Global ETD Search

11	Caracterização funcional das isoformas de splicing do gene ADAM23 / Functional characterization of ADAM23 gene splicing isoforms Cavalher, Felicia Peterson 13 September 2012 (has links) A ADAM23 é uma glicoproteína transmembrana pertencente à família ADAM (A Disintegrin and Metalloprotease) que apresenta a estrutura protéica típica dos membros desta família, mas não possui atividade de metaloprotease. O gene ADAM23 apresenta três isoformas de splicing, α, β e γ, que codificam proteínas com porções C-terminais distintas. As isoformas α e β codificam proteínas com domínios transmembranas diferentes, enquanto γ provavelmente consiste em uma isoforma secretada ou citoplasmática de ADAM23. Foi demonstrado que o gene ADAM23 está epigeneticamente silenciado em tumores de mama de estágios mais avançados e que seu silenciamento está associado a um maior risco de desenvolvimento de metástases e a um pior prognóstico. Recentemente, foi descrito que a proteína ADAM23 interage diretamente com a integrina αVβ3 na linhagem tumoral de mama MDA-MB-435, sendo capaz de modular seu estado conformacional, controlando sua ativação. Utilizando RNAi, observou-se que o silenciamento completo do gene ADAM23 (i.e., as três isoformas) aumenta os níveis de αVβ3 em conformação ativa na superfície das células MDA-MB-435, promovendo um incremento de sua capacidade migratória e adesiva. No presente trabalho, avaliamos por reações de amplificação em tempo real o perfil de expressão das três isoformas de splicing do gene ADAM23 em cinco tecidos normais (mama, cólon, cérebro, próstata e pâncreas) e em doze linhagens tumorais derivadas destes tecidos. Observamos diferenças nos níveis de expressão das isoformas em todas as amostras avaliadas, tanto dentro de uma determinada amostra, como quando comparamos tecidos normais entre si ou com linhagens tumorais. A isoforma γ é a mais expressa em todos os tecidos normais (exceto em cérebro) e em todas as linhagens tumorais. Em tecido normal de mama e de próstata e nas doze linhagens tumorais, ADAM23α é a segunda isoforma mais expressa, sendo β a menos expressa. Constatamos também que a fração representada por cada isoforma, em relação à expressão total do gene ADAM23, está alterada nas linhagens tumorais, em comparação aos tecidos normais correspondentes. Com o intuito de elucidar a função das isoformas de ADAM23 separadamente, utilizamos shRNAs (short hairpin RNAs) para reduzir a expressão de cada isoforma de modo individual e específico na linhagem tumoral MDA-MB-435, e avaliamos seu efeito na proliferação, na morfologia, na adesão e no espraiamento celular. Verificamos que a redução da expressão da isoforma γ aumentou significativamente a taxa de proliferação das células MDA-MB-435 cultivadas em modelo tridimensional. Demonstramos também que ADAM23γ participa da regulação da morfologia e da capacidade de espraiamento das células MDA-MB-435 em condições padrão de cultivo (i.e., meio de cultura completo e placas não-sensibilizadas com substratos) e em componentes específicos da matriz extracelular, como fibronectina, colágeno I e matrigel. A isoforma α também está envolvida no controle da morfologia e do espraiamento da linhagem MDA-MB-435, porém, de modo distinto da isoforma γ. Já ADAM23β não interfere na morfologia das células MDA-MB-435 e tem efeito marginal no espraiamento celular apenas em condições padrão de cultivo. Em conjunto, nossos resultados demonstram que as isoformas de ADAM23 são diferencialmente expressas em tecidos normais e tumorais, e exercem funções biológicas distintas. / ADAM23 is a transmembrane glycoprotein that belongs to the ADAM (A Disintegrin and Metalloprotease) family of proteins and exhibits the typical protein structure of the family members, but it doesn\'t have metalloprotease activity. The ADAM23 gene has three splicing isoforms, α, β and γ, that code for proteins with different C-terminal regions. Isoforms α and β code for proteins with different transmembrane domains, while γ probably constitute a secreted or cytoplasmatic isoform of ADAM23. It has been demonstrated that the ADAM23 gene is epigenetically silenced in advanced stage breast tumors and that its silencing is associated with a higher risk of developing metastases and with a worse prognosis. Recently, it was described that ADAM23 protein interacts directly with αVβ3 integrin in the breast tumor cell line MDA-MB-435, modulating its conformational