Tn502 and Tn512 Are res Site Hunters That Provide Evidence of Resolvase-Independent Transposition to Random Sites

In this study, we report on the transposition behavior of the mercury(II) resistance transposons Tn502 and Tn512, which are members of the Tn5053 family. These transposons exhibit targeted and oriented insertion in the par region of plasmid RP1, since par-encoded components, namely, the ParA resolvase and its cognate res region, are essential for such transposition. Tn502 and, under some circumstances, Tn512 can transpose when par is absent, providing evidence for an alternative, par-independent pathway of transposition. We show that the alternative pathway proceeds by a two-step replicative process involving random target selection and orientation of insertion, leading to the formation of cointegrates as the predominant product of the first stage of transposition. Cointegrates remain unresolved because the transposon-encoded (TniR) recombination system is relatively inefficient, as is the host-encoded (RecA) system. In the presence of the res-ParA recombination system, TniR-mediated (and RecA-mediated) cointegrate resolution is highly efficient, enabling resolution both of cointegrates involving functional transposons (Tn502 and Tn512) and of defective elements (In0 and In2). These findings implicate the target-encoded accessory functions in the second stage of transposition as well as in the first. We also show that the par-independent pathway enables the formation of deletions in the target molecule.It is widely recognized that mobile genetic elements contribute to genome plasticity and have been a driving force in the emergence and spread of resistance determinants within and between bacterial species; their impact is ongoing (10, 51). Significant among these elements are various classes of plasmids, transposons, and integrons which may lack resistance determinants or carry one or multiple determinants. Resistance determinants that have become globally dispersed in environmental and clinically significant bacteria include mercury(II) resistance (2, 17), evident even in ancient bacteria (27), and antibiotic resistance, which has increased in dominance since the advent of the antibiotic era (23, 40).This paper concerns the mercury resistance (mer) transposons Tn502 and Tn512, whose sequence organization and transpositional behavior show that they are new members of a family of elements exemplified by the mer transposon Tn5053 (22). These elements are closely related to those in the Tn402 family, which contain an integron (intI) recombination system (14, 36). Members of the two families differ in the positions of the mer or intI determinants (modules) near one end of the transposition (tni) module. The latter module contains four genes (tniABQR), and the entire transposon is bounded by 25-bp inverted-repeat termini (IRi and IRt). TniA, TniB, and TniQ are required to form the transpositional cointegrate, which is then resolved by the action of TniR (a serine resolvase) on a resolution (res) sequence located between tniR and tniQ (22). The transposon in its new location is flanked by 5-bp direct repeats (DRs) (20, 22). TniA, which contains a D,D(35)E transposase catalytic motif, is thought to function cooperatively with TniB, a putative nucleotide-binding protein, as the active TniAB transposase (21, 36). Studies of TniA conducted in vitro show binding to the IRs and to additional 19-bp repeat sequences that make up the complex termini of the transposon (21). The precise role of TniQ is unknown.An unexpected and unique feature of Tn5053 and Tn402 is that they depend on externally coded accessory functions for efficient transposition, namely, a res site served by a cognate resolvase (25). As a consequence, these transposons exhibit a strong transpositional bias for some target res sites (20, 25, 26) and have aptly been described as “res site hunters” (25). One such efficient interaction involves the res-ParA multimer resolution system of plasmid RP1 (IncPα); other plasmid- or transposon-encoded systems are less efficient or are refractory. Although the role of the external resolvase remains obscure, its capacity to bind to its cognate res is an essential requirement whereas its catalytic activity is not (20). For each interaction system, the target sites typically cluster in a single part of res but not necessarily within the same subregion and, on occasion, can lie in the vicinity of res. Typically, the transposon is in a single orientation with IRi closest to the resolvase gene. In one study, Tn402 clustered at two target sites, one within res and one nearby, and the orientations were different at the two sites (20).The experimentally observed target preference described above also occurs in natural associations of Tn5053/Tn402-like elements and became evident on sequencing class 1 integrons, which were often found positioned close to different res-resolvase gene regions (6, 20, 25). Most Tn402 family elements are comprised of an intI module that is flanked on the left by IRi and on the right by a 3′ conserved sequence (3′-CS) (13). In others, a remnant tni gene cluster may be present instead of the 3′-CS, and IRt occurs at the right flank. The structure of the latter category of integrons strongly indicated that they are defective transposons that were presumably capable of relocation provided that tni functions were supplied in trans (6, 32). The movement of In33 (Tn2521) from a chromosomal to a plasmid location appears to have been such an in trans event (30, 42), and others involving In0 and In2 are demonstrated in this study. In contrast, the integrons that lack the IRt end appear to be nonmobile remnants of Tn402-like transposons; they belong to several lineages, including those in which the incurred deletions are attributable to acquired insertion sequences (6). More recently, intact Tn5053/Tn402-like transposons and class 1 integrons have increasingly been detected in the res-parA region of IncP plasmids (39), which are arguably the most promiscuous of known plasmids (50). These various experimental and natural interactions provide insight into the dispersal pathways possible for Tn5053/Tn402-like elements.The res-hunting attribute is a striking feature that is experimentally supported by studies of four family members (namely, Tn5053 [22, 25], Tn402 [20, 26], and in this study, Tn502 [48] and Tn512). Another facet of the transposition of Tn502 is explored here. It concerns the observation that loss of the preferred par target region in RP1 does not abolish transposition of Tn502 (48), contrary to the finding with Tn5053 (25, 26) and, in this study, Tn512. The continued, low-frequency transposition of Tn502 involved at least three dispersed locations (48); however, nothing is known about the nature of these sites or about the features and requirements of the transposition process. Here we address these issues and uncover the existence of an alternative, par-independent pathway that is employed by Tn502 and is available to Tn512 under some circumstances. The study also provides information on the roles of the TniR and host (RecA) recombination systems in the resolution of transpositional cointegrates and on the ability of the par-independent transposition pathway to generate plasmid deletions.     

Generation of Single-Copy Transposon Insertions in Clostridium perfringens by Electroporation of Phage Mu DNA Transposition Complexes

