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The forces that center the mitotic spindle in the C. elegans embryoGarzon-Coral, Carlos 31 March 2015 (has links) (PDF)
The precise positioning of the mitotic spindle to the cell center during mitosis is a fundamental process for chromosome segregation and the division plane definition. Despite its importance, the mechanism for spindle centering remains elusive. To study this mechanism, the dynamic of the microtubules was characterized at the bulk and at the cortex in the C. elegans embryo. Then, this dynamic was correlated to the centering forces of the spindle that were studied by applying calibrated magnetic forces via super-paramagnetic beads inserted into the cytoplasm of one- and two-cell C. elegans embryos. Finally, these results were confronted with the different centering models: cortical pushing model, cortical pulling model and the cytoplasmic pulling model.
This thesis shows that: (i) The microtubules dynamic of the spindle aster is controlled spatially in the C. elegans embryo, with not rescues and catastrophes in the cytoplasm but in the centrosome and the cortex, respectively. (ii) The centering mechanism of the spindle behaved roughly as a damped spring with a spring constant of 18 12 pN/ m and a drag coefficient of 127 65 pN s/ m (mean SD). This viscoelastic behavior is evidence of a centering force that recovers and/or maintains the position of the spindle in the cell center. (iii) It seems to be two mechanisms that recover/maintain the spindle position. A fast one that may work for transient displacements of the spindle and a slow one that work over large and long perturbations. (iv) The centering forces scale with the cell size. The centering forces are higher in the two-cell embryo. This result argues against a centering mechanism mediated by cytoplasmic factors. It seems to be a limit for the relation of centering force to size, as the forces found in the four-cell embryo are comparable to the single-cell ones. (v) The centering forces scale with the amount of microtubules in the cell. This strengthens the belief that the microtubules are the force transmission entities of the centering mechanism. (vi) The boundary conditions are important to maintain the centering forces. A transient residency time of microtubules at the cortex, which is controlled by cortical catastrophe factors, is indispensable for a proper force transmission by the microtubules. (vii) The elimination of cortical catastrophe factors provides evidence for microtubules buckling, which is taken as a proof of polymerization forces. (viii) The cortical pulling forces mediated by the gpr-1/2 pathway do not seem to be involved in centering and it is proposed they are present in the cell for off-center positioning purposes. (ix) The forces generated by vesicle transport are enough to displace the spindle and they are suggested to be auxiliary forces to centering. (x) The forces associated with the spindle change dramatically during cell division. From metaphase to anaphase the forces associated with the spindle scale up to five times. This behavior was consistent during the development of the embryo as the same pattern was observed in the one-, two- and four-cell embryo. (xi) The higher forces found during anaphase are not cortical pulling (via pgr-1/2 pathway) depended, and it is proposed the spindle is `immobilised' by tethering or by an unknown cortical pulling pathway.
To this date, this thesis presents the most complete in-vivo measurements of the centering forces in association with the microtubules dynamics. Taken together the results constrain molecular models of centering. This thesis concludes that most probably the predominant forces of the spindle centering mechanism during mitosis are generated by astral microtubules pushing against the cortex.
Additionally, this thesis presents the most complete map of forces during cell division during development, which will prove to be indispensable to understand the changes the spindle undergoes when it changes its function.
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Studies of Drosophila Greatwall kinase in mitosis, meiosis and oogenesisZhao, Xinbei January 2009 (has links)
No description available.
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Centrosome and Mitotic Spindle Organization in Human CellsLawo, Steffen 10 January 2014 (has links)
Robust bipolar spindle formation and faithful transmission of genetic material are vital to the maintenance of genome integrity and cellular homeostasis. Chromosome segregation errors can result in aneuploidy, a hallmark of human solid tumors. The assembly of a microtubule-based mitotic spindle relies on the concerted action of centrosomes, spindle microtubules, molecular motors and nonmotor spindle proteins. Before mitosis, centrosomes need to duplicate and increase in size in order to gain sufficient microtubule nucleation activity during bipolar spindle formation. This process is called centrosome maturation and coincides with a dramatic change of centrosome structure. However, the architecture of centrosomes and the organization of centrosome components in both interphase and mitosis have long remained elusive.
