Characterization and genome analysis of two novel Aeromonas hydrophila phages PZL-Ah1and PZL-Ah8

Aeromonas hydrophila (A.hydrophila) is an opportunistic pathogen of fish-human-livestock, which poses a seriously affects to the development of aquaculture. Phage therapy is considered as a process to alternatively control bacterial infections and contaminations. In this study, the genomes of two Aeromonas hydrophila- specific phages PZL-Ah1 and PZL-Ah8 were isolated, characterized and genomic sequence analyzed. Transmission electron microscopy showed that the two phages had been classified as the member of the Podoviridae family. Both the two phages in this study had relatively narrow host range with lytic activity against Aeromonas spp. strains. However, they could lyse 3 common A.hydrophila strain. As revealed from the whole genomic sequence analysis, PZL-Ah1 and PZL-Ah8 coverd the double-stranded genome of 38,641 bp and 40,855 bp in length, with the GC content of 53.68% and 51.89%, respectively. Through gene comparison in NCBI database revealed that PZL-Ah1 and PZL-Ah8 were 97.67% − 95.51% identical to Stenotrophomonas phage IME15 and Aeromonas Phage T7-Ah. Phylogenetic analysis showed that PZL-Ah8, PZL-Ah1 and other two phages belonged to the same genus. A total of 44 and 52 open reading frames (ORFs) were predicted in the PZL-Ah1 and PZL-Ah8 genome, respectively. In the process of gene annotation, 28 (63.6%) ORFs in PZL-Ah1 and 29 (55.8%) ORFs in PZL-Ah8 were known to functional proteins in NCBI database, while the remaining ORFs were classified as “hypothetical proteins”, whose functions were yet unknown. By comparing, ORF 02, ORF 29 and ORF 04 in PZL-Ah1, ORF24 in PZL-Ah8 were responsible for the host cell lysis. In conclusion, genomic studies of these two novel phages would lay the foundation for expanding the phage genome database and providing good candidates for phage typing applications.

Reduced pathogenicity of velogenic NDV strain AF22420-I via site-directed mutagenesis of V gene

Newcastle disease virus (NDV), an avian paramyxovirus, has the potential to be used as an anti-cancer therapeutic vaccine due to its oncolytic and immunostimulatory activities. The virus can be categorised into three pathotypes: lentogenic, mesogenic, and velogenic; of the three pathotypes, the lentogenic strains such as the La Sota are the preferred pathotype for vaccine development due to their low virulence to birds. On the other hand, the translation of the virus to clinic of the velogenic strain AF2240-I is hindered by its virulence towards birds although it exhibits strong oncolysis with significant outcomes both in vitro and in vivo. This study aims to reduce the pathogenicity of AF2240-I yet retaining the anti-cancer properties of the virus. To achieve this, the V protein that acts as an interferon antagonist was chosen to be mutated. It is a non-structural protein that does not interfere with the binding and infection of the virus; hence, mutation of this virulence factor was deducted to be able to reduce harm to the avian species but retain its anti-cancer properties as much as possible. The V protein, which was produced from the insertion of an additional G into a conserved editing site of the P gene, was mutated by substituting the G nucleotide at position 411 from the start of P gene to a T nucleotide. This mutation will produce a premature stop codon from the V mRNA, resulting in a truncated V protein; but only causes a silent mutation in the P protein. The recombinant virus was recovered by the use of BHK cells stably expressing the phage T7 RNA polymerase. The pathogenicity of the mutated virus was determined in 9- to 11-day-old embryonated SPF chicken eggs. The mean death time (MDT) was determined to be 73.6 hours at the minimal lethal dose of 10-7, resembling to that of a mesogenic strain. The virulence of the mutated virus has been successfully reduced where it could be potentially used as the vector for the development of recombinant oncolytic virus for cancer treatment.

Biological Characterization and Evolution of Bacteriophage T7-△holin During the Serial Passage Process

