Agrobacterium tumefaciens Type IV Secretion Protein VirB3 Is an Inner Membrane Protein and Requires VirB4, VirB7, and VirB8 for Stabilization

Agrobacterium tumefaciens VirB proteins assemble a type IV secretion apparatus and a T-pilus for secretion of DNA and proteins into plant cells. The pilin-like protein VirB3, a membrane protein of unknown topology, is required for the assembly of the T-pilus and for T-DNA secretion. Using PhoA and green fluorescent protein (GFP) as periplasmic and cytoplasmic reporters, respectively, we demonstrate that VirB3 contains two membrane-spanning domains and that both the N and C termini of the protein reside in the cytoplasm. Fusion proteins with GFP at the N or C terminus of VirB3 were fluorescent and, like VirB3, localized to a cell pole. Biochemical fractionation studies demonstrated that VirB3 proteins encoded by three Ti plasmids, the octopine Ti plasmid pTiA6NC, the supervirulent plasmid pTiBo542, and the nopaline Ti plasmid pTiC58, are inner membrane proteins and that VirB4 has no effect on membrane localization of pTiA6NC-encoded VirB3 (pTiA6NC VirB3). The pTiA6NC and pTiBo542 VirB2 pilins, like VirB3, localized to the inner membrane. The pTiC58 VirB4 protein was earlier found to be essential for stabilization of VirB3. Stabilization of pTiA6NC VirB3 requires not only VirB4 but also two additional VirB proteins, VirB7 and VirB8. A binary interaction between VirB3 and VirB4/VirB7/VirB8 is not sufficient for VirB3 stabilization. We hypothesize that bacteria use selective proteolysis as a mechanism to prevent assembly of unproductive precursor complexes under conditions that do not favor assembly of large macromolecular structures.Bacteria use type IV secretion (T4S) to deliver macromolecules to prokaryotes and eukaryotes (12). Animal and human pathogens deliver proteins to their eukaryotic hosts to affect cellular processes causing disease. The plant-pathogenic bacterium Agrobacterium tumefaciens delivers both proteins and DNA to plants and other eukaryotes. DNA delivered by Agrobacterium directs constitutive synthesis of phytohormones in a transformed plant cell, promoting cancerous growth (56). The Ptl toxin of Bordetella pertussis modifies G proteins by ADP-ribosylation, affecting intracellular cell signaling, and CagA of Helicobacter pylori disrupts epithelial cell polarity by inhibiting PAR1 kinase activity (37, 44, 47). T4S is ancestrally related to bacterial conjugation, a mechanism used by bacteria for interbacterial plasmid transfer, enabling them to acquire novel genes for antibiotic resistance, degradation of organic molecules, toxin production, and other virulence traits (29).The VirD4/VirB family of proteins, found conserved in many alphaproteobacteria, mediates T4S (12). The Ti plasmid-encoded Agrobacterium T4S system requires VirD4 and 11 VirB proteins, VirB1 to VirB11, for efficient DNA transfer (7, 54). The membrane and membrane-associated VirB proteins assemble a macromolecular structure at the cell membrane to promote substrate transfer (12). The octopine Ti plasmid pTiA6NC-encoded VirB6 to VirB11 proteins assemble the T4S apparatus at a cell pole (34, 35, 39). The VirD4 coupling protein targets the VirE2 substrate protein to the cell pole (4). A recent study found that the nopaline Ti plasmid pTiC58 T4S system (T4SS) and its substrates form a helical array around the cell circumference (1). Structural studies using Escherichia coli conjugative plasmid pKM101-encoded VirB homologues showed that TraN (VirB7), TraO (VirB9), and TraF (VirB10) form the core complex and that TraF forms a channel at the outer membrane (11, 23). The Agrobacterium VirB proteins assemble a T-pilus, an appendage composed primarily of VirB2, with VirB5 and VirB7 as its minor constituents (38, 40, 41, 48, 50, 55). VirB3, a homolog of the pilin-like TraL protein encoded in E. coli plasmids, is postulated to function in T-pilus assembly (52). Three ATP-utilizing proteins, VirB4, VirB11, and VirD4, supply energy for substrate translocation (3, 9, 34).The membrane topology of all the VirB proteins, except for VirB3, was determined by analyses of random phoA insertion mutants, targeted phoA fusions, and targeted bla fusions (6, 14, 15, 21, 22, 31, 35, 53). phoA and bla, which encode alkaline phosphatase and β-lactamase, respectively, serve as excellent markers for periplasmic proteins, as they are enzymatically active only when targeted to the cell periplasm (8, 30). Green fluorescent protein (GFP) is an ideal cytoplasmic marker because it fluoresces only when located in the cytoplasm (19, 20). When GFP is targeted to the periplasm through fusion with a membrane-spanning domain (MSD), it fails to fold properly and does not fluoresce.The prevailing view, based on in silico analysis, is that VirB3 is a bitopic membrane protein with a periplasmic C terminus. No phoA-positive insertions in virB3, however, were identified in two random mutagenesis studies of the virB operon (6, 15). The small size of VirB3, a polypeptide of 108 amino acids (aa), could be a contributing factor to the negative findings. Yet several PhoA-positive insertions in two smaller VirB proteins, VirB2 (74-aa mature peptide) and VirB7 (41-aa mature peptide), were successfully obtained in both studies. Therefore, the negative findings may also be indicative of the presence of a small periplasmic domain in VirB3. Biochemical studies showed that the nopaline Ti plasmid pTiC58-encoded VirB3 protein (pTiC58 VirB3) associates with the bacterial outer membrane, while VirB2 associates with both the inner and outer membranes (52). The pTiC58 VirB4 protein is required for localization of VirB3 to the outer membrane (33). VirB4 is also required for VirB3 stability (33, 55). A low level of VirB3 accumulated in a nonpolar pTiC58 virB6 deletion mutant; however, addition of virB6 in trans did not restore the level of the protein, even though it restored tumorigenicity (27). VirB3 participates in the formation of protein complexes with the T-pilus proteins VirB2 and VirB5 (55).Homologues of VirB3 are found in many alphaproteobacteria with a T4SS. While most VirB3 homologues are small proteins, several recently identified homologues are fusions of VirB3 and the immediate downstream protein VirB4 (5, 10, 24). These fusion homologs, which include Actinobacillus MagB03 (GenBank accession no. {"type":"entrez-protein","attrs":{"text":"AAG24434","term_id":"10880920","term_text":"AAG24434"}}AAG24434), Campylobacter CmgB3/4 ({"type":"entrez-protein","attrs":{"text":"EAQ71805","term_id":"87248841","term_text":"EAQ71805"}}EAQ71805), Yersinia pseudotuberculosis TriC ({"type":"entrez-protein","attrs":{"text":"CAF25448","term_id":"51591645","term_text":"CAF25448"}}CAF25448), Citrobacter koseri PilX3-4 ({"type":"entrez-protein","attrs":{"text":"ABV12046","term_id":"157082368","term_text":"ABV12046"}}ABV12046), and Klebsiella pneumoniae PilX3-4 ({"type":"entrez-protein","attrs":{"text":"BAF49490","term_id":"134048868","term_text":"BAF49490"}}BAF49490), have VirB3 at the N terminus and VirB4 at the C terminus. Agrobacterium VirB4 is an integral membrane protein with a cytoplasmic N terminus (14). Its homologues are expected to have a similar topology. The prevailing view that pTi VirB3 has a periplasmic C terminus is inconsistent with the cytoplasmic location of the N terminus of VirB4 in the VirB3-VirB4 fusion protein homologues.In this study, we report the membrane topology of Agrobacterium VirB3 and demonstrate that the C terminus of the protein resides in the cytoplasm. We also demonstrate that VirB3 is an inner membrane protein, not an outer membrane protein as previously reported (52). The octopine Ti plasmid pTiA6NC VirB4 protein does not affect membrane localization of VirB3 but does stabilize VirB3. VirB4, however, is not sufficient for pTiA6NC VirB3 stabilization. Two additional proteins, VirB7 and VirB8, are required for the stabilization of pTiA6NC VirB3.     