In this thesis, I describe the identification and characterization of novel regulators that are essential for centrosome and mitotic spindle organization in human cells. One such regulator is human Augmin, an evolutionarily conserved eight-subunit protein complex that has essential functions for centrosome and spindle integrity. I present evidence that human Augmin promotes microtubule-dependent nucleation of microtubules by targeting microtubule-nucleating complexes to the mitotic spindle. This function of Augmin is important for generation and/or stabilization of kinetochore microtubules within the mitotic spindle, and its loss results in destabilization of kinetochore microtubules and spindle assembly errors. These errors culminate in cells displaying multipolar spindles with fragmented centrosomes and mitotic arrest. A second regulator of centrosome and spindle organization described in this thesis is CEP192. I show that CEP192 is critical for recruitment of microtubule-nucleating complexes to centrosomes and, consequently, for centrosome maturation, mitotic spindle formation, and centriole duplication. Finally, I describe novel organizational features of the centrosome using a subdiffraction microscopy approach. Because of a lack of higher-order structural information, centrosomes have traditionally been described as amorphous clouds. My results now reveal that centrosome components instead occupy separable spatial domains throughout the cell cycle and highlight the role of higher-order protein organization in the regulation of centrosome assembly and function. Collectively, this work has significantly expanded our current knowledge of centrosome architecture and biogenesis and of the mechanisms that underlie robust bipolar spindle assembly.
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Basic nuclear protein synthesis during the cell cycle analysed by unit gravity sedimentation.Tang, Shun Chii. January 1972 (has links)
No description available.
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Centrosome and Mitotic Spindle Organization in Human CellsLawo, Steffen 10 January 2014 (has links)
Robust bipolar spindle formation and faithful transmission of genetic material are vital to the maintenance of genome integrity and cellular homeostasis. Chromosome segregation errors can result in aneuploidy, a hallmark of human solid tumors. The assembly of a microtubule-based mitotic spindle relies on the concerted action of centrosomes, spindle microtubules, molecular motors and nonmotor spindle proteins. Before mitosis, centrosomes need to duplicate and increase in size in order to gain sufficient microtubule nucleation activity during bipolar spindle formation. This process is called centrosome maturation and coincides with a dramatic change of centrosome structure. However, the architecture of centrosomes and the organization of centrosome components in both interphase and mitosis have long remained elusive.
In this thesis, I describe the identification and characterization of novel regulators that are essential for centrosome and mitotic spindle organization in human cells. One such regulator is human Augmin, an evolutionarily conserved eight-subunit protein complex that has essential functions for centrosome and spindle integrity. I present evidence that human Augmin promotes microtubule-dependent nucleation of microtubules by targeting microtubule-nucleating complexes to the mitotic spindle. This function of Augmin is important for generation and/or stabilization of kinetochore microtubules within the mitotic spindle, and its loss results in destabilization of kinetochore microtubules and spindle assembly errors. These errors culminate in cells displaying multipolar spindles with fragmented centrosomes and mitotic arrest. A second regulator of centrosome and spindle organization described in this thesis is CEP192. I show that CEP192 is critical for recruitment of microtubule-nucleating complexes to centrosomes and, consequently, for centrosome maturation, mitotic spindle formation, and centriole duplication. Finally, I describe novel organizational features of the centrosome using a subdiffraction microscopy approach. Because of a lack of higher-order structural information, centrosomes have traditionally been described as amorphous clouds. My results now reveal that centrosome components instead occupy separable spatial domains throughout the cell cycle and highlight the role of higher-order protein organization in the regulation of centrosome assembly and function. Collectively, this work has significantly expanded our current knowledge of centrosome architecture and biogenesis and of the mechanisms that underlie robust bipolar spindle assembly.
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Epidermal cell kinetics in normal and X-irradiated pig skinMorris, Gerard Michael January 1987 (has links)
No description available.
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Changes in leucocytes following stimulation of mitosis / by D.W. Burton. / Stimulation of mitosis in leucocytesBurton, D. W. (David Winn) January 1966 (has links)
Typescript / Includes bibliographical references. (p. [1]-[20]) / 171, [20] leaves : ill. ; 26 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 Zoology, 1966
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Isolation of copy number suppressors of the nimA1 kinase and mitotic regulation of nucleolar structure in Aspergillus nidulansUkil, Leena. January 2007 (has links)
Thesis (Ph. D.)--Ohio State University, 2007.
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Mitotic microtubule depolymerization and XMAP215 /Shirasu-Hiza, Michele, January 2004 (has links)
Thesis (Ph.D.)--University of California, San Francisco, 2004. / Includes bibliographical references. Also available online.
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Prevention of the inhibitory effects of imidazole, benzimidazole, and histamine on mitosis and root elongation in Vicia faba rootsMcCorquodale, Donald James, January 1956 (has links)
Thesis (Ph. D.)--University of Wisconsin--Madison, 1956. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 92-96).
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