Global ETD Search

31	Study of Neurodegenerative Process: Modeling Microtubule Cytoskeleton Disruption and Tau Protein Phosphorylation in Rodent Cortical Neurons Qian, Cheng 01 October 2018 (has links) No description available. Neurosciences Biology Microtubule Tubulin Tau Phosphorylation Zinc
32	Rev Interacts With Tubulin Heterodimers To Cause Cell Cycle Defects Kotha Lakshmi Narayan, Poornima 23 April 2010 (has links) No description available. Cellular Biology Rev Microtubules tubulin heterodimers
33	Mechanismen der sensiblen Mechanotransduktion in Kardiomyozyten Schreiber, Anna 14 November 2016 (has links) (PDF) Die vorgelegte Dissertationsschrift dient der Identifizierung des Mechanismus, über welchen neonatale Kardiomyozyten der Ratte biaxialen zyklischen Stretch wahrnehmen. Angriffspunkt dafür bildeten sowohl Stretch Activated Ion Channels (SAIC) als auch die mit Integrinen assoziierte Focal Adhesion Kinase (FAK). Die Inhibition der SAIC erfolgte mit Gadolinium und eine Blockade der FAK konnte durch den FAK-Inhibitor II erreicht werden. Eigens angelegte Zellkulturen wurden unter definierten Parametern für 24 Stunden unter Einwirkung genannter Stoffe gestretcht und anschließend einer Analyse mittels Immunfluoreszenz und Western Blot unterzogen. Gestretchte Kardiomyozyten richteten sich schräg zur Achse der einwirkenden Kraft aus und wiesen eine Polarisierung von Connexin 43 auf, außerdem zeigte sich dessen gesteigerte Expression. Durch die Blockade der FAK konnte lediglich eine aufgehobene Polarisierung von Connexin 43 bei unveränderter Expression und Ausrichtung der Kardiomyozyten festgestellt werden. Auch die Mikrotubuli veränderten nach Stretch ihre Orientierung bezogen auf die Zellachse. Die zunächst annähernde Parallelität der Fasern zeigte sich nach Inhibition der FAK deutlich aufgelockert. Für die Aktinfilamente konnte dies nicht nachgewiesen werden. Die Integrine dienen demnach der Wahrnehmung von Stretch und vermitteln die Polarisierung von Connexin 43 sowie die Orientierung der Mikrotubuli über die FAK. Für die anderen genannten Prozesse ist die Aktivierung eines FAK-unabhängigen Integrin-Signalweges denkbar. Gadolinium hatte insgesamt keinen Effekt auf beschriebene Veränderungen, sodass ein Einfluss der SAIC auf Stretch-induzierte Veränderungen in Kardiomyozyten ausgeschlossen werden konnte. Gleichzeitig konnte durch die Beobachtung der Polarisierung von Microtubule Organizing Center, Kinesin und Golgi-Apparat die Hypothese der sich durch Stretch orientierenden neonatalen Kardiomyozyte unterstützt werden, welche die Voraussetzung für die Anordnung von Connexin 43 an den Zellpolen darstellen könnte. Sowohl die Selbstorganisation des Myokards im Rahmen der Embryogenese als auch die Pathophysiologie verschiedener kardialer Erkrankungen könnte dadurch womöglich besser verstanden werden. Stretch Kardiomyozyten Connexin 43 FAK Tubulin stretch cardiomyocyte connexin 43 FAK tubulin ddc:610
34	Design, Syntheses and Bioactivities of Androgen Receptor Targeted Taxane Analogs, Simplified Fluorescently Labeled Discodermolide Analogs, and Conformationally Constrained Discodermolide Analogs Qi, Jun 22 April 2010 (has links) Prostate cancer is the most common non-skin cancer for men in America. The androgen receptor exerts transcriptional activity and plays an important role for the proliferation of prostate cancer cells. Androgen receptor ligands bind the androgen receptor and inhibit its transcriptional activity effectively. However, prostate cancer can progress to hormone refractory prostate cancer (HRPC) to avoid this effect. Chemotherapies are currently the primary treatments for HRPC. Unfortunately, none of the available chemotherapies are curative. Among them, paclitaxel and docetaxel are two of the most effective drugs for HRPC. More importantly, docetaxel is the only form of chemotherapy known to prolong survival in the HRPC patients. We hypothesized that the conjugation of paclitaxel or docetaxel with an androgen receptor ligand will overcome the resistance mechanism of HRPC. Eleven conjugates were designed, synthesized and biologically evaluated. Some of them were active against androgen-independent prostate cancer, but they were all less active than paclitaxel and docetaxel. Discodermolide is a microtubule interactive agent, and has a similar mechanism of action to paclitaxel. Interestingly, discodermolide is active against paclitaxel-resistant cancer cells and can synergize with paclitaxel, which make it an attractive anticancer drug candidate. Understanding the bioactive conformation of discodermolide