The guanine-nucleotide-exchange factor Cdc24p is targeted to the nucleus and polarized growth sites.

Generation of cellular asymmetry or cell polarity plays a critical role in cell-cycle-regulated morphogenetic processes involving the actin cytoskeleton. The GTPase Cdc42 regulates actin rearrangements and signal transduction pathways in all eukaryotic cells [1], and the temporal and spatial regulation of Cdc42p depends on the activity and targeting of its guanine-nucleotide exchange factor (GEF). Cdc24p, the Saccharomyces cerevisiae GEF for Cdc42p, is found in a particulate fraction and localizes to the plasma membrane [2] [3] at sites of polarized growth [4]. We show that Cdc24p labeled with green fluorescent protein (GFP-Cdc24p) was targeted to pre-bud sites, the tips and sides of enlarging buds, and mating projections in pheromone-treated cells. Unexpectedly, GFP-Cdc24p also localized to the nucleus and GFP-Cdc24p levels diminished before nuclear division followed by its reappearance in divided nuclei and mother-bud necks during cytokinesis. The Cdc24p amino-terminal 283 amino acids were necessary and sufficient for nuclear localization, which depended on the cyclin-dependent-kinase inhibitor Far1p. The Cdc24p carboxy-terminal 289 amino acids were necessary and sufficient for targeting to the pre-bud site, bud, mother-bud neck, and mating projection. Targeting was independent of the Cdc24p-binding proteins Far1p, the GTPase Rsr1p/Bud1p, the scaffold protein Bem1p, and the G(beta) subunit Ste4p. These data are consistent with a temporal and spatial regulation of Cdc24p-dependent activation of Cdc42p during the cell cycle.

Suppressor analysis of fimbrin (Sac6p) overexpression in yeast.

Yeast fimbrin (Sac6p) is an actin filament-bundling protein that is lethal when overexpressed. To identify the basis for this lethality, we sought mutations that can suppress it. A total of 1326 suppressor mutations were isolated and analyzed. As the vast majority of mutations were expected to simply decrease the expression of Sac6p to tolerable levels, a rapid screen was devised to eliminate these mutations. A total of 1324 mutations were found to suppress by reducing levels of Sac6p in the cell. The remaining 2 mutations were both found to be in the actin gene and to make the novel changes G48V (act1-20) and K50E (act1-21). These mutations suppress the defect in cytoskeletal organization and cell morphology seen in ACT1 cells that overexpress SAC6. These findings indicate that the lethal phenotype caused by Sac6p overexpression is mediated through interaction with actin. Moreover, the altered residues lie in the region of actin previously implicated in the binding of Sac6p, and they result in a reduced affinity of actin for Sac6p. These results indicate that the two mutations most likely suppress by reducing the affinity of actin for Sac6p in vivo. This study suggests it should be possible to use this type of suppressor analysis to identify other pairs of physically interacting proteins and suggests that it may be possible to identify sites where such proteins interact with each other.