Study of the TmoS/TmoT two‐component system: towards the functional characterization of the family of TodS/TodT like systems

The two‐component system TmoS/TmoT controls the expression of the toluene‐4‐monooxygenase pathway in Pseudomonas mendocina RK1 via modulation of P_tmoX activity. The TmoS/TmoT system belongs to the family of TodS/TodT like proteins. The sensor kinase TmoS is a 108 kDa protein composed of seven different domains. Using isothermal titration calorimetry we show that purified TmoS binds a wide range of aromatic compounds with high affinities. Tightest ligand binding was observed for toluene (K_D = 150 nM), which corresponds to the highest affinity measured between an effector and a sensor kinase. Other compounds with affinities in the nanomolar range include benzene, the 3 xylene isomers, styrene, nitrobenzene or p‐chlorotoluene. We demonstrate that only part of the ligands that bind to TmoS increase protein autophosphorylation in vitro and consequently pathway expression in vivo. These compounds are referred to as agonists. Other TmoS ligands, termed antagonists, failed to increase TmoS autophosphorylation, which resulted in their incapacity to stimulate gene expression in vivo. We also show that TmoS saturated with different agonists differs in their autokinase activities. The effector screening of gene expression showed that promoter activity of P_tmoX and P_todX (controlled by the TodS/TodT system) is mediated by the same set of 22 compounds. The common structural feature of these compounds is the presence of a single aromatic ring. Among these ligands, toluene was the most potent inducer of both promoter activities. Information on the TmoS/TmoT and TodS/TodT system combined with a sequence analysis of family members permits to identify distinct features that define this protein family.     

Antimicrobial resistance: progress and challenges in antibiotic discovery and anti-infective therapy

The alarming rise in the emergence of antimicrobial resistance in human, animal and plant pathogens is challenging global health and food production. Traditional strategies used for antibiotic discovery persistently result in the re-isolation of known compounds, calling for the need to develop more rational strategies to identify new antibiotics. Additionally, anti-infective therapy approaches targeting bacterial signalling pathways related to virulence is emerging as an alternative to the use of antibiotics. In this perspective article, we critically analyse approaches aimed at revitalizing the identification of new antibiotics and to advance antivirulence therapies. The development of high-throughput in vivo, in vitro and in silico platforms, together with the progress in chemical synthesis, analytical chemistry and structural biology, are reviving a research area that is of tremendous relevance for global health.     

The use of isothermal titration calorimetry to unravel chemotactic signalling mechanisms

Chemotaxis is based on the action of chemosensory pathways and is typically initiated by the recognition of chemoeffectors at chemoreceptor ligand-binding domains (LBD). Chemosensory signalling is highly complex; aspect that is not only reflected in the intricate interaction between many signalling proteins but also in the fact that bacteria frequently possess multiple chemosensory pathways and often a large number of chemoreceptors, which are mostly of unknown function. We review here the usefulness of isothermal titration calorimetry (ITC) to study this complexity. ITC is the gold standard for studying binding processes due to its precision and sensitivity, as well as its capability to determine simultaneously the association equilibrium constant, enthalpy change and stoichiometry of binding. There is now evidence that members of all major LBD families can be produced as individual recombinant proteins that maintain their ligand-binding properties. High-throughput screening of these proteins using thermal shift assays offer interesting initial information on chemoreceptor ligands, providing the basis for microcalorimetric analyses and microbiological experimentation. ITC has permitted the identification and characterization of many chemoreceptors with novel specificities. This ITC-based approach can also be used to identify signal molecules that stimulate members of other families of sensor proteins.     

Cyclic ADP-ribose and inositol 1,4,5-trisphosphate mobilizes Ca from distinct intracellular pools in permeabilized lacrimal acinar cells

In permeabilized lacrimal acinar cells, cyclic ADP-ribose (cADP-ribose) and inositol 1,4,5-trisphosphate (Ins(1,4,5)P₃) release Ca²⁺ in a dose dependent manner from distinct thapsigargin-sensitive Ca²⁺ pools. Ryanodine specifically blocks the Ca²⁺ response to cADP-ribose, whereas heparin strongly reduces the response to Ins(1,4,5)P₃ application. GTP causes a rapid Ca²⁺ release by a ryanodine- and heparin-insensitive mechanism and potentiates Ins(1,4,5)P₃ but not cADP-ribose evoked Ca²⁺ release. It is estimated that cADP-ribose can release 16 μmol Ca²⁺/I cells, whereas Ins(1,4,5)P₃ can mobilize 55 μmol Ca²⁺/I cells. The results suggest that cADP-ribose and Ins(1,4,5)P₃ release Ca²⁺ from distinct internal stores and that a third Ca²⁺ pool exists which can selectively interact with the Ins(1,4,5)P₃-sensitive Ca²⁺ store by a GTP-mediated process.