Global ETD Search

1	The role of tubulin polyglutamylation and its potential effectors in spermatogenesis / Le rôle de la polyglutamylation de la tubuline et de ses effecteurs potentiels dans la spermatogenèse. Lawera, Aleksandra Anna 17 December 2012 (has links) Les microtubules sont des éléments du cytosquelette, composées d'hétérodimères de tubuline de type α et β. Ils jouent un rôle important dans plusieurs processus cellulaires, dont le transport cytoplasmique, la mobilité et la division cellulaire. Cependant, les mécanismes par lesquels les microtubules sont adaptés à ces rôles très différents restent largement méconnus.Les modifications post-traductionnelles de la tubuline pourraient contribuer à la diversité de fonction des microtubules. Parmi celles-ci, la polyglutamylation pourrait jouer un rôle important en changeant d'une manière importante les propriétés des microtubules, et les adaptant ainsi à leurs différents rôles. La polyglutamylation correspond à l'addition de longues chaînes latérales d'acides glutamiques aux extrémités C-terminales des tubulines α et β. Ces régions sont des sites connues d'interactions de la tubuline avec ses protéines associées (MAP) et les moteurs moléculaires. Au cours de mes travaux, j'ai étudié le rôle de polyglutamylation de la tubuline dans le développement des spermatozoïdes. En utilisant la souris et la drosophile comme organismes modèles, j'ai montré que le changement de niveau de polyglutamylation de la tubuline dans les spermatozoïdes, soit par une régulation positive soit par régulation négative, provoque des anomalies structurales des spermatozoïdes et entraîne une stérilité des mâles. J'ai également étudié la rôle de la katanine, un enzyme coupant les microtubules, effecteur potentiel de la polyglutamylation. J'ai montré qu'en absence de la katanine, la production des cellules germinales est gravement compromise chez les mâles, provoquant également une stérilité. Pris ensemble, ces résultats démontrent que la régulation de polyglutamylation de la tubuline est indispensable pour le développement correct des spermatozoïdes et que son effet pourrait être médié par la katanine, enzyme dont l'activité pourrait dépendre de la polyglutamylation de la tubuline.Durant mes travaux, j'ai également développé une nouvelle technique de production des microtubules différentiellement glutamylés. En utilisant comme matière primaire de la tubuline de cerveau porcin, hautement polyglutamylée, j'ai réalisé une déglutamylation produisant ainsi une tubuline déglutamylée. En utilisant les deux types de microtubules (avec ou sans polyglutamylation), il est possible de tester si les interactions entre les microtubules et les MAP dépendent de la polyglutamylation de la tubuline. / Microtubules are essential cytoskeletal elements composed of α- and β-tubulin heterodimers. They are involved in a number of cellular processes, including intracellular transport, cell motility and cell division. However, how microtubules can adapt to all these different functions remains largely unknown. One of the mechanism, which could contribute to microtubule diversity are posttranslational modifications of tubulin. Among tubulin modifications polyglutamylation has a high potential for changing microtubule properties and thus adapting them to different roles. It consists of addition of long glutamate side chains to multiple glutamate residues located in the C-terminal tail of both α- and β-tubulin, which are known as interaction sites for many microtubule associated proteins (MAPs) and molecular motors. In my studies I focused on the role of polyglutamylation in sperm development. Using mice and Drosophila as model systems, I showed that changing the levels of this modification, either by up- or downregulation, results in the assembly of structurally abnormal sperm and causes male sterility. In addition, I also addressed the role of one of the potential effectors of polyglutamylation, a microtubule-severing enzyme called katanin. I demonstrated that in the absence of katanin the production of male germ cells is severely compromised leading to male sterility. Taken together my data suggest that proper balance of tubulin polyglutamylation is essential for sperm development and that its effects may be mediated by katanin whose