Transposon mutagenesis is a tool that is widely used for the identification of genes involved in the virulence of bacteria. Until now, transposon mutagenesis in Clostridium perfringens has been restricted to the use of Tn916-based methods with laboratory reference strains. This system yields primarily multiple transposon insertions in a single genome, thus compromising its use for the identification of virulence genes. The current study describes a new protocol for transposon mutagenesis in C. perfringens, which is based on the bacteriophage Mu transposition system. The protocol was successfully used to generate a single-insertion mutant library both for a laboratory strain and for a field isolate. Thus, it can be used as a tool in large-scale screening to identify virulence genes of C. perfringens.Clostridium perfringens is a gram-positive, anaerobic bacterium that forms heat-resistant spores. It is widespread in the soil and commonly found in the gastrointestinal tract of mammals. It has been implicated in several medical conditions in humans, ranging from mild food poisoning to necrotic enteritis and gas gangrene. C. perfringens strains also cause a variety of important diseases in domestic animals, including several enteric syndromes, such as enterotoxemia in cattle, sheep, and pigs, necrotic enteritis in poultry, and typhocolitis in equines (17, 40).Understanding the pathogenesis of these infections is of crucial importance for the development of new tools for the prevention and control of C. perfringens-related diseases. Genetic modification is a valuable approach to identify new virulence factors and to study their role in the pathogenesis of C. perfringens.Since the 1980s, several tools for manipulation of C. perfringens at the molecular level have been developed (1, 5, 28, 35, 38). Among these tools, transposon mutagenesis is a method that is widely used for identification of virulence genes. Until now, the only reproducible method for transposon mutagenesis in C. perfringens was based on Tn916, a tetracycline resistance-encoding conjugative transposon originally isolated from Enterococcus faecalis (10, 11, 13). Tn916 has been used extensively for transposon mutagenesis due to its broad host range and has been proven to be valuable for the identification of genes in C. perfringens (3, 7, 22). Nevertheless, this method has major disadvantages; multiple Tn916 insertion events occur with an incidence of 65% to 75%, severely complicating identification of genes responsible for phenotype changes (3, 7, 19). Furthermore, Tn916 is still active after insertion, resulting in unstable mutants (6, 39, 42). To our knowledge, generation of Tn916-derived transposon mutants in C. perfringens field strains has never been described.Although a variety of transposon mutagenesis methods are available for gram-positive bacteria (4, 37, 41, 43), the inherent species nonspecificity, as well as the lack of mobility of the integrated transposon, makes the bacteriophage Mu-based transposon delivery system a system of choice for a variety of species (16, 26, 46). The Mu transposition approach includes in vitro assembly of a complex between the transposon DNA and the transposase enzyme, the transpososome, followed by delivery of the transpososome into the recipient cells. Once inside a cell, the Mu transpososome becomes activated in the presence of divalent cations, resulting in genomic integration of the delivered transposon. The bacteriophage Mu transposition system is also functional in vitro (15, 32, 33), in contrast to the Tn916 mutagenesis strategy, which is restricted to transposon mobilization in vivo following conjugation or electroporation. Under the optimal in vitro conditions, the Mu transposition reaction requires only the MuA transposase, a mini-Mu transposon, and target DNA as macromolecular components (15).In this study, a novel protocol is described for transposon mutagenesis in C. perfringens that exploits the bacteriophage Mu transposition system. To our knowledge, this report is the first report describing a mutagenesis method generating single-insertion transposon mutants in laboratory and field isolates of C. perfringens. This method is important for the identification of C. perfringens virulence factors involved in the numerous diseases caused by this bacterium.     

Characterization of the Tn916 Conjugative Transposon in a Food-Borne Strain of Lactobacillus paracasei

Food-borne antibiotic-resistant lactic acid bacteria have received growing attention in the past few years. We have recently identified tetracycline-resistant Lactobacillus paracasei in samples of milk and natural whey starter cultures employed in the manufacturing process of a typical Italian fermented dairy product, Mozzarella di Bufala Campana. In the present study, we have characterized at the molecular level the genetic context of tetracycline resistance determinants in these natural strains, which we have identified as tet(M). This gene was present in 21 independent isolates, whose fingerprinting profiles were distributed into eight different repetitive extragenic palindromic groups by cluster analysis. We provide evidence that the gene is associated with the broad-host, conjugative transposon Tn916, which had never before been described to occur in L. paracasei. PCR analysis of four independent isolates by use of specifically designed primer pairs detected the presence of a circular intermediate form of the transposon, carrying a coupling sequence (GGCAAA) located between the two termini of Tn916. This novel coupling sequence conferred low conjugation frequency in mating experiments with the recipient strain JH2-2 of Enterococcus faecalis.Several genetic determinants conferring tetracycline resistance have been described to occur in gram-positive, nonpathogenic bacteria (2, 20). Among them, tet(M), encoding a ribosomal protection protein, is most commonly found in lactic acid bacteria (LAB). The issue of antibiotic resistance spreading among commensal bacteria has received great interest in recent years, and the presence of antibiotic-resistant species in the environment, including food products, has been extensively reported (reviewed in references 2 and 20). Conjugative transposons represent important vehicles for dissemination of antimicrobial resistance within gram-positive and gram-negative bacteria (23). These elements can move from the genome of a donor bacterium to that of a recipient by conjugation (6). Tn916, an 18-kb element containing the genetic determinant for tetracycline resistance, was the first conjugative transposon to be identified. It carries the tet(M) gene and has a broad host range, comprising both gram-positive and gram-negative bacteria (7). Along with the tetracycline resistance gene, Tn916 carries the genes responsible for its own excision (xis) and integration (int) as well as the mob genes, which mediate conjugal transfer (4). The transposition process starts with excision of the transposon, mediated by the Int and Xis proteins, leading to the formation of a nonreplicative circular intermediate which is transferred to the recipient and integrates into a new target site. Excision represents the rate-limiting step and occurs through reciprocal, site-specific recombination between the nonhomologous regions located at the two termini of the integrated transposon, known as coupling sequences, which are retained in the circular intermediate (17).Lactobacillus paracasei belongs to the microbial group of LAB and represents, along with the closely related species Lactobacillus casei, one of the most common bacterial species employed in the food industry. It is naturally present in raw milk and in dairy products, such as typical cheeses obtained by traditional manufacturing procedures in different Mediterranean countries (1, 11, 18, 26). Moreover, due to its probiotic functions, it is also employed as food additive (3, 5). Among its beneficial properties for human health, a recent study suggested that L. paracasei can be considered a potential enhancer of systemic immunity (22). However, only a few studies analyzed antibiotic resistance in L. paracasei (15, 19).In the past few years, our studies have focused on the identification of genes responsible for antibiotic resistance in LAB isolated from traditional dairy foods manufactured without employing commercial starter cultures. Fermentation in such products is therefore carried out by natural starters, mostly reflecting the microbiological composition of raw milk, which is affected in turn by the environment in which the animals live. Moreover, selective pressure exerted by technological steps along the manufacturing procedure often has a deep impact on bacterial composition in the final product. The widespread use and misuse of antibiotics have applied strong selective pressure in the environment, favoring survival and spread of antibiotic-resistant species. It is therefore of special relevance to identify antibiotic resistance determinants in food-borne bacteria, their persistence along the production line of specific products, and their capability of horizontal transfer to those species that can colonize the human gut.In the present study, we have characterized at the molecular level a group of tetracycline-resistant L. paracasei isolates, previously identified in raw milk and natural whey starter cultures employed in the manufacture of the Italian traditional cheese Mozzarella di Bufala Campana (9). We provide evidence that in these isolates, tetracycline resistance is due to the presence of the conjugative transposon Tn916, carrying the tet(M) gene and capable of horizontal, interspecies transfer to the opportunistic pathogen Enterococcus faecalis via a circular intermediate containing a novel coupling sequence that confers a low-frequency-conjugation phenotype. Molecular analysis of the resulting primary E. faecalis transconjugants revealed the presence of a circular intermediate of Tn916 carrying the same coupling sequence found in the L. paracasei donor strains.     

