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Functional characterization of plant EXO70 exocyst subunit isoforms and their membrane targeting mechanisms
Sekereš, Juraj ; Potocký, Martin (advisor) ; Jaillais, Yvon (referee) ; Ischebeck, Till (referee)
Vesicle tethering complex exocyst is one of the key regulators of the cell polarity and morphogenesis in eukaryotes. The complex interacts with the secretory vesicle, as well as plasma membrane, and facilitates formation of cis SNARE complex leading into fusion of the vesicle with target destination. Two of the eight exocyst subunits, the SEC3 and EXO70 are known to bind plasma membrane via protein and lipid interactors in Opisthokont model organisms. Genomes of angiosperm plants encode a surprisingly wide repertoire of EXO70 isoforms with over 20 present in both Arabidopsis and diploid tobacco genome. It has been proposed that different EXO70 isoforms would form parts of functionally distinct subtypes of the plant exocyst complex driving membrane trafficking to various membrane domains. Specific interactions of peripheral membrane proteins with particular membrane phospholipids largely contribute to targeting of cellular components to subcellular compartments and membrane domains. This thesis focuses on role of protein-lipid interactions in regulation of plant cell polarity and contributes to functional analysis of the plant EXO70 family diversity. We introduce the topic with the theoretical reviews summarizing role of protein-lipid interactions in establishing plant cell membrane domains at...
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The role of cell polarity signaling in the plasticity of cancer cell invasiveness
Gandalovičová, Aneta ; Brábek, Jan (advisor) ; Cvrčková, Fatima (referee)
Throughout the last few years cancer research has focused on studying the origin of secondary tumors, i.e. metastases, which are a direct outcome of the ability of cancer cells to disseminate from the primary tumor and invade the adjacent tissue. Generally, cancer cells migrate by two distinct mechanisms- amoeboid or mesenchymal. Whereas the mesenchymal migration mode can be described as "path generating", the amoeboid mode resembles a "path finding" way of migration. Both types of invasion are regulated by divergent signaling pathways that are closely related to cell polarity and cytoskeleton reorganization. Responsible for cell polarization are not only the polarity complexes Par, Scribble and Crumbs, but also phosphoinositides and Rho GTPases Rac, Rho and Cdc42, which, additionally, regulate the dynamics of the cytoskeleton. By a mutual interplay they regulate cell motility. It cannot come as a surprise that their deregulation commonly results in tumorigenesis. A more thorough comprehension of the signaling pathways leading to cancer cell invasiveness is a necessary step towards understanding the complex problem of metastasis. Key words: invasiveness, amoeboid, mesenchymal, cell polarity, motility, Rho GTPases, polarity complexes
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Conventional and Novel Functions of the Exocyst Complex in Plants
Kulich, Ivan ; Žárský, Viktor (advisor) ; Baluška, František (referee) ; Hašek, Jiří (referee)
Exocyst is an octameric protein complex, conserved across all Eukaryotes. Its role, originally described in yeast, resides in a tethering of the secretory vesicles to the plasma membrane prior to the membrane fusion of the two membranes. Subunits SEC3 and EXO70 are believed to be spatial landmarks for the vesicles delivery. While yeast genome encodes single EXO70, we find dozens of them in land plants (23 in Arabidopsis). This work is focused at a role of the exocyst complex in plant cells. Its first part documents, that exocyst is essential for delivery of the cell wall components, namely pectins, but also for pathogen induced secondary cell wall thickening. Second part reveals an unconventional role of EXO70B1 subunit harboring exocyst subcomplex at an autophagic pathway to the vacuole and raises many questions about plant secretory pathway.
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Mechanisms of establishment and maintenance of PIN polarity in Arabidopsis
Glanc, Matouš ; Friml, Jiří (advisor) ; Grebe, Markus (referee) ; Luschnig, Christian (referee)
Cell polarity is a key concept in plant biology. The subcellular localization of Pin- formed (PIN) auxin efflux carriers in the root of "#$%&'()*&* is remarkably asymmetrical, making PINs prominent markers to study cell polarity. In spite of its developmental importance and two decades of research, the molecular basis of PIN polarity remains largely unknown. In this thesis, I employed advanced transgenic and fluorescence microscopy approaches to gain insight into several aspects of PIN polarity regulation. I participated in establishing a novel genetically encoded inhibitor of endocytosis, an invaluable tool for the study of the importance of endocytosis for various cellular processes, including PIN polarity. I demonstrated that apical polarity of PIN2 needs to be re-established after cell division and that this process depends on endocytosis, '+!,(-( protein secretion and the action of WAG1 and related protein kinases, but not transcytosis, cell-cell signaling or intact cytoskeleton. Finally, I identified the previously unknown role of MAB4/MEL proteins in PIN polarity, which lies in the ability of MAB4/MELs to reduce PIN lateral diffusion and thus contribute to PIN polarity maintenance. My results, besides broadening current understanding of PIN polarity regulation, identify mechanisms that...