activity has been proposed to be dependent on tubulin polyglutamylation. Moreover, during my PhD project I developed a method for production of differentially glutamylated microtubules. Using porcine brain tubulin, which is known to be highly glutamylated, as a starting material I perform deglutamylation to obtain the non-glutamylated version of it. Obtaining these two types of tubulin allows now to directly testing whether the interactions between microtubules and the MAPs of interests are dependent on tubulin polyglutamyaltion. Microtubules Polyglutamylation Spermatogenèse Katanine Microtubules Polyglutamylation Spermatogenesis Katanin
2	Uloha kataninu, ATPázy štěpící mikrotubuly, při modulaci buněčné motility a proliferace glioblastomových buněk. / Uloha kataninu, ATPázy štěpící mikrotubuly, při modulaci buněčné motility a proliferace glioblastomových buněk. Uhlířová, Jana January 2016 (has links) Glioblastomas are the most common and the deadliest types of brain tumours. Due to their highly invasive behaviour, they are incurable by convencial therapeutical strategies. It was shown that some components of microtubules, namely class III β-tubulin, γ-tubulin and microtubule severing protein spastin are overexpressed in glioblastoma cell lines as well as glioblastomas. This diploma thesis is focused on the expression, subcellular distribution and function of katanin, another microtubule-severing enzyme, in gliobastoma cell lines. Katanin is formed by catalytic (p60) and regulatory (p80) subunits. Expression and cellular localization of both katanin subunits was studied in panel of human glioblastoma cell lines isolated form adults (T98G, U87MG, U118MG and U138 MG) and child (KNS42). Data presented in this thesis demonstrated that katanin subunits were overexpresed both on transcript and protein levels in T98G, U87MG and KNS42 cell lines, but not in U138MG and U118MG cell lines when compared to normal non- transformed human astrocytes. Immunofluorescence microscopy revealed that both katanin subunits were diffusively distributed in cytoplasm and concentrated on spindle poles of mitotic cells and on leading edges of migrating cells. Examination of cell motility revealed that velocities in...
3	The Generation of Recombinant Zea mays Spastin and Katanin Proteins for In Vitro Analysis Alodailah, Sattam Sonitan 12 1900 (has links) Plant microtubules play essential roles in cell processes such as cell division, cell elongation, and organelle organization. Microtubules are arranged in highly dynamic and ordered arrays, but unlike animal cells, plant cells lack centrosomes. Therefore, microtubule nucleation and organization are governed by microtubule-associated proteins, including a microtubule-severing protein, katanin. Mutant analysis and in vitro characterization has shown that the highly conserved katanin is needed for the organization of the microtubule arrays in Arabidopsis and rice as well as in a variety of animal models. Katanin is a protein complex that is part of the AAA+ family of ATPases. Katanin is composed of two subunits, katanin-p60, a catalytic subunit and katanin-p80, a regulatory subunit. Spastin is another MT-severing protein that was identified on the basis of its homology to katanin. In animal cells, spastin is also needed for microtubule organization, but its functionality has not yet been investigated in plants. To initiate an exploration of the function of katanin-p60 and spastin in Zea mays, my research goal was to generate tools for the expression and purification of maize katanin-p60 and spastin proteins in vitro. Plasmids that express katanin-p60 and spastin with N-terminal GST tags were designed and constructed via In-Fusion® cloning after traditional cloning methods were not successful. The constructs were expressed in E. coli, then the recombinant proteins were purified. To determine if the GST-tagged proteins are functional, ATPase activity and tubulin polymerization assays were performed. While both GST-katanin-p60 and GST-spastin hydrolyzed ATP indicating that the ATPase domains are functional, the results of the tubulin polymerization assays were less clear and further experimentation is necessary. Microtubules Spastin katanin cytoskeleton Plant microtubules. Recombinant proteins. Corn -- Cytology.
4	Regulation of Katanin Activity on Microtubules Tyler, Madison A. 31 October 2017 (has links) (PDF) The cytoskeleton is a dynamic network of microtubules constantly being reorganized to meet the spatiotemporal demands of the cell. Microtubules are organized into subcellular highways to control cell processes such as cell division, cargo transport, and neuronal development and maintenance. Reorganization of this intricate network is tightly regulated by various stabilizing and destabilizing microtubule-associated proteins that decorate the network. Katanin p60 is a microtubule destabilizing enzyme from the ATPases Associated with various Activities (AAA+) family. It can both sever and depolymerize microtubules. In order to sever microtubules, katanin recognizes the tubulin carboxy-terminal tails (CTTs) and hydrolyzes ATP. Using super-resolution microscopy and image analysis, we find that the tubulin CTTs are not required for katanin to depolymerize microtubules. We also characterize the regulation of microtubule severing and depolymerization by katanin in various nucleotide states. A better understanding of how CTTs and nucleotides regulate microtubule severing and depolymerization by katanin will help future research aimed to correct katanin activity when these processes goes awry as in improper chromosome segregation during mitosis or loss of microtubule integrity in neuronal diseases. katanin enzyme microtubules ATPase depolymerization severing Biophysics Molecular Biology
5	Rôle de la spastin dans le developpement des circuits moteurs et leur dégénérescence dans les paraplégies spastiques héréditaires / Spastin implication in the development of motor circuits and their degeneration in hereditary spastic paraplegias Jardin, Nicolas 30 September 2016 (has links) Les mutations du gène SPG4 codant la spastin sont responsables de la forme la plus fréquente de Paraplégies Spastiques Héréditaires (PSH), des maladies neurologiques caractérisées par une dégénérescence des faisceaux cortico-spinaux. La spastin, ainsi que son homologue p60-katanin sont des enzymes de cassure des microtubules (MSE) essentielles à la croissance des neurones moteurs spinaux (NMS) chez l'embryon de poisson-zèbre mais dont le rôle dans les processus de guidage axonal également dépendant des microtubules (MTs) demeurent énigmatiques. Les principaux objectifs de ma thèse ont consisté à préciser le rôle et le degré de redondance fonctionnelle existant entre ces deux MSE lors de l'établissement des circuits moteurs chez ce téléoste et de clarifier les mécanismes pathogéniques à l¿origine des PSH liées au gène SPG4.J'ai tout d'abord contribué à montrer que la p60-Katanin contrôle la trajectoire des axones des NMS et la mobilité des larves de façon dose-dépendante et non redondante avec la spastin. De plus, notre étude identifie la polyglutamylation des MTs par TTLL6 comme un élément clé de l'activité de la p60-Katanin lors de ce processus. Sur le même modèle, j'ai révélé un rôle différentiel des isoformes majoritaires de la spastin (résultant d¿une traduction alternative, M1 et M61) au cours du développement des NMS en démontrant un rôle coopératif de M1 et d'autres protéines de PSH dans l'inhibition de la voie des BMPs et révélant un rôle pour M61 en aval de la signalisation Neuropilin-1. Ces données suggèrent que l'altération de ces deux grandes voies de signalisation essentielles au développement des NMS pourrait contribuer à la pathogénèse des formes SPG4. / Mutations in SPG4, encoding spastin cause the major form of Hereditary Spastic Paraplegias (HSP), a paralytic disorder characterised by the degeneration of the corticospinal tracts. Spastin and its close homologue p60-katanin are microtubule-severing enzymes (MSE) required for spinal motor neuron (SMN) axon extension during zebrafish development. However, their roles in SMN axon navigation which also rely on microtubules (MTs) remain elusive. My PhD work aimed at refining the functional specificity and redundancy of these MSE during motor circuit wiring and clarifying the physiopathology of SPG4-linked HSP. I have first contributed to show that p60-Katanin controls SMN axon targeting and larval locomotion in a dose-dependent manner. We also demonstrated that Spastin and p60-Katanin play differential roles in SMN