Integrative and Sequence Characteristics of a Novel Genetic Element,ICE6013, in Staphylococcus aureus

A survey of chromosomal variation in the ST239 clonal group of methicillin-resistant Staphylococcus aureus (MRSA) revealed a novel genetic element, ICE6013. The element is 13,354 bp in length, excluding a 6,551-bp Tn552 insertion. ICE6013 is flanked by 3-bp direct repeats and is demarcated by 8-bp imperfect inverted repeats. The element was present in 6 of 15 genome-sequenced S. aureus strains, and it was detected using genetic markers in 19 of 44 diverse MRSA and methicillin-susceptible strains and in all 111 ST239 strains tested. Low integration site specificity was discerned. Multiple chromosomal copies and the presence of extrachromosomal circular forms of ICE6013 were detected in various strains. The circular forms included 3-bp coupling sequences, located between the 8-bp ends of the element, that corresponded to the 3-bp direct repeats flanking the chromosomal forms. ICE6013 is predicted to encode 15 open reading frames, including an IS30-like DDE transposase in place of a Tyr/Ser recombinase and homologs of gram-positive bacterial conjugation components. Further sequence analyses indicated that ICE6013 is more closely related to ICEBs1 from Bacillus subtilis than to the only other potential integrative conjugative element known from S. aureus, Tn5801. Evidence of recombination between ICE6013 elements is also presented. In summary, ICE6013 is the first member of a new family of active, integrative genetic elements that are widely dispersed within S. aureus strains.ST239 is a globally distributed clonal group of methicillin-resistant Staphylococcus aureus (MRSA). Currently, ST239 is a major cause of MRSA infections in Asian hospitals (5, 18, 25, 37, 45, 64, 74). Pulsed-field gel electrophoresis has detected extensive chromosomal variation in local ST239 populations (3, 24, 52, 72). As ST239 has geographically spread and diversified, its variants have been given more than a dozen different names (20, 22, 24, 25, 49, 52, 61, 67, 68, 73), which reflects their clinical significance in various locales. The molecular basis for the ecological success of ST239 is unclear, but virulence-associated traits such as enhanced biofilm development and epidemiological characteristics such as a propensity to cause device-associated bacteremia and pulmonary infections have been highlighted (3, 19, 27, 54).Multilocus genetic investigations of the ST239 chromosome revealed that it is a hybrid with estimated parental contributions of approximately 20% and 80% from distantly related ST30- and ST8-like parents, respectively (58). Unusual for naturally isolated bacteria was the finding that these parental contributions were large chromosomal replacements rather than a patchwork of localized recombinations. It was postulated that conjugation might be responsible for the natural transfer of hundreds of kilobases of contiguous chromosomal DNA that resulted in ST239 (58). Recent genomic investigations have presented evidence that large chromosomal replacements also occur within Streptococcus agalactiae strains and that they can be mimicked with laboratory conjugation experiments (12). Importantly, conjugative transfer frequencies in S. agalactiae were found to be highest near three genomic islands (12), two of which were identified as being integrative conjugative elements (ICEs) (13).ICEs and conjugative transposons are synonyms and refer to genetic elements that are maintained by integration into a replicon and are transmitted by self-encoded conjugation functions (56). ICEs abound in the genomes of S. agalactiae (11), but only one potential ICE has been identified in staphylococci to date: Tn5801 was discovered through the genomic sequencing of S. aureus strain Mu50 (46). Tn5801 is most similar to a truncated genetic element, CW459tet(M), from Clostridium perfringens (57). Both Tn5801 and CW459tet(M) have Tyr recombinases, regulatory genes, and tetM modules that are similar to those of the prototypical gram-positive conjugative transposon, Tn916. Moreover, both Tn5801 and CW459tet(M) integrate into the same locus, guaA, at a nearly identical 11-bp sequence. Although the conjugative transfer module of CW459tet(M) is deleted (57), the conjugative transfer module of Tn5801 is similar to that of Tn916.We suspected that ST239 strains might carry novel accessory genes that contribute to their chromosomal variation and ecological success. To explore this possibility, we conducted a survey of chromosomal variation in ST239 using a PCR scanning approach. We report the discovery and partial characterization of a novel genetic element, ICE6013, that resulted from the survey.     

Characterization of the Transposase Encoded by IS256, the Prototype of a Major Family of Bacterial Insertion Sequence Elements

IS256 is the founding member of the IS256 family of insertion sequence (IS) elements. These elements encode a poorly characterized transposase, which features a conserved DDE catalytic motif and produces circular IS intermediates. Here, we characterized the IS256 transposase as a DNA-binding protein and obtained insight into the subdomain organization and functional properties of this prototype enzyme of IS256 family transposases. Recombinant forms of the transposase were shown to bind specifically to inverted repeats present in the IS256 noncoding regions. A DNA-binding domain was identified in the N-terminal part of the transposase, and a mutagenesis study targeting conserved amino acid residues in this region revealed a putative helix-turn-helix structure as a key element involved in DNA binding. Furthermore, we obtained evidence to suggest that the terminal nucleotides of IS256 are critically involved in IS circularization. Although small deletions at both ends reduced the formation of IS circles, changes at the left-hand IS256 terminus proved to be significantly more detrimental to circle production. Taken together, the data lead us to suggest that the IS256 transposase-mediated circularization reaction preferentially starts with a sequence-specific first-strand cleavage at the left-hand IS terminus.IS256 is an insertion sequence widespread in the genomes of multiresistant enterococci and staphylococci (3). The element, which is 1,324 bp in size, consists of a single open reading frame encoding a transposase protein flanked by noncoding regions (NCRs) harboring imperfect inverted repeats (IRs) (see Fig. ​Fig.1A).1A). IS256 occurs in multiple free copies in its host genomes but is also known to form the ends of composite transposon Tn4001 conferring aminoglycoside resistance (29). In Staphylococcus epidermidis, IS256 has been identified as a typical marker of hospital-acquired multiresistant and biofilm-forming clones causing opportunistic infections in immunocompromised patients (11, 20-22, 26, 34). The element has been shown to trigger heterogeneous biofilm expression by reversible transposition into biofilm-associated genes and regulators (4, 5, 19, 49, 56). Also, IS256 has the capacity to influence antibiotic resistance, either by insertion into regulatory genes or by modulating antibiotic resistance gene expression through formation of strong hybrid promoters resulting from transposition into the neighborhood of antibiotic resistance genes (6, 18, 31, 32). Finally, multiple genomic IS256 copies may serve as crossover points for homologous recombination events and thereby play an important role in genome flexibility, adaptation, and evolution of staphylococcal and enterococcal genomes (29, 42, 55).Open in a separate windowFIG. 1.IS256 transposase binding to IS termini. (A) Genetic organization of IS256. The transposase gene (tnp) is flanked by NCRs that harbor imperfect IRs (IR_L and IR_R) at the ends of the element. The nucleotide sequence of the IRs is indicated by uppercase boldface letters, with nucleotide numbering referring to GenBank accession no. {"type":"entrez-nucleotide","attrs":{"text":"M18086","term_id":"152946","term_text":"M18086"}}M18086. Insertion of IS256 into the S. epidermidis icaC gene on plasmid pIL2 (27) is shown, and black boxes mark the 8-bp target site duplications (TSDs) generated upon transposition of the element. Black bars at the top indicate localizations of DNA fragments used in the EMSAs presented in panels B to D. (B to D) EMSAs of purified IS256 transposase protein (CBP-Tnp) with various IS256-specific DNA fragments. A 15.5 nM concentration of an IS terminus (left)-carrying DNA fragment (B) or an IS terminus (right)-carrying DNA-fragment (C), as well as an interal IS256 fragment (D), were used with increasing amounts of protein. All experiments were performed in the presence of unspecific competitor [50 μg of poly(dI-dC) ml⁻¹]. Molar ratios between DNA and protein comprised a range of 1:3 (50 nM CBP-Tnp) to 1:52 (800 nM CBP-Tnp).Given its important biological role, it is surprising that very little is known about the molecular function of IS256 and its lifestyle. Empirical analyses of IS256 insertion sites in various bacterial genomes and loci did not reveal nucleotide sequence specificity for target site selection (3, 29, 56). Typically, IS256 generates 8- or 9-bp target site duplications (TSDs) upon transposition that are caused by staggered nicks of the target DNA and refill of the resulting gaps by the host repair system (43). In the course of phase variation events, IS256 TSDs can be completely removed, with the original host sequence being restored (56). Such precise IS256 excisions are caused by an illegitimate recombination event that requires fully intact TSDs but no functional IS256 transposase (14). IS256 transposition itself was found to involve the formation of double-stranded circular IS256 molecules in which the insertion sequence (IS) ends abut, bridged by a few base pairs of host DNA originating from the original insertion site (27, 39). IS256 circle formation is a strictly transposase-dependent process and IS circles are regarded as transposition intermediates which are likely to be relinearized during transposition. However, details of the transposition reaction, including circle formation, putative relinearization, target site selection, and insertion of the element are far from being understood at the molecular level. We experimentally addressed here, for the first time for a bacterial transposase of the IS256 family, the DNA-binding properties of this protein. We identified a DNA-binding domain in the N-terminal region of the protein. The domain contains a putative classical helix-turn-helix (HTH) motif that is demonstrated to be involved in sequence-specific interactions of the IS256 transposase with the IRs present in the NCRs of the element. Moreover, we suggest a role for the terminal nucleotides of the IS256 nucleotide sequence in first-strand cleavage and subsequent circularization of the element.     