state and controlling its activation. Using RNAi, it was observed that the complete silencing of ADAM23 gene (the three isoforms) raises the levels of αVβ3 in its active conformation in the surface of MDA-MB-435 cells, promoting an increase in its migratory and adhesive capacity. In the present work, we evaluated by real time PCR the expression pattern of the three splicing isoforms of ADAM23 gene in five normal tissues (breast, colon, brain, prostate and pancreas) and in twelve tumor cell lines derived from these tissues. We observed differences in the expression levels of the three isoforms in all samples, either within a specific sample or comparing normal tissues among them or with tumor cell lines. Isoform γ has the highest expression in all normal tissues (except for brain) and in all tumor cell lines evaluated. In breast and prostate normal tissues and in all tumor cell lines, ADAM23α is the second most expressed isoform, while β is the less expressed. We also noticed that the ratio represented by each isoform, relative to the total expression of ADAM23 gene, is altered in the tumor cell lines, compared to the corresponding normal tissues. With the aim to elucidate the function of ADAM23 isoforms separately, we used shRNAs (short hairpin RNAs) to reduce the expression of each isoform specifically in the MDA-MB-435 tumor cell line, and studied its effects in proliferation, morphology, adhesion and cell spreading. We observed that the reduced expression of isoform γ significantly increased the proliferation rate of MDA-MB-435 cells cultivated in tridimensional system. Also, we demonstrated that ADAM23γ participates in the regulation of cell morphology and spreading of MDA-MB-435 cells, both in standard culture conditions (cell culture media with fetal serum and in plates not sensitized with substrates) and in specific components of extracellular matrix, such as fibronectin, collagen type I and matrigel. Isoform α is also involved in the control of morphology and spreading of MDA-MB-435 cell line, although in a distinct manner from isoform γ. ADAM23β doesn\'t interfere in the morphology of MDA-MB-435 cells and plays a discrete role in cell spreading only under standard culture conditions. Together, our results demonstrate that ADAM23 isoforms are differently expressed in normal and tumoral tissue, and play distinct biological roles. ADAM23 ADAM23 Cell spreading Espraiamento celular Expressão gênica Gene expression Proliferação Proliferation Splicing Splicing
12	Cell sensing on strain-stiffening substrates is not fully explained by the nonlinear mechanical property Rudnicki, Mathilda Sophia 17 April 2012 (has links) Cells respond to their mechanical environment by changing shape and size, migrating, or even differentiating to a more specialized cell type. A better understanding of the response of cells to surrounding cues will allow for more targeted and effected designs for biomedical applications, such as disease treatment or cellular therapy. The spreading behavior of both human mesenchymal stem cells (hMSCs) and 3T3 fibroblasts is a function of substrate stiffness, and can be quantified to describe the most visible response to how a cell senses stiffness. The stiffness of the substrate material can be modulated by altering the substrate thickness, and this has been done with the commonly-used linearly elastic gel, polyacrylamide (PA). Though easy to produce and tune, PA gel does not exhibit strain-stiffening behavior, and thus is not as representative of biological tissue as fibrin or collagen gel. Fibroblasts on soft fibrin gel show spreading similar to much stiffer linear gels, indicating a difference in cell stiffness sensing on these two materials. We hypothesize cells can sense further into fibrin and collagen gels than linear materials due to the strain-stiffening material property. The goal of this work is to compare the material response of linear (PA) and strain-stiffening (fibrin, collagen gel) substrates through modulation of effective stiffness of the materials. The two-step approach is to first develop a finite element model to numerically simulate a cell contracting on substrates of different thicknesses, and then to validate the numerical model by quantifying fibroblast spreading on sloped fibrin and collagen gels. The finite element model shows that the effective stiffness of both linear and nonlinear materials sharply increases once the