Regulation and substrate specificity of the Git and AZAP ARTGAP families /

Cuthbert, Ellen Jebb.

January 2008

Thesis (Ph. D.)--University of Virginia, 2008. / Includes bibliographical references. Also available via the Internet as viewed 10 July 2008.

The role of the P2X7 receptor in injury-induced calcium dynamics and cell migration in the corneal epithelium

Minns, Martin Scott

08 April 2016

Wound healing in the corneal epithelium is an essential process to maintain corneal clarity and organism health. The earliest events of cellular injury response include the release of nucleotides and the activation of P2 purinergic receptors. While the purinergic receptor P2X7 has been shown to promote cell migration, its role in corneal epithelial wound healing is still poorly understood. The goal of this work is to better understand the role of P2X7 in the injury response. We analyzed P2X7 expression after epithelial injury in rat corneal organ cultures and found that the receptor localizes to the leading edge of the corneal epithelium. However, overall mRNA and protein expression of P2X7 decreased after injury. Inhibition of P2X7 activation significantly delayed wound closure and prevented the leading edge-localization after injury. We found that P2X7 inhibition altered the wound-induced calcium wave in epithelial cells and altered the number and distribution of focal adhesions in the migrating cells. Live cell imaging of epithelial cells showed that P2X7 inhibition led to altered actin rearrangement, with thick actin bundles in the treated cells. In order to determine the importance of P2X7 in epithelial differentiation and stratified cell migration, we developed a stratified culture model. The cells in the stratified model expressed proliferative and differentiation markers similar to organ cultured corneas, as well as similar P2X7 expression and localization after injury. Together, these results show the importance of P2X7 in the overall purinergic response to injury, and provide tools to study P2X7 in stratified corneal cell migration. To determine if P2X7 may contribute to pathologic delayed wound healing in diseases such as type 2 diabetes, we analyzed P2X7 expression in diabetic human corneas and diabetic model rodent corneas. We showed that P2X7 expression is significantly elevated in unwounded diabetic corneas, and that wound healing is delayed in the rodent model. These data show that elevated P2X7 expression may contribute to the delayed healing in disease and may be a possible therapeutic target.

Cellular biology

Calcium

Cell migration

Cornea

Epithelium

Focal adhesions

Purinergic receptors

Estímulo por soro em fibroblastos quiescentes induz a fosforilação da miosina-Va e sua localização em adesões focais / Serum by stimulation in quiescent fibroblasts induces phosphorylation of myosin - Va and its location in focal adhenosis

