Limitation of phosphate assimilation maintains cytoplasmic magnesium homeostasis

Abstract

AbstractPhosphorus (P) is an essential component of several core biological molecules. In bacteria, P is mainly acquired as inorganic orthophosphate (Pi). Once in the cytoplasm, Pi is incorporated into adenosine triphosphate (ATP), which exists primarily as a Mg2+salt. Notably, whereas P is essential, excess of cytosolic Pi hinders growth. Here we demonstrate that cytotoxic effects of excessive Pi uptake result from its assimilation into ATP and subsequent disruption of Mg2+dependent processes. We show thatSalmonella entericacells experiencing cytoplasmic Mg2+starvation restrict Pi uptake, thereby limiting the availability of an ATP precursor. This response prevents excessive ATP synthesis, overproduction of ribosomal RNA, chelation of free cytoplasmic Mg2+and the destabilization of Mg2+-dependent core processes that ultimately hinder bacterial growth and leads to loss of cellular viability. We demonstrate that, even when cytoplasmic Mg2+is not limiting, excessive Pi uptake leads to increased ATP synthesis, depletion of free cytoplasmic Mg2+, inhibition of translation and growth. Our results establish that bacteria must restrict Pi uptake to prevent the depletion of cytoplasmic Mg2+. Furthermore, they provide a framework to understand the molecular basis of Pi cytotoxicity and reveal a regulatory logic employed by bacterial cells to control P assimilation.ImportancePhosphorus (P) is essential for life. As the fifth most abundant element in living cells, P is required for the synthesis of an array of biological molecules including (d)NTPs, nucleic acids and membranes. Organisms typically acquire environmental P as inorganic phosphate. While essential for growth and viability, excessive intracellular Pi is toxic for both bacteria and eukaryotes. Using the bacteriumSalmonella entericaas a model, we demonstrate that Pi cytotoxicity is manifested following its assimilation into ATP, which acts as a chelating agent for intracellular cations, most notably, Mg2+. These results identify physiological processes disrupted by excessive Pi and elucidate a regulatory logic employed by bacteria to prevent uncontrollable P assimilation.