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Molecular characterization of the human actin depolymerizing factorHawkins, Mark G. January 1992 (has links)
No description available.
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Novel roles for matix metalloproteinases in cell-matrix interactionsMessent, Anthea Jane January 1997 (has links)
No description available.
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Structure-function analysis of Tetraspanin CD151Zevian, Shannin Christine 01 May 2011 (has links)
The basement membrane protein laminin-332 (laminin-5) mediates both stable cell adhesion and rapid cell migration, and thus has the potential to either restrain or promote tumor cell metastasis. The major cellular receptors for laminin-332 are integrin α3β1, which mediates rapid tumor cell migration, and integrin α6β4, which often mediates stable cell attachment. Tetraspanin protein CD151 interacts directly with both α3β1 and α6β4 integrins and with other tetraspanins, thereby promoting α3β1 and α6β4 association with tetraspanin-enriched microdomains on the cell surface. To explore the possibility of selectively modulating tumor cell responses to laminin-332, we re-expressed a series of CD151 mutants in epidermoid carcinoma cells with near total, RNAi- mediated silencing of endogenous CD151. CD151's interactions with its integrin partners or its interactions with other tetraspanins were selectively disrupted by specific mutations in the CD151 large extracellular loop (EC2 domain) or in intracellular CD151 palmitoylation sites, respectively. CD151- integrin association and CD151-tetraspanin association were both important for α3β1 integrin- dependent initial adhesion and rapid migration on laminin-332. Remarkably, however, only CD151-integrin association was required for stable, α6β4 integrin-dependent cell attachment on laminin-332. In gap-filling assays, where CD151-silenced cells moved more rapidly than WT cells, again, only CD151-integrin association was required to restrict movement into the gap, suggesting that both α3β1 and α6β4 integrin must be able to associate with CD151 in order restrict group motility. In addition, we found that a QRD amino acid motif in the CD151 EC2 domain that had been thought to be crucial for CD151-integrin interaction is not essential for CD151-integrin association or for CD151's ability to promote several different integrin functions. These new data suggest potential strategies for selectively modulating migratory cell responses to laminin-332, while leaving stable cell attachment on laminin-332 intact.
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noneChen, Jir-Wen 31 July 2003 (has links)
Hepatocellular carcinoma (HCC) is one of the most prevalent cancers worldwide. Hepatocarcinogenesis is considered a multifactorial and mulitstep process that involves the activation of oncogenes or the inactivation of tumor suppressor genes. Tumor suppressor gene PTEN (also known as MMAC or TEP1) is located on human chromosome 10q23. The 403¡Vamino acid PTEN protein encodes dual specificity protein phosphatases. Mutation of the PTEN is a common event in advanced stage of diverse human cancers. In our previous studies, immunohistochemical analysis indicated that reduced PTEN expression was found in nearly 40% of HCC specimens. Furthermore, restored PTEN expression by adenovirus gene delivery effectively inhibited the in vitro and in vivo tumorigenicity of Mahlavu cells, a human HCC cell line with PTEN inactivation. In the present study, we further characterize whether PTEN gene delivery still suppressed the oncogenic potential in HCC cell lines with functional PTEN. By expression and sequencing analysis, we identified human SK-Hep-1 cells as the hepatoma cell line with functional PTEN expression. The optimal condition for adenovirus vector to infect SK-Hep-1 cells was determined at the multiplicity of infection (MOI) of 50-100. Tough SK-Hep-1 cells were effectively transduced with exogenous PTEN gene, the enhanced PTEN expression by adenovirus gene delivery did not alter the phosphoryation extent of Akt in SK-Hep1 cells. Nevertheless, PTEN gene delivery reduced the proliferation of SK-Hep-1 cells by ~20%. In addition, the motility of PTEN-transduced SK-Hep-1 cells significantly decreased comparing to cells of control groups. Western blot analysis suggested the decreased cell motility might be attributed to the reduced phosphorylation of focal adhesion kinase (FAK) by PTEN gene delivery. Above all, PTEN gene delivery profoundly reduced the colony formation of SK-Hep-1 cells in soft-agar. However, PTEN gene delivery did not affect the secretion of matrix metallo-proteinases (MMPs) release. Animal studies will be carried out in the future to validate the present in vitro findings. In summary, PTEN gene delivery holds promise for treatment of HCC even when the hepatoma cells possess functional PTEN gene.
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Measurement and theory of cochlear non-linearity : mechanoelectrical transduction and efferent controlLukashkin, Andrei Nikolaevich January 1999 (has links)
No description available.
