Hsp90 is an essential molecular chaperone in the eukaryotic cytosol. Its function is modulated by cochaperones and posttranslational modifications. Importantly, the phosphatase Ppt1 is a dedicated regulator of the Hsp90 chaperone system. Little is known about Ppt1-dependent phosphorylation sites and how these affect Hsp90 activity. Here, we identified the major phosphorylation sites of yeast Hsp90 in its middle or the C-terminal domain and determined the subset regulated by Ppt1. In general, phosphorylation decelerates the Hsp90 machinery, reduces chaperone function in vivo, sensitizes yeast cells to Hsp90 inhibition and affects DNA repair processes. Modification of one particular site (S485) is lethal, whereas others modulate Hsp90 activity via distinct mechanisms affecting the ATPase activity, cochaperone binding and manipulating conformational transitions in Hsp90. Our mechanistic analysis reveals that phosphorylation of Hsp90 permits a regulation of the conformational cycle at distinct steps by targeting switch points for the communication of remote regions within Hsp90.
Protein phosphorylation is the most important type of reversible post-translational modification involved in the regulation of cellular signal-transduction processes. In addition to controlling normal cellular physiology on the molecular level, perturbations of phosphorylation-based signaling networks and cascades have been implicated in the onset and progression of various human diseases. Recent advances in mass spectrometry-based proteomics helped to overcome many of the previous limitations in protein phosphorylation analysis. Improved isotope labeling and phosphopeptide enrichment strategies in conjunction with more powerful mass spectrometers and advances in data analysis have been integrated in highly efficient phosphoproteomics workflows, which are capable of monitoring up to several thousands of site-specific phosphorylation events within one large-scale analysis. Combined with ongoing efforts to define kinase-substrate relationships in intact cells, these major achievements have considerable potential to assess phosphorylation-based signaling networks on a system-wide scale. Here, we provide an overview of these exciting developments and their potential to transform signal-transduction research into a technology-driven, high-throughput science.
Even though protein phosphatases are key regulators of signal transduction, their cellular mechanisms of action are poorly understood. Here, we undertook a large-scale proteomics survey to identify cellular protein targets of a serine/threonine phosphatase. We used SILAC-based quantitative MS to measure differences in protein expression and phosphorylation upon ablation of the serine/threonine phosphatase Ppt1 in Saccharomyces cerevisiae. Phosphopeptide fractionation by strong cation exchange chromatography combined with immobilized metal affinity chromatography (IMAC) enrichment enabled quantification of more than 8000 distinct phosphorylation sites in Ppt1 wild-type versus Ppt1-deficient yeast cells. We further quantified the relative expression of 1897 yeast proteins and detected no major protein changes accompanying Ppt1 deficiency. Notably, we found 33 phosphorylation sites to be significantly and reproducibly up-regulated while no phosphorylation events were repressed in cells lacking Ppt1. Ppt1 acted on its cellular target proteins in a sequence- and site-specific fashion. Several of the regulated phosphoproteins were involved in the response to heat stress in agreement with known Ppt1 functions. Additionally, biosynthetic enzymes were particularly prominent among Ppt1-regulated phosphoproteins, pointing to unappreciated roles of Ppt1 in the control of various metabolic functions. These results demonstrate the utility of large-scale and quantitative phosphoproteomics to identify cellular sites of serine/threonine phosphatase action in an unbiased manner.
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