thickness is reduced below 10µm. Due to the strain-stiffening behavior, the nonlinear material experiences a more drastic increase in effective stiffness at these low thicknesses. Experimentally, the gradual response of cell area of HLF and 3T3 fibroblasts on fibrin and collagen gels is significantly different (p<0.05) from these cell types on PA gel. This gradual increase in area as substrate thickness decreases was not predicted by the finite element model. Therefore, cell spreading response to stiffness is not explained by just the nonlinearity of the material. mechanosensing effective stiffness fibroblasts strain-stiffening extracellular matrix linear nonlinear cell spreading
13	Forward Chemical Genetics Drug Screen Yields Novel Proteases and Proteolytic Inhibitors of HGF–induced Epithelial–Mesenchymal Transition Schuler, Jeffrey Thomas 01 March 2016 (has links) Hepatocyte Growth Factor (HGF)–induced Epithelial–Mesenchymal Transition (EMT) is a complex cellular pathway that causes epithelial cell scattering by breaking cell–cell contacts, eliminating apical–basal polarity, and replacing epithelial markers and characteristics with mesenchymal markers. Early EMT events include a brief period of cell spreading, followed by cell compaction and cell–cell contact breaks. A forward chemical genetics drug screen of 50,000 unique compounds measuring HGF–induced cell scattering identified 26 novel EMT inhibitors, including 2 proteolytic inhibitors. Here, we show that B5500–4, one of the EMT inhibitors from the screen, blocks HGF–induced EMT by a predicted blocking of the protease furin, in addition to secondarily blocking Beta–Secretase (BACE).We also show that MMP–12 and MMP–9 are required for HGF–induced EMT to progress. MMP–12 is required for cell contraction, and its inhibition produces a continuous cell spreading phenotype.We also demonstrate that both furin and BACE activity are required for HGF–induced EMT to proceed, but that they are involved in separate pathways. We show that BACE inhibition leads to a failure of cell spreading in early EMT, and that EphA2 is a member of this pathway. We also demonstrate that it is likely BACE2, and not BACE1 that is responsible for early cell spreading. Furin is also required for HGF–induced cell scattering, but does not play a role in the cell spreading process. These findings highlight the importance of proteolytic activity at the earliest stages of HGF–induced EMT. EMT cell spreading cell compaction HGF BACE EphA2 Furin MMP–9 MMP–12 Physiology
14	Mechanisms of Integrin Signal Transduction Stefansson, Anne January 2007 (has links) <p>Integrins are a protein family of cell surface receptors, expressed in all cell types in the human body, except the red blood cells. Besides their importance in mediating physical connections with the surrounding environment, the integrin family members are also vital signalling mediators. They have no intrinsic kinase activity; instead the signals are transduced through conformational changes. </p><p>In this thesis, work is presented which is focused on molecular mechanisms of integrin signal transduction. The signal transduction was first studied from a structural point of view, determining the transmembrane domain borders of a few selected integrin family members and ruling out a signalling model involving a “piston-like” movement. </p><p>Then, downstream signalling events involved in the beta1 integrin-induced activation of Akt via the PI3kinase family were characterized. Our results identify a novel pathway for PI3K/Akt activation by beta1 integrins, which is independent of focal adhesion kinase (FAK), Src and EGF receptor. Furthermore, both beta1 integrins and EGF receptors induced phosphorylation of Akt at the regulatory sites Thr308 and Ser473, but only EGF receptor stimulation induced tyrosine phosphorylation of Akt.</p><p>Finally, signals from beta1 integrins underlying the morphologic changes during cell spreading were studied. A rapid integrin-induced cell spreading dependent on actin polymerisation was observed by using total internal reflection fluorescence (TIRF) microscopy. This integrin-induced actin polymerisation was shown to be dependent on PI3K p110alpha catalytic subunit and to involve the conserved Lys756 in the beta1-integrin membrane proximal part.</p> Cell biology Integrin Integrin signalling PI3K Akt/PKB Integrin transmembrane domain cell spreading Cellbiologi
