Cumulative effect of prophage burden on Shiga toxin production in Escherichia coli.

Shigatoxigenic Escherichia coli (STEC) such as E. coli O157 are significant human pathogens, capable of producing severe, systemic disease outcomes. The more serious symptoms associated with STEC infection are primarily the result of Shiga toxin (Stx) production, directed by converting Stx bacteriophages. During phage-mediated replication and host cell lysis, the toxins are released en masse from the bacterial cells, and the severity of disease is linked inexorably to toxin load. It is common for a single bacterial host to harbour more than one heterogeneous Stx prophage, and it has also been recently proven that multiple isogenic prophage copies can exist in a single cell, contrary to the lambda immunity model. It is possible that in these multiple lysogens there is an increased potential for production of Stx. This study investigated the expression profiles of single and double isogenic lysogens of Stx phage 24(B) using quantitative PCR to examine transcription levels, and a reporter gene construct as a proxy for the translation levels of stx transcripts. Toxin gene expression in double lysogens was in excess of the single lysogen counterpart, both in the prophage state and after induction of the lytic life cycle. In addition, double lysogens were found to be more sensitive to an increased induction stimulus than single lysogens, suggesting that maintenance of a stable prophage is less likely when multiple phage genome copies are present. Overall, these data demonstrate that the phenomenon of multiple lysogeny in STEC has the potential to impact upon disease pathology through increased toxin load.

Bacteriophage lambda: a paradigm revisited.

Bacteriophage lambda has an archetypal immunity system, which prevents the superinfection of its Escherichia coli lysogens. It is now known that superinfection can occur with toxigenic lambda-like phages at a high frequency, and here we demonstrate that the superinfection of a lambda lysogen can lead to the acquisition of additional lambda genomes, which was confirmed by Southern hybridization and quantitative PCR. As many as eight integration events were observed but at a very low frequency (6.4 x 10(-4)) and always as multiple insertions at the established primary integration site in E. coli. Sequence analysis of the complete immunity region demonstrated that these multiply infected lysogens were not immunity mutants. In conclusion, although lambda superinfection immunity can be confounded, it is a rare event.

Multilocus characterization scheme for shiga toxin-encoding bacteriophages.

Shiga toxin-producing Escherichia coli (STEC) strains are food-borne pathogens whose ability to produce Shiga toxin (Stx) is due to integration of Stx-encoding lambdoid bacteriophages. These Stx phages are both genetically and morphologically heterogeneous, and here we report the design and validation of a PCR-based multilocus typing scheme. PCR primer sets were designed for database variants of a range of key lambdoid bacteriophage genes and applied to control phages and 70 stx(+) phage preparations induced from a collection of STEC isolates. The genetic diversity residing within these populations could be described, and observations were made on the heterogeneity of individual gene targets, including the unexpected predominance of short-tailed phages with a highly conserved tail spike protein gene. Purified Stx phages can be profiled using this scheme, and the lambdoid phage-borne genes in induced STEC preparations can be identified as well as those residing in the noninducible prophage complement. The ultimate goal is to enable robust and realistically applicable epidemiological studies of Stx phages and their traits. The impact of Stx phage on STEC epidemiology is currently unknown.

Survival of a Shiga toxin-encoding bacteriophage in a compost model.

Bacteriophages that carry the Shiga toxin gene (stx) represent an additional hazard in cattle manure-based fertilizers in that their survival could lead to toxigenic conversion of Escherichia coli and other bacteria post-composting. A Stx-phage in which the Shiga toxin (stx(2)) gene was inactivated by insertion of a chloramphenicol resistance gene was used in combination with a rifampicin-resistant E. coli host where RecA is constitutively activated so that all infectious phage particles could be enumerated by plaque assay. PCR-based confirmation methods and the additional application of a host enrichment protocol ensured that very low numbers of surviving bacteriophage could be detected and unequivocally identified. Stx-bacteriophage numbers declined rapidly over the first 48 h and none could be detected after 3 days. The host enrichment method was applied after 6 days and no bacteriophages were recovered. While addition of fresh E. coli cells at intervals after the compost temperature had reduced below 40 degrees C demonstrated that E. coli growth could be supported in the compost, Stx-phages or their lysogens were never detected. Here, we demonstrate that composting animal manure for 40 days during which a temperature of >60 degrees C is maintained for at least 5 days is effective at removing both E. coli and a model infectious Stx-encoding bacteriophage.

