Global ETD Search

171	Engineered Molecular Probes for Systematic Studies of Cellular Response in Collective Cell Migration Riahi, Reza January 2013 (has links) The investigation of complex biological processes, such as wound healing, cell migration, cancer cell invasion, and gene regulatory networks can be benefited tremendously by novel biosensing techniques with high stability and spatiotemporal resolution. In particular, molecular probes with qualities including high stability, sensitivity, and specificity are highly sought-after for long-term monitoring of gene expression in individual cells. Among different single-cell analysis techniques oligonucleotide optical probes is a promising detection method to monitor the dynamics of cellular responses. Herein, the design and optimization of double-stranded LNA probes are first investigated. With alternating DNA/LNA monomers for optimizing the stability and specificity, we show that the probe is highly stable in living cells and is capable of detecting changes in gene expression induced by external stimuli. Using dsLNA probes we then demonstrate the novel approaches to monitor the spatiotemporal gene expression response during cell injury. Our results also suggest a potential autoregulatory role of Nrf2 in injury induced EMT. We also show that the signaling level of dsLNA probe can serve as a molecular signature for the leader cells near the wound which allows us to track the behaviors of leader cells during collective cell migration. Finally multimodal GNR-LNA approach is proposed to map spatiotemporal gene expression profile and reveal dynamic characteristics of heat shock response in photothermal operations. Gene expression Optical molecular Probes wound healing assays Mechanical Engineering collective cell migration
172	Emergent Leader Cells in Collective Cell Migration in In Vitro Wound Healing Assay Yang, Yongliang January 2014 (has links) Collective cell migration is critical for various physiological and pathological processes. In vitro wound healing assay has been widely used to study collective cell migration due to its technical simplicity and ability of revealing the complexity of collective cell migration. This project studies the function and importance of leader cells, the cells pulling cell monolayer migrating into free space, in endothelium and skin epithelial regeneration via plasma lithography enhanced in vitro wound healing assay. Despite leader cells have been identified in in vitro wound healing assays, little is known about their regulation and function on collective cell migration. First, I investigated the role of leader cells in endothelial cell collective migration. I found that the leader cell density is positively related with the cell monolayer migration rates. Second, we used this knowledge to study the effects of arsenic treatment on skin regeneration via in vitro wound healing assay. We found that low concentration of arsenic treatment can accelerate the keratinocyte monolayer migration. We further found that arsenic affected cell migration by modulating leader cell density through Nrf2 signaling pathway. As a conclusion of these studies, we evaluated the function of leader cells in collective cell migration, and elucidated the mechanism of arsenic treatment on skin regeneration. endothelial cell leader cell monolayer migration skin regeneration Mechanical Engineering collective cell migration
173	Étude des voies de signalisation en amont et en aval de la petite GTPase Rac1 Pelletier, Ariane 09 1900 (has links) Les évènements moléculaires en amont et en aval de la petite GTPase Rac1 menant à la migration cellulaire sont encore mal compris. La première partie du projet consiste à utiliser une approche protéomique non-biaisée pour tenter d’identifier les partenaires de Rac. Pour ce faire, nous avons développé une méthode de purification efficace et rapide de manière à maintenir les complexes protéiques transitoires intacts. Dans un deuxième temps, nous avons identifié des sites de phosphorylation sur la RacGEF atypique Dock5 en aval des intégrines. Afin de mieux comprendre le rôle de la phosphorylation de cette protéine, nous avons criblé une banque de kinases ce qui nous a permis d’identifier 14 kinases pouvant phosphoryler la région PXXP de Dock5. D’après nos résultats, ceci aurait comme effet de diminuer l’interaction entre Dock5 et ses partenaires contenant des domaines SH3. Ainsi, la phosphorylation de Dock5 régulerait la formation de complexes et le recrutement de Dock5 par des protéines adaptatrices. / The molecular events upstream and downstream of Rac leading to cell migration and still to date not fully understood allthough more than 20 effectors have been identified for this GTPase. The first part of our project is to use a non-biased proteomic approach to try to identify novel binding partners of Rac1. In order to do so, we developped a novel purification strategy that enabled us to purify Rac and its binding partners in a timely manner. The second part of our project is to understand the role of Dock5 phosphorylation downstream of the integrins. We identified phosphorylated residues in the PXXP region of the atypical RacGEF upon fibronectin stimulation and found 14 kinases able to phosphorylate this region. According to our results, Dock5 phosphorylation does not affect its GEF activity but diminishes its interaction with various SH3 domain-containing proteins. Thus, our data suggest that Dock5 phosphorylation would regulate complex formation and recruitment of this protein by adaptor proteins. Migration cellulaire Rac1 Dock5 Cell migration Rac1 Dock5