Johnny Alex Rockenbach Zenzen

11 March 2016

A montagem e desmontagem das adesões focais (AF) desempenham um papel fundamental em diversos processos celulares, incluindo migração celular e sobrevivência. Resultados prévios do nosso laboratório mostram que fibroblastos nulos ou silenciados para miosina-Va sofrem um atraso na desmontagem das adesões, sugerindo um papel para a miosinaVa neste processo. Neste trabalho, visamos analisar a dinâmica de montagem das AF em fibroblastos murinos imortalizados NIH3T3, utilizando sondas fluorescentes para visualização de componentes de adesão focal. A formação das AF foi analisada após estímulo por soro de células quiescentes, o que leva a intensa polimerização de actina, reorganização do citoesqueleto e montagem das AF. A cinética de montagem das AF foi observada em ensaios ao longo do tempo, de células fixadas em 0, 5, 15, 30, 120 minutos após estímulo, e marcadas para miosina-Va fosforilada (p-miosina-Va, S1650), FAK fosforilada (p-FAK, Y397), vinculina, dinamina-2, integrina-?1, faloidina, Ki67 e DAPI. Os nossos resultados mostraram um aumento de fluorescência de p-miosina-Va por todo o citoplasma após a estímulo com soro, e revelaram que a p-miosina-Va co-localiza com pFAK nas AF logo após o estímulo, essa localização da p-miosina-Va nas AF diminui ao passar do tempo e retorna após 120 minutos. Isto é consistente com os resultados anteriores de um papel da miosina-Va na dinâmica das AF. Também é possível perceber uma maior concentração de p-miosina-Va e dinamina-2 na região perinuclear, 5 minutos após estímulo, e o espalhamento de ambas as proteínas pelo citoplasma com o passar do tempo. Demonstramos, por Western blotting, que o estímulo por soro não causa alteração na quantidade total de miosina-Va em nenhum dos tempos analisados em relação à condição de quiescência, mas induz, após 5 e 15 minutos, um aumento apreciável de p-miosina-Va, que sofre queda e variações nos tempos posteriores. Para nosso conhecimento, esta é a primeira demonstração de que a fosforilação da miosina-Va aumenta em resposta ao soro e estamos investigando se este evento está ligado à dinâmica das adesões focais em fibroblastos / The assembly and disassembly of focal adhesions (FA) play a critical role in several cellular process, including cell migration and survival. Previous work from our laboratory showed that fibroblasts without myosin-Va show a delay in focal adhesion disassembly, suggesting a role for myosin-Va in this process. In this work, we aim at imaging the dynamics of focal adhesion disassembly and reassembly in cells, with fluorescent probes for visualization of focal adhesion components. Here, we used murine NIH3T3 fibroblasts to analyze FA formation after serum stimulation of quiescent cells, which leads to intense polymerization of actin and reorganization of the cytoskeleton and FA assembly. The kinetics of FA assembly was observed in a time-course assay of cells fixed at 0, 5, 15, 30 and 120 min after serum stimulation, and stained for phosphorylated myosin-Va (p-myosin-Va, S1650), phosphorylated FAK (p-FAK, Y397), vinculin, phalloidin and DAPI. Our results showed an increase of pmyosin-Va staining throughout the cytoplasm upon serum stimulation, and revealed that pmyosin-Va does not colocalize with FAK in FA at early time points. However, colocalization is observed after 30 to 120 min. This is consistent with previous results of a role for myosin-Va in FA disassembly. It is also possible to observe a higher concentration of p-myosin-Va and dynamin-2 in the perinuclear region 5 minutes after stimulation, and the spreading of both proteins in the cytoplasm over time. We demonstrate by Western blotting that serum stimulation does not cause change in total amount of myosin-Va, in any of the times analyzed in relation to the quiescent condition, but induces, after 5 and 15 minutes, an appreciable increase of pmyosin-Va suffering drop and variations in the later times. To our knowledge, this is the first demonstration that phosphorylation of myosin-Va increases in response to serum and we are investigating whether this event is connected to the dynamics of focal adhesions in fibroblasts

Adesão Focal

FAK

Miosina Va

Quiescência

FAK

Focal Adhesions

Myosin Va

Quiescence

Regulation of vascular smooth muscle actin cytoskeleton by Hic-5

Pieri, Maria

January 2016

Vascular smooth muscle cells (VSMC) constitute an important component of blood vessels and are primarily responsible for vessel contraction. In vascular disorders such as hypertension and atherosclerosis as well as pregnancy and exercise, VSMC demonstrate increased capacity to proliferate and migrate, resulting in vascular remodelling. The actin cytoskeleton is an important component of vascular contractility and is also essential for proliferation and migration of VSMC. Vasoactive agonists such as Endothelin-1 (ET-1) and Noradrenaline (NA), have been shown to mediate VSMC contraction through changes in actin cytoskeleton and focal adhesion (FA) remodelling, and have also been reported to cause VSMC migration in the appropriate setting. The aim of this study was to investigate the signalling mechanisms responsible for FA dependent actin cytoskeleton remodelling of VSMC in response to ET-1 and NA, with a special focus on Hydrogen peroxide-inducible clone 5 (Hic-5). The latter is a FA protein shown to regulate actin cytoskeleton dynamics in small arteries in response to Noradrenaline (NA) and the response of VSMC to arterial injury and abdominal aortic aneurysm. We have shown that Src-dependent tyrosine phosphorylation of Hic-5 regulated its subcellular localisation in mouse embryonic fibroblasts and VSMC, but was not responsible for the effects of ET-1 and NA on actin filament remodelling or Hic-5 redistribution in VSMC. ET-1 stimulation caused an increase in Hic-5 localisation at FAs concurrent with an increase in the density of actin filaments, whereas NA stimulation caused a decrease in Hic-5 localisation at FAs in VSMC concurrent with actin filament redistribution at the cell cortex. Hic-5 was the FA protein that demonstrated the most dramatic changes in subcellular localisation in response to ET-1 and NA, when compared to paxillin (Hic-5 homologue) or vinculin (classical FA marker). NA-mediated changes in Hic-5 localisation and actin filament distribution were more pronounced compared to ET-1-mediated changes. Further investigation into the NA-induced changes suggested that actin filament disassembly preceded Hic-5 relocalisation from FAs to the cytosol. These results show that vasoactive peptides cause Hic-5 relocalisation and actin filament rearrangement in VSMCs in an agonist-dependent manner. Given that VSMC FA remodelling and actin cytoskeleton reorganisation occur during contraction and arterial remodelling, our data identify Hic-5 as a key regulator of these processes in response to NA and ET-1. Furthermore, these data have implications in agonist- specific VSM function such as migration and contraction.