Random Mutagenesis of Clostridium cellulolyticum by Using a Tn1545 Derivative

Further understanding of the plant cell wall degradation system of Clostridium cellulolyticum and the possibility of metabolic engineering in this species highlight the need for a means of random mutagenesis. Here, we report the construction of a Tn1545-derived delivery tool which allows monocopy random insertion within the genome.The economic feasibility and sustainability of lignocellulosic ethanol production are dependent on the development of robust microorganisms which can efficiently degrade and/or convert plant biomass to ethanol (5). The anaerobic, mesophilic, Gram-positive bacterium Clostridium cellulolyticum is a candidate microorganism, as it is capable of hydrolyzing plant cell wall polysaccharides and fermenting the hydrolysis products to ethanol and other metabolites (7). C. cellulolyticum achieves this efficient hydrolysis by using multiprotein extracellular enzymatic complexes, termed cellulosomes (13). As plant cell walls consist of several intertwined heterogeneous polymers, primarily composed of cellulose, hemicellulose, and pectin, cellulosomes contain many subunits (cellulosomal enzymes) with diverse and complementary enzymatic properties (2). Thus, this model organism is also a good candidate for the development of novel and efficient cellulases and hemicellulases for the saccharification of plant biomass.Gene transfer has been successfully carried out in C. cellulolyticum (8, 12). This possibility has allowed the in vivo function of cellulosomal enzymes in C. cellulolyticum to be examined by overexpression (9) or down expression (11) of targeted genes. However, random mutagenesis of the entire chromosome and screening of mutants to identify key components for plant cell wall degradation have never been described. Conjugative transfer of Tn1545 from Enterococcus faecalis to C. cellulolyticum has been described but is limited by low transfer frequency and poor reproducibility (8). To improve transposon mutagenesis of C. cellulolyticum, we exploited the two-plasmid Tn1545 delivery system described by Trieu-Cuot et al. (15). In this system, the Tn916 integrase-encoding gene is carried by an expression vector, whereas the attachment site of Tn1545 is carried by a suicide vector. Tn916 and Tn1545 being closely related (4), integration of the Tn1545 derivative occurs in the genome after transformation of the strain with both vectors (15).     

Base Flipping in V(D)J Recombination: Insights into the Mechanism of Hairpin Formation,the 12/23 Rule,and the Coordination of Double-Strand Breaks

