To survive in a dynamic and unpredictable environment, cells must correctly interpret and integrate extracellular signals with internal factors. In particular, internal stores of nutrients must be managed for use during periods of nutrient limitation. To gain insight into this complex process, we combined biochemical and spectroscopic techniques to follow the dynamics of the phosphate responsive signaling pathway in both single yeast cells and populations. We demonstrate that the phosphate-responsive genes PHO5 and PHO84 exhibit different kinetics of transcriptional induction in response to phosphate starvation, and that transient phosphate limitation causes induction of PHO84 but not PHO5. This differential kinetic behavior is largely eliminated in cells that lack the ability to store phosphate internally in the form of polyphosphate, but the threshold of external phosphate required for induction of PHO5 and PHO84 is unaffected. Our observations indicate that polyphosphate acts as a buffer that can be mobilized during periods of phosphate limitation and enables the phosphate-responsive signaling pathway to filter transient fluctuations in extracellular phosphate levels.homeostasis ͉ nutrients ͉ polyphosphate ͉ signaling C ellular responses to environmental cues involve a complex interplay between intracellular conditions and extracellular factors, coordinated via elaborate signal transduction cascades that initiate changes in metabolism and gene regulation. Insight into how cellular responses facilitate survival in dynamic environments can be gained by following the response to deprivation of the essential nutrient, phosphate, in the model organism, Saccharomyces cerevisiae.In response to phosphate starvation, budding yeast cells have three major responses: they mobilize internal stores of phosphate (1, 2), up-regulate production of a plasma membrane transporter involved in phosphate uptake (Pho84), and increase production of phosphatases (e.g., Pho5) that are secreted into the extracellular environment to liberate inorganic phosphate (P i ) by hydrolysis of organic phosphates (3, 4). These responses are mediated primarily at the level of gene regulation and are controlled by a signaling pathway known as the phosphateresponsive signaling (PHO) pathway (5-7). Key components in the PHO signaling pathway include a cyclin͞cyclin-dependent kinase complex, Pho80͞Pho85, whose activity is regulated in response to phosphate conditions, and its transcription factor substrate, Pho4, which regulates phosphate-responsive gene transcription (5,8,9). Phosphorylation of Pho4 on four serine residues by Pho80͞Pho85 controls Pho4 subcellular localization and its interaction with another transcription factor, Pho2 (10).When cells are grown in medium containing a high concentration of P i , Pho80͞Pho85 is active, Pho4 is fully phosphorylated and localized to the cytoplasm, and transcription of phosphateresponsive genes such as PHO5 and PHO84 is turned off (8, 9). In response to phosphate limitation, Pho80͞Pho85 is inactivated, and ...
