Abstract

Eukaryotic cells adapt to environmental changes by altering their protein complements through synthesis and degradation. Cells that adapt poorly or improperly may either cease to exist (e.g., apoptosis) or become neoplastic (e.g., hepatoma). Cells adapt to low levels of amino acids by sequestering proteins and organelles for lysosomal degradation via a process called autophagy. The data from many laboratories suggest that autophagy is turned on during apoptosis and turned off during neoplastic growth implicating a role for autophagy in suppressing cancerous growth. Indeed, Beclin is a tumor suppressor that was originally shown to be required for autophagy in yeast. Our long-term goals are to characterize the molecular aspects of the regulation and mechanisms of cellular autophagy. We have characterized the degradation of peroxisomes and endogenous proteins by autophagy in the yeast Pichiapastoris under various environmental conditions. We have utilized this genetic model to identify 14 GSA genes that are required for glucose-induced selective autophagy. We have recently observed that during autophagy Gsa11 becomes associated with an organelle that is juxtaposed to the vacuole. In addition, this interaction requires the indirect or direct action of four additional GSA proteins including two protein kinases suggesting this event is highly regulated. Our results show that Gsa11 and its complex have a primary function in the sequestration of organelles for vacuole degradation. We propose that this organelle anchors at its surface a complex of proteins including Gsa11 that somehow organize the formation of the autophagic vacuole. In this application, we propose to examine the molecular and structural aspects of this organelle and the events required for the assembly of this complex in order to better understand its function. Our hypothesis is: Gsa11 must associate with a membrane-bound organelle prior to the sequestration events that occur during autophagy. We will utilize the versatility of our yeast model combined with a multidisciplinary approach of biochemical, cell biological, molecular biological, and genetic procedures to test our hypothesis. We will identify and characterize those GSA proteins that influence either directly or indirectly the formation of the Gsa11 complex. We will specifically evaluate the role of two protein kinases in the assembly of this complex. Finally, we will determine if the human homologue of Gsa11 is required for autophagy in a hepatoma cell line. The data obtained here will provide new insights into the events of sequestration of organelles for lysosomal degradation. In addition, with our new understanding of the molecular events of autophagy, we can begin to design clinical approaches by which to turn on autophagy and arrest neoplastic growth.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA095552-03
Application #
6794642
Study Section
Special Emphasis Panel (ZRG1-CDF-4 (02))
Program Officer
Spalholz, Barbara A
Project Start
2002-09-03
Project End
2007-08-31
Budget Start
2004-09-01
Budget End
2005-08-31
Support Year
3
Fiscal Year
2004
Total Cost
$235,164
Indirect Cost

  Institution

Name
University of Florida
Department
Anatomy/Cell Biology
Type
Schools of Medicine
DUNS #
969663814
City
Gainesville
State
FL
Country
United States
Zip Code
32611

  Publications

Akin, Debra; Wang, S Keisin; Habibzadegah-Tari, Pouran et al. (2014) A novel ATG4B antagonist inhibits autophagy and has a negative impact on osteosarcoma tumors. Autophagy 10:2021-35
Aris, John P; Fishwick, Laura K; Marraffini, Michelle L et al. (2012) Amino acid homeostasis and chronological longevity in Saccharomyces cerevisiae. Subcell Biochem 57:161-86
Madorsky, Irina; Opalach, Katherine; Waber, Amanda et al. (2009) Intermittent fasting alleviates the neuropathic phenotype in a mouse model of Charcot-Marie-Tooth disease. Neurobiol Dis 34:146-54
Schroder, Laura A; Ortiz, Michael V; Dunn Jr, William A (2008) The membrane dynamics of pexophagy are influenced by Sar1p in Pichia pastoris. Mol Biol Cell 19:4888-99
Wohlgemuth, Stephanie E; Julian, David; Akin, Debora E et al. (2007) Autophagy in the heart and liver during normal aging and calorie restriction. Rejuvenation Res 10:281-92
Schroder, Laura A; Glick, Benjamin S; Dunn, William A (2007) Identification of pexophagy genes by restriction enzyme-mediated integration. Methods Mol Biol 389:203-18
Fry, Michelle R; Thomson, J Michael; Tomasini, Amber J et al. (2006) Early and late molecular events of glucose-induced pexophagy in Pichia pastoris require Vac8. Autophagy 2:280-8
Chang, Tina; Schroder, Laura A; Thomson, J Michael et al. (2005) PpATG9 encodes a novel membrane protein that traffics to vacuolar membranes, which sequester peroxisomes during pexophagy in Pichia pastoris. Mol Biol Cell 16:4941-53
Dunn Jr, William A; Cregg, James M; Kiel, Jan A K W et al. (2005) Pexophagy: the selective autophagy of peroxisomes. Autophagy 1:75-83