15	Mechanisms of Integrin Signal Transduction Stefansson, Anne January 2007 (has links) Integrins are a protein family of cell surface receptors, expressed in all cell types in the human body, except the red blood cells. Besides their importance in mediating physical connections with the surrounding environment, the integrin family members are also vital signalling mediators. They have no intrinsic kinase activity; instead the signals are transduced through conformational changes. In this thesis, work is presented which is focused on molecular mechanisms of integrin signal transduction. The signal transduction was first studied from a structural point of view, determining the transmembrane domain borders of a few selected integrin family members and ruling out a signalling model involving a “piston-like” movement. Then, downstream signalling events involved in the beta1 integrin-induced activation of Akt via the PI3kinase family were characterized. Our results identify a novel pathway for PI3K/Akt activation by beta1 integrins, which is independent of focal adhesion kinase (FAK), Src and EGF receptor. Furthermore, both beta1 integrins and EGF receptors induced phosphorylation of Akt at the regulatory sites Thr308 and Ser473, but only EGF receptor stimulation induced tyrosine phosphorylation of Akt. Finally, signals from beta1 integrins underlying the morphologic changes during cell spreading were studied. A rapid integrin-induced cell spreading dependent on actin polymerisation was observed by using total internal reflection fluorescence (TIRF) microscopy. This integrin-induced actin polymerisation was shown to be dependent on PI3K p110alpha catalytic subunit and to involve the conserved Lys756 in the beta1-integrin membrane proximal part. Cell biology Integrin Integrin signalling PI3K Akt/PKB Integrin transmembrane domain cell spreading Cellbiologi
16	Caracterização funcional das isoformas de splicing do gene ADAM23 / Functional characterization of ADAM23 gene splicing isoforms Felicia Peterson Cavalher 13 September 2012 (has links) A ADAM23 é uma glicoproteína transmembrana pertencente à família ADAM (A Disintegrin and Metalloprotease) que apresenta a estrutura protéica típica dos membros desta família, mas não possui atividade de metaloprotease. O gene ADAM23 apresenta três isoformas de splicing, α, β e γ, que codificam proteínas com porções C-terminais distintas. As isoformas α e β codificam proteínas com domínios transmembranas diferentes, enquanto γ provavelmente consiste em uma isoforma secretada ou citoplasmática de ADAM23. Foi demonstrado que o gene ADAM23 está epigeneticamente silenciado em tumores de mama de estágios mais avançados e que seu silenciamento está associado a um maior risco de desenvolvimento de metástases e a um pior prognóstico. Recentemente, foi descrito que a proteína ADAM23 interage diretamente com a integrina αVβ3 na linhagem tumoral de mama MDA-MB-435, sendo capaz de modular seu estado conformacional, controlando sua ativação. Utilizando RNAi, observou-se que o silenciamento completo do gene ADAM23 (i.e., as três isoformas) aumenta os níveis de αVβ3 em conformação ativa na superfície das células MDA-MB-435, promovendo um incremento de sua capacidade migratória e adesiva. No presente trabalho, avaliamos por reações de amplificação em tempo real o perfil de expressão das três isoformas de splicing do gene ADAM23 em cinco tecidos normais (mama, cólon, cérebro, próstata e pâncreas) e em doze linhagens tumorais derivadas destes tecidos. Observamos diferenças nos níveis de expressão das isoformas em todas as amostras avaliadas, tanto dentro de uma determinada amostra, como quando comparamos tecidos normais entre si ou com linhagens tumorais. A isoforma γ é a mais expressa em todos os tecidos normais (exceto em cérebro) e em todas as linhagens tumorais. Em tecido normal de mama e de próstata e nas doze linhagens tumorais, ADAM23α é a segunda isoforma mais expressa, sendo β a menos expressa. Constatamos também que a fração representada por cada isoforma, em relação à expressão total do gene ADAM23, está alterada nas linhagens tumorais, em comparação aos tecidos normais correspondentes. Com o intuito de elucidar a função das isoformas de ADAM23 separadamente, utilizamos shRNAs (short hairpin RNAs) para reduzir a expressão de cada isoforma de modo individual e específico na linhagem tumoral MDA-MB-435, e avaliamos seu efeito na proliferação, na morfologia, na