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Tropomyosin in Normal and Malignant Cells and the Action of Picropodophyllin on the Microfilament and Microtubule SystemsZhao Rathje, Li-Sophie January 2009 (has links)
Cell motility is a fundamental process, enabling cells to migrate, for instance during embryogenesis, tissue repair and defense. Force is generated by two protein systems, which also participate in cell proliferation, control macromolecular and organelle distribution and determine the fine structure of the cell interior. The major components of these are actin and tubulin, respectively, and they are referred to as the microfilament and the microtubule systems. This thesis focuses on tropomyosin, one of many microfilament associated proteins coupled to actin dynamics and organization and expressed in several isoform variants. Altered distribution and isoform expression of tropomyosin are signatures of malignant cells and are dealt with in the current thesis. The presence of tropomyosin isoforms in protruding lamellipodia of migrating cells is demonstrated, and a method to fractionate tropomyosin depending on its organization in an easily extractable, and a more tightly bound cytoplasmic form is presented. Analysis of the loosely associated tropomyosin fraction by gel filtration chromatography revealed that most of the tropomyosins in this fraction exist in a multimeric form. It was also observed that the distribution of tropomyosin varied between non-transformed and transformed cells with most of the isoforms enriched in the loosely bound fraction in the latter category of cells. Possibly this reflects the extensive reorganization of the microfilament system observed in cancer cells and which, depending on the context, can be normalized by introduction of certain tropomyosin isoforms. Many anti-cancer drugs target the microtubule system, inhibit cell division and promote apoptosis. Here it is shown that picropodophyllin, which has promising anticancer properties has a destabilizing effect on microtubules and via the microfilament system causes cells to detach from their substratum. Furthermore, picropodophyllin interferes with stimulation of the insulin-like growth factor receptor, which is involved in growth stimulation, differentiation and survival and whose expression is up-regulated in cancer cells.
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Identification of a Novel G-protein Interactor, RADIL, and Functional Characterization of its Role in Cancer Cell MotilityAhmed, Syed Mukhtar 19 March 2013 (has links)
Cell adhesion and migration play crucial roles in development of multicellular organisms, immune surveillance, wound repair and cancer metastasis. The Gβγ subunits of heterotrimeric G-proteins have been implicated in signalling activities that promote cell adhesion and migration but the molecular mechanisms are unclear. Using a mass-spectrometry based proteomic approach we identified a protein complex between Gβγ and Rap1a that is bridged by a novel Rap1 effector, Radil. Overexpression of constitutively active Rap1a, Gβγ or stimulation of cells with the GPCR ligand fMLP triggers recruitment of Radil to the plasma membrane. Exogenous expression of Radil promotes cell spreading through Rap1-dependent inside-out activation of integrins leading to enhanced cell-matrix adhesion. Structure function experiments demonstrated that the RA and PDZ domains of Radil are required for its ability to promote cell adhesion. Using phage-display and mass-spectrometry we identified the kinesin family protein KIF14 as a novel interacting partner for Radil. Both KIF14 and Radil colocalized on microtubules in a PDZ-dependent manner. Depletion of KIF14 or disruption of microtubules led to accumulation of Radil at the cell membrane. Functionally, KIF14 is a negative regulator of Radil signalling as its depletion increased cell spreading and integrin activation and both phenotypes are rescued by simultaneous knockdown of Radil. Knockdown of KIF14 affects focal adhesion dynamics, which we determined is due to delayed adhesion disassembly. Depletion of either KIF14 or Radil dramatically decreased breast cancer cell migration and invasion in vitro. Additionally, knockdown of Radil compromised the ability of cells to metastasize to the lung and reduced tu-mor growth in xenograft mouse models. Collectively, these studies describe a functional re-quirement for the Gβγ-Rap1a-Radil complex during GPCR signalling for the control of integrin-mediated cell adhesion, cell motility and cancer progression.
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Regulation by phytoestrogens of migration, actin cytoskeleton, and signaling cascades relevant to cancer cell motilityAzios, Nicolas Gabriel 05 August 2013 (has links)
Genistein, daidzein, and resveratrol are polyphenolic plant compounds called phytoestrogens (PEs) because they are capable of binding and activating estrogen receptor (ER) isoforms due to structural similarity to estrogen (E2). The central hypothesis governing these investigations is that PEs can bind to plasmamembrane ERs, cross-talk with epidermal growth factor receptor (EGFR), and signal downstream to an array of molecular pathways including those involved in cell motility. This is relevant to breast cancer metastasis as PEs have been shown to have both preventative and promotional effects on breast cancer cells. The data herein investigates the role of E2, genistein, daidzein, and resveratrol in cell migration, actin cytoskeleton organization, focal adhesion assembly, as well as EGFR, focal adhesion kinase (FAK), and Rho family GTPase activation in ER (+/-) human breast cancer cells. We report that E2 and EGF increase cell migration, induce Rac-dependent lamellipodia formation, increase focal adhesion assembly, and increase EGFR, FAK, and Rac activity in ER[beta] (+) cells. We report that genistein and daidzein also increase cell migration, Rac-dependent lamellipodia formation, focal adhesion assembly, and FAK activity in ER[beta] (+) cells. Resveratrol demonstrates