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Plant cuticle
Voloshina, Mariia ; Schwarzerová, Kateřina (advisor) ; Synek, Lukáš (referee)
The cuticle is a lipidic structure covering plant aerial organs, providing mechanical rigidity and acting as a protective barrier. It contains the cutin polyester and waxes, which are derived from very-long-chain fatty acids. These compounds are synthesised in two separate pathways. The cuticular biosynthetic machinery is incredibly complex and employs a multitude of enzymes, some of which are functionally redundant, are present in different tissues or catalyse reactions with substrates of various chain lengths. The mechanisms of how these compounds are transported and how the cuticle is assembled rely on ABC transporters, LTP lipid carrier proteins, cutin synthases, and cutinsomes. Knowledge of these highly dynamic processes is very fragmented and the integrated model of cutin synthesis is yet to be elucidated. A tight connection between the cuticle and the cell wall, conventionally seen as two separate entities, has also been implied. The complexity of these mechanisms is also reflected in their transcriptional and post-transcriptional regulation. While SHINE and MIXTA-like transcriptional factors and the WW-domain protein CFL1 regulate the cuticle's synthesis throughout a plant's development, ABA-dependent MYB transcriptional factors are important during abiotic stress. Recent research also...
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Functions of the exocyst complex in secretion and cell wall biogenesis
Vukašinović, Nemanja ; Synek, Lukáš (advisor) ; Růžička, Kamil (referee) ; Kost, Benedikt (referee)
The mechanical strength of plant tissues and organs can be attributed to specific properties of the cell wall. In many cases, in order to establish their final shape, cells deposit various cell wall materials in a localized manner. This is achieved by highly organized action of the endomembrane system which is essential for biosynthesis and secretion of cell wall proteins and polysaccharides. The exocyst complex is a conserved tethering complex in eukaryotes and it is involved in tethering of secretory vesicles to the sites of secretion at the plasma membrane. In this study, we address several aspects of the plant exocyst complex architecture and cell wall development using molecular biology techniques and advanced confocal microscopy. We demonstrated that two SEC10 exocyst subunits are present in Arabidopsis thaliana and share redundant functions. We also showed that the architecture of the plant exocyst complex shares several structural features with the yeast one. We demonstrated the importance of the functional EXO84b exocyst subunit for normal tracheary element development and showed that the main constituents of the secondary cell walls are deposited normally in exocyst mutants. We described a clear difference in the exocyst microtubule-independent dynamics in epidermal cells vs. cell type...
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