572.8

Vascular smooth muscle: a target for treatment of aging-induced aortic stiffness

Gao, Yuan Zhao

28 October 2015

Cardiovascular disease is the leading cause of human death worldwide. Currently, the prevalence of cardiovascular disease and health care costs associated with its onset continue to increase in both developed and developing societies. Concordant with the need to improve preventative measures is the imperative to develop more effective and efficient remedies for incident cardiovascular pathologies. Increased aortic stiffness with aging has recently emerged as an early, independent, and consistent physiological predictor of cardiovascular disease and represents an attractive target for possible therapeutic options. The success of any biomedical strategy in this regard is incumbent upon comprehension of biological processes and mechanical properties attributable to constituent components within the aortic wall. This dissertation tested the hypothesis that aging-induced changes to smooth muscle maintenance of biomechanical homeostasis within the aorta lead to undesirable increases in stiffness, correlative with increased risk of negative cardiovascular outcomes. Conventionally, mechanical studies and models have identified extracellular matrix as the primary determinant of changes in stiffness, but new research presented here shows that this may not be true. In viable ex vivo preparations of aortic tissue, roughly half of the maximal elastic modulus results from alpha-agonist activation of smooth muscle cells. Investigation of the biochemical interactions that characterize this effect revealed a link between aging and decreased expression of Src, a kinase involved in numerous signaling pathways governing cellular growth and survival, as well as defective regulation of focal adhesions between the smooth muscle cells and extracellular matrix. These findings were integrated into a model of aortic contractility and stiffness that establishes an aging-impaired regulatory complex comprising focal adhesions and non-muscle actin cytoskeleton in vascular smooth muscle cells. A better understanding of the mechanisms underlying this model may motivate the design of potential therapeutics, deliverable to previously overlooked target sites within aortic smooth muscle, and ultimately novel treatments for aging-induced cardiovascular disease. / 2017-10-27T00:00:00Z

Biomedical engineering

Src

Actin cytoskeleton

Aging

Aortic stiffness

Focal adhesions

Vascular smooth muscle

Mean Square Displacement for a Discrete Centroid Model of Cell Motion and a Mathematical Analysis of Focal Adhesion Lifetimes and Their Effect on Cell Motility

Rosen, Mary Ellen Furner

09 February 2021

One of the characteristics that distinguishes living things from non-living things is motility. On the cellular level, the motility or non-motility of different types of cells can be life building, life-saving or life-threatening. A thorough study of cell motion is needed to help understand the underlying mechanisms that enhance or prohibit cell motion. We introduce a discrete centroid model of cell motion in the context of a generalized random walk. We find an approximation for the theoretical mean square displacement (MSD) that uses a subset of the state space to estimate the MSD for the entire space. We give some intuition as to why this is an unexpectedly good estimate. A lower and upper bound for the MSD is also given. We extend the centroid model to an ODE model and use it to analyze the distribution of focal adhesion (FA) lifetimes gathered from experimental data. We found that in all but one case a unimodal, non-symmetric gamma distribution is a good match for the experimental data. We use a detach-rate function in the ODE model to determine how long a FA will persist before it detaches. A detach-rate function that is dependent on both force and time produces distributions with a best fit gamma curve that closely matches the data. Using the data gathered from the matching simulations, we calculate both the cell speed and mean FA lifetime and compare them. Where available, we also compare this relationship to that of the experimental data and find that the simulation reasonably matches it in most cases. In both the simulations and experimental data, the cell speed and mean FA lifetime are related, with longer mean lifetimes being indicative of slower speeds. We suspect that one of the main predictors of cell speed for migrating cells is the distribution of the FA lifetimes.

