Global ETD Search

11	Mechanics of Gram-positive bacterial cell adhesion Echelman, Daniel Jay January 2018 (has links) Bacteria adhere despite severe mechanical perturbations. In Gram-positive bacteria, this adhesion is dependent upon a set of extracellular proteins, most notably pili, that have a unique abundance of internal disulfide, isopeptide, and thioester bonds. How these cell adhesion proteins manage to withstand such mechanical assaults, and what role these internal covalent bonds play to that end, remain open questions. Herein, we apply single-molecule force spectroscopy to delve into the mechanical behavior of three Gram-positive pilus proteins. We find that structural components of the Actinomyces oris and Corynebacterium diphtheriae pili have isopeptide-delimited extensions at extreme mechanical forces. This behavior enables efficient energy dissipation under high mechanical loads. Meanwhile, the pilus tip adhesin of Streptococcus pyogenes can covalently bind to targets via its internal thioester bond. We find that reactions with this internal thioester bond are reversible, and that both the nucleophilic bond cleavage and its spontaneous reformation are negatively force-dependent, inhibited at forces above ~30 pN and above ~7 pN, respectively. Based on these observations, we propose a model of shear-enhanced covalent adhesion for Gram-positive bacteria. Finally, we move from single-molecule characterization to application as we explore the potential of a peptide competitors to modulate the folding and function of bacterial virulence factors. Biophysics Nanoscience Microbiology Cell adhesion--Molecular aspects Gram-positive bacteria Cells--Mechanical properties
12	Stainless steel hollow sphere foams : processing and properties Clark, Justin Lewis 12 1900 (has links) No description available. Cells Mechanical properties Foamed materials Mechanical properties
13	Estudo de processos de adesão bacteriana : propriedades mecânicas e efeitos do microambiente sobre adesão, crescimento e mobilidade da Xylella fastidiosa / Study of bacterial cell adhesion processes : mechanical properties and microenvironment effects on adhesion, growth and motility of Xylella fastidiosa Monteiro, Moniellen Pires, 1988- 06 June 2017 (has links) Orientador: Mônica Alonso Cotta / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Física Gleb Wataghin / Made available in DSpace on 2018-09-02T02:33:05Z (GMT). No. of bitstreams: 1 Monteiro_MoniellenPires_D.pdf: 5193520 bytes, checksum: fab290a9074ae3dd188d4ebb636ff0e7 (MD5) Previous issue date: 2017 / Resumo: Nesta tese investigamos processos de adesão da Xylella fastidiosa, bactéria gram-negativa, fitopatógena, que forma biofilmes no xilema de plantas. O trabalho teve como objetivos entender alguns aspectos do processo de adesão bacteriana e do mecanismo de transporte de células e biofilmes em sistemas que simulam os vasos do xilema. Consideramos em particular as estratégias utilizadas pela X.fastidiosa para aderir à superfície, dentre elas, a secreção de substâncias poliméricas extracelulares (EPS), a presença de adesinas fimbriais (pili) e afimbriais (XadA1) e moléculas sinalizadoras de detecção de quórum (relacionadas à formação de agregados). Como ponto de partida quantificamos as propriedades elásticas do sistema composto pelo EPS e células bacterianas, em diferentes tempos de cultivo bacteriano. Para isso utilizamos medidas de espectroscopia de força e Raman confocal durante os estágios iniciais de adesão celular e formação de agregados. Mostramos que a rigidez do sistema célula/EPS diminui progressivamente com o aumento do tempo de crescimento bacteriano. Verificamos que existe uma mudança no valor de rigidez em diferentes partes da célula, região polar e corpo bacteriano; os menores valores de rigidez encontrados no polo sugerem uma resposta mecânica mais flexível nesta região, associada com o ponto de adesão inicial da célula à superfície. No estudo de adesão e mobilidade da X.fastidiosa, utilizamos dispositivos microfluídicos modificados quimicamente, via funcionalização de superfície (em microcanais Polidimetilsiloxano/vidro) e via introdução de molécula de detecção de quórum (em microcanais impressos em poliácido láctico), para tornar o ambiente mais próximo ao do xilema da planta. Foram feitas funcionalizações de superfície com uma celulose sintética, simulando a composição química dos vasos do xilema (majoritariamente composto por celulose), e com a adesina XadA1, e observamos os efeitos sobre a adesão, crescimento e mobilidade celular. Verificamos que a adesina XadA1 aumenta a densidade bacteriana se comparada às demais superficies, além de aumentar a força de adesão bacteriana