Magnesium Transporters as Crucial Regulators of Bacterial Survival and Pathogenicity

Magnesium is an essential divalent cation required for adenosine triphosphate (ATP)-dependent reactions, nucleic acid metabolism, and ribosomal stability. Bacteria depend on specialized transport systems to maintain intracellular Mg2+ homeostasis as it cannot freely cross the phospholipid bilayer. During infection, host nutritional immunity restricts metal availability, and magnesium limitation within the phagosome compromises bacterial metabolism and stability. This review summarizes the major bacterial magnesium transport systems and their roles in survival and pathogenicity, with an emphasis on Salmonella and extension to clinically relevant ESKAPE pathogens. We focus on the PhoPQ-regulated MgtA, MgtB, and MgtC system, in which low magnesium, acidic pH, and other host-derived signals activate PhoPQ to induce mgt gene expression. MgtA and MgtB act as high-affinity P-type ATPases, whereas MgtC promotes bacterial survival within the intramacrophage environment by inhibiting bacterial F-type ATP synthase through specific interactions with subunit a. We also discuss CorA as a conserved channel for basal Mg2+ uptake and MgtE as a Mg2+-selective channel whose gating responds to intracellular Mg2+ and ATP. Finally, we consider the conservation and variation in these systems across pathogenic bacteria and their potential as therapeutic targets for antimicrobial development.