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The role of atmospheric precipitation in anther dehiscence
Kampová, Anna ; Vosolsobě, Stanislav (advisor) ; Valuchová, Soňa (referee)
Anther dehiscence is an important process taking place at the end of the plant life cycle. This process consists of various follow-up steps which result in anther opening and pollen grains exposure. Good timing of the anther dehiscence must be synchronized with pollen grains maturation and flower opening. Atmospheric precipitation is a high-risk factor for the anther dehiscence. Male fitness of plants can be reduced when anthers open during poor weather conditions. The aim of this study was to investigate the effect of atmospheric precipitation, rain and dew, on Arabidopsis arenosa anther dehiscence. We observed that rain and dew led to a postponed final stage of the anther dehiscence. This caused delayed pollen release. The effect of aqueous and nonaqueous environment on the anther dehiscence was also tested. Experiments with transformation of A. arenosa using Agrobacterium tumefaciens were performed. Key words: anther dehiscence, flower opening, rain, dew, Arabidopsis arenosa, Agrobacterium tumefaciens, transformation
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Mechanoreception in plants
Martinek, Jan ; Vosolsobě, Stanislav (advisor) ; Kulich, Ivan (referee)
Because of their sessile nature, plants are unable to change their location and thus they are forced to adapt as much as possible to the environment they grow in. Plants evolved the ability to sense many environmental cues, which enables them to perceive the conditions in their surroundings. One class of these stimuli are mechanical forces - from wind sways to contact with obstacles, herbivores or other plants - other mechanical stimuli are e.g. gravity or sound waves. Carnivorous or climbing plants have structures specialised for perception and rapid response to mechanical stimuli. Intriguingly, there is a less spectacular but maybe even more interesting and important response to mechanical perturbation in non-specialized plants. This thesis tries to summarize ubiquity of mechanoperception in plant kingdom and its adaptive importance for the plant life - from activation of traps, to morphological adaptation for growth at windy sites, tendril coiling in climbing plants and root navigation through obstacles in soil. In the following part, the thesis summarizes the recent knowledge of molecular processes accompanied with mechanoreception, signal transduction and integration, and response to mechanostimulation. In the last part I proppose a scheme of mechanosensing workflow from initial mechanical...
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The effect of desiccation on streptophyte algae - mechanisms of stress resistance
Pošmourný, Martin ; Pichrtová, Martina (advisor) ; Vosolsobě, Stanislav (referee)
In this thesis I dealt streptophyta algae resistance against desiccation. Even though the area previously devoted only a few people. Considerable amount of work in recent years has been published on the subject. They were found interesting information and discovered new facts. Research continues on and on, and it would be useful to look at what was observed. I believe that understanding this phenomenon is the key to understanding some of the events in the evolution of nature and realizing how tough life can be on the very border of its possible occurrence. I tried to sort out the current knowledge about the mechanisms of stress resistance streptophyta algae and hope that I obtained an overview will help me understand better this issues. So far, it has been observed several approaches to defend against drying. Preventing drying, adaptation to water shortage and tolerance to desiccation. Among the preventive methods of defense include creating clusters of cells, multi-layered mats or secretion mucilage. As an adaptation to the lack of water algae evolved more complex answers in the form of changes in ultrastructure, or regulation of physiological processes. Klebsormidium is capable of half an hour to start the production of significant quantities callose and incorporate it into the cell wall. This...
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Mechanisms that control physiological seed dormancy
Řezková, Natálie ; Ponert, Jan (advisor) ; Vosolsobě, Stanislav (referee)
Physiological dormancy is an important developmental trait ensuring that seed does not germinate when the environmental factors are appropriate only temporary. The transition from seed dormancy to germination is regulated by a large number of factors and the phytohormone abscisic acid (ABA) plays a crucial role. Enhanced response to ABA and its biosynthesis is a key mechanism in dormancy induction and maintenance. ABA interacts antagonistically with gibberellins (GAs). Therefore GA biosynthesis and ABA catabolism are positive germination regulators. However, other phytohormones are also involved in the regulation of dormancy and germination. The most studied is ethylene which supports germination similarly to GA. Numerous factors affect dormancy at molecular level, namely chromatin remodeling, gene products that function only in dormancy regulation [e.g. DELAY OF GERMINATION 1 (DOG1)] or gene products that mediate seed response to environmental factors. The dormancy, its induction, depth and release, is driven not only by environmental conditions affecting mature seeds, but also by conditions acting during seed maturation in a maternal plant when the primary dormancy is induced. Requirements for dormancy release and germination induction may vary considerably between species. The physiological...
