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

Studium interakce proteinů zapojených do exocytózy v obraně před patogenem / Study of the interaction of proteins involved in the exocytosis in the plant defense against pathogens

Ortmannová, Jitka

January 2013

Plant cells are mostly immobile, therefore it is crucial for them to distinguish a direction of the signals coming into the cell and on the other hand they have to precisely target their own signals. To achieve this communication, plant cells use endomembrane system and secretory vesicles, which are recruited to the specific membrane domains. This ability is important for the plant defense against pathogenic microorganisms and it even forms a part of the innate plant immunity. Two complexes, the exocyst and SNARE, play a prominent role in the process of polarized secretion. In this work, we focused on a possible interaction between these two complexes in preinvasive defense and particularly, we studied the exocyst subunit EXO70B2 and SNARE protein SYP121. We obtained double mutant plants of EXO70B2 and SYP121 by utilizing the reverse genetics approach. These mutant plants did not show any obvious phenotype under standard conditions in comparison with Wt plants. However, we observed marked defects of secretory pathway in double mutant exo70B2/syp121 after infection by pathogenic fungi Blumeria graminis f. sp. hordei. Using histochemical staining, we described problems with the deposition of defensive papilla and secretion of haustorial encasement. We prove that these defects are not connected with...

Role podjednotky exocystu AtEXO70E2 v autofagii a sekreci / The role of exocyst subunit AtEXO70E2 in autophagy and secretion

Moulík, Michal

January 2021

Exocyst is a protein complex composed of eight subunits, evolutionarily conserved in yeasts, animals, and plants. The main function of exocyst is to mediate the tethering of secretory vesicles to the plasma membrane. However, the involvement of exocyst in some other processes, especially in autophagy, has been recently discovered. Plant exocyst is specific because most of its subunits have multiple paralogs. The most diversified subunit is EXO70, which is encoded by 23 paralogous genes in Arabidopsis thaliana. In this thesis, I dealt with subunit AtEXO70E2 (AT5G61010), which has been localized to double-membrane compartments considerably reminiscent of autophagosomes. These compartments were named EXPOs (for exocyst-positive organelles) and described as a component of unconventional protein secretion pathways. There are also hints that EXO70E2 could play a role in autophagic processes. However, details of this relationship remained unexplored. For my experiments, I used stably transformed lines of A. thaliana and transiently transformed leaves of Nicotiana benthamiana. I performed numerous colocalization experiments, applied various pharmacological treatments to the studied lines, and analyzed a mutant line in the EXO70E2 gene. According to my observations, protein EXO70E2 is expressed especially...

Hexagonal packing of Drosophila wing epithelial cells by the Planar Cell Polarity pathway

Classen, Anne-Kathrin

31 August 2006

The mechanisms that order cellular packing geometry are critical for the functioning of many tissues, but are poorly understood. Here we investigate this problem in the developing wing of Drosophila. The surface of the wing is decorated by hexagonally packed hairs that are uniformly oriented towards the distal wing tip. They are constructed by a hexagonal array of wing epithelial cells. We find that wing epithelial cells are irregularly arranged throughout most of development but become hexagonally packed shortly before hair formation. During the process, individual cell junctions grow and shrink, resulting in local neighbor exchanges. These dynamic changes mediate hexagonal packing and require the efficient delivery of E-cadherin to remodeling junctions; a process that depends on both the large GTPase Dynamin and the function of Rab11 recycling endosomes. We suggest that E-cadherin is actively internalized and recycled as wing epithelial cells pack into a regular hexagonal array. Hexagonal packing furthermore depends on the activity of the Planar Cell Polarity proteins. The Planar Cell Polarity group of proteins coordinates complex and polarized cell behavior in many contexts. No common cell biological mechanism has yet been identified to explain their functions in different tissues. A genetic interaction between Dynamin and the Planar Cell Polarity mutants suggests that the planar cell polarity proteins may modulate Dynamin-dependent trafficking of E-cadherin to enable the dynamic remodeling of junctions. We furthermore show that the Planar Cell Polarity protein Flamingo can recruit the exocyst component Sec5. Sec5 vesicles also co-localizes with E-cadherin and Flamingo. Based on these observations we propose that during the hexagonal repacking of the wing epithelium these proteins polarize the trafficking of E-cadherin-containing exocyst vesicles to remodeling junctions. The work presented in this thesis shows that one of the basic cellular functions of planar cell polarity signaling may be the regulation of dynamic cell adhesion. In doing so, the planar cell polarity pathway mediates the acquisition of a regular packing geometry of Drosophila wing epithelial cells. We identify polarized exocyst-dependent membrane traffic as the first basic cellular mechanism that can explain the role of PCP proteins in different developmental systems.

Planar cell polarity

junctional remodeling

E-cadherin

hexagonal

epithelial packing

Drosophila

exocyst

Sec5

Flamingo

recycling

Dynamin

Rab11

wing hairs

Planare Polarität

hexagonal

E-cadherin

Drosophila

Exocyst

Sec5

Flamingo

Recycling

Dynamin

Rab11

Flügelhaare

ddc:570

rvk:WG 5900

Drosophila

Polarität

Recycling

Dynamin

Flügel<Zoologie>

Cadherine

Exocytose

Ephitelzelle

Hexagonal packing of Drosophila wing epithelial cells by the Planar Cell Polarity pathway

Classen, Anne-Kathrin

25 July 2006

The mechanisms that order cellular packing geometry are critical for the functioning of many tissues, but are poorly understood. Here we investigate this problem in the developing wing of Drosophila. The surface of the wing is decorated by hexagonally packed hairs that are uniformly oriented towards the distal wing tip. They are constructed by a hexagonal array of wing epithelial cells. We find that wing epithelial cells are irregularly arranged throughout most of development but become hexagonally packed shortly before hair formation. During the process, individual cell junctions grow and shrink, resulting in local neighbor exchanges. These dynamic changes mediate hexagonal packing and require the efficient delivery of E-cadherin to remodeling junctions; a process that depends on both the large GTPase Dynamin and the function of Rab11 recycling endosomes. We suggest that E-cadherin is actively internalized and recycled as wing epithelial cells pack into a regular hexagonal array. Hexagonal packing furthermore depends on the activity of the Planar Cell Polarity proteins. The Planar Cell Polarity group of proteins coordinates complex and polarized cell behavior in many contexts. No common cell biological mechanism has yet been identified to explain their functions in different tissues. A genetic interaction between Dynamin and the Planar Cell Polarity mutants suggests that the planar cell polarity proteins may modulate Dynamin-dependent trafficking of E-cadherin to enable the dynamic remodeling of junctions. We furthermore show that the Planar Cell Polarity protein Flamingo can recruit the exocyst component Sec5. Sec5 vesicles also co-localizes with E-cadherin and Flamingo. Based on these observations we propose that during the hexagonal repacking of the wing epithelium these proteins polarize the trafficking of E-cadherin-containing exocyst vesicles to remodeling junctions. The work presented in this thesis shows that one of the basic cellular functions of planar cell polarity signaling may be the regulation of dynamic cell adhesion. In doing so, the planar cell polarity pathway mediates the acquisition of a regular packing geometry of Drosophila wing epithelial cells. We identify polarized exocyst-dependent membrane traffic as the first basic cellular mechanism that can explain the role of PCP proteins in different developmental systems.

info:eu-repo/classification/ddc/570

ddc:570