Evidence for VirB4-Mediated Dislocation of Membrane-Integrated VirB2 Pilin during Biogenesis of the Agrobacterium VirB/VirD4 Type IV Secretion System

Agrobacterium VirB2 pilin is required for assembly of the VirB/VirD4 type IV secretion system (T4SS). The propilin is processed by signal sequence cleavage and covalent linkage of the N and C termini, and the cyclized pilin integrates into the inner membrane (IM) as a pool for assembly of the secretion channel and T pilus. Here, by use of the substituted cysteine accessibility method (SCAM), we defined the VirB2 IM topology and then identified distinct contributions of the T4SS ATPase subunits to the pilin structural organization. Labeling patterns of Cys-substituted pilins exposed to the membrane-impermeative, thiol-reactive reagent 3-(N-maleimidopropionyl)biocytin (MPB) supported a topology model in which two hydrophobic stretches comprise transmembrane domains, an intervening hydrophilic loop (residues 90 to 94) is cytoplasmic, and the hydrophilic N and C termini joined at residues 48 and 121 form a periplasmic loop. Interestingly, the VirB4 ATPase, but not a Walker A nucleoside triphosphate (NTP) binding motif mutant, induced (i) MPB labeling of Cys94, a residue that in the absence of the ATPase is located in the cytoplasmic loop, and (ii) release of pilin from the IM upon osmotic shock. These findings, coupled with evidence for VirB2-VirB4 complex formation by coimmunoprecipitation, support a model in which VirB4 functions as a dislocation motor to extract pilins from the IM during T4SS biogenesis. The VirB11 ATPase functioned together with VirB4 to induce a structural change in the pilin that was detectable by MPB labeling, suggestive of a role for VirB11 as a modulator of VirB4 dislocase activity.The Agrobacterium tumefaciens VirB/VirD4 type IV secretion system (T4SS) delivers effector proteins and DNA to plant cells during infection (1, 14). The 11 VirB proteins and VirD4 substrate receptor mediate assembly of the envelope-spanning translocation channel, whereas the VirB proteins independently of VirD4 are required for polymerization of the extracellular T pilus (6, 32, 46). These T4SS subunits include the three ATPases VirD4, VirB4, and VirB11; a trans-envelope core complex comprised of VirB7, VirB9, and VirB10; subunits involved in assembly or spatial positioning of the core complex (VirB1, VirB6, and VirB8); and other structural components (VirB2 pilin, VirB3, and pilus-associated VirB5) (1, 14, 43, 48, 55, 70). The VirB/VirD4 subunits are conserved among many Gram-negative bacterial T4SSs, and recent structures of homologs of VirD4, VirB5, VirB8, VirB10, and VirB11 and a VirB7/VirB9/VirB10 machine subassembly are supplying exciting new information about T4SS machine architectures (11, 28, 29).The pilin subunit VirB2 is a component of both the secretion channel and T pilus (39, 47, 48). Its role in substrate transfer was established with a modified chromatin immunoprecipitation (ChIP) assay termed transfer DNA (T-DNA) immunoprecipitation (TrIP), wherein the pilin (but not the T pilus) was shown to form formaldehyde-cross-linkable contacts with the translocating T-DNA substrate (10). TrIP studies with virB mutant strains also supplied evidence that VirB2 occupies a distal portion of the translocation channel near or at the outer membrane (OM) (10). Complementary genetic studies identified mutations in several VirB subunits, including VirB6, VirB9, VirB10, and VirB11, that selectively block T pilus production without affecting substrate transfer (39, 40, 41, 62). These Tra⁺ Pil⁻ “uncoupling” mutations do not bypass the requirement for VirB2 production for substrate transfer, as the further deletion of virB2 from the Tra⁺ Pil⁻ mutant strains renders these strains transfer defective (39, 41, 62). Therefore, VirB2 pilin, but not an intact T pilus, is required for passage of substrates to target cells.The pathways culminating in the integration of VirB2 into the two terminal organelles, the secretion channel and T pilus, are fundamentally poorly understood. The early VirB protein-independent reactions involve insertion of the 12.3-kDa propilin into the inner membrane (IM); cleavage of a long, 47-residue signal sequence, presumably by LepB signal peptidase; and covalent joining of the N-terminal Gln48 and C-terminal Ser121 to form the mature, cyclic pilin (24). This unusual head-to-tail cyclization reaction was also shown for the VirB2 homolog, TrbC (24/51% sequence identity/similarity) of plasmid RP4 (24, 34, 44). Other VirB2 homologs, such as F plasmid TraA (19/47% identity/similarity) (67), remain linear although their N termini are modified by N acetylation (54).Prevailing models suggest that mature forms of conjugative pilins accumulate in the IM as pools for use in assembly of the channel/pilus upon receipt of an unknown morphogenetic signal(s). The IM-integrated VirB2, TraA_F, and TrbC_RP4 pilins likely adopt similar topologies, as deduced from similar predicted secondary structures and results of reporter fusion studies with periplasmically active alkaline phosphatase (PhoA) (5, 22, 56). Two hydrophobic domains are thought to orient across the IM so that a small, intervening hydrophilic loop is cytoplasmic and the hydrophilic N and C termini are periplasmic. Detailed studies confirming this overall topology are lacking, and limited information exists regarding the nature of pilin interactions with other T4SS subunits (36, 51). Furthermore, little is known about the mechanism or energetic requirements for dislocation of membrane-integrated forms of conjugative pilins during machine morphogenesis.In A. tumefaciens, mutations in the Walker A nucleoside triphosphate (NTP) binding site motifs of the VirB4 and VirB11 ATPases render cells defective for substrate transfer and pilus production, indicating that NTP energy consumption by both ATPases is essential for assembly of the two terminal organelles (6, 7, 58, 62, 68). VirB4-like subunits are signatures of all T4SSs described to date, whereas VirB11-like proteins are common but not ubiquitous among the T4SSs (1). Some T4SSs, such as the conjugation machines encoded by Escherichia coli F-like plasmids, lack VirB11 homologs, and yet their conjugative pili extend and retract dynamically by a mechanism(s) dependent on VirB4 homologs (18, 65). On the basis of these observations, it is reasonable to propose that the VirB4-like subunits catalyze early reactions associated with assembly of conjugative pili.Here, we used the scanning cysteine accessibility method (SCAM) (9) to define the IM topology of cyclized VirB2. We then assayed for contributions of VirB subunits to the pilin structural organization. We present biochemical evidence for VirB4-mediated dislocation of VirB2 pilin from the membrane and also for a contribution by VirB11 in modulating pilin tertiary or quaternary structure. We discuss our findings in the context of recent advances in our understanding of T4SS machine assembly and architecture.     

