Rudy Antoine scite author profile

A collection of large virulence exoproteins, including Ca2+‐independent cytolysins, an iron acquisition protein and several adhesins, are secreted by the two‐partner secretion (TPS) pathway in various Gram‐negative bacteria. The hallmarks of the TPS pathway are the presence of an N‐proximal module called the ‘secretion domain’ in the exoproteins that we have named the TpsA family, and the channel‐forming β‐barrel transporter proteins we refer to as the TpsB family. The genes for cognate exoprotein and transporter protein are usually organized in an operon. Specific secretion signals are present in a highly conserved region of the secretion domain of TpsAs. TpsBs probably serve as specific receptors of the TpsA secretion signals and as channels for the translocation of the exoproteins across the outer membrane. A subfamily of transporters also mediates activation of their cognate cytolysins upon secretion. The exoproteins are synthesized as precursors with an N‐terminal cleavable signal peptide, and a subset of them carries an extended signal peptide of unknown function. According to our current model, the exoproteins are probably translocated across the cytoplasmic membrane in a Sec‐dependent fashion, and their signal peptide is probably processed by a LepB‐type signal peptidase. The N‐proximal secretion domain directs the exoproteins towards their transporters early, so that translocation across both membranes is coupled. The exoproteins transit through the periplasm in an extended conformation and fold progressively at the cell surface before eventually being released into the extracellular milieu. Several adhesins also undergo extensive proteolytic processing upon secretion. The genes of many new TpsAs and TpsBs are found in recently sequenced genomes, suggesting that the TPS pathway is widespread.

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Structural insights into the signalling mechanisms of two-component systems

Jacob‐Dubuisson¹,

Mechaly²,

Betton³

et al. 2018

Nat Rev Microbiol

225

219

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Two-component systems reprogramme diverse aspects of microbial physiology in response to environmental cues. Canonical systems are composed of a transmembrane sensor histidine kinase and its cognate response regulator. They catalyse three reactions: autophosphorylation of the histidine kinase, transfer of the phosphoryl group to the regulator and dephosphorylation of the phosphoregulator. Elucidating signal transduction between sensor and output domains is highly challenging given the size, flexibility and dynamics of histidine kinases. However, recent structural work has provided snapshots of the catalytic mechanisms of the three enzymatic reactions and described the conformation and dynamics of the enzymatic moiety in the kinase-competent and phosphatase-competent states. Insight into signalling mechanisms across the membrane is also starting to emerge from new crystal structures encompassing both sensor and transducer domains of sensor histidine kinases. In this Progress article, we highlight such important advances towards understanding at the molecular level the signal transduction mechanisms mediated by these fascinating molecular machines.

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Subtilisin-like autotransporter serves as maturation protease in a bacterial secretion pathway

Coutte

Antoine

Drobecq

et al. 2001

EMBO J

128

167

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Proteins of Gram-negative bacteria destined to the extracellular milieu must cross the two cellular membranes and then fold at the appropriate time and place. The synthesis of a precursor may be a strategy to maintain secretion competence while preventing aggregation or premature folding (especially for large proteins). The secretion of 230 kDa ®lamentous haemagglutinin (FHA) of Bordetella pertussis requires the synthesis and the maturation of a 367 kDa precursor that undergoes the proteolytic removal of its~130 kDa C-terminal intramolecular chaperone domain. We have identi®ed a speci®c protease, SphB1, responsible for the timely maturation of the precursor FhaB, which allows for extracellular release of FHA. SphB1 is a large exported protein with a subtilisin-like domain and a C-terminal domain typical of bacterial autotransporters. SphB1 is the ®rst described subtilisin-like protein that serves as a specialized maturation protease in a secretion pathway of Gram-negative bacteria. This is reminiscent of pro-protein convertases of eukaryotic cells.

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Rudy Antoine

Two‐partner secretion in Gram‐negative bacteria: a thrifty, specific pathway for large virulence proteins

Structural insights into the signalling mechanisms of two-component systems

Subtilisin-like autotransporter serves as maturation protease in a bacterial secretion pathway

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