Phosphorylation of Hsl1 by Hog1 leads to a G2 arrest essential for cell survival at high osmolarity

Control of cell cycle progression by stress-activated protein kinases (SAPKs) is essential for cell adaptation to extracellular stimuli. Exposure of yeast to osmostress leads to activation of the Hog1 SAPK, which controls cell cycle at G1 by the targeting of Sic1. Here, we show that survival to osmostress also requires regulation of G2 progression. Activated Hog1 interacts and directly phosphorylates a residue within the Hsl7-docking site of the Hsl1 checkpoint kinase, which results in delocalization of Hsl7 from the septin ring and leads to Swe1 accumulation. Upon Hog1 activation, cells containing a nonphosphorylatable Hsl1 by Hog1 are unable to promote Hsl7 delocalization, fail to arrest at G2 and become sensitive to osmostress. Together, we present a novel mechanism that regulates the Hsl1-Hsl7 complex to integrate stress signals to mediate cell cycle arrest and, demonstrate that a single MAPK coordinately modulates different cell cycle checkpoints to improve cell survival upon stress.     

The Stress-activated Protein Kinase Hog1 Mediates S Phase Delay in Response to Osmostress

Control of cell cycle progression by stress-activated protein kinases (SAPKs) is essential for cell adaptation to extracellular stimuli. Exposure of yeast to osmostress activates the Hog1 SAPK, which modulates cell cycle progression at G1 and G2 by the phosphorylation of elements of the cell cycle machinery, such as Sic1 and Hsl1, and by down-regulation of G1 and G2 cyclins. Here, we show that upon stress, Hog1 also modulates S phase progression. The control of S phase is independent of the S phase DNA damage checkpoint and of the previously characterized Hog1 cell cycle targets Sic1 and Hsl1. Hog1 uses at least two distinct mechanisms in its control over S phase progression. At early S phase, the SAPK prevents firing of replication origins by delaying the accumulation of the S phase cyclins Clb5 and Clb6. In addition, Hog1 prevents S phase progression when activated later in S phase or cells containing a genetic bypass for cyclin-dependent kinase activity. Hog1 interacts with components of the replication complex and delays phosphorylation of the Dpb2 subunit of the DNA polymerase. The two mechanisms of Hog1 action lead to delayed firing of origins and prolonged replication, respectively. The Hog1-dependent delay of replication could be important to allow Hog1 to induce gene expression before replication.     

Hog1 mediates cell-cycle arrest in G1 phase by the dual targeting of Sic1

Activation of stress-activated protein kinases (SAPKs) is essential for proper cell adaptation to extracellular stimuli. The exposure of yeast cells to high osmolarity, or mutations that lead to activation of the Hog1 SAPK, result in cell-cycle arrest. The mechanisms by which Hog1 and SAPKs in general regulate cell-cycle progression are not completely understood. Here we show that Hog1 regulates cell cycle progression at the G1 phase by a dual mechanism that involves downregulation of cyclin expression and direct targeting of the CDK-inhibitor protein Sic1. Hog1 interacts physically with Sic1 in vivo and in vitro, and phosphorylates a single residue at the carboxyl terminus of Sic1, which, in combination with the downregulation of cyclin expression, results in Sic1 stabilization and inhibition of cell-cycle progression. Cells lacking Sic1 or containing a Sic1 allele mutated in the Hog1 phosphorylation site are unable to arrest at G1 phase after Hog1 activation, and become sensitive to osmostress. Together, our data indicate that the Sic1 CDK-inhibitor is the molecular target for the SAPK Hog1 that is required to modulate cell-cycle progression in response to stress.     

Discovering novel interactions at the nuclear pore complex using bead halo: a rapid method for detecting molecular interactions of high and low affinity at equilibrium

A highly sensitive, equilibrium-based binding assay termed "Bead Halo" was used here to identify and characterize interactions involving components of the nucleocytoplasmic transport machinery in eukaryotes. Bead Halo uncovered novel interactions between the importin Kap95 and the nucleoporins (nups) Nic96, Pom34, Gle1, Ndc1, Nup84, and Seh1, which likely occur during nuclear pore complex biogenesis. Bead Halo was also used to characterize the molecular determinants for binding between Kap95 and the family of nups that feature multiple phenylalanine-glycine motifs (FG nups). Binding was sensitive to the number of FG motifs present and to amino acid (AA) residues immediately flanking the FG motifs. Also, binding was reduced but not abolished when phenylalanine residues in all FG motifs were replaced by tyrosine or tryptophan. These results suggest flexibility in the binding pockets of Kap95 and synergism in binding FG motifs. The hypothesis that Nup53 and Nup59 bind directly to membranes through a C-terminal amphipathic alpha helix and to DNA via an RNA recognition motif domain was also tested and validated using Bead Halo. The results support a role for these nups in nuclear pore membrane biogenesis and in gene expression. Finally, Bead Halo detected binding of the nups Gle1, Nup60, and Nsp1 to phospholipid bilayers. This may reflect the known interaction between Gle1 and phosphoinositides and suggests similar interactions for Nup60 and Nsp1. As the Bead Halo assay detected molecular interactions in cell lysates, as well as between purified components, it can be adapted for large-scale proteomic studies using automated robotics and microscopy.