Interactions between Brucella suis VirB8 and Its Homolog TraJ from the Plasmid pSB102 Underline the Dynamic Nature of Type IV Secretion Systems

The proteinVirB8 plays a critical role in the assembly and function of the Agrobacterium tumefaciens virB type IV secretion system (T4SS). The structure of the periplasmic domain of both A. tumefaciens and Brucella suis VirB8 has been determined, and site-directed mutagenesis has revealed amino acids involved in the dimerization of VirB8 and interactions with VirB4 and VirB10. We have shown previously that TraJ, the VirB8 homologue from pSB102, and the chimeric protein TraJB8, encompassing the cytoplasmic and transmembrane (TM) domains of TraJ and the periplasmic domain of VirB8, were unable to complement a B. suis mutant containing an in-frame deletion of the virB8 gene. This suggested that the presence of the TraJ cytoplasmic and TM domains could block VirB8 dimerization or assembly in the inner membrane. By bacterial two-hybrid analysis, we found that VirB8, TraJ, and the chimeras can all interact to form both homo- and heterodimers. However, the presence of the TM domain of TraJ resulted in much stronger interactions in both the homo- and heterodimers. We expressed the wild-type and chimeric proteins in wild-type B. suis. The presence of proteins carrying the TM domain of TraJ had a dominant negative effect, leading to complete loss of virulence. This suggests that the T4SS is a dynamic structure and that strong interactions block the spatial flexibility required for correct assembly and function.Brucellosis is a major worldwide zoonosis primarily affecting developing countries and causing them severe economic losses (7). Bacteria of the genus Brucella, the causative agent, are gram-negative facultative intracellular pathogens of various wild and domestic mammals, as well as humans, where it causes a very debilitating disease known as Malta fever (48). In addition, these bacteria are also a focus of concern as possible biological warfare agents (23).The key aspect of Brucella virulence is its ability to survive and proliferate within professional and nonprofessional phagocytes (7). Once phagocytosed, this bacteria subverts the vesicular traffic in the host cell to establish a niche in a compartment derived from the endoplasmic reticulum, where it multiplies (3, 34, 39, 40, 41). Several factors have been reported to be essential for the virulence of this bacterium (16, 17, 18, 19, 21, 22, 29, 31). Strikingly, we (36) and others (44) have demonstrated the presence in Brucella of a type IV secretion system (T4SS) that is encoded by the virB operon and whose integrity is required for virulence (8, 14, 19). Several other species of gram-negative bacteria have been found to rely on the presence of a T4SS for full virulence (10, 13). Both extracellular (Helicobacter) and intracellular (Legionella, Bartonella) pathogens use their T4SSs to inject effector proteins directly into the target cell, where they affect the biology of the cell. Bordetella pertussis uses its T4SS to secrete the pertussis toxin into the extracellular medium, where it is taken up by cells. The T4SS of Agrobacterium tumefaciens translocates both effector proteins and a nucleoprotein complex into target plant cells through a mechanism reminiscent of bacterial conjugation through T4SS.The A. tumefaciens VirB T4SS, which is considered the T4SS paradigm, is composed of 11 different proteins named VirB1 to VirB11 plus VirD4. These proteins can be functionally subdivided in three different groups. The proteins VirB4, VirB11, and VirD4 are inner membrane ATPases with a large cytoplasmic domain and are believed to provide the energy required for T4SS assembly and for the translocation of effectors. VirB2 and VirB5 form an extracellular bacterial appendage believed to anchor the bacteria to the host cell (4, 25). Finally, VirB3 and VirB6 to VirB10 are believed to form a channel-like structure spanning both the inner and outer membranes of the bacteria.Among these structural proteins, VirB8 has been shown to play a key role in the assembly of the T4SS. Recent studies with A. tumefaciens demonstrated that VirB8 acts as a nucleation center required to recruit VirB9 and VirB10 into clusters in the outer membrane (15, 30) and to localize VirB proteins at the cell pole (26). VirB8 is a protein spanning the bacterial inner membrane, with the first 67 amino acids forming a short cytoplasmic tail, followed by a single hydrophobic transmembrane (TM) domain. The carboxy-terminal moiety of the protein, of 172 amino acids, is believed to be entirely periplasmic. Recently, the three-dimensional structures of the periplasmic domains of VirB8 from Brucella suis (46) and A. tumefaciens (5) have been determined. Using these structural data, site-directed mutagenesis has been performed on the periplasmic part of B. suis VirB8, showing that changes in amino acids that inhibit the dimerization of VirB8 or its interactions with VirB4 or VirB10 also affect T4SS assembly and B. suis virulence (37). Among all of the homologs of B. suis VirB8, the closest are the proteins TraJ, encoded in the tra operons of broad-host-range plasmids pSB102 and pIPO2 (43, 45). The TraJ protein from pSB102 shares more than 50% identity with B. suis VirB8 at the amino acid level, and this percentage increases to more than 60% when only the periplasmic domain is considered. In a previous study, we have taken advantage of this close similarity between VirB8 and TraJ to examine the possibility of a functional heterologous complementation of VirB8 by TraJ in BS1008, a B. suis mutant carrying an in-frame deletion of the virB8 gene (38). From our results, it appeared that the protein TraJ was unable to complement BS1008. As the major similarities between VirB8 and TraJ were found in their respective periplasmic domains, we constructed chimeric genes encoding proteins in which the major part of the periplasmic domain of one protein (amino acids 77 to 241 of TraJ and amino acids 76 to 239 of VirB8) was replaced with the corresponding part of the other protein (these proteins are described in Fig. ​Fig.1)1) and studied the ability of these chimeric proteins to restore the virulence of BS1008. The TraJB8 chimera, where the periplasmic part of VirB8 replaces the corresponding part of TraJ, was also unable to complement BS1008. In contrast, B8TraJ, the reverse chimera in which the periplasmic part of TraJ replaces the corresponding part of VirB8, partially restored the virulence of BS1008. These results show that, when fused to the cytoplasmic and TM parts of VirB8, the periplasmic part of TraJ can functionally replace the corresponding part of VirB8 in T4SS assembly. In contrast, the cytoplasmic and TM parts of TraJ cannot replace the corresponding part of VirB8, whether fused to the periplasmic part of TraJ or VirB8. To further elucidate these points, we undertook a more detailed study of the interactions of these proteins by bacterial two-hybrid (BACTH) analysis. Here we show that the proteins VirB8, B8TraJ, TraJB8, and TraJ display strikingly different abilities to interact with themselves, as well as with VirB8 itself. Further, the TM domain of these proteins plays a crucial role in determining the strength of these interactions. Finally we show that, when overexpressed in a wild-type B. suis strain, these various proteins are able to modulate its virulence, even leading to complete loss of virulence. These data give interesting clues concerning the mechanisms of type IV secretion.Open in a separate windowFIG. 1.Schematic representation of the proteins used in this study. Light and dark gray parts represent protein domains from VirB8 and TraJ, respectively. All proteins were synthesized as fusion proteins with the T18 or T25 subunit of the B. pertussis adenylate cyclase domain fused to the amino-terminal end of the VirB8- and/or TraJ-containing part. In the case of the periplasmic domains of VirB8 (VirB8p) and TraJ (TraJp), synthesis of these proteins as fusions with the subunits of B. pertussis adenylate cyclase likely targets them to the bacterial cytoplasm, as suggested by fractionation studies. The rightmost column indicates whether the corresponding proteins have (+) or have not (−) been detected in Western blotting experiments.     