adesão e no espraiamento celular. Verificamos que a redução da expressão da isoforma γ aumentou significativamente a taxa de proliferação das células MDA-MB-435 cultivadas em modelo tridimensional. Demonstramos também que ADAM23γ participa da regulação da morfologia e da capacidade de espraiamento das células MDA-MB-435 em condições padrão de cultivo (i.e., meio de cultura completo e placas não-sensibilizadas com substratos) e em componentes específicos da matriz extracelular, como fibronectina, colágeno I e matrigel. A isoforma α também está envolvida no controle da morfologia e do espraiamento da linhagem MDA-MB-435, porém, de modo distinto da isoforma γ. Já ADAM23β não interfere na morfologia das células MDA-MB-435 e tem efeito marginal no espraiamento celular apenas em condições padrão de cultivo. Em conjunto, nossos resultados demonstram que as isoformas de ADAM23 são diferencialmente expressas em tecidos normais e tumorais, e exercem funções biológicas distintas. / ADAM23 is a transmembrane glycoprotein that belongs to the ADAM (A Disintegrin and Metalloprotease) family of proteins and exhibits the typical protein structure of the family members, but it doesn\'t have metalloprotease activity. The ADAM23 gene has three splicing isoforms, α, β and γ, that code for proteins with different C-terminal regions. Isoforms α and β code for proteins with different transmembrane domains, while γ probably constitute a secreted or cytoplasmatic isoform of ADAM23. It has been demonstrated that the ADAM23 gene is epigenetically silenced in advanced stage breast tumors and that its silencing is associated with a higher risk of developing metastases and with a worse prognosis. Recently, it was described that ADAM23 protein interacts directly with αVβ3 integrin in the breast tumor cell line MDA-MB-435, modulating its conformational state and controlling its activation. Using RNAi, it was observed that the complete silencing of ADAM23 gene (the three isoforms) raises the levels of αVβ3 in its active conformation in the surface of MDA-MB-435 cells, promoting an increase in its migratory and adhesive capacity. In the present work, we evaluated by real time PCR the expression pattern of the three splicing isoforms of ADAM23 gene in five normal tissues (breast, colon, brain, prostate and pancreas) and in twelve tumor cell lines derived from these tissues. We observed differences in the expression levels of the three isoforms in all samples, either within a specific sample or comparing normal tissues among them or with tumor cell lines. Isoform γ has the highest expression in all normal tissues (except for brain) and in all tumor cell lines evaluated. In breast and prostate normal tissues and in all tumor cell lines, ADAM23α is the second most expressed isoform, while β is the less expressed. We also noticed that the ratio represented by each isoform, relative to the total expression of ADAM23 gene, is altered in the tumor cell lines, compared to the corresponding normal tissues. With the aim to elucidate the function of ADAM23 isoforms separately, we used shRNAs (short hairpin RNAs) to reduce the expression of each isoform specifically in the MDA-MB-435 tumor cell line, and studied its effects in proliferation, morphology, adhesion and cell spreading. We observed that the reduced expression of isoform γ significantly increased the proliferation rate of MDA-MB-435 cells cultivated in tridimensional system. Also, we demonstrated that ADAM23γ participates in the regulation of cell morphology and spreading of MDA-MB-435 cells, both in standard culture conditions (cell culture media with fetal serum and in plates not sensitized with substrates) and in specific components of extracellular matrix, such as fibronectin, collagen type I and matrigel. Isoform α is also involved in the control of morphology and spreading of MDA-MB-435 cell line, although in a distinct manner from isoform γ. ADAM23β doesn\'t interfere in the morphology of MDA-MB-435 cells and plays a discrete role in cell spreading only under standard culture conditions. Together, our results demonstrate that ADAM23 isoforms are differently expressed in normal and tumoral tissue, and play distinct biological roles. ADAM23 Espraiamento celular Expressão gênica Proliferação Splicing ADAM23 Cell spreading Gene expression Proliferation Splicing
