The Shigella T3SS needle transmits a signal for MxiC release, which controls secretion of effectors

Type III secretion systems (T3SSs) are key determinants of virulence in many Gram-negative bacteria, including animal and plant pathogens. They inject 'effector' proteins through a 'needle' protruding from the bacterial surface directly into eukaryotic cells after assembly of a 'translocator' pore in the host plasma membrane. Secretion is a tightly regulated process, which is blocked until physical contact with a host cell takes place. Host cell sensing occurs through a distal needle 'tip complex' and translocators are secreted before effectors. MxiC, a Shigella T3SS substrate, prevents premature effector secretion. Here, we examine how the different parts of T3SSs work together to allow orderly secretion. We show that T3SS assembly and needle tip composition are not altered in an mxiC mutant. We find that MxiC not only represses effector secretion but that it is also required for translocator release. We provide genetic evidence that MxiC acts downstream of the tip complex and then the needle during secretion activation. Finally, we show that the needle controls MxiC release. Therefore, for the first time, our data allow us to propose a model of secretion activation that goes from the tip complex to cytoplasmic MxiC via the needle.     

Oligomeric states of the Shigella translocator protein IpaB provide structural insights into formation of the type III secretion translocon

The Shigella flexneri Type III secretion system (T3SS) senses contact with human intestinal cells and injects effector proteins that promote pathogen entry as the first step in causing life threatening bacillary dysentery (shigellosis). The Shigella Type III secretion apparatus (T3SA) consists of an anchoring basal body, an exposed needle, and a temporally assembled tip complex. Exposure to environmental small molecules recruits IpaB, the first hydrophobic translocator protein, to the maturing tip complex. IpaB then senses contact with a host cell membrane, forming the translocon pore through which effectors are delivered to the host cytoplasm. Within the bacterium, IpaB exists as a heterodimer with its chaperone IpgC; however, IpaB's structural state following secretion is unknown due to difficulties isolating stable protein. We have overcome this by coexpressing the IpaB/IpgC heterodimer and isolating IpaB by incubating the complex in mild detergents. Interestingly, preparation of IpaB with n‐octyl‐oligo‐oxyethylene (OPOE) results in the assembly of discrete oligomers while purification in N,N‐dimethyldodecylamine N‐oxide (LDAO) maintains IpaB as a monomer. In this study, we demonstrate that IpaB tetramers penetrate phospholipid membranes to allow a size‐dependent release of small molecules, suggesting the formation of discrete pores. Monomeric IpaB also interacts with liposomes but fails to disrupt them. From these and additional findings, we propose that IpaB can exist as a tetramer having inherent flexibility, which allows it to cooperatively interact with and insert into host cell membranes. This event may then lay the foundation for formation of the Shigella T3SS translocon pore.     

The type 3 secretion system requires actin polymerization to open translocon pores

Many bacterial pathogens require a type 3 secretion system (T3SS) to establish a niche. Host contact activates bacterial T3SS assembly of a translocon pore in the host plasma membrane. Following pore formation, the T3SS docks onto the translocon pore. Docking establishes a continuous passage that enables the translocation of virulence proteins, effectors, into the host cytosol. Here we investigate the contribution of actin polymerization to T3SS-mediated translocation. Using the T3SS model organism Shigella flexneri, we show that actin polymerization is required for assembling the translocon pore in an open conformation, thereby enabling effector translocation. Opening of the pore channel is associated with a conformational change to the pore, which is dependent upon actin polymerization and a coiled-coil domain in the pore protein IpaC. Analysis of an IpaC mutant that is defective in ruffle formation shows that actin polymerization-dependent pore opening is distinct from the previously described actin polymerization-dependent ruffles that are required for bacterial internalization. Moreover, actin polymerization is not required for other pore functions, including docking or pore protein insertion into the plasma membrane. Thus, activation of the T3SS is a multilayered process in which host signals are sensed by the translocon pore leading to the activation of effector translocation.     