Essential Role of the SycP Chaperone in Type III Secretion of the YspP Effector

The Ysa type III secretion (T3S) system enhances gastrointestinal infection by Yersinia enterocolitica bv. 1B. One effector protein targeted into host cells is YspP, a protein tyrosine phosphatase. It was determined in this study that the secretion of YspP requires a chaperone, SycP. Genetic analysis showed that deletion of sycP completely abolished the secretion of YspP without affecting the secretion of other Ysps by the Ysa T3S system. Analysis of the secretion and translocation signals of YspP defined the first 73 amino acids to form the minimal region of YspP necessary to promote secretion and translocation by the Ysa T3S system. Function of the YspP secretion/translocation signals was dependent on SycP. Curiously, when YspP was constitutively expressed in Y. enterocolitica bv. 1B, it was recognized and secreted by the Ysc T3S system and the flagellar T3S system. In these cases, the first 21 amino acids were sufficient to promote secretion, and while SycP did enhance secretion, it was not essential. However, neither the Ysc T3S system nor the flagellar T3S system translocated YspP into mammalian cells. This supports a model where SycP confers secretion/translocation specificities for YspP by the Ysa T3S system. A series of biochemical approaches further established that SycP specifically interacts with YspP and protected YspP degradation in the cell prior to secretion. Collectively, the evidence suggests that YspP secretion by the Ysa T3S system is a posttranslational event.Many gram-negative bacteria have evolved sophisticated delivery systems termed type III secretion (T3S) systems to transport effector proteins into the cytosols of eukaryotic host cells (10, 21, 22). The translocated effectors manipulate host cell activities in various ways, thereby permitting the establishment of a pathogenic or symbiotic interaction (20). T3S systems are ancestrally related to the flagellar T3S system, having in common a basal body spanning the inner and outer bacterial membranes responsible for the appropriate selection of polypeptides delivered into a hollow channel leading out of the bacterium. At the outer surface, flagellar polypeptides travel the length of the adjoining hook and filament, but in T3S systems, the secreted polypeptides pass through a special hollow needle that extends away from the bacterium to the targeted host cell (10, 21, 22). Heterologous multimeric proteins localized to the tip of the needle form the translocon, a porelike channel that is assembled in the eukaryotic plasma membrane, enabling the injection of bacterial effectors (24, 48, 51).Two terminologies are distinctly used to describe protein transport by T3S systems. While “secretion” is a transport event for proteins from the bacterial cytosol into the extracellular milieu, “translocation” is a transport event for proteins from the bacterial cytosol into the eukaryotic host''s cytosol. Generally, secretion but not translocation is mediated by the first 20 amino acids of effector proteins (41, 46, 47), albeit mRNA sequences at the N terminus of some proteins have been also considered to function as the secretion signals (3, 44). This secretion event is independent of the presence of cognate effector chaperones (46, 59). Despite no conservation of the amino acids among the secretion signals, amphipathic or disordered secondary structures of the peptides are thought to function as the secretion signals recognized by the T3S apparatuses (22, 34, 35). In contrast, translocation usually requires both the secretion (the first 20 amino acids) and the translocation (amino acids 20 to 100) signals (46, 47, 59). This translocation event is efficiently mediated by the presence of the cognate chaperones (9, 14, 30), and the chaperone-effector complexes have been proposed to function as the three-dimensional signals recognized by the T3S apparatuses (5, 33, 38, 49, 50).Many T3S effectors employ cognate chaperones in the bacterial cytoplasm (43, 57). The effector chaperones have been categorized into two subgroups, class 1A and class 1B, primarily based on the substrate properties (and the gene locations) (13, 43). Class 1A chaperones commonly bind to one effector, and most of them are encoded by genes located adjacent to the gene encoding the cognate effectors. In contrast, class 1B chaperones bind to multiple effectors and are encoded by genes located within operons that code for structural components of the T3S apparatus that are distant to the cognate effector genes. Evolutionally, this subgroup of chaperones is thought to be an archetype of effector chaperones. Although T3S effector chaperones lack primary sequence similarity even in same subgroup, overall the effector chaperones whose three-dimensional structures are solved share similar folds, consisting of three α-helices and five β-strands (5, 36, 38, 49, 54). Similarly, effector chaperones share the common biochemical characteristics of acidic properties (pI 4 to 5) and low molecular masses (12 to 15 kDa), with a tendency to form homodimers (43). These homodimers recognize the chaperone binding domains (CBD) of the cognate effectors, which are usually located in the amino-terminal 20 to 100 amino acids (translocation signal) of the effector (19, 30, 59). Despite the wealth of information about individual chaperones, a universally accepted model for the mechanisms by which they promote secretion is lacking. One study shows that the guidance of chaperone-effector complexes toward the T3S apparatus is provided by the affinity of their chaperones to the ATPase of the T3S apparatus, whereby the ATPase releases the chaperones from the complexes and then unfolds the cognate effector for secretion (2). Several additional functions of T3S effector chaperones have been reported, including the prevention of effector aggregation prior to delivery to the secretion system, limitation of premature interactions, and protection of effectors from protease degradation in bacterial cells (17, 43). When an organism has multiple T3S pathways, as is the case for some Yersinia spp., there is the opportunity to gain new insight into how a given chaperone might influence T3S system specificity for substrates. Without direct testing of the aforementioned mechanistic models, the role of a chaperone in T3S and how it affects the overall sequence of pathogenic events is, at best, a conjecture.Highly virulent strains of Yersinia enterocolitica bv. 1B have a total of three T3S systems. The first T3S system (Ysc) is encoded by the virulence plasmid, and it secretes six effectors termed Yops. Ysc T3S is important for systemic infection (11, 12, 42). This T3S system is common to all Yersinia species pathogenic to humans, including another enteropathogen, Yersinia pseudotuberculosis, and the plague pathogen Yersinia pestis. The second system (Ysa) is encoded by a cluster of genes mapping to the Ysa pathogenicity island (25, 53). The Ysa T3S system secretes a set of eight effectors termed Ysps and, interestingly, also secretes three Yops, YopE, YopN, and YopP/YopJ (39, 58, 61). This Ysa T3S system is restricted to clinical isolates of Y. enterocolitica bv. 1B and promotes the initial establishment of infection in gastrointestinal tissue (39, 55). The third T3S system is an integral part of the flagellum and secretes proteins termed Fops to the extracellular milieu (64).Previously, we identified the suite of Ysp proteins secreted by the Ysa T3S system (39). However, little is known about the detailed mechanism by which these proteins are secreted and translocated by this system. Among the Ysp proteins identified, YspP is a protein tyrosine phosphatase (PTPase) whose activity is required for full virulence (39). Here, we found a small open reading frame (ORF) immediately downstream of yspP and designated it sycP. The SycP protein was demonstrated to be a YspP-specific chaperone essential for both the secretion and the translocation of YspP by the Ysa T3S system. In addition, we also examined the secretion specificity requirements for YspP secretion by three different T3S systems as model cases. Interestingly, our data suggest that the mechanisms by which the secretion and translocation signals are recognized are different, depending on the type of T3S system examined.     

Conjugative Plasmid Transfer and Adhesion Dynamics in an Escherichia coli Biofilm

