EMD-34137
Complex structure of Clostridioides difficile binary toxin unfolded CDTa-bound CDTb-pore (short).
EMD-34137
Single-particle2.8 Å
Deposition: 19/08/2022Map released: 26/10/2022
Last modified: 03/07/2024
Sample Organism:
Clostridioides difficile
Sample: Clostridioides difficile transferase complex
Fitted models: 7yvs (Avg. Q-score: 0.549)
Deposition Authors: Yamada T
,
Kawamoto A ,
Yoshida T ,
Sato Y,
Kato T ,
Tsuge H
Sample: Clostridioides difficile transferase complex
Fitted models: 7yvs (Avg. Q-score: 0.549)
Deposition Authors: Yamada T
,
Kawamoto A ,
Yoshida T ,
Sato Y,
Kato T ,
Tsuge H
Cryo-EM structures of the translocational binary toxin complex CDTa-bound CDTb-pore from Clostridioides difficile.
Abstract:
Some bacteria express a binary toxin translocation system, consisting of an enzymatic subunit and translocation pore, that delivers enzymes into host cells through endocytosis. The most clinically important bacterium with such a system is Clostridioides difficile (formerly Clostridium). The CDTa and CDTb proteins from its system represent important therapeutic targets. CDTb has been proposed to be a di-heptamer, but its physiological heptameric structure has not yet been reported. Here, we report the cryo-EM structure of CDTa bound to the CDTb-pore, which reveals that CDTa binding induces partial unfolding and tilting of the first CDTa α-helix. In the CDTb-pore, an NSS-loop exists in 'in' and 'out' conformations, suggesting its involvement in substrate translocation. Finally, 3D variability analysis revealed CDTa movements from a folded to an unfolded state. These dynamic structural information provide insights into drug design against hypervirulent C. difficile strains.
Some bacteria express a binary toxin translocation system, consisting of an enzymatic subunit and translocation pore, that delivers enzymes into host cells through endocytosis. The most clinically important bacterium with such a system is Clostridioides difficile (formerly Clostridium). The CDTa and CDTb proteins from its system represent important therapeutic targets. CDTb has been proposed to be a di-heptamer, but its physiological heptameric structure has not yet been reported. Here, we report the cryo-EM structure of CDTa bound to the CDTb-pore, which reveals that CDTa binding induces partial unfolding and tilting of the first CDTa α-helix. In the CDTb-pore, an NSS-loop exists in 'in' and 'out' conformations, suggesting its involvement in substrate translocation. Finally, 3D variability analysis revealed CDTa movements from a folded to an unfolded state. These dynamic structural information provide insights into drug design against hypervirulent C. difficile strains.