Preparation and characterization of translocator/chaperone complexes and their component proteins from Shigella flexneri

Shigella flexneri causes a severe form of bacillary dysentery also known as shigellosis. Onset of shigellosis requires bacterial invasion of colonic epithelial cells which is initiated by the delivery of translocator and effector proteins to the host cell membrane and cytoplasm, respectively, by the Shigella type III secretion system (TTSS). The Shigella translocator proteins, IpaB and IpaC, form a pore complex in the host cell membrane to facilitate effector delivery; however, prior to their secretion IpaB and IpaC are partitioned in the bacterial cytoplasm by association with the cytoplasmic chaperone IpgC. To determine their structural and biophysical properties, recombinant IpaB/IpgC and IpaC/IpgC complexes were prepared for their first detailed in vitro analysis. Both IpaB/IpgC and IpaC/IpgC complexes are highly stable and soluble heterodimers whose formation prevents IpaB-IpaC interaction as well as Ipa-dependent disruption of phospholipid membranes. Circular dichroism spectroscopy shows that IpgC binding has a detectable influence on IpaC secondary/tertiary structure and stability. In contrast, IpaB structure is not as dramatically affected by chaperone binding. To more precisely ascertain the influence of chaperone binding on IpaC structure and stability, single tryptophan mutants were generated for detailed fluorescence spectroscopy analysis. These mutants provide a low-resolution picture of how IpaC exists in the Shigella cytoplasm with chaperone binding possibly involving distinct regions within the N- and C-terminal halves of IpaC. This preliminary assessment of the IpaC-IpgC interaction is supported by initial deletion mutagenesis studies. The data provide the first structural analysis of IpgC association with IpaB and IpaC.     

Binding affects the tertiary and quaternary structures of the Shigella translocator protein IpaB and its chaperone IpgC

Shigella flexneri uses its type III secretion system (T3SS) to promote invasion of human intestinal epithelial cells as the first step in causing shigellosis, a life-threatening form of dysentery. The Shigella type III secretion apparatus (T3SA) consists of a basal body that spans the bacterial envelope and an exposed needle that injects effector proteins into target cells. The nascent Shigella T3SA needle is topped with a pentamer of the needle tip protein invasion plasmid antigen D (IpaD). Bile salts trigger recruitment of the first hydrophobic translocator protein, IpaB, to the tip complex where it senses contact with a host membrane. In the bacterial cytoplasm, IpaB exists in a complex with its chaperone IpgC. Several structures of IpgC have been determined, and we recently reported the 2.1 ? crystal structure of the N-terminal domain (IpaB(74.224)) of IpaB. Like IpgC, the IpaB N-terminal domain exists as a homodimer in solution. We now report that when the two are mixed, these homodimers dissociate and form heterodimers having a nanomolar dissociation constant. This is consistent with the equivalent complexes copurified after they had been co-expressed in Escherichia coli. Fluorescence data presented here also indicate that the N-terminal domain of IpaB possesses two regions that appear to contribute additively to chaperone binding. It is also likely that the N-terminus of IpaB adopts an alternative conformation as a result of chaperone binding. The importance of these findings within the functional context of these proteins is discussed.     

Using disruptive insertional mutagenesis to identify the in situ structure‐function landscape of the Shigella translocator protein IpaB

Bacterial type III secretion systems (T3SS) are used to inject proteins into mammalian cells to subvert cellular functions. The Shigella T3SS apparatus (T3SA) is comprised of a basal body, cytoplasmic sorting platform and exposed needle with needle “tip complex” (TC). TC maturation occurs when the translocator protein IpaB is recruited to the needle tip where both IpaD and IpaB control secretion induction. IpaB insertion into the host membrane is the first step of translocon pore formation and secretion induction. We employed disruptive insertional mutagenesis, using bacteriophage T4 lysozyme (T4L), within predicted IpaB loops to show how topological features affect TC functions (secretion control, translocon formation and effector secretion). Insertions within the N‐terminal half of IpaB were most likely to result in a loss of steady‐state secretion control, however, all but the two that were not recognized by the T3SA retained nearly wild‐type hemolysis (translocon formation) and invasiveness levels (effector secretion). In contrast, all but one insertion in the C‐terminal half of IpaB maintained secretion control but were impaired for hemolysis and invasion. These nature of the data suggest the latter mutants are defective in a post‐secretion event, most likely due to impaired interactions with the second translocator protein IpaC. Intriguingly, only two insertion mutants displayed readily detectable T4L on the bacterial surface. The data create a picture in which the makeup and structure of a functional T3SA TC is highly amenable to physical perturbation, indicating that the tertiary structure of IpaB within the TC is more plastic than previously realized.     