is important for drug development, but this task is difficult due to the linear and flexible structure of discodermolide. Indirect evidence for the orientation of discodermolide in the tubulin binding pocket can be obtained from fluorescence spectroscopy of the discodermolide tubulin complex. For this purpose, we designed and synthesized a simplified fluorescently labeled discodermolide analog, and it was active in the tubulin assembly bioassay. In addition, a conformationally constrained discodermolide was designed to mimic the bioactive conformation according to computational modeling. The synthetic effort was made, but failed during one of the final steps. / Ph. D. docetaxel paclitaxel taxol tubulin binding conformation fluorescence discodermolide microtubules tubulin androgen receptor cyanonilutamide
35	The microtubule cytoskeleton of the corn smut fungus Ustilago maydis Shiel, Anna Iwona January 2014 (has links) Microtubules in the fungal pathogen Ustilago maydis have important roles, which include polar budding, morphogenesis and nuclear migration. They also serve as tracks for molecular motors, responsible for intracellular transport of organelles and membrane trafficking. Moreover, microtubules are indispensable during both interphase and cell division, and they play a crucial role in long-distance microtubule-based transport, which occurs in neurons or fungal hypha. Therefore, in order to carry out their functions correctly they need to be well organised and stabilised, which is achieved mainly by various microtubule-associated proteins. In this thesis, different aspects of microtubule (MT) cytoskeleton organisation in U. maydis were investigated, using bioinformatics and experimental approaches. In the first part of the thesis I studied the microtubule-associated protein (MAP) repertoire in U. maydis, which has never been done before in a comprehensive way. For this purpose, searches across five eukaryotic model organisms were conducted to identify all of their known MAPs, to query the U. maydis database. In addition, all of the proteins were checked for their domain architecture, to help decide if an orthologue had been found. As a result, 66 potential MAP orthologues were identified. The second part of this thesis focused on identifying novel factors involved in the organisation of the microtubule cytoskeleton using a specially designed genetic screen. This work involved five microtubule-organisation defect (MOD) mutants, generated by UV-mutagenesis, which were characterised by inability to produce long hyphae as well as by short, fragmented microtubules. To find which genes were responsible for this phenotype, the genomes of all mutants were sequenced and compared with a wild-type genome, and mutations in many genes were found. The analysis revealed potential candidate genes responsible for the specific phenotype of the mutants. However, most probably, UV-generated point mutations in more than one gene played a part in the defective microtubule array. In the final part of this thesis, the function of two beta-tubulin isotypes in U. maydis was analysed. Using conditional mutants, I demonstrated that there are subtle functional differences between the two beta tubulins. 500
36	Regulation of microtubule nucleation in Schizosaccharomyces pombe : recruitment of Mto1 to the site of the prospective eMTOC Miller, Victoria Jane January 2010 (has links) Mto1 recruits γ-tubulin to the sites of cytoplasmic microtubule nucleation in the fission yeast Schizosaccharomyces pombe. The regulation of Mto1 localisation is central to re-modelling of the microtubule cytoskeleton during the cell cycle. This thesis describes how Mto1 is recruited to the cell equator during mitosis, thereby establishing the equatorial microtubule nucleation centre (eMTOC). F-actin is found to be required for Mto1 localisation to the cell equator and Mto1 is shown to co-localise with the cytokinetic actin ring (CAR). Yeast 2-hybrid screening and tandem-affinity purification were used to screen for additional proteins required for Mto1 localisation to the equator. Further candidate screening identified Myp2, a type II myosin present in the CAR, as being required for Mto1 localisation to the cell equator. Myp2 is shown to physically interact with Mto1 and to be required for formation of the post-anaphase microtubule array. The regulation of Mto1 localisation to the cell equator was also studied. Time-lapse microscopy reveals that Mto1 localisation to the equator does not require either the anaphase-promoting complex or the septation initiation network, both of which have been previously shown to be necessary for the recruitment of γ-tubulin to the eMTOC. Maintenance of the equatorial CAR has previously been attributed to the postanaphase array. The position of the CAR in the mto1-427 mutant strain, which fails to nucleate a PAA, is shown to be unaltered from wild-type strain during exponential growth, suggesting that the PAA does not centre the CAR during normal growth. 572.8
