Global ETD Search

221	Impact of Narrow Constraint on Single Cell Motion Ficorella, Carlotta 17 May 2023 (has links) Die extrazelluläre Mikroumgebung spielt eine grundlegende Rolle bei der Entwicklung von Metastasen und hat einen großen Einfluss auf die Wahl der Migrationsstrategien, die von Karzinomzellen während der Invasion angewandt werden. In-vitro Anordnungen sind hilfreiche Instrumente für die Untersuchung von Zellmigration und -invasion, da sie grundlegende Merkmale von In-vivo-Geweben reproduzieren können. Ziel dieser Forschungsarbeit ist es, die Fähigkeit von mesenchymalen und epithelialen Brusttumorzellen zu untersuchen, sich zu verflüssigen und durch enge und starre Mikrostrukturen zu navigieren. Wir verwendeten eine mikrofluidische Vorrichtung mit trichterförmigen Mikroverengungen und verglichen das Verhalten von fünf verschiedenen menschlichen Brustkrebszelllinien in der Mikrovorrichtung bei Stimulation durch Chemoattraktoren. Wir fanden heraus, dass grundsätzlich verschiedene Zelllinien das gleiche invasive Potenzial haben, da normale Epithelzellen in der Lage waren, durch die stark komprimierenden Trichter zu wandern, ähnlich wie die invasiveren mesenchymalen Zellen. Wir fanden auch heraus, dass die Migration der normalen Epithelzellen auch ohne einen chemo-attraktiven Stimulus stattfindet. Wir konzentrierten unsere Beobachtungen auf die Rolle des Aktin- und Intermediärfilament-Zytoskeletts während der eingeschränkten Migration und zeigten, dass das Aktin-Zytoskelett eine starke und langanhaltende Reorganisation erfährt, damit die Zellen durch die engen Verengungen kriechen können. Wir sahen keinen Hinweis darauf, dass das Keratin- und Vimentin-Zwischenfilament- Zytoskelett während der Invasion in die Mikroverengungen eine aktive mechanische Rolle spielte. Insbesondere die Expression des Vimentin-Zwischenfilamentproteins korrelierte in unserem Versuchsaufbau nicht mit der Invasionsfähigkeit einzelner Zellen. Unter diesen Voraussetzungen wurden die passiven (Elastizität und Viskosität) und aktiven (Kontraktilität) viskoelastischen Eigenschaften der Zellen weiter untersucht und quantifiziert. Wir fanden keinen signifikanten Unterschied in der passiven viskoelastischen Reaktion der Zellen, nachdem sie oszillierenden Druckkräften mittels AFM-Sondierung ausgesetzt waren, was darauf hindeutet, dass Elastizität und Viskosität nicht zur Unterscheidung zwischen invasiven und nicht-invasiven Zellen verwendet werden können. Es wurde kein Hinweis darauf gefunden, dass die Kompressionsversteifung die Invasion durch die Mikroverengungen entweder behindert oder fördert. Schließlich haben wir bei der Betrachtung aktiver viskoelastischer Parameter die kontraktile Reaktion unserer Zelllinien verglichen, wenn sie mit dem mikrofluidischen optischen Strecker Laser-Streckkräften ausgesetzt wurden. Hier fanden wir eine klare Korrelation zwischen den Zelllinien, die ein invasives Verhalten in den Mikroverengungen zeigten, und denjenigen, die eine aktive (substratunabhängige) kontraktile Reaktion in der optischen Streckvorrichtung zeigten. Wir kommen zu dem Schluss, dass ein entscheidender Faktor für eine erfolgreiche Migration durch hohe räumliche Enge die Fähigkeit der Zellen ist, aktiv Aktin-Stressfasern zu erzeugen und abzubauen, was sich in der Fähigkeit manifestiert, von einer substratabhängigen und stressfaserbasierten Kontraktilität zu einer substratunabhängigen kortikalen Kontraktilität zu wechseln. Confined single cancer cell migration info:eu-repo/classification/ddc/530 ddc:530
222	ERK3 and DGKζ interact to modulate cell motility in lung cancer cells Myers, Amanda 13 May 2022 (has links) No description available. Biochemistry Cellular Biology Molecular Biology Biology ERK3 MAPK6 DGKzeta DGKζ lung cancer cell migration