174	p53 Regulates the Formation of Lamellipodia and Circular Dorsal Ruffles Through Caldesmon and PTEN VANDENBERG, Laura Joanna 14 June 2011 (has links) Vascular smooth muscle cell migration is a significant contributor to many aspects of heart disease, and specifically atherosclerosis. Tissue damage in the arteries can result in the formation of a fatty streak. Smooth muscle cells (SMC) can then migrate to this site to form a fibrous cap, stabilizing the fatty plaque. Since cardiovascular disease is the leading cause of death in developed countries, this function of SMC is an essential area of study. The formation of lamellipodia and circular dorsal ruffles were studied in this project as indicators that cell migration is occurring. The roles of the proteins p53, Rac, caldesmon and PTEN were investigated with regards to these actin-based structures. The tumour suppressor p53 is often reported to cause apoptosis, senescence or cell cycle arrest when stress is placed on a cell, but has recently been shown to regulate cell migration as well. It was determined in this project that p53 could inhibit the formation of both lamellipodia and circular dorsal ruffles. It was also shown that this could occur directly through an inhibition of the GTPase Rac. Previous studies have shown that p53 can upregulate caldesmon, a protein which is known to bind to and stabilize actin filaments while inhibiting Arp2/3-mediated branching. It was confirmed that p53 could upregulate caldesmon, and that caldesmon could inhibit the formation of lamellipodia and circular dorsal ruffles. The phosphorylation of caldesmon by p21-associated kinase (PAK) or extracellular signal-related kinase (Erk) was shown to effectively reverse the ability of caldesmon to inhibit these structures. The role of phosphatase and tensin homologue deleted on chromosome 10 (PTEN) was also studied with regards to this signalling pathway. PTEN was shown to inhibit lamellipodia and circular dorsal ruffles through its lipid phosphatase activity. It was concluded that p53 can inhibit the formation of lamellipodia and circular dorsal ruffles in vascular SMC, and that this occurs through Rac, caldesmon and PTEN. / Thesis (Master, Biochemistry) -- Queen's University, 2011-06-10 13:15:37.081 p53 caldesmon PTEN lamellipodia circular dorsal ruffles cell migration Rac Erk PAK
175	CCN2 – Keratinocyte Interactions In Vitro and In Vivo Kiwanuka, Elizabeth January 2014 (has links) Cutaneous wound healing is a complex process involving the migration of inflammatory cells to the wound site, deposition of extracellular matrix, and the reestablishment of an intact epithelial barrier. Re-epithelialization depends on the proliferation and directional migration of keratinocytes from the wound edges. Initially, keratinocytes migrate over a provisional wound matrix that is rich in fibronectin, and as the wound heals the provisional matrix becomes replaced by one consisting of collagen and proteoglycans. Re-epithelialization is tightly regulated by a variety of peptides such as growth factors, cytokines and proteases, and abnormalities may result in chronic non-healing wounds or hypertrophic scars. CCN2 (Connective Tissue Growth Factor) is a multifunctional protein with effects on cells and their interactions with the connective tissue. CCN2 is expressed in a variety of cell types and regulates numerous cell functions including proliferation, differentiation, adhesion, migration and stimulation of collagen production. While the importance of CCN2 for the fibrotic response has been well studied, its involvement in keratinocyte function has not yet been fully explored. Using an in vivo wound model, the expression of CCN2 was captured at the leading keratinocyte edge during re-epithelialization. In vitro, exogenous addition of CCN2 to human keratinocyte cultures promoted keratinocyte migration. Subsequently, integrin a5b1 was identified as an important mediator of CCN2 enhancement of keratinocyte adhesion to fibronectin. CCN2 activated the FAK-MAPK signaling pathway, and pretreatment with MEK1 specific inhibitor PD98059 markedly reduced CCN2-promoted keratinocyte migration. In vitro, CCN2 expression was induced by TGF-β1. Compared with inhibiting the SMAD pathway, blocking MAPK was more effective in reducing TGF-β1-induced CCN2 mRNA and protein expression. In addition, CCN2-induced keratinocyte spreading required FAK. Treatment with CCN2 led to actin disassembly and altered the activity of the Rho proteins and p190RhoGAP in keratinocytes. Furthermore, Cdc42 mediated CCN2-induced cell polarity. In conclusion, using in vivo and in vitro models, CCN2 was shown to regulate keratinocyte function by promoting keratinocyte adhesion, spreading and migration. A complete understanding of CCN2 expression in keratinocytes is crucial in order to develop novel therapies for wound healing. CCN2 connective tissue growth factor keratinocytes re-epithelialization cell migration cell signaling