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Dynamics of ALBA proteins in Arabidopsis thaliana evaluated by fluorescence microscopy
Popelářová, Anna ; Honys, David (advisor) ; Vosolsobě, Stanislav (referee)
ALBA proteins were discovered in Archaea more than 30 years ago. They were gradually identified to be well conserved in Eucaryotes as well. A functional dimeric form of these proteins with DNA and RNA-binding capability was claimed in both mentioned domains of organisms. However, their roles diversified during evolution and vary in between organisms. In Archaea, ALBAs are involved in the genome organization and RNA-protein interactions. In Eukaryotes, there are presented two different subfamilies of ALBA proteins - Rpp20 and Rpp25 subfamily. A sole protein from each subfamily was identified in some organisms though they were multiplied in plants, respectively. These proteins can interact with each other and participate in ontogenetic development and stress responses. According to several studies, ALBA proteins were found to be involved in DNA stability maintenance or pre-rRNA splicing in the nucleus of Arabidopsis thaliana. However, they have been shown to play a role in the cellular metabolism and stress responses in cytoplasm. Six ALBA proteins were identified in the genome of A. thaliana, three from each subfamily. In this study, all heterodimeric protein- protein interactions were investigated by the bimolecular fluorescence complementation (BiFC) assay which revealed positive results in...
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Connection between Unfolded Protein Response (UPR) and plant immunity
Kapr, Jan ; Burketová, Lenka (advisor) ; Vosolsobě, Stanislav (referee)
This bachelor thesis is concerned with the specific pathway in a response to endoplasmic reticulum stress in plant cells - the Unfolded Protein Response (UPR) and its role in plant immunity signalling. The work summarizes the main recent knowledges of molecular components of plant immunity and response to plant pathogens, focusing on important molecules that are also connected to UPR. The role of salicylic acid as a molecule on a crossroad between UPR signalling pathways and local and systemic resistence, is highlighted in this work. Recently, the phospholipids have also been shown to be important component of signaling pathways in response to biotic stress in plants and their role is also mentioned.
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The mechanisms of pollen incompatibility in the Brassicaceae family
Šesták, Petr ; Fíla, Jan (advisor) ; Vosolsobě, Stanislav (referee)
Sporophytic incompatibility (SI) represents one of the systems by which angiosperms prevent pollination by their own pollen or by the pollen from a genetically related plant. It is mostly studied in the Brassicaceae family, mainly due to its agricultural importance. Another reason is that the model plant Arabidopsis thaliana belongs to this family. In the last three decades, advances in molecular biological methods enabled the characterization of a large part of the signalling cascade that leads to the rejection of incompatible pollen. Then, the functions of various cellular components (e.g. cytoskeleton, exocyst or proteasome) involved in the incompatible response to pollination are studied mainly by live cell microscopy. Last but not least, the function of SI under various abiotic stresses was described to reveal their influence on SI mechanisms. The aim of this bachelor thesis is to summarize the new discoveries characterizing the molecular mechanisms of SI in the Brassicaceae family, to describe the processes leading to the germination of compatible pollen grain and to characterize the newly described proteins involved in cellular signalling leading to the rejection of incompatible pollen.
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The role of atmospheric precipitation in anther dehiscence
Kampová, Anna ; Vosolsobě, Stanislav (advisor) ; Valuchová, Soňa (referee)
Anther dehiscence is an important process taking place at the end of the plant life cycle. This process consists of various follow-up steps which result in anther opening and pollen grains exposure. Good timing of the anther dehiscence must be synchronized with pollen grains maturation and flower opening. Atmospheric precipitation is a high-risk factor for the anther dehiscence. Male fitness of plants can be reduced when anthers open during poor weather conditions. The aim of this study was to investigate the effect of atmospheric precipitation, rain and dew, on Arabidopsis arenosa anther dehiscence. We observed that rain and dew led to a postponed final stage of the anther dehiscence. This caused delayed pollen release. The effect of aqueous and nonaqueous environment on the anther dehiscence was also tested. Experiments with transformation of A. arenosa using Agrobacterium tumefaciens were performed. Key words: anther dehiscence, flower opening, rain, dew, Arabidopsis arenosa, Agrobacterium tumefaciens, transformation
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Evolution of physiological adaptations of plants during dry land colonization.
Červenka, Ondřej ; Žárský, Viktor (advisor) ; Vosolsobě, Stanislav (referee)
Terrestrialization, the transition of plants from water to land and the subsequent colonization of these new habitats, took place approximately 480 million years ago. This event caused significant changes in the planet's surface and enabled the formation of modern terrestrial ecosystems. It is associated with a number of morphological, anatomical and physiological adaptations, without which terrestrial plants would not be able to control newly inhabited habitats. The aim of this thesis is to summarize current knowledge about the possible ancestor of land plants, based on fossil remains and phylogenetic studies. The chapter dealing with macrofossils highlights the importance of the Scottish locality near the village of Rhynie and the description of the oldest vascular land plant Cooksonia barrandei. Attention is also paid to the alternation of generations within the life cycle, including a brief excursion into the history of the study and a description of the metagenesi sof rhyniophytes. Molecular aspects of this issue are also described, especially the emphasis on the role of biopolymers and phytohormones.
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