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1	Prosthecobacter BtubAB form bacterial mini microtubules Deng, Xian January 2018 (has links) The tubulin/FtsZ superfamily contains a large set of proteins that spans through all kingdoms of life, with αβ-tubulins being the eukaryotic representatives and FtsZ being the best studied prokaryotic homologue. It is believed that all tubulin/FtsZ-related proteins have evolved from a common ancestor, however, members from this superfamily have diverged in many aspects. αβ-tubulins polymerise into giant and hollow microtubules in the presence of GTP. Despite the size of around 25 nm wide, microtubules display sophisticated dynamics. In particular, dynamic instability, the stochastic change between fast growth and rapid shrinkage, is a hallmark of microtubules. In contrast to αβ-tubulins, FtsZ lacks the C-terminal domain of tubulins and it probably functions as single homopolymeric protofilaments, possibly through treadmilling dynamics. There is strong divergence of the biological functions in the tubulin/FtsZ superfamily. Microtubules are involved in fundamental processes such as motility, transport and chromosomal segregation, whereas FtsZ is involved in bacterial cytokinesis (bacterial cell division), and the equivalent role of FtsZ is carried out by actin-based and ESCRTIII-based systems in eukaryotes. It seems that there is a big evolutionary gap between αβ-tubulins and FtsZ, and the only properties that are conserved within the tubulin/FtsZ superfamily are fold, protofilament formation and GTPase activity. In 2002, a pair of tubulin-like genes, btuba and btubb were identified in Prosthecobacter bacteria, with higher sequence homology to eukaryotic tubulins than FtsZ or any other bacterial homologues. The crystal structures solved later revealed, again, a closer similarity to αβ-tubulins than to their prokaryotic equivalents. It has been known for a while that BtubAB form filaments in the presence of GTP, however, little knowledge has been available regarding the filament architecture. In this project, I determined the near atomic resolution structure of the in vitro BtubAB filament using cryoEM and cryoET, revealing a hollow tube that consists of four protofilaments. A closer look showed that BtubAB filaments have many conserved microtubule features including: an overall polarity, similar longitudinal contacts, M-loops in lateral interfaces, and the presence of the seam, a structural hallmark of microtubules. My study also shows that BtubC, a protein with a TPR fold, binds to the BtubAB filaments in a stoichiometric manner, similar to some MAPs on microtubules. Based on this work, I concluded that BtubAB from Prosthecobacter form bacterial ‘mini microtubules’, and my work provided interesting insight into the evolution of tubulin/FtsZ-related proteins.
2	Coiled coil Cytoskeleton in Bacterial Cell Architecture : Studies of Growth and Development in Streptomyces Bagchi, Sonchita January 2011 (has links) Bacterial cytoskeleton is an exciting and relatively new field of research. Recent findings have proven that microbes are well-organized and neatly structured organisms. In this study we have shown that intermediate filament-like proteins with a characteristic rod domain architecture of coiled coil segments separated by non-coiled coil linkers, are widely spread among bacteria. We identified and characterized an intermediate filament-like protein (named FilP after filamentous protein) in Streptomyces coelicolor. It shares the characteristic biochemical property of eukaryotic intermediate filaments of formation of spontaneous filaments in vitro without requiring any energy or co-factor. We have provided here a preliminary model of its assembly in vitro. FilP also forms in vivo filaments in S. coelicolor hyphae, which are strongest at the sub-apical location of growing vegetative hyphae. We have proposed that FilP cytoskeletal network provides rigidity to the hyphae, especially at the growing tips, by interacting with an essential coiled coil protein DivIVA and possibly other partner elements, yet to be found. S. coelicolor is a well-studied model organism with a complicated life cycle. It germinates from a spore and spreads by forming branched vegetative hyphae. Lack of nutrients in the environment initiates formation of aerial hyphae in the air, perpendicular to the vegetative ones. The aerial hyphae differentiate into spore chains and eventually grey-pigmented dispersed individual spores are released. The signals involved in sporulation including cell division and chromosome segregation are not clear yet. We characterized here a novel locus consisting of two genes: a small putative membrane protein with no defined function, named SmeA and a member of the SpoIIIE/FtsK family, called SffA. The expression of this locus appears to be dependent on whiA and whiG-whiH-whiI pathways. This finding is intriguing as it can provide insight to the relationship between two apparently unrelated pathways, both leading to the same function of septation and maturation during sporulation. Coiled coil proteins Bacterial cytoskeleton Differentiation Cell and molecular biology Cell- och molekylärbiologi