37	Exploitation of the Protein Tubulin For Controlling African Trypanosomiasis ngiles@anhb.uwa.edu.au, Natalie Giles January 2005 (has links) This thesis presents the results of an investigation into the structural protein, tubulin, as a potential target for anti-trypanosomatid drug discovery and vaccine development. Recombinant alpha- and beta- tubulin proteins from Trypanosoma brucei rhodesiense were expressed as soluble fusion proteins in an E. coli expression system. The recombinant alpha- and beta- tubulins were used to determine the nature of binding of novel trifluralin analogues EPL-AJ 1003, 1007, 1008, 1016 and 1017. Native tubulin from rats was used to determine the extent of binding to mammalian tubulin. The results of this study clearly demonstrate two important aspects of the binding of trifluralins to tubulin. Firstly, they have specific affinity for trypanosomal tubulin compared with mammalian regardless of the chemical composition of the trifluralin analogue tested. Secondly, they have a demonstrably stronger affinity for alpha-tubulin compared with beta-tubulin. In addition, compounds 1007, 1008, 1016 and 1017 have strong binding affinities for alpha-tubulin, with limited binding affinity for mammalian tubulin, which indicates that these compounds selectively bind to trypanosomal tubulin. The morphology of bloodstream forms of T. b. rhodesiense exposed to trifluralin analogues was studied using electron microscopy and immunofluorescence to determine the ultrastructural changes these compounds induce as a result of binding to tubulin. All compounds tested induced severe irreparable damage in T. b. rhodesiense, including perturbation of subpellicular microtubules, extensive cytoplasmic swellings, axoneme and paraflagellar rod malformation, disconfiguration around the flagellar pocket and membrane disintegration. These results suggest that the mechanism of action of these trifluralin analogues is through the disruption of polymerization of tubulin into microtubules as a result of binding to alpha-tubulin. The potential for recombinant trypanosomal tubulins to be used as vaccine candidates was assessed by monitoring parasitaemia and length of survival of mice immunised with the proteins and challenged with a lethal infection of T. b. rhodesiense. Although all the mice vaccinated with recombinant tubulin developed a patent parasitaemia and did not survive, they were partially protected because their patency period and length of survival were significantly greater than the control groups. Furthermore, plasma collected from mice immunised with recombinant trypanosomal tubulin contained antibodies that recognized tubulin in a soluble extraction from T. b. rhodesiense. The results of this thesis confirm the potential for the structural protein, tubulin, to be used as a target for anti-trypanosomatid drug discovery and vaccine development. tubulin trypanosomiasis recombinant protein drug discovery vaccine discovery
38	Tropomyosin in Normal and Malignant Cells and the Action of Picropodophyllin on the Microfilament and Microtubule Systems Zhao Rathje, Li-Sophie January 2009 (has links) Cell motility is a fundamental process, enabling cells to migrate, for instance during embryogenesis, tissue repair and defense. Force is generated by two protein systems, which also participate in cell proliferation, control macromolecular and organelle distribution and determine the fine structure of the cell interior. The major components of these are actin and tubulin, respectively, and they are referred to as the microfilament and the microtubule systems. This thesis focuses on tropomyosin, one of many microfilament associated proteins coupled to actin dynamics and organization and expressed in several isoform variants. Altered distribution and isoform expression of tropomyosin are signatures of malignant cells and are dealt with in the current thesis. The presence of tropomyosin isoforms in protruding lamellipodia of migrating cells is demonstrated, and a method to fractionate tropomyosin depending on its organization in an easily extractable, and a more tightly bound cytoplasmic form is