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Biocrystallization as a new concept in development of piezoelectronics for use in biomaterials
Dobešová, Kateřina ; Plichta, Tomáš (referee) ; Sedláček, Petr (advisor)
This thesis focuses on biofilament methods and biocrystallization of bacterial cells producing polyhydroxyalkanoates, specifically the bacterium Cupriavidus necator H16. The main techniques used for cell orientation include spin-coating and acoustic waves. Biocrystallization was induced by temperature, osmotic, and acid stress. The degree of cell orientation was monitored by an atomic force microscope, and crystallization was determined by FTIR. Among other parameters, the thickness of the layers was evaluated using a profilometer. The amount of PHA in the bacterial cells was determined by gas chromatography. The preparation of crystalline ordered layers of biomaterials represents a route to piezoelectric biomaterials.
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Cell inclusions in microscopic eukaryotes
Pilátová, Jana
This thesis reports, for the first time, a systematic study identifying various cell inclusions across the broad diversity of all major eukaryotic supergroups. Raman microspectroscopy technique was employed as a powerful technique, which is becoming the method of the first choice for such studies. In Chapter 1, the spatial reconstruction of chloroplasts of the unicellular zygnematophyte Cylindrocystis sp. (Streptophyta) revealed "empty spaces" inside. Subsequent analysis showed massive accumulations of polyphosphate, which is not located in the cytoplasm as in other species, but inside the chloroplasts. This newly discovered ability of the zygnematophytes, a sister group of terrestrial plants, to accumulate polyphosphate leads us to speculate about a possible adaptation to extreme Arctic conditions or even a preadaptation leading to plant terrestrialization. Chapter 2 summarizes the serendipitous discovery of purine crystalline inclusions in dinoflagellates and other microalgae. Investigated dinoflagellate species comprised zooxanthellae, the endosymbionts of reef-building corals, and the species causing toxic algal blooms. Purine crystals were further shown to act as dynamic high-capacity nitrogen storage. To show how widespread purine inclusions are, a revision of crystalline inclusions in all...
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Cell inclusions in microscopic eukaryotes
Pilátová, Jana ; Schwarzerová, Kateřina (advisor) ; Gierlinger, Notburga (referee) ; Prášil, Ondřej (referee)
This thesis reports, for the first time, a systematic study identifying various cell inclusions across the broad diversity of all major eukaryotic supergroups. Raman microspectroscopy technique was employed as a powerful technique, which is becoming the method of the first choice for such studies. In Chapter 1, the spatial reconstruction of chloroplasts of the unicellular zygnematophyte Cylindrocystis sp. (Streptophyta) revealed "empty spaces" inside. Subsequent analysis showed massive accumulations of polyphosphate, which is not located in the cytoplasm as in other species, but inside the chloroplasts. This newly discovered ability of the zygnematophytes, a sister group of terrestrial plants, to accumulate polyphosphate leads us to speculate about a possible adaptation to extreme Arctic conditions or even a preadaptation leading to plant terrestrialization. Chapter 2 summarizes the serendipitous discovery of purine crystalline inclusions in dinoflagellates and other microalgae. Investigated dinoflagellate species comprised zooxanthellae, the endosymbionts of reef-building corals, and the species causing toxic algal blooms. Purine crystals were further shown to act as dynamic high-capacity nitrogen storage. To show how widespread purine inclusions are, a revision of crystalline inclusions in all...
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