Influence of oligomerization state on the structural properties of invasion plasmid antigen B from Shigella flexneri in the presence and absence of phospholipid membranes

Shigella flexneri causes bacillary dysentery, an important cause of mortality among children in the developing world. Shigella secretes effector proteins via its type III secretion system (T3SS) to promote bacterial uptake into human colonic epithelial cells. The T3SS basal body spans the bacterial cell envelope anchoring a surface‐exposed needle. A pentamer of invasion plasmid antigen D lies at the nascent needle tip and invasion plasmid antigen B (IpaB) is recruited into the needle tip complex on exposure to bile salts. From here, IpaB forms a translocon pore in the host cell membrane. Although the mechanism by which IpaB inserts into the membrane is unknown, it was recently shown that recombinant IpaB can exist as either a monomer or tetramer. Both of these forms of IpaB associate with membranes, however, only the tetramer forms pores in liposomes. To reveal differences between these membrane‐binding events, Cys mutations were introduced throughout IpaB, allowing site‐specific fluorescence labeling. Fluorescence quenching was used to determine the influence of oligomerization and/or membrane association on the accessibility of different IpaB regions to small solutes. The data show that the hydrophobic region of tetrameric IpaB is more accessible to solvent relative to the monomer. The hydrophobic region appears to promote membrane interaction for both forms of IpaB, however, more of the hydrophobic region is protected from solvent for the tetramer after membrane association. Limited proteolysis demonstrated that changes in IpaB's oligomeric state may determine the manner by which it associates with phospholipid membranes and the subsequent outcome of this association. Proteins 2014; 82:3013–3022. © 2014 Wiley Periodicals, Inc.     

Secretion of type III effectors into host cells in real time

Type III secretion (T3S) systems are key features of many gram-negative bacteria that translocate T3S effector proteins directly into eukaryotic cells. There, T3S effectors exert many effects, such as cellular invasion or modulation of host immune responses. Studying spatiotemporal orchestrated secretion of various effectors has been difficult without disrupting their functions. Here we developed a new approach using Shigella flexneri T3S as a model to investigate bacterial translocation of individual effectors via multidimensional time-lapse microscopy. We demonstrate that direct fluorescent labeling of tetracysteine motif-tagged effectors IpaB and IpaC is possible in situ without loss of function. Studying the T3S kinetics of IpaB and IpaC ejection from individual bacteria, we found that the entire pools of IpaB and IpaC were released concurrently upon host cell contact, and that 50% of each effector was secreted in 240 s. This method allows an unprecedented analysis of the spatiotemporal events during T3S.     

The needle component of the type III secreton of Shigella regulates the activity of the secretion apparatus

Gram-negative bacteria commonly interact with eukaryotic host cells by using type III secretion systems (TTSSs or secretons). TTSSs serve to transfer bacterial proteins into host cells. Two translocators, IpaB and IpaC, are first inserted with the aid of IpaD by Shigella into the host cell membrane. Then at least two supplementary effectors of cell invasion, IpaA and IpgD, are transferred into the host cytoplasm. How TTSSs are induced to secrete is unknown, but their activation appears to require direct contact of the external distal tip of the apparatus with the host cell. The extracellular domain of the TTSS is a hollow needle protruding 60 nm beyond the bacterial surface. The monomeric unit of the Shigella flexneri needle, MxiH, forms a superhelical assembly. To probe the role of the needle in the activation of the TTSS for secretion, we examined the structure-function relationship of MxiH by mutagenesis. Most point mutations led to normal needle assembly, but some led to polymerization or possible length control defects. In other mutants, secretion was constitutively turned "on." In a further set, it was "constitutively on" but experimentally "uninducible." Finally, upon induction of secretion, some mutants released only the translocators and not the effectors. Most types of mutants were defective in interactions with host cells. Together, these data indicate that the needle directly controls the activity of the TTSS and suggest that it may be used to "sense" host cells.     

Ultrastructural analysis of IpaD at the tip of the nascent MxiH type III secretion apparatus of Shigella flexneri

Shigella flexneri is a Gram-negative enteric pathogen that is the predominant cause of bacillary dysentery. Shigella uses a type III secretion system to deliver effector proteins that alter normal target cell functions to promote pathogen invasion. The type III secretion apparatus (T3SA) consists of a basal body, an extracellular needle, and a tip complex that is responsible for delivering effectors into the host cell cytoplasm. IpaD [Ipa (invasion plasmid antigen)] is the first protein to localize to the T3SA needle tip, where it prevents premature effector secretion and serves as an environmental sensor for triggering recruitment of the translocator protein IpaB to the needle tip. Thus, IpaD would be expected to form a stable structure whose overall architecture supports its functions. It is not immediately obvious from the published IpaD crystal structure (Protein Data Bank ID 2j0o) how a multimer of IpaD would be incorporated at the tip of the first static T3SA intermediate, nor what its functional role would be in building a mature T3SA. Here, we produce three-dimensional reconstructions from transmission electron microscopy images of IpaD localized at the Shigella T3SA needle tip for comparison to needle tips from a Shigella ipaD-null mutant. The results demonstrate that IpaD resides as a homopentamer at the needle tip of the T3SA. Furthermore, comparison to tips assembled from the distal domain IpaD(Δ192-267) mutation shows that IpaD adopts an elongated conformation that facilitates its ability to control type III secretion and stepwise assembly of the T3SA needle tip complex.     