The potential of site-specific recombinases as novel reporters in whole-cell biosensors of pollution.

DNA recombinases show some promise as reporters of pollutants providing that appropriate promoters are used and that the apparent dependence of expression on cell density can be solved. Further work is in progress using different recombinases and other promoters to optimize recombinase expression as well as to test these genetic constructs in contaminated environmental samples such as soil and water. It may be that a graded response reflecting pollutant concentration may not be possible. However, they show great promise for providing definitive detection systems for the presence of a pollutant and may be applicable to address the problem of bioavailability of pollutants in complex environments such as soil.

Evolvable social agents for bacterial systems modeling.

We present two approaches to the individual-based modeling (IbM) of bacterial ecologies and evolution using computational tools. The IbM approach is introduced, and its important complementary role to biosystems modeling is discussed. A fine-grained model of bacterial evolution is then presented that is based on networks of interactivity between computational objects representing genes and proteins. This is followed by a coarser grained agent-based model, which is designed to explore the evolvability of adaptive behavioral strategies in artificial bacteria represented by learning classifier systems. The structure and implementation of the two proposed individual-based bacterial models are discussed, and some results from simulation experiments are presented, illustrating their adaptive properties.

Short-tailed stx phages exploit the conserved YaeT protein to disseminate Shiga toxin genes among enterobacteria.

Infection of Escherichia coli by Shiga toxin-encoding bacteriophages (Stx phages) was the pivotal event in the evolution of the deadly Shiga toxin-encoding E. coli (STEC), of which serotype O157:H7 is the most notorious. The number of different bacterial species and strains reported to produce Shiga toxin is now more than 500, since the first reported STEC infection outbreak in 1982. Clearly, Stx phages are spreading rapidly, but the underlying mechanism for this dissemination has not been explained. Here we show that an essential and highly conserved gene product, YaeT, which has an essential role in the insertion of proteins in the gram-negative bacterial outer membrane, is the surface molecule recognized by the majority (ca. 70%) of Stx phages via conserved tail spike proteins associated with a short-tailed morphology. The yaeT gene was initially identified through complementation, and its role was confirmed in phage binding assays with and without anti-YaeT antiserum. Heterologous cloning of E. coli yaeT to enable Stx phage adsorption to Erwinia carotovora and the phage adsorption patterns of bacterial species possessing natural yaeT variants further supported this conclusion. The use of an essential and highly conserved protein by the majority of Stx phages is a strategy that has enabled and promoted the rapid spread of shigatoxigenic potential throughout multiple E. coli serogroups and related bacterial species. Infection of commensal bacteria in the mammalian gut has been shown to amplify Shiga toxin production in vivo, and the data from this study provide a platform for the development of a therapeutic strategy to limit this YaeT-mediated infection of the commensal flora.

Identification of multiple integration sites for Stx-phage Phi24B in the Escherichia coli genome, description of a novel integrase and evidence for a functional anti-repressor.

The key virulence factor in Shiga-toxigenic Escherichia coli is the expression of Shiga toxin (Stx), which is conferred by Stx-encoding temperate lambdoid phages (Stx-phages). It had been assumed that Stx-phages would behave similarly to lambda phage. However, contrary to the lambda superinfection immunity model, it has been demonstrated that double lysogens can be produced with the Stx-phage Phi24(B). Here, the Phi24(B) integrase gene is identified, and the preferred site of integration defined. Although an E. coli int gene was identified close to the Phi24(B) integration site, it was shown not to be involved in the phage integration event. An additional six potential integration sites were identified in the E. coli genome, and three of these were confirmed experimentally. Two of the other potential sites lie within genes predicted to be essential to E. coli and are therefore unlikely to support phage integration. A Phi24(B) gene, possessing similarity to the well-characterized P22 ant gene, was identified. RT-PCR was used to demonstrate that ant is transcribed in a Phi24(B) E. coli lysogen, and expression of an anti-repressor is the likely explanation for the absence of immunity to superinfection. Demonstration of the ability of Phi24(B) to form multiple lysogens has two potentially serious impacts. First, multiple integrated prophages will drive the evolution of bacterial pathogens as novel Stx-phages emerge following intracellular mutation/recombination events. Second, multiple copies of the stx gene may lead to an increase in toxin production and consequently increased virulence.

Diversity of phage integrases in Enterobacteriaceae: development of markers for environmental analysis of temperate phages.

Viruses are the most abundant biological entities in aquatic systems. Temperate bacteriophages have enormous influences on microbial diversity, genetic exchange and bacterial population dynamics. However, development of molecular tools for their detection in the environment has been problematic. The integrase gene is used here as a molecular marker to analyse the diversity of temperate bacteriophages in a population of freshwater bacteria. Interrogation of the GenBank database revealed 32 non-cryptic enteric phage integrase sequences, leading to the development of a suite of 11 degenerate primer sets specific to the extant sequences elucidated. Application of these primer sets to enterobacterial isolates recovered from a freshwater pond and the temperate phages induced from them revealed a number of diverse integrase genes, including novel integrase-like sequences not represented in the databases. This highlights the potential of utilizing the integrase gene family as a marker for phage diversity.

Relationship between nucleic acid ratios and growth in Listeria monocytogenes.

Listeria monocytogenes is a pathogen whose distribution in a range of foodstuffs requires the development of methods for sensitive and rapid detection. Molecular biological methods usually rely on specific detection of L. monocytogenes rDNA directly amplified by the application of PCR to DNA extracts. Information on the metabolic status of L. monocytogenes populations would be valuable and can, in theory, be provided by quantitative detection of rRNA itself. Both fluorometry and oligonucleotide probe assays were applied to L. monocytogenes cultures to quantify RNA and DNA and produced more meaningful data than previous estimates for bacteria based on eukaryotic nucleic acid standards. In batch culture, the RNA-DNA ratio was found to be greatest at the end of exponential growth, after which RNA became degraded in accordance with the rapid decrease in viability. When the pH of the medium was controlled at neutrality, culture viability was dramatically extended and although RNA was degraded, intact DNA was maintained for the duration of the experiment. Ribosome numbers per cell were estimated to decrease from about 25000 observed during mid-exponential growth to about 600 during stationary phase, under pH-controlled conditions. Like Escherichia coli, therefore, L. monocytogenes loses viability and rRNA rapidly once exponential growth has ceased in batch culture. However, much improved survival of a culturable L. monocytogenes population when pH is controlled has clear implications for the persistence of this species in buffered environments such as dairy products.

Transfer of plasmid pBC16 between Bacillus thuringiensis strains in non-susceptible larvae.

Plasmid transfer was investigated in larvae of insects of the orders Coleoptera, Diptera, and Lepidoptera. The effects of introducing Bacillus thuringiensis strains in live non-susceptible larvae, and in the presence of added insecticidal toxins to kill the larvae, were examined. Plasmid transfer was not detected as the strains passed through non-susceptible live larvae, but was detected when the larvae were toxin-killed. The results indicate that growth of B. thuringiensis and plasmid transfer between strains while simply passing through an insect gut system is an infrequent event. In toxin-killed larvae, a more complex picture was recorded. B. thuringiensis subsp. kurstaki transferred pBC16 at a lower rate in killed Phaedon cochleriae larvae compared to previous work studying transfer with this strain in susceptible Lacanobia oleracea larvae. Similarly, B. thuringiensis subsp. tenebrionis transferred pBC16 in killed L. oleracea larvae, while no transfer in susceptible P. cochleriae larvae was detected. The results indicate that gene transfer was more frequent in killed L. oleracea larvae. When both B. thuringiensis strains were studied in Aedes aegypti, transfer of pBC16 was detected in toxin-killed larvae. This was surprising since in similar studies with strain B. thuringiensis subsp. israelensis that kills mosquitoes, transfer of pBC16 was not detected in mosquito cadavers. The improved transfer frequency of B. thuringiensis subsp. kurstaki and subsp. tenebrionis compared to B. thuringiensis subsp. israelensis in laboratory broth culture could account for this difference in detection of transfer within killed insects.

Bacteria in post-glacial freshwater sediments.

Prokaryote communities in post-glacial profundal freshwater sediments of Windermere, representing 10-12,000 years of deposition, were examined for culturability, viability and community structure. The potential for active geochemical cycles was inferred from the presence of specific groups of bacteria. Direct count procedures revealed 10(12) cells (g dry wt sediment)-1 in the surface sediments, which declined to approximately 10(9) cells (g dry wt sediment)-1 at 6 m depth of core (Representing approximately 10,000 years of deposition). The majority of the cells in the upper sediments were metabolically active when challenged with viability probes and responded to the direct viable count method. Below 250 cm, viability shown by 5-cyano-2,3-diotyl tetrazolium chloride (CTC) dye was not significantly different from the direct count; however, counts obtained with 5-carboxyfluorescein diacetate (CFDA) and the direct viable count both declined significantly from the direct count below 250 cm and 1 m, respectively. Culture was achieved from samples throughout the core, although the numbers of culturable bacteria decreased significantly with depth, from 10(7) c.f.u. (g dry wt sediment)-1 to 10(1)-10(2) c.f.u. (g dry wt sediment)-1 below 3 m depth. Among culturable isolates, Gram-positives and Gram-negatives were found at all levels of the core, and spore-forming heterotrophs dominated. Although sulphate-reducing bacteria were not detected below 20 cm, isolates demonstrating denitrifying activity were detected at all depths. PCR performed on samples taken below 3 m (deposited more than 7000 years ago) using eubacterial and archaeal primers revealed sequences similar to those found in deep sediments of the Pacific Ocean and the presence of methanogenic archaea. These observations indicate that bacteria and archaea are capable of long-term persistence and activity in deep, aged freshwater sediments.

Mosaic plasmids and mosaic replicons: evolutionary lessons from the analysis of genetic diversity in IncFII-related replicons.

The alpha replicons of the multi-replicon plasmids pGSH500 and pLV1402 have been characterized by DNA sequence analysis. Analysis of the DNA sequence of a 3672 bp HIN:dIII fragment from pFDT100, which contains the pGSH500 alpha replicon, revealed similarity to a number of replicons belonging to, or related to, those of the IncFII family. The replicon region contains copA, tapA, repA and oriR, and replication initiation and termination sites are related to those from the IncFII replicon of R1. A copB gene was found to lie upstream of the HIN:dIII site in the parental plasmid pGSH500. Downstream of oriR, a 707 bp region shows 72.6% identity to a region of the Escherichia coli chromosome at 43.3', suggesting this region of pGSH500 may have been incorporated into the plasmid during a past chromosomal recombination event. Oligonucleotide primers homologous to consensus regions in the copB and repA genes, and the oriR regions from a number of IncFII-related replicons were used to amplify replication regions from pLV1402. Analysis of the amplified regions has shown the presence of copB, copA, tapA and repA genes. Phylogenetic analysis of Rep protein sequences from the RepFIIA family of antisense-control-regulated replicons revealed the presence of three distinct subgroups of Rep proteins. Comparative analysis of DNA and protein sequences from members of the RepFIIA family provides evidence supporting the roles of both non-selective divergence in co-integrate (multi-replicon) plasmids and Chi-mediated-recombination in replicon evolution, and in particular, that such processes may have been widespread in the evolution of the RepFIIA family.

Immunity profiles of wild-type and recombinant shiga-like toxin-encoding bacteriophages and characterization of novel double lysogens.

The pathogenicity of Shiga-like toxin (stx)-producing Escherichia coli (STEC), notably serotype O157, the causative agent of hemorrhagic colitis, hemolytic-uremic syndrome, and thrombotic thrombocytopenic purpura, is based partly on the presence of genes (stx(1) and/or stx(2)) that are known to be carried on temperate lambdoid bacteriophages. Stx phages were isolated from different STEC strains and found to have genome sizes in the range of 48 to 62 kb and to carry either stx(1) or stx(2) genes. Restriction fragment length polymorphism patterns and sodium dodecyl sulfate-polyacrylamide gel electrophoresis protein profiles were relatively uninformative, but the phages could be differentiated according to their immunity profiles. Furthermore, these were sufficiently sensitive to enable the identification and differentiation of two different phages, both carrying the genes for Stx2 and originating from the same STEC host strain. The immunity profiles of the different Stx phages did not conform to the model established for bacteriophage lambda, in that the pattern of individual Stx phage infection of various lysogens was neither expected nor predicted. Unexpected differences were also observed among Stx phages in their relative lytic productivity within a single host. Two antibiotic resistance markers were used to tag a recombinant phage in which the stx genes were inactivated, enabling the first reported observation of the simultaneous infection of a single host with two genetically identical Stx phages. The data demonstrate that, although Stx phages are members of the lambdoid family, their replication and infection control strategies are not necessarily identical to the archetypical bacteriophage lambda, and this could be responsible for the widespread occurrence of stx genes across a diverse range of E. coli serotypes.