Tn5 transposase cleaves the transposon end using a hairpin intermediate on the transposon end. This involves a flipped base that is stacked against a tryptophan residue in the protein. However, many other members of the cut-and-paste transposase family, including the RAG1 protein, produce a hairpin on the flanking DNA. We have investigated the reversed polarity of the reaction for RAG recombination. Although the RAG proteins appear to employ a base-flipping mechanism using aromatic residues, the putatively flipped base is not at the expected location and does not appear to stack against any of the said aromatic residues. We propose an alternative model in which a flipped base is accommodated in a nonspecific pocket or cleft within the recombinase. This is consistent with the location of the flipped base at position −1 in the coding flank, which can be occupied by purine or pyrimidine bases that would be difficult to stabilize using a single, highly specific, interaction. Finally, during this work we noticed that the putative base-flipping events on either side of the 12/23 recombination signal sequence paired complex are coupled to the nicking steps and serve to coordinate the double-strand breaks on either side of the complex.Antibody and T-cell receptor (TCR) diversity is generated by V(D)J recombination initiated by the RAG proteins, RAG1 and RAG2. The recombination signal sequences (RSSs), where recombination takes place, have a distinctive arrangement resembling transposon ends. The relationship between V(D)J recombination and transposition was established beyond doubt by the discovery of RAG-mediated transposition and by the identification of a triad of conserved active-site residues. This evidence placed RAG1 firmly within the family of transposases and retroviral integrases that have a characteristic DDE triad of amino acid residues that coordinate catalytic metal ions in the active site (1, 26, 30, 35, 39, 46). Later, the Transib family of transposons was identified as the likely ancestral group of RAG1 (33).In V(D)J recombination, the RAG proteins excise the DNA between a pair of RSSs. This fragment is the equivalent of an excised transposon, and it takes no further part in the canonical V(D)J recombination reaction. Instead, the variable regions of the genes encoding antibodies and TCR are created by the imprecise rejoining of the flanking DNA, referred to as the “coding flank.” A key feature of the cleaved coding flanks is that they have covalently closed hairpin ends. The asymmetric resolution of these hairpins contributes to the diversification of the coding sequences during rejoining. The hairpins themselves arise as a consequence of the molecular mechanism RAG-mediated RSS cleavage.The crystal structure for the catalytic core of the human immunodeficiency virus type 1 integrase protein revealed a structural fold shared in common with RNase H and the Holliday junction resolving enzyme RuvC (22). RNase H and RuvC monomers each perform a simple nicking reaction that requires a single phosphoryl transfer event. Cut-and-paste transposition, which requires at least three phosphoryl transfer steps at each transposon end, therefore presents a mechanistic challenge. One solution to this challenge was revealed by the discovery of the DNA-hairpin cleavage-intermediate in V(D)J recombination and Tn10 transposition (Fig. ​(Fig.1)1) (34, 57). However, it is interesting to note that the existence of this intermediate was first suggested by Coen and colleagues on the basis of the genomic scars produced by excision of the hAT family transposon Tam3 in Antirrhinum majus (14).Open in a separate windowFIG. 1.Hairpin-processing reactions of opposite polarity. Most prokaryotic and eukaryotic members of the DDE family have hairpin intermediates of opposite polarity. In this paper, we refer to the two strands of DNA as “first strand” or “second strand” depending on the order of cleavage. The first strand therefore corresponds to the transferred and nontransferred strands of the prokaryotic and eukaryotic elements, respectively. Scissile phosphates are in red. The transposon end and RSS are shown as gray triangles. (Left panel) In Tn5 and Tn10, the first step of the reaction is a nick on the bottom (first) strand that exposes the 3′-OH at the end of the transposon. The second strand is cleaved by a direct transesterification reaction, which generates a “proximal-hairpin” intermediate on the transposon end (5, 34). Resolution by a nick at the tip of the hairpin yields a blunt transposon end. Distortion of the DNA helix can be detected by permanganate sensitivity of the T−1 and T+2 residues on the second strand. The insert shows the crystal structure of the Tn5 transposon end, highlighting the flipped base at position +2 (19). Two tryptophan residues are also shown. One acts as a “wedge” or “probe” residue inserted into the DNA helix, while the other provides stacking interactions that stabilize the flipped base. The W323 probe residue resides within the catalytic core close to the DDE residue E326, whereas the W298 stacking residue is in the inserted subdomain (see text for further details). Base flipping takes place after the first nick and is probably maintained for all subsequent steps, including integration (3, 7). (Right panel) In V(D)J recombination and the hAT family of transposons, the polarity of the reaction is reversed. The first nick is on the top strand providing a 3′-OH group on the flanking DNA (53, 71, 77). Transesterification yields a “distal hairpin” intermediate on the flanking DNA that is processed by the host. The positions of relevant thymidine residues in our substrates are indicated.All DDE family transposases, including RAG1, cut the DNA to expose the 3′-OH at the end of the element (or RSS). However, the fate of the opposite strand and the order of strand cleavage events vary within the group (reviewed in references13, 18, and 55). Some enzymes, such as the retroviral integrases and the bacteriophage Mu transposase, nick and integrate the 3′-OH directly without second-strand cleavage. The cut-and-paste transposons, which cleave both strands of DNA, can be divided into two groups. With some notable exceptions such as the piggyBac element, most prokaryotic family members cleave the bottom strand of the recombination site first, whereas most eukaryotic members cleave the top strand first (8, 10, 20, 41, 47, 48, 77). For those family members with a hairpin mechanism, the inverted polarity of the first step dictates the reversal of all subsequent steps (Fig. ​(Fig.1).1). In consequence, most eukaryotic members of the family can achieve transposition with one less phosphoryl transfer reaction than the prokaryotic members, which are obliged to resolve the hairpin intermediate. The eukaryotic members can simply release the hairpin ends or, as in the case of RAG, hand them on to host factors for further processing (40).Insight into the hairpin mechanism was provided by a crystal structure for the Tn5 transpososome, in which the penultimate base on the second, nontransferred, strand was flipped from the helix and stacked against a tryptophan side chain in the protein (Fig. ​(Fig.1)1) (19). The flipped base seemed to provide the steric freedom that is presumed to be required for making and resolving the hairpin intermediate. Two groups searched for a residue in RAG1 that performs a function equivalent to the stacking tryptophan in the Tn5 transposase (27, 45). This work identified several candidate residues on the basis of their respective mechanistic defects and their rescue by modified DNA substrates.Here we have further assessed the candidate stacking residues using biochemical techniques previously used to study the dynamics of base flipping in Tn5 and Tn10 transposition (6, 7). We have identified a distortion at position −1 of the V(D)J coding flank DNA. It is introduced after the first nick at the RSS and is therefore reminiscent of the flipped base at the end of Tn5. The distortion is perfectly correlated with the ability of wild-type and mutant RAG-RSS complexes to perform the hairpin step of the reaction. We conclude that this base is probably equivalent to the flipped base in Tn5. However, none of the candidate aromatic residues seems to fulfill the function of the putative stacking tryptophan residue. We therefore propose a model in which base flipping in RAG recombination is significantly different from that in Tn5 transposition.Canonical V(D)J recombination occurs within a 12/23 RSS paired complex (24, 36, 60, 72, 73). This restriction is known as the 12/23 rule. More recently a further restriction, the so-called “beyond 12/23” (B12/23) rule has been proposed to explain the exclusion of direct Vβ-to-Jβ joining in the TCR β region, despite the presence of appropriately oriented pairs of 12 and 23 RSSs (4, 21, 31, 32).Little is known of the mechanisms that enforce the 12/23 rule or coordinate cleavage on either side of the complex. However, during this work, we observed that the coding flank distortion was coupled on either side of a 12/23 RSS paired complex: the distortion of a nicked coding flank is suppressed by an unnicked partner. We present a model and discuss the biological significance of this conformational coupling and its relevance to the B12/23 rule.     

A mariner-Based Transposon System for In Vivo Random Mutagenesis of Clostridium difficile

Understanding the molecular basis of Clostridium difficile infection is a prerequisite to the development of effective countermeasures. Although there are methods for constructing gene-specific mutants of C. difficile, currently there is no effective method for generating libraries of random mutants. In this study, we developed a novel mariner-based transposon system for in vivo random mutagenesis of C. difficile {"type":"entrez-nucleotide","attrs":{"text":"R20291","term_id":"774925","term_text":"R20291"}}R20291, the BI/NAP1/027 epidemic strain at the center of the C. difficile outbreaks in Stoke Mandeville, United Kingdom, in 2003 to 2004 and 2004 to 2005. Transposition occurred at a frequency of 4.5 (±0.4) × 10⁻⁴ per cell to give stable insertions at random genomic loci, which were defined only by the nucleotide sequence TA. Furthermore, mutants with just a single transposon insertion were generated in an overwhelming majority (98.3% in this study). Phenotypic screening of a C. difficile {"type":"entrez-nucleotide","attrs":{"text":"R20291","term_id":"774925","term_text":"R20291"}}R20291 random mutant library yielded a sporulation/germination-defective clone with an insertion in the germination-specific protease gene cspBA and an auxotroph with an insertion in the pyrimidine biosynthesis gene pyrB. These results validate our mariner-based transposon system for use in forward genetic studies of C. difficile.Clostridium difficile infection is widely recognized as the leading cause of health care-associated diarrhea in North America and Europe. Infection usually follows antibiotic treatment, which disrupts the native gastrointestinal microflora and thus allows C. difficile to proliferate. The emergence of so-called “epidemic” or “hypervirulent” strains of C. difficile over the last 5 to 10 years has compounded an already serious problem. Classed as BI/NAP1/027, these epidemic strains are believed to cause a more severe disease and lead to increased mortality and relapse rates (11, 20, 24).Understanding the genetic and molecular basis of C. difficile infection will be a crucial step in the development of effective countermeasures. Methods for directed gene inactivation in C. difficile have recently been described (7, 21). This has opened the way for reverse genetic studies, in which the exact role of a specific gene, hypothesized to be important in a given phenotype, can be elucidated experimentally. By way of contrast, forward genetic studies aim to identify the genetic basis of a particular phenotype without making any assumptions about the genes involved. In forward genetic studies, transposons are often used to generate libraries of random insertion mutants. Libraries are then screened to identify mutants that are defective in a particular phenotype. Identification of the gene or genes which have been inactivated by transposon insertion then implicates them as having a role in that particular phenotype. Recently, just such an approach was used to identify a novel toxin-regulatory locus in Clostridium perfringens (29). This study elegantly demonstrated the power of forward genetic studies in bacterial pathogens.A number of transposon mutagenesis systems have been described for Gram-positive bacteria (2, 3, 15, 16, 29, 32). Two different systems have recently been developed for use in C. perfringens (15, 29). Both are in vitro mutagenesis systems which rely on being able to transform the recipient organism. As such, they are not suitable for use in C. difficile because in the laboratory at present, recombinant DNA can be transferred into C. difficile only via conjugation. The conjugative transposons Tn916 and Tn5397 have been studied in C. difficile, but both have been found either to have a strong target site preference or to yield multiple insertions in individual clones (9, 30). Therefore, neither is well suited to generating libraries of random C. difficile mutants.We reasoned that a mariner-based transposon mutagenesis system would be an effective tool for generating libraries of random C. difficile mutants. The mariner-transposable element Himar1 has been shown to insert randomly into the genomes of many bacterial species (3, 6, 16, 17, 32). The cognate Himar1 transposase is the only factor required for transposition, which occurs via a cut-and-paste mechanism (13, 14). The transposon itself is defined by inverted terminal repeats (ITRs) at either end and inserts into a TA target site. This is highly appropriate for an organism with a low-GC content such as C. difficile. In this study, we have developed a novel mariner-based transposon system for in vivo random mutagenesis of C. difficile. Moreover, we have demonstrated the system in C. difficile {"type":"entrez-nucleotide","attrs":{"text":"R20291","term_id":"774925","term_text":"R20291"}}R20291, the BI/NAP1/027 epidemic strain at the center of the C. difficile outbreaks in Stoke Mandeville, United Kingdom, in 2003 to 2004 and 2004 to 2005. This new genetic tool opens the way for forward genetic studies of C. difficile.     