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Mechanisms of establishment and maintenance of PIN polarity in Arabidopsis
Glanc, Matouš ; Friml, Jiří (advisor) ; Grebe, Markus (referee) ; Luschnig, Christian (referee)
Cell polarity is a key concept in plant biology. The subcellular localization of Pin- formed (PIN) auxin efflux carriers in the root of "#$%&'()*&* is remarkably asymmetrical, making PINs prominent markers to study cell polarity. In spite of its developmental importance and two decades of research, the molecular basis of PIN polarity remains largely unknown. In this thesis, I employed advanced transgenic and fluorescence microscopy approaches to gain insight into several aspects of PIN polarity regulation. I participated in establishing a novel genetically encoded inhibitor of endocytosis, an invaluable tool for the study of the importance of endocytosis for various cellular processes, including PIN polarity. I demonstrated that apical polarity of PIN2 needs to be re-established after cell division and that this process depends on endocytosis, '+!,(-( protein secretion and the action of WAG1 and related protein kinases, but not transcytosis, cell-cell signaling or intact cytoskeleton. Finally, I identified the previously unknown role of MAB4/MEL proteins in PIN polarity, which lies in the ability of MAB4/MELs to reduce PIN lateral diffusion and thus contribute to PIN polarity maintenance. My results, besides broadening current understanding of PIN polarity regulation, identify mechanisms that...
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Role of exocyst complex in growth and development of moss Physcomitrella patens
Rawat, Anamika Ashok ; Žárský, Viktor (advisor) ; Binarová, Pavla (referee) ; Fendrych, Matyáš (referee)
During the course of evolution the early land plants gained extensive innovations that can be seen in modern day plants. The polar growth is an ancient feature of eukaryotic cells and is one of preadaptations that helped plants in successful colonization of land. The polar growth in plants regulates not only the direction of cell expansion and structural properties of cell wall but especially also the orientation of cell division, and is governed by various factors, including the exocyst complex. The exocyst is a well conserved vesicle tethering multi-subunit complex involved in tethering of secretory vesicles to the target membrane. The essential role of the exocyst complex in regulation of various cellular processes in Angiosperms is now well documented. Here I present results of a doctoral project that contributed to phylogenetic analyses of the land plant exocyst complex and especially to uncovering functions of three moss exocyst subunits, namely EXO70 (isoform PpEXO70.3d), SEC6 and SEC3 (isoforms PpSEC3A and PpSEC3B) in the model organism Physcomitrella patens. Various knock-out (KO) mutants in several moss exocyst subunits (Ppexo70.3d, Ppsec6, Ppsec3a and Ppsec3b) show pleiotropic defects directly or indirectly linked to the cell polarity regulation. Cell elongation and differentiation,...
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The role of cell polarity signaling in the plasticity of cancer cell invasiveness
Gandalovičová, Aneta ; Brábek, Jan (advisor) ; Cvrčková, Fatima (referee)
Throughout the last few years cancer research has focused on studying the origin of secondary tumors, i.e. metastases, which are a direct outcome of the ability of cancer cells to disseminate from the primary tumor and invade the adjacent tissue. Generally, cancer cells migrate by two distinct mechanisms- amoeboid or mesenchymal. Whereas the mesenchymal migration mode can be described as "path generating", the amoeboid mode resembles a "path finding" way of migration. Both types of invasion are regulated by divergent signaling pathways that are closely related to cell polarity and cytoskeleton reorganization. Responsible for cell polarization are not only the polarity complexes Par, Scribble and Crumbs, but also phosphoinositides and Rho GTPases Rac, Rho and Cdc42, which, additionally, regulate the dynamics of the cytoskeleton. By a mutual interplay they regulate cell motility. It cannot come as a surprise that their deregulation commonly results in tumorigenesis. A more thorough comprehension of the signaling pathways leading to cancer cell invasiveness is a necessary step towards understanding the complex problem of metastasis. Key words: invasiveness, amoeboid, mesenchymal, cell polarity, motility, Rho GTPases, polarity complexes
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Conventional and Novel Functions of the Exocyst Complex in Plants
Kulich, Ivan ; Žárský, Viktor (advisor) ; Baluška, František (referee) ; Hašek, Jiří (referee)
Exocyst is an octameric protein complex, conserved across all Eukaryotes. Its role, originally described in yeast, resides in a tethering of the secretory vesicles to the plasma membrane prior to the membrane fusion of the two membranes. Subunits SEC3 and EXO70 are believed to be spatial landmarks for the vesicles delivery. While yeast genome encodes single EXO70, we find dozens of them in land plants (23 in Arabidopsis). This work is focused at a role of the exocyst complex in plant cells. Its first part documents, that exocyst is essential for delivery of the cell wall components, namely pectins, but also for pathogen induced secondary cell wall thickening. Second part reveals an unconventional role of EXO70B1 subunit harboring exocyst subcomplex at an autophagic pathway to the vacuole and raises many questions about plant secretory pathway.
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