Levels of the Secreted Vibrio cholerae Attachment Factor GbpA Are Modulated by Quorum-Sensing-Induced Proteolysis

Vibrio cholerae is the etiologic agent of cholera in humans. Intestinal colonization occurs in a stepwise fashion, initiating with attachment to the small intestinal epithelium. This attachment is followed by expression of the toxin-coregulated pilus, microcolony formation, and cholera toxin (CT) production. We have recently characterized a secreted attachment factor, GlcNAc binding protein A (GbpA), which functions in attachment to environmental chitin sources as well as to intestinal substrates. Studies have been initiated to define the regulatory network involved in GbpA induction. At low cell density, GbpA was detected in the culture supernatant of all wild-type (WT) strains examined. In contrast, at high cell density, GbpA was undetectable in strains that produce HapR, the central regulator of the cell density-dependent quorum-sensing system of V. cholerae. HapR represses the expression of genes encoding regulators involved in V. cholerae virulence and activates the expression of genes encoding the secreted proteases HapA and PrtV. We show here that GbpA is degraded by HapA and PrtV in a time-dependent fashion. Consistent with this, ΔhapA ΔprtV strains attach to chitin beads more efficiently than either the WT or a ΔhapA ΔprtV ΔgbpA strain. These results suggest a model in which GbpA levels fluctuate in concert with the bacterial production of proteases in response to quorum-sensing signals. This could provide a mechanism for GbpA-mediated attachment to, and detachment from, surfaces in response to environmental cues.Vibrio cholerae has adapted to lifestyles in dual environments, allowing survival in aquatic locations, as well as the ability to colonize the epithelium of the human small intestine. This intestinal colonization by V. cholerae is a prerequisite for the disease cholera in humans. Intestinal colonization proceeds in a stepwise manner, initiating with attachment to the epithelial cell layer by multiple attachment factors (26). This stable attachment localizes the bacterium in an environment conducive for activation of subsequent virulence factors, including the toxin-coregulated pilus, a type IVb pilus that mediates cell-cell interactions and microcolony formation (27). Cholera toxin (CT) is produced and extracellularly secreted by bacteria within the microcolonies and enters into intestinal epithelial cells. CT causes the disruption of fluid and electrolyte balance and results in the voluminous rice water diarrhea characteristically observed with cholera patients.The ability of V. cholerae to bind to surfaces is crucial for the initial stages of colonization of both the aquatic and intestinal environments. Previous studies observing V. cholerae in the aquatic setting identified the ability of the bacteria to attach to zooplankton and phytoplankton, binding to surface structures that include chitin as a major component (7, 10, 11, 19, 21, 42). Chitin, a polymer consisting primarily of a β-1,4 linkage of GlcNAc monomers, is the most abundant aquatic carbon source and, when presented on the surfaces of zooplankton, aquatic exoskeletons, algae, and plants, provides a substrate for V. cholerae surface binding (8, 19-22). V. cholerae is able to break down chitin into carbon to use as a nutrient source via degradation by secreted chitinases (12). We have described a protein, GbpA (GlcNAc binding protein A), which facilitates the binding of V. cholerae to chitin, specifically to the chitin monomer GlcNAc, a sugar residue that is also found on the surface of epithelial cells (3, 16, 26). GbpA mediates binding to chitin, GlcNAc, and exoskeletons of Daphnia magna, as well as participates in effective intestinal colonization within the infant mouse model of cholera (26). GbpA is a secreted protein that exits the cell via the type 2 secretion system by which it mediates attachment by a yet uncharacterized mechanism (26). Previous studies examining the role of GbpA in binding to surfaces have been conducted utilizing various wild-type (WT) strains of V. cholerae, specifically O395 (26) and N16961 (33). These strains both are of the O1 serogroup but are differentially classified as classical (43) and El Tor biotypes (18), respectively. The classical biotype was responsible for the first six pandemics of cholera, whereas El Tor is the cause of the current pandemic (39).Quorum sensing regulates multiple bacterial processes, including virulence, formation of biofilms, and bioluminescence (25, 35, 36). In contrast to many other bacterial quorum-sensing systems, virulence gene expression and biofilm formation in V. cholerae is expressed under conditions of low cell density and repressed at high cell density (17, 35, 48). HapR, a member of the TetR family of regulatory proteins, is a central regulator on which the three parallel inputs of the V. cholerae quorum-sensing system converge (30, 35). During low-cell-density conditions, characteristic of growth within the aquatic environment or stages of early intestinal colonization, the quorum-sensing system is not engaged. Under conditions of high cell density, bacterial numbers and secreted autoinducer molecules are increased to a level that triggers the V. cholerae quorum-sensing system.HapR regulates gene function in two ways, serving as both an activator and repressor. At high cell density, HapR functions in the capacity of a repressor of the toxin-coregulated pilus and CT virulence cascade (29, 31) as well as a repressor of vps gene expression (17), preventing biofilm formation. In addition to repressing gene expression, at high cell density HapR activates the expression of genes encoding extracellularly secreted proteases HapA and PrtV (14, 17, 23, 45-47). HapA, also referred to as hemagglutinin/protease (HA/P), was first reported as a mucinase by Burnet (6) and later characterized as a zinc- and calcium-dependent metalloprotease (4). Extracellularly secreted via the V. cholerae type 2 secretion pathway (40), HA/P has been demonstrated to cleave fibronectin, lactoferrin, and mucin (15), as well as to participate in the activation of the CT A subunit (5). Further studies have led to the suggestion that HA/P is a detachase, critical for the release of V. cholerae from the surface of intestinal cells (2, 14, 38). PrtV is a second protease encoded by a gene that is activated by HapR (47). It has been demonstrated to be essential for both V. cholerae killing of Caenorhabditis elegans, as well as protecting V. cholerae from predator grazing by various flagellates (32, 45).The data presented here indicate that HapA and PrtV participate in the targeted degradation of the attachment factor GbpA. We demonstrate that GbpA is present during the logarithmic phase of growth and conditions of low cell density but that it is not present in the supernatant of high-cell-density cultures of strains that express functional HapR. Further studies revealed that during stages of high cell density, proteases HapA and PrtV, encoded by HapR-activated genes, are responsible for GbpA degradation in the culture supernatant. These findings suggest that the attachment factor GbpA is potentially a ligand targeted for protease degradation during the epithelial detachment process. This process could aid in the release of V. cholerae back into the aquatic environment following late stages of intestinal colonization.     

Relatedness of Vibrio cholerae O1/O139 Isolates from Patients and Their Household Contacts,Determined by Multilocus Variable-Number Tandem-Repeat Analysis

The genetic relatedness of Vibrio cholerae O1/O139 isolates obtained from 100 patients and 146 of their household contacts in Dhaka, Bangladesh, between 2002 and 2005 was assessed by multilocus variable-number tandem-repeat analysis. Isolate genotypes were analyzed at five loci containing tandem repeats. Across the population, as well as within households, isolates with identical genotypes were clustered in time. Isolates from individuals within the same household were more likely to have similar or identical genotypes than were isolates from different households, but even within a household, isolates from different individuals often had different genotypes. When household contacts were sampled regularly for 3 weeks after the illness of the household index patient, isolates with genotypes related to the index patient appeared in contacts, on average, ∼3 days after the index patient, while isolates with unrelated genotypes appeared in contacts ∼6 days after. Limited data revealed that multiple isolates from the same individual collected within days of each other or even from a single stool sample may have identical, similar, or unrelated genotypes as well. Our results demonstrate that genetically related V. cholerae strains cluster in local outbreaks but also suggest that multiple distinct strains of V. cholerae O1 may circulate simultaneously within a household.Vibrio cholerae is the etiologic agent of cholera, a secretory diarrheal disease with a high mortality rate in humans if untreated (25). Serogroups of V. cholerae, a motile, Gram-negative, curved rod, can be defined serologically by the O side chain of the lipopolysaccharide (LPS) component of the outer membrane (9). V. cholerae is found in a variety of forms in aquatic ecosystems (41, 42), and more than 200 different serogroups have been isolated, mostly from environmental sources (45). However, the vast majority of V. cholerae strains that cause the clinical disease cholera belong to serogroup O1 or O139 (37, 42). V. cholerae O1, the historical agent of epidemic and pandemic cholera and the current leading cause of cholera both globally and in Bangladesh (42), is classified into two major biotypes, classical and El Tor (44), and two major serotypes, Ogawa and Inaba (48). The current global pandemic is caused by V. cholerae O1 El Tor. A second pathogenic serogroup, O139, emerged in the Bengal region in 1992 by horizontal transfer of new LPS biosynthesis-encoding genes into the El Tor biotype (1, 4). This new serogroup continues to cocirculate with El Tor V. cholerae O1 serotypes Ogawa and Inaba as a cause of disease in humans, although it accounts for a smaller proportion of all cholera now than in its first years of circulation (16, 20). Recently, comparative genomics has revealed an extensive amount of lateral gene transfer between strains, suggesting that genomic classification may be an alternative to serogrouping for classifying pathogenic V. cholerae strains (11).Toxigenic V. cholerae may be present in environmental sources in regions of endemicity and emerge, often seasonally, to cause cholera in humans (12, 18). Once an outbreak has begun, organisms from one infected individual are more infectious for the next individual, a property termed hyperinfectivity, and these forms may be able to pass directly from human to human through fecal-oral contamination (35). However, because vibrio organisms are difficult to isolate from implicated environmental or domestic water sources (28, 29), little is known about the diversity of V. cholerae in inocula that cause human infection.Established laboratory methods for differentiating V. cholerae strains, apart from serogrouping and serotyping, include rRNA restriction fragment length polymorphism (ribotyping), pulsed-field gel electrophoresis (PFGE), and multilocus sequence typing (MLST). These methods, however, have a limited capacity to differentiate between pathogenic V. cholerae strains, as clinical isolates are relatively genetically monomorphic. For instance, V. cholerae O1 comprises approximately 30 ribotypes (39); however, only a few ribotypes are common in clinical isolates, ribotypes evolve slowly, and all isolates of a given pathogenic V. cholerae serotype in a local area over a period of multiple years often belong to a single ribotype (8, 14, 17). In a broad sampling of 154 V. cholerae isolates from Bangladesh and worldwide over several decades, only 15 ribotypes were identified, and of these, many were found in nonpathogenic environmental isolates only; only five ribotypes were associated with the V. cholerae O1 El Tor biotype that currently predominates as the cause of clinical disease, while pathogenic isolates of serogroup O139 were indistinguishable from each other by ribotype (19).PFGE, in which restriction endonuclease digestion of genomic DNA generates mutation-sensitive banding patterns, is often more sensitive than ribotyping in detecting strain variation (7, 34, 51) and detects extensive genetic variation within nonpathogenic V. cholerae serogroups (3, 46). However, PFGE types change slowly and are useful primarily for distinguishing between strains in different pandemics or between different continental branches of those pandemics. In an analysis of 180 mostly western-hemisphere isolates (7), PFGE differences had developed from a prior pandemic strain over the 30 years since its arrival in Latin America, but a new strain that had been causing disease for 2 years still had only a single PFGE type across the 64 isolates analyzed. Similarly, in a Japanese study (2), although 19 PFGE types were identified among O1 isolates, the majority of the domestic isolates, along with several imported isolates, belonged to a single PFGE type.Further differentiation between V. cholerae isolates is achievable by MLST, which characterizes isolates by internal DNA sequences in selected housekeeping genes (32). Nevertheless, epidemic strains also cluster tightly in this typing scheme (5, 32) and the method has been useful primarily for determining relationships between nontoxigenic strains (36) or for linking regional outbreaks (which typically appear monoclonal by these methods) with the pandemic strain responsible (5, 33).Although these methods have distinguished major pandemic clones from other nonpathogenic human and environmental isolates of V. cholerae, the near clonality of pathogenic O1 and O139 strains means that established methods may not provide sufficiently robust differentiation of these genetically similar pathogenic strains to answer important epidemiological questions. Therefore, there is a need for other methods that can distinguish among clinical O1 and O139 isolates and track the epidemiology of outbreaks in a restricted geographic area on a shorter time scale.Multilocus variable-number tandem-repeat (VNTR) analysis (MLVA) is one method that may be useful for differentiating between pathogenic V. cholerae O1 and O139 strains that would be indistinguishable by other techniques (15). This method examines short repeating DNA segments at various locations in the genome that can vary in number at each location and uses the number of repeats at each varying locus as a fingerprint to distinguish between isolates.Escherichia coli is the paradigm organism for demonstrating the value of the MLVA method. Noller et al. (38) showed that E. coli O157 isolates that were indistinguishable by MLST could be distinguished to some extent by PFGE but that MLVA distinguished between isolates that had the same PFGE type and did so in a manner consistent with the known epidemiology of the isolates (38a). In addition, machine-scored VNTR assays have been demonstrated to be robust and portable and to discriminate clearly between isolates by using relatively few loci, therefore limiting the effect of compounding genotyping errors (6).For V. cholerae, five VNTR loci have been identified (15), and the initial application of MLVA at those loci has demonstrated distinct populations of clinical isolates of V. cholerae in different geographic regions within Bangladesh and India (23, 47). Predominant isolates in each of two rural Bangladeshi regions varied gradually over a time scale of months to years (47), and isolates collected from India over a 15-year period varied widely, with individual MLVA types clustering in time and place—some with widespread dissemination and others with limited local occurrence only (23). MLVA has also been used to classify hybrid and altered V. cholerae variants and to demonstrate their genetic distance from the pandemic El Tor strain (10). Use of the MLVA method for epidemiologic study of cholera requires that V. cholerae VNTR alleles remain reasonably stable during bacterial replication in patients or in laboratory culture after isolation. Some degree of stability of two of the five loci used in V. cholerae MLVA has been demonstrated previously by serial passage in vitro through four overnight cultures (15). In this study, we used MLVA to examine V. cholerae O1 and O139 isolates obtained from infected patients and their household contacts—including multiple isolates from the same individual and isolates from multiple individuals within the same household—in a large city where cholera is endemic.     