Intra- and Interspecies Conjugal Transfer of Tn916-Like Elements from Lactococcus lactis In Vitro and In Vivo

Tetracycline-resistant Lactococcus lactis strains originally isolated from Polish raw milk were analyzed for the ability to transfer their antibiotic resistance genes in vitro, using filter mating experiments, and in vivo, using germfree rats. Four of six analyzed L. lactis isolates were able to transfer tetracycline resistance determinants in vitro to L. lactis Bu2-60, at frequencies ranging from 10⁻⁵ to 10⁻⁷ transconjugants per recipient. Three of these four strains could also transfer resistance in vitro to Enterococcus faecalis JH2-2, whereas no transfer to Bacillus subtilis YBE01, Pseudomonas putida KT2442, Agrobacterium tumefaciens UBAPF2, or Escherichia coli JE2571 was observed. Rats were initially inoculated with the recipient E. faecalis strain JH2-2, and after a week, the L. lactis IBB477 and IBB487 donor strains were introduced. The first transconjugants were detected in fecal samples 3 days after introduction of the donors. A subtherapeutic concentration of tetracycline did not have any significant effect on the number of transconjugants, but transconjugants were observed earlier in animals dosed with this antibiotic. Molecular analysis of in vivo transconjugants containing the tet(M) gene showed that this gene was identical to tet(M) localized on the conjugative transposon Tn916. Primer-specific PCR confirmed that the Tn916 transposon was complete in all analyzed transconjugants and donors. This is the first study showing in vivo transfer of a Tn916-like antibiotic resistance transposon from L. lactis to E. faecalis. These data suggest that in certain cases food lactococci might be involved in the spread of antibiotic resistance genes to other lactic acid bacteria.The abuse of antibiotic use is regarded as the major cause of the accumulation and dissemination of antibiotic resistance genes in the environment (33). For several decades, studies on selection and spread of antibiotic resistance genes have focused mainly on clinically relevant microbial species. Nevertheless, many investigators have recently speculated that commensal bacteria, including lactic acid bacteria (LAB), may act as reservoirs of antibiotic resistance determinants (40). Genes conferring acquired resistance to tetracycline, erythromycin, and vancomycin have been detected and characterized for Lactococcus, Enterococcus, and Lactobacillus species isolated from fermented meat and milk products (13, 18, 23, 49, 50, 56). Introduction of such bacteria into humans through ingestion of commercial food products may have negative consequences by dissemination of antibiotic resistance genes via the food chain to the resident microbiota of the human gastrointestinal tract and, in the worst case, to pathogenic bacteria (4, 17, 55). Therefore, it seems important to assess the risk of antibiotic resistance gene transmission in the environment and in the guts of animals and humans and to establish the genetic basis of the detected resistance and transmission mechanisms.Dissemination of genetic information by horizontal gene transfer is common in the microbial world and is accomplished mainly by the following three mechanisms: natural transformation, conjugation, and transduction (14). Many antibiotic resistance genes have been detected on mobile genetic elements, such as plasmids and conjugative transposons, and it is believed that conjugation is the main mode of horizontal dissemination of antibiotic resistance determinants between bacterial species.Conjugative transposons mediate their own transfer from a donor DNA molecule in one bacterial cell to a target molecule in another cell. Tn916, which spans about 18 kb and confers resistance to tetracycline via tet(M), belongs to the Tn916-Tn1545 family of conjugative transposons and was first identified in Enterococcus faecalis DS16 (20). It is able to be maintained in a wide range of clinically important gram-positive and gram-negative species (12, 44).Excision of Tn916 from the donor molecule is required for conjugative transposition and results in a covalently closed circular transposon molecule that is an intermediate in conjugal transfer (10). A single strand of the covalently closed circular transposon is transferred to the recipient cell, where the complementary strand is synthesized to recreate a double-stranded circular transposon, which inserts into a target site (48).Lactococcus lactis strains are used worldwide as starter organisms in the dairy industry and for the manufacturing of many fermented products. Conjugation has been described widely for lactococci, although mainly for exploitation of this process for development of improved starter strains (22, 38, 39, 51, 53).The objective of the present study was to establish the ability of wild-type L. lactis isolates to transfer tetracycline resistance determinants to gram-positive bacteria, namely, L. lactis Bu2-60, E. faecalis JH2-2, and Bacillus subtilis YBE01, and to gram-negative bacteria, namely, Pseudomonas putida KT2442, Agrobacterium tumefaciens UBAPF2, and Escherichia coli JE2571, by using the filter mating approach. In order to confirm whether these donor strains were able to transfer the tetracycline resistance genes to E. faecalis JH2-2 in vivo in the gastrointestinal tract, we also used germfree rats.     

Genome-Wide Transposon Mutagenesis Identifies a Role for Host Neuroendocrine Stress Hormones in Regulating the Expression of Virulence Genes in Salmonella

