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Single Cell Force Spectroscopy for Quantification of Cellular Adhesion on SurfacesJanuary 2016 (has links)
abstract: Cell adhesion is an important aspect of many biological processes. The atomic force microscope (AFM) has made it possible to quantify the forces involved in cellular adhesion using a technique called single cell force spectroscopy (SCFS). AFM based SCFS offers versatile control over experimental conditions for probing directly the interaction between specific cell types and specific proteins, surfaces, or other cells. Transmembrane integrins are the primary proteins involved in cellular adhesion to the extra cellular matix (ECM). One of the chief integrins involved in the adhesion of leukocyte cells is αMβ2 (Mac-1). The experiments in this dissertation quantify the adhesion of Mac-1 expressing human embryonic kidney (HEK Mac-1), platelets, and neutrophils cells on substrates with different concentrations of fibrinogen and on fibrin gels and multi-layered fibrinogen coated fibrin gels. It was shown that multi-layered fibrinogen reduces the adhesion force of these cells considerably. A novel method was developed as part of this research combining total internal reflection microscopy (TIRFM) with SCFS allowing for optical microscopy of HEK Mac-1 cells interacting with bovine serum albumin (BSA) coated glass after interacting with multi-layered fibrinogen. HEK Mac-1 cells are able to remove fibrinogen molecules from the multi-layered fibrinogen matrix. An analysis methodology for quantifying the kinetic parameters of integrin-ligand interactions from SCFS experiments is proposed, and the kinetic parameters of the Mac-1 fibrinogen bond are quantified. Additional SCFS experiments quantify the adhesion of macrophages and HEK Mac-1 cells on functionalized glass surfaces and normal glass surfaces. Both cell types show highest adhesion on a novel functionalized glass surface that was prepared to induce macrophage fusion. These experiments demonstrate the versatility of AFM based SCFS, and how it can be applied to address many questions in cellular biology offering quantitative insights. / Dissertation/Thesis / Doctoral Dissertation Physics 2016
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Cellular locomotion and adhesion in the context of different substrate propertiesBaronsky, Thilo 10 June 2016 (has links)
No description available.
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Cell adhesion and cell mechanics during zebrafish development / Zelladhäsion und Zellmechanik während der ZebrafischentwicklungKrieg, Michael 11 January 2010 (has links) (PDF)
During vertebrate development, gastrulation leads to the formation of three distinct germlayers. In zebrafish a central process is the delamination and the ingression of single cells from a common ancestor tissue - that will lead to the formation of the germlayers. Several molecules have been identified to regulate this process but the precise cellular mechanisms are poorly understood. Differential adhesiveness, a concept first introduced by Steinberg over 40 years ago, has been proposed to represent a key phenomena by which single hypoblast cells separate from the epiblast to form the mesendoderm at later stages. In this work it is shown that differential adhesion among the germlayer progenitor cells alone cannot predict germlayer formation. It is a combination of several mechanical properties such as cell cortex tension, cell adhesion and membrane mechanical properties that influence the migratory behavior of the constituent cells.
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Analyzing Interactions Between Cells And Extracellular Matrix By Atomic Force MicroscopyFriedrichs, Jens 10 December 2009 (has links) (PDF)
Interactions of cells with the extracellular matrix (ECM) have important roles in various physiological and pathological processes, including tissue morphogenesis during embryonic development, wound healing and tumor invasion. Although most of the proteins involved in cell-ECM interactions have been identified, the underlying mechanisms and involved signaling pathways are incompletely understood. Here, atomic force microscope-based imaging and single-cell force measurements were used to characterize the interactions of different cell types with ECM proteins.
The interplay between cells and ECM is complex. However, two interaction types, protein-protein and protein-carbohydrate, predominate. Integrins, adhesion receptors for ECM, mediate the former, galectins, a family of animal lectins, the latter. In the second chapter of this thesis, the contributions of both receptor families to the interactions of epithelial MDCK cells with ECM proteins are presented. It was found that galectins-3 and 9 are highly expressed in MDCK cells and required for optimal long-term adhesion (90 minutes) to ECM proteins collagen-I and laminin-111. Interestingly, early adhesion (< 2 minutes) to laminin-111, was integrin-independent and instead mediated by carbohydrate interactions and galectins. In contrast, early adhesion to collagen-I was exclusively mediated by integrins. Moreover, cells frequently entered an enhanced adhesion state, marked by a significant increase in the force required for cell detachment. Although adhesion was mediated by integrins, adhesion enhancement was especially observed in cells depleted for galectin-3. It was proposed that galectin-3 influences integrin-mediated adhesion complex formation by altering receptor clustering.
