Search Results (211)

Globally, the rise in MDR P. aeruginosa infections poses a serious threat to public health, as these strains frequently exhibit extensive resistance to conventional antibiotics, prompting interest in bacteriophages as alternative treatments. In this study, we isolated and characterized a lytic P. aeruginosa phage, vB_Pae_YuaWU01, from hospital sewage in southern Thailand. Morphological analysis revealed Siphovirus-like characteristics. The phage demonstrated efficient host adsorption, with approximately 85.9% of particles attached within 15 min, and exhibited a latent period of 50 min with a burst size of 17.2 PFU/cell. It showed strong lytic activity, consistently suppressing bacterial growth without no regrowth observed over 72 h. Notably, the phage significantly inhibited biofilm formation by up to 59.9% and reduced pre-established biofilms by 39.78% at the highest tested concentration (10⁹ PFU/mL). Genome analysis revealed a 61,824 bp double-stranded DNA genome with 64.48% GC content and 88 predicted genes. Bioinformatic analysis suggests that the genome is organized into structural, replication, and lysis modules. Importantly, no toxin, antimicrobial resistance, lysogeny, or tRNA genes were identified, suggesting a favorable safety profile. The phage was classified within the genus Yuavirus, showing 97.4% genomic similarity to Sphaerotilus phage SN1, which infects a different host strain. The findings highlight its potential as a genetically safe therapeutic agent; however, its limited host range indicates that it may be best positioned as a strategic component of phage cocktails or as a synergistic partner with antibiotics to maximize therapeutic efficacy. Full article

Caulobacter segnis strain CBR1 enhances the germination rate and total biomass of Arabidopsis plants. Since bacteriophages are usually present in the rhizosphere, we isolated three additional bacteriophages, designated TMCBR2, TMCBR3, and W2, that can replicate using CBR1 as the host strain. The genome sizes and morphologies of the new phages were similar to those of the previously isolated Kronos phage, and when we compared the nucleotide sequence of these new phage genomes, we found only minor differences among the four phage genomes. Pairwise sequence comparisons indicated that the phage genomes should be grouped into three separate species within Kronosvirus genus. Interestingly, we found that most of the genomic variation occurred among genes of unknown function within a 10 kb region of the 42 kb genomes with little variation in the remaining 32 kb which contains the genes known to be important for phage propagation. Full article

Foodborne pathogens of Enterobacteriaceae are becoming an increasing global concern, with multidrug-resistant strains posing significant risks to food safety and public health, especially in high-risk products like dairy. This research focused on isolating, biologically characterizing, and genomically profiling new bacteriophages that target key Enterobacteriaceae members as potential biocontrol agents. Eight phages were isolated from wastewater using four bacterial hosts and analyzed through transmission electron microscopy, one-step growth analysis, adsorption kinetics, host range evaluation, whole-genome sequencing, comparative genomics, phylogenetic analysis, proteomic profiling, and virion assembly pathway characterization. All eight isolates exhibited icosahedral heads with contractile tails typical of Myoviridae morphology, demonstrated broad-spectrum lytic activity against 21 bacterial strains (infectivity: 47.6–95.2%), showed high adsorption efficiencies (84.75–99.98%), and had burst sizes ranging from 11 to 166 particles per cell. Genome sizes varied from 103 to 170 kb with coding densities between 92–96%. Importantly, none contained antimicrobial resistance genes, virulence factors, or lysogeny-associated elements, confirming their strictly lytic lifestyles and favorable biosafety profiles. Phylogenetic and comparative analyses indicated mosaic genomic structures influenced by horizontal gene transfer rather than host phylogeny. These findings provide a robust biological and genomic basis for evaluating these phages as potentially safe and effective alternatives to antibiotics in controlling foodborne Enterobacteriaceae, pending further in situ validation. Full article

Chryseobacterium indologenes MA9 is a causative agent of root rot disease in Panax notoginseng (P. notoginseng), with its high incidence being a major manifestation of continuous cropping barriers, severely hindering the sustainable development of the P. notoginseng industry. In this study, a novel lytic bacteriophage, MA9V-3, was isolated from wastewater, targeting C. indologenes MA9. The phage produced clear plaques, ranging from 1 to 3 mm in diameter, with a surrounding halo. Phage MA9V-3 achieved an adsorption rate of up to 80% after 30 min of contact with C. indologenes MA9, a latent period of approximately 40 min, and an average burst-size if 160 PFU/cell. Transmission electron microscopy revealed that phage MA9V-3 possesses an icosahedral head and a contractile tail, exhibiting a typical myovirus-like morphology. According to the latest ