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Structural studies of the integrin αvβ₃ and the integrin binding fragment of human fibrillin-1Lee, Stephen S. J. January 2003 (has links)
No description available.
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A multilevel approach to define the hierarchical organisation of extracellular matrix microfibrilsGodwin, Alan January 2016 (has links)
Extracellular matrix (ECM) microfibrils are critical components of connective tissues with a wide range of mechanical and cellular signalling functions. The focus of this PhD thesis is the study of two microfibrillar assemblies, fibrillin-1 and collagen VI. Fibrillin is a large ECM glycoprotein which facilitates the deposition of elastin in elastic tissues such aorta, skin and lung and sequesters growth factors in the matrix. Collagen VI is a heteromeric network-forming collagen which is expressed in tissues such as skin, lung, blood vessels and articular cartilage where it anchors cells into the ECM allowing for the transduction of biochemical and mechanical signals. The structures of some individual domains and short fragments of both fibrillin and collagen VI have been solved, but it is not fully understood how they are arranged into microfibrils and how these microfibrils are arranged into tissues. Therefore the aim of this project has been to determine the hierarchical organisation of fibrillin and collagen VI across multiple length scales. The nanoscale structure of the fibrillin microfibril was determined using negative stain TEM and single particle reconstruction. Microfibrils had a hollow tube-like structure with well-defined bead, arm, interbead and shoulder regions. To overcome flexibility observed in the microfibril, separate sub-models of the different fibrillin regions were modelled. The bead region had a complex double layered structure with an interwoven core and ring structures. The arm region had four separate densities which are potentially formed from dimers of fibrillin molecules. Serial block face scanning electron microscopy (SBF-SEM) and electron tomography allowed for the in situ 3D imaging of individual fibrillin microfibrils in ciliary zonule tissue. Microfibrils in ciliary zonule fibres were held together by cross bridges between microfibrils. These ciliary zonule fibres were then organised into larger fascicle-like structures which were stabilised by circumferentially arranged ciliary zonule fibres. The frozen hydrated structure of the collagen VI half-bead was reconstructed using cryo-TEM. The half-bead region had a compact hollow head, and flexible tail regions, the tail regions were linked together by the collagenous interbead region. SBF-SEM and electron tomography of the pericellular matrix (PCM) of murine articular cartilage revealed that the PCM had a meshwork-like organisation formed from globular densities ~30 nm in diameter. Together a combinatorial approach to image ECM microfibrils from the sub-molecular level to intact tissue structures spanning nanometre to millimetre length scales is presented. This provides a better understanding of how fibrillin and collagen VI microfibrils are organised in tissues.
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The control of microfibril orientation in the cell wall of NitellaLevy, S. January 1986 (has links)
No description available.
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Cortical microtubules and physical properties of cellulose microfibrils during primary cell wall formation in Arabidopsis thalianaFujita, Miki 05 1900 (has links)
Growth anisotropy, in which cells grow predominantly in one direction, is common in plant cells, and an essential event for plant form and function. The direction and degree of growth anisotropy are governed by the mechanical properties of the primary cell wall. When aligned in a parallel manner, cellulose microfibrils accommodate great resistance in the direction of their alignment to expansion driven by isotropic turgor pressure. Using the Arabidopsis thaliana inflorescence stem as a model system, field emission scanning electron microscopy (FESEM) analysis demonstrated that the establishment of parallel arrangement of microfibrils is closely correlated with anisotropic cell expansion. In the novel anisotropy 1 (any1) mutant allele of the primary cellulose synthase CesA1, growth defects were correlated with random cellulose microfibril patterns in some inflorescence stem tissues.
Microtubules have been considered to be the most likely candidates for controlling the orientation of cellulose microfibrils. Recent studies have indeed demonstrated a close association of the plasma membrane-localized cellulose-synthase-complexes (CSCs) that produce cellulose and cortical microtubules. Despite this close association, microtubule disruption did not cause cellulose microfibrils to lose parallel alignment in the radial and inner periclinal walls of cells in the inflorescence stem, suggesting that microtubules influence mechanical properties of cellulose microfibrils other than orientation. X-ray diffraction analysis demonstrated that cellulose crystallinity in wild-type plants declines at the growth-promoting temperature of 29°C, whereas crystallinity fails to adapt and remains high in mor1-1, the temperature-sensitive mutant whose microtubule arrays become disorganized at its restrictive temperature (29°C). This finding suggests that organized microtubules are involved in reducing cellulose crystallinity that normally accompanies increased cell expansion.
Live-cell imaging of CSCs by tracking a yellow fluorescent protein (YFP)-tagged CesA6 subunit in hypocotyl cells demonstrated that dynamic and well-organized microtubules affect the velocity, the direction of movement, and the density of CSCs, suggesting that there is a close relationship between microtubules and CSCs. Together with the finding that microtubules also control the distribution of COBRA, a GPI-anchored wall protein that is essential for growth anisotropy, I discuss the variety of roles microtubules play in anisotropic growth.
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Cortical microtubules and physical properties of cellulose microfibrils during primary cell wall formation in Arabidopsis thalianaFujita, Miki 05 1900 (has links)
Growth anisotropy, in which cells grow predominantly in one direction, is common in plant cells, and an essential event for plant form and function. The direction and degree of growth anisotropy are governed by the mechanical properties of the primary cell wall. When aligned in a parallel manner, cellulose microfibrils accommodate great resistance in the direction of their alignment to expansion driven by isotropic turgor pressure. Using the Arabidopsis thaliana inflorescence stem as a model system, field emission scanning electron microscopy (FESEM) analysis demonstrated that the establishment of parallel arrangement of microfibrils is closely correlated with anisotropic cell expansion. In the novel anisotropy 1 (any1) mutant allele of the primary cellulose synthase CesA1, growth defects were correlated with random cellulose microfibril patterns in some inflorescence stem tissues.
Microtubules have been considered to be the most likely candidates for controlling the orientation of cellulose microfibrils. Recent studies have indeed demonstrated a close association of the plasma membrane-localized cellulose-synthase-complexes (CSCs) that produce cellulose and cortical microtubules. Despite this close association, microtubule disruption did not cause cellulose microfibrils to lose parallel alignment in the radial and inner periclinal walls of cells in the inflorescence stem, suggesting that microtubules influence mechanical properties of cellulose microfibrils other than orientation. X-ray diffraction analysis demonstrated that cellulose crystallinity in wild-type plants declines at the growth-promoting temperature of 29°C, whereas crystallinity fails to adapt and remains high in mor1-1, the temperature-sensitive mutant whose microtubule arrays become disorganized at its restrictive temperature (29°C). This finding suggests that organized microtubules are involved in reducing cellulose crystallinity that normally accompanies increased cell expansion.
Live-cell imaging of CSCs by tracking a yellow fluorescent protein (YFP)-tagged CesA6 subunit in hypocotyl cells demonstrated that dynamic and well-organized microtubules affect the velocity, the direction of movement, and the density of CSCs, suggesting that there is a close relationship between microtubules and CSCs. Together with the finding that microtubules also control the distribution of COBRA, a GPI-anchored wall protein that is essential for growth anisotropy, I discuss the variety of roles microtubules play in anisotropic growth.
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Ultrastructural and immunochemical studies of elastin-associated microfibrils /Prosser, Ian W. January 1984 (has links) (PDF)
Thesis (Ph. D.)--University of Adelaide, Dept. of Pathology, 1985. / Includes bibliographical references (leaves 266-303).
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Cortical microtubules and physical properties of cellulose microfibrils during primary cell wall formation in Arabidopsis thalianaFujita, Miki 05 1900 (has links)
Growth anisotropy, in which cells grow predominantly in one direction, is common in plant cells, and an essential event for plant form and function. The direction and degree of growth anisotropy are governed by the mechanical properties of the primary cell wall. When aligned in a parallel manner, cellulose microfibrils accommodate great resistance in the direction of their alignment to expansion driven by isotropic turgor pressure. Using the Arabidopsis thaliana inflorescence stem as a model system, field emission scanning electron microscopy (FESEM) analysis demonstrated that the establishment of parallel arrangement of microfibrils is closely correlated with anisotropic cell expansion. In the novel anisotropy 1 (any1) mutant allele of the primary cellulose synthase CesA1, growth defects were correlated with random cellulose microfibril patterns in some inflorescence stem tissues.
Microtubules have been considered to be the most likely candidates for controlling the orientation of cellulose microfibrils. Recent studies have indeed demonstrated a close association of the plasma membrane-localized cellulose-synthase-complexes (CSCs) that produce cellulose and cortical microtubules. Despite this close association, microtubule disruption did not cause cellulose microfibrils to lose parallel alignment in the radial and inner periclinal walls of cells in the inflorescence stem, suggesting that microtubules influence mechanical properties of cellulose microfibrils other than orientation. X-ray diffraction analysis demonstrated that cellulose crystallinity in wild-type plants declines at the growth-promoting temperature of 29°C, whereas crystallinity fails to adapt and remains high in mor1-1, the temperature-sensitive mutant whose microtubule arrays become disorganized at its restrictive temperature (29°C). This finding suggests that organized microtubules are involved in reducing cellulose crystallinity that normally accompanies increased cell expansion.
Live-cell imaging of CSCs by tracking a yellow fluorescent protein (YFP)-tagged CesA6 subunit in hypocotyl cells demonstrated that dynamic and well-organized microtubules affect the velocity, the direction of movement, and the density of CSCs, suggesting that there is a close relationship between microtubules and CSCs. Together with the finding that microtubules also control the distribution of COBRA, a GPI-anchored wall protein that is essential for growth anisotropy, I discuss the variety of roles microtubules play in anisotropic growth. / Science, Faculty of / Botany, Department of / Graduate
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Acellular mechanisms of extracellular matrix degradationThurstan, Sarah Ashley January 2013 (has links)
Exposure of the skin to ultraviolet radiation (UVR) results clinically in the formation of deep wrinkles and mottled pigmentation and histologically, in a vast remodelling of the dermal extracellular matrix (ECM), in particular the elastic fibre network. Fibrillin microfibrils and fibulin-5 are early biomarkers of photoageing, where a loss of these fibres from the dermal epidermal junction is apparent. A study by our group showed that isolated fibrillin microfibrils and fibronectin which are rich in amino acids which absorb energy from UVR (UV-chromophores) are susceptible to UVR-induced damage, whilst UV-chromophore poor collagen type I is not. This research, with other earlier studies, indicates that acellular mechanism may work in tandem with cell-mediated up-regulation of matrix metalloproteinases (MMPs) in the progression of photoageing. This thesis aims to: i) test whether acellular mechanisms of photoageing are a result of direct photon absorption and/or the photodynamic production of reactive oxygen species (ROS); ii) assess the functional consequences of UVB degradation on the susceptibility of fibrillin microfibrils to MMPs and; iii) assay whether ECM proteins are differentially susceptible to solar simulated radiation (SSR) or UVA (315-400nm) alone using physiologically relevant doses of irradiation. Isolated proteins were exposed to UVB (280-315nm) in depleted-O2 conditions and in the presence of deuterium oxide. Depleted-O2 conditions decreased and deuterium oxide conditions increased UVR-induced degradation. Isolated proteins also show a similar pattern of degradation when exposed to H2O2 as an exogenous source of ROS. These results indicate that ROS play an important role in the differential degradation of dermal proteins. MMPs-3 and -9 are both upregulated in the skin after exposure to UVR and have the ability to degrade elastic fibre components. After exposure to UVB, damaged fibrillin microfibrils become more susceptible to degradation by both MMPs-3 and -9. Chromophore-rich fibrillin microfibrils and fibronectin are susceptible to degradation by both SSR and UVA alone, whereas chromophore-poor collagens type I and VI and tropoelastin are not. These results support our previous findings that amino acid composition of proteins is a good indicator of their relative susceptibility to UV-induced damage with a physiologically relevant irradiation system. In conclusion this work shows that ROS are an important mediator of acellular mechanisms of photoageing and that amino acid composition is a good indication of relative susceptibility of proteins to both ROS and UVR. The ability to predict ROS-susceptible proteins also has wider implications for human ageing as a whole.
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Hormonal control of wood formation in radiata pineWelsh, Shayne January 2006 (has links)
Pinus radiata is by far the dominant species grown in New Zealand plantations as a renewable source of wood. Several wood quality issues have been identified in the material produced, including the high incidence of compression wood, which is undesirable for end users. At present our understanding of the complex array of developmental processes involved in wood formation (which has a direct bearing on wood quality) is limited. Hence, the forest industry is interested in attaining a better understanding of the processes involved. Towards this goal, and for reasons of biological curiosity, the experiments described in this thesis were carried out to investigate several aspects of xylem cell development. In an in arbor study, changes in the orientation of cortical microtubules and cellulose microfibrils were observed in developing tracheids. Results obtained provide evidence that cortical microtubules act to guide cellulose synthase complexes during secondary wall formation in tracheids. The mechanisms involved in controlling cell wall deposition in wood cells are poorly understood, and are difficult to study, especially in arbor. A major part of this thesis involved the development of an in vitro method for culturing radiata pine wood in which hormone levels, nutrients, sugars and other factors, could be controlled without confounding influences from other parts of the tree. The method developed was used in subsequent parts of this thesis to study compression wood development, and the influence of the hormone gibberellin on cellulose microfibril organisation in the cell wall. Results from the in vitro compression wood experiments suggested that: 1. when a tree is growing at a lean, the developing cell wall was able to perceive compressive forces generated by the weight of the rest of the tree, rather than perceive the lean per se. 2. ethylene, rather than auxin, was involved in the induction of compression wood. Culture of stem explants with gibberellin resulted in wider cells, with steeper cortical microtubules, and correspondingly steeper cellulose microfibrils in the S2 layer of developing wood cells. This observation provides further evidence that the orientation of microtubules guides the orientation of cellulose microfibrils. Overall, the work described in this thesis furthers our knowledge in the field of xylem cell development. The stem culture protocol developed will undoubtedly provide a valuable tool for future studies to be carried out.
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Ultrastructural and immunochemical studies of elastin-associated microfibrils / by Ian W. ProsserProsser, Ian W. (Ian William) January 1984 (has links)
Bibliography: leaves 266-303 / xviii, 303 leaves : ill ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Pathology, 1985
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