Characterization of mammalian exocyst subunit Sec3

Andersen, Nicholas John

01 December 2009

The Exocyst is a hetero-octameric complex involved in tethering of post-Golgi vesicle transport to sites of membrane expansion. In budding yeast, the Exocyst targets vesicles to bud site resulting in bud emergence and abscission of the daughter cell. Mammalian Exocyst is recruited to developing lateral membranes after cadherin mediated adhesion and then is segregated to adherens junctional complexes (AJC). In polarized epithelia, the Exocyst is required for basal-lateral transport of LDL receptor. Additional Exocyst subunit localizations and functions have been identified. It is not known whether these supplementary roles can be attributed to the Exocyst or other unidentified Exocyst subcomplexes. Sec3, an Exocyst subunit, is hypothesized to be a landmark of polarization in yeast. In polarized epithelia, GFP tagged Sec3 remained cytosolic in polarized epithelia unlike Sec6/8. Sec3-GFP was recruited to lateral membranes only after dual over expression of heterologous GLYT1. Little is known about endogenous mammalian Sec3. Our work suggests Sec3 defines an Exocyst subcomplex that is required for desmosome integrity. Sec3 and additional subunits (Sec6, Sec8, Sec15, Exo70, and Exo84) were present at desmosomes, but Sec3 failed to localize to AJC. Only antibodies to Sec6 and Sec8 labeled AJC. Reduction of Sec3 protein expression resulted in the impairment of desmosome morphology and function with no detrimental effect on adherens junctions. These data suggest the existence of functionally different Exocyst subcomplexes. Sec3-exocyst recruited minus-end directed microtubule motor KifC3 to desmosomes. KifC3 was previously shown to be recruited with a microtubule anchoring complex to basal-lateral membrane. This suggests Sec3 may recruit KifC3 to organize microtubules at desmosomes. This would establish a pathway to efficiently transport newly synthesized basal-lateral cargo. These results suggest a novel mechanism of the Exocyst to regulate post-Golgi vesicular transport and intercellular adhesion.

Cell Adhesion

Desmosome

Exocyst

KifC3

Polarity

Sec3

Cell Biology

Role komplexu exocyst v růstu a vývoji mechu Physcomitrella patens / Role of exocyst complex in growth and development of moss Physcomitrella patens

Rawat, Anamika Ashok

January 2017

During the course of evolution the early land plants gained extensive innovations that can be seen in modern day plants. The polar growth is an ancient feature of eukaryotic cells and is one of preadaptations that helped plants in successful colonization of land. The polar growth in plants regulates not only the direction of cell expansion and structural properties of cell wall but especially also the orientation of cell division, and is governed by various factors, including the exocyst complex. The exocyst is a well conserved vesicle tethering multi-subunit complex involved in tethering of secretory vesicles to the target membrane. The essential role of the exocyst complex in regulation of various cellular processes in Angiosperms is now well documented. Here I present results of a doctoral project that contributed to phylogenetic analyses of the land plant exocyst complex and especially to uncovering functions of three moss exocyst subunits, namely EXO70 (isoform PpEXO70.3d), SEC6 and SEC3 (isoforms PpSEC3A and PpSEC3B) in the model organism Physcomitrella patens. Various knock-out (KO) mutants in several moss exocyst subunits (Ppexo70.3d, Ppsec6, Ppsec3a and Ppsec3b) show pleiotropic defects directly or indirectly linked to the cell polarity regulation. Cell elongation and differentiation,...