a biphasic concentration-dependent effect on the same signaling pathways. Resveratrol at 5 [micromolar] increases cell migration, lamellipodia formation, and increases FAK and Rac activity in ER[beta] (+) cells similar to E2. Conversely, resveratrol at 50 [micromolar] inhibits cell migration/invasion, blocks E2/EGFinduced migration, induces sustained and unpolarized filopodia, decreases focal adhesion assembly, increases EGFR activity, and decreases FAK, Cdc42, and Rac activity in ER[beta] (+) cells. The induction of filopodia by 50 [micromolar] resveratrol is partially Rho GTPaseindependent and can be observed in serum and on extracellular matrices. The induction by 50 [micromolar] resveratrol of a global, sustained extension of filopodia in conjunction with inhibition of focal adhesion assembly, as well as FAK, Cdc42, and Rac activity is hypothesized to negatively affect breast cancer cell motility. Ultimately, the elucidation of these cell structures and signaling mechanisms in response to PEs will help to determine a preventive or promotional role for plant compound-based therapies in breast cancer metastasis. / text
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Identification of a Novel G-protein Interactor, RADIL, and Functional Characterization of its Role in Cancer Cell MotilityAhmed, Syed Mukhtar 19 March 2013 (has links)
Cell adhesion and migration play crucial roles in development of multicellular organisms, immune surveillance, wound repair and cancer metastasis. The Gβγ subunits of heterotrimeric G-proteins have been implicated in signalling activities that promote cell adhesion and migration but the molecular mechanisms are unclear. Using a mass-spectrometry based proteomic approach we identified a protein complex between Gβγ and Rap1a that is bridged by a novel Rap1 effector, Radil. Overexpression of constitutively active Rap1a, Gβγ or stimulation of cells with the GPCR ligand fMLP triggers recruitment of Radil to the plasma membrane. Exogenous expression of Radil promotes cell spreading through Rap1-dependent inside-out activation of integrins leading to enhanced cell-matrix adhesion. Structure function experiments demonstrated that the RA and PDZ domains of Radil are required for its ability to promote cell adhesion. Using phage-display and mass-spectrometry we identified the kinesin family protein KIF14 as a novel interacting partner for Radil. Both KIF14 and Radil colocalized on microtubules in a PDZ-dependent manner. Depletion of KIF14 or disruption of microtubules led to accumulation of Radil at the cell membrane. Functionally, KIF14 is a negative regulator of Radil signalling as its depletion increased cell spreading and integrin activation and both phenotypes are rescued by simultaneous knockdown of Radil. Knockdown of KIF14 affects focal adhesion dynamics, which we determined is due to delayed adhesion disassembly. Depletion of either KIF14 or Radil dramatically decreased breast cancer cell migration and invasion in vitro. Additionally, knockdown of Radil compromised the ability of cells to metastasize to the lung and reduced tu-mor growth in xenograft mouse models. Collectively, these studies describe a functional re-quirement for the Gβγ-Rap1a-Radil complex during GPCR signalling for the control of integrin-mediated cell adhesion, cell motility and cancer progression.
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Discovery and Characterization of WISH/DIP/SPIN90 Proteins as a Class of ARP2/3 Complex Activators that Function to Seed Branched Actin NetworksWagner, Andrew 10 April 2018 (has links)
Assembly of branched actin filaments produces dynamic structures required during membrane associated processes including cell motility and endocytosis. The Actin Related Protein 2/3 (Arp2/3) complex is the only known regulator capable of nucleating actin branches. To specify the sub cellular localization and timing of actin assembly the complex is tightly regulated. Canonical activation of the Arp2/3 complex by Wiskott-Aldrich Syndrome proteins (WASP), requires preformed actin filaments, ensuring the complex nucleates new actin filaments off the sides of preformed filaments. WASP proteins can therefore propagate branch formation but cannot initiate a Y-branch without performed filaments. A key question, then, is what is the source of preformed filaments that seed branched actin network formation in cells? It is unclear how activation of Arp2/3 by multiple regulators is balanced to specify actin filament architectures that are productive in vivo. In this dissertation, we identified WISH/DIP1/SPIN90 (WDS) family proteins as activators of the Arp2/3 complex that do not require preformed filaments, and evaluated whether WDS proteins seed branching nucleation.
In chapter II, we dissected the biochemical properties of WDS proteins and found they activate the Arp2/3 complex using a non-WASP like mechanism. Importantly, we discovered WDS-mediated Arp2/3 activation produces linear, unbranched filaments, and this activity is conversed from yeast to mammals. These observations highlight that WDS proteins have the biochemical capacity to seed actin branches.
In chapter III, we observed WDS-generated linear filaments can seed WASP-mediated branching directly using single molecule microscopy with fluorescently labeled Dip1. We find that WDS-mediated nucleation co-opts features of branching nucleation.
In chapter IV, we investigated how WDS activity is balanced with WASP. We discovered WDS proteins use a single turnover mechanism to activate Arp2/3 and this is conserved during endocytosis. In contrast, WASP-mediated activation is multi-turnover, highlighting a crucial difference between WDS proteins and WASP. Our observations explain how Arp2/3 may limit linear filament production to initiate networks and favor branches during network propagation. Finally, we use fission yeast to show that increasing Dip1 is sufficient to cause defects in actin assembly and the timing of actin patches at sites of endocytosis.
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