Bacterial signals and cell responses during Shigella entry into epithelial cells

Shigella invades epithelial cells by inducing cytoskeletal reorganization localized at the site of bacterial–host cell interaction. During entry, the Shigella type III secretion apparatus allows the insertion of a pore that contains the IpaB and IpaC proteins into cell membranes. Insertion of this complex is thought to allow translocation of the carboxy-terminus moiety of IpaC, but also of other Shigella effectors, such as IpaA, into the cell cytosol. IpaC triggers actin polymerization and the formation of filopodial and lamellipodial extensions dependent on the Cdc42 and Rac GTPases. IpaA, on the other hand, binds to the focal adhesion protein vinculin and induces depolymerization of actin filaments. IpaA and the GTPase Rho are not required for actin polymerization at the site of bacterial contact with the cell membrane, but allow the transformation of the IpaC-induced extensions into a structure that is productive for bacterial entry. Rho is required for the recruitment at entry foci of ezrin, a cytoskeletal linker required for Shigella entry, and also of the Src tyrosine kinase. The Src tyrosine kinase activity, which is required for Shigella -induced actin polymerization, also appears to be involved in a negative regulatory loop that downregulates Rho at the site of entry.     

Connexin-dependent inter-cellular communication increases invasion and dissemination of Shigella in epithelial cells

Shigella flexneri, the causative agent of bacillar dystentery, invades the colonic mucosa where it elicits an intense inflammatory reaction responsible for destruction of the epithelium. During cell invasion, contact with host cells activates the type-III secretion of the Shigella IpaB and IpaC proteins. IpaB and IpaC are inserted into host cell plasma membranes and trigger initial signals that result in actin polymerization, while allowing cytosolic access of other bacterial effectors that further reorganize the cytoskeleton. After internalization, Shigella moves intracellularly and forms protrusions that infect neighbouring cells, promoting bacterial dissemination across the epithelium. Here, we show that during cell invasion, Shigella induces transient peaks in intracellular calcium concentration that are dependent on a functional type-III secretory apparatus. In addition, Shigella invasion induces the opening of Connexin 26 (Cx26) hemichannels in an actin- and phospholipase-C-dependent manner, allowing release of ATP into the medium. The released ATP, in turn, increases bacterial invasion and spreading, as well as calcium signalling induced by Shigella. These results provide evidence that pathogen-induced opening of connexin channels promotes signalling events that favour bacterial invasion and dissemination.     

Shigella IpaD has a dual role: signal transduction from the type III secretion system needle tip and intracellular secretion regulation

Type III secretion systems (T3SSs) are protein injection devices essential for the interaction of many Gram‐negative bacteria with eukaryotic cells. While Shigella assembles its T3SS when the environmental conditions are appropriate for invasion, secretion is only activated after physical contact with a host cell. First, the translocators are secreted to form a pore in the host cell membrane, followed by effectors which manipulate the host cell. Secretion activation is tightly controlled by conserved T3SS components: the needle tip proteins IpaD and IpaB, the needle itself and the intracellular gatekeeper protein MxiC. To further characterize the role of IpaD during activation, we combined random mutagenesis with a genetic screen to identify ipaD mutant strains unable to respond to host cell contact. Class II mutants have an overall defect in secretion induction. They map to IpaD's C‐terminal helix and likely affect activation signal generation or transmission. The Class I mutant secretes translocators prematurely and is specifically defective in IpaD secretion upon activation. A phenotypically equivalent mutant was found in mxiC. We show that IpaD and MxiC act in the same intracellular pathway. In summary, we demonstrate that IpaD has a dual role and acts at two distinct locations during secretion activation.     