223	Regulators of G-protein Signaling, RGS13 and RGS16, are Associated with CXCL12-mediated CD4+ T Cell Migration Xia, Lijin 06 August 2008 (has links) (PDF) Chemokines are important chemical signals that guide lymphocyte movement within the immune system and promote the organization and functions of germinal centers (GCs) in the secondary lymphoid tissues. Previous studies have shown that GC T cells exhibit high expression of chemokine receptor 4, CXCR4, but that these cells are unable to migrate to the ligand for this receptor, the chemokine CXCL12. This “migratory paralysis” to CXCL12 was found to be correlated with the expression of two Regulators of G-protein Signaling, RGS13 and RGS16 in the GC T cells. The objective of my research was to determine whether RGS13 and RGS16 expression were associated with CXCL12-mediated CD4+ T cell migration. Because human GC T cells are rare and vary from one individual to another, I utilized two human neoplastic CD4+ T cell lines (i.e. Hut78 and SupT1) to facilitate and standardize my research. I also confirmed my observations using primary CD4+ T cells. Hut78 cells behaved similarly to GC T cells interms of CXCL12-mediated migration and RGS13 and RGS16 expression, while SupT1 cells appeared similar to CD4+ T cells that resided outside of GCs. The effect of RGS13 and RGS16 expression in the various CD4+ T cells was examined by altering the natural levels of these genes using RNA-mediated silencing and/or gene overexpression analysis after which, I examined the ability of the cells to migrate to CXCL12. RNA-mediated silencing of RGS16-, but not RGS13-, expression in Hut78 T cells resulted in a doubling of the migration rate in response to CXCL12. Over-expression of RGS13 or RGS16 in SupT1 and primary CD4+ T cells resulted in migration that was decreased by fifty percent. Because GC T cells demonstrated decreased migration to CXCL12 signals that may help them leave the GC, I reasoned that these cells may have an increased opportunity over other CD4+ T cells to become infected by the Human Immunodeficiency Virus (HIV) trapped on Follicular Dendritic Cells in the GCs of infected subjects. Examination of GC T cells obtained from HIV-infected subjects indicated that these cells were more frequently infected by HIV than other CD4+ T cells thereby confirming my postulate. My research indicated that RGS13 and RGS16 were associated with CXCL12-mediated CD4+ T cell migration and suggests that these molecules may play an important role in HIV pathogenesis within the GC. chemokine regulator of G-protein signaling (RGS) cell migration germinal center T cell HIV Biochemistry Chemistry
224	Normal epithelial and triple-negative breast cancer cells show the same invasion potential in rigid spatial confinement Ficorella, Carlotta, Martinez Vazquez, Rebeca, Heine, Paul, Lepera, Eugenia, Cao, Jing, Warmt, Enrico, Osellame, Roberto, Käs, Josef A. 26 April 2023 (has links) The extra-cellular microenvironment has a fundamental role in tumor growth and progression, strongly affecting the migration strategies adopted by single cancer cells during metastatic invasion. In this study, we use a novel microfluidic device to investigate the ability of mesenchymal and epithelial breast tumor cells to fluidize and migrate through narrowing microstructures upon chemoattractant stimulation. We compare the migration behavior of two mesenchymal breast cancer cell lines and one epithelial cell line, and find that the epithelial cells are able to migrate through the narrowest microconstrictions as the more invasive mesenchymal cells. In addition, we demonstrate that migration of epithelial cells through a highly compressive environment can occur in absence of a chemoattractive stimulus, thus evidencing that they are just as prone to react to mechanical cues as invasive cells info:eu-repo/classification/ddc/530 ddc:530
225	Jamming transitions in cancer Oswald, Linda, Grosser, Steffen, Smith, David M., Käs, Josef A. 25 April 2023 (has links) The traditional picture of tissues, where they are treated as liquids defined by properties such as surface tension or viscosity has been redefined during the last few decades by the more fundamental question: under which conditions do tissues display liquid-like or solid-like behaviour? As a result, basic concepts arising from the treatment of tissues as solid matter, such as cellular jamming and glassy tissues, have shifted into the current focus of biophysical research. Here, we review recent works examining the phase states of tissue with an emphasis on jamming transitions in cancer. When metastasis occurs, cells gain the ability to leave the primary tumour and infiltrate other parts of the body. Recent studies have shown that a linkage between an unjamming transition and tumour progression indeed exists, which could be of importance when designing surgery and treatment approaches for cancer patients info:eu-repo/classification/ddc/530 ddc:530