176	Role of cellular dynamics, adhesion and polarity in the context of primordial germ cell migration in Xenopus laevis embryos Dzementsei, Aliaksandr 02 July 2013 (has links) No description available. 570 Primordial germ cell Xenopus laevis cell migration cellular adhesion Biologie (PPN619462639)
177	Cellular adhesion gene SELP is associated with rheumatoid arthritis and displays differential allelic expression Burkhardt, Jana, Blume, Mechthild, Petit-Teixeira, Elisabeth, Teixeira, Vitor Hugo, Steiner, Anke, Quente, Elfi, Wolfram, Grit, Scholz, Markus, Pierlot, Céline, Migliorini, Paola, Bombardieri, Stefano, Balsa, Alejandro, Westhovens, René, Barrera, Pilar, Radstake, Timothy R. D. J., Alves, Helena, Bardin, Thomas, Prum, Bernard, Emmrich, Frank, Cornelis, Francois, Ahnert, Peter, Kirsten, Holger 05 September 2014 (has links) (PDF) In rheumatoid arthritis (RA), a key event is infiltration of inflammatory immune cells into the synovial lining, possibly aggravated by dysregulation of cellular adhesion molecules. Therefore, single nucleotide polymorphisms of 14 genes involved in cellular adhesion processes (CAST, ITGA4, ITGB1, ITGB2, PECAM1, PTEN, PTPN11, PTPRC, PXN, SELE, SELP, SRC, TYK2, and VCAM1) were analyzed for association with RA. Association analysis was performed consecutively in three European RA family sample groups (Nfamilies = 407). Additionally, we investigated differential allelic expression, a possible functional consequence of genetic variants. SELP (selectin P, CD62P) SNP-allele rs6136-T was associated with risk for RA in two RA family sample groups as well as in global analysis of all three groups (ptotal = 0.003). This allele was also expressed preferentially (p,1026) with a two- fold average increase in regulated samples. Differential expression is supported by data from Genevar MuTHER (p1 = 0.004; p2 = 0.0177). Evidence for influence of rs6136 on transcription factor binding was also found in silico and in public datasets reporting in vitro data. In summary, we found SELP rs6136-T to be associated with RA and with increased expression of SELP mRNA. SELP is located on the surface of endothelial cells and crucial for recruitment, adhesion, and migration of inflammatory cells into the joint. Genetically determined increased SELP expression levels might thus be a novel additional risk factor for RA. Adhäsionsmoleküle Genotypisierung Zelltranskription Zellwanderung Gelenkrheumatismus Adhesion molecules cell migration genotyping transcription factors rheumatoid arthritis ddc:610
178	IGF:VN complexes and their role in breast cell migration Hollier, Brett G. January 2007 (has links) Members of the insulin-like growth factor (IGF) family are mitogenic growth factors which have been shown to play critical roles in both normal growth and development, and tumour biology. The IGF system is complex and the biological effects of the IGFs are determined by diverse interactions between many molecules, including interactions with the extracellular matrix (ECM). Recent observations have demonstrated that IGFs can associate with the ECM protein vitronectin (VN) and this interaction can modulate IGF-stimulated biological functions. It has been demonstrated previously that IGF-II can bind directly to VN, while IGF-I associates with VN indirectly via the involvement of IGF-binding proteins (IGFBPs) -2, -3, -4 and -5. As the IGF system plays important roles in both normal breast development and in the transformation and progression of breast cancer, this study aimed to describe the effects of substrate-bound IGF-I:IGFBP:VN complexes on breast cell functions and to dissect the mechanisms underlying these responses. The studies reported in this thesis demonstrate that substrate-bound IGF-I:IGFBP:VN complexes, containing IGFBP-3 and IGFBP-5, are potent stimulators of proliferation and migration in the "normal", non-tumourigenic MCF-10A breast epithelial and MCF-7 breast carcinoma cell lines. Interestingly, substrate-bound IGF-I:IGFBP:VN complexes were less effective in increasing the migration of the metastatic MDA-MB-231 breast cancer cell line. This, however, is due to these cells expressing the αvβ3 integrin which can support a highly migratory phenotype independent of IGF-I-stimulation. Taken