Abstract

The long term goal of this work is to contribute to an understanding of general principles of eukaryotic gene transcription regulatory mechanisms. The gene regulatory system that is being studied here is the galactose-responsive transcription switch, the GAL gene switch, of the small eucaryote, S. cerevisiae. The activities of three proteins, Gal4, Gal80 and Gal3 constitute the primary mechanistic elements of the switch. Gal4, a typical eukaryotic DNA binding transcriptional activator, binds UASgal sites of GAL genes independently of galactose. The Gal4 transcriptional activation domain (Gal4AD) is inhibited in the absence of galactose by binding GalSO. Galactose and ATP activate Gal3 to bind GalSO, relieving GalSO inhibition of Gal4AD and enabling Gal4AD to activate transcription. How the Gal3-Gal80 interaction activates Gal4 is controversial. A widely accepted Non-dissociation model posits that Gal3 binds to a nuclear Gal80-Gal4- UASgal complex to expose the Gal4AD. Our published evidence for GalSO nucleo-cytoplasmic shuttling and Gal80-Gal4 dissociation along with data indicative of Gal80-Gal3 interaction in the cytoplasm challenges the Non-dissociation model. Newer data we have recently published point to the GalSO self- association equilibrium and distinct Gal80 monomer and dimer preferences for binding to Gal3 and Gal4, respectively, as additional features that are not accounted for by a Non-dissociation model. We posit a new model """"""""the GalSO Shuttle"""""""" model that specifies that a GalSO monomer binds to activated Gal3 in the cytoplasm and causes; 1) a redistribution of GalSO that decreases its concentration in the nucleus, and 2) a reduction in the cellular concentration of the GalSO dimer, the form of GalSO that the model specifies as the form that binds to and inhibits Gal4. The GalSO Shuttle model invokes GalSO nucleo-cytoplasmic rapid shuttling, Gal80-Gal3 binding in the cytoplasm, rapid Gal80 monomer-dimer equilibrium, GalSO monomer and dimer binding preference differences, and dissociation of GalSO from Gal4 as key mechanistic features of the GAL gene switch. The proposed experiments combine genetic, cell biological, and physical methods to test aspects/predictions of the GalSO Shuttle model.
All Aims converge on determining how the sub- cellular distributions and dynamics of Gal3 and GalSO integrate with all relevant ligand-protein, protein- protein and protein-DNA interactions to comprise the overall GAL gene switch mechanism. HEALTH RELATEDNESS: this work will provide insight into how individual mechanistic elements involving cellular organization and macromolecular dynamics and interactions are integrated to provide overall principles of transcriptional regulation. Such insight is an important goal for human health care delivery because many disease states, including cancers, are often due to defects in gene regulatory systems. Moreover, what we learn about this gene switch can help design new gene switches for gene expression therapies. ? ? ?

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM027925-26
Application #
7350916
Study Section
Molecular Genetics C Study Section (MGC)
Program Officer
Tompkins, Laurie
Project Start
1979-09-01
Project End
2011-03-31
Budget Start
2008-04-01
Budget End
2009-03-31
Support Year
26
Fiscal Year
2008
Total Cost
$370,233
Indirect Cost

  Institution

Name
Ohio State University
Department
Biochemistry
Type
Schools of Arts and Sciences
DUNS #
832127323
City
Columbus
State
OH
Country
United States
Zip Code
43210

  Publications

Egriboz, Onur; Goswami, Sudip; Tao, Xiaorong et al. (2013) Self-association of the Gal4 inhibitor protein Gal80 is impaired by Gal3: evidence for a new mechanism in the GAL gene switch. Mol Cell Biol 33:3667-74
Hellman, Lance M; Zhao, Chunxia; Melikishvili, Manana et al. (2011) Histidine-tag-directed chromophores for tracer analyses in the analytical ultracentrifuge. Methods 54:31-8
Egriboz, Onur; Jiang, Fenglei; Hopper, James E (2011) Rapid GAL gene switch of Saccharomyces cerevisiae depends on nuclear Gal3, not nucleocytoplasmic trafficking of Gal3 and Gal80. Genetics 189:825-36
Jiang, Fenglei; Frey, Benjamin R; Evans, Margery L et al. (2009) Gene activation by dissociation of an inhibitor from a transcriptional activation domain. Mol Cell Biol 29:5604-10
Pilauri, Vepkhia; Bewley, Maria; Diep, Cuong et al. (2005) Gal80 dimerization and the yeast GAL gene switch. Genetics 169:1903-14
Carrozza, Michael J; John, Sam; Sil, Alok Kumar et al. (2002) Gal80 confers specificity on HAT complex interactions with activators. J Biol Chem 277:24648-52
Mylin, L M; Hopper, J E (1997) Inducible expression cassettes in yeast: GAL4. Methods Mol Biol 62:131-48
Blank, T E; Woods, M P; Lebo, C M et al. (1997) Novel Gal3 proteins showing altered Gal80p binding cause constitutive transcription of Gal4p-activated genes in Saccharomyces cerevisiae. Mol Cell Biol 17:2566-75
Long, R M; Hopper, J E (1995) Genetic and carbon source regulation of phosphorylation of Sip1p, a Snf1p-associated protein involved in carbon response in Saccharomyces cerevisiae. Yeast 11:233-46
Mylin, L M; Bushman, V L; Long, R M et al. (1994) SIP1 is a catabolite repression-specific negative regulator of GAL gene expression. Genetics 137:689-700

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