To control their attachment to ECM proteins, cells regulate integrin receptors. One regulatory process is integrin crosstalk, where the binding of one type of integrin influences the activity of another type. In the third chapter, the implementation of a single-cell force spectroscopy assay to identify such crosstalks and gain insight into their mechanisms is described. In this assay the interactions of integrin receptors being specifically attached to one ligand are characterized in dependence of another ligand-bond receptor pair. With this assay a crosstalk between collagen-binding integrin α1β1 and fibronectin-binding integrin α5β1 was identified in HeLa cells. This crosstalk was directional from integrin α1β1 to integrin α5β1 and appeared to regulate integrin α5β1 by inducing its endocytosis.
In the fourth and final chapter, mechanisms of matrix-induced cell alignment were studied by imaging cells on two-dimensional matrices assembled of highly aligned collagen fibrils. Integrin α2β1 was identified as the predominant receptor mediating cell polarization. Time-lapse AFM demonstrated that during alignment cells deform the matrix by reorienting individual collagen fibrils. Cells deformed the collagen matrix asymmetrically, revealing an anisotropy in matrix rigidity. When matrix rigidity was rendered uniform by chemical cross-linking or when the matrix was formed from collagen fibrils of reduced tensile strength, cell polarization did not occur. This suggested that both the high tensile strength and pliability of collagen fibrils contribute to the anisotropic rigidity of the matrix and lead to directional cellular traction and cell polarization. During alignment, cellular protrusions contacted the collagen matrix from below and above. This complex entanglement of cellular protrusions and collagen fibrils may further promote cell alignment by maximizing cellular traction.
The work presented here adds to the understanding of cell-ECM interactions. Atomic force microscopy imaging allowed characterizing the behavior of cells on nanopatterned collagen matrices whereas single-cell force spectroscopy revealed insights into the regulation of cell adhesion by galectins. Furthermore, methodological advances in the single-cell force spectroscopy assay allowed the intracellular regulation of receptor molecules to be studied. The work demonstrates that atomic force microscopy is a versatile tool to study cell-ECM interactions.
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Analyzing Interactions Between Cells And Extracellular Matrix By Atomic Force MicroscopyFriedrichs, Jens 11 November 2009 (has links)
Interactions of cells with the extracellular matrix (ECM) have important roles in various physiological and pathological processes, including tissue morphogenesis during embryonic development, wound healing and tumor invasion. Although most of the proteins involved in cell-ECM interactions have been identified, the underlying mechanisms and involved signaling pathways are incompletely understood. Here, atomic force microscope-based imaging and single-cell force measurements were used to characterize the interactions of different cell types with ECM proteins.
The interplay between cells and ECM is complex. However, two interaction types, protein-protein and protein-carbohydrate, predominate. Integrins, adhesion receptors for ECM, mediate the former, galectins, a family of animal lectins, the latter. In the second chapter of this thesis, the contributions of both receptor families to the interactions of epithelial MDCK cells with ECM proteins are presented. It was found that galectins-3 and 9 are highly expressed in MDCK cells and required for optimal long-term adhesion (90 minutes) to ECM proteins collagen-I and laminin-111. Interestingly, early adhesion (< 2 minutes) to laminin-111, was integrin-independent and instead mediated by carbohydrate interactions and galectins. In contrast, early adhesion to collagen-I was exclusively mediated by integrins. Moreover, cells frequently entered an enhanced adhesion state, marked by a significant increase in the force required for cell detachment. Although adhesion was mediated by integrins, adhesion enhancement was especially observed in cells depleted for galectin-3. It was proposed that galectin-3 influences integrin-mediated adhesion complex formation by altering receptor clustering.
To control their attachment to ECM proteins, cells regulate integrin receptors. One regulatory process is integrin crosstalk, where the binding of one type of integrin influences the activity of another type. In the third chapter, the implementation of a single-cell force spectroscopy assay to identify such crosstalks and gain insight into their mechanisms is described. In this assay the interactions of integrin receptors being specifically attached to one ligand are characterized in dependence of another ligand-bond receptor pair. With this assay a crosstalk between collagen-binding integrin α1β1 and fibronectin-binding integrin α5β1 was identified in HeLa cells. This crosstalk was directional from integrin α1β1 to integrin α5β1 and appeared to regulate integrin α5β1 by inducing its endocytosis.
