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Science 25 February 1994:
Vol. 263. no. 5150, pp. 1153 - 1156
DOI: 10.1126/science.8108735
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Articles

Science, Vol 263, Issue 5150, 1153-1156
Copyright © 1994 by American Association for the Advancement of Science

articles

Phosphorylation of the transcription factor PHO4 by a cyclin-CDK complex, PHO80-PHO85

A Kaffman, I Herskowitz, R Tjian, and EK O'Shea

School of Medicine, Department of Biochemistry and Biophysics, University of California at San Francisco 94143.

Induction of the yeast gene PHO5 is mediated by the transcription factors PHO2 and PHO4. PHO5 transcription is not detectable in high phosphate; it is thought that the negative regulators PHO80 and PHO85 inactivate PHO2 and PHO4. Here it is reported that PHO80 has homology to yeast cyclins and interacts with PHO85, a p34cdc2/CDC28-related protein kinase. The PHO80-PHO85 complex phosphorylates PHO4; this phosphorylation is correlated with negative regulation of PHO5. These results demonstrate the existence of a cyclin-cdk complex that is used for a regulatory process other than cell-cycle control and identify a physiologically relevant substrate for this complex.


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Phosphorylation regulates association of the transcription factor Pho4 with its import receptor Pse1/Kap121.
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Cooperative Pho2-Pho4 Interactions at the PHO5 Promoter Are Critical for Binding of Pho4 to UASp1 and for Efficient Transactivation by Pho4 at UASp2.
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   Abstract »    Full Text »
Physiological Regulation of the Derepressible Phosphate Transporter in Saccharomyces cerevisiae.
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   Abstract »    Full Text »
Swi5 Controls a Novel Wave of Cyclin Synthesis in Late Mitosis.
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   Abstract »    Full Text »
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(1998)
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Nucleosome Transactions on the Promoters of the Yeast GAL and PHO Genes.
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J. Biol. Chem. 272, 26795-26798
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Cyclin G2 Is Up-regulated during Growth Inhibition and B Cell Antigen Receptor-mediated Cell Cycle Arrest.
M. C. Horne, K. L. Donaldson, G. L. Goolsby, D. Tran, M. Mulheisen, J. W. Hell, and A. F. Wahl (1997)
J. Biol. Chem. 272, 12650-12661
   Abstract »    Full Text »    PDF »
Mitotic chromosome condensation in the rDNA requires TRF4 and DNA topoisomerase I in Saccharomyces cerevisiae..
I B Castano, P M Brzoska, B U Sadoff, H Chen, and M F Christman (1996)
Genes & Dev. 10, 2564-2576
   Abstract »    PDF »
Cyclin G1 and Cyclin G2 Comprise a New Family of Cyclins with Contrasting Tissue-specific and Cell Cycle-regulated Expression.
M. C. Horne, G. L. Goolsby, K. L. Donaldson, D. Tran, M. Neubauer, and A. F. Wahl (1996)
J. Biol. Chem. 271, 6050-6061
   Abstract »    Full Text »    PDF »
Inhibitors of mammalian G1 cyclin-dependent kinases..
C J Sherr and J M Roberts (1995)
Genes & Dev. 9, 1149-1163
   PDF »
Cell cycle control by a complex of the cyclin HCS26 (PCL1) and the kinase PHO85.
F. Espinoza, J Ogas, I Herskowitz, and D. Morgan (1994)
Science 266, 1388-1391
   Abstract »    PDF »
The PCL2 (ORFD)-PHO85 cyclin-dependent kinase complex: a cell cycle regulator in yeast.
V Measday, L Moore, J Ogas, M Tyers, and B Andrews (1994)
Science 266, 1391-1395
   Abstract »    PDF »
Phosphate-regulated inactivation of the kinase PHO80-PHO85 by the CDK inhibitor PHO81.
K. Schneider, R. Smith, and E. O'Shea (1994)
Science 266, 122-126
   Abstract »    PDF »
Differential regulation of E2F transactivation by cyclin/cdk2 complexes..
B D Dynlacht, O Flores, J A Lees, and E Harlow (1994)
Genes & Dev. 8, 1772-1786
   Abstract »    PDF »
Researchers find new role for cell cycle proteins.
J Marx (1994)
Science 263, 1093
   PDF »
Transcriptional Regulation of the Yeast PHO8 Promoter in Comparison to the Coregulated PHO5 Promoter.
M. Munsterkotter, S. Barbaric, and W. Horz (2000)
J. Biol. Chem. 275, 22678-22685
   Abstract »    Full Text »    PDF »
Regulation of the Yeast Transcriptional Factor PHO2 Activity by Phosphorylation.
C. Liu, Z. Yang, J. Yang, Z. Xia, and S. Ao (2000)
J. Biol. Chem. 275, 31972-31978
   Abstract »    Full Text »    PDF »


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