A Conserved Acetyl Esterase Domain Targets Diverse Bacteriophages to the Vi Capsular Receptor of Salmonella enterica Serovar Typhi

A number of bacteriophages have been identified that target the Vi capsular antigen of Salmonella enterica serovar Typhi. Here we show that these Vi phages represent a remarkably diverse set of phages belonging to three phage families, including Podoviridae and Myoviridae. Genome analysis facilitated the further classification of these phages and highlighted aspects of their independent evolution. Significantly, a conserved protein domain carrying an acetyl esterase was found to be associated with at least one tail fiber gene for all Vi phages, and the presence of this domain was confirmed in representative phage particles by mass spectrometric analysis. Thus, we provide a simple explanation and paradigm of how a diverse group of phages target a single key virulence antigen associated with this important human-restricted pathogen.Bacteriophages are dependent for their survival on the presence of susceptible host bacteria in their environment. The first stage of recognition of the bacterial host normally involves binding of a specific phage attachment protein to a receptor molecule on the bacterial surface. Bacteria can evade phage infection by various mechanisms, including accumulating escape mutations in the receptor, acquiring phage inhibitory proteins, or directly modifying the receptor, for example, lipopolysaccharide (LPS) (43). In addition, phage can adapt to recognize different receptors through a number of genetic mechanisms involving evolution of their attachment proteins (20) or by tropism switching (21, 22).Phage can exploit capsular exopolysaccharides as receptors, some of which are associated with virulence in pathogens (5, 23, 35). A notable example is the Vi capsule found in Salmonella enterica serovar Typhi (S. Typhi) and some isolates of S. Dublin and Citrobacter freundii (29). The Vi capsule of S. Typhi is an important virulence factor, facilitating the bacteria to escape opsonization and other forms of immune surveillance (14, 30) as well as potentially helping the bacteria to evade phage that would otherwise target the O:9 LPS, which the Vi capsule can, at least in part, mask (27). In the middle of the last century, a set of lytic phages were isolated that utilized the Vi capsule as a receptor (6). These Vi phages were exploited in diagnostic laboratories as a “typing set” to distinguish between different strains of S. Typhi isolated from typhoid patients (8). A secondary typing set was generated from Vi typing phage II by adapting this phage to grow on different S. Typhi hosts (6). At this time, typhoid was still common in many parts of Europe and North America, and clinicians tested some of these Vi phages for their potential in phage therapy experiments with human typhoid patients (11). Although this work showed significant promise, phage therapy gradually disappeared from clinical practice in many countries as antibiotics became readily available.S. Typhi is a monophyletic serovar of the broad enteric species S. enterica (16, 31). Interestingly, S. Typhi is host restricted to humans and has no known zoonotic source. Unlike many other S. enterica serovars, S. Typhi normally causes a systemic infection and does not persist in the intestine efficiently, where high levels of bacteriophage are present. Although it is rare in developed countries, S. Typhi is still a significant cause of mortality in many developing countries (26). Most current clinical isolates are Vi positive when first isolated (2), but it is noteworthy that the Vi capsule biosynthesis and export genes are carried by an operon within a potentially unstable island called Salmonella pathogenicity island 7 (SPI-7) (29).Although some phenotypic characterization of the Vi phage has been undertaken (1), very little has been performed at the molecular level. We previously showed that Vi typing phage II-E1 is related to the S. Typhimurium phage ES18 (4, 28), with synteny in many capsid and tail proteins. We have now further characterized the other members of this S. Typhi Vi phage collection, designated types I, III, IV, V, VI, and VII (abbreviated from here on as Vi phages I, III, IV, etc.) (6, 11), by utilizing electron microscopy and genomic analysis. This analysis shows that this collection of Vi phages represents a diverse group of bacteriophages that have adapted to growth on S. Typhi through convergent evolution within their tail spike protein genes and the acquisition of conserved acetyl esterase domains.     

Temperature-Dependent Phage Resistance of Listeria monocytogenes Epidemic Clone II

Listeria monocytogenes epidemic clone II (ECII) has been responsible for two multistate outbreaks in the United States in 1998-1999 and in 2002, in which contaminated ready-to-eat meat products (hot dogs and turkey deli meats, respectively) were implicated. However, ecological adaptations of ECII strains in the food-processing plant environment remain unidentified. In this study, we found that broad-host-range phages, including phages isolated from the processing plant environment, produced plaques on ECII strains grown at 37°C but not when the bacteria were grown at lower temperatures (30°C or below). ECII strains grown at lower temperatures were resistant to phage regardless of the temperature during infection and subsequent incubation. In contrast, the phage susceptibility of all other tested strains of serotype 4b (including epidemic clone I) and of strains of other serotypes and Listeria species was independent of the growth temperature of the bacteria. This temperature-dependent phage susceptibility of ECII bacteria was consistently observed with all surveyed ECII strains from outbreaks or from processing plants, regardless of the presence or absence of cadmium resistance plasmids. Phages adsorbed similarly on ECII bacteria grown at 25°C and at 37°C, suggesting that resistance of ECII strains grown at 25°C was not due to failure of the phage to adsorb. Even though the underlying mechanisms remain to be elucidated, temperature-dependent phage resistance may represent an important ecological adaptation of L. monocytogenes ECII in processed, cold-stored foods and in the processing plant environment, where relatively low temperatures prevail.Listeria monocytogenes is responsible for an estimated 2,500 cases of serious food-borne illness (listeriosis) and 500 deaths annually in the United States. It affects primarily pregnant women, newborns, the elderly, and adults with weakened immune systems. L. monocytogenes is frequently found in the environment and can grow at low temperatures, thus representing a serious hazard for cold-stored, ready-to-eat foods (18, 31).Two multistate outbreaks of listeriosis in the United States, in 1998-1999 and in 2002, respectively, were caused by contaminated ready-to-eat meats (hot dogs and turkey deli meats, respectively) contaminated by serotype 4b strains that represented a novel clonal group, designated epidemic clone II (ECII) (3, 4). ECII strains have distinct genotypes as determined by pulsed-field gel electrophoresis and various other subtyping tools, and harbor unique genetic markers (6, 8, 11, 19, 34). The genome sequencing of one of the isolates (L. monocytogenes H7858) from the 1998-1999 outbreak revealed the presence of a plasmid of ca. 80 kb (pLM80), which harbored genes mediating resistance to the heavy metal cadmium as well as genes conferring resistance to the quaternary ammonium disinfectant benzalkonium chloride (10, 29).Listeria phages (listeriaphage) have long been used for subtyping purposes (33), and extensive research has focused on the genomic characterization (2, 24, 26, 35), transducing potential (14), and biotechnological applications of selected phages (25). In addition, applications of listeriaphage as biocontrol agents in foods and the processing plant environment have been investigated (12, 15, 22). However, limited information exists on phages from processing plant environments and on the impact of environmental conditions on susceptibility of L. monocytogenes strains representing the major epidemic-associated clonal groups to such phages. We have found that strains harboring ECII-specific genetic markers can indeed be recovered from the environment of turkey-processing plants (9). Furthermore, environmental samples from such processing plants yielded phages with broad host range, which were able to infect L. monocytogenes strains of various serotypes, and different Listeria species (20). In this study, we describe the impact of growth temperature on susceptibility of L. monocytogenes ECII strains to phages, including phages isolated from turkey-processing plant environmental samples.     

