Abstract EN:

The adenylate cyclase toxin (CyaA) is one of the major virulence factor produced by Bordetella pertussis, the causative agent of whopping cough. CyaA has the unique capacity to translocate its catalytic domain directly across the plasma membrane. Then, the catalytic domain binds to calmodulin (CaM) to produce high levels of cAMP, leading to cell intoxication. Although several models have been proposed, the molecular mechanism and the forces involved in the translocation of CyaA remain elusive. The calcium gradient, the membrane potential across the plasma membrane and post-translational acylation are required for an efficient CyaA translocation. During my PhD, I mainly investigated the translocation process. It has been previously shown that deletion of the translocation region abolishes the delivery of the catalytic domain into the cytosol of target cells. In this region, the peptide P454 (residues 454 to 484 of CyaA) was identified and exhibits membrane-active properties related to antimicrobial peptides, i.e membrane interaction, α-helical folding upon membrane insertion and membrane permeabilization. We have investigated the role of P454 on the translocation process. We observed that negatively charged and fluidic membrane favor P454 membrane insertion. The peptide contains two arginine residues that are critically involved in its membrane-active properties. We further identified that P454 exhibits the intrinsic propensity to translocate across lipid bilayers and forms a stable complex with CaM. We identified several residues from P454 involved in both membrane interaction and CaM binding. We showed in the context of the full-length CyaA toxin that these residues are essential for the efficient translocation of the catalytic domain into the cell and production of cAMP. We propose a translocation model in which the membrane-active P454 segment from the translocation region destabilizes the membrane, favoring its translocation. In the cytosol, the P454 segment is trapped by CaM and the formation of the complex may act as a driving force pulling the catalytic domain across the plasma membrane. We further showed that CaM binding to the main CaM-binding site in the catalytic domain induces local and long-range allosteric effects that stabilize the enzymatic site, allowing fast ATP catalysis to cAMP, leading to host subversion. The relevance of these results for the translocation and activation of CyaA are discussed.