Structure of the core of the type III secretion system export apparatus

Kuhlen, Lucas; Abrusci, Patrizia; Johnson, Steven; Gault, Joseph; Deme, Justin C.; Caesar, Joseph; Dietsche, Tobias; Mebrhatu, Mehari Tesfazgi; Ganief, Tariq; Maček, Boris; Wagner, Samuel; Robinson, Carol V.; Lea, Susan M.

doi:10.1038/s41594-018-0086-9

Cited by 152 publications

(309 citation statements)

References 44 publications

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“…The core export apparatus components SctR, SctS and SctT form a helical assembly with nearly the same helical parameters as the needle filament: about 5.5 subunits per turn and a helical rise of about 4.0 Å per subunit (Kuhlen et al , ). These data suggest that the core export apparatus templates assembly of the helical filament and thus, also the inner rod should possess these helical properties.…”

Section: Resultsmentioning

confidence: 99%

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The inner rod of virulence‐associated type III secretion systems constitutes a needle adapter of one helical turn that is deeply integrated into the system's export apparatus

Torres-Vargas

Kronenberger

Roos

et al. 2019

Molecular Microbiology

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Summary Type III secretion injectisomes are essential virulence factors for many pathogenic bacteria by mediating the transport of effector proteins into eukaryotic host cells. The secretion conduit of injectisomes is formed by a helical assembly of three hydrophobic proteins (SctR, SctS and SctT), an inner rod (SctI) and a needle filament (SctF). SctI is thought to play a role in switching between the secretion of different substrate classes and assembly of the inner rod has been implicated in regulating the length of the needle filament. While high‐resolution structures of the hydrophobic components and of the needle filament have been solved, little is known about the structure and the assembly of the inner rod, which impedes the deeper assessment of its function. Here we show by exhaustive in vivo photocrosslinking that SctI engages in extensive interactions with SctR and SctT throughout its entire length. Our data imply that the inner rod serves as an adapter between the export apparatus and the needle filament by forming one helical turn. We show that assembly of the inner rod does not play a role in needle length control nor in substrate specificity switching. Instead, our findings imply that inner rod assembly must precede assembly of the needle filament.

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Section: Resultsmentioning

confidence: 99%

“…The inner rod itself is anchored to the core export apparatus components SctR and SctT, that, together with SctS, also form a helical assembly with nearly identical helical parameters as the needle filament ( Fig. 1B,C) (Dietsche et al, 2016;Kuhlen et al, 2018;Johnson et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

The inner rod of virulence‐associated type III secretion systems constitutes a needle adapter of one helical turn that is deeply integrated into the system's export apparatus

Torres-Vargas

Kronenberger

Roos

et al. 2019

Molecular Microbiology

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“…The high level of sequence conservation within all T3SS implied that this complex would be similarly assembled in virulence T3SS. Native mass spectrometry (nMS) of purified virulence system complexes supported this, revealing a core SctR5T1 complex equivalent to FliP5R1 (Kuhlen, Abrusci et al 2018). However, the number of SctS subunits was highly variable in samples and seemed to reflect lower stability of these complexes c.f.…”

Section: Introductionmentioning

confidence: 90%

“…We have recently demonstrated that a subset of these proteins assembles into a core exportgate complex, and reported the structure of a flagellar FliP5Q4R1 (hereafter termed FliPQR) complex at 4.2 Å structure by cryo-electron microscopy (Kuhlen, Abrusci et al 2018). Strikingly placing the FliPQR structure into lower resolution basal body structures revealed that this complex, built from three putative membrane proteins and purified from membranes when expressed in isolation of the rest of the T3SS, physiologically exists in an 20 extra-membrane location at the core of the basal body (Worrall, Hong et al 2016, Kuhlen, Abrusci et al 2018}. This positioning of the complex, in conjunction with the observation that it exhibits helical symmetry, suggested that it seeds assembly of the axial helical components that culminate in the flagellum or needle.…”

Section: Introductionmentioning

confidence: 99%

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The structure of an injectisome export gate demonstrates conservation of architecture in the core export gate between flagellar and virulence type three secretion systems

Johnson

Kuhlen

Deme

et al. 2019

Preprint

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Export of proteins through type three secretion systems (T3SS) is critical for motility and virulence of many major bacterial pathogens. Proteins are exported though a genetically defined export gate complex consisting of three proteins. We have recently shown at 4.2 Å that the flagellar complex of these three putative membrane proteins (FliPQR in flagellar systems, SctRST in virulence systems) assemble into an extra-membrane helical assembly that likely seeds correct assembly of the rod above. Here we present the structure of an equivalent complex from the more fragile Shigella virulence system at 3.5 Å by cryo-electron microscopy. This higher resolution structure reveals further detail and confirms the prediction of 30 structural conservation in this core complex. Analysis of particle heterogeneity also reveals details of how the SctS/FliQ subunits sequentially assemble in the complex.Introduction:

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The sorting platform in the type III secretion pathway: From assembly to function

Soto

Lara‐Tejero

2023

BioEssays

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The type III secretion system (T3SS) is a specialized nanomachine that enables bacteria to secrete proteins in a specific order and directly deliver a specific set of them, collectively known as effectors, into eukaryotic organisms. The core structure of the T3SS is a syringe‐like apparatus composed of multiple building blocks, including both membrane‐associated and soluble proteins. The cytosolic components organize together in a chamber‐like structure known as the sorting platform (SP), responsible for recruiting, sorting, and initiating the substrates destined to engage this secretion pathway. In this article, we provide an overview of recent findings on the SP's structure and function, with a particular focus on its assembly pathway. Furthermore, we discuss the molecular mechanisms behind the recruitment and hierarchical sorting of substrates by this cytosolic complex. Overall, the T3SS is a highly specialized and complex system that requires precise coordination to function properly. A deeper understanding of how the SP orchestrates T3S could enhance our comprehension of this complex nanomachine, which is central to the host‐pathogen interface, and could aid in the development of novel strategies to fight bacterial infections.

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Structure of the core of the type III secretion system export apparatus

Cited by 152 publications

References 44 publications

The inner rod of virulence‐associated type III secretion systems constitutes a needle adapter of one helical turn that is deeply integrated into the system's export apparatus

The inner rod of virulence‐associated type III secretion systems constitutes a needle adapter of one helical turn that is deeply integrated into the system's export apparatus

The structure of an injectisome export gate demonstrates conservation of architecture in the core export gate between flagellar and virulence type three secretion systems

The sorting platform in the type III secretion pathway: From assembly to function

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