Bacterial sensing of environmental signals plays a key role in regulating virulence and mediating bacterium-host interactions. The sensing of the neuroendocrine stress hormones epinephrine (adrenaline) and norepinephrine (noradrenaline) plays an important role in modulating bacterial virulence. We used MudJ transposon mutagenesis to globally screen for genes regulated by neuroendocrine stress hormones in Salmonella enterica serovar Typhimurium. We identified eight hormone-regulated genes, including yhaK, iroC, nrdF, accC, yedP, STM3081, and the virulence-related genes virK and mig14. The mammalian α-adrenergic receptor antagonist phentolamine reversed the hormone-mediated effects on yhaK, virK, and mig14 but did not affect the other genes. The β-adrenergic receptor antagonist propranolol had no activity in these assays. The virK and mig14 genes are involved in antimicrobial peptide resistance, and phenotypic screens revealed that exposure to neuroendocrine hormones increased the sensitivity of S. Typhimurium to the antimicrobial peptide LL-37. A virK mutant and a virK mig14 double mutant also displayed increased sensitivity to LL-37. In contrast to enterohemorrhagic Escherichia coli (EHEC), we have found no role for the two-component systems QseBC and QseEF in the adrenergic regulation of any of the identified genes. Furthermore, hormone-regulated gene expression could not be blocked by the QseC inhibitor LED209, suggesting that sensing of hormones is mediated through alternative signaling pathways in S. Typhimurium. This study has identified a role for host-derived neuroendocrine stress hormones in downregulating S. Typhimurium virulence gene expression to the benefit of the host, thus providing further insights into the field of host-pathogen communication.Bacterial sensing of environmental signals plays a key role in regulating virulence gene expression and bacterium-host interactions. It is increasingly recognized that detection of host-derived molecules, such as the neuroendocrine stress hormones (catecholamines) epinephrine (adrenaline) and norepinephrine (noradrenaline), plays an important role in modulating bacterial virulence (29, 42).Physical and psychological stress has been linked to increased severity and susceptibility to infection in humans and other animals (23, 42), and epinephrine/norepinephrine levels are an important factor in this. Stress triggers an increase in plasma epinephrine levels (31), and plasma levels of epinephrine and norepinephrine have been reported to increase with patients suffering from postoperative sepsis compared to patients with no complications (32). Administration of norepinephrine and epinephrine to otherwise healthy subjects increases the severity of bacterial infections, including Clostridium perfringens in humans and enterohemorrhagic Escherichia coli (EHEC) in calves (42, 63, 65). Treatment with norepinephrine also increases the virulence of Salmonella enterica serovar Enteritidis in chicks and Salmonella enterica serovar Typhimurium in mice, with a substantial increase in bacterial numbers recovered from the cecum and liver in both cases (47, 65).Norepinephrine is found in large concentrations in the gut due to release by gastrointestinal neurones; indeed up to half the norepinephrine in the body may be produced in the enteric nervous system (ENS) (3). Epinephrine, while not normally found in the gut, is present in the bloodstream and is also produced by macrophages in response to bacteria-derived lipopolysaccharide (LPS) (12, 26). S. Typhimurium is an enteropathogen, can also cross the epithelial barrier to cause systemic infection, and will therefore encounter both these molecules in the normal infection cycle.Phenotypes induced by stress hormones in bacteria include increased adherence of EHEC to bovine intestinal mucosa (63), upregulation of type III secretion and Shiga toxin production in EHEC (22, 60), upregulation of type III secretion in Vibrio parahaemolyticus (51), increase in invasion of epithelial cells and breakdown of epithelial tight junctions by Campylobacter jejuni (15), affected motility and expression of iron uptake genes in S. Typhimurium (8, 9, 36), and modulated virulence in Borrelia burgdorferi (59). Epinephrine and norepinephrine can overcome the growth inhibition of many bacteria, including Salmonella, in serum-containing media (13, 43), due to the ability to act as a siderophore to facilitate iron uptake (13, 28, 47).Norepinephrine and epinephrine also interact with bacterial quorum-sensing (QS) systems. QS is a process of bacterial cell-cell communication in which each cell produces small signal molecules termed “autoinducers” (AIs), which regulate gene expression when a critical threshold concentration and therefore population density have been reached. QS affects diverse processes, including motility, virulence, biofilm formation, type III secretion, and luminescence (6, 64).The EHEC AI-3 QS system is important for motility and expression of the type III secretion system encoded by the locus of enterocyte effacement (LEE) (60). AI-3 sensing and signal transduction are mediated via the QseBC and QseEF two-component systems, respectively. Epinephrine and norepinephrine can substitute for AI-3, causing cross talk between the two signaling systems and induction of type III secretion and motility (57, 60). The sensor kinase QseC is autophosphorylated upon binding either epinephrine or norepinephrine (14), demonstrating the presence of adrenergic receptors in bacteria. These adrenergic phenotypes can also be blocked by the mammalian α- and β-adrenergic antagonists phentolamine and propranolol, although it should be noted that QseC is blocked only by the former (14, 60). This suggests the occurrence of cross talk between bacterial and mammalian cell signaling systems and the existence of multiple bacterial adrenergic sensors.To elucidate the role of host-derived stress hormones in the physiology and pathogenicity of S. Typhimurium, we used MudJ transposon mutagenesis to screen globally for epinephrine- and norepinephrine-regulated genes in S. Typhimurium.     

Alignment of the c-Type Cytochrome OmcS along Pili of Geobacter sulfurreducens

Immunogold localization revealed that OmcS, a cytochrome that is required for Fe(III) oxide reduction by Geobacter sulfurreducens, was localized along the pili. The apparent spacing between OmcS molecules suggests that OmcS facilitates electron transfer from pili to Fe(III) oxides rather than promoting electron conduction along the length of the pili.There are multiple competing/complementary models for extracellular electron transfer in Fe(III)- and electrode-reducing microorganisms (8, 18, 20, 44). Which mechanisms prevail in different microorganisms or environmental conditions may greatly influence which microorganisms compete most successfully in sedimentary environments or on the surfaces of electrodes and can impact practical decisions on the best strategies to promote Fe(III) reduction for bioremediation applications (18, 19) or to enhance the power output of microbial fuel cells (18, 21).The three most commonly considered mechanisms for electron transfer to extracellular electron acceptors are (i) direct contact between redox-active proteins on the outer surfaces of the cells and the electron acceptor, (ii) electron transfer via soluble electron shuttling molecules, and (iii) the conduction of electrons along pili or other filamentous structures. Evidence for the first mechanism includes the necessity for direct cell-Fe(III) oxide contact in Geobacter species (34) and the finding that intensively studied Fe(III)- and electrode-reducing microorganisms, such as Geobacter sulfurreducens and Shewanella oneidensis MR-1, display redox-active proteins on their outer cell surfaces that could have access to extracellular electron acceptors (1, 2, 12, 15, 27, 28, 31-33). Deletion of the genes for these proteins often inhibits Fe(III) reduction (1, 4, 7, 15, 17, 28, 40) and electron transfer to electrodes (5, 7, 11, 33). In some instances, these proteins have been purified and shown to have the capacity to reduce Fe(III) and other potential electron acceptors in vitro (10, 13, 29, 38, 42, 43, 48, 49).Evidence for the second mechanism includes the ability of some microorganisms to reduce Fe(III) that they cannot directly contact, which can be associated with the accumulation of soluble substances that can promote electron shuttling (17, 22, 26, 35, 36, 47). In microbial fuel cell studies, an abundance of planktonic cells and/or the loss of current-producing capacity when the medium is replaced is consistent with the presence of an electron shuttle (3, 14, 26). Furthermore, a soluble electron shuttle is the most likely explanation for the electrochemical signatures of some microorganisms growing on an electrode surface (26, 46).Evidence for the third mechanism is more circumstantial (19). Filaments that have conductive properties have been identified in Shewanella (7) and Geobacter (41) species. To date, conductance has been measured only across the diameter of the filaments, not along the length. The evidence that the conductive filaments were involved in extracellular electron transfer in Shewanella was the finding that deletion of the genes for the c-type cytochromes OmcA and MtrC, which are necessary for extracellular electron transfer, resulted in nonconductive filaments, suggesting that the cytochromes were associated with the filaments (7). However, subsequent studies specifically designed to localize these cytochromes revealed that, although the cytochromes were extracellular, they were attached to the cells or in the exopolymeric matrix and not aligned along the pili (24, 25, 30, 40, 43). Subsequent reviews of electron transfer to Fe(III) in Shewanella oneidensis (44, 45) appear to have dropped the nanowire concept and focused on the first and second mechanisms.Geobacter sulfurreducens has a number of c-type cytochromes (15, 28) and multicopper proteins (12, 27) that have been demonstrated or proposed to be on the outer cell surface and are essential for extracellular electron transfer. Immunolocalization and proteolysis studies demonstrated that the cytochrome OmcB, which is essential for optimal Fe(III) reduction (15) and highly expressed during growth on electrodes (33), is embedded in the outer membrane (39), whereas the multicopper protein OmpB, which is also required for Fe(III) oxide reduction (27), is exposed on the outer cell surface (39).OmcS is one of the most abundant cytochromes that can readily be sheared from the outer surfaces of G. sulfurreducens cells (28). It is essential for the reduction of Fe(III) oxide (28) and for electron transfer to electrodes under some conditions (11). Therefore, the localization of this important protein was further investigated.     