navigation and identified TTLL6-mediated MT polyglutamylation as a key event in regulating p60-Katanin activity in this process. Concomitantly, I have conducted a functional analysis of spastin main isoforms (resulting from alternative translation, M1 and M61) during zebrafish development, which reveals their critical and specific involvement in two distinct signalling pathways that are both essential for motor circuit wiring and locomotor behaviours. This study has provided compelling evidences for a concerted role for M1 and other HSP proteins in the down-regulation of the BMP pathway and reveals a specific role for M87 as a downstream effector of Neuropilin-1 signalling. Altogether, our study emphasizes defective BMP signalling as a key pathogenic mechanism in HSP, and shows that dysregulation of the Neuropilin-1 pathway may equally contribute to SPG4-linked HSP. Spastin Katanin Guidage axonal Signalisation Bmp Neuropilin Spastin Zebrafish Spastic paraplegias 616.8
6	Rôle des ATPases de type AAA associées aux microtubules et de la polyglutamylation de la tubuline dans la navigation axonale des motoneurones de poisson-zèbre / AAA microtubule-associated proteins and tubulin polyglutamylation implication in zebrafish spinal motor neuron axon navigation Ten Martin, Daniel 22 September 2014 (has links) Le bon fonctionnement du système nerveux dépend de la précision avec laquelle sont formées les connexions synaptiques lors du développement embryonnaire et post-natal. La navigation des cônes de croissance vers leurs cibles dépend en dernier lieu de la réorganisation dynamique du réseau d’actine et de microtubules (MTs). Historiquement considérés comme les acteurs principaux de l'élongation axonale, les MTs ont été plus récemment impliqués dans des processus d'orientation du cône de croissance et de guidage axonal, montrant ainsi le rôle capital que les protéines associées aux microtubules (MAPs) peuvent jouer dans la navigation axonale. Notre équipe s’intéresse aux protéines appartenant à un sous-groupe des protéines AAA (pour ATPases Associated with diverse cellular Activities) comprenant trois enzymes de cassure des MTs : la spastin, la katanin et la fidgetin, ainsi que deux protéines apparentées à cette dernière, les fidgetin-like 1 et 2 L’analyse fonctionnelle de fidgetin-like 1 et katanin chez le poisson zèbre a permis de montrer le rôle différentiel de ces protéines dans le guidage axonal des Neurones Moteurs Spinaux (NMS). Finalement, nous avons évalué l’impact d’une modification post-traductionnelle de la tubuline, la polyglutamylation, sur le développement axonal des NMS et l’activité de cassure des microtubules par katanin. Notre étude de deux enzymes de polyglutamylation neuronales, TTLL6 et TTLL11, a mis en évidence le rôle différentiel de ces deux enzymes dans la navigation axonale des NMS, ainsi que l’influence de la polyglutamylation par TTLL6, mais pas par TTLL11, sur l’activité de cassure des MTs par katanin dans ce processus biologique. / The formation of a functional nervous system depends on the accuracy of its network wiring during embryonic and postnatal development. Axon outgrowth and navigation ultimately rely on the reorganization of the microtubule (MT) and actin networks. Historically considered as key players in axon extension, MTs have been gradually shown to play an instructive role in axon guidance decisions, which sheds new light on the potential involvement of MT-associated proteins (MAPs) in these navigational processes. Our team program aims at deciphering the differential role and functional redundancy of a few neuronal MT-associated ATPases, including the MT-severing spastin, katanin and the newly discovered fidgetin-like 1, in SMN axon outgrowth. During my PhD, I have first participated in the functional analysis of fidgetin-like 1, which has revealed that this ATPase controls SMN axon outgrowth via the regulation of MT plus-end dynamics. My main PhD project focused on the involvement of katanin in SMN development, which has established the pivotal role of this MT-severing enzyme in SMN axon targeting. Furthermore, I have explored the potential involvement of a MT post-translational modification, the tubulin polyglutamylation, in SMN axon outgrowth and navigation, and its influence on katanin MT-severing activity. Interestingly, my analysis of two neuronal MT polyglutamylases, TTLL6 and TTLL11, shows that these two enzymes differentially affect SMN axon outgrowth and pathfinding, and reveals the exclusive impact of TTLL6-mediated polyglutamylation on katanin MT-severing activity during this developmental process. Microtubule Katanin Poisson zèbre Polyglutamylation TTLL Guidage axonal Microtubule Zebrafish 573.8