In the fourth and final chapter, mechanisms of matrix-induced cell alignment were studied by imaging cells on two-dimensional matrices assembled of highly aligned collagen fibrils. Integrin α2β1 was identified as the predominant receptor mediating cell polarization. Time-lapse AFM demonstrated that during alignment cells deform the matrix by reorienting individual collagen fibrils. Cells deformed the collagen matrix asymmetrically, revealing an anisotropy in matrix rigidity. When matrix rigidity was rendered uniform by chemical cross-linking or when the matrix was formed from collagen fibrils of reduced tensile strength, cell polarization did not occur. This suggested that both the high tensile strength and pliability of collagen fibrils contribute to the anisotropic rigidity of the matrix and lead to directional cellular traction and cell polarization. During alignment, cellular protrusions contacted the collagen matrix from below and above. This complex entanglement of cellular protrusions and collagen fibrils may further promote cell alignment by maximizing cellular traction.
The work presented here adds to the understanding of cell-ECM interactions. Atomic force microscopy imaging allowed characterizing the behavior of cells on nanopatterned collagen matrices whereas single-cell force spectroscopy revealed insights into the regulation of cell adhesion by galectins. Furthermore, methodological advances in the single-cell force spectroscopy assay allowed the intracellular regulation of receptor molecules to be studied. The work demonstrates that atomic force microscopy is a versatile tool to study cell-ECM interactions.
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Cell adhesion and cell mechanics during zebrafish developmentKrieg, Michael 07 December 2009 (has links)
During vertebrate development, gastrulation leads to the formation of three distinct germlayers. In zebrafish a central process is the delamination and the ingression of single cells from a common ancestor tissue - that will lead to the formation of the germlayers. Several molecules have been identified to regulate this process but the precise cellular mechanisms are poorly understood. Differential adhesiveness, a concept first introduced by Steinberg over 40 years ago, has been proposed to represent a key phenomena by which single hypoblast cells separate from the epiblast to form the mesendoderm at later stages. In this work it is shown that differential adhesion among the germlayer progenitor cells alone cannot predict germlayer formation. It is a combination of several mechanical properties such as cell cortex tension, cell adhesion and membrane mechanical properties that influence the migratory behavior of the constituent cells.
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Quantifying adhesive interactions between cells and extracellular matrix by single-cell force spectroscopyTaubenberger, Anna Verena 08 October 2009 (has links) (PDF)
Interactions of cells with their environment regulate important cellular functions and are required for the organization of cells into tissues and complex organisms. These interactions involve different types of adhesion receptors. Interactions with extracellular matrix (ECM) proteins are mainly mediated by the integrin family of adhesion molecules. Situations in which integrin-ECM interactions are deregulated cause diseases and play a crucial role in cancer cell invasion. Thus, the mechanisms underlying integrin-binding and regulation are of high interest, particularly at the molecular level.
How can cell-ECM interactions be studied? While there are several methods to analyze cell adhesion, few provide quantitative data on adhesion forces. One group, single-cell force spectroscopy (SCFS), quantifies adhesion at the single-cell level and can therefore differentiate the adhesive properties of individual cells. One implementation of SCFS is based on atomic force microscopy (AFM); this technique has been employed in the presented work. Advantageously AFM-SCFS combines high temporal and spatial cell manipulation, the ability to measure a large range of adhesion forces and sufficiently high-force resolution to allow the study of single-molecule binding events in the context of a living cell. Since individual adhesion receptors can be analyzed within their physiological environment, AFM-SCFS is a powerful tool to study the mechanisms underlying integrin-regulation.
The presented work is split into six chapters. Chapter one gives background information about cell-ECM interactions. In chapter two, different adhesion assays are compared and contrasted. The theoretical Bell-Evans model which is used to interpret integrin-mediated cell adhesion is discussed in chapter three. Thereafter, the three projects that form the core of the thesis are detailed in chapters four through six.
