Control of Salmonella Newport on cherry tomato using a cocktail of lytic bacteriophages.

Bacteriophages have been envisioned as tools to control a variety of foodborne pathogenic bacteria. Salmonella is a foodborne pathogen that is a threat to public health around the world. Contaminated tomatoes have been associated with several Salmonella outbreaks. Hence, the objective of this work was to identify and characterize different lytic bacteriophages against Salmonella Newport, as one of top ten Salmonella serovars associated with human salmonellosis in North America, and then apply these phages to enhance the safety of cherry tomatoes. Four lytic phages against Salmonella Newport were selected based on their ability to lyse a majority of the 26 screened Salmonella serovars. The selected phages belong to Myoviridae (vB_SnwM_CGG4-1, vB_SnwM_CGG4-2) and Siphoviridae (vB_SnwM_CGG3-1, vB_SnwM_CGG3-2) families. They were found to be stable at different temperatures and pH, have latent periods ranging from 53 to 65 min and burst sizes from 92 to 177. In addition, the two Myoviridae phages have a lower frequency of developing bacteriophage insensitive mutants when compared with the Siphoviridae phages. No significant change in virulence gene expression was observed in the developed bacteriophage insensitive mutants when compared to the parental phage sensitive strain. Furthermore, the vB_SnwM_CGG4-1 genome revealed no homology to virulence or lysogenic genes. A phage cocktail was used to control the growth of S. Newport in broth medium and on contaminated cherry tomato. Complete inhibition of bacterial growth in broth medium was observed at 25 °C for 24 h. In addition, a 4.5 log10 unit reduction in the bacterial count was observed when applying the phage cocktail onto contaminated tomatoes stored at 22 °C for 3 days. These findings suggest that the isolated phages can be used for biocontrol of S. Newport to improve the safety of ready-to-eat (RTE) produce.

[New temperate Pseudomonas aeruginosa phage, phi297: specific features of genome structure].

The genome structure and some specific features of temperate Pseudomonas aeruginosa phage phi297 are considered. Analysis of sequencing data and genome annotation suggest that the phi297 genome displays a mosaic structure, which has formed through combining gene blocks from bacteria of taxonomically remote groups and/or their phages. The results of a comparison of the phi297 DNA homology level and pattern with the genome sequences of the currently known related P. aeruginosa bacteriophages are interpreted from the perspective of assumed active migration of these phages between different bacterial species.

[Properties of the new D3-like Pseudomonas aeruginosa bacteriophage phiPMG1: genome structure and prospects for the use in phage therapy].

Results of studying the novel virulent phage phiPMG1 active on Pseudomonas aeruginosa are presented. phiPMG1 was shown to exhibit detectable homology and resemblance in the total genome structure with temperate converting phage D3. Phage phiPMG1 differs from D3 in that it fails to stably lysogenize bacteria and can grow on strains carrying plasmids that cause growth inhibition of phage D3 and some other phages. This significantly diminishes the probability of horizontal gene transfer with phage phiPMG1 and suggests the possible employment of this phage in phage therapy. A comparison of genome structures in phages phiPMG1 and D3 demonstrated not only high homology of 65 genes, but also the presence in the phiPMG1 genome of 16 genes that were not recorded in the files of NCBI database. Apparently, the evolution of genomes in phages of this species is mostly associated with migrations into other species of bacteria and recombinations with phages of other species (for example, F116). Detailed structural analysis a genome region in which the essential nonhomology is exhibited between three D3-like phages (D3, phiPMG1, and PAJU2) revealed that the phiPMG1 genome supposedly is phylogenetically closer than the others to the genome of a hypothetical ancestor phage belonging to this species.

Complete genome sequence of the giant Pseudomonas phage Lu11.

The complete genome sequence of the giant Pseudomonas phage Lu11 was determined, comparing 454 and Sanger sequencing. The double-stranded DNA (dsDNA) genome is 280,538 bp long and encodes 391 open reading frames (ORFs) and no tRNAs. The closest relative is Ralstonia phage ϕRSL1, encoding 40 similar proteins. As such, Lu11 can be considered phylogenetically unique within the Myoviridae and indicates the diversity of the giant phages within this family.