Crystal Structure of ORF12 from Lactococcus lactis Phage p2 Identifies a Tape Measure Protein Chaperone

We report here the characterization of the nonstructural protein ORF12 of the virulent lactococcal phage p2, which belongs to the Siphoviridae family. ORF12 was produced as a soluble protein, which forms large oligomers (6- to 15-mers) in solution. Using anti-ORF12 antibodies, we have confirmed that ORF12 is not found in the virion structure but is detected in the second half of the lytic cycle, indicating that it is a late-expressed protein. The structure of ORF12, solved by single anomalous diffraction and refined at 2.9-Å resolution, revealed a previously unknown fold as well as the presence of a hydrophobic patch at its surface. Furthermore, crystal packing of ORF12 formed long spirals in which a hydrophobic, continuous crevice was identified. This crevice exhibited a repeated motif of aromatic residues, which coincided with the same repeated motif usually found in tape measure protein (TMP), predicted to form helices. A model of a complex between ORF12 and a repeated motif of the TMP of phage p2 (ORF14) was generated, in which the TMP helix fitted exquisitely in the crevice and the aromatic patches of ORF12. We suggest, therefore, that ORF12 might act as a chaperone for TMP hydrophobic repeats, maintaining TMP in solution during the tail assembly of the lactococcal siphophage p2.During industrial milk fermentation, Lactococcus lactis cells are added to transform milk into an array of fermented products such as cheese. However, this manufacturing process may be impaired by lytic phages present in the factory environment as well as in the milk itself (30). Due to the destructive effects of phage infections on bacterial fermentation, much effort has been undertaken to isolate and study the biodiversity of these bacteriophages. Lactococcal bacteriophages belong to at least 10 different genetically distinct species of double-stranded DNA viruses (9). Of them, three lactococcal phage species, all belonging to the Siphoviridae family, are the major source of problems in milk fermentation, namely, the 936, P335, and c2 species (7, 28, 29). Furthermore, members of the 936 species are by far responsible for the majority of infections (50 to 80%) (1, 24, 41). Numerous phages of the 936 species have been isolated, and several have been characterized at the genome level (25). However, little is known concerning their molecular mechanisms of infection, although we recently solved the structure of the receptor-binding protein (RBP) of our model 936-like phage, namely, the virulent phage p2 (38, 43), and of phages belonging to the P335 species (27, 34, 37, 38).As with all viruses, bacteriophage genomes are quite compact, leaving little room for noncoding sequences (4). In fact, phage genes are disposed in an operon-type organization (4), and the order of genes corresponds to the different phases of the infection cycle. Moreover, genes are often in clusters (referred to as modules), with gene products from adjacent genes generally found to interact with each other. Interestingly, phage genome organization, including individual gene order, is often conserved within a given species, particularly within the Siphoviridae family. In the case of L. lactis virulent phages belonging to the 936 or P335 species, this principle applies particularly to the morphogenesis gene module, which includes all the genes coding for the phage structural protein genes. For the tail assembly, a module comprises a set of genes between the portal protein, which is connecting the tail to the capsid, and the RBP, which is located at the tip of the tail and is involved in host recognition (39, 43).The characterization of tail assembly genes of lactococcal phages has been more extensive for temperate siphophages belonging to the P335 species (27, 34, 37, 38). Because of the similarities in genome organization, the findings in this phage species can, in some cases, be used as clues toward understanding the morphology of 936-like phages. For the temperate phage Tuc2009 (P335 species), all structural proteins required for tail and baseplate assembly have been identified (27, 34, 37, 38). Genes located between those coding for the tape measure protein (TMP) and BppL (RBP) were identified as corresponding to components of the baseplate structure, located at the tail distal end. Furthermore, a gene coding for the major tail protein (MTP) was also identified at a position upstream from tmp. Between the genes coding for the MTP and those coding for the TMP in Tuc2009 are two gene products identified as gpG and gpGT, which are not present in the phage particle. These two proteins were named based on their likely role analogous to the tail assembly proteins present in coliphage lambda, a model virus belonging to the Siphoviridae family (21, 27, 47). gpGT has an essential role in lambda tail assembly, acting prior to tail shaft assembly, while the role of gpG in tail assembly is not known (21). Both gpG and gpGT are also absent from mature lambda virions (21). It has been argued that they may act as assembly chaperones (47).A close examination of 936 genomes indicates the presence of two genes coding for gpG and gpGT-like proteins. Analysis of the phage p2 genome, closely related to that of lactococcal phage sk1 (6), revealed that the putative tail assembly proteins could correspond to gene products ORF12 and ORF13. These two genes are followed by the TMP gene corresponding to orf14, other genes coding for other structural proteins, and the RBP gene orf18. During our ongoing investigation of the structure of phage p2, we report here the cloning, expression, and crystal structure of ORF12 in order to decipher its role in the tail assembly process.     

Mutagenesis and Functional Characterization of the RNA and Protein Components of the toxIN Abortive Infection and Toxin-Antitoxin Locus of Erwinia

Bacteria are constantly challenged by bacteriophage (phage) infection and have developed multiple adaptive resistance mechanisms. These mechanisms include the abortive infection systems, which promote “altruistic suicide” of an infected cell, protecting the clonal population. A cryptic plasmid of Erwinia carotovora subsp. atroseptica, pECA1039, has been shown to encode an abortive infection system. This highly effective system is active across multiple genera of gram-negative bacteria and against a spectrum of phages. Designated ToxIN, this two-component abortive infection system acts as a toxin-antitoxin module. ToxIN is the first member of a new type III class of protein-RNA toxin-antitoxin modules, of which there are multiple homologues cross-genera. We characterized in more detail the abortive infection phenotype of ToxIN using a suite of Erwinia phages and performed mutagenesis of the ToxI and ToxN components. We determined the minimal ToxI RNA sequence in the native operon that is both necessary and sufficient for abortive infection and to counteract the toxicity of ToxN. Furthermore, site-directed mutagenesis of ToxN revealed key conserved amino acids in this defining member of the new group of toxic proteins. The mechanism of phage activation of the ToxIN system was investigated and was shown to have no effect on the levels of the ToxN protein. Finally, evidence of negative autoregulation of the toxIN operon, a common feature of toxin-antitoxin systems, is presented. This work on the components of the ToxIN system suggests that there is very tight toxin regulation prior to suicide activation by incoming phage.Interactions between bacteria and their natural parasites, bacteriophages (phage), have global-scale effects (42). Although the vast majority of the phage infections, which occur at a rate of 10²⁵ infections per s (26), are overlooked by humans, en masse they affect environmental nutrient cycling (18) and have long been known to be vital to the spread and continued diversity of microbial genes (11). A tiny proportion of this activity can directly affect our everyday activities; the lysis of bacteria following phage infection has potential medical benefits, such as use in phage therapy (30), or can be economically damaging, as it is in cases of bacterial fermentation failure (for instance, in the dairy industry [31]).Gram-positive lactococcal strains used in dairy fermentation have been shown to naturally harbor multiple phage resistance mechanisms (16). These mechanisms can be broadly classed as systems which (i) prevent phage adsorption, (ii) interfere with phage DNA injection, (iii) restrict unmodified DNA, and (iv) induce abortive infection. There is also an increasing amount of research that focuses on new systems that use clustered regularly interspaced short palindromic repeats to mediate phage resistance (3). Clustered regularly interspaced short palindromic repeats and associated proteins, although widespread in archaea and bacteria (39), have not been identified yet in lactococcal strains (23).The abortive infection (Abi) systems induce cell death upon phage infection and often rely on a toxic protein to cause “altruistic cell suicide” in the infected host (16). Although Abi systems have been studied predominantly using lactococcal systems, because of their potential economic importance (8) they have been identified in some gram-negative species, such as Escherichia coli, Vibrio cholerae, Shigella dysenteriae, and Erwinia carotovora (9, 14, 36, 38). The prr and lit systems of E. coli have been studied at the molecular level, and their mode of action and mode of activation by incoming phage have been identified (2, 37, 38). In contrast, lactococcal Abi systems have been characterized mainly by the range of phages actively aborted and the scale of these effects, and the Abi systems have been grouped based on general modes of action (8, 12). More recently, research has begun to identify more specific lactococcal Abi activities at the molecular level (12, 17) and has revealed phage activation of two such Abi systems (6, 21).An Abi system was identified on plasmid pECA1039, which was isolated from a strain of the phytopathogen E. carotovora subsp. atroseptica (14). Designated ToxIN, this two-component Abi system operates as a novel protein-RNA toxin-antitoxin (TA) system to abort phage infection in multiple gram-negative bacteria. The toxic activity of the ToxN protein was inhibited by ToxI RNA, which consists of 5.5 direct repeats of 36 nucleotides. It is now recognized that TA loci, which were originally characterized as “plasmid addiction” modules (43), are widely distributed in the chromosomes of archaea and bacteria (19) and in phage genomes, such as that of the extrachromosomal prophage P1 (27). As a result, the precise biological role of TA systems is under debate (29). It is clear, however, that they can be effective phage resistance systems, as is the case for toxIN in E. carotovora subsp. atroseptica (14) and hok/sok and mazEF in E. coli (22, 33). Previously characterized TA systems operate with both components interacting as either RNAs (e.g., hok/sok) (type I) or proteins (e.g., MazE and MazF) (type II). In this study, a mutagenesis approach was used to further characterize the ToxI and ToxN components of the new (type III) protein-RNA TA Abi system. The regulation of the operon and the mode of phage activation were also examined.     