A conjugative plasmid from the catheter-associated urinary tract infection strain Escherichia coli MS2027 was sequenced and annotated. This 42,644-bp plasmid, designated pMAS2027, contains 58 putative genes and is most closely related to plasmids belonging to incompatibility group X (IncX1). Plasmid pMAS2027 encodes two important virulence factors: type 3 fimbriae and a type IV secretion (T4S) system. Type 3 fimbriae, recently found to be functionally expressed in E. coli, played an important role in biofilm formation. Biofilm formation by E. coli MS2027 was specifically due to expression of type 3 fimbriae and not the T4S system. The T4S system, however, accounted for the conjugative ability of pMAS2027 and enabled a non-biofilm-forming strain to grow as part of a mixed biofilm following acquisition of this plasmid. Thus, the importance of conjugation as a mechanism to spread biofilm determinants was demonstrated. Conjugation may represent an important mechanism by which type 3 fimbria genes are transferred among the Enterobacteriaceae that cause device-related infections in nosocomial settings.Bacterial biofilms are complex communities of bacterial cells living in close association with a surface (17). Bacterial cells in these protected environments are often resistant to multiple factors, including antimicrobials, changes in the pH, oxygen radicals, and host immune defenses (19, 38). Biofilm formation is a property of many bacterial species, and a range of molecular mechanisms that facilitate this process have been described (2, 3, 11, 14, 16, 29, 33, 34). Often, the ability to form a biofilm is dependent on the production of adhesins on the bacterial cell surface. In Escherichia coli, biofilm formation is enhanced by the production of certain types of fimbriae (e.g., type 1 fimbriae, type 3 fimbriae, F1C, F9, curli, and conjugative pili) (14, 23, 25, 29, 33, 39, 46), cell surface adhesins (e.g., autotransporter proteins such as antigen 43, AidA, TibA, EhaA, and UpaG) (21, 34, 35, 40, 43), and flagella (22, 45).The close proximity of bacterial cells in biofilms creates an environment conducive for the exchange of genetic material. Indeed, plasmid-mediated conjugation in monospecific and mixed E. coli biofilms has been demonstrated (6, 18, 24, 31). The F plasmid represents the best-characterized conjugative system for biofilm formation by E. coli. The F pilus mediates adhesion to abiotic surfaces and stabilizes the biofilm structure through cell-cell interactions (16, 30). Many other conjugative plasmids also contribute directly to biofilm formation upon derepression of the conjugative function (16).One example of a conjugative system employed by gram-negative Enterobacteriaceae is the type 4 secretion (T4S) system. The T4S system is a multisubunit structure that spans the cell envelope and contains a secretion channel often linked to a pilus or other surface filament or protein (8). The Agrobacterium tumefaciens VirB-VirD4 system is the archetypical T4S system and is encoded by 11 genes in the virB operon and one gene (virD4) in the virD operon (7, 8). Genes with strong homology to genes in the virB operon have also been identified on other conjugative plasmids. For example, the pilX1 to pilX11 genes on the E. coli R6K IncX plasmid and the virB1 to virB11 genes are highly conserved at the nucleotide level (28).We recently described identification and characterization of the mrk genes encoding type 3 fimbriae in a uropathogenic strain of E. coli isolated from a patient with a nosocomial catheter-associated urinary tract infection (CAUTI) (29). The mrk genes were located on a conjugative plasmid (pMAS2027) and were strongly associated with biofilm formation. In this study we determined the entire sequence of plasmid pMAS2027 and revealed the presence of conjugative transfer genes homologous to the pilX1 to pilX11 genes of E. coli R6K (in addition to the mrk genes). We show here that biofilm formation is driven primarily by type 3 fimbriae and that the T4S apparatus is unable to mediate biofilm growth in the absence of the mrk genes. Finally, we demonstrate that conjugative transfer of pMAS2027 within a mixed biofilm confers biofilm formation properties on recipient cells due to acquisition of the type 3 fimbria-encoding mrk genes.     

An IcmF Family Protein,ImpLM, Is an Integral Inner Membrane Protein Interacting with ImpKL,and Its Walker A Motif Is Required for Type VI Secretion System-Mediated Hcp Secretion in Agrobacterium tumefaciens

An intracellular multiplication F (IcmF) family protein is a conserved component of a newly identified type VI secretion system (T6SS) encoded in many animal and plant-associated Proteobacteria. We have previously identified ImpL_M, an IcmF family protein that is required for the secretion of the T6SS substrate hemolysin-coregulated protein (Hcp) from the plant-pathogenic bacterium Agrobacterium tumefaciens. In this study, we characterized the topology of ImpL_M and the importance of its nucleotide-binding Walker A motif involved in Hcp secretion from A. tumefaciens. A combination of β-lactamase-green fluorescent protein fusion and biochemical fractionation analyses revealed that ImpL_M is an integral polytopic inner membrane protein comprising three transmembrane domains bordered by an N-terminal domain facing the cytoplasm and a C-terminal domain exposed to the periplasm. impL_M mutants with substitutions or deletions in the Walker A motif failed to complement the impL_M deletion mutant for Hcp secretion, which provided evidence that ImpL_M may bind and/or hydrolyze nucleoside triphosphates to mediate T6SS machine assembly and/or substrate secretion. Protein-protein interaction and protein stability analyses indicated that there is a physical interaction between ImpL_M and another essential T6SS component, ImpK_L. Topology and biochemical fractionation analyses suggested that ImpK_L is an integral bitopic inner membrane protein with an N-terminal domain facing the cytoplasm and a C-terminal OmpA-like domain exposed to the periplasm. Further comprehensive yeast two-hybrid assays dissecting ImpL_M-ImpK_L interaction domains suggested that ImpL_M interacts with ImpK_L via the N-terminal cytoplasmic domains of the proteins. In conclusion, ImpL_M interacts with ImpK_L, and its Walker A motif is required for its function in mediation of Hcp secretion from A. tumefaciens.Many pathogenic gram-negative bacteria employ protein secretion systems formed by macromolecular complexes to deliver proteins or protein-DNA complexes across the bacterial membrane. In addition to the general secretory (Sec) pathway (18, 52) and twin-arginine translocation (Tat) pathway (7, 34), which transport proteins across the inner membrane into the periplasm, at least six distinct protein secretion systems occur in gram-negative bacteria (28, 46, 66). These systems are able to secrete proteins from the cytoplasm or periplasm to the external environment or the host cell and include the well-documented type I to type V secretion systems (T1SS to T5SS) (10, 15, 23, 26, 30) and a recently discovered type VI secretion system (T6SS) (4, 8, 22, 41, 48, 49). These systems use ATPase or a proton motive force to energize assembly of the protein secretion machinery and/or substrate translocation (2, 6, 41, 44, 60).Agrobacterium tumefaciens is a soilborne pathogenic gram-negative bacterium that causes crown gall disease in a wide range of plants. Using an archetypal T4SS (9), A. tumefaciens translocates oncogenic transferred DNA and effector proteins to the host and ultimately integrates transferred DNA into the host genome. Because of its unique interkingdom DNA transfer, this bacterium has been extensively studied and used to transform foreign DNA into plants and fungi (11, 24, 40, 67). In addition to the T4SS, A. tumefaciens encodes several other secretion systems, including the Sec pathway, the Tat pathway, T1SS, T5SS, and the recently identified T6SS (72). T6SS is highly conserved and widely distributed in animal- and plant-associated Proteobacteria and plays an important role in the virulence of several human and animal pathogens (14, 19, 41, 48, 56, 63, 74). However, T6SS seems to play only a minor role or even a negative role in infection or virulence of the plant-associated pathogens or symbionts studied to date (5, 37-39, 72).T6SS was initially designated IAHP (IcmF-associated homologous protein) clusters (13). Before T6SS was documented by Pukatzki et al. in Vibrio cholerae (48), mutations in this gene cluster in the plant symbiont Rhizobium leguminosarum (5) and the fish pathogen Edwardsiella tarda (51) caused defects in protein secretion. In V. cholerae, T6SS was responsible for the loss of cytotoxicity for amoebae and for secretion of two proteins lacking a signal peptide, hemolysin-coregulated protein (Hcp) and valine-glycine repeat protein (VgrG). Secretion of Hcp is the hallmark of T6SS. Interestingly, mutation of hcp blocks the secretion of VgrG proteins (VgrG-1, VgrG-2, and VgrG-3), and, conversely, vgrG-1 and vgrG-2 are both required for secretion of the Hcp and VgrG proteins from V. cholerae (47, 48). Similarly, a requirement of Hcp for VgrG secretion and a requirement of VgrG for Hcp secretion have also been shown for E. tarda (74). Because Hcp forms a hexameric ring (41) stacked in a tube-like structure in vitro (3, 35) and VgrG has a predicted trimeric phage tail spike-like structure similar to that of the T4 phage gp5-gp27 complex (47), Hcp and VgrG have been postulated to form an extracellular translocon. This model is further supported by two recent crystallography studies showing that Hcp, VgrG, and a T4 phage gp25-like protein resembled membrane penetration tails of bacteriophages (35, 45).Little is known about the topology and structure of T6SS machinery subunits and the distinction between genes encoding machinery subunits and genes encoding regulatory proteins. Posttranslational regulation via the phosphorylation of Fha1 by a serine-threonine kinase (PpkA) is required for Hcp secretion from Pseudomonas aeruginosa (42). Genetic evidence for P. aeruginosa suggested that the T6SS may utilize a ClpV-like AAA⁺ ATPase to provide the energy for machinery assembly or substrate translocation (41). A recent study of V. cholerae suggested that ClpV ATPase activity is responsible for remodeling the VipA/VipB tubules which are crucial for type VI substrate secretion (6). An outer membrane lipoprotein, SciN, is an essential T6SS component for mediating Hcp secretion from enteroaggregative Escherichia coli (1). A systematic study of the T6SS machinery in E. tarda revealed that 13 of 16 genes in the evp gene cluster are essential for secretion of T6S substrates (74), which suggests the core components of the T6SS. Interestingly, most of the core components conserved in T6SS are predicted soluble proteins without recognizable signal peptide and transmembrane (TM) domains.The intracellular multiplication F (IcmF) and H (IcmH) proteins are among the few core components with obvious TM domains (8). In Legionella pneumophila Dot/Icm T4SSb, IcmF and IcmH are both membrane localized and partially required for L. pneumophila replication in macrophages (58, 70, 75). IcmF and IcmH are thought to interact with each other in stabilizing the T4SS complex in L. pneumophila (58). In T6SS, IcmF is one of the essential components required for secretion of Hcp from several animal pathogens, including V. cholerae (48), Aeromonas hydrophila (63), E. tarda (74), and P. aeruginosa (41), as well as the plant pathogens A. tumefaciens (72) and Pectobacterium atrosepticum (39). In E. tarda, IcmF (EvpO) interacted with IcmH (EvpN), EvpL, and EvpA in a yeast two-hybrid assay, and its putative nucleotide-binding site (Walker A motif) was not essential for secretion of T6SS substrates (74).In this study, we characterized the topology and interactions of the IcmF and IcmH family proteins ImpL_M and ImpK_L, which are two essential components of the T6SS of A. tumefaciens. We adapted the nomenclature proposed by Cascales (8), using the annotated gene designation followed by the letter indicated by Shalom et al. (59). Our data indicate that ImpL_M and ImpK_L are both integral inner membrane proteins and interact with each other via their N-terminal domains residing in the cytoplasm. We also provide genetic evidence showing that ImpL_M may function as a nucleoside triphosphate (NTP)-binding protein or nucleoside triphosphatase to mediate T6S machinery assembly and/or substrate secretion.     