3	La machinerie de motilité de Myxococcus xanthus : caractérisation d'une nouvelle famille de moteurs moléculaires dans l'enveloppe bactérienne / The motility machinery of Myxococcus xanthus : characterization of a new molecular motor family in the bacterial cell envelope Faure, Laura 18 January 2017 (has links) Dans les cellules il existe deux grandes sources d’énergie : l’ATP et la force proton-motrice, produites au niveau du cytoplasme et de la membrane interne respectivement. La mise en place de processus actifs dans la membrane externe ou à la surface des bactéries à Gram négatif requière la présence de machineries protéiques transmettant les forces de leur lieu de production à leur lieu d’utilisation. Durant ma thèse j’ai étudié une de ces machines : la machinerie de motilité (Agl-Glt) de Myxococcus xanthus. Plus précisément, j’ai cherché à comprendre comment les composants de cette machine s’organisent pour permettre le déplacement d’une bactérie. J’ai montré que l’assemblage de la machinerie de motilité au pôle avant des cellules nécessite la formation d’une plateforme cytosolique sur laquelle vient se fixer la machine Agl-Glt. Sous l’action du moteur, le complexe interne de la machine se déplace en direction du pôle arrière en suivant une trajectoire hélicoïdale de main droite. Au niveau de la surface les protéines de membrane externe sont recrutées au niveau d’adhésions focales et permettent l’ancrage de la machinerie au substrat. Enfin, la transmission des forces de la membrane interne à la surface par la machinerie de motilité génère le déplacement des cellules selon une trajectoire hélicoïdale de main gauche. Finalement, cette étude a révélé l’existence d’une machine protéique de l’enveloppe dont l’activité repose sur l’association d’un moteur linéaire et du cytosquelette bactérien. De par l’homologie qu’il existe entre les systèmes il est possible de proposer que ce type de machines peut-être retrouvé associées à d’autres fonctions que la motilité cellulaire. / Two energy sources are present in cells: the ATP and the Proton Motive Force, produced in the cytoplasm and inner membrane respectively. Active processes in the outer membrane or on the surface of Gram negative bacteria require the presence of a proteic machinery to transduce the forces from their production site, in the cytoplasm or inner membrane, to their usage site. During my thesis I have studied one of these machineries: the motility machinery (Agl-Glt) of Myxococcus xanthus. More precisely, I try to understand how the components of this transmembrane machinery interact with each other to promote cell motility. I have shown that the assembly of the motility machinery at the leading pole requires the formation of a cytoplasmic platform onto which the Agl-Glt machinery is going to nucleate. The inner-membrane motor complex moves intracellularly along a right-handed path in the cell and becomes stationary at focal adhesion sites on the surface through the connection of the motor to the outer membrane proteins of the complex. This powers the left-handed helical motion of the bacteria. Finally, this study reveals the existence of a dynamic transmembrane machinery which associates the bacterial cytoskeleton to a linear motor to promote cell movement. The homology between the systems tells us that this type of motor is likely to be found associate with other function than cell motility. Motilité Microscopie TIRF Machinerie protéique Moteur moléculaire Cytosquelette bactérien Motility TIRF microscopy Proteic machinery Molecular motor Bacterial cytoskeleton. 570
4	Rôle du cytosquelette d'Actine bactérien MreB dans la motilité cellulaire chez Myxococcus xanthus Mouhamar, Fabrice 02 November 2011 (has links) Myxococcus Xanthus possède un cycle developpemental multicellulaire entièrement sous la dépendance de la capacité des cellules à se déplacer sur des surfaces solides. M. xanthus possède deux systèmes de motilité génétiquement séparé, une motilité Sociale dépendant des pili de Type IV et une motilité Aventurière dont le mécanisme est encore peu compris. Notre hypothèse de travail est que la motilité Aventurière est qu’en des points régulièrement répartis le long du corps cellulaire soient couplés adhésion et traction de ce corps par une interaction entre des moteurs moléculaire et le cytosquelette d’Actine bactérienne MreB. Mon projet est de caractériser la relation qu’il pourrait y avoir entre le cytosquelette et les points d’adhésion durant la motilité. Pour étudier l’implication du cytosquelette MreB durant le mouvement, nous avons utilisé une approche pharmaceutique utilisant l’A22, une drogue permettant la dépolymérisation rapide et spécifique du cytosquelette sans affecter la viabilité des cellules à court terme. De plus j’ai aussi étudier les interactions possible entre MreB et différentes protéines de motilité comme la petite GTPase MglA, qui est connue pour est essentielle au recrutement des machineries de motilité. / Myxococcus xanthus has a multicellular developmental cycle which is dependent on the capacity of the cells to move accross solid surfaces. M. xanthus uses two motility systems: Social motility system is dependent on Type-IV pili, and the Adventurous motility system, the mechanism of which is poorly understood. Our working hypothesis is that Adventurous motility is performed by adhesion points localized along the cell body where a molecular machinery pulls the cell body by interacting with the MreB cytoskeleton. My project aims to characterize the relationship between the adhesion points and the cytoskeleton during movement. To study the involvement of MreB during motility we use A22, a drug known to rapidly and specifically depolymerise in live microscopy assays. Furthermore, I have study also the interactions between MreB and differents proteins like MglA a small GTPase, which we belive is essential for the recruitment of the machineries. A22 Complexes d'adhésion Polarité cellulaire Complexe de motilité Localisation de protéines MreB Cytosquelette bactérien A22 Adhesion complexes Cell polarity Motility clusters Protein localization Bacterial cytoskeleton
5	Untersuchungen von Cytoskelett-Komponenten und Motilität bei Mycoplasma pneumoniae / Investigations of cytoskeletal components and motility in Mycoplasma pneumoniae Hegermann, Jan 22 January 2004 (has links) No description available. 570 Biowissenschaften, Biologie Mathematics and Computer Science Bakterielles Cytoskelett Elektronenmikroskopie Immunfluoreszenz Mycoplasma Bacterial cytoskeleton elektron microscopy immuno-fluorescence mycoplasma 42.15 42.30 W

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