Studium funkce genů EXO70H7 a EXO70H8 ve vývoji Arabidopsis thaliana. / Function study of EXO70H7 and EXO70H8 genes in Arabidopsis thaliana development.

Modráčková, Jana

January 2020

Complex Exocyst consists of eight proteins and it is known as a Sec6/8. Its composition is evolutionarily highly conserved amongst all the species. This complex is involved in vesicle trafficking as a part of attaching mechanism to a specific place on the plasma membrane. EXO70 subunit has been found in 23 copies in Arabidopsis thaliana genome. In this study we have been examine paraloges EXO70H7 and EXO70H8. There have been suggestions that these genes are important in development of roots according to the previous studies. We have not been able to identify any significant phenotype within the mutant plants in these genes. There has been studied other mutant appearance during the stress experiments. Most of these experiments did not identify any divergence. Only experiments with germination during stress conditions revealed significantly worse germination of exo70H7 mutant seeds on the medium containing sorbitol. This suggests that mutant seeds have a worse protection against osmotic stress. Significantly worse germination of exo70H8 seeds on the medium with excess NaCl indicates that these seeds incriminate to higher absorption of sodium ions. Analysis of the cell localization of GFP constructs brought knowledge of appearance EXO70H7 and EXO70H8 proteins. EXO70H7 locates in the cytoplasm and in...

Exploring Cellular Dynamics : From Vesicle Tethering to Cell Migration

Ashrafzadeh, Parham

January 2016

Cells in the body communicate with each other in order to cooperate efficiently. This communication is in part achieved by regulated secretion of signaling molecules, which when released from a cell may activate receptors present at the plasma membrane of an adjacent cell. Such signals affect both cell fate and behavior. Dysregulated signaling may lead to disease, including cancer. This thesis is focused on how exocytosis and subsequent activation and trafficking of receptors can be regulated, and what the consequences of this regulation may be for cell migration. Actin filaments are important transport structures for secretory vesicle trafficking. In Paper 1, actin polymerization was shown to induce formation of ordered lipid domains in the plasma membrane. Accordingly, actin filaments may thus create and stabilize specific membrane domains that enable docking of vesicles containing secretory cargo. The RhoGEF FGD5 regulates Cdc42 which can result in cytoskeletal rearrangements. In Paper II, FGD5 was shown to be selectively expressed in blood vessels and required for normal VEGFR2 signaling. FGD5 protected VEGFR2 from proteasome-mediated degradation and was essential for endothelial cells to efficiently respond to chemotactic gradients of VEGFA. The exocyst component EXOC7 is essential for tethering secretory vesicles to the plasma membrane prior to SNARE-mediated fusion. In Paper III, EXOC7 was required for trafficking of VEGFR2-containing vesicles to the inner plasma membrane and VEGFR2 presentation at the cell surface. The ability of tumor cells to escape the primary tumor and establish metastasis is in part dependent on their capacity to migrate. In Paper IV, a method based on time-lapse microscopy and fluorescent dyes was created to analyze single cancer cell migration in mixed cancer cell cultures, and in particular the influence of different types on neighboring cells was assessed. In conclusion, these studies have enhanced our understanding of the mechanisms behind cellular trafficking, and may be applied in the future to develop more specific therapeutics to treat cancer and other diseases associated with abnormal angiogenesis and cellular migration.

angiogenesis

cancer

cell migration

exocyst complex

exocytosis

FGD5

lipid rafts

plasma membrane

receptor trafficking

VEGFR2

Studium vybraných podjednotek komplexu exocyst u rostlin a jejích interaktorů v autofagické dráze / Study of selected plant exocyst subunits and its interactors in autophagy pathway.

Rácová, Denisa

January 2015

Exocyst is a binding protein complex, which is evolutionary conserved in yeast, animal and in plant cells. It has crucial role in regulation of cell morfogenesis and cell polarity. The function of the exocyst complex is binding of secretoric vesicle to the proper side on plasma membrane in penultimate step of exocytosis. This process is essecial for function and survival of cell. Another process crucial for the cell is autophagy. In plants autophagy plays important role in the responses to nutrient starvation, senescence, abiotic and biotic stress. RabG3b are small GTPases, which have positive role in autophagy. In this work I described the interaction between RabG3b and some of subunits of exocyst complex: Exo70B1, Exo70B2 and Exo84b. I also studied changes in morfogenesis of tonoplast by induction and inhibition of authophagy and induction of anthocyans synthesis in Arabidopsis thaliana.