In the first project (chapter 4), α2β1-integrin mediated cell adhesion to collagen type I, the most abundant structural protein in vertebrates, was quantified using CHO cells. Firstly, α2β1-collagen interactions were investigated at the single-molecule level. Dynamic force spectroscopy permitted calculation of bond specific parameters, such as the bond dissociation rate koff (1.3 ± 1.3 sec-1) and the barrier width xu (2.3 ± 0.3 Å). Next, α2β1-integrin mediated cell adhesion to collagen type I was monitored over contact times between 0 and 600 sec. Thereby the kinetics of α2β1-integrin mediated interactions was explored and insights into the underlying binding mechanisms were gained.
In the second project (chapter five), effects of cryptic integrin binding sites within collagen type I exerted on pre-osteoblasts were investigated. Collagen type I matrices were thermally denatured which lead to exposure of cryptic RGD (Arg-Gly-Asp)-motifs. As a consequence pre-osteoblasts enhanced their adhesion to denatured collagen. Compared to native collagen type I, adhesion to denatured collagen was mediated by a different set of integrins, including αv- and α5β1-integrins. Cells grown on denatured collagen showed enhanced spreading and motility, which correlated with increased focal adhesion kinase phosphorylation levels. Moreover, osteogenic differentiation kinetics and differentiation potential were increased on denatured collagen. The findings of this project open new perspectives for optimization of tissue engineering substrates.
In the third part (chapter six), the effect of the fusion protein BCR/ABL, a hallmark of chronic myeloid leukemia, on adhesion of myeloid progenitor cells was studied. Adhesion between BCR/ABL transformed progenitor cells to bone marrow derived stromal cells and to different ECM proteins was quantitatively compared to that of control cells. The tyrosine kinase activity of BCR/ABL enhanced cell adhesion, which was blocked by imatinib mesylate, a drug interfering with BCR/ABL activity. BCR/ABL-enhanced adhesion correlated with increased β1-integrin cell surface concentrations. Since adhesion of leukemic cells to the bone marrow compartment is critical for the development of drug resistance, the reported results may provide a basis for optimized target therapies.
In the three described projects AFM-based SCFS was applied to investigate early steps of integrin-mediated adhesion at the molecular level. Taken together, the results demonstrate that AFM-SCFS is a versatile tool that permits monitoring of cell adhesion from single-molecule interactions to the formation of more complex adhesion sites at the force level. / Interaktionen zwischen Zellen und ihrer Umgebung sind maßgeblich an der Regulierung zellulärer Funktionen beteiligt und daher notwendig für die Organisation von Zellen in Geweben und komplexen Organismen. Zellinteraktionen mit der extrazellulären Matrix (EZM) werden hauptsächlich durch Integrine vermittelt. Situationen, in denen Integrin- EZM Interaktionen verändert sind, können Krankheiten verursachen und spielen zudem eine wichtige Rolle bei der Invasion von Krebszellen. Daher besteht ein großes Interesse darin, die molekularen Mechanismen, die Integrin-EZM Interaktionen regulieren, besser zu verstehen.
Wie können Zell-EZM Interaktionen untersucht werden? Obwohl es mehrere Methoden gibt, mit denen Zelladhäsion untersucht werden kann, sind die wenigsten dazu geeignet, Zelladhäsionskräfte zu quantifizieren. Einzelzellspektroskopie erfasst die Adhäsionskräfte einzelner Zellen quantitativ und ermöglicht dadurch eine differenzierte Betrachtung der Adhäsion individueller Zellen. Eine Variante der Einzelzellspektroskopie basiert auf der Rasterkraftmikroskopie (AFM); diese Technik wurde in der vorliegenden Arbeit verwendet. Ein Vorteil von AFM- Einzelzellspektroskopie besteht darin, dass Zellen mit hoher zeitlicher und räumlicher Präzision manipuliert werden können. Zelladhäsionskräfte können zudem über einen großen Kraftbereich hinweg untersucht werden. Dabei ermöglicht es die hohe Kraftauflösung, einzelne Integrin-Ligandenbindungen in lebenden Zellen zu untersuchen.
Die vorliegende Arbeit gliedert sich in sechs Kapitel. Kapitel eins gibt Hintergrundinformationen über Zell-EZM Wechselwirkungen. In Kapitel zwei werden verschiedene Adhäsionsassays einander gegenüber gestellt. Das theoretische Bell-Evans Modell, mit dessen Hilfe die gewonnenen Daten interpretiert wurden, wird in Kapitel drei diskutiert. Im Anschluss werden drei Projekte, welche das Herzstück dieser Doktorarbeit bilden, in Kapiteln vier bis sechs näher ausgeführt.
