Implication of a gene deletion on a Salmonella Enteritidis phage growth parameters.

Synthetic biology has been applied countless times for the modification and improvement of bacterial strains and for the synthesis of products that do not exist in nature. Phages are natural predators of bacteria controlling their population levels; however, their genomes carry several genes with unknown functions. In this work, Bacteriophage Recombineering of Electroporated DNA was used to assess the influence of deletion of a single gene with unknown function in the overall replication parameters of Salmonella phage PVP-SE2. Deletion of ORF_01, transcribed immediately after infection, reduced both the latent and rise periods by 5 min in PVP-SE2ΔORF_01 compared to the wild-type phage. A direct consequence of the deletion led to a smaller progeny release per infected cell by the mutant compared to the wild-type phage. Despite the difference in growth characteristics, the mutant phage remained infective towards exponentially growing cells. The mutation engineered endured for at least ten passages, showing that there is no reversion back to the wild-type sequence. This study provides proof of concept that methodologies used for phage engineering should always be complemented by phage growth characterization to assess whether a mutation can trigger undesirable characteristics.

Selection and characterization of a multivalent Salmonella phage and its production in a nonpathogenic Escherichia coli strain.

We report the selection and amplification of the broad-host-range Salmonella phage phi PVP-SE1 in an alternative nonpathogenic host. The lytic spectrum and the phage DNA restriction profile were not modified upon replication in Escherichia coli Bl21, suggesting the possibility of producing this phage in a nonpathogenic host, contributing to the safety and easier approval of a product based on this Salmonella biocontrol agent.

Salmonella Enteritidis bacteriophage candidates for phage therapy of poultry.

AIMS: Salmonella is a worldwide foodborne pathogen causing acute enteric infections in humans. In the recent years, the use of bacteriophages has been suggested as a possible tool to combat this zoonotic pathogen in poultry farms. This work aims to isolate and perform comparative studies of a group of phages active against a collection of specific Salmonella Enteritidis strains from Portugal and England. Also, suitable phage candidates for therapy of poultry will be selected. METHODS AND RESULTS: The Salm. Enteritidis strains studied were shown to have a significantly high occurrence of defective (cryptic) prophages; however, no live phages were found in the strains. Bacteriophages isolated from different environments lysed all except one of the tested Salm. Enteritidis strains. The bacteriophages studied were divided into different groups according to their genetic homology, RFLP profiles and phenotypic features, and most of them showed no DNA homology with the bacterial hosts. The bacteriophage lytic efficacy proved to be highly dependent on the propagation host strain. CONCLUSIONS: Despite the evidences shown in this work that the Salm. Enteritidis strains used did not produce viable phages, we have confirmed that some phages, when grown on particular hosts, behaved as complexes of phages. This is most likely because of the presence of inactive phage-related genomes (or their parts) in the bacterial strains which are capable of being reactivated or which can recombine with lytic phages. Furthermore, changes of the bacterial hosts used for maintenance of phages must be avoided as these can drastically modify the parameters of the phage preparations, including host range and lytic activity. SIGNIFICANCE AND IMPACT OF THE STUDY: This work shows that the optimal host and growth conditions must be carefully studied and selected for the production of each bacteriophage candidate for animal therapy.

Isolation and characterization of bacteriophages for avian pathogenic E. coli strains.

AIMS: To isolate and characterize bacteriophages, and to evaluate its lytic performance against avian pathogenic Escherichia coli (APEC) strains with high patterns of antibiotic resistance, in order to select phages for a therapeutic product to treat colibacillosis in chickens. METHODS AND RESULTS: Bacteriophages were isolated from poultry sewage and tested against 148 O-serotyped APEC strains. The morphological characterization of the bacteriophages was made by transmission electronic microscopy (TEM) observations and the genetic comparison between bacteriophages DNA was performed by restriction fragment length polymorphism (RFLP) patterns. Results showed that 70.5% of the tested E. coli strains were sensitive to a combination of three of the five isolated phages, that seemed to be virulent and taxonomically belong to the Caudovirales order. Two of them look like 16-19, T4-like phages (Myoviridae) and the third is a T1-like phage and belongs to Syphoviridae family. All of them are genetically different. CONCLUSIONS: It was possible to obtain a combination of three different lytic bacteriophages with broad lytic spectra against the most prevalent O-serotypes of APEC. SIGNIFICANCE AND IMPACT OF THE STUDY: Data reported in this study, presents an in vitro well studied phage product to be used as antimicrobial agent to treat colibacillosis in poultry industry.