A New Borrelia Species Defined by Multilocus Sequence Analysis of Housekeeping Genes

Analysis of Lyme borreliosis (LB) spirochetes, using a novel multilocus sequence analysis scheme, revealed that OspA serotype 4 strains (a rodent-associated ecotype) of Borrelia garinii were sufficiently genetically distinct from bird-associated B. garinii strains to deserve species status. We suggest that OspA serotype 4 strains be raised to species status and named Borrelia bavariensis sp. nov. The rooted phylogenetic trees provide novel insights into the evolutionary history of LB spirochetes.Multilocus sequence typing (MLST) and multilocus sequence analysis (MLSA) have been shown to be powerful and pragmatic molecular methods for typing large numbers of microbial strains for population genetics studies, delineation of species, and assignment of strains to defined bacterial species (4, 13, 27, 40, 44). To date, MLST/MLSA schemes have been applied only to a few vector-borne microbial populations (1, 6, 30, 37, 40, 41, 47).Lyme borreliosis (LB) spirochetes comprise a diverse group of zoonotic bacteria which are transmitted among vertebrate hosts by ixodid (hard) ticks. The most common agents of human LB are Borrelia burgdorferi (sensu stricto), Borrelia afzelii, Borrelia garinii, Borrelia lusitaniae, and Borrelia spielmanii (7, 8, 12, 35). To date, 15 species have been named within the group of LB spirochetes (6, 31, 32, 37, 38, 41). While several of these LB species have been delineated using whole DNA-DNA hybridization (3, 20, 33), most ecological or epidemiological studies have been using single loci (5, 9-11, 29, 34, 36, 38, 42, 51, 53). Although some of these loci have been convenient for species assignment of strains or to address particular epidemiological questions, they may be unsuitable to resolve evolutionary relationships among LB species, because it is not possible to define any outgroup. For example, both the 5S-23S intergenic spacer (5S-23S IGS) and the gene encoding the outer surface protein A (ospA) are present only in LB spirochete genomes (36, 43). The advantage of using appropriate housekeeping genes of LB group spirochetes is that phylogenetic trees can be rooted with sequences of relapsing fever spirochetes. This renders the data amenable to detailed evolutionary studies of LB spirochetes.LB group spirochetes differ remarkably in their patterns and levels of host association, which are likely to affect their population structures (22, 24, 46, 48). Of the three main Eurasian Borrelia species, B. afzelii is adapted to rodents, whereas B. valaisiana and most strains of B. garinii are maintained by birds (12, 15, 16, 23, 26, 45). However, B. garinii OspA serotype 4 strains in Europe have been shown to be transmitted by rodents (17, 18) and, therefore, constitute a distinct ecotype within B. garinii. These strains have also been associated with high pathogenicity in humans, and their finer-scale geographical distribution seems highly focal (10, 34, 52, 53).In this study, we analyzed the intra- and interspecific phylogenetic relationships of B. burgdorferi, B. afzelii, B. garinii, B. valaisiana, B. lusitaniae, B. bissettii, and B. spielmanii by means of a novel MLSA scheme based on chromosomal housekeeping genes (30, 48).     

PDK1 Regulates Vascular Remodeling and Promotes Epithelial-Mesenchymal Transition in Cardiac Development