Quadruplex Real-Time PCR Assay for Detection and Identification of Vibrio cholerae O1 and O139 Strains and Determination of Their Toxigenic Potential

Vibrio cholerae is a natural inhabitant of the aquatic environment. However, its toxigenic strains can cause potentially life-threatening diarrhea. A quadruplex real-time PCR assay targeting four genes, the cholera toxin gene (ctxA), the hemolysin gene (hlyA), O1-specific rfb, and O139-specific rfb, was developed for detection and differentiation of O1, O139, and non-O1, non-O139 strains and for prediction of their toxigenic potential. The specificity of the assay was 100% when tested against 70 strains of V. cholerae and 31 strains of non-V. cholerae organisms. The analytical sensitivity for detection of toxigenic V. cholerae O1 and O139 was 2 CFU per reaction with cells from pure culture. When the assay was tested with inoculated water from bullfrog feeding ponds, 10 CFU/ml could reliably be detected after culture for 3 h. The assay was more sensitive than the immunochromatographic assay and culture method when tested against 89 bullfrog samples and 68 water samples from bullfrog feeding ponds. The applicability of this assay was confirmed in a case study involving 15 bullfrog samples, from which two mixtures of nontoxigenic O1 and toxigenic non-O1/non-O139 strains were detected and differentiated. These data indicate that the quadruplex real-time PCR assay can both rapidly and accurately detect/identify V. cholerae and reliably predict the toxigenic potential of strains detected.Occasional outbreaks and pandemics caused by the bacterium Vibrio cholerae indicate that cholera is still a global threat to public health (1, 2, 6, 13, 14). The disease may become life-threatening if appropriate therapy is not undertaken quickly. Of the more than 200 serogroups of V. cholerae that have been identified (28), two serogroups, O1 and O139, cause epidemic and pandemic cholera (14), whereas non-O1, non-O139 serogroups are associated only with sporadic, isolated outbreaks of diarrhea (3, 23). O1 and O139 strains are also categorized as toxin-producing and non-toxin-producing strains. The toxin-producing strains cause life-threatening secretory diarrhea, while the non-toxin-producing isolates elicit only mild diarrhea. These differences among the serogroups of V. cholerae demand rapid diagnostic tests capable of both distinguishing O1 and O139 from other serogroups and differentiating toxin-producing from nonproducing isolates (20).PCR has become a molecular alternative to culture, microscopy, and biochemical testing for the identification of bacterial species (27). Many PCR methods have been developed for characterization of serogroups (O1 and/or O139), biotypes, and the toxigenic potential of V. cholerae strains (7, 11, 15, 19, 21, 22, 24-26). However, these conventional PCR methods require gel electrophoresis for product analysis and are therefore not suitable for routine use due to the risk of carryover contamination, low throughput, and intensive labor.Real-time PCR allows detection of amplification product accumulation through fluorescence intensity changes in a closed-tube setting, which is faster and more sensitive than conventional PCR and has become increasingly popular in clinical microbiology laboratories. Moreover, when multicolor fluorophore-labeled probes and/or melting curve analysis is used, multiplex real-time PCR can be designed to simultaneously detect many different target genes in a single reaction tube (8). So far, the majority of published real-time PCR assays for V. cholerae detect no more than two genes simultaneously (4, 8, 18), which precludes their use for simultaneous serogroup and toxin status determination. Recent reports show that multiplex real-time PCR greatly improves specificity and sensitivity for the detection of V. cholerae through either melting curve analysis (9) or using differently fluorophore-labeled probes (10).In the present work, we report the development of a quadruplex real-time PCR assay that enables simultaneous serogroup differentiation and toxigenic potential detection. By using four different fluorophore-labeled probes, which target hlyA, O1-specfic rfb, O139-specific rfb, and ctxA, the quadruplex assay can reveal whether the target is an O1, O139, or non-O1/non-O139 strain and whether the bacterium detected is capable of producing toxins. We report that by alleviating primer dimer formation by use of a homotag-assisted nondimer system (HANDS) (5), we were able to retain the analytical sensitivity of uniplex PCR and successfully differentiated serogroups and toxigenic potentials from aquatic animal and environmental samples.     

Quantification of Shiga Toxin-Converting Bacteriophages in Wastewater and in Fecal Samples by Real-Time Quantitative PCR

Shiga toxin-converting bacteriophages (Stx phages) are involved in the pathogenicity of some enteric bacteria, such as Escherichia coli O157:H7. Stx phages are released from their bacterial hosts after lytic induction and remain free in the environment. Samples were analyzed for the presence of free Stx phages by an experimental approach based on the use of real-time quantitative PCR (qPCR), which enables stx to be detected in the DNA from the viral fraction of each sample. A total of 150 samples, including urban raw sewage samples, wastewater samples with fecal contamination from cattle, pigs, and poultry, and fecal samples from humans and diverse animals, were used in this study. Stx phages were detected in 70.0% of urban sewage samples (10 to 10³ gene copies [GC] per ml) and in 94.0% of animal wastewater samples of several origins (10 to 10¹⁰ GC per ml). Eighty-nine percent of cattle fecal samples were positive for Stx phages (10 to 10⁵ GC per g of sample), as were 31.8% of other fecal samples of various origins (10 to 10⁴ GC per g of sample). The stx₂ genes and stx₂ variants were detected in the viral fraction of some of the samples after sequencing of stx₂ fragments amplified by conventional PCR. The occurrence and abundance of Stx phages in the extraintestinal environment confirm the role of Stx phages as a reservoir of stx in the environment.Shiga toxin-producing Escherichia coli (STEC) is associated with diarrhea, hemorrhagic enterocolitis, and hemolytic-uremic syndrome in humans (46). Escherichia coli serotype O157:H7 is the main cause of these diseases, although other serotypes of E. coli and other enterobacteria species have been described (36). These E. coli serotypes produce at least two immunologically distinct Shiga toxins, called Stx1 and Stx2. In addition to these, several variations of these toxins have been reported in recent years, showing differences in virulence and distribution in the host populations examined (48, 51). Shiga toxin genes are carried by temperate bacteriophages (19, 35). Stx-encoding bacteriophages investigated to date consist of double-stranded DNA and have lambdoid genetic structures (19, 27, 32, 37, 47). The induction and regulation of these phages are directly involved in the production of toxin and, therefore, in the pathogenicity of the strains (8, 50). Stx phages are efficient vectors for the transfer of toxin genes, being able to convert nonpathogenic bacterial hosts into Stx-producing strains by transduction of stx, as has been demonstrated under various conditions (1, 4, 27, 28, 41, 49).Most of the reported outbreaks of STEC infections are associated with cattle products (10, 17), with the consumption of contaminated foods (10, 34), and with several waterborne infections (30). Stx phages are present within fecally contaminated aquatic environments (9, 28, 30, 32, 45). Moreover, a high percentage of STEC strains present in extraintestinal environments carry inducible Stx phages (14, 30).As individuals infected with STEC strains shed large quantities of Stx phages in feces, Stx phages should be prevalent in the environment, as are other viruses transmitted by the fecal-oral route (5, 11) or bacteriophages infecting bacteria present in the intestinal tract (16, 23). Moreover, those STEC strains isolated from food and animals carry inducible Stx phages (24, 27, 42). The virulence profiles of STEC strains isolated from food also suggest the presence of inducible Stx phages (10).Stx phages in sewage have been detected by nested PCR (28, 29, 31). However, to quantify them, the most probable number (MPN) method was applied, which allows only a rough estimate of the amount of Stx phages present in the sample. To assess the number of Stx phages accurately, real-time quantitative PCR (qPCR) technology is a useful tool. This technology is both sensitive and specific, and it gives accurate quantitative results (25). Comparison with a standard enables the number of copies of stx to be quantified, which can then be translated into the number of Stx phage particles.Little is known about the prevalence of phages carrying stx in fecal samples. The data available on the numbers of these phages in fecally contaminated water samples were only roughly estimated. The first step to evaluate the role of Stx phages in the environment as lateral gene transfer vectors is to know the extent of these viruses in the environment. The aim of this study is to report quantitative data on the abundance of Stx phages in urban sewage samples, in wastewater samples from cattle, pigs, and poultry, and in diverse fecal samples, calculated by means of a methodology based on qPCR.     

The Autolysin LytA Contributes to Efficient Bacteriophage Progeny Release in Streptococcus pneumoniae

Most bacteriophages (phages) release their progeny through the action of holins that form lesions in the cytoplasmic membrane and lysins that degrade the bacterial peptidoglycan. Although the function of each protein is well established in phages infecting Streptococcus pneumoniae, the role—if any—of the powerful bacterial autolysin LytA in virion release is currently unknown. In this study, deletions of the bacterial and phage lysins were done in lysogenic S. pneumoniae strains, allowing the evaluation of the contribution of each lytic enzyme to phage release through the monitoring of bacterial-culture lysis and phage plaque assays. In addition, we assessed membrane integrity during phage-mediated lysis using flow cytometry to evaluate the regulatory role of holins over the lytic activities. Our data show that LytA is activated at the end of the lytic cycle and that its triggering results from holin-induced membrane permeabilization. In the absence of phage lysin, LytA is able to mediate bacterial lysis and phage release, although exclusive dependence on the autolysin results in reduced virion egress and altered kinetics that may impair phage fitness. Under normal conditions, activation of bacterial LytA, together with the phage lysin, leads to greater phage progeny release. Our findings demonstrate that S. pneumoniae phages use the ubiquitous host autolysin to accomplish an optimal phage exiting strategy.Streptococcus pneumoniae (pneumococcus), a common and important human pathogen, is characterized by the high incidence of lysogeny in isolates associated with infection (34, 44). Pneumococcal bacteriophages (phages) share with the majority of bacteriophages infecting other bacterial species the “holin-lysin” system to lyse the host cell and release their progeny at the end of the lytic cycle. Genes encoding both holins and lysins (historically termed “endolysins”) are indeed found in the genomes of all known pneumococcal phages (8, 28, 31, 37). Supporting this mechanism, a lytic phenotype in the heterologous Escherichia coli system was achieved only by the simultaneous expression of the Ejh holin and the Ejl endolysin of pneumococcal phage EJ-1 (8). When these proteins were independently expressed, cellular lysis was not perceived. Similar results were shown for pneumococcal phage Cp-1, not only in E. coli, but also in the pneumococcus itself (28).Phage lysins destroy the pneumococcal peptidoglycan network due to their muralytic activity, whereas holins have been shown in S. pneumoniae to form nonspecific lesions (8), most likely upon a process of oligomerization in the cytoplasmic membrane, as observed for the E. coli phage λ (13, 14, 43). It was generally proposed that holin lesions allow access of phage lysins to the cell wall (52, 54), as the majority of phage lysins, including the pneumococcal endolysins, lack a typical N-terminal secretory signal sequence and transmembrane domains (8). However, recent evidence also highlights the possibility for a holin-independent targeting of phage lysins to the cell wall, where holin lesions seem to be crucial for the activation of the already externalized phage lysins (42, 50, 51). Regardless of the mechanism operating in S. pneumoniae to activate phage lysins, holin activity compromises membrane integrity.Pneumococcal cells present their own autolytic activity, mainly due to the presence of a powerful bacterial cell wall hydrolase, LytA (an N-acetylmuramoyl-l-alanine-amidase), responsible for bacterial lysis under certain physiological conditions (47). Although other bacterial species also encode peptidoglycan hydrolases, the extensive lysis shortly after entering stationary phase caused by LytA is a unique feature of S. pneumoniae. Interestingly, LytA is translocated across the cytoplasmic membrane to the cell wall—where it remains inactive—in spite of the absence of a canonical N-terminal sequence signal (7). In the cell wall, autolysin activities are tightly regulated by mechanisms that seem to be related to the energized state of the cell membrane. In fact, depolarizing agents are able to trigger autolysis in Bacillus subtilis (16, 17), and bacteriocin-induced depletion of membrane potential triggers autolysis of some species of the genera Lactococcus and Lactobacillus, closely related to streptococci (29). It is therefore possible that the holin-inflicted perturbations of the S. pneumoniae cytoplasmic membrane upon the induction of the lytic cycle may trigger not only the lytic activity of the phage lysin, but also that of inactive LytA located in the cell wall. Accordingly, LytA could also participate in the release of phage particles at the end of the infectious cycle, especially considering its powerful autolytic activity. Previous studies have suggested a role for the host autolytic enzyme in the release of phage progeny (11, 38), but in fact, the evidence is unclear and dubious, considering that the existence of phage-encoded lysins was unknown or very poorly understood and some of the experimental conditions used to show a role of LytA could have also affected the activity of the phage lysin (38).To clarify the possible role of the bacterial autolysin in host lysis, we used the S. pneumoniae strain SVMC28, lysogenic for the SV1 prophage (34), which contains a typical “holin-lysin” cassette, and a different host strain lysogenized with the same SV1 phage. Our results show that LytA is activated by the holin-induced membrane disruption, just like the phage endolysin. In the absence of the endolysin, LytA is capable of mediating host lysis, releasing functional phage particles able to complete their life cycle. Still, sole dependence on LytA results in an altered pattern of phage release that may reduce phage fitness. Importantly, we also show that, together with the endolysin, the concurrent LytA activation is critical for optimal phage progeny release.     

