Abstract
The virulence of Shigella mainly resides in the use of a Type 3 Secretion System (T3SS) to inject several proteins inside the host cell. Three categories of proteins are hierarchically secreted: (1) the needle components (MxiH and MxiI), (2) the translocator proteins which form a pore (translocon) inside the host cell membrane, and (3) the effectors interfering with the host cell signaling pathways. In the absence of host cell contact, the T3SS is maintained in an “off” state by the presence of a tip complex. We have previously identified a gatekeeper protein, MxiC, which sequesters effectors inside the bacteria probably by interacting with MxiI, the inner‐rod component. Upon cell contact and translocon insertion, a signal is most likely transmitted from the top of the needle to the base, passing through the needle and allowing effectors release. However, the molecular mechanism underlying the transmission of the activation signal through the needle is still poorly understood. In this work, we investigate the role of MxiI in the activation of the T3SS by performing a mutational study. Interestingly we have shown that mutations of a single residue in MxiI (T82) induce an mxiC‐like phenotype and prevent the interaction with MxiC. Moreover, we have shown that the L26A mutation significantly reduces T3 secretion. The L26A mutation impairs the interaction between MxiI and Spa40, a keystone component of the switch between needle assembly and translocators secretion. The L26A mutation also sequesters MxiC. All these results highlight the crucial role of MxiI in regulating the secretion and transmitting the activation signal of the T3SS.
Highlights
Shigella is a highly adapted human pathogen that causes shigellosis known as bacillary dysentery
The T3S apparatus (T3SA) is composed of more than 20 proteins assembled into four parts: (1) a cytoplasmic part called the C-ring, (2) an export apparatus localized in the inner-membrane ring, (3) a basal body spanning the inner (IM) and outer (OM) membranes, and (4) an extracellular needle (Blocker et al, 1999; Burkinshaw & Strynadka, 2014; Chatterjee, Chaudhury, McShan, Kaur, & de Guzman, 2013)
As sequence similarities exist between T3SA components of different bacteria harboring a Type 3 Secretion System (T3SS), homologous proteins of MxiI are found in Yersinia (YscI), Salmonella (PrgJ), Pseudomonas (PscI), or Burkhoderia (BsaK)
Summary
Shigella is a highly adapted human pathogen that causes shigellosis known as bacillary dysentery. The cytoplasmic part of Spa (Spa40CT), an inner-membrane protein, undergoes a conformational change following its autocleavage into two fragments, called Spa40CC and Spa40CN (Botteaux et al, 2010; Deane et al, 2008a; Monjarás Feria, Lefebre, Stierhof, Galán, & Wagner, 2015; Shen, Moriya, Martinez-Argudo, & Blocker, 2012) which allows its interaction with the needle length ruler, Spa (Botteaux, Sani, Kayath, Boekema, & Allaoui, 2008). We have shown that the C-terminal part of MxiI (74–93 residues), probably located inside the secretion channel, is sufficient for MxiC binding
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