Membrane traffic researchers have an increasingly detailed view of the mechanisms that drive vesicular transport, but we have only a limited grasp of the events that create, maintain, and transform membrane compartments. Based partly on work from my group, budding yeasts are a powerful system for tackling these questions. We will employ the yeasts Saccharomyces cerevisiae and Pichia pastoris to explore fundamental aspects of membrane compartmentation and organization.
Specific Aim #1 is to characterize how cisternal maturation drives secretory cargo transport and Golgi compartmentation using S. cerevisiae. The nonstacked Golgi in S. cerevisiae enables the maturation of individual cisternae to be visualized by fluorescence microscopy. We will use this system to test the assumption that secretory cargo proteins travel through the Golgi in maturing cisternae, and to address the long-standing question of how Golgi cisternae become functionally specialized. Sub-Aim #1A is to track a fluorescent secretory cargo through the Golgi during cisternal maturation. Our hypothesis is that secretory cargo proteins remain in maturing cisternae as resident Golgi proteins come and go. We will test this hypothesis using a novel regulatable fluorescent secretory cargo that can be trapped in the yeast ER and then released for transport through the Golgi. Sub-Aim #1B is to define Golgi organization by a kinetic analysis of resident Golgi proteins. Our hypothesis is that Golgi maturation occurs in discrete kinetic stages that generate functionally distinct types of cisternae. To test this idea and to classify Golgi cisternae, we will perform a systematic, quantitative study of the relative arrival and departure times of resident S. cerevisiae Golgi proteins in wild-type and mutant strains.
Specific Aim #2 is to characterize the physical and functional interactions of ER exit sites (ERES) with other compartments using P. pastoris. A typical P. pastoris cell has 3-4 ERES, each of which is next to a Golgi stack. We will explore the relationship of the ERES with the early Golgi and with the pre-autophagosomal structure (PAS). Sub-Aim #2A is to test whether ERES formation requires association with the early Golgi. Our hypothesis is that the unit of self-organization in the early secretory pathway consists of an ERES plus associated early Golgi membranes. To test this idea, we will seek to disrupt the tethers that link the ERES to the early Golgi in P. pastoris, and will determine whether ERES organization is lost in the absence of tethering. Sub-Aim #2B is to test whether PAS assembly occurs in proximity to functionally specialized ERES. Our hypothesis is that specialized ERES in P. pastoris associate with both the vacuole and the PAS. We will take advantage of the simple morphology in this yeast to clarify how the location and dynamics of the PAS relate to those of ERES.

Public Health Relevance

Abnormal secretory pathway function is a causative agent in diseases such as cancer and developmental disorders. Adequate treatments will require a cell biological understanding of the organization and operation of secretory compartments. The proposed study aims to reveal these basic principles.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
3R01GM104010-07S1
Application #
9964379
Study Section
Program Officer
Ainsztein, Alexandra M
Project Start
2013-09-15
Project End
2021-06-30
Budget Start
2019-07-01
Budget End
2020-06-30
Support Year
7
Fiscal Year
2019
Total Cost
Indirect Cost
Name
University of Chicago
Department
Genetics
Type
Schools of Medicine
DUNS #
005421136
City
Chicago
State
IL
Country
United States
Zip Code
60637
Day, Kasey J; Casler, Jason C; Glick, Benjamin S (2018) Budding Yeast Has a Minimal Endomembrane System. Dev Cell 44:56-72.e4
Casler, Jason C; Glick, Benjamin S (2018) Visualizing Secretory Cargo Transport in Budding Yeast. Curr Protoc Cell Biol :e80
Barrero, Juan J; Casler, Jason C; Valero, Francisco et al. (2018) An improved secretion signal enhances the secretion of model proteins from Pichia pastoris. Microb Cell Fact 17:161
Glick, Benjamin S (2017) New insights into protein secretion: TANGO1 runs rings around the COPII coat. J Cell Biol 216:859-861
Liu, Xu; Mao, Kai; Yu, Angela Y H et al. (2016) The Atg17-Atg31-Atg29 Complex Coordinates with Atg11 to Recruit the Vam7 SNARE and Mediate Autophagosome-Vacuole Fusion. Curr Biol 26:150-160
Barrero, Juan J; Papanikou, Effrosyni; Casler, Jason C et al. (2016) An improved reversibly dimerizing mutant of the FK506-binding protein FKBP. Cell Logist 6:e1204848
Sturmberger, Lukas; Chappell, Thomas; Geier, Martina et al. (2016) Refined Pichia pastoris reference genome sequence. J Biotechnol 235:121-31
Day, Kasey J; Papanikou, Effrosyni; Glick, Benjamin S (2016) 4D Confocal Imaging of Yeast Organelles. Methods Mol Biol 1496:1-11
Papanikou, Effrosyni; Day, Kasey J; Austin, Jotham et al. (2015) COPI selectively drives maturation of the early Golgi. Elife 4:
Bhave, Madhura; Papanikou, Effrosyni; Iyer, Prasanna et al. (2014) Golgi enlargement in Arf-depleted yeast cells is due to altered dynamics of cisternal maturation. J Cell Sci 127:250-7

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