Characterization of translocation pores inserted into plasma membranes by type III-secreted Esp proteins of enteropathogenic Escherichia coli

Abstract: SummaryMany mucosal pathogens use type III secretion systems for the injection of effector proteins into target cells. The type III-secreted proteins EspB and EspD of enteropathogenic Escherichia coli (EPEC) are inserted into the target cell membrane. Together with EspA, these proteins are supposed to constitute a molecular syringe, channelling other effector proteins into the host cell. In this model, EspB and EspD would represent the tip of the needle forming a pore into target cell membranes. Although conta… Show more

“…From the same transcript as that for EspA, two additional translocators (EspD and EspB) are translated to form the transmembrane pore that facilitates effector translocation across the host membrane (14). Secretion of the TTS translocators requires the assistance of cytoplasmic chaperones that have some common properties, namely that they have a low molecular mass (Ͻ15 kDa), have an acidic pI, and contain a C-terminal amphipathic helix (41).…”

“…EspA polymerizes into the filamentous structure, and its polymerization is dependent on coiled-coil interactions between the C-terminal region of the molecule (11) in a way similar to flagella assembly (9). EspB has been reported to interact with EspA (12,13) and EspD (14), and the complexes that form at the distal portion of the needle structure may act as a pore at the contact site with the host cell membrane and participate in the initial step of bacterial adherence (15).…”

Identification of a Third EspA-binding Protein That Forms Part of the Type III Secretion System of Enterohemorrhagic Escherichia coli

“…From the same transcript as that for EspA, two additional translocators (EspD and EspB) are translated to form the transmembrane pore that facilitates effector translocation across the host membrane (14). Secretion of the TTS translocators requires the assistance of cytoplasmic chaperones that have some common properties, namely that they have a low molecular mass (Ͻ15 kDa), have an acidic pI, and contain a C-terminal amphipathic helix (41).…”

“…EspA polymerizes into the filamentous structure, and its polymerization is dependent on coiled-coil interactions between the C-terminal region of the molecule (11) in a way similar to flagella assembly (9). EspB has been reported to interact with EspA (12,13) and EspD (14), and the complexes that form at the distal portion of the needle structure may act as a pore at the contact site with the host cell membrane and participate in the initial step of bacterial adherence (15).…”

Identification of a Third EspA-binding Protein That Forms Part of the Type III Secretion System of Enterohemorrhagic Escherichia coli

“…De forma simultánea a la unión de T3SS al enterocito y a la entrada de las proteínas efectoras a través de los poros, la bacteria ingresa la proteína Tir (receptor) que facilita la adherencia a la intimina bacteriana y es indispensable para la formación del pedestal y la lesión intestinal 35 . Una vez dentro de la célula hospedera, la cabeza de Tir se proyecta a la superficie de la membrana del enterocito, donde actúa como receptor para la intimina y para la transmisión de señales después de la interacción 36 .…”

Mecanismos de virulencia de Escherichia coli enteropatógena

“…In EPEC, the needle in turn is capped by a filamentous extension composed of EspA (13)(14)(15)(16)(17) that facilitates the span of the T3SS across the microvilliated surface of the infected host gut epithelial cells. In the final step of assembly, the translocon (EspB and EspD) assembles at the tip of the EspA filament and inserts into the host membrane to form a pore (18) for direct delivery of virulence effectors into the host cell.…”

Structural Analysis of a Specialized Type III Secretion System Peptidoglycan-cleaving Enzyme