Gene cluster conferring streptomycin, sulfonamide, and tetracycline resistance in Escherichia coli O157:H7 phage types 23, 45, and 67.

Multidrug resistance to streptomycin, sulfonamide, and tetracycline (AMR-SSuT) was identified in 156 of 171 isolates of Escherichia coli O157:H7 of phage types 23, 45, and 67. In 154 AMR-SSuT isolates, resistance was encoded by strA, strB, sul2, and tet(B), which in 59 of 63 tested isolates were found clustered together on the chromosome within the cdiA locus.

Enhancement of a two-phase partitioning bioreactor system by modification of the microbial catalyst: demonstration of concept.

Application of two-phase partitioning bioreactors (TPPB) to the degradation of phenol and xenobiotics has been limited by the fact that many organic compounds that would otherwise be desirable delivery solvents can be utilized by the microorganisms employed. The ability to metabolize the solvent itself could interfere with xenobiotic degradation, limiting remediation efficiency, and hence represents a microbial characteristic incompatible with process goals. To avoid the issue of bioavailability, previous TPPB applications have relied on complex and often expensive delivery solvents or suboptimal catalyst-solvent pairings. In an effort to enhance TPPB activity and applicability, a genetically engineered derivative of Pseudomonas putida ATCC 11172 mutated in its ability to utilize medium-chain-length alcohols was generated (AVP2) and applied as the catalyst within a TPPB system with decanol as the delivery solvent. Kinetic analysis verified that the genetic alteration had not negatively affected phenol degradation. The volumetric productivity of AVP2 (0.48 g/L x h(-1)) was equivalent to that seen for wild-type ATCC 11172 (0.51 g/L x h(-1)), but a comparison of initial cell concentrations and yields revealed an improved phenol-degrading efficiency for the mutant under process conditions. Yield coefficients, cell dry weight, and viable count determinations all confirmed the stability of the modified phenotype. This work illustrates the possibilities for TPPB process enhancement through a careful combination of genetic modification and solvent selection.

Expanded application of a two-phase partitioning bioreactor through strain development and new feeding strategies.

This research demonstrated the microbial treatment of concentrated phenol wastes using a two-phase partitioning bioreactor (TPPB). TPPBs are characterized by a cell-containing aqueous phase and an immiscible and biocompatible organic phase that partitions toxic substrates to the cells on the basis of their metabolic demand and the thermodynamic equilibrium of the system. Process limitations imposed by the capability of wild-type Pseudomonas putida ATCC 11172 to utilize long chain alcohols were addressed by strain modification (transposon mutagenesis) to eliminate this undesirable biochemical characteristic, enabling use of a range of previously bioavailable organics as delivery solvents. Degradation of phenol in a system with the modified strain as catalyst and industrial grade Adol 85 NF (primarily oleyl alcohol) as the solvent was demonstrated, with the system ultimately degrading 36 g of phenol within 38 h. Volumetric phenol consumption rates by wild type P. putida ATCC 11172 and the genetically modified derivative revealed equivalent phenol degrading capabilities (0.49 g/L x h vs 0.47 g/L x h respectively, in paired fermentations), with the latter presenting a more efficient remediation option due to decreased solvent losses arising from the modified strain's forced inability to consume the delivery solvent as a substrate. Two feeding strategies and system configurations were evaluated to expand practical applications of TPPB technology. The ability to operate with a lower solvent ratio over extended periods revealed potential for long-term application of TPPB to the treatment of large masses of phenol while minimizing solvent costs. Repeated recovery of 99% of phenol from concentrated phenol solutions and subsequent treatment within a TPPB scheme demonstrated applicability of the approach to the remediation of highly contaminated "effluents" as well as large masses of bulk phenol. Operation of the TPPB system in a dispersed manner, rather than as two distinct phases, resulted in volumetric consumption rates similar to those previously achieved only in systems operated with enriched air.

Identification and characterization of the AgmR regulator of Pseudomonas putida: role in alcohol utilization.