Single amino acid substitutions on the needle tip protein IpaD increased Shigella virulence

Infection of colonic epithelial cells by Shigella is associated with the type III secretion system, which serves as a molecular syringe to inject effectors into host cells. This system includes an extracellular needle used as a conduit for secreted proteins. Two of these proteins, IpaB and IpaD, dock at the needle tip to control secretion and are also involved in the insertion of a translocation pore into host cell membrane allowing effector delivery. To better understand the function of IpaD, we substituted thirteen residues conserved among homologous proteins in other bacterial species. Generated variants were tested for their ability to surface expose IpaB and IpaD, to control secretion, to insert the translocation pore, and to invade host cells. In addition to a first group of seven ipaD variants that behaved similarly to the wild-type strain, we identified a second group with mutations V314D and I319D that deregulated secretion of all effectors, but remained fully invasive. Moreover, we identified a third group with mutations Y153A, T161D, Q165L and Y276A, that exhibited increased levels of translocators secretion, pore formation, and cell entry. Altogether, our results offer a better understanding of the role of IpaD in the control of Shigella virulence.     

The Type III Secretion Translocation Pore Senses Host Cell Contact

Type III secretion systems (T3SS) are nano-syringes used by a wide range of Gram-negative pathogens to promote infection by directly injecting effector proteins into targeted host cells. Translocation of effectors is triggered by host-cell contact and requires assembly of a pore in the host-cell plasma membrane, which consists of two translocator proteins. Our understanding of the translocation pore, how it is assembled in the host cell membrane and its precise role in effector translocation, is extremely limited. Here we use a genetic technique to identify protein-protein contacts between pore-forming translocator proteins, as well as the T3SS needle-tip, that are critical for translocon function. The data help establish the orientation of the translocator proteins in the host cell membrane. Analysis of translocon function in mutants that break these contacts demonstrates that an interaction between the pore-forming translocator PopD and the needle-tip is required for sensing host cell contact. Moreover, tethering PopD at a dimer interface also specifically prevents host-cell sensing, arguing that the translocation pore is actively involved in detecting host cell contact. The work presented here therefore establishes a signal transduction pathway for sensing host cell contact that is initiated by a conformational change in the translocation pore, and is subsequently transmitted to the base of the apparatus via a specific contact between the pore and the T3SS needle-tip.     

Deoxycholate interacts with IpaD of Shigella flexneri in inducing the recruitment of IpaB to the type III secretion apparatus needle tip

Type III secretion (TTS) is an essential virulence function for Shigella flexneri that delivers effector proteins that are responsible for bacterial invasion of intestinal epithelial cells. The Shigella TTS apparatus (TTSA) consists of a basal body that spans the bacterial inner and outer membranes and a needle exposed at the pathogen surface. At the distal end of the needle is a "tip complex" composed of invasion plasmid antigen D (IpaD). IpaD not only regulates TTS, but is required for the recruitment and stable association of the translocator protein IpaB at the TTSA needle tip in the presence of deoxycholate or other bile salts. This phenomenon is not accompanied by induction of TTS or the recruitment of IpaC to the Shigella surface. We now show that IpaD specifically binds fluorescein-labeled deoxycholate and, based on energy transfer measurements and docking simulations, this interaction appears to occur where the N-terminal domain of IpaD meets its central coiled-coil, a region that may also be involved in needle-tip interactions. TTS is initiated as a series of distinct steps and that small molecules present in the bacterial milieu are capable of inducing the first step of TSS through interactions with the needle tip protein IpaD. Furthermore, the amino acids proposed to be important for deoxycholate binding by IpaD appear to have significant roles in regulating tip complex composition and pathogen entry into host cells.     

Cytoplasmic targeting of IpaC to the bacterial pole directs polar type III secretion in Shigella

Type III secretion (T3S) systems are largely used by pathogenic gram-negative bacteria to inject multiple effectors into eukaryotic cells. Upon cell contact, these bacterial microinjection devices insert two T3S substrates into host cell membranes, forming a so-called 'translocon' that is required for targeting of type III effectors in the cell cytosol. Here, we show that secretion of the translocon component IpaC of invasive Shigella occurs at the level of one bacterial pole during cell invasion. Using IpaC fusions with green fluorescent protein variants (IpaCi), we show that the IpaC cytoplasmic pool localizes at an old or new bacterial pole, where secretion occurs upon T3S activation. Deletions in ipaC identified domains implicated in polar localization. Only polar IpaCi derivatives inhibited T3S, while IpaCi fusions with diffuse cytoplasmic localization had no detectable effect on T3S. Moreover, the deletions that abolished polar localization led to secretion defects when introduced in ipaC. These results indicate that cytoplasmic polar localization directs secretion of IpaC at the pole of Shigella, and may represent a mandatory step for T3S.     