presented. Analysis of the loosely associated tropomyosin fraction by gel filtration chromatography revealed that most of the tropomyosins in this fraction exist in a multimeric form. It was also observed that the distribution of tropomyosin varied between non-transformed and transformed cells with most of the isoforms enriched in the loosely bound fraction in the latter category of cells. Possibly this reflects the extensive reorganization of the microfilament system observed in cancer cells and which, depending on the context, can be normalized by introduction of certain tropomyosin isoforms. Many anti-cancer drugs target the microtubule system, inhibit cell division and promote apoptosis. Here it is shown that picropodophyllin, which has promising anticancer properties has a destabilizing effect on microtubules and via the microfilament system causes cells to detach from their substratum. Furthermore, picropodophyllin interferes with stimulation of the insulin-like growth factor receptor, which is involved in growth stimulation, differentiation and survival and whose expression is up-regulated in cancer cells. Tropomyosin Actin Picropodophyllin Tubulin Cell motility Cancer Cell biology Cellbiologi
39	Molecular dissection of established and proposed members of the Op18/Stathmin family of tubulin binding proteins Brännström, Kristoffer January 2009 (has links) My initial aim was a functional analysis of the conserved Op18/stathmin family of microtubule-regulators, which includes the ubiquitous cytosolic Op18 protein and the neural membrane-attached RB3 and SCG10 proteins. The solved X-ray structure has shown that these proteins form a complex with tubulin -heterodimers via two imperfect helical repeats, which result in two head-to-tail aligned heterodimers in a tandem-tubulin complex. We have analyzed GTP exchange and GTP hydrolysis at the two exchangeable GTP-binding sites (E-site) within the tandem-tubulin complex. A comparison of Op18, RB3 and SCG10 proteins indicates that Op18/Stathmin family proteins have evolved to maintain the two heterodimers in a configuration that restrains the otherwise potent GTPase productive interactions facilitated by the head-to-head alignment of heterodimers in protofilaments. We concluded from these studies that tubulin heterodimers in complex with Op18/stathmin family members are subject to allosteric effects that prevent futile cycles of GTP hydrolysis. To understand the significance of the large differences in tubulin affinity of Op18, RB3 and SCG10, we have fused each of the heterodimer-binding regions of these three proteins with the CD2 cell-surface protein to generate confined plasma membrane localization of the resulting CD2 chimeras. We showed that, in contrast to CD2-Op18, both the CD2-SCG10 and CD2-RB3 chimeras sequester tubulin at the plasma membrane, which results in >35% reduction of cytosolic tubulin heterodimer levels. However, all three CD2-chimeras, including the tubulin sequestration-incompetent CD2-Op18, destabilize interphase microtubules. Given that microtubules are in extensive contact with the plasma membrane during the interphase, these findings indicate that Op18-like proteins have the potential to destabilize microtubules by both sequestration and direct interaction with microtubules. Sm16/SmSLP (Stathmin-Like Protein) has been identified as a protein released during skin penetration of the Schistosoma mansoni parasite. This protein has been ascribed both anti-inflammatory activities and a functional similarity with the conserved cytosolic tubulin-binding protein stathmin/Op18. However, our studies refuted any functional similarity with stathmin/Op18 and we found instead that Sm16/SmSLP is a lipid bilayer binding protein that is taken up by cells through endocytosis. To study immuno-modulatory properties of Sm16/SmSLP, we designed an engineered version with decreased aggregation propensity, thus facilitating expression and purification of a soluble Sm16 /SmSLP protein from the eukaryotic organism Pichia pastoris. Determination of the hydrodynamic parameters revealed that both the recombinant and native Sm16/SmSLP is a ~9-subunits oligomer. The recombinant protein was found to have no effect on T lymphocyte activation, cell proliferation or the basal level of cytokine production of whole human blood or monocytic cells. Interestingly, however, recombinant Sm16 was found to potently inhibit the cytokine response to the Toll-like receptor (TLR) ligands lipopolysaccharide (LPS) and Poly(I:C). Since Sm16 specifically inhibits degradation of the IRAK1 signaling protein in LPS stimulated monocytes, it seems likely that inhibition is exerted proximal to the TLR-complex. Op18/Stathmin Sm16 tubulin microtubule schistosoma mansoni Molecular biology Molekylärbiologi