Antimicrobial assessment of phage therapy using a porcine model of biofilm infection.

Antibiotic resistant bacterial communities persist in many types of wounds, chronic wounds in particular, in the form of biofilms. Biofilm formation is a major cause of severe infections and the main reason for a negative treatment outcome and slow healing progression. Chronic wounds are a silent epidemic essentially affecting people with co-morbid conditions such as diabetes and obesity and elderly persons particularly those with movement limitations. The development of complementary and alternative effective strategies to antibiotics for the treatment of chronic wounds is highly desired. Phage therapy constitutes a very promising approach in the control of topical microbial populations. In this work newly isolated phages were tested for their efficacy to control bacterial species that predominate in chronic wounds. Phage effectiveness was studied on 24-h old biofilms formed in polystyrene microplates and in porcine skin explants using two treatment approaches: individual phage and a cocktail of phages against four main pathogens commonly isolated from chronic wounds. The two models produced variations in the surface colonization ability, assessed by viable bacterial counts and microscopy visualization after using peptide nucleic acid (PNA) or locked nucleic acid probes (LNA) and 2'-O-methyl (2'-OMe) in fluorescence in situ hybridization (FISH), and in the phage-host interactions. Phages alone and combined caused greater reductions in the number of viable cells when biofilms had been formed on porcine skins and with greater variations detected at 4 h and 24 h of sampling. These results suggest that porcine skin models should be preferentially used to assess the use of phages and phage cocktails intended for topical use in order to understand the fate, throughout treatment time, of the population when dealing with biofilm-related infections.

Real-time quantification of Pseudomonas fluorescens cell removal from glass surfaces due to bacteriophage varphiS1 application.

AIMS: To study the efficacy of the lytic phage varphiS1 in eliminating Pseudomonas fluorescens in the early stage of biofilm formation, using an in situ and real time methodology for cell quantification. METHODS AND RESULTS: Cell adhesion and phage infection studies were carried out in a parallel plate flow chamber under laminar conditions. Cells were allowed to adhere until reaching 1.7-1.8 x 10(6) cells cm(-2) and phage infection was performed with two different phage concentrations (2 x 10(9) PFU ml(-1) and 1 x 10(10) PFU ml(-1)). Phage concentration clearly affects the speed of infection. The less concentrated phage solution promoted a three times slower rate of cell removal but did not affect the overall percentage of cell removal. In fact, after a longer infection period the less concentrated phage solution reached the same 93% cell removal value. CONCLUSIONS: Phages are efficient in the eradication of bacterial cells at the early stage of biofilm formation and their presence at the surface did not allow bacterial recolonization of the surface. SIGNIFICANCE AND IMPACT OF THE STUDY: To date, no published studies have been made concerning in situ and real time quantification of cell removal from surfaces due to phage action.

Phage therapy as an alternative or complementary strategy to prevent and control biofilm-related infections.

The complex heterogeneous structure of biofilms confers to bacteria an important survival strategy. Biofilms are frequently involved in many chronic infections in consequence of their low susceptibility to antibiotics as well as resistance to host defences. The increasing need of novel and effective treatments to target these complex structures has led to a growing interest on bacteriophages (phages) as a strategy for biofilm control and prevention. Phages can be used alone, as a cocktail to broaden the spectra of activity, or in combination with other antimicrobials to improve their efficacy. Here, we summarize the studies involving the use of phages for the treatment or prevention of bacterial biofilms, highlighting the biofilm features that can be tackled with phages or combined therapy approaches.

Extraction of exopolymers from biofilms: the protective effect of glutaraldehyde.

The extraction of the exopolymeric matrix is a prerequisite to properly assessing the composition of the biofilm. Several extraction methods have already been developed, however, no universal method has yet been adopted because the compromise between high yields of extraction and minimum cell lysis is difficult to establish. In fact, most of the extraction methods promote leakage of intracellular material. The most common extraction methods, Dowex resin and sonication, were assayed in biofilms of Pseudomonas fluorescens and Alcaligenes denitrificans submitted to a pre-treatment with glutaraldehyde (GTA). The assessment of ATP released after extraction was used as a criterion of cell lysis. The results showed that GTA is a protective agent against cell lysis. The pre-treatment with GTA is particularly useful combined with sonication.