Cell motion

biology

dynamical systems

stochastic process

focal adhesions

Physical Sciences and Mathematics

Mean Square Displacement for a Discrete Centroid Model of Cell Motion and a Mathematical Analysis of Focal Adhesion Lifetimes and Their Effect on Cell Motility

Rosen, Mary Ellen Furner

09 February 2021

One of the characteristics that distinguishes living things from non-living things is motility. On the cellular level, the motility or non-motility of different types of cells can be life building, life-saving or life-threatening. A thorough study of cell motion is needed to help understand the underlying mechanisms that enhance or prohibit cell motion. We introduce a discrete centroid model of cell motion in the context of a generalized random walk. We find an approximation for the theoretical mean square displacement (MSD) that uses a subset of the state space to estimate the MSD for the entire space. We give some intuition as to why this is an unexpectedly good estimate. A lower and upper bound for the MSD is also given. We extend the centroid model to an ODE model and use it to analyze the distribution of focal adhesion (FA) lifetimes gathered from experimental data. We found that in all but one case a unimodal, non-symmetric gamma distribution is a good match for the experimental data. We use a detach-rate function in the ODE model to determine how long a FA will persist before it detaches. A detach-rate function that is dependent on both force and time produces distributions with a best fit gamma curve that closely matches the data. Using the data gathered from the matching simulations, we calculate both the cell speed and mean FA lifetime and compare them. Where available, we also compare this relationship to that of the experimental data and find that the simulation reasonably matches it in most cases. In both the simulations and experimental data, the cell speed and mean FA lifetime are related, with longer mean lifetimes being indicative of slower speeds. We suspect that one of the main predictors of cell speed for migrating cells is the distribution of the FA lifetimes.

Cell motion

biology

dynamical systems

stochastic process

focal adhesions

Physical Sciences and Mathematics

L’influence d’une surface nanoporeuse de titane sur l’activité de cellules ostéoblastiques

Guadarrama Bello, Dainelys

04 1900

Afin d’améliorer la performance et l’intégration des biomatériaux dans le tissu hôte, l’intérêt actuel est d’exploiter des approches de nanotechnologie pour produire des biomatériaux possédant des surfaces bioactives. Il est connu que l’interaction des cellules avec la surface des biomatériaux détermine la réponse du tissu hôte et le succès d’un implant. La topographie est l'un des principaux facteurs influençant l'activité fonctionnelle des cellules en contact avec des biomatériaux. Cependant, les mécanismes impliqués demeurent imprécis. Notre groupe a exploité un traitement chimique simple afin de créer des surfaces de titane nanoporeuses uniques qui expriment une influence cellulaire sélective, favorisant ainsi la formation osseuse in vivo et in vitro. Dans ce travail, nous avons réduit la durée du traitement afin d’obtenir une surface nanotopographique mono-planaire, puis évaluer l’influence d’une telle surface sur la formation par des cellules pré-ostéoblastiques MC3T3-E1 d’adhésions focales et de filopodes, ainsi que sur l’expression de gènes codant pour différentes protéines associées à l’adhésion et la signalisation cellulaire. Des disques de titane commercialement pur (cp-Ti) ont été traités avec un mélange d’acide sulfurique et de peroxyde d’hydrogène (50/50 v/v) pendant 1.5 heures. La caractérisation par microscopie électronique à balayage à haute résolution et pour microscopie à force atomique a confirmé la formation d’une surface effectivement mono-planaire caractérisée par des nanopores d’une taille moyenne de 20 ± 5 nm. Les cellules ont été mises en culture pour des périodes de 6, 24 et 72 heures sur des disques contrôles polis et avec une surface nanoporeuse. L'analyse de l’expression de la vinculine par immunofluorescence a révélé un plus grand nombre d’adhésions focales par les cellules sur la surface traitée. Le PCR quantitatif a également montré une augmentation significative de l'expression des gènes pour différents marqueurs d'adhésions focales, telles que paxilline, taline, et différentes intégrines comme par exemple les intégrines α1, β1 et α5. Par microscopie électronique à balayage, les cellules sur la surface nanoporeuse révèlent une présence plus importante de filopodes vis à vis des surfaces contrôles. Ces structures affichent de manière unique de très petites protrusions membranaires latérales d’entre 10-15 nm qui suivent les bords des nanopores. L’augmentation des adhésions focales, l'abondance des filopodes et de leurs petites protrusions pourraient engendre interaction accrue avec la surface et modifier les relations biomécaniques à l’échelle nanométrique pour déclencher des cascade régulant la prolifération cellulaire. / To improve the performance and integration of biomaterials in the host tissue, the focus is presently on exploiting nanotechnology approaches to produce biomaterials with bioactive surfaces. It is known that the cell-biomaterial interactions determine the response of the host tissue and therefore the success of implants. Topography is a key factor that influences the functional activity of cells; however, the mechanisms implicated remain unclear. Our group has exploited a simple chemical treatment to create unique nanoporous titanium surfaces that selectively influence cell behaviour and favor osteogenic activity both in vitro and in vivo. In this work, we have reduced treatment time in order to obtain a monoplanar nanostructured surface, and we have evaluated its influence on the formation of focal adhesions, filopodia, and on gene expression for different cell adhesion and signaling proteins by MC3T3-E1 pre-osteoblastic cells. Commercially pure titanium (cp-Ti) was treated with a mixture of H2SO4/H2O2 (50/50 v/v) for 1.5h. Characterization by high-resolution field-emission scanning electron microscopy and atomic force microscopy characterization showed the formation of a nanoporous surface with a mean pore diameter of 20 ± 5 nm. Cells were cultured and plated on polished (control) and nanotextured discs for periods of 6, 24 and 72 hours. Immunofluorescence analysis of vinculin expression revealed the formation of more focal adhesions by cells seeded on nanostructured surfaces. Quantitative PCR likewise showed significant increase of gene expression for various focal adhesion markers, including paxillin, talin, and different integrins such as integrin α1, β1 and α5. As compared to controls, scanning electron microscopy of cells on the treated surface revealed the presence of more filopodia. These uniquely displayed very small lateral membrane protrusions between 10-15 nm that appeared to follow the walls of the nanopores. Together with the increase in focal adhesions, the abundance of filopodia and associated protrusions could contribute to the adhesive interaction with the surface and modify the nanoscale biomechanical relationships to trigger cellular cascades regulating cell proliferation.

nanotopographie

filopodes

adhésions focales

expression des gènes

Nanotopography

Filopodia

Focal adhesions

Gene expression

Strukturní a regulační aspekty aktivace kinázy Src / Structural and regulatory aspects of Src kinase activation

Koudelková, Lenka

January 2020

Src kinase plays a crucial role in a multitude of fundamental cellular processes. Src is an essential component of signalling pathways controlling cellular proliferation, motility or differentiation, and is often found deregulated in tumours. Src activity is therefore maintained under stringent and complex regulation mediated by SH3 and SH2 domains and the phosphorylation state of tyrosines 416 and 527. Active Src adopts an open conformation whereas inactive state of the kinase is characterised by a compact structure stabilised by inhibitory intramolecular interactions. We identified phosphorylation of tyrosine 90 within binding surface of SH3 domain as a new regulatory switch controlling Src kinase activation. Using substitutions mimicking phosphorylation state of the residue we demonstrated that tyrosine 90 phosphorylation controls Src catalytic activity, conformation and interactions mediated by the SH3 domain, representing a positive regulatory mechanism leading to elevated activation of mitogenic pathways and increased invasive potential of cells. Based on correlation between compactness of Src structure and its catalytic activity, we constructed a FRET-based sensor of Src conformation enabling to measure the dynamics of Src activation in cells with spatio-temporal resolution. We found that...

Biologický význam tyrozínové fosforylace v SH3 doméně proteinu CAS / The biological importance of CAS SH3 domain tyrosine phosphorylation

Janoštiak, Radoslav

January 2010

Protein CAS is a major tyrosine-phosphorylated protein in cells transformed by v-crk and v-src oncogenes. It is a multidomain adaptor protein, which serves as a scaffold for assembly of signalling complexes which are important for migration and invasiveness of Src-transformed cells. A novel phosphorylation site in N-terminal SH3 domain was identified - tyrosine 12 located on binding surface of CAS SH3 domain. To study biological importance of tyrosine 12 phosphorylation, non-phosphorylable (Y12F) and phosphomimicking ( Y12E) mutant of CAS were prepared. We found that phosphomimicking mutation Y12E leads to decreased interaction of CAS SH domain with kinase FAK a phosphatase PTP-PEST and also reduce tyrosine phosphorylation of FAK. Using GFP-tagged CAS protein, we show that Y12E mutation caused delocalization of CAS from focal adhesion but has no effect on localization of CAS to podosome-type adhesion. Non-phosphorylable mutation Y12F cause hyperphosphorylation of CAS substrate domain and decrease turnover of focal adhesion and associated cell migration of mouse embryonal fibroblasts (MEFs) independent to integrin singalling. Analogically to migration, CAS Y12F decrease invasiveness of Src-transformed MEF. The results of this diploma thesis show that phosphorylation of Tyr12 in CAS SH3 domain is...