authors:  Karen M Doersch; Kelvin A Moses; Warren E Zimmer
Journal:  Exp Biol Med (Maywood)       Date:  2016-07-20

9.  TGF-β Effects on Prostate Cancer Cell Migration and Invasion Require FosB.

Authors:  Cachétne S X Barrett; Ana C Millena; Shafiq A Khan
Journal:  Prostate       Date:  2016-09-07       Impact factor: 4.104

10.  Rho GTPases RhoA and Rac1 mediate effects of dietary folate on metastatic potential of A549 cancer cells through the control of cofilin phosphorylation.

Authors:  Natalia V Oleinik; Kristi L Helke; Emily Kistner-Griffin; Natalia I Krupenko; Sergey A Krupenko
Journal:  J Biol Chem       Date:  2014-08-01       Impact factor: 5.157
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