17	Investigation of the function of myotubularin through the examination of protein-protein interactions and exclusion of MTMR1 as a frequent cause of X-linked myotubular myopathy Copley, LaRae 01 December 2004 (has links) No description available. X-linked myotubular myopathy MTMR1 protein protein interactions peptide antibodies cell spreading membrane ruffling
18	Exploring Super-Loading Mechanisms of the Motor-Clutch Model Fernandes, Ketan Earl 22 July 2022 (has links) No description available. Biomedical Engineering Biomedical Research
19	Investigations of the spreading and closure mechanisms of phagocytosis in J774a.1 macrophages Kovari, Daniel T. 27 May 2016 (has links) Phagocytosis is the process by which cells engulf foreign bodies. It is the hallmark behavior of white blood cells, being the process through which those cells ingest and degrade pathogens and debris. To date a large amount of research has focused on documenting the existence and role of biochemical components involved with phagocytosis. Scores of signaling molecules have been implicated in the complex signal cascade which drives the process. These molecules are small (typically no larger than 5 nanometers) and operate in a crowded, chemically “noisy,” environment, yet they coordinate the cell's activity over comparatively expansive distances (as large as 20 micrometers). How these molecular processes scale-up to coordinate the activities of the cell over such massive distances is largely unknown. Using a planar analog of phagocytosis termed “frustrated phagocytosis,” we experimentally demonstrate that phagocytosis occurs in three distinct phases: initial cell-antigen binding, symmetric spreading, and late-stage contraction. Initial binding and symmetric spreading appears to be both mechanically and chemically similar to the quasi-universal cellular behaviors of adhesion and migration. Adhesion and migration have received extensive attention from the biophysics community in recent years. Leveraging these similarities, we adapt the biomechanical frameworks used in models of migration to phagocytosis. We show that macroscopic properties such as a cell's effective viscosity and membrane cortical tension can be used to model cell behavior during phagocytosis. Our experiments reveal that late-stage contraction distinguishes frustrated phagocytosis from other spreading behaviors. This contraction is myosin dependent. Additionally we demonstrate, for the first time, that late-stage contraction corresponds with formation of a contractile F-actin belt. Based on the dynamic contraction model (DC) developed to explain actin structure during cell migration we propose a DC model of phagocytosis which posits that contractile belt formation is the result of a late-stage myosin activity coupled with F-actin. Phagocytosis Frustrated phagocytosis Actin Cytoskeleton Traction force microscopy Dynamic contraction model Structure illumination microscopy Cell spreading Cell adhesion
20	Engineered Surfaces for Biomaterials and Tissue Engineering Peter George Unknown Date (has links) The interaction of materials with biological systems is of critical importance to a vast number of applications from medical implants, tissue engineering scaffolds, blood-contacting devices, cell-culture products, as well as many other products in industries as diverse as agriculture. This thesis describes a method for the modification of biomaterial surfaces and the generation of tissue engineering scaffolds that utilises the self assembly of poly (styrene)-block-poly (ethylene oxide) (PS-PEO) block copolymers. Block copolymers consist of alternating segments of two or more chemically distinct polymers. The salient feature of these materials is their ability to self organise into a wide range of micro-phase separated structures generating patterned surfaces that have domain sizes in the order of 10-100nm. Further, it is also possible to specifically functionalise only one segment of the block copolymer, providing a means to precisely locate specific biological signals within the 10-100nm domains of a nano-patterned surface, formed via the programmed micro-phase separation of the block copolymer system. The density and spatial location of signalling molecules can be controlled by altering several variables, such as block length, block asymmetry, as well as processing parameters, providing the potential to authentically emulate the cellular micro to nano-environment and thus greatly improving on existing biomaterial and tissue