Two-phase partitioning bioreactors (TPPBs) comprise an aqueous phase containing all non-carbon nutrients necessary for microbial growth and a solvent phase containing high concentrations of inhibitory or toxic substrates that partition at sub-inhibitory levels to the aqueous phase in response to cellular demand. This work aimed at eliminating the growth of Pseudomonas putida ATCC 11172 on medium-chain-length (C8-C12) aliphatic alcohols, hence enabling their use as xenobiotic delivery solvents within two-phase partitioning bioreactors. Experiments resulted in the isolation of a mini-Tn5 mutant unable to utilize these alcohols. The mutation, which also eliminated growth on glycerol and ethanol, was identified to be within a homologue of the P aeruginosa agmR gene, which encodes a response regulator. Enzyme analysis of the agmR::Tn5Km mutant cell extracts revealed a 10-fold decrease in pyrroloquinoline quinone (PQQ)-dependent alcohol dehydrogenase activity. A knockout in a gene (exaA) encoding a PQQ-linked alcohol dehydrogenase slowed but did not eliminate growth on medium-chain-length alcohols or ethanol, suggesting metabolic redundancy within P. putida ATCC 11172. Analysis of P. putida KT2440 genome sequence data indicated the presence of two PQQ-linked alcohol dehydrogenase-encoding genes. The successful elimination of alcohol utilization in the agmR mutant indicates control by AgmR on multiple pathways and presents a useful strain for biotechnological applications requiring alcohol non-utilizing microbial catalysts.

Three-component-mediated serotype conversion in Pseudomonas aeruginosa by bacteriophage D3.

Bacteriophage D3 is capable of lysogenizing Pseudomonas aeruginosa PAO1 (serotype O5), converting the O-antigen from O5 to O16 and O-acetylating the N-acetylfucosamine moiety. To investigate the mechanism of lysogenic conversion, a 3.6 kb fragment from the D3 genome was isolated capable of mediating serotypic conversion identical to the D3 lysogen strain (AK1380). The PAO1 transformants containing this 3.6 kb of D3 DNA exhibited identical lipopolysaccharide (LPS) banding patterns to serotype O16 in silver-stained SDS-PAGE gels and displayed reactivity to an antibody specific for O-acetyl groups. Further analysis led to the identification of three open reading frames (ORFs) required for serotype conversion: an alpha-polymerase inhibitor (iap); an O-acetylase (oac); and a beta-polymerase (wzybeta). The alpha-polymerase inhibitor (Iap) is capable of inhibiting the assembly of the serotype-specific O5 B-band LPS and allows the phage-encoded beta-polymerase (Wzybeta) to form new beta-linked B-band LPS. The D3 phage also alters the LPS by the addition of O-acetyl groups to the FucNAc residue in the O-antigen repeat unit by the action of the D3 O-acetylase (Oac). These three components form a simple yet elegant system by which bacteriophage D3 is capable of altering the surface of P. aeruginosa PAO1.

Sequence of the genome of Salmonella bacteriophage P22.

The sequence of the nonredundant region of the Salmonella enterica serovar Typhimurium temperate, serotype-converting bacteriophage P22 has been completed. The genome is 41,724 bp with an overall moles percent GC content of 47.1%. Numerous examples of potential integration host factor and C1-binding sites were identified in the sequence. In addition, five potential rho-independent terminators were discovered. Sixty-five genes were identified and annotated. While many of these had been described previously, we have added several new ones, including the genes involved in serotype conversion and late control. Two of the serotype conversion gene products show considerable sequence relatedness to GtrA and -B from Shigella phages SfII, SfV, and SfX. We have cloned the serotype-converting cassette (gtrABC) and demonstrated that it results in Salmonella serovar Typhimurium LT2 cells which express antigen O1. Many of the putative proteins show sequence relatedness to proteins from a great variety of other phages, supporting the hypothesis that this phage has evolved through the recombinational exchange of genetic information with other viruses.

Sequence of the genome of the temperate, serotype-converting, Pseudomonas aeruginosa bacteriophage D3.

