The Arf GTPase exchange factor Sec7p interaction network:

• Main Author: Gloor, Yvonne
• Other Authors: Technische Universität Dresden, Fakultät Mathematik und Naturwissenschaften
• Format: Doctoral Thesis
• Language: English
• Published: Saechsische Landesbibliothek- Staats- und Universitaetsbibliothek Dresden 2017
• Subjects: Yeast; Golgi traffic; Sec7p; Pik1p; Cpd1p; Hefe; Golgi Transport; ddc:570; rvk:WE 3650
• Online Access: http://nbn-resolving.de/urn:nbn:de:bsz:14-ds-1202827858817-78960; http://nbn-resolving.de/urn:nbn:de:bsz:14-ds-1202827858817-78960; http://www.qucosa.de/fileadmin/data/qucosa/documents/337/Thesis_Yvonne_Gloor.pdf

The Golgi apparatus is the main crossroad of the intracellular trafficking network in all eukaryotic cells and plays a crucial role in the distribution of cellular material. To ensure the proper sorting and delivery of cargo proteins to their destination while maintaining Golgi homeostasis the coordination of all transport events to and from this organelle is required. Although a cascade of activation events has already been reported for Golgi Ypt/Rab proteins that function in the exocytic pathway, their connection to incoming vesicles from endosomal compartments or to the different Arf mediated vesicle formation machineries has still to be established. In addition, the role of lipids and the interplay between lipid and protein regulators at the Golgi are largely missing. In the present study, we used several approaches to unravel the crosstalk between known regulators of Golgi trafficking and to identify new proteins involved in this process. As starting point, we considered the results from four different screens before focusing on the role of Arf exchange factors. We report two new physical interactors of the late Golgi Arf-GEF Sec7p: the lipid kinase Pik1p and the cyclic nucleotide phosphodiesterase Cpd1p. In addition, our studies on the function of Sec7p revealed additional feature of this protein and it’s relationship to the other yeast Golgi Arf-GEFs. Arf proteins and their regulators play an important role in the formation of vesicles at the exit from the Golgi apparatus. There are three Golgi-localized Arf-GEFs in S.cerevisiae, Sec7p and the redundant Gea1p/Gea2p. While it has been established that Sec7p function does not overlap with the Gea’s, the specific role of these proteins remains unclear. We show that Sec7p colocalizes poorly with the Gea’s, indicating that these proteins activate Arf on different Golgi sub-compartments. In addition, our data suggest that Sec7p mainly promotes the formation of post-Golgi transport vesicles supporting forward transport from the late Golgi while the Gea’s primarily regulate COPI-mediated retrograde traffic. This observation is consistent with published data from mammalian cells and suggests that the spatial and temporal regulation of Arf is conserved from yeast to mammals. Both Arf regulation and phosphatidylinositol 4-phosphate (PI4P) metabolism are important factors for Golgi function. Here, we show that the yeast PI4-kinase, Pik1p binds specifically to Sec7p but not Gea1p or Gea2p. Taken together, the physical interaction, the colocalization and similar transport phenotypes of the respective mutants suggests a functional link between Pik1p and Sec7p but not the Gea’s. In addition, Pik1p binds to the catalytic domain of Sec7p and could directly influence the activity of the GEF. We propose that this interaction coordinates Arf activation with PI4P production to generate a highly specific dual recognition system for the recruitment of specific effectors to the late Golgi. Besides its catalytic domain, Sec7p shares several conserved regions with other members of the BIG/GBF Arf-GEF subfamilies, including the N-terminal DCB (Dimerization/Cyclophilin Binding) domain. We show that a single point mutation in the DCB domain of Sec7p efficiently inhibits Arf activation without affecting membrane recruitment of the GEF and could interfere with a possible dimerization of the protein. We identified Cpd1p as an allele specific dosage suppressor of the Sec7p DCB domain mutation. Cpd1p and Sec7p physically interact and both proteins localize independently to the late Golgi. Increased Golgi level of Cpd1p compensates for the loss of interaction due to the mutation in the DCB domain of Sec7p. The catalytic activity of Cpd1p is important for the rescue, indicating an intriguing connection between the Arf activation cycle and ADP-ribose derivates. We also find that Cpd1p interacts with several other proteins involved in Golgi- and post-Golgi transport events. Hence, Cpd1p is a new regulator of vesicular traffic at the Golgi that could act as a scaffolding factor for Sec7p and other transport proteins.