GAL4/YPL248C Literature Guide Help

Other names published for GAL4: GAL81, YPL248C

GAL4 - Genetic Interactions (25)

ReferenceOther Genes Addressed
Campbell RN, et al.  (2011) Isolation of compensatory inhibitor domain mutants to novel activation domain variants using the split-ubiquitin screen. Yeast 28(8):569-78
Phenix H, et al.  (2011) Quantitative epistasis analysis and pathway inference from genetic interaction data. PLoS Comput Biol 7(5):e1002048
Li Y, et al.  (2010) Alterations in the Interaction Between GAL4 and GAL80 Effect Regulation of the Yeast GAL Regulon Mediated by the F box Protein Dsg1. Curr Microbiol 61(3):210-6
Zheng J, et al.  (2010) Epistatic relationships reveal the functional organization of yeast transcription factors. Mol Syst Biol 6():420
Ferdous A, et al.  (2007) The role of the proteasomal ATPases and activator monoubiquitylation in regulating Gal4 binding to promoters. Genes Dev 21(1):112-23
Lim MK, et al.  (2007) Gal11p dosage-compensates transcriptional activator deletions via Taf14p. J Mol Biol 374(1):9-23
Khanday FA, et al.  (2002) Molecular characterization of MRG19 of Saccharomyces cerevisiae. Implication in the regulation of galactose and nonfermentable carbon source utilization. Eur J Biochem 269(23):5840-50
Melcher K  (2000) The strength of acidic activation domains correlates with their affinity for both transcriptional and non-transcriptional proteins. J Mol Biol 301(5):1097-112
Rodriguez C and Flores C  (2000) Mutations in GAL2 or GAL4 alleviate catabolite repression produced by galactose in Saccharomyces cerevisiae. Enzyme Microb Technol 26(9-10):748-755
Allard S, et al.  (1999) NuA4, an essential transcription adaptor/histone H4 acetyltransferase complex containing Esa1p and the ATM-related cofactor Tra1p. EMBO J 18(18):5108-19
Balasubramanian B and Morse RH  (1999) Binding of Gal4p and bicoid to nucleosomal sites in yeast in the absence of replication. Mol Cell Biol 19(4):2977-85
Hirst M, et al.  (1999) GAL4 is regulated by the RNA polymerase II holoenzyme-associated cyclin-dependent protein kinase SRB10/CDK8. Mol Cell 3(5):673-8
Koh SS, et al.  (1998) An activator target in the RNA polymerase II holoenzyme. Mol Cell 1(6):895-904
Ryan MP, et al.  (1998) SWI-SNF complex participation in transcriptional activation at a step subsequent to activator binding. Mol Cell Biol 18(4):1774-82
Blank TE, et al.  (1997) Novel Gal3 proteins showing altered Gal80p binding cause constitutive transcription of Gal4p-activated genes in Saccharomyces cerevisiae. Mol Cell Biol 17(5):2566-75
Cairns BR, et al.  (1996) Essential role of Swp73p in the function of yeast Swi/Snf complex. Genes Dev 10(17):2131-44
Rubin DM, et al.  (1996) Identification of the gal4 suppressor Sug1 as a subunit of the yeast 26S proteasome. Nature 379(6566):655-7
Russell SJ, et al.  (1996) Isolation and characterization of SUG2. A novel ATPase family component of the yeast 26 S proteasome. J Biol Chem 271(51):32810-7
Sadowski I, et al.  (1996) Phosphorylation of Ga14p at a single C-terminal residue is necessary for galactose-inducible transcription. Mol Cell Biol 16(9):4879-87
Lee M and Struhl K  (1995) Mutations on the DNA-binding surface of TATA-binding protein can specifically impair the response to acidic activators in vivo. Mol Cell Biol 15(10):5461-9
Melcher K and Johnston SA  (1995) GAL4 interacts with TATA-binding protein and coactivators. Mol Cell Biol 15(5):2839-48
Stargell LA and Struhl K  (1995) The TBP-TFIIA interaction in the response to acidic activators in vivo. Science 269(5220):75-8
Hu GZ and Ronne H  (1994) Yeast BTF3 protein is encoded by duplicated genes and inhibits the expression of some genes in vivo. Nucleic Acids Res 22(14):2740-3
Matsumoto K, et al.  (1983) Cyclic AMP may not be involved in catabolite repression in Saccharomyces cerevisiae: evidence from mutants unable to synthesize it. J Bacteriol 156(2):898-900
Tsuyumu S and Adams BG  (1974) Dilution kinetic studies of yeast populations: in vivo aggregation of galactose utilizing enzymes and positive regulator molecules. Genetics 77(3):491-505