Im ersten Projekt (Kapitel vier) wurde die Adhäsion von α2β1-Integrin exprimierenden CHO Zellen zu Kollagen I, dem häufigsten strukturellen Protein in Wirbeltieren, quantitativ untersucht. Zunächst wurden α2β1-Kollagen-Interaktionen auf Einzelmolekülebene analysiert. Mithilfe der dynamischen Kraftspektroskopie wurden für diese Bindung Dissoziationsrate koff (1.3 ± 1.3 sec-1) und Potentialbarrierenbreite xu (2.3 ± 0.3 Å) bestimmt. Daraufhin wurde die α2β1-vermittelte Adhäsion über einen Zeitraum von zehn Minuten untersucht. Dadurch konnten Einblicke in die Kinetik von α2β1-integrin vermittelter Zelladhäsion sowie in die zugrunde liegenden Regulationsmechanismen gewonnen werden.
Im zweiten Projekt (Kapitel fünf) wurde die Rolle von kryptischen Integrin-Bindungsstellen in Kollagen I untersucht. Die zuvor verwendeten Kollagenoberflächen wurden thermisch denaturiert, wodurch versteckte RGD (Arg-Gly-Asp)-Sequenzen freigelegt wurden. Die partielle Denaturierung hatte- verglichen mit nativem Kollagen I- eine erhöhte Adhäsion von Präosteoblasten (MC3T3-E1) zur Folge, was auf das Binden zusätzlicher Integrine zurückgeführt wurde. Im Unterschied zu nativem Kollagen wurde die Zelladhäsion zu denaturiertem Kollagen I u.a. durch αv- and α5β1-Integrine vermittelt. Präosteoblasten zeigten verstärktes Zellspreiten sowie höhere Motilität auf denaturiertem Kollagen I; zudem wurde ein erhöhtes Differenzierungpotential der Präosteoblasten festgestellt. Die in diesem Projekt erhaltenen Einblicke bilden eine hilfreiche Basis für die Entwicklung optimierter Oberflächen für diverse Zell- und Gewebekulturanwendungen.
Im dritten Projekt (Kapitel sechs) wurde der Einfluss des Fusionproteins BCR/ABL, charakteristisch für chronische myeloische Leukämie, auf die Adhäsion von myeloischen Vorläuferzellen untersucht. Dazu wurde die Adhäsion von BCR/ABL transformierten Vorläuferzellen (32D Zellen) bzw. Kontrollzellen zu Stromazellen (M2-10B4) sowie verschiedenen EZM Proteinen untersucht. BCR/ABL erhöhte die Zelladhäsion der myeloischen Vorläuferzellen signifikant. Dieser Effekt wurde durch die Zugabe von Imatinib, welches die Tyrosinkinaseaktivität von BCR/ABL inhibiert, aufgehoben. Die BCR/ABL-verstärkte Zelladhäsion korrelierte mit erhöhten β1-Integrin-konzentrationen. Da die Adhäsion von Leukämiezellen im Knockenmark bekanntermaßen kritisch für die Entwicklung von Resistenzen gegenüber verschiedenen Wirkstoffen ist, könnten die Ergebnisse dieser Studie eine Grundlage für die Entwicklung optimierter Target-Therapien sein.
In den drei beschriebenen Projekten wurde AFM Einzelzellspektroskopie verwendet, um Integrin- vermittelte Adhäsion auf molekularer Ebene zu untersuchen. Die Ergebnisse zeigen, dass AFM-Einzelzellspektroskopie ein vielseitiges Werkzeug darstellt, das überaus geeignet dazu ist, Zelladhäsion- ausgehend von Einzelmolekülinteraktionen bis hin zur Entstehung komplexerer Adhäsionsstellen- auf der Kraftebene zu verfolgen.
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Effet inhibiteur des glycoclusters dans l'adhésion bactérienne des Pseudomonas aeruginosa caractérisé par microscopie à force atomique : de la molécule à la cellule / Glycocluster inhibition effect on bacterial adhesion of Pseudomonas aeruginosa characterized by atomic force microscopy and spectroscopy : from molecule to cellZuttion, Francesca 24 October 2016 (has links)
La bactérie Pseudomonas aeruginosa (PA) est un pathogène responsable de 20%-30% des infections nosocomiales en milieu hospitalier. Pour les individus sains, elle ne présente pas de réel danger, mais pour les personnes atteintes par la mucoviscidose et les patients immunodéprimés, elle est la cause principale de mortalité et des infections pulmonaires. PA a développé des souches multi-résistantes aux antibiotiques et des nouvelles approches thérapeutiques plus efficaces sont donc nécessaires. Elle se fixe à la surface des cellules-hôtes par une interaction entre des protéines (lectines) présentes sur sa membrane et des sucres présents sur la membrane cellulaire. L’interaction lectine-sucre joue un rôle important dans l’adhésion de la bactérie puis dans la fabrication d’un biofilm pathogène.Une nouvelle approche thérapeutique consiste à créer des molécules synthétiques (glycomimes) de plus grande affinité que les sucres présents sur les cellules. Pour cela, plus de 150 glycomimes ont été synthétisés et examinés afin de trouver le meilleur candidat pour empêche le processus d'infection de bactéries. Certains d'entre eux ont été choisis et étudiés par la Microscopie à Force Atomique (AFM). Cette thèse est consacrée à l’étude des interactions lectine-glycomime et aussi cellule-bactérie par AFM. L’imagerie combinée avec la modélisation permet de comprendre le rôle du glycomime sur la géométrie des complexes créés et la spectroscopie permet de mesurer les forces d’interaction présentes lors de l’adhésion, au niveau moléculaire et cellulaire. Une réduction de l’adhésion bactérienne a été observée après l’introduction du glycomime, confirmant son rôle d’inhibiteur et la validité de toute la démarche. L’objectif ultime est l’identification des meilleurs glycomimes à introduire afin de développer de nouveaux médicaments. / Pseudomonas aeruginosa (PA) is a human opportunistic pathogen responsible for 20% -30% of nosocomial infections in French hospitals. For healthy people, it presents no real danger, but for people with cystic fibrosis disease and immune-compromised patients, it is the leading cause of mortality and lung infections. PA has developed antibiotic multi-resistant strains and new and more effective therapeutic approaches are needed. It binds to the surface of the host cells by an interaction between proteins (lectins) present on the membrane and sugars of the host-cell membrane. The lectin-sugar interaction plays an important role in adherence of the bacteria and in the manufacture of a pathogenic biofilm.A new therapeutic approach is to create synthetic molecules (glycoclusters) of greater affinity than the natural sugars present on the cells. To this aim, more than 150 glycoclusters have been synthetized and screened to find the best candidate to inhibit the bacteria infection process. Some of them have been selected and studied by Atomic Force Microscopy (AFM). In particular, this thesis is devoted to study the lectin-glycocluster and cell-bacteria interactions by AFM. The combination of AFM imaging with molecular dynamic simulations let understanding the role of the geometry of the glycoclusters on the complex formation, while AFM spectroscopy accesses the lectin-glycocluster interaction forces at the molecular and cellular levels. The reduction of bacterial adhesion has been observed upon the addition of the glycocluster. This confirms the anti-adhesive properties of the glycocluster and validates the procedure. The ultimate goal is the identification of the best glycoclusters in order to develop new drugs.
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Quantifying adhesive interactions between cells and extracellular matrix by single-cell force spectroscopyTaubenberger, Anna Verena 07 October 2009 (has links)
Interactions of cells with their environment regulate important cellular functions and are required for the organization of cells into tissues and complex organisms. These interactions involve different types of adhesion receptors. Interactions with extracellular matrix (ECM) proteins are mainly mediated by the integrin family of adhesion molecules. Situations in which integrin-ECM interactions are deregulated cause diseases and play a crucial role in cancer cell invasion. Thus, the mechanisms underlying integrin-binding and regulation are of high interest, particularly at the molecular level.
How can cell-ECM interactions be studied? While there are several methods to analyze cell adhesion, few provide quantitative data on adhesion forces. One group, single-cell force spectroscopy (SCFS), quantifies adhesion at the single-cell level and can therefore differentiate the adhesive properties of individual cells. One implementation of SCFS is based on atomic force microscopy (AFM); this technique has been employed in the presented work. Advantageously AFM-SCFS combines high temporal and spatial cell manipulation, the ability to measure a large range of adhesion forces and sufficiently high-force resolution to allow the study of single-molecule binding events in the context of a living cell. Since individual adhesion receptors can be analyzed within their physiological environment, AFM-SCFS is a powerful tool to study the mechanisms underlying integrin-regulation.