226	Development of an Injectable Hydrogel Platform to Capture and Eradicate Glioblastoma Cells with Chemical and Physical Stimuli Khan, Zerin Mahzabin 15 May 2023 (has links) Glioblastoma multiforme (GBM) is the most aggressive type of primary brain tumor. Even after patients undergo maximum and safe surgical resection followed by adjuvant chemotherapy and radiation therapy, residual GBM cells form secondary tumors which lead to poor survival times and prognoses for patients. This tumor recurrence can be attributed to the inherent GBM heterogeneity that makes it difficult to eradicate the therapy-resistant and tumorigenic subpopulation of GBM cells with stem cell-like properties, referred to as glioma stem cells (GSCs). Additionally, the migratory nature of GBM/GSCs enable them to invade into the healthy brain parenchyma beyond the resection cavity to generate new tumors. In an effort to address these challenges of GBM recurrence, this research aimed to develop a biomaterials-based approach to attract, capture, and eradicate GBM cells and GSCs with chemical and physical stimuli. Specifically, it is proposed that after surgical removal of the primary GBM tumor mass, an injectable hydrogel can be dispensed into the resection cavity for crosslinking in situ. A combination of chemical and physical cues can then induce the migration of the residual GBM/GSCs into the injectable hydrogel to localize and concentrate the malignant cells prior to non-invasively abating them. In order to develop this proposed treatment, this dissertation focused on 1) characterizing and optimizing the thiol-Michael addition injectable hydrogel, 2) attracting and entrapping GBM/GSCs into the hydrogel with CXCL12-mediated chemotaxis, and 3) assessing the feasibility of utilizing histotripsy to mechanically and non-invasively ablate cells entrapped in the hydrogel. The results revealed that hydrogel formulations comprising 0.175 M NaHCO3(aq) and 50 wt% water content were the most optimal for physical, chemical, and biological compatibility with the GBM microenvironment on the basis of their swelling characteristics, sufficiently crosslinked polymer networks, degradation rates, viscoelastic properties, and interactions with normal human astrocytes. Loading the hydrogel with 5 µg/mL of CXCL12 was optimal for the slow, sustained release of the chemokine payload. A dual layer hydrogel platform demonstrated in vitro that the resulting chemotactic gradient induced the invasion of GBM cells and GSCs from the extracellular matrix and into the synthetic hydrogel with ameboid migration and myosin IIA activation. This injectable hydrogel also demonstrated direct therapeutic benefits by passively eradicating entrapped GBM cells through matrix diffusion limitations as well as decreasing the GBM malignancy and GSC stemness upon cancer cell-hydrogel interactions. Research findings revealed the hydrogels can be synthesized under clinically relevant conditions mimicking GBM resection in vitro, and hydrogels were distinguishable with ultrasound imaging. Furthermore, the synthetic hydrogel was acoustically active to generate a stable cavitation bubble cloud with histotripsy treatment for ablation of entrapped red blood cells with well-defined, uniform lesion areas. Overall, the results from this research demonstrate this injectable hydrogel is a promising platform to attract and entrap malignant GBM/GSCs for subsequent eradication with chemical and physical stimuli. Further development of this platform, such as by integrating electric cues for electrotaxis-directed cell migration, may help to improve the cancer cell trapping capabilities and thereby mitigate GBM tumor recurrences in patients. / Doctor of Philosophy / Glioblastoma multiforme (GBM) is the deadliest type of primary brain cancer. Upon GBM