à superfície. Quanto a inserção de molécula sinalizadora, observamos que a presença destas moléculas no cultivo bacteriano aumenta a densidade celular e altera a forma de pequenos agregados / Abstract: In this thesis we investigated the adhesion processes of Xylella fastidiosa, a gram-negative, phytopathogenic bacterium that forms biofilms in the xylem of plants. The objective of this work was the understanding of several aspects of the bacterial adhesion process, as well as the mechanism of cell and biofilm transport in systems that simulate xylem vessels. In particular, we considered the strategies used by X.fastidiosa to adhere to a surface; among them, the secretion of extracellular polymeric substances (EPS), the presence of fimbrial (pili) and afimbrial (XadA1) adhesins and quorum detection molecules (related to cluster formation). As a starting point we quantified the elastic properties of the system composed of EPS and bacterial cells, at different times of bacterial culture. For this purpose, we used force spectroscopy and confocal Raman measurements during the initial stages of cell adhesion and cluster formation. We have shown that stiffness decreases progressively with increasing bacterial growth time. We observed that stiffness values varied along different parts of the cell, polar region and bacterial body. The lower stiffness values found at the pole suggest a more flexible mechanical response in this region, associated with the initial adhesion point of the cell to the surface. For the investigation on X.fastidiosa adhesion and mobility, we used chemically modified microfluidic devices via surface functionalization (in Polydimethylsiloxane / glass microchannels) and via the introduction of a quorum detection molecule (in microchannels printed on polylactic acid) to make the environment more closely resemble the plant xylem. Surface functionalizations were performed with a synthetic cellulose, simulating the chemical composition of xylem vessels (mainly composed of cellulose), and the XadA1 adhesin, and we observed the effects on cell adhesion, growth and mobility. Our results showed that immobilized XadA1 increased the bacterial density when compared to other surfaces studied; furthermore, it increased the bacterial adhesion force to the surface. Regarding the addition of the signaling molecules, we observed that their presence in the bacterial culture increases cell density and changes the shape of small clusters / Doutorado / Física / Doutora em Ciências / 2010/51748-7 / 479486/2012-3 / FAPESP / CNPQ Adesão celular Células - Propriedades mecânicas Dispositivos microfluídicos Biofilme Xylella fastidiosa Cell adhesion Cells - Mechanical properties Microfluidic devices Biofilms Xylella fastidiosa
14	Optical techniques for the investigation of a mechanical role for FRMD6/Willin in the Hippo signalling pathway Goff, Frances January 2019 (has links) The mammalian hippo signalling pathway controls cell proliferation and apoptosis via transcriptional co-activators YAP and TAZ, and as such is a key regulator of organ and tissue growth. Multiple cellular components converge in this pathway, including the actin cytoskeleton, which is required for YAP/TAZ activity. The precise mechanism by which the mechanical actomyosin network regulates Hippo signalling, however, is unknown. Optical methods provide a non-invasive way to image and study the biomechanics of cells. In the past two decades, super-resolution fluorescence microscopy techniques that break the diffraction limit of light have come to the fore, enabling visualisation of intracellular detail at the nanoscale level. Optical trapping, on the other hand, allows precise control of micron-sized objects such as cells. Here, super resolution structured illumination microscopy (SIM) and elastic resonator interference stress microscopy (ERISM) were used to investigate a potential role for the FERM-domain protein FRMD6, or Willin, in the mechanical control of the Hippo pathway in a neuronal cell model. A double optical trap was also integrated with the Nikon-SIM with the aim of cell stretching. Willin expression was shown to modify the morphology, neuronal differentiation, actin cytoskeleton and forces of SH-SY5Y cells. Optical trapping from above the SIM objective, however, was demonstrated to be ineffective for manipulation of adherent cells. The results presented here indicate a function for Willin in the assembly of actin stress fibres that may be the result of an interaction with the Hippo pathway regulator AMOT. Further investigation, for example by direct cell stretching, is required to elucidate the exact role of Willin in the mechanical control of YAP/TAZ.