The presented work is split into six chapters. Chapter one gives background information about cell-ECM interactions. In chapter two, different adhesion assays are compared and contrasted. The theoretical Bell-Evans model which is used to interpret integrin-mediated cell adhesion is discussed in chapter three. Thereafter, the three projects that form the core of the thesis are detailed in chapters four through six.
In the first project (chapter 4), α2β1-integrin mediated cell adhesion to collagen type I, the most abundant structural protein in vertebrates, was quantified using CHO cells. Firstly, α2β1-collagen interactions were investigated at the single-molecule level. Dynamic force spectroscopy permitted calculation of bond specific parameters, such as the bond dissociation rate koff (1.3 ± 1.3 sec-1) and the barrier width xu (2.3 ± 0.3 Å). Next, α2β1-integrin mediated cell adhesion to collagen type I was monitored over contact times between 0 and 600 sec. Thereby the kinetics of α2β1-integrin mediated interactions was explored and insights into the underlying binding mechanisms were gained.
In the second project (chapter five), effects of cryptic integrin binding sites within collagen type I exerted on pre-osteoblasts were investigated. Collagen type I matrices were thermally denatured which lead to exposure of cryptic RGD (Arg-Gly-Asp)-motifs. As a consequence pre-osteoblasts enhanced their adhesion to denatured collagen. Compared to native collagen type I, adhesion to denatured collagen was mediated by a different set of integrins, including αv- and α5β1-integrins. Cells grown on denatured collagen showed enhanced spreading and motility, which correlated with increased focal adhesion kinase phosphorylation levels. Moreover, osteogenic differentiation kinetics and differentiation potential were increased on denatured collagen. The findings of this project open new perspectives for optimization of tissue engineering substrates.
In the third part (chapter six), the effect of the fusion protein BCR/ABL, a hallmark of chronic myeloid leukemia, on adhesion of myeloid progenitor cells was studied. Adhesion between BCR/ABL transformed progenitor cells to bone marrow derived stromal cells and to different ECM proteins was quantitatively compared to that of control cells. The tyrosine kinase activity of BCR/ABL enhanced cell adhesion, which was blocked by imatinib mesylate, a drug interfering with BCR/ABL activity. BCR/ABL-enhanced adhesion correlated with increased β1-integrin cell surface concentrations. Since adhesion of leukemic cells to the bone marrow compartment is critical for the development of drug resistance, the reported results may provide a basis for optimized target therapies.
In the three described projects AFM-based SCFS was applied to investigate early steps of integrin-mediated adhesion at the molecular level. Taken together, the results demonstrate that AFM-SCFS is a versatile tool that permits monitoring of cell adhesion from single-molecule interactions to the formation of more complex adhesion sites at the force level. / Interaktionen zwischen Zellen und ihrer Umgebung sind maßgeblich an der Regulierung zellulärer Funktionen beteiligt und daher notwendig für die Organisation von Zellen in Geweben und komplexen Organismen. Zellinteraktionen mit der extrazellulären Matrix (EZM) werden hauptsächlich durch Integrine vermittelt. Situationen, in denen Integrin- EZM Interaktionen verändert sind, können Krankheiten verursachen und spielen zudem eine wichtige Rolle bei der Invasion von Krebszellen. Daher besteht ein großes Interesse darin, die molekularen Mechanismen, die Integrin-EZM Interaktionen regulieren, besser zu verstehen.
Wie können Zell-EZM Interaktionen untersucht werden? Obwohl es mehrere Methoden gibt, mit denen Zelladhäsion untersucht werden kann, sind die wenigsten dazu geeignet, Zelladhäsionskräfte zu quantifizieren. Einzelzellspektroskopie erfasst die Adhäsionskräfte einzelner Zellen quantitativ und ermöglicht dadurch eine differenzierte Betrachtung der Adhäsion individueller Zellen. Eine Variante der Einzelzellspektroskopie basiert auf der Rasterkraftmikroskopie (AFM); diese Technik wurde in der vorliegenden Arbeit verwendet. Ein Vorteil von AFM- Einzelzellspektroskopie besteht darin, dass Zellen mit hoher zeitlicher und räumlicher Präzision manipuliert werden können. Zelladhäsionskräfte können zudem über einen großen Kraftbereich hinweg untersucht werden. Dabei ermöglicht es die hohe Kraftauflösung, einzelne Integrin-Ligandenbindungen in lebenden Zellen zu untersuchen.
