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Filopodial movement in Cyphoderia ampulla (Ehr.)Berrend, Robert E. January 1958 (has links)
Thesis (Ph. D.)--University of Wisconsin--Madison, 1959. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 66-68).
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Rôle du peptide LL-37 dans le cancer du sein : son interaction avec la membrane plasmique stimule l'entrée de calcium et la migration cellulaire par l'activation des canaux ioniques TRPV2 et BKCa / Role of the LL-37 peptide in breast cancer : stimulation of calcium entry and cell migration through the TRPV2 and BKCa channels by its interaction with the plasma membraneGambade, Audrey 18 December 2015 (has links)
Le peptide antimicrobien LL-37 a été retrouvé surexprimé dans différents types de cancer et plus particulièrement dans le cancer du sein dans lequel il est associé au développement des métastases. Nous avons observé, in vitro, que la migration de trois lignées cancéreuses mammaires est augmentée par le peptide LL-37 et son énantiomère (D)-LL-37, excluant la fixation du peptide à un récepteur protéique. Sur les cellules cancéreuses mammaires MDA-MB-435s, le peptide se fixe à la membrane plasmique et diminue sa fluidité. La microscopie électronique localise LL-37 dans les cavéoles et à la surface de structures impliquées dans la migration cellulaire, les pseudopodes. LL-37 induit une entrée de calcium via le canal TRPV2 dont l’activité est augmentée par son recrutement dans les pseudopodes. Ce recrutement est dépendant de l’activation de la voie de signalisation PI3K/AKT induite par LL-37. L’entrée de calcium via TRPV2 est potentialisée par l’activation du canal potassique BKCa, localisé aussi dans les pseudopodes. Des ARN interférents contre TRPV2 inhibent à 70% la migration induite par LL-37, donnant un rôle prépondérant à ce canal dans les effets pro-migratoire du peptide. La fixation du peptide LL-37 aux membranes des cellules cancéreuses et l’activation de canaux ioniques constituent un nouvel axe de recherche pour comprendre le rôle du peptide dans la progression tumorale. / The antimicrobial peptide LL-37 is overexpressed in several types of cancer, among which breast cancer were it is associated with metastasis development. Our experiments on three mammary cancer cell lines have shown that LL-37 increases cell migration. Both its natural (L)-form and its (D)-enantiomer are equally active, excluding a specific binding to a protein receptor. On the MDA-MB-435s cell line, LL-37 attaches to plasma membrane and reduces its fluidity. Electron microscopy localized LL-37 on the surface of pseudopodia, structures implicated in cell migration, and in caveolae. LL-37 induces calcium entry via the TRPV2 channel, which is recruited to pseudopodia. Recruitment depends on activation of PI3K/AKT signaling induced by LL-37. Calcium entry via TRPV2 is potentiated by activation of the BKCa potassium channel also located in pseudopodia. TRPV2 suppression by RNA interference results in 70% reduction of cell migration induced by LL-37, attributing a crucial role of this channel to the promigratory effects of the peptide. Binding of LL-37 to cancer cell membranes and in consequence the activation of ion channels constitutes a novel research field to understand its role in tumor progression.
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Functional analysis of Abp1 in DictyosteliumWang, Yanqin, 1974- 05 May 2015 (has links)
This work identified an ortholog of Abp1 (actin binding protein 1) in Dictyostelium (Dabp1). In order to analyze the functions of Dabp1 in Dictyostelium, loss-of–function studies and gain-of-function studies were performed by generating cells that either deleted the Dabp1 gene from the genome or overexpressed the Dabp1 protein. In these mutants, most actin-based processes were intact. However, cell motility was altered during early development. During chemotactic streaming, more than 90% of wild type cells had a single leading pseudopodium and a single uropod, whereas more than 27% of Dabp1 null cells projected multiple pseudopodia. Similarly, ~ 90% of cells that overexpressed Dabp1 projected multiple pseudopodia during chemotactic streaming, and displayed reduced rates of cell movement. Expression of the SH3 domain of Dabp1 showed this domain to be an important determinant in regulating pseudopodium number. These results suggest that Abp1 controls pseudopodium number and motility in early stages of chemotactic aggregation in Dictyostelium. This work also revealed an interplay between Dabp1 and MyoB, one of the Myosin I proteins, in controlling pseudopodia formation in Dictyostelium. These two proteins colocalize partially at the cortex in growing cells. The peripheral localization of MyoB was dependent on Dabp1. Depletion of both Dabp1 and MyoB caused defects in organization of the actin cytoskeleton and actin related activities such as formation of small F-actin filled spikes on the cell cortex of growing cells, a higher percentage of multinucleated cells, and an increased number of pseudopodia branching extensively. When MyoB was overexpressed in Dabp1 null mutants, cells had similar phenotypes as Dabp1/MyoB double null mutants, and displayed an increased number of pseudopodia with many branches. Overexpression of Dabp1 in MyoB null mutants rescued the defects in pseudopodia formation. The SH3 of Dabp1 was shown to be important for the rescue of defects caused by depletion of MyoB. Collectively, these data suggest that MyoB and Dabp1 work cooperatively to regulate the uniformity and integrity of the actin extensions during chemotaxis. MyoB requires Dabp1 to function in this process. Dabp1 may function as a scaffold to recruit MyoB to the proper localization. These studies of Dabp1 in Dictyostelium raise broad question about functions of actinassociated proteins in pseudopodia formation and the importance of uniformity and integrity for actin structures in chemotaxis. / text
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Focal adhesion kinase signaling spatially regulates adhesion dynamics in fibroblastsIwanicki, Marcin P. January 2008 (has links)
Thesis (Ph. D.)--University of Virginia, 2008. / Title from title page. Includes bibliographical references. Also available online through Digital Dissertations.