15	MECHANICAL PROPERTIES OF Sc₀․₁Ce₀․₀₁Zr₀․₈₉O₂ ELECTROLYTE MATERIAL FOR INTERMEDIATE TEMPERATURE SOLID OXIDE FUEL CELLS Lim, Wendy 2009 December 1900 (has links) Scandia doped zirconia has been considered a candidate for electrolyte material in intermediate temperature Solid Oxide Fuel Cells (SOFCs) due to its high ionic conductivity, chemical stability and good electrochemical performance. The aim of this study is to determine the mechanical properties of SCZ, ie. zirconia (ZrO₂) doped with Scandia (Sc₂O₃) and small amount of ceria (CeO₂) that are important for reliability and durability of the components manufactured from SCZ. The SCZ was prepared from powder by uniaxiall cold pressing at subsequent sintering at 1550 ºC for 4 hours. The density and porosity of the sintered samples was measured following the ASTM Standard C20-00 for alcohol immersion method. A pure cubic phase of SCZ sample was identified by X-ray diffraction (XRD) at room temperature. Quantitative compositional analyses for Zr, Sc, Ce, Hf and Ti were carried out on a Cameca SX50 electron microprobe with wavelength-dispersive spectroscopy (WDS) and energy-dispersive spectroscopy (EDS). Scanning Electron Microscopy (SEM) images were acquired using both secondary electron (SE) and back-scattered electron (BSE) detectors. WDS and EDS analysis also revealed that Zr, Sc, Ce, Hf and Ti are relatively homogeneously distributed in the structure. The average grain size of sintered SCZ samples was measured to be 4 μm. Thermal expansion at different temperatures for the SCZ ceramic was determined using Thermal Mechanical Analyzer, and the instantaneous Coefficient of Thermal Expansion (CTE) was found to be 8.726х10⁻⁶ 1/°C in the in 25-400 °C temperature range. CTE increases monotonically with temperature above 400 ºC to 1.16х10⁻⁵ at 890 °C, most likely as a result of thermo-chemical expansion due to an increase in oxygen vacancy concentration. Room temperature Vickers hardens of 12.5 GPa was measured at loads of 1000 g, while indentation fracture toughness was found to vary from 2.25 to 4.29 MPa m¹⁄², depending on the methodology that was used to calculate fracture toughness from the length of the median corner cracks. Elastic moduli, namely Young and shear moduli were determined using Resonance Ultrasound Spectroscopy (RUS). It was found that elastic moduli decreases with temperature in non-linear manner, with significant drop in the 300-600 °C temperature range, the same temperature range in which loss modulus determined by Dynamic Mechanical Analyzer exhibits frequency dependant peaks. The high loss modulus and significant drop in elastic moduli in that temperature regime is attributed to the relaxation of doping cation-oxygen vacancies clusters. The flexural strength in 4-point bending was measured at room temperature, 400 °C, 600 °C and 800 °C. and the results were analyzed using Weibull statistics. It was found that flexural strength changes with temperature in a sigmoidal way, with the minimum strength at around 600 °C. Non-linear decrease in strength with temperature can be traced back to the changes in elastic moduli that are caused predominately by relaxation of oxygen vacancies. Solid Oxide Fuel Cells SOFC Bending strength
16	Modeling Lysis Dynamcis Of Pore Forming Toxins And Determination Of Mechanical Properties Of Soft Materials Vaidyanathan, M S 11 1900 (has links) (PDF) Pore forming toxins are known for their ability to efficiently form transmembrane pores which eventually leads to cell lysis. PFTs have potential applications in devel-oping novel drug and gene delivery strategies. Although structural aspects of many pore forming toxins have been studied, very little is known about the dynamics and subsequent rupture mechanisms. In the first part of the thesis, a combined experimental and modeling study to understand the lytic action of Cytolysin A (ClyA) toxins on red blood cells (RBCs) has been presented. Lysis experiments are carried out on a 1% suspension of RBCs for different initial toxin concentrations ranging from 100 – 500 ng/ml and the extent of lysis is monitored spectrophotometrically. Using a mean field approach, we propose a non – equilibrium adsorption-reaction model to quantify the rate of pore