Identification and Characterization of a Phosphodiesterase That Inversely Regulates Motility and Biofilm Formation in Vibrio cholerae

Vibrio cholerae switches between free-living motile and surface-attached sessile lifestyles. Cyclic diguanylate (c-di-GMP) is a signaling molecule controlling such lifestyle changes. C-di-GMP is synthesized by diguanylate cyclases (DGCs) that contain a GGDEF domain and is degraded by phosphodiesterases (PDEs) that contain an EAL or HD-GYP domain. We constructed in-frame deletions of all V. cholerae genes encoding proteins with GGDEF and/or EAL domains and screened mutants for altered motility phenotypes. Of 52 mutants tested, four mutants exhibited an increase in motility, while three mutants exhibited a decrease in motility. We further characterized one mutant lacking VC0137 (cdgJ), which encodes an EAL domain protein. Cellular c-di-GMP quantifications and in vitro enzymatic activity assays revealed that CdgJ functions as a PDE. The cdgJ mutant had reduced motility and exhibited a small decrease in flaA expression; however, it was able to produce a flagellum. This mutant had enhanced biofilm formation and vps gene expression compared to that of the wild type, indicating that CdgJ inversely regulates motility and biofilm formation. Genetic interaction analysis revealed that at least four DGCs, together with CdgJ, control motility in V. cholerae.Cyclic diguanylate (c-di-GMP) is a ubiquitous second messenger in bacteria. It is synthesized by diguanylate cyclases (DGCs) that contain a GGDEF domain and is degraded by phosphodiesterases (PDEs) that contain an EAL or HD-GYP domain (46, 48, 50). The receptors of c-di-GMP, which can be proteins or RNAs (riboswitches), bind to c-di-GMP and subsequently transmit the signal to downstream targets (22). C-di-GMP signaling is predicted to occur via a common or localized c-di-GMP pool(s) through so-called c-di-GMP signaling modules harboring DGCs and PDEs, receptors, and targets that affect cellular function (22).C-di-GMP controls various cellular functions, including the transition between a planktonic lifestyle and biofilm lifestyle. In general, high concentrations of c-di-GMP promote the expression of adhesive matrix components and result in biofilm formation, while low concentrations of c-di-GMP result in altered motility upon changes in flagellar or pili function and/or production (reviewed in reference 25). C-di-GMP inversely regulates motility and biofilm formation by implementing control at different levels through gene expression or through posttranslational mechanisms (reviewed in reference 25).Vibrio cholerae, the causative agent of the disease cholera, uses c-di-GMP signaling to undergo a motile-to-sessile lifestyle switch that is important for both environmental and in vivo stages of the V. cholerae life cycle. The survival of the pathogen in both natural aquatic environments and during infection depends on the appropriate regulation of motility, surface attachment, and colonization factors (26). The V. cholerae genome encodes a total of 62 putative c-di-GMP metabolic enzymes: 31 with a GGDEF domain, 12 with an EAL domain, 10 with both GGDEF and EAL domains, and 9 with an HD-GYP domain (21). V. cholerae contains a few known or predicted c-di-GMP receptors: two riboswitches (53), five PilZ domain proteins (43), VpsT (31), and CdgG (6). C-di-GMP regulates virulence, motility, biofilm formation, and the smooth-to-rugose phase variation in V. cholerae (6, 8, 9, 12, 30, 33, 43, 45, 54, 56, 57). However, particular sets of proteins have not been matched to discrete cellular processes.Some of the DGCs and PDEs involved in regulating motility in V. cholerae have been identified: rocS and cdgG mutants exhibit a decrease in motility (45), while cdgD and cdgH mutants exhibit an increase in motility (6). In addition, VieA (PDE) positively regulates motility in the V. cholerae classical biotype but not in the El Tor biotype (7). AcgA (PDE) positively regulates motility at low concentrations of inorganic phosphate (42). In this study, we investigated the role of each putative gene encoding DGCs and PDEs in controlling cell motility. In addition to the already-characterized proteins CdgD, CdgH, and RocS, we identified two putative DGCs (CdgK and CdgL) that negatively control motility and a putative PDE (CdgJ) that positively controls motility. We further characterized CdgJ and showed that it functions as a PDE and inversely regulates motility and biofilm formation. Genetic interaction studies revealed that DGCs CdgD, CdgH, CdgL, and CdgK and PDE CdgJ form a c-di-GMP signaling network to control motility in V. cholerae.     

Genome Organization and Characterization of the Virulent Lactococcal Phage 1358 and Its Similarities to Listeria Phages

Virulent phage 1358 is the reference member of a rare group of phages infecting Lactococcus lactis. Electron microscopy revealed a typical icosahedral capsid connected to one of the smallest noncontractile tails found in a lactococcal phage of the Siphoviridae family. Microbiological characterization identified a burst size of 72 virions released per infected host cell and a latent period of 90 min. The host range of phage 1358 was limited to 3 out of the 60 lactococcal strains tested. Moreover, this phage was insensitive to four Abi systems (AbiK, AbiQ, AbiT, and AbiV). The genome of phage 1358 consisted of a linear, double-stranded, 36,892-bp DNA molecule containing 43 open reading frames (ORFs). At least 14 ORFs coded for structural proteins, as identified by SDS-PAGE coupled to liquid chromatography-tandem mass spectrometry (LC-MS/MS) analyses. The genomic organization was similar to those of other siphophages. All genes were on the same coding strand and in the same orientation. This lactococcal phage was unique, however, in its 51.4% GC content, much higher than those of other phages infecting this low-GC Gram-positive host. A bias for GC-rich codons was also observed. Comparative analyses showed that several phage 1358 structural proteins shared similarity with two Listeria monocytogenes phages, P35 and P40. The possible origin and evolution of lactococcal phage 1358 is discussed.The first sequenced genome of a phage infecting Lactococcus lactis (bIL67) was reported in 1994 (57). Its genomic characterization was performed with the prospect of a better understanding of lactococcal phage biology. L. lactis is a Gram-positive bacterium added to milk to produce an array of fermented dairy products. In this human-made environment, substantial amounts of lactococcal cells are cultivated on a daily basis in large fermentation vats, and these added cells randomly encounter virulent phages present in heat-treated but nonsterile milk. Moreover, it is widely acknowledged that the increased use of the same bacterial strains within existing dairy facilities inevitably leads to milk fermentation failures due to the multiplication of virulent phages. This biotechnological problem reduces yields and lowers the quality of fermented products (51).Over 700 lactococcal phage isolates have been reported in the literature (3). To date, more than 25 complete genome sequences of lactococcal phages are publicly available in the NCBI database, and the sequencing of others is under way. These numbers indicate that Lactococcus phages are among the most studied of the bacterial viruses. All lactococcal phages belong to the order Caudovirales and are included within two families according to their tail morphology: the Siphoviridae (long noncontractile tail [most lactococcal phages]) and the Podoviridae (short noncontractile tail [few lactococcal phages]) (14). Currently, phages infecting L. lactis strains have been divided into 10 genetically distinct groups (14). The complete genomic sequence is available for at least one representative of 8 of the groups.Early sequencing efforts concentrated on the genomes of lactococcal phages belonging to the 936, c2, and P335 groups (Siphoviridae), because members of these groups were regularly isolated in dairy plants (8, 36, 50). PCR-based methods were also devised to rapidly classify these phages (41). These Siphoviridae phages pose a significant risk to the dairy industry, and their characterization is important for developing adapted antiphage strategies to limit their propagation and evolution.In recent years, representatives of the less recognized lactococcal phage groups have been characterized, including phages Q54 (22), KSY1 (13), 1706 (23), asccφ28 of the P034 group (39), and P087 (63). Their molecular characterizations were aimed at understanding why some phage groups (936, c2, and P335) predominate while the others have remained marginal, at best. However, it was recently reported that P034-like phages may be emerging in certain regions (52). Genomic and microbiological analyses indicated that members of these rare phage groups were likely the result of recombination between different lactococcal phages and phages infecting other Gram-positive bacteria, and they may not be fit to multiply rapidly in milk. For example, lactococcal phage 1706 shares similarities with Ruminococcus and Clostridium prophages (23). Similarly, L. lactis phage P087 structural proteins share identity with gene products found in a prophage in the Enterococcus faecalis genome (63). It was also shown previously that lactococcal phage asccφ28 was related to Streptococcus pneumoniae phage Cp-1 and Bacillus subtilis φ29-like phages (39). It was suggested that phages 1706, asccφ28, and P087 acquired a receptor-binding protein complex from another lactococcal phage that enabled them to infect a L. lactis host.Here, we report the complete genome sequence and analysis of phage 1358, a virulent representative of the 9th lactococcal phage group.     