diagnosis, patients first undergo surgery to remove the tumor from the brain. After waiting several weeks for the wound healing process due to surgery, patients are administered chemotherapy with drugs and radiation therapy to eradicate any remaining GBM cells. Even after undergoing these combinatorial treatments, the cancer returns and leads to median survival times of only 15 months in 90% of patients. Complete GBM eradication is difficult, since the cancer cells can migrate into healthy brain tissue beyond the original tumor site. Additionally, GBM is highly heterogenous and composed of different cell types that can resist chemotherapy and radiation therapy, which lead to secondary tumors and cancer relapse. To address these challenges, this dissertation aimed to develop a polymer-based material (specifically a hydrogel) that can attract, entrap, and localize the GBM cells into the material to subsequently eradicate them with chemical and physical signals. This hydrogel platform would have important clinical implications, as it can potentially be dispensed into the empty cavity after surgical removal of the tumor in the brain. The hydrogel can then be harnessed to attract residual GBM cells for directed migration into the hydrogel to concentrate and localize the cancer cells for their subsequent destruction with a non-invasive technology. In order to develop this proposed treatment, this dissertation investigated the following three aims: 1) to study and optimize the injectable hydrogel for chemical, physical, and biological compatibility with the GBM therapy; 2) to utilize chemical signals to attract and entrap the GBM cells into the hydrogel; and 3) to apply focused ultrasound with high amplitude, short duration negative pressure pulses to mechanically fractionate and destroy the cells entrapped in the hydrogel. The results revealed that the hydrogel comprising 0.175 M NaHCO3(aq) and 50 wt% water content was the most optimal formulation. CXCL12 chemokine proteins loaded into the hydrogel at 5 µg/mL released slowly from the hydrogel to generate a chemical gradient and thereby attract GBM cells to promote their invasion into the hydrogel matrix. The hydrogel was demonstrated to respond well to focused ultrasound treatment, which was capable of mechanically fractionating and destroying red blood cells in the hydrogel uniformly. Overall, the results from this research provide support that this hydrogel platform can attract, entrap, and eradicate GBM cells with chemical and physical stimuli. Hence, further improvement of this platform and implementation of this novel GBM treatment may in the future help minimize GBM cancer relapse in patients who undergo conventional therapies, thereby extending their survival times. glioblastoma cancer cell migration CXCL12 chemotaxis histotripsy ablation focused ultrasound
227	Microfluidic Lab-on-a-Chip for Studies of Cell Migration under Spatial Confinement Sala, Federico, Osellame, Roberto, Käs, Josef A., Martínez Vázquez, Rebeca 22 February 2024 (has links) Understanding cell migration is a key step in unraveling many physiological phenomena and predicting several pathologies, such as cancer metastasis. In particular, confinement has been proven to be a key factor in the cellular migration strategy choice. As our insight in the field improves, new tools are needed in order to empower biologists’ analysis capabilities. In this framework, microfluidic devices have been used to engineer the mechanical and spatial stimuli and to investigate cellular migration response in a more controlled way. In this work, we will review the existing technologies employed in the realization of microfluidic cellular migration assays, namely the soft lithography of PDMS and hydrogels and femtosecond laser micromachining. We will give an overview of the state of the art of these devices, focusing on the different geometrical configurations that have been exploited to study specific aspects of cellular migration. Our scope is to highlight the advantages and possibilities given by each approach and to envisage the future developments in in vitro migration studies under spatial confinement in microfluidic devices.
