The small membrane protein MgrB regulates PhoQ bifunctionality to control PhoP target gene expression dynamics

In Escherichia coli and other γ‐proteobacteria, the PhoQ‐PhoP two‐component signaling system responds to low extracellular Mg⁺⁺ and cationic antimicrobial peptides. On transition to inducing conditions, the expression of PhoP‐dependent genes increases rapidly, but then decays to a new, intermediate steady‐state level, a phenomenon often referred to as partial adaptation. The molecular basis for this partial adaptation has been unclear. Here, using time‐lapse fluorescence microscopy to examine PhoP‐dependent gene expression in individual E. coli cells we show that partial adaptation arises through a negative feedback loop involving the small protein MgrB. When E. coli cells are shifted to low Mg⁺⁺, PhoQ engages in multiple rounds of autophosphorylation and phosphotransfer to PhoP, which, in turn, drives the expression of mgrB. MgrB then feeds back to inhibit the kinase activity of PhoQ. PhoQ is bifunctional such that, when not active as a kinase, it can stimulate the dephosphorylation of PhoP. Thus, MgrB drives the inactivation of PhoP and the observed adaptation in PhoP‐dependent gene expression. Our results clarify the source of feedback inhibition in the E. coli PhoQ‐PhoP system and reveal how exogenous factors, such as MgrB, can combine with a canonical two‐component signaling pathway to produce complex temporal dynamics in target gene expression.     

The connector SafA interacts with the multi-sensing domain of PhoQ in Escherichia coli

Sensor histidine kinases of two-component signal transduction systems (TCSs) respond to various environmental signals and transduce the external stimuli across the cell membrane to their cognate response regulators. Recently, membrane proteins that modulate sensory systems have been discovered. Among such proteins is SafA, which activates the PhoQ/PhoP TCS by direct interaction with the sensor PhoQ. SafA is directly induced by the EvgS/EvgA TCS, thus connecting the two TCSs, EvgS/EvgA and PhoQ/PhoP. We investigated how SafA interacted with PhoQ. Bacterial two-hybrid and reporter assays revealed that the C-terminal region (41-65 aa) of SafA activated PhoQ at the periplasm. Adding synthetic SafA(41-65) peptide to the cell culture also activated PhoQ/PhoP. Furthermore, direct interaction between SafA(41-65) and the sensor domain of PhoQ was observed by means of surface plasmon resonance. NMR spectroscopy of (15) N-labelled PhoQ sensor domain confirmed that SafA and Mg(2+) provoked a different conformational change of PhoQ. Site-directed mutagenesis studies revealed that R53, within SafA(41-65), was important for the activation of PhoQ, and D179 of the PhoQ sensor domain was required for its activation by SafA. SafA activated PhoQ by a different mechanism from cationic antimicrobial peptides and acidic pH, and independent of divalent cations and MgrB.     

PhoP can activate its target genes in a PhoQ-independent manner

The PhoP/PhoQ two-component system controls the extracellular magnesium depletion response in Salmonella enterica. Previous studies have shown that PhoP is unable to up-regulate its target genes in the absence of PhoQ function. In this work, we demonstrate that PhoP overexpression can substitute for PhoQ- and phosphorylation-dependent activation. Either a high concentration of PhoP or activation via phosphorylation stimulates PhoP self-association.     

Overlaid positive and negative feedback loops shape dynamical properties of PhoPQ two-component system

Bacteria use two-component systems (TCSs) to sense environmental conditions and change gene expression in response to those conditions. To amplify cellular responses, many bacterial TCSs are under positive feedback control, i.e. increase their expression when activated. Escherichia coli Mg²⁺ -sensing TCS, PhoPQ, in addition to the positive feedback, includes a negative feedback loop via the upregulation of the MgrB protein that inhibits PhoQ. How the interplay of these feedback loops shapes steady-state and dynamical responses of PhoPQ TCS to change in Mg²⁺ remains poorly understood. In particular, how the presence of MgrB feedback affects the robustness of PhoPQ response to overexpression of TCS is unclear. It is also unclear why the steady-state response to decreasing Mg²⁺ is biphasic, i.e. plateaus over a range of Mg²⁺ concentrations, and then increases again at growth-limiting Mg²⁺. In this study, we use mathematical modeling to identify potential mechanisms behind these experimentally observed dynamical properties. The results make experimentally testable predictions for the regime with response robustness and propose a novel explanation of biphasic response constraining the mechanisms for modulation of PhoQ activity by Mg²⁺ and MgrB. Finally, we show how the interplay of positive and negative feedback loops affects the network’s steady-state sensitivity and response dynamics. In the absence of MgrB feedback, the model predicts oscillations thereby suggesting a general mechanism of oscillatory or pulsatile dynamics in autoregulated TCSs. These results improve the understanding of TCS signaling and other networks with overlaid positive and negative feedback.