Comparative Genomics and Transduction Potential of Enterococcus faecalis Temperate Bacteriophages

To determine the relative importance of temperate bacteriophage in the horizontal gene transfer of fitness and virulence determinants of Enterococcus faecalis, a panel of 47 bacteremia isolates were treated with the inducing agents mitomycin C, norfloxacin, and UV radiation. Thirty-four phages were purified from culture supernatants and discriminated using pulsed-field gel electrophoresis (PFGE) and restriction mapping. From these analyses the genomes of eight representative phages were pyrosequenced, revealing four distinct groups of phages. Three groups of phages, ΦFL1 to 3, were found to be sequence related, with ΦFL1A to C and ΦFL2A and B sharing the greatest identity (87 to 88%), while ΦFL3A and B share 37 to 41% identity with ΦFL1 and 2. ΦFL4A shares 3 to 12% identity with the phages ΦFL1 to 3. The ΦFL3A and B phages possess a high DNA sequence identity with the morphogenesis and lysis modules of Lactococcus lactis subsp. cremoris prophages. Homologs of the Streptococcus mitis platelet binding phage tail proteins, PblA and PblB, are encoded on each sequenced E. faecalis phage. Few other phage genes encoding potential virulence functions were identified, and there was little evidence of carriage of lysogenic conversion genes distal to endolysin, as has been observed with genomes of many temperate phages from the opportunist pathogens Staphylococcus aureus and Streptococcus pyogenes. E. faecalis JH2-2 lysogens were generated using the eight phages, and these were examined for their relative fitness in Galleria mellonella. Several lysogens exhibited different effects upon survival of G. mellonella compared to their isogenic parent. The eight phages were tested for their ability to package host DNA, and three were shown to be very effective for generalized transduction of naive host cells of the laboratory strains OG1RF and JH2-2.Enterococcus faecalis is a member of the natural flora of humans and colonizes the gastrointestinal and vaginal tracts and the oral cavity. In recent years it has emerged as an important opportunistic nosocomial pathogen and is a causative agent of bacteremia, infective endocarditis, and surgical wound and urinary tract infections. The accumulation of acquired antibiotic resistance determinants, in addition to its intrinsic resistance and tenacity, has given rise to the evolution of clinical isolates of E. faecalis that are therapeutically problematic (19). Greater notoriety was afforded to this species following the observed transfer of the conjugative transposon Tn1546 to Staphylococcus aureus, imparting vancomycin resistance (11). Subsequent analysis has revealed that multiple independent E. faecalis-dependent vanA transfers had occurred in the United States prior to 2007 (50). This places enterococci in an important and dynamic position within the health care system, warranting their increased study.The specific determinants that are proposed to contribute to the virulence of E. faecalis are not universally present, and expression of the cognate genes is variable (21, 37). For example, in a recent study of 106 clonally diverse strains of E. faecalis the metallopeptidase gelatinase (GelE) was shown to be expressed in less than 60% of 106 genotypically positive isolates, whereas expression of cytolysin was less frequently observed (expression in ∼25% of isolates, with 30% being genotypically positive) (33). A proposed pathogenicity island identified with E. faecalis V583 (49) is composed of a variable gene set encoding the virulence determinants enterococcal surface protein, cytolysin, and aggregation substance. This highly variable 150-kb mobile element contains many components of unknown function that are hypothesized to facilitate survival and/or transmission in the health care setting (34, 40, 49).Two sequenced and annotated genomes of E. faecalis have been completed and published to date. These are the blood isolate and first-observed vancomycin-resistant strain V583 (40) and the oral isolate OG1RF, used as a common laboratory strain (8). A major difference between these genomes is the presence in V583 of seven regions containing phage-associated sequences. In contrast, OG1RF contains only one phage remnant, which was proposed by McBride et al. (33) to form part of the core genome, a theory supported by the presence in OG1RF of this phage remnant region together with two CRISPR loci. CRISPR sequences provide sequence-specific resistance to bacteriophages via the assembly of phage DNA sequences interspersed as spacers between repeats, in concert with associated cas genes, which collectively operate as an RNA-based gene silencing mechanism (5, 6, 28, 30, 36, 42). This elegant heritable mechanism is proposed to limit horizontal gene transfer of bacteriophage, transposable elements, and conjugative plasmids (9, 10, 32).Within the firmicute division of Gram-positive bacteria, temperate bacteriophages are key vectors for the horizontal transfer of virulence genes. In Staphylococcus aureus, bacteriophages encode and mobilize an impressive array of immune evasion genes (54, 55) and Panton-Valentine leukocidin (43). Several bacteriophage-encoded virulence determinants also contribute to pathogenesis in group A Streptococcus (2, 3, 4).The role of bacteriophages in the virulence of E. faecalis is not clear. Encoded within seven phage-related sequences of strain V583, there are multiple reported homologs of the Streptococcus mitis platelet-binding proteins PblA and PblB (7) and a ferrochelatase (40). In contrast, the absence of mobile genetic elements (MGEs) in strain OG1RF led Bourgogne et al. (8) to speculate that they did not engender virulence in E. faecalis.In this study we determined the morphology and complete genome sequences of eight induced bacteriophages purified from clinical isolates of E. faecalis. We sought to determine the potential carriage of genes that might contribute to the virulence or fitness of this organism and characterize the capacity of these phages to participate in transduction.