engineering technologies. This thesis achieved several aims as outlined below; Developed methods to control the self-assembly of PS-PEO block copolymers and generate nano-patterned surfaces and scaffolds with utility for biomaterials applications. PS-PEO diblock copolymers were blended with polystyrene (PS) homopolymer and spin cast, resulting in the rapid self-assembly of vertically oriented PEO cylinders in a matrix of PS. Due to the kinetically constrained phase-separation of the system, increasing addition of homopolymer is shown to reduce the diameter of the PEO domains. This outcome provides a simple method that requires the adjustment of a single variable to tune the size of vertically oriented PEO domains between 10-100nm. Polymeric scaffolds for tissue engineering were manufactured via a method that combines macro-scale temperature induced phase separation with micro-phase separation of block copolymers. The phase behaviour of these polymer-solvent systems is described, and potential mechanisms leading to this spectacular structure formation are presented. The result is highly porous scaffolds with surfaces comprised of nano-scale self-assembled block copolymer domains, representing a significant advance in currently available technologies. Characterised the properties of these unique nano-structured materials as well as their interaction with proteinaceous fluids and cells. Nano-patterned PS-PEO self-assembled surfaces showed a significant reduction in protein adsorption compared to control PS surfaces. The adhesion of NIH 3T3 fibroblast cells was shown to be significantly affected by the surface coverage of PEO nano-domains formed by copolymer self-assembly. These nano-islands, when presented at high number density (almost 1000 domains per square micron), were shown to completely prevent cellular attachment, even though small amounts of protein were able to bind to the surface. In order to understand the mechanism by which these surfaces resisted protein and cellular adsorption we utilised neutron reflection to study their solvation and swelling properties. The results indicate that the PEO domains are highly solvated in water; however, the PEO chains do not extend into the solvent but remain in their isolated domains. The data supports growing evidence that the key mechanism by which PEO prevents protein adsorption is the blocking of protein adsorption sites. Control the nano-scale presentation of cellular adhesion and other biological molecules via the self-assembly of functionalised PS-PEO block copolymers Precise control over the nano-scale presentation of adhesion molecules and other biological factors represents a new frontier for biomaterials science. Recently, the control of integrin spacing and cellular shape has been shown to affect fundamental biological processes, including differentiation and apoptosis. We present the self-assembly of maleimide functionalised PS-PEO copolymers as a simple, yet highly precise method for controlling the position of cellular adhesion molecules. By controlling the phase separation of the functional PS-PEO block copolymer we alter the nano-scale (on PEO islands of 8-14 nm in size) presentation of the adhesion peptide, GRGDS, decreasing lateral spacing from 62 nm to 44 nm and increasing the number density from ~ 450 to ~ 900 islands per um2. The results indicate that the spreading of NIH-3T3 fibroblasts increases as the spacing between islands of RGD binding peptides decreases. Further, the same functional PS-PEO surfaces were utilised to immobilise poly-histidine tagged proteins and ECM fragments. The technologies developed in this thesis aim to improve on several weaknesses of existing biomaterials, in particular, directing cellular behaviour on surfaces, and within tissue engineering scaffolds, but also, on the prevention of fouling of biomaterials via non-specific protein adsorption. The application of block copolymer self-assembly for biomaterial and tissue engineering systems described in this thesis has great potential as a platform technology for the investigation of fundamental cell-surface and protein-surface interactions as well as for use in existing and emerging biomedical applications. Block copolymer polystyrene-block-poly (ethylene oxide) self-assembly Nanotechnolgy Surface Modification Protein Adsorption cell spreading tissue engineering integrin RGD

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