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Melanin transfer in human skin cells is mediated by filopodia--a model for homotypic and heterotypic lysosome-related organelle transferSingh, Suman K., Kurfurst, R., Nizard, C., Schnebert, S., Perrier, E., Tobin, Desmond J. January 2010 (has links)
No / Transfer of the melanocyte-specific and lysosome-related organelle, the melanosome, from melanocytes to keratinocytes is crucial for the protection of the skin against harmful ultraviolet radiation (UVR)--our main physiological cutaneous stressor. However, this commonplace event remains a most enigmatic process despite several early hypotheses. Recently, we and others have proposed a role for filopodia in melanin transfer, although conclusive experimental proof remained elusive. Using known filopodial markers (MyoX/Cdc42) and the filopodial disrupter, low-dose cytochalasin-B, we demonstrate here a requirement for filopodia in melanosome transfer from melanocytes to keratinocytes and also, unexpectedly, between keratinocytes. Melanin distribution throughout the skin represents the key phenotypic event in skin pigmentation. Melanocyte filopodia were also necessary for UVR-stimulated melanosome transfer, as this was also inhibited by MyoX knockdown and low-dose cytochalasin-B. Knockdown of keratinocyte MyoX protein, in its capacity as a phagocytosis effector, resulted in the inhibition of melanin uptake by keratinocytes. This indicates a central role for phagocytosis by keratinocytes of melanocyte filopodia. In summary, we propose a new model for the regulation of pigmentation in human skin cells under both constitutive and facultative (post-UVR) conditions, which we call the "filopodial-phagocytosis model." This model also provides a unique and highly accessible way to study lysosome-related organelle movement between mammalian cells.
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Bone morphogenetic proteins differentially regulate pigmentation in human skin cellsSingh, Suman K., Abbas, Waqas A., Tobin, Desmond J. January 2012 (has links)
No / Bone morphogenetic proteins (BMPs) are a large family of multi-functional secreted signalling molecules. Previously BMP2/4 were shown to inhibit skin pigmentation by downregulating tyrosinase expression and activity in epidermal melanocytes. However, a possible role for other BMP family members and their antagonists in melanogenesis has not yet been explored. In this study we show that BMP4 and BMP6, from two different BMP subclasses, and their antagonists noggin and sclerostin were variably expressed in melanocytes and keratinocytes in human skin. We further examined their involvement in melanogenesis and melanin transfer using fully matched primary cultures of adult human melanocytes and keratinocytes. BMP6 markedly stimulated melanogenesis by upregulating tyrosinase expression and activity, and also stimulated the formation of filopodia and Myosin-X expression in melanocytes, which was associated with increased melanosome transfer from melanocytes to keratinocytes. BMP4, by contrast, inhibited melanin synthesis and transfer to below baseline levels. These findings were confirmed using siRNA knockdown of BMP receptors BMPR1A/1B or of Myosin-X, as well as by incubating cells with the antagonists noggin and sclerostin. While BMP6 was found to use the p38MAPK pathway to regulate melanogenesis in human melanocytes independently of the Smad pathway, p38MAPK, PI3-K and Smad pathways were all involved in BMP6-mediated melanin transfer. This suggests that pigment formation may be regulated independently of pigment transfer. These data reveal a complex involvement of regulation of different members of the BMP family, their antagonists and inhibitory Smads, in melanocytes behaviour.
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