7	Characterizing the Inhibition of Katanin Using Tubulin Carboxy-Terminal Tail Constructs Reed, Corey E 07 November 2016 (has links) Understanding how the cellular cytoskeleton is maintained and regulated is important to elucidate the functions of many structures such as the mitotic spindle, cilia and flagella. Katanin p60, microtubule-severing enzymes from the ATPase associated with cellular activities (AAA+) family, has previously been shown in our lab to be inhibited by free tubulin as well as α- and β-tubulin carboxy-terminal tail (CTT) constructs. Here we investigate the inhibition ability of several different tubulin CTT sequences. We quantify the effect of the addition of these constructs on the severing and binding activity of katanin. We find that some constructs inhibit katanin better than others and two constructs that appear to enhance katanin activity. Our findings add nuance to our previous findings that consensus α-tubulin tails are less inhibitory of katanin than consensus β-tubulin [3]. Surprisingly, we find that a polyglutamate sequence activates katanin while it has previously been shown to inhibit spastin, a different microtubule-severing enzyme associated with the neuromuscular disease Hereditary Spastic Paraplegia [23]. These results highlight that different CTT sequences can control the activity of severing enzymes and ultimately affect the cytoskeletal network organization in a cell type and location-dependent manner. Microtubule Katanin Severing Cytoskeleton Inhibition Carboxy-terminal tail Biochemistry Biophysics Molecular Biology
8	Molecular simulations uncover the nanomechanics of heat shock protein (70 kDa) & Indentation simulations of microtubules reveal katanin severing insights Merz, Dale R., Jr. 02 June 2020 (has links) No description available. Biophysics heat shock protein microtubules molecular dynamics pulling simulation katanin severing protein folding
9	A Genetic Approach to Identify Proteins that Interact with Eukaryotic Microtubule Severing Proteins via a Yeast Two Hybrid System Alhassan, Hassan H 05 1900 (has links) Microtubules (MT) are regulated by multiple categories of proteins, including proteins responsible for severing MTs that are therefore called MT-severing proteins. Studies of katanin, spastin, and fidgetin in animal systems have clarified that these proteins are MT-severing. However, studies in plants have been limited to katanin p60, and little is known about spastin or fidgetin and their function in plants. I looked at plant genomes to identify MT-severing protein homologues to clarify which severing proteins exist in plants. I obtained data from a variety of eukaryotic species to look for MT-severing proteins using homology to human proteins and analyzed these protein sequences to obtain information on the evolution of MT-severing proteins in different species. I focused this analysis on MT-severing proteins in the maize and Arabidopsis thaliana genomes. I created evolutionary phylogenetic trees for katanin-p60, katanin-p80, spastin, and fidgetin using sequences from animal, plant, and fungal genomes. I focused on Arabidopsis spastin and worked to understand its functionality by identifying protein interaction partners. The yeast two-hybrid technique was used to screen an Arabidopsis cDNA library to identify putative spastin interactors. I sought to confirm the putative protein interactions by using molecular tools for protein localization such as the YFP system. Finally, a Biomolecular Fluorescence Complementation (BiFC) assay was initiated as a proof of concept for confirmation of in vivo protein-protein interaction. Microtubules Microtubule-severing proteins MT-severing Katanin Spastin Fidgetin Cell biology Yeast Two Hybrid Protein-protein interaction Biology, Genetics Biology, Molecular Biology, Cell Plant microtubules. Proteins.

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