Temperate bacteriophage D3, a member of the virus family Siphoviridae, is responsible for serotype conversion in its host, Pseudomonas aeruginosa. The complete sequence of the double-stranded DNA genome has been determined. The 56,426 bp contains 90 putative open reading frames (ORFs) and four genes specifying tRNAs. The latter are specific for methionine (AUG), glycine (GGA), asparagine (AAC), and threonine (ACA). The tRNAs may function in the translation of certain highly expressed proteins from this relatively AT-rich genome. D3 proteins which exhibited a high degree of sequence similarity to previously characterized phage proteins included the portal, major head, tail, and tail tape measure proteins, endolysin, integrase, helicase, and NinG. The layout of genes was reminiscent of lambdoid phages, with the exception of the placement of the endolysin gene, which parenthetically also lacked a cognate holin. The greatest sequence similarity was found in the morphogenesis genes to coliphages HK022 and HK97. Among the ORFs was discovered the gene encoding the fucosamine O-acetylase, which is in part responsible for the serotype conversion events.

Cloning and analysis of the capsid morphogenesis genes of Pseudomonas aeruginosa bacteriophage D3: another example of protein chain mail?

The terminal DNA restriction fragments (PstI-D and -B) of Pseudomonas aeruginosa bacteriophage D3 were ligated, cloned, and sequenced. Of the nine open reading frames in this 8.3-kb fragment, four were identified as encoding large-subunit terminase, portal, ClpP protease, and major head proteins. The portal and capsid proteins showed significant homology with proteins of the lambdoid coliphage HK97. Phage D3 was purified by CsCl equilibrium gradient centrifugation (rho = 1.533 g/ml), and sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed six proteins with molecular masses of 186, 91, 79, 70, 45, and 32 kDa. The pattern was unusual, since a major band corresponding to the expected head protein (43 kDa) was missing and a significant amount of the protein was retained in the stacking gel. The amino terminus of the 186-kDa protein was sequenced, revealing that the D3 head is composed of cross-linked 31-kDa protein subunits, resulting from the proteolysis of the 43-kDa precursor. This is identical to the situation observed with coliphage HK97.

Transfer RNA genes and their significance to codon usage in the Pseudomonas aeruginosa lamboid bacteriophage D3.

Using tRNAscan-SE and FAStRNA we have identified four tRNA genes in the delayed early region of the bacteriophage D3 genome (GenBank accession No. AF077308). These are specific for methionine (AUG), glycine (GGA), asparagine (AAC), and threonine (ACA). The D3 Thr- and Gly-tRNAs recognize codons, which are rarely used in Pseudomonas aeruginosa and presumably, influence the rate of translation of phage proteins. BLASTN searches revealed that the D3 tRNA genes have homology to tRNA genes from Gram-positive bacteria. Analysis of codon usage in the 91 ORFs discovered in D3 indicates patterns of codon usage reminiscent of Escherichia coli or P. aeruginosa.

Functional analysis of sigma-70 consensus promoters in Pseudomonas aeruginosa and Escherichia coli.

A series of synthetic promoters, based upon the Escherichia coli sigma 70 consensus promoter sequence, was constructed upstream of the lacZ reporter gene in the modified broad-host-range vector pQF52. The role of the intervening spacer region in gene expression in Pseudomonas aeruginosa and E. coli was studied by insertions and deletions within this region. In P. aeruginosa and E. coli the patterns of gene expression were identical with maximum beta-galactosidase activity being measured from promoters possessing 19 bp in their intervening regions, presumably as a result of impeded promoter clearance with the consensus 17-bp promoter. In P. aeruginosa a second occurrence of enhanced activity, which could not be attributed to the involvement of the alternative sigma factor RpoN (sigma 54), was evident with the promoter having a 16-bp spacer.

Overexpression, purification, and analysis of the c1 repressor protein of Pseudomonas aeruginosa bacteriophage D3.

A 3.1-kb region of the bacteriophage D3 genome which contains the immunity functions has recently been sequenced (GenBank accession No. L22692). Sequence analysis indicated the presence of a putative repressor gene (c1) whose protein product functions to maintain the bacteriophage genome as a stably integrated prophage in the chromosome of Pseudomonas aeruginosa. A plasmid was constructed that overexpresses repressor C1 protein under control of P(tac) in Escherichia coli. C1 protein was subsequently purified and characterized as a 223 amino acid protein with specific binding affinity for 14-base imperfect palindromic operator sequences located on the genome of bacteriophage D3. N-terminal protein sequence data obtained from automated Edman degradation (16 cycles) of purified repressor protein were identical to the predicted sequence based on DNA sequence analysis of the c1 open reading frame.