formation on the cell surface. By analysing the model in a pre-lysis regime, the number of pores per RBC to initiate rupture was found to lie between 400 and 800. The time constants for pore formation are estimated to lie between 1-25 s and monomer conformation time scales were found to be 2-4 times greater than the oligomerization times. Using this model, we are able to predict the extent of cell lysis as a function of the initial toxin concentration. Various kinetic models for oligomerization mechanism have been explored. Irreversible sequential kinetic model has the best agreement with the available experimental data. Subsequent to the mean field approach, a population balance model was also formulated. The mechanics of cell rupture due to pore formation is poorly understood. Efforts to address this issue are concerned with understanding the changes in the membrane mechanical properties such as the modulus and tension in the presence of pores. The second part of the thesis is concerned with using atomic force microscopy to measure the mechanical properties of cells. We explore the possibility of employing tapping mode AFM (TM-AFM) to obtain the elastic modulus of soft samples. The dynamics of TM-AFM is modelled to predict the elastic modulus of soft samples, and predict optimal cantilever stiffness for soft biological samples. From experiments using TM-AFM on Nylon-6,6 the elastic modulus is predicted to lie between 2 and 5 GPa. For materials having elastic moduli in the range of 1– 20 GPa, the cantilever stiffness from simulations is found to lie in the range of 1 – 50 N/m. For soft biological samples, whose elastic moduli are in the range of 10-1000 kPa, a narrower range of cantilever stiffness (0.1 – 0.6 N/m), should be used. Cell Biotechnoloy Cell Lysis Pore Forming Toxins Cytolysin A Toxins - Lysis Tapping Mode Atomic Force Microscope Soft Materials - Mechanical Properties Cell Micrbiology Cells - Mechanical Properties Cytolysin A (ClyA) Chemical Engineering
17	Effects of interstitial fluid flow and cell compression in FAK and SRC activities in chondrocytes Cho, Eunhye 08 November 2013 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / Articular cartilage is subjected to dynamic mechanical loading during normal daily activities. This complex mechanical loading, including cell deformation and interstitial fluid flow, affects chondrocyte mechano-chemical signaling and subsequent cartilage homeostasis and remodeling. Focal adhesion kinase (FAK) and Src are known to be main mechanotransduction proteins, but little is known about the effect of mechanical loading on FAK and Src under its varying magnitudes and types. In this study, we addressed two questions using C28/I2 chondrocytes subjected to the different types and magnitudes of mechanical loading: Does a magnitude of the mechanical loading affect activities of FAK and Src? Does a type of the mechanical loading also affect their activities? Using fluorescence resonance energy transfer (FRET)-based FAK and Src biosensor in live C28/I2 chondrocytes, we monitored the effects of interstitial fluid flow and combined effects of cell deformation/interstitial fluid flow on FAK and Src activities. The results revealed that both FAK and Src activities in C28/I2 chondrocytes were dependent on the different magnitudes of the applied fluid flow. On the other hand, the type of mechanical loading differently affected FAK and Src activities. Although FAK and Src displayed similar activities in response to interstitial fluid flow only, simultaneous application of cell deformation and interstitial fluid flow induced differential FAK and Src activities possibly due to the additive effects of cell deformation and interstitial fluid flow on Src, but not on FAK. Collectively, the data suggest that the intensities and types of mechanical loading are critical in regulating FAK and Src activities in chondrocytes. FAK, Src, Mechanotransduction Cells -- Mechanical properties Cells -- Morphology Cellular signal transduction Tissue engineering Cell physiology Osteoarthritis Body fluids -- Pressure Tissues -- Mechanical properties Fluorescence spectroscopy Articular cartilage -- Pathophysiology
18	Signaling mechanisms that suppress the anabolic response of osteoblasts and osteocytes to fluid shear stress Hum, Julia M. 11 July 2014 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / Bone is a dynamic organ that responds to its external environment. Cell signaling cascades are initiated within bone cells when changes in mechanical loading occur. To describe these molecular signaling networks that sense a mechanical signal and convert it into a transcriptional response, we proposed the mechanosome model. “GO” and “STOP” mechansomes contain an adhesion-associated protein and a nucleocytoplasmic shuttling transcription factor. “GO” mechanosomes functions to promote the anabolic response of bone to mechanical loading, while “STOP” mechanosomes function to suppress the anabolic response of bone to mechanical loading. While much work has been done to describe the molecular mechanisms that enhance the anabolic response of bone to loading, less is known about the signaling mechanisms that suppress bone’s response to loading. We studied two adhesion-associated proteins, Src and Pyk2, which may function as “STOP” mechanosomes. Src kinase is involved in a number of signaling pathways that respond to changes in external loads on bone. An inhibition of Src causes an increase in the expression of the anabolic bone gene osteocalcin. Additionally, mechanical stimulation of osteoblasts and osteocytes by fluid shear stress further enhanced expression of osteocalcin when Src activity was inhibited. Importantly, fluid shear stress stimulated an increase in nuclear Src activation and activity. The mechanism by which Src participates in attenuating anabolic gene transcription remains unknown. The studies described here suggest Src and Pyk2 increase their association in response to fluid shear stress. Pyk2, a protein-tyrosine kinase, exhibits nucleocytoplasmic shuttling, increased association with methyl-CpG-binding protein 2 (MBD2), and suppression of osteopontin expression in response to fluid shear stress. MBD2, known to be involved in DNA methylation and interpretation of DNA methylation patterns, may aid in fluid shear stress-induced suppression of anabolic bone genes. We conclude that both Src and Pyk2 play a role in regulating bone mass, possibly through a complex with MBD2, and function to limit the anabolic response of bone cells to fluid shear stress through the suppression of anabolic bone gene expression. Taken together, these data support the hypothesis that “STOP” mechanosomes exist and their activity is simulated in response to fluid shear stress. Mechanotransduction Osteoblast Osteocyte Osteoblasts Osteoblasts -- Metabolism Bones -- Molecular aspects Cells -- Mechanical properties Osteoclast inhibition Human mechanics Cell metabolism Cellular signal transduction DNA -- Methylation Protein-tyrosine kinase -- Research Gene expression Cellular control mechanisms
19	F-Actin regulation of SNARE-mediated insulin secretion Kalwat, Michael Andrew 07 October 2013 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / In response to glucose, pancreatic islet beta cells secrete insulin in a biphasic manner, and both phases are diminished in type 2 diabetes. In beta cells, cortical F-actin beneath the plasma membrane (PM) prevents insulin granule access to the PM and glucose stimulates remodeling of this cortical F-actin to allow trafficking of insulin granules to the PM. Glucose stimulation activates the small GTPase Cdc42, which then activates p21-activated kinase 1 (PAK1); both Cdc42 and PAK1 are required for insulin secretion. In conjunction with Cdc42-PAK1 signaling, the SNARE protein Syntaxin 4 dissociates from F-actin to allow SNARE complex formation and insulin exocytosis. My central hypothesis is that, in the pancreatic beta cell, glucose signals through a Cdc42-PAK1-mediated pathway to remodel the F-actin cytoskeleton to mobilize insulin granules to SNARE docking sites at the PM to evoke glucose stimulated second phase insulin secretion. To investigate this, PAK1 was inhibited in MIN6 beta cells with IPA3 followed by live-cell imaging of F-actin remodeling using the F-actin probe, Lifeact-GFP. PAK1 inhibition prevented normal glucose-induced F-actin remodeling. PAK1 inhibition also prevented insulin granule accumulation at the PM in