The Exocyst Complex in Regulation of Cell Morfogenesis and Pathogen Defence
Cell morphogenesis and related regulatory processes in plant cells are the dominant field of interest in our laboratory. Plant morphogenesis results from two processes - oriented cell division and differential cell growth. We focus on intracellular molecular mechanisms driving cellular morphogenesis such as exocystosis. Proteins participating in these mechanisms are, despite of the major differences in cell structure and behaviour, often very similar to those found in the fungal and animal kingdoms (Žárský and Cvrčková, 1997; Cvrčková et al., 2001).
One of elements regulating exocytosis is the exocyst, an ancient protein complex generally found in eukaryots. The exocyst serves as an effector of RAB and RHO GTPases and is crucial for polarized cell growth. It participates in targeting and tethering of secretory vesicles to secretory domains of the plasma membrane. The exocyst is consists of eight subunits termed SEC3, SEC5, SEC6, SEC8, SEC10, SEC15, EXO70, and EXO84.
We proved that the exocyst is present in plants, where it functions namely in cells characterized by intensive secretion (Hála et al 2008). Mutants of Arabidopsis thaliana in SEC8, EXO70A1, and EXO84b subunits are dwarf sterile plants (Synek et al. 2006, Fendrych et al. 2010). Other exocyst mutants are defective in seed coat formation or in polar growth of pollen tubes, root hairs and etiolated hypocotyls (Cole et al. 2005, Hála et al. 2008, Kulich et al. 2010). During cell division, the exocyst also plays an important role in establishment and maturation of the new wall separating daughter cells (Fendrych et al. 2010). Currently we also try to determine the interaction partners of the exocyst complex (e.g. RAB GTPases) and elucidate possible role of the exocyst in recycling of plasma membrane proteins.
Interestingly, we demonstrated that some isoforms of the EXO70 subunit are also involved in response to pathogen in Arabidopsis, e.g. an important role in formation of specialized structures and cell wall apposition engaged in the plant defense (Pečenková et al. 2010).
Recently we employed the moss Physcomitrella patens as another model organism for this study. Using the technique of gene targeting, we are able to generate disruption mutants in exocyst subunits that exhibit significant morphological changes (Brejškova et al.).
Small GTPases in Exocytosis
Small GTPases form a family of monomeric proteins that control many polarized processes within the plant cell. We focus on the RAB GTPase subfamily connected with membranes via double geranylgeranyl anchors. The anchors are attached by action of a protein complex called RAB geranylgeranyl transferase (RAB GGT). We study how the geranylation status affects intracellular vesicle transport, hormone signaling, and plant morphogenesis. When RAB GGT activity is decreased we observe small plants with curled leaves, loss of shoot apical dominance, no response to gravity direction changes in shoots, changes in morphogenesis in the dark (Hála et al. 2010).
RAB GTPases are currently extensively studied as important regulators of the intracellular vesicular transport. Using biochemical, molecular biological and genetic approaches, we study RAB GTPases involved in terminal steps of exocytosis – especially those regulating the exocyst complex. We attempt to identify interactors of such RABs as a tool to determine particular role of different RABs in the plant cell.
Furthermore, we study RAB GDP dissociation inhibitors (RAB GDI) that belong to basic regulators of small GTPases with redundant functions and play essential role in the plant cell.
Čeština
English