The secreted IpaB and IpaC invasins and their cytoplasmic chaperone IpgC are required for intercellular dissemination of Shigella flexneri

Invasion of epithelial cells by Shigella flexneri involves entry and dissemination. The main effectors of entry, IpaB and IpaC, are also required for contact haemolytic activity and escape from the phagosome in infected macrophages. These proteins are stored in the cytoplasm in association with the chaperone IpgC, before their secretion by a type III secretion apparatus is activated by host cells. We used a His-tagged IpgC protein to purify IpgC-containing complexes and showed that only IpaB and IpaC are associated with IpgC. Plasmids expressing His6-IpgC either alone or together with IpaB or IpaC under the control of an IPTG-inducible lac promoter were introduced into ipgC , ipaB or ipaC mutants. Induction of expression of the recombinant plasmid-encoded proteins by IPTG allowed bacteria to enter epithelial cells, and the role of these proteins in dissemination was investigated by incubating infected cells in either the absence or the presence of IPTG. The size of plaques produced by recombinant strains on cell monolayers was regulated by IPTG, indicating that IpgC, IpaB and IpaC were each required for efficient dissemination. Electron microscopy analysis of infected cells indicated that these proteins were necessary for lysis of the membrane of the protrusions during cell-to-cell spread.     

The structures of coiled-coil domains from type III secretion system translocators reveal homology to pore-forming toxins

Many pathogenic Gram-negative bacteria utilize type III secretion systems (T3SSs) to alter the normal functions of target cells. Shigella flexneri uses its T3SS to invade human intestinal cells to cause bacillary dysentery (shigellosis) that is responsible for over one million deaths per year. The Shigella type III secretion apparatus is composed of a basal body spanning both bacterial membranes and an exposed oligomeric needle. Host altering effectors are secreted through this energized unidirectional conduit to promote bacterial invasion. The active needle tip complex of S. flexneri is composed of a tip protein, IpaD, and two pore-forming translocators, IpaB and IpaC. While the atomic structure of IpaD has been elucidated and studied, structural data on the hydrophobic translocators from the T3SS family remain elusive. We present here the crystal structures of a protease-stable fragment identified within the N-terminal regions of IpaB from S. flexneri and SipB from Salmonella enterica serovar Typhimurium determined at 2.1 Å and 2.8 Å limiting resolution, respectively. These newly identified domains are composed of extended-length (114 Å in IpaB and 71 Å in SipB) coiled-coil motifs that display a high degree of structural homology to one another despite the fact that they share only 21% sequence identity. Further structural comparisons also reveal substantial similarity to the coiled-coil regions of pore-forming proteins from other Gram-negative pathogens, notably, colicin Ia. This suggests that these mechanistically separate and functionally distinct membrane-targeting proteins may have diverged from a common ancestor during the course of pathogen-specific evolutionary events.     

Crystal structure of PrgI-SipD: insight into a secretion competent state of the type three secretion system needle tip and its interaction with host ligands

Many infectious gram-negative bacteria, including Salmonella typhimurium, require a Type Three Secretion System (T3SS) to translocate virulence factors into host cells. The T3SS consists of a membrane protein complex and an extracellular needle together that form a continuous channel. Regulated secretion of virulence factors requires the presence of SipD at the T3SS needle tip in S. typhimurium. Here we report three-dimensional structures of individual SipD, SipD in fusion with the needle subunit PrgI, and of SipD:PrgI in complex with the bile salt, deoxycholate. Assembly of the complex involves major conformational changes in both SipD and PrgI. This rearrangement is mediated via a π bulge in the central SipD helix and is stabilized by conserved amino acids that may allow for specificity in the assembly and composition of the tip proteins. Five copies each of the needle subunit PrgI and SipD form the T3SS needle tip complex. Using surface plasmon resonance spectroscopy and crystal structure analysis we found that the T3SS needle tip complex binds deoxycholate with micromolar affinity via a cleft formed at the SipD:PrgI interface. In the structure-based three-dimensional model of the T3SS needle tip, the bound deoxycholate faces the host membrane. Recently, binding of SipD with bile salts present in the gut was shown to impede bacterial infection. Binding of bile salts to the SipD:PrgI interface in this particular arrangement may thus inhibit the T3SS function. The structures presented in this study provide insight into the open state of the T3SS needle tip. Our findings present the atomic details of the T3SS arrangement occurring at the pathogen-host interface.