response to glucose. The ERK pathway was implicated, as glucose-stimulated ERK activation was decreased under PAK1-depleted conditions. Further study showed that inhibition of ERK impaired insulin secretion and cortical F-actin remodeling. One of the final steps of insulin secretion is the fusion of insulin granules with the PM which is facilitated by the SNARE proteins Syntaxin 4 on the PM and VAMP2 on the insulin granule. PAK1 activation was also found to be critical for Syntaxin 4-F-actin complex dynamics in beta cells, linking the Cdc42-PAK1 signaling pathway to SNARE-mediated exocytosis. Syntaxin 4 interacts with the F-actin severing protein Gelsolin, and in response to glucose Gelsolin dissociates from Syntaxin 4 in a calcium-dependent manner to allow Syntaxin 4 activation. Disrupting the interaction between Syntaxin 4 and Gelsolin aberrantly activates endogenous Syntaxin 4, elevating basal insulin secretion. Taken together, these results illustrate that signaling to F-actin remodeling is important for insulin secretion and that F-actin and its binding proteins can impact the final steps of insulin secretion. F-actin SNARE Syntaxin Gelsolin PAK1 Cdc42 diabetes insulin secretion islet ERK Diabetes -- Research Diabetes -- Pathophysiology Pancreatic beta cells Insulin -- Physiological effect Actin genes Exocytosis Glycoproteins Synapses Glucose Cells -- Mechanical properties Cellular signal transduction -- Research
20	Probing cellular mechano-sensitivity using biomembrane-mimicking cell substrates of adjustable stiffness Lin, Yu-Hung 12 1900 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / It is increasingly recognized that mechanical properties of substrates play a pivotal role in the regulation of cellular fate and function. However, the underlying mechanisms of cellular mechanosensing still remain a topic of open debate. Traditionally, advancements in this field have been made using polymeric substrates of adjustable stiffness with immobilized linkers. While such substrates are well suited to examine cell adhesion and migration in an extracellular matrix environment, they are limited in their ability to replicate the rich dynamics found at cell-cell interfaces. To address this challenge, we recently introduced a linker-functionalized polymer-tethered multi-bilayer stack, in which substrate stiffness can be altered by the degree of bilayer stacking, thus allowing the analysis of cellular mechanosensitivity. Here, we apply this novel biomembrane-mimicking cell substrate design to explore the mechanosensitivity of C2C12 myoblasts in the presence of cell-cell-mimicking N-cadherin linkers. Experiments are presented, which demonstrate a relationship between the degree of bilayer stacking and mechanoresponse of plated cells, such as morphology, cytoskeletal organization, cellular traction forces, and migration speed. Furthermore, we illustrate the dynamic assembly of bilayer-bound N-cadherin linkers underneath cellular adherens junctions. In addition, properties of individual and clustered N-cadherins are examined in the polymer-tethered bilayer system in the absence of plated cells. Alternatively, substrate stiffness can be adjusted by the concentration of lipopolymers in a single polymer-tethered lipid bilayer. On the basis of this alternative cell substrate concept, we also discuss recent results on a linker-functionalized single polymer-tethered bilayer substrate with a lateral gradient in lipopolymer concentration (substrate viscoelasticity). Specifically, we show that the lipopolymer gradient has a notable impact on spreading, cytoskeletal organization, and motility of 3T3 fibroblasts. Two cases are discussed: 1. polymer-tethered bilayers with a sharp boundary between low and high lipopolymer concentration regions and 2. polymer-tethered bilayers with a gradual gradient in lipopolymer concentration. Artificial Substrate Cadherin Polymer-tethered Bilayer Biomembrane-mimicking Lipid Bilayer Cadherins -- Research Cell junctions -- Research Polymers -- Surfaces Bilayer lipid membranes -- Research Cell adhesion -- Research -- Analysis Cellular control mechanisms -- Research Polymers -- Rheology Artificial cells -- Research

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