Identification of Genes Involved in Biofilm Formation and Respiration via Mini-Himar Transposon Mutagenesis of Geobacter sulfurreducens

Electron transfer from cells to metals and electrodes by the Fe(III)-reducing anaerobe Geobacter sulfurreducens requires proper expression of redox proteins and attachment mechanisms to interface bacteria with surfaces and neighboring cells. We hypothesized that transposon mutagenesis would complement targeted knockout studies in Geobacter spp. and identify novel genes involved in this process. Escherichia coli mating strains and plasmids were used to develop a conjugation protocol and deliver mini-Himar transposons, creating a library of over 8,000 mutants that was anaerobically arrayed and screened for a range of phenotypes, including auxotrophy for amino acids, inability to reduce Fe(III) citrate, and attachment to surfaces. Following protocol validation, mutants with strong phenotypes were further characterized in a three-electrode system to simultaneously quantify attachment, biofilm development, and respiratory parameters, revealing mutants defective in Fe(III) reduction but unaffected in electron transfer to electrodes (such as an insertion in GSU1330, a putative metal export protein) or defective in electrode reduction but demonstrating wild-type biofilm formation (due to an insertion upstream of the NHL domain protein GSU2505). An insertion in a putative ATP-dependent transporter (GSU1501) eliminated electrode colonization but not Fe(III) citrate reduction. A more complex phenotype was demonstrated by a mutant containing an insertion in a transglutaminase domain protein (GSU3361), which suddenly ceased to respire when biofilms reached approximately 50% of the wild-type levels. As most insertions were not in cytochromes but rather in transporters, two-component signaling proteins, and proteins of unknown function, this collection illustrates how biofilm formation and electron transfer are separate but complementary phenotypes, controlled by multiple loci not commonly studied in Geobacter spp.Geobacter sulfurreducens is a member of the metal-reducing Geobacteraceae family and was originally isolated based on its ability to transfer electrons from internal oxidative reactions to extracellular electron acceptors such as insoluble Fe(III) or Mn(IV) oxides (5). G. sulfurreducens is also able to use an electrode as its sole electron acceptor for respiration, a phenotype which has many possible biotechnological applications (28, 29), and serves as a useful tool for direct measurement of electron transfer rates (2, 31). As G. sulfurreducens was the first Geobacteraceae genome sequence available (34) and the only member of this family with a robust genetic system (7), it serves as a model organism for extracellular electron transfer studies.The proteins facilitating electron transfer to insoluble Fe(III) oxides by individual Geobacter cells and how these cells interact in multicellular biofilms are not fully understood. Many genes implicated in Fe(III) and electrode reduction were identified based on proteomic and microarray analysis of cultures grown with fumarate versus Fe(III) citrate as a terminal electron acceptor (9, 15, 35). More recently, similar expression data from Fe(III) oxide and electrode-grown cultures have also become available (8, 12, 16). In most extracellular electron transfer studies, outer membrane proteins (such as c-type cytochromes) have been the focus (4, 23, 27, 32), leading to targeted knockout studies of at least 14 cytochromes to date.To reduce an insoluble electron acceptor, Geobacter spp. must achieve direct contact with the substrate (36). While contact with small Fe(III) oxide particles may be transient, growth on Fe(III)-coated surfaces or electron-accepting electrodes requires biofilm formation (31, 39). For example, when G. sulfurreducens produces an exponentially increasing rate of electron transfer at an electrode, this demonstrates that all newly divided cells remain embedded in the growing, conductive biofilm (2, 31). Thus, in addition to the need for an array of outer membrane cytochromes, there is also a need for control of both cell-cell contact and cell-surface contact.While a genetic system for G. sulfurreducens has been developed, conjugal transfer of a plasmid or a transposon has not been reported (7). The broad-host-range cloning vector pBBR1MCS-2 has previously been electroporated into G. sulfurreducens, but its mobilization capabilities were not utilized (7). Similarly, a number of suicide vectors have been identified for G. sulfurreducens, but none have been used to deliver transposons for mutagenesis. mariner-based transposon mutagenesis systems have been successful in a variety of Bacteria and Archaea, producing random insertions (20, 25, 40, 41, 43, 46, 48, 49). For example, genes involved in Shewanella oneidensis cytochrome maturation were discovered using the modified transposon mini-Himar RB1 (3).In this work, we describe a system for the conjugal transfer of the pBBR1MCS family of plasmids from Escherichia coli to G. sulfurreducens, which allowed transposon mutagenesis based on pMiniHimar RB1. Under strictly anaerobic conditions, a library of insertion mutants was constructed and screened to identify genes putatively involved in attachment and Fe(III) citrate reduction. Approximately 8,000 insertion mutants were isolated, with insertions distributed throughout the G. sulfurreducens chromosome. Subsequent characterization revealed mutants defective in metal reduction but unaffected in all aspects of electrode reduction, as well as mutants able to reduce metals but incapable of electrode reduction. These observations greatly expand the list of Geobacter mutants with defects in respiration or biofilm formation, and this library serves as a resource for further screening of extracellular electron transfer phenotypes.     

Identification of Flagellar Motility Genes in Yersinia ruckeri by Transposon Mutagenesis

Here we demonstrate that flagellar secretion is required for production of secreted lipase activity in the fish pathogen Yersinia ruckeri and that neither of these activities is necessary for virulence in rainbow trout. Our results suggest a possible mechanism for the emergence of nonmotile biotype 2 Y. ruckeri through the mutational loss of flagellar secretion.Yersinia ruckeri is the etiologic agent of enteric redmouth disease, a disease of salmonid fish species that is found worldwide in areas where salmonid fish species are farmed (3, 6, 18, 20). Vaccines for enteric redmouth disease have been used successfully for nearly 3 decades and consist of immersion-applied, killed whole-cell preparations of motile serovar 1 Y. ruckeri strains (22). Recently though, outbreaks have been reported in vaccinated fish at trout farms in the United Kingdom (2), Spain (9), and the United States (1). The Y. ruckeri strains isolated from these outbreaks are uniformly atypical serovar 1 isolates lacking both flagellar motility and secreted lipase activity. These variants have been classified as Y. ruckeri biotype 2 (BT2) and are believed to have a reduced sensitivity to immersion vaccination (2). The objective of this study was to obtain a better understanding of the emergence of BT2 Y. ruckeri by identifying genetic elements necessary for expression of the Y. ruckeri flagellum and determining the role that the flagellum plays in virulence by using a rainbow trout infection model.