40	Assessment of the Antiprotozoal Activity of some Tubulin Inhibitors Following Cyclodextrin Complexation. pmenon1@optusnet.com.au, Kathleen Ilona Menon January 2002 (has links) The purpose of the present study was to evaluate the potential usefulness of tubulin inhibitors when complexed with hydroxypropyl-â-cyclodextrin (ÇPâCD) against a range of protozoan parasites. This approach involved investigations into the complexation of these drugs with ÇPâCD, and subsequent investigations of these drugs and their complexes in regard to cytotoxicity, pharmacokinetics, in vitro efficacy against Giardia, Cryptosporidium and rodent malaria (Plasmodium chabaudi), and their in vivo efficacy against Giardia and malaria. Albendazole (ABZ) is a benzimidazole carbamate with a broad anti-parasite spectrum, while the dinitroanilines trifluralin (TF) and oryzalin (OZ) have recently been found to exhibit activity against certain parasites. All three compounds are microtubule antagonists in either nematodes or weeds and have poor aqueous solubility, with the solubility of ABZ and OZ dependent on pH. Cyclodextrins (CD) have a hydrophobic cavity that allows them to form inclusion complexes with hydrophobic drugs, resulting in increased drug aqueous solubility, and often, improved drug dissolution and bioavailability. Thus the complexation of these drugs with ÇPâCD was investigated. All three compounds exhibited type AL phase solubility diagrams with ÇPâCD complexation, with additional increases in ABZ and OZ solubility achieved through the manipulation of temperature and pH. OZ displayed a stronger interaction with ÇPâCD when ionised over its neutral form. However, insufficient concentrations of the TF/ÇPâCD complex were achieved for drug efficacy studies. The cytotoxicity of the drugs and their complexes was assessed using the assay kit Cytotox 96 with human carcinoma cells. This is a colourimetric assay that measures lactate dehydrogenase release as a consequence of compromised cellular and membrane integrity. Both ABZ and OZ are cytotoxic to rapidly proliferating and differentiating cells but are not cytotoxic to cells in the stationary phase. Complexation did not affect drug cytotoxicity. In pharmacokinetic studies, complexation improved ABZ (and metabolites) bioavailability, but had no significant affect on OZ bioavailability. In vitro drug assessment studies found ABZ to be highly effective against Giardia, and effectiveagainst Cryptosporidium and malaria. OZ on the other hand exhibited no activity against Giardia, but was effective against Cryptosporidium and malaria. Complexation did not improve the antiprotozoal efficacy of either ABZ or OZ. In particular, excess ÇPâCD decreased the antigiardial effects of ABZ, possibly due to competitive complex formation. In addition, complexation did not improve the antiprotozoal effects of ABZ in vivo. However, the cytotoxic effect of the ABZ/ÇPâCD complex was more evident in the treatment of malaria in vivo, resulting in increased anaemia and suppression in weight gain, due to the improved bioavailability of ABZ and metabolites. ÇPâCD alone was found to be cytotoxic at greater than 2.5%, and inhibited Giardia both in vitro and in vivo at greater than 1% and 2% respectively. This was attributed to membrane disruption caused by the dissolution and removal of membrane components. In comparison, malaria grew better in the presence of ÇPâCD in vitro, with no detrimental effect observed at up to 8% ÇPâCD. This was attributed to either the increased solubilization of a necessary media component, or the complexation and removal of an inhibitory compound from the cultivation medium. Therefore ÇPâCD complexation did not improve the antiprotozoal activity of the tubulin antagonists ABZ and OZ. However, the results of the pharmacokinetic studies suggest that anthelmintic activity of ABZ, particularly against systemic infections, may be improved with oral administration of the ABZ/ÇPâCD complex. In addition, the antiparasitic activity of ÇPâCD alone may be promising, especially against intestinal infections. Finally, the improved in vitro cultivation of P. chabaudi in the presence of ÇPâCD presents a promising approach to its potential long term cultivation. Cyclodextrin Complexation Tubulin Inhibitors Antiprotozoal Activity protozoan parasites

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