Bacteriophage T7 gene 17.5 coding for the only known holin is one of the components of its lysis system, but the holin activity in T7 is more complex than a single gene, and evidence points to the existence of additional T7 genes with holin activity. In this study, a T7 phage with a gene 17.5 deletion (T7-△holin) was rescued and its biological characteristics and effect on cell lysis were determined. Furthermore, the genomic evolution of mutant phage T7-△holin during serial passage was assessed by whole-genome sequencing analysis. It was observed that deletion of gene 17.5 from phage T7 delays lysis time and enlarges the phage burst size; however, this biological characteristic recovered to normal lysis levels during serial passage. Scanning electron microscopy showed that the two opposite ends of E. coli BL21 cells swell post-T7-△holin infection rather than drilling holes on cell membrane when compared with T7 wild-type infection. No visible progeny phage particle accumulation was observed inside the E. coli BL21 cells by transmission electron microscopy. Following serial passage of T7-△holin from the 1st to 20th generations, the mRNA levels of gene 3.5 and gene 19.5 were upregulated and several mutation sites were discovered, especially two missense mutations in gene 19.5, which indicate a potential contribution to the evolution of the T7-△holin. Although the burst size of T7-△holin increased, high titer cultivation of T7-△holin was not achieved by optimizing the culture process. Accordingly, these results suggest that gene 19.5 is a potential lysis-related component that needs to be studied further and that the T7-△holin strain with its gene 17.5 deletion is not adequate to establish the high-titer phage cultivation process.

Matrix-trapped viruses can prevent invasion of bacterial biofilms by colonizing cells

Bacteriophages can be trapped in the matrix of bacterial biofilms, such that the cells inside them are protected. It is not known whether these phages are still infectious and whether they pose a threat to newly arriving bacteria. Here we address these questions using Escherichia coli and its lytic phage T7. Prior work has demonstrated that T7 phages are bound in the outermost curli polymer layers of the E. coli biofilm matrix. We show that these phages do remain viable and can kill colonizing cells that are T7-susceptible. If cells colonize a resident biofilm before phages do, we find that they can still be killed by phage exposure if it occurs soon thereafter. However, if colonizing cells are present on the biofilm long enough before phage exposure, they gain phage protection via envelopment within curli-producing clusters of the resident biofilm cells.

Modification of Bacteriophages to Increase Their Association with Lung Epithelium Cells In Vitro

There is currently a renaissance in research on bacteriophages as alternatives to antibiotics. Phage specificity to their bacterial host, in addition to a plethora of other advantages, makes them ideal candidates for a broad range of applications, including bacterial detection, drug delivery, and phage therapy in particular. One issue obstructing phage efficiency in phage therapy settings is their poor localization to the site of infection in the human body. Here, we engineered phage T7 with lung tissue targeting homing peptides. We then used in vitro studies to demonstrate that the engineered T7 phages had a more significant association with the lung epithelium cells than wild-type T7. In addition, we showed that, in general, there was a trend of increased association of engineered phages with the lung epithelium cells but not mouse fibroblast cells, allowing for targeted tissue specificity. These results indicate that appending phages with homing peptides would potentially allow for greater phage concentrations and greater efficacy at the infection site.

λ Recombineering Used to Engineer the Genome of Phage T7

Bacteriophage T7 and T7-like bacteriophages are valuable genetic models for lytic phage biology that have heretofore been intractable with in vivo genetic engineering methods. This manuscript describes that the presence of λ Red recombination proteins makes in vivo recombineering of T7 possible, so that single base changes and whole gene replacements on the T7 genome can be made. Red recombination functions also increase the efficiency of T7 genome DNA transfection of cells by ~100-fold. Likewise, Red function enables two other T7-like bacteriophages that do not normally propagate in E. coli to be recovered following genome transfection. These results constitute major technical advances in the speed and efficiency of bacteriophage T7 engineering and will aid in the rapid development of new phage variants for a variety of applications.

Simulations of Phage T7 Capsid Expansion Reveal the Role of Molecular Sterics on Dynamics

Molecular dynamics techniques provide numerous strategies for investigating biomolecular energetics, though quantitative analysis is often only accessible for relatively small (frequently monomeric) systems. To address this limit, we use simulations in combination with a simplified energetic model to study complex rearrangements in a large assembly. We use cryo-EM reconstructions to simulate the DNA packaging-associated 3 nm expansion of the protein shell of an initially assembled phage T7 capsid (called procapsid or capsid I). This is accompanied by a disorder–order transition and expansion-associated externalization displacement of the 420 N-terminal tails of the shell proteins. For the simulations, we use an all-atom structure-based model (1.07 million atoms), which is specifically designed to probe the influence of molecular sterics on dynamics. We find that the rate at which the N-terminal tails undergo translocation depends heavily on their position within hexons and pentons. Specifically, trans-shell displacements of the hexon E subunits are the most frequent and hexon A subunits are the least frequent. The simulations also implicate numerous tail translocation intermediates during tail translocation that involve topological traps, as well as sterically induced barriers. The presented study establishes a foundation for understanding the precise relationship between molecular structure and phage maturation.