An Investigation of the Exocyst Complex and its role in Compatible Pollen-pistil Interactions in Arabidopsis

Haasen, Katrina Ellen

06 April 2010

Compatible interactions between male gametophytes (pollen) and the female reproductive organ (pistil) are essential for fertilization in flowering plants. Recognition at a molecular level allows “compatible” pollen grains to adhere/germinate on the stigma while pollen grains from unrelated plant species are largely ignored. The exocyst is a large eight subunit complex that is primarily involved in polarized secretion or regulated exocytosis in eukaryotic cells where it functions to tether vesicles to the plasma membrane. Recent research has implicated one of the Exo70 family members, Exo70A1, in compatible pollen-pistil interactions in Arabidopsis and Brassica. The loss of Exo70A1 in Arabidopsis Col-0 stigmas leads to the rejection of compatible pollen producing a “female sterile” phenotype. Through my research I have demonstrated that, driven by a stigma-specific promoter, an RFP:Exo70A1 fusion protein rescues this defect in exo70A1-1 mutant and Exo70A1 is found to be localized to the plasma membrane at flower opening.

Exocyst Complex

Arabidopsis

Molecular signaling

Plant Reproduction

Pollen-Pistil Interactions

Compatibility

Self-Incompatibility

Exo70A1

Vesicle Trafficking

Docking Complexes

Brassica

Stigma

Papillae Cells

0307

0309

An Investigation of the Exocyst Complex and its role in Compatible Pollen-pistil Interactions in Arabidopsis

Haasen, Katrina Ellen

06 April 2010

Compatible interactions between male gametophytes (pollen) and the female reproductive organ (pistil) are essential for fertilization in flowering plants. Recognition at a molecular level allows “compatible” pollen grains to adhere/germinate on the stigma while pollen grains from unrelated plant species are largely ignored. The exocyst is a large eight subunit complex that is primarily involved in polarized secretion or regulated exocytosis in eukaryotic cells where it functions to tether vesicles to the plasma membrane. Recent research has implicated one of the Exo70 family members, Exo70A1, in compatible pollen-pistil interactions in Arabidopsis and Brassica. The loss of Exo70A1 in Arabidopsis Col-0 stigmas leads to the rejection of compatible pollen producing a “female sterile” phenotype. Through my research I have demonstrated that, driven by a stigma-specific promoter, an RFP:Exo70A1 fusion protein rescues this defect in exo70A1-1 mutant and Exo70A1 is found to be localized to the plasma membrane at flower opening.

Exocyst Complex

Arabidopsis

Molecular signaling

Plant Reproduction

Pollen-Pistil Interactions

Compatibility

Self-Incompatibility

Exo70A1

Vesicle Trafficking

Docking Complexes

Brassica

Stigma

Papillae Cells

0307

0309

Specifita vybraných podjednotek exocystu při vývoji trichomu / Specificity of selected exocyst subunits in trichome development

Glanc, Matouš

January 2014

Trichomes are fine epidermal outgrowths covering aerial organs of most land plants. Although unicellular trichomes of Arabidopsis thaliana have long been used as a model system in plant cell and developmental biology, surprisingly little is known about the processes involved in cell wall biogenesis during the last stage of trichome maturation. A role of EXO70H4, a putative subunit of the vesicle tethering complex exocyst, in trichome maturation has recently been identified in our laboratory. Image analysis, histochemical detection and FT-IR spectroscopy methods were used in this study to analyze cell wall defects of the exo70H4 LOF mutant, revealing the mutation causes altered deposition of pectins and possibly also lignins and hemicelluloses. Transgenic lines with EXO70 paralogues driven by the EXO70H4 promoter were prepared and their analysis revealed that the closest paralogue EXO70H3, unlike EXO70A1 and EXO70B1, can complement the exo70H4 mutation. Based on the results, questions concerning trichome cell wall composition, the role of EXO70H4 in trichome maturation and functions of the plant exocyst complex are discussed. Keywords: Arabidopsis, trichome, cell wall, secretory pathway, exocyst complex, EXO70H4, FT-IR spectroscopy