Loss of Rhb1, a Rheb-Related GTPase in Fission Yeast, Causes Growth Arrest With a Terminal Phenotype Similar to That Caused by Nitrogen Starvation

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Loss of Rhb1, a Rheb-Related GTPase in Fission Yeast, Causes Growth Arrest With a Terminal Phenotype Similar to That Caused by Nitrogen Starvation

Kathleen E. Mach^a, Kyle A. Furge^a, and Charles F. Albright^a
^a Department of Biochemistry, Vanderbilt University School of Medicine, Nashville, Tennessee 37232-0146

Corresponding author: Charles F. Albright, DuPont Pharmaceuticals, 500 S. Ridgeway Ave., Glenolden, PA 19036., charles.f.albright{at}dupontpharma.com (E-mail)

Communicating editor: P. G. YOUNG

The Rheb GTPase is most similar in primary sequence to the Ras,Rap, R-Ras, and Ral GTPases, which regulate cell growth anddifferentiation in many cell types. A likely fission yeast homologueof mammalian Rheb, which we designated Rhb1, was identifiedby genome sequencing. Our investigation of rhb1 showed thatrhb1^- cells arrested cell growth and division with a terminalphenotype similar to that of nitrogen-starved cells. In particular,cells depleted of Rhb1 arrested as small, round cells with 1NDNA content, arrested more quickly in low-nitrogen medium, andinduced expression of fnx1 and mei2 mRNA, two mRNAs that werenormally induced by nitrogen starvation. Since mammalian Rhebbinds and may regulate Raf-1, a Ras effector, we tested forfunctional overlap between Ras1 and Rhb1 in fission yeast. Thisanalysis showed that Ras1 overexpression did not suppress rhb1^-mutant phenotypes, Rhb1 overexpression did not suppress ras1^-mutant phenotypes, and ras1^- rhb1^- double mutants had phenotypesequal to the sum of the corresponding single-mutant phenotypes.Hence, there is no evidence for overlapping functions betweenRas1 and Rhb1. On the basis of this study, we hypothesize thatRhb1 negatively regulates entry into stationary phase when extracellularnitrogen levels are adequate for growth. If this hypothesisis correct, then Rhb1 and Ras1 regulate alternative responsesto limiting nutrients.

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				N. Hay and N. Sonenberg Upstream and downstream of mTOR Genes & Dev., August 15, 2004; 18(16): 1926 - 1945. [Abstract] [Full Text] [PDF]

				M. van Slegtenhorst, E. Carr, R. Stoyanova, W. D. Kruger, and E. P. Henske Tsc1+ and tsc2+ Regulate Arginine Uptake and Metabolism in Schizosaccharomyces pombe J. Biol. Chem., March 26, 2004; 279(13): 12706 - 12713. [Abstract] [Full Text] [PDF]

				Y. Kim, D. Ramirez-Montealegre, and D. A. Pearce A role in vacuolar arginine transport for yeast Btn1p and for human CLN3, the protein defective in Batten disease PNAS, December 23, 2003; 100(26): 15458 - 15462. [Abstract] [Full Text] [PDF]

				A. P. Tabancay Jr., C.-L. Gau, I. M. P. Machado, E. J. Uhlmann, D. H. Gutmann, L. Guo, and F. Tamanoi Identification of Dominant Negative Mutants of Rheb GTPase and Their Use to Implicate the Involvement of Human Rheb in the Activation of p70S6K J. Biol. Chem., October 10, 2003; 278(41): 39921 - 39930. [Abstract] [Full Text] [PDF]

				P. H. Patel, N. Thapar, L. Guo, M. Martinez, J. Maris, C.-L. Gau, J. A. Lengyel, and F. Tamanoi Drosophila Rheb GTPase is required for cell cycle progression and cell growth J. Cell Sci., September 1, 2003; 116(17): 3601 - 3610. [Abstract] [Full Text] [PDF]

				A. F. Castro, J. F. Rebhun, G. J. Clark, and L. A. Quilliam Rheb Binds Tuberous Sclerosis Complex 2 (TSC2) and Promotes S6 Kinase Activation in a Rapamycin- and Farnesylation-dependent Manner J. Biol. Chem., August 29, 2003; 278(35): 32493 - 32496. [Abstract] [Full Text] [PDF]

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