Die vorliegende Arbeit gliedert sich in sechs Kapitel. Kapitel eins gibt Hintergrundinformationen über Zell-EZM Wechselwirkungen. In Kapitel zwei werden verschiedene Adhäsionsassays einander gegenüber gestellt. Das theoretische Bell-Evans Modell, mit dessen Hilfe die gewonnenen Daten interpretiert wurden, wird in Kapitel drei diskutiert. Im Anschluss werden drei Projekte, welche das Herzstück dieser Doktorarbeit bilden, in Kapiteln vier bis sechs näher ausgeführt.
Im ersten Projekt (Kapitel vier) wurde die Adhäsion von α2β1-Integrin exprimierenden CHO Zellen zu Kollagen I, dem häufigsten strukturellen Protein in Wirbeltieren, quantitativ untersucht. Zunächst wurden α2β1-Kollagen-Interaktionen auf Einzelmolekülebene analysiert. Mithilfe der dynamischen Kraftspektroskopie wurden für diese Bindung Dissoziationsrate koff (1.3 ± 1.3 sec-1) und Potentialbarrierenbreite xu (2.3 ± 0.3 Å) bestimmt. Daraufhin wurde die α2β1-vermittelte Adhäsion über einen Zeitraum von zehn Minuten untersucht. Dadurch konnten Einblicke in die Kinetik von α2β1-integrin vermittelter Zelladhäsion sowie in die zugrunde liegenden Regulationsmechanismen gewonnen werden.
Im zweiten Projekt (Kapitel fünf) wurde die Rolle von kryptischen Integrin-Bindungsstellen in Kollagen I untersucht. Die zuvor verwendeten Kollagenoberflächen wurden thermisch denaturiert, wodurch versteckte RGD (Arg-Gly-Asp)-Sequenzen freigelegt wurden. Die partielle Denaturierung hatte- verglichen mit nativem Kollagen I- eine erhöhte Adhäsion von Präosteoblasten (MC3T3-E1) zur Folge, was auf das Binden zusätzlicher Integrine zurückgeführt wurde. Im Unterschied zu nativem Kollagen wurde die Zelladhäsion zu denaturiertem Kollagen I u.a. durch αv- and α5β1-Integrine vermittelt. Präosteoblasten zeigten verstärktes Zellspreiten sowie höhere Motilität auf denaturiertem Kollagen I; zudem wurde ein erhöhtes Differenzierungpotential der Präosteoblasten festgestellt. Die in diesem Projekt erhaltenen Einblicke bilden eine hilfreiche Basis für die Entwicklung optimierter Oberflächen für diverse Zell- und Gewebekulturanwendungen.
Im dritten Projekt (Kapitel sechs) wurde der Einfluss des Fusionproteins BCR/ABL, charakteristisch für chronische myeloische Leukämie, auf die Adhäsion von myeloischen Vorläuferzellen untersucht. Dazu wurde die Adhäsion von BCR/ABL transformierten Vorläuferzellen (32D Zellen) bzw. Kontrollzellen zu Stromazellen (M2-10B4) sowie verschiedenen EZM Proteinen untersucht. BCR/ABL erhöhte die Zelladhäsion der myeloischen Vorläuferzellen signifikant. Dieser Effekt wurde durch die Zugabe von Imatinib, welches die Tyrosinkinaseaktivität von BCR/ABL inhibiert, aufgehoben. Die BCR/ABL-verstärkte Zelladhäsion korrelierte mit erhöhten β1-Integrin-konzentrationen. Da die Adhäsion von Leukämiezellen im Knockenmark bekanntermaßen kritisch für die Entwicklung von Resistenzen gegenüber verschiedenen Wirkstoffen ist, könnten die Ergebnisse dieser Studie eine Grundlage für die Entwicklung optimierter Target-Therapien sein.
In den drei beschriebenen Projekten wurde AFM Einzelzellspektroskopie verwendet, um Integrin- vermittelte Adhäsion auf molekularer Ebene zu untersuchen. Die Ergebnisse zeigen, dass AFM-Einzelzellspektroskopie ein vielseitiges Werkzeug darstellt, das überaus geeignet dazu ist, Zelladhäsion- ausgehend von Einzelmolekülinteraktionen bis hin zur Entstehung komplexerer Adhäsionsstellen- auf der Kraftebene zu verfolgen.
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