One essential downstream signaling pathway of receptor tyrosine kinases (RTKs), such as vascular endothelial growth factor receptor (VEGFR) and the Tie2 receptor, is the phosphoinositide-3 kinase (PI3K)-phosphoinositide-dependent protein kinase 1 (PDK1)-Akt/protein kinase B (PKB) cascade that plays a critical role in development and tumorigenesis. However, the role of PDK1 in cardiovascular development remains unknown. Here, we deleted PDK1 specifically in endothelial cells in mice. These mice displayed hemorrhage and hydropericardium and died at approximately embryonic day 11.5 (E11.5). Histological analysis revealed defective vascular remodeling and development and disrupted integrity between the endothelium and trabeculae/myocardium in the heart. The atrioventricular canal (AVC) cushion and valves failed to form, indicating a defect in epithelial-mesenchymal transition (EMT), together with increased endothelial apoptosis. Consistently, ex vivo AVC explant culture showed impeded mesenchymal outgrowth. Snail protein was reduced and was absent from the nucleus in AVC cells. Delivery of the Snail S6A mutant to the AVC explant effectively rescued EMT defects. Furthermore, adenoviral Akt delivery rescued EMT defects in AVC explant culture, and deletion of PTEN delayed embryonic lethality of PDK1 endothelial deletion mice by 1 day and rendered normal development of the AVC cushion in the PDK1-deficient heart. Taken together, these results have revealed an essential role of PDK1 in cardiovascular development through activation of Akt and Snail.Polypeptide growth factors, such as insulin, insulin-like growth factor 1 (IGF-I), vascular endothelial growth factor (VEGF), and angiopoietin 1 (Ang1), exert biological functions through binding to their transmembrane receptors that belong to a large family of receptor tyrosine kinases (RTKs) (4). Consequently, the receptor molecules form homo- or heterodimers, and the intracellular tyrosines at the carboxyl termini of the receptors become phosphorylated (37). Numerous distinct adaptor/regulatory proteins, through their Src homologous 2 (SH2) domains, bind to the phosphotyrosines and transduce the signal to downstream pathways, among which are two essential and well-characterized signaling cascades—the mitogen-activated protein kinase (MAPK) and phosphoinositide-3 kinase (PI3K)-phosphoinositide-dependent protein kinase 1 (PDK1)-Akt signaling pathways (4, 13, 37).The regulatory subunit of PI3K, p85, possesses the SH2 domain and can, therefore, bind to phosphotyrosines on the RTKs and subsequently render activation of the catalytic subunit of PI3K, p110 (7, 8). Active p110 phosphorylates phosphoinositide biphosphate (PIP2), turning it into PIP3 that recruits PDK1 and Akt to the cellular membrane, where Akt is phosphorylated at threonine 308 (T308 for Akt1) by PDK (5, 23, 30). The serine 473 (S473) of Akt (Akt1) is phosphorylated by mTOR complex 2 (mTORC2) and other kinases (17, 36). Phosphorylation of Akt at these two amino acids brings it to full activation. In PDK1-deficient embryonic stem (ES) cells, T308 phosphorylation was abolished and most of the Akt activity was lost, although the S473 phosphorylation was intact (40).Akt plays an important role in multiple biological processes, such as cell survival, growth, glucose metabolism, and angiogenesis (2, 12, 14-16, 22, 23, 39, 41-43). In mammals, there are three Akt isoforms, termed Akt 1, -2, and -3. Previously, we generated Akt1- and Akt3-deficient mice and studied their roles in mouse development (2, 15, 39, 42, 43). We found that the Akt1 and -3 double knockout (KO) (DKO) mice were embryonically lethal at around embryonic day 12 (E12) and manifested developmental defects in multiple tissues, including the cardiovascular system (14, 15, 43). These studies suggest that the Akt signaling pathway is involved in cardiovascular development.Other than Akt isoforms, PDK1 also activates another group of AGC family kinases, such as p70 ribosomal S6 kinase (S6K) (32), serum, and glucocorticoid-induced protein kinase (SGK) (26), p90 ribosomal S6 kinase (RSK) (21), and atypical isoforms of protein kinase C (PKC) (31). Comprehensive and intensive mouse genetic studies performed mainly by Alessi and coworkers have confirmed the regulation of these AGC kinases by PDK1 (3, 9, 10, 27-29, 40).PDK1 knockout mice were severely growth retarded and died at around E9.0, indicating an essential role of PDK1 in development (27). However, its function and downstream targets in cardiovascular development are still elusive. To study this, we deleted PDK1 specifically in endothelial cells through Cre recombinase-mediated excision (25). The results have revealed an essential role of PDK1 in vascular remodeling and integrity and in cardiac development through activation of Akt and its downstream target of Snail.     

Legionella pneumophila Strain 130b Possesses a Unique Combination of Type IV Secretion Systems and Novel Dot/Icm Secretion System Effector Proteins

Legionella pneumophila is a ubiquitous inhabitant of environmental water reservoirs. The bacteria infect a wide variety of protozoa and, after accidental inhalation, human alveolar macrophages, which can lead to severe pneumonia. The capability to thrive in phagocytic hosts is dependent on the Dot/Icm type IV secretion system (T4SS), which translocates multiple effector proteins into the host cell. In this study, we determined the draft genome sequence of L. pneumophila strain 130b (Wadsworth). We found that the 130b genome encodes a unique set of T4SSs, namely, the Dot/Icm T4SS, a Trb-1-like T4SS, and two Lvh T4SS gene clusters. Sequence analysis substantiated that a core set of 107 Dot/Icm T4SS effectors was conserved among the sequenced L. pneumophila strains Philadelphia-1, Lens, Paris, Corby, Alcoy, and 130b. We also identified new effector candidates and validated the translocation of 10 novel Dot/Icm T4SS effectors that are not present in L. pneumophila strain Philadelphia-1. We examined the prevalence of the new effector genes among 87 environmental and clinical L. pneumophila isolates. Five of the new effectors were identified in 34 to 62% of the isolates, while less than 15% of the strains tested positive for the other five genes. Collectively, our data show that the core set of conserved Dot/Icm T4SS effector proteins is supplemented by a variable repertoire of accessory effectors that may partly account for differences in the virulences and prevalences of particular L. pneumophila strains.Many bacterial pathogens use specialized protein secretion systems to deliver into host cells virulence effector proteins that interfere with the antimicrobial responses of the host and facilitate the survival of the pathogen (5, 10, 22, 76). The components of these secretion systems are highly conserved. Comparative bioinformatic analysis of pathogen genomes revealed an ever-increasing number of proteins that are likely to be translocated virulence effectors. Only a few effectors have been characterized, and their biochemical functions are unknown, yet the identification of translocated effector proteins and their mechanism of action is fundamental to understanding the pathogenesis of many bacterial infections.Legionella pneumophila is the etiological agent of Legionnaires’ disease, which is an acute form of pneumonia (34, 66). L. pneumophila serogroup 1 accounts for more than 90% of all cases worldwide. Although L. pneumophila is an environmental organism, its ability to survive and replicate in amoebae, such as Acanthamoeba castellanii, has equipped the organism with the capacity to replicate in human cells (45, 58, 68, 80). Following the inhalation of aerosols containing L. pneumophila into the human lung, the bacteria promote their uptake by alveolar macrophages and epithelial cells (21, 44, 71), where they replicate within an intracellular vacuole that avoids fusion with the endocytic pathway (46, 47). L. pneumophila evades endosome fusion by establishing a replicative vacuole that shares many characteristics with the endoplasmic reticulum (ER) (48, 53, 89). The formation of the unique Legionella-containing vacuole (LCV) requires the Dot (defective in organelle trafficking)/Icm (intracellular multiplication) type IV secretion system (T4SS) (85, 91).Type IV secretion systems are versatile multiprotein complexes that can transport DNA and proteins to recipient bacteria or host cells (19, 36). Based on structural and organizational similarity, three main T4SS classes have been distinguished: T4SSA, T4SSB, and genomic island-associated T4SS (GI-T4SS) (3, 51). The genetic organization and components of T4SSA have high similarity to the classical VirB4/VirD4 transfer DNA (T-DNA) transfer system of Agrobacterium tumefaciens (3). In the sequenced L. pneumophila strains, three distinct T4SSAs with different prevalences among strains have been described: Lvh, Trb-1, and Trb-2 (37, 83, 86). The Lvh (Legionella vir homologues) T4SSA is not required for intracellular bacterial replication in macrophages and amoebae but seems to contribute to infection at lower temperatures and inclusion in Acanthamoeba castellanii cysts (6, 78, 86).The Dot/Icm T4SSB secretes and translocates multiple bacterial effector proteins into the vacuolar membrane and cytosol of the host cell (31, 70). The functions of the great majority of these proteins are unknown. Several effectors have similarity to eukaryotic proteins or carry eukaryotic motifs (7, 16, 25). They are predicted to allow L. pneumophila to manipulate host cell processes by functional mimicry (31, 70). Many of the effectors have paralogues or belong to related protein families that are likely to have overlapping functions.Comparative analysis of the recent L. pneumophila genome sequences has revealed their diversity and plasticity (16, 18, 88). This plasticity enables the bacterium to acquire new genetic factors, including new effector proteins that enhance bacterial replication and survival in eukaryotic cells. This has resulted in a diverse species in which 7 to 11% of the genes in each L. pneumophila isolate are strain specific (38). Some of the diversity occurs among genes encoding Dot/Icm effectors, including those within the same family. For example some ankyrin repeat and F-box effector genes are highly conserved, while others vary considerably between L. pneumophila isolates (16, 41, 62, 73, 75). Even though it is not experimentally proven, the subsequent selection of Dot/Icm effectors among different L. pneumophila isolates might reflect their usefulness in host-pathogen interactions, whereby different effector repertoires are maintained during adaptation to different environmental niches or hosts. This may then translate into differences in virulence during opportunistic infection.In this study, we sequenced the genome of L. pneumophila serogroup 1 strain 130b (ATCC BAA-74, also known as Wadsworth or AA100) (29, 30) and analyzed the sequence for T4SSs and novel Dot/Icm effectors. This analysis established that the strain encodes a unique combination of T4SSs and a set of Dot/Icm effectors that had not been described previously but that are present in a range of clinical and environmental L. pneumophila isolates. The new effectors represent the latest members of an ever-growing list of T4SS substrates and presumably reflect the great capacity of L. pneumophila for adaptation to a variety of hosts.     