228	Design, synthesis and in vitro biological evaluation of potential polysialyltransferase (ST8SiaII) inhibitors Ali, Marrwa M. January 2020 (has links) The full text will be available at the end of the embargo period: 5th March 2027 Polysialyltransferase Anti-metastatic Cancer Cell migration Inhibitors Neural development Evaluation Tumours
229	An immunohistopathological and functional investigation of β3 integrin antagonism as a therapeutic strategy in cancer. Characterisation, development, and utilisation of preclinical cancer models to investigate novel ¿3 integrin anatgonists. Alshammari, Fatemah O.F.O. January 2013 (has links) Tumour cell dissemination is a major issue with the treatment of cancer, thus new therapeutic strategies which can control this process are needed. Antagonism of integrins highly expressed in tumours is one potential strategy. The integrins are transmembrane glycoprotein adhesive receptors. Two of the integrins, αVβ3 and αIIbβ3, are highly expressed in a number of tumours and induce bi-directional signalling through their interaction with extracellular matrix proteins, and growth factor receptors. Through this signalling they play an important role in a number of cellular processes that are involved in tumour dissemination such as tumour growth, migration, invasion, metastasis and angiogenesis. Dual αIIbβ3 and αVβ3 integrin antagonism will have a direct effect on β3-expressing tumour cells that leads to the inhibition of cell migration and dissemination. Furthermore, through targeting tumour cell interaction with endothelial cells and platelets, this will also lead to inhibition of angiogenesis and metastasis. The aim of this project was to characterise the expression of αVβ3 and αIIbβ3 integrin in a panel of tumour cell lines and in human tumour xenograft samples, and to develop and utilise cell-based models to investigate potential novel β3 antagonists. The expression of αV and β3 subunits was detected in xenograft tissue using immunoblotting techniques. A panel of cell lines of different tumour types including melanoma, prostate, breast, colon and non small cell lung carcinoma was then characterised for αVβ3 and αIIbβ3 integrin expression using immunoblotting and immunocytochemistry. Melanoma cell lines demonstrated the strongest αVβ3 expression. No αIIbβ3 integrin expression was seen in any of the cell lines evaluated. A selection of cell lines with varying αVβ3 expression were then used to develop a functional test for cell migration, the scratch wound healing assay. Migration of tumour cells that expressed αVβ3 integrin was inhibited by the known β3 antagonists, cRGDfV peptide and LM609 antibody. A panel of 12 potential novel β3 integrin antagonists was screened for cytotoxicity and activity in the validated scratch assay. ICT9055 was the most effective antagonist in inhibition of M14 cell migration as determined by the scratch assay, with an IC50 of < 0.1 µM. Therefore the work presented in this thesis has established models and tools for evaluating potential novel β3 integrin antagonists, and identified a promising molecule to progress for further preclinical evaluation. / Public Authority for Applied Education and Training (PAAET)
230	Beyond cell Adhesion: Exploring the Role of Cadherin-11 Extracellular Processing by ADAM Metalloproteases in Cranial Neural Crest Migration McCusker, Catherine D. 01 February 2010 (has links) The migration of the cranial neural crest is an essential part of cranio-facial development in every vertebrate embryo. The cranial neural crest (CNC) is a transient population of cells that forms the lateral border of the anterior neural plate. In the tailbud stage Xenopus embryo, the neural crest cells delaminate from the neural tube, and undergo a large-scale migration from the dorsal to ventral region of the embryo. The CNC travels along distinct pathways, and populates specific regions of the embryos face. Once the CNC ceases migrating, it differentiates into a variety of tissues that are essential for cranio-facial structure and function. Some of these tissues include bones, muscle, cartilage, and ganglia. The CNC receives a concert of signals from neighboring tissues during and after CNC migration as well as signals transmitted among CNC cells, which act together to determine the fate of each CNC cell. Therefore, the proper migration of the CNC is an essential part of cranio-facial development. What molecules are important for the process of CNC migration? As one might imagine, a milieu of different molecules and interactions are essential for this complicated embryological process to occur. The work presented in this dissertation will focus on the role of a cell adhesion molecule that is important for Xenopus CNC migration. Typically, the amount of cell adhesion decreases within tissues undergoing migration. This behavior is essential to allow fluidity within the tissue as it moves. However, cell adhesions are fundamental for cell migration to occur because the moving cells need a platform on which to mechanically propel themselves. These interactions can occur between the migrating cell and extracellular matrix molecules (ECM), or can happen between cells. The cranial neural crest utilizes both cell-ECM and cell-cell interactions during the process of migration. The amount of cell adhesion mediated by either of these mechanisms will depend on where the cell is located within the CNC. Cells located at the periphery of the CNC tissue, which is surrounded by a matrix of ECM, will have more cell-ECM interactions. Cells located deeper in the CNC tissue, where there is little ECM, will rely more on cell-cell interactions. The work presented in this thesis focuses on a cell-cell adhesion molecule that is part of the cadherin superfamily of molecules. With this in mind, these studies should be descriptive of the environment within the CNC, and to a less degree the environment between the CNC and the surrounding tissues. The work presented in this dissertation will focus on cadherin-11, which is a classical cadherin that is specifically expressed in the cranial neural crest during its migration. How does cadherin-11 function in the CNC during this process? The work presented here suggests that the main role of cadherin-11 in the CNC is to perform as a cell adhesion molecule. However, too much cell adhesion is inhibitory to migration. In this respect, many of the studies described in this work indicate that cadherin-11 mediated cell adhesion is tightly regulated during CNC migration. Here I show that cadherin-11 is extracellularly processed by ADAM metalloproteases, ADAM9 and ADAM13, which removes the adhesive domain of cadherin-11. This extracellular cleavage event occurs throughout CNC migration, and is likely the main mechanism that regulates cadherin-11 mediated cell adhesion. Cleavage of cadherin-11 by ADAMs does not seem to affect its ability to interact with cytoplasmic binding partners, â-catenin and p120-catenin. This observation supports the idea that the “purpose” of cadherin-11 cleavage is to regulate cell adhesion, and not to induce (cell autonomous) signaling events. Additionally, the secreted extracellular domain of cadherin-11 (EC1-3) retains biological activity. This fragment can bind to a number of cell surface molecules in tissue culture including full-length cadherin-11 and specific members of the ADAM family. This observation suggests that EC1-3 may interact with full-length cadherin-11 molecules in vivo, and inhibit cadherin-11 mediated cell adhesion during CNC migration. EC1-3 can rescue CNC migration in embryos that overexpress cadherin-11, further supporting this hypothesis. Many of the above observations have been published in my first-author paper entitled “Extracellular processing of cadherin-11 by ADAM metalloproteases is essential for Xenopus cranial neural crest migration” published in the journal Molecular Biology of the Cell in 2009. Some of the unpublished work in this dissertation further focuses on how EC1-3 effects CNC migration in an ex vivo environment. During these studies, the observation was made that overexpression of EC1-3 in a cranial neural crest explant produces abnormal directional movement. In these experiments, it appeared as though certain regions of the CNC explant were “attracting” other regions of the explant. The preliminary studies described in chapter IV are aimed at answering the question; does EC1-3 attract migrating CNC cells? Here, we generated a Matlab program in order to effectively quantify the amount of directional movement of CNC explants presented with a source of EC1-3. In addition to quantifying cell directionality, this program can also decipher between cells moving with random or directed motion, and measure the velocity of cell migration within certain coordinates. Therefore, this program should be useful other ex vivo studies that require the observation of these features. To conclude, the work presented in this dissertation suggests that the role of cadherin-11 during cranial neural crest migration is predominately based on the adhesive function. In order for CNC migration to proceed, the amount of cadherin-11 mediated cell-cell adhesion is tightly regulated throughout this process. These cell-cell interactions are likely important for “sheet” and “branch” migration where CNC cells maintain a lot of cell-cell cohesion. ADAM Cadherin Cell migration Cell signaling Cranial neural crest Developmental biology/Embryology Cell Biology

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