together this suggests a particularly important role for these complexes in stimulating a highly migratory phenotype in pre-invasive or poorly metastatic breast cells. Studies using IGF-I analogues were also undertaken to establish if there was a requirement for ternary complex formation and the type-1-IGF receptor (IGF-1R) in the enhanced migration responses observed. These studies determined IGF-I:IGFBP:VN-stimulated migration to be dependent upon both heterotrimeric IGF-I:IGFBP:VN complex formation and activation of the IGF-1R. Furthermore, the enhanced cellular migration was abolished upon incubation of MCF-7 and MCF-10A cells with function blocking antibodies directed at VN-binding integrins and the IGF-IR. In addition, analysis of the signal transduction pathways underlying the enhanced cell migration revealed that the complexes stimulate a transient activation of the ERK/MAPK signaling pathway, while simultaneously producing a sustained activation of the PI3-K/AKT pathway. Optimal intracellular signaling required activation of both the IGF-1R and VN-binding integrins, as antibody mediated inhibition of either receptor led to substantial decreases in both ERK/MAPK and PI3-K/AKT pathway activation. Furthermore, experiments using pharmacological inhibitors of these pathways determined a pivotal role for PI3-K/AKT activation in substrate-bound IGF-I:IGFBP:VN-stimulated cell migration. In order to confirm an important role for the PI3-K/AKT pathway in these responses, wild-type and activated-AKT was transiently overexpressed in MCF-10A cells. Overexpression of both wild-type and activated-AKT further enhanced cellular migration in response to substrate-bound IGF-I:IGFBP:VN complexes. However, these responses still required co-activation of the IGF-1R and VN-binding integrins. In an attempt to obtain a global view of the possible molecular mechanisms underpinning IGF-I:IGFBP:VN-stimulated cell migration, oligonucleotide microarrays were used to screen for candidate genes important for the observed migratory responses. The microarray studies identified 165 genes which were differentially expressed in cells migrating in response to substrate-bound IGF-I:IGFBP:VN complexes. Gene ontology and functional analysis revealed many of these genes to be significantly associated with biological functions relevant to cancer transformation and progression, including cell growth and proliferation, cell death and cellular movement. In regard to cell migration, a number of the genes identified have previously reported roles in cellular movement, migration and metastasis, which may provide future targets to augment IGF-I:IGFBP:VN-stimulated cell migration. Taken together, the studies reported throughout this thesis have provided the first mechanistic insights into the action of IGF-I:IGFBP:VN complexes and add further evidence to support the involvement of VN-binding integrins and their co-operativity with the IGF-IR in the promotion of tumour cell migration. Importantly, identifying the molecular mechanisms by which IGF:VN complexes enhance breast cell function will lead to not only a better understanding of this critical interaction, but also aid in developing diagnostic tests and therapeutics directed at treating breast cancer. IGF mitogenic growth factors tumour cancer breast cancer VN-binding integrins IGF-IR cancer cell migration
179	Morphogenesis of testis cords Alexander Combes Unknown Date (has links) To date, studies into sex determination and gonadal development have focused on the regulatory mechanisms governing development of the male or female phenotype. However, the formation of the testis and ovary from the bipotential gonad also present a fascinating model of tissue organisation which has been largely overlooked. When seeking to understand tissue organisation during gonadal development, the formation of testis cords takes center stage. However, despite a growing understanding of the cellular events in testis development, a number of key questions about the formation of testis cords remain unanswered. Specifically, I aimed to investigate the role of cell migration in testis organization, and the structure and morphogenesis of testis cords in three dimensions. To address these aims experimentally, I investigated the early morphogenesis of testis cords and the dependence of cord formation on cell migration from the mesonephros. I found that virtually all of the migrating cells express endothelial markers, indicating that endothelial, not peritubular myoid cells underlie the dependence of cord formation on cell migration. Further, disruption of endothelial cell migration and vascular organisation using a blocking antibody to VE-cadherin, also disrupted the development of testis cords. These data reveal that migrating endothelial cells are required for testis cord formation, consistent with increasing evidence of a broader role for vasculature in establishing tissue architecture