|
|
Role of cytoskeleton in plant cell morphogenesis
Miklánková, Pavlína ; Schwarzerová, Kateřina (advisor) ; Sekereš, Juraj (referee)
The cells are able to acquire variety of shapes, in which cytoskeleton plays an important role. Cytoskeleton influences deposition of cell wall materials, regulates vesicle movement in cell, participates in exocytosis and endocytosis. Cortical microtubules affect celulose accumulation in cell wall and determine direction of cell expansion, although the exact connection between microtubules and cellulose remains unclear. Actin promotes growth and contributes to its spatial regulation in both tip ang diffuse growing cells. Actin is important for secretion in expanding cells but its exact functions in cell growth regulation are not explained yet. Analysis of mutants, spectroscopic methods, cytoskeletal drugs, fluorescence proteins and other methods are used to better understand how actin and microtubule cytoskeleton are integrated during plant cell morphogenesis. Epidermal and trichome cells of Arabidopsis thaliana are a good model of research and they are used for most studies.
|
|
|
Characterization of the PTEN domain of selected Arabidopsis class II formins
Přerostová, Sylva ; Cvrčková, Fatima (advisor) ; Havelková, Lenka (referee)
Formins are proteins facilitating formation of actin filaments. They affect structure of cytoskeleton and participate in cytokinesis and tip growth. There are 2 classes of formins in Arabidopsis thaliana, which include FH1 and FH2 (Formin Homology 1 and 2) domain. Formins of the class I have usually a transmembrane domain on N-terminus. Due to this fact they can interact with membranes. Some formins from the class II include PTEN domain (Phosphatase and Tensin Homolog) derived from sequences of PTEN proteins which has lost the function of phosphatase. It is assumed this domain can bind on a membrane via the phosphatase section or C2 domain. This thesis was focused on the formin AtFH13 from the class II in Arabidopsis thaliana and on its PTEN domain. There were analyzed differences between mutants and wild-types in length of roots in seedlings and in size of seeds and seed coats, and observed the effect of dexamethasone on the length of roots on AtFH13. PTEN domain of the formin was isolated from cDNA, cloned to a vector and fused with YFP. The tagged protein was visualized by the method of transient expression in epidermal cells in the leaves of Nicotiana benthamiana. No big differences were observed between plants mutant in the gene AtFH13 and wild-type in choice parameters. Dexamethasone did't influence...
|
|
|
Microtubule-associated proteins in plants
Benáková, Martina ; Krtková, Jana (advisor) ; Vinopal, Stanislav (referee)
1. Abstract and key words MTs are one of the basic cellular protein structure. Their features and function are influenced and modified by group of other proteins, i.e. microtubule-associated proteins (MAPs). In the last decades, an extensive research on MAPs and their wide range of functions has been carried out. Therefore we are aware of the involvement of some of the MAPs in MT dynamics, other have been shown to have rather structural function. They bundle MTs with various cell structures, such as the other MTs, proteins, organelles, actin cytoskeleton or plasma membrane. Many described MAPs are homologous in the whole eukaryotic domain, for example MAP65 or EB1 (END BINDING 1) family, therefore it is interesting to follow if and how the functions of plant MAPs differ from their animal counterparts. On the other hand, there are many specific MAPs with unique functions in plants, e.g. ATK5 or SPR1 (SPIRAL 1). This Bachelor thesis is a survey on current knowledge of plant MAPs and it makes an effort to present their characteristic and functions in plant cell and organism. Key words: cytoskeleton, microtubules, microtubule-associated proteins, plant cell, growth and development
|
|
|
The effect of the mast cell activation on the microtubule organisation
Hájková, Zuzana ; Dráber, Pavel (advisor) ; Binarová, Pavla (referee)
The activation of bone marrow-derived mast cells (BMMCs) induces a number of cell processes such as degranulation, proliferation and cytoskeleton rearrangements. Although microtubules are important in these processes, molecular mechanisms that control changes in microtubule organisation during cell activation are unknown. Activation of BMMCs can be achieved in several ways. Under physiological conditions, the aggregation of IgE receptors (FcRI) on the surface of BMMCs leads to the initiation of specific signaling pathways. Cells can be also activated nonspecifically by a tyrosine phosphatase inhibitor pervanadate, or by thapsigargin that inhibits Ca2+ ATPase pumps located on the endoplasmic reticulum. In this diploma thesis it was found out that rapid morphological changes can be monitored when BMMC are immobilised on the fibronectin before their activation. It was proved that specific and nonspecific activation events lead to microtubule reorganization, as well as to generation of a large number of microtubule-dependent protrusions. In the course of FcRI aggregation, generation of microtubule protrusions depends on the activity of Src family protein tyrosine kinases and on the intracellular Ca2+ concentration. STIM1, an endoplasmic reticulum Ca2+ sensor, which participates in the activation of...
|
|
|
Electric field generated by higher vibration modes of microtubule
Cifra, Michal ; Havelka, D. ; Kučera, Ondřej ; Pokorný, Jiří
Certain structures in a living cell may generate electric oscillations. Microtubules, which form a part of a cellular skeleton, belong to this class of structures and ful-fill all conditions for generation of electric oscillations in kHz÷GHz band. We present selected results from calculations of the oscillatory electric field generated by higher vibration modes of microtubules. We propose that the electric field of certain modes may play specific function in cellular organization
|
|
| |
|
|
Calculation of the Electromagnetic Field Around Microtubule
Havelka, D. ; Cifra, Michal
Microtubules are important structures in cytoskeleton which organizes the cell. Single microtubule is composed of electrically polar structures, tubulin heterodimers, which have strong electric dipole moment. Vibrations are expected to be generated in microtubules, thus tubulin heterodimers as electric dipoles are oscillating. This gives rise to electromagnetic field, which is detected around the cells. We calculate here the electromagnetic field of microtubules if they are excited at 1 GHz. This paper includes the work done in bachelor thesis of the first author.
|
|
| |
|
| |
|
| |
guest ::