Functional Dissection of the Conjugative Coupling Protein TrwB

The conjugative coupling protein TrwB is responsible for connecting the relaxosome to the type IV secretion system during conjugative DNA transfer of plasmid R388. It is directly involved in transport of the relaxase TrwC, and it displays an ATPase activity probably involved in DNA pumping. We designed a conjugation assay in which the frequency of DNA transfer is directly proportional to the amount of TrwB. A collection of point mutants was constructed in the TrwB cytoplasmic domain on the basis of the crystal structure of TrwBΔN70, targeting the nucleotide triphosphate (NTP)-binding region, the cytoplasmic surface, or the internal channel in the hexamer. An additional set of transfer-deficient mutants was obtained by random mutagenesis. Most mutants were impaired in both DNA and protein transport. We found that the integrity of the nucleotide binding domain is absolutely required for TrwB function, which is also involved in monomer-monomer interactions. Polar residues surrounding the entrance and inside the internal channel were important for TrwB function and may be involved in interactions with the relaxosomal components. Finally, the N-terminal transmembrane domain of TrwB was subjected to random mutagenesis followed by a two-hybrid screen for mutants showing enhanced protein-protein interactions with the related TrwE protein of Bartonella tribocorum. Several point mutants were obtained with mutations in the transmembranal helices: specifically, one proline from each protein may be the key residue involved in the interaction of the coupling protein with the type IV secretion apparatus.Bacterial conjugation can be viewed mechanistically as a rolling-circle replication system linked to a type IV secretion process. The two processes come into contact through the activity of a protein that couples the plasmid replication machinery to the export system in the membrane, allowing horizontal dissemination of the replicating DNA molecule (35). This key protein is called “coupling protein” (here “T4CP” for “type IV CP”). It is present in all conjugative systems as well as in many type IV secretion systems (T4SS) involved in bacterial virulence (16). The secreted substrate in bacterial conjugation is the relaxase or pilot protein, attached to the DNA strand. The shoot-and-pump model for bacterial conjugation proposes that, after secretion of the protein through the T4SS, the T4CP works as a motor for export of the rest of the DNA molecule (36). In addition to its presumed role as a DNA transporter, TrwB is also required for transport of relaxase TrwC in the absence of DNA transfer (15).In accordance with its proposed coupling activity, early genetic experiments made patent that the function of conjugative T4CPs depended on interactions with both the cytoplasmic substrate complex (the relaxosome) and the T4SS (6, 7). Thus, T4CP interactions with other conjugation proteins are a key aspect of their function. There have been several reports of interactions between T4CPs from conjugative plasmids and either relaxosomal components—such as F-TraD with TraM (14, 38), RP4-TraG with TraI (49), and pCF10-PcfC with PcfF and PcfG (11)—or T4SS components such as R27-TraG with TrhB (17). T4CP-T4SS interactions have also been reported for the VirB/D4 T4SS involved in DNA transfer from Agrobacterium tumefaciens to plant cells (1, 9). Both sets of interactions have only been concurrently shown for TrwB, the T4CP of plasmid R388. TrwB interacts with proteins TrwA and TrwC, which form the R388 relaxosome, and with the R388 T4SS component TrwE (37). While the interaction with the relaxosome is highly specific for its cognate system (24, 37, 48), the interaction between the T4CP and the T4SS is less specific: a single T4CP can interact functionally with several conjugative T4SS. Interestingly, a correlation was observed between the strength of the T4CP-TrwE-like interaction and the efficiency of DNA transfer (37). T4CPs also interact with TrwE-like components of T4SS involved in virulence (13). In the case of the highly related Trw T4SS systems of plasmid R388 and the human pathogen Bartonella, it was further demonstrated that R388 TrwE could be functionally replaced by the Bartonella tribocorum TrwE homolog, TrwE_Bt (13).T4CPs are integral membrane proteins anchored to the inner membrane by an N-terminal transmembrane domain (TMD). The soluble cytoplasmic domain of TrwB (TrwBΔN70), lacking this TMD, has been biochemically and structurally analyzed in detail. It retains the ability to bind NTPs and to unspecifically bind DNA (42). The characterization of its DNA-dependent ATPase activity (53) strengthened the possibility that T4CPs work as DNA motors. This activity is also stimulated by the oriT-binding protein TrwA (52).The determination of the three-dimensional (3D) structure of TrwBΔN70 indicated a quaternary structure consisting of hexamers that form an almost spherical, orange-shaped structure with a 20-Å inner channel (ICH) (18, 19). Each monomer is composed of two main structural domains: the nucleotide-binding domain (NBD) and the all-alpha domain (AAD). The NBD has α/β topology and is reminiscent of RecA and DNA ring helicases. The AAD is facing the cytoplasmic side and bears significant structural similarity to the N-terminal domain of site-specific recombinase XerD and also to a 40-residue segment of the DNA binding domain of protein TraM, the component of the relaxosome of F-like plasmids that interacts with its cognate T4CP, TraD. The structure of the hexamer as a whole resembles that of the F₁-ATPase, raising interesting perspectives into the possible way of action of coupling proteins as molecular motors in conjugation (5).There have been several attempts to functionally dissect T4CPs. In F-TraD, it was determined that its C terminus is essential for relaxosomal specificity, probably through an interaction with TraM (4, 39, 48). The cytoplasmic domain of the related TraD protein of plasmid R1 stimulates both transesterase and helicase activities of its cognate relaxase, TraI (41, 51). A series of random mutations were shown to affect TraD oligomerization (23). In VirD4, the T4CP of the VirB T4SS of A. tumefaciens, both the periplasmic domain plus key residues of the NBD are required for its location at the cell poles (31); its interaction with the T4SS protein substrate VirE2 does not require the N-terminal TMD (2). Mutational analysis of R27 TraG showed that the periplasmic residues are essential for interaction with the T4SS (22). An N-terminal deletion variant of PcfC, the T4CP of the Enterococcus plasmid pCF10, loses its membrane localization but retains its ability to bind relaxosomal components (11). Biochemical analysis of full-length R388 TrwB showed that the N-terminal TMD stabilizes the protein, aids oligomerization, and affects nucleotide selection (25-27). This region is essential for T4SS interaction, but TrwBΔN70 retains the ability to interact with the relaxosomal components TrwA and TrwC (37). Taken together, these analyses suggested that the N-terminal TMD of the T4CPs is necessary for T4SS interaction, oligomerization, and cellular location and that the C-terminal cytoplasmic domain is necessary for relaxosomal interactions and ATPase activity associated with DNA transport.In this study, we set up different assays to search for mutants affecting TrwB function in DNA and protein transfer. We constructed a series of TrwB point mutants based on the 3D structure of TrwBΔN70. Most selected residues were essential for TrwB function in conjugation, especially under conditions where TrwB was in limiting quantities. We analyzed the in vivo properties of selected mutants with a battery of in vivo assays to map functional domains. Also, random mutants in the TMD were screened for improved interactions with the T4SS, which allowed mapping of the TrwB-TrwE interaction domain.