during organogenesis. To address the question of cord structure and morphogenesis, I developed and applied a novel fluorescence-based three-dimensional modeling approach to show that Sertoli cells coalesce into irregular groups surrounding germ cells, and that these groups are remodeled to form highly regular toroidal loops, joined by a flattened plexus at the dorsal side. This plexus is punctured by blood vessels as they ingress from the mesonephros, and contracts during maturation to form part of the rete testis. Variation in cord number and position demonstrates that cord establishment is not a stereotypic process. However, a tightly regulated modeling mechanism must contribute to uniformity on cord diameter and orientation as these parameters remain consistent across samples of the same age. These data clarify questions of cord structure and organisation, establish that cord formation is a variable process, and demonstrate novel structural features within the network of testis cords. Finally, to investigate an in vivo model where vascularisation and cord formation may be disrupted, I analysed gonads from embryos lacking Cited2. Consistent with a previous study, I found that testis development was delayed in Cited2-/- gonads, but found that despite the reported transcriptional recovery after the delay, testis vascular and cord structure was permanently disrupted. To investigate the defects in cord formation I assayed cell migration and found that migration was not disrupted in XY gonads, or mesonephroi lacking Cited2. However, ectopic cell migration was observed in the XX gonad in a dose-dependent response to loss of functional Cited2 alleles. Correspondingly, the female pathway was initially delayed but rallied for a late recovery, implicating Sf1 in the initiation of ovarian differentiation. These data underscore the fragility of the molecular control of sex determination as absence of Cited2 in the male permanently disrupts testis morphology, whereas in the female, promoters of the male pathway are not sufficiently suppressed. From these studies I construct an integrated model of testis cord formation and conclude that testis cord formation is a novel form of tubulogenesis. This morphogenesis is unique and offers insights into cell and tissue organisation, vascular interactions in organogenesis, and mechanisms of tube formation. Further study of cord formation is likely to lead to a broader understanding of tissue morphogenesis during development. Testis Development Organogenesis Testis cord Vasculature Imaging Cell migration 3D Modelling SF1 Cited2 Morphogenesis
180	Electrical stimulation of cells involved in wound healing Ly, Mai Thanh, Graduate School of Biomedical Engineering, Faculty of Engineering, UNSW January 2008 (has links) Problem investigated: Chronic wounds are not only a major burden to the patient arising from general pain and discomfort but also generate economic costs to both these individuals and the health care system. Various electrical stimulation regimes have been employed to study the effects of electrical stimulation on wound healing both in vivo and in vitro. In was hypothesised that electrical stimulation using various waveforms can modulate cell function, particularly cell migration. The aim of this thesis was to study the effects of electrical stimulation on cellular migration, in particular endothelial cells and fibroblasts, key cell types involved in wound healing. The impact of collagen matrix on cell migration was also assessed. Methods: Cells were seeded on either glass or collagen I substrate and stimulated with various electrical regimes via platinum electrodes connected to a constant current source. Cell migration was accessed by manual tracking of cell nuclei over a period of 3 hours from digital time-lapse images acquired during stimulation. Data from cell tracking were analysed for directional migration, migration rates and mean square displacement. Results: No directional cell migration for both endothelial cells and fibroblasts were observed when stimulated with either alternating or biphasic currents. However, surface substrate had impacted on cell motility with opposite effects being observed for the two cell types. Endothelial cells tended to migrate at a faster rate on collagen I substrate than on glass, compared with fibroblasts, which displayed a slower rate of migration on collagen I substrate. Significant changes in mean square displacement of biphasic current stimulated cells on collagen I substrate compared to unstimulated cells were also observed. Conclusion: This thesis has illustrated cell migration can be modulated by electrical stimulation, in particular asymmetric biphasic current. It has also been demonstrated surface substrate can impact cell migration. Surface substrate Electrical stimulation Cell migration Wound healing Biphasic stimulation AC stimulation

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