Genetic and sequence analysis of the cos region of the temperate Pseudomonas aeruginosa bacteriophage, D3.

The location and structure of the cos ends of bacteriophage D3, which infects Pseudomonas aeruginosa strain PAO, has been determined using a combination of deletion analysis, transposon mutagenesis, and sequencing directly off the phage DNA. Phage D3 was found to have 9-bp 3' cos ends, making it the first phage of a Gram-negative organism known to have 3' cos ends. A 700-bp region flanking the cos site was necessary for efficient transduction of D3 cosmid derivatives. This region was found to contain incomplete inverted repeat sequences flanking the cos site, along with adenine-rich repeats homologous to coliphage gama Ter binding sites. Possible IHF binding sites were also present.

Physical mapping of several heat-shock genes in Pseudomonas aeruginosa and the cloning of the mopA (GroEL) gene.

Using a series of oligonucleotides synthesized on the basis of conserved nucleotide or amino acid motifs in heat-shock genes/proteins, we have physically mapped the dnaK, lon, and hptG genes of Pseudomonas aeruginosa. Hybridization data suggest that there is a single copy of the mopBA (GroES/GroEL) operon but several additional copies of mopA. In addition, the map coordinates for the rpoD, rpoS, and rpoH genes were determined. The mopA gene from the mopBA operon was cloned and sequenced. The protein product of this gene showed 79% amino acid identity to the Escherichia coli GroEL and 98% identity to the GroEL sequence from P. aeruginosa ATCC 27853. A number of discrepancies were found with the latter sequence.

Cloning the gene for the heat shock response positive regulator (sigma 32 homolog) from Pseudomonas aeruginosa.

A 31 base pair synthetic oligonucleotide based on the genes for the Escherichia coli heat shock sigma factor (rpoH) and the Pseudomonas aeruginosa housekeeping sigma factor (rpoD) was employed in conjunction with the Tanaka et al. (K. Tanaka, T. Shiina, and H. Takahashi, 1988. Science (Washington, D.C.), 242: 1040-1042) RpoD box probe to identify the location of the rpoH gene in P. aeruginosa genomic digests. This gene was cloned into plasmid pGEM3Z(f+), sequenced, and found to share 67% nucleotide identity and 77% amino acid homology with the rpoH gene and its product (sigma 32) of E. coli. The plasmid containing the rpoH gene complemented the function of sigma 32 in an E. coli rpoH deletion mutant. Furthermore, this plasmid directed the synthesis of a 32-kDa protein in an E. coli S-30 in vitro transcription-translation system. Primer extension studies were used to identify the transcriptional start sites under control and heat-stressed (45 and 50 degrees C) conditions. Two promoter sites were identified having sequence homology to the E. coli sigma 70 and sigma 24 consensus sequences.

Cloning of the early promoters of Pseudomonas aeruginosa bacteriophage D3: sequence of the immunity region of D3.

The early promoters of bacteriophage D3 of Pseudomonas aeruginosa were cloned and physically mapped to the right 25% of the phage genome. The promoters were cloned into promoter selection vector pQF26, and their relative strengths, the direction of transcription, and whether they were directly regulated by repressor were determined. A 3.3-kb fragment of the genome containing the immunity region was sequenced and analyzed (GenBank accession number: L22692). The promoter activity associated with this region was determined to be bidirectional and repressible, indicating that this region contains operator-promoter complexes. Sequence and functional analyses suggest that this region is analogous to the immunity region of coliphage lambda. Two strong promoters, one of which was repressible, were found to be located adjacent to the immunity region. Clear-plaque mutant phage D3c contains insertion element IS222, which causes it to behave as a repressor-negative (c1) variant. The site of insertion of IS222 was sequenced and determined to lie within the c1 gene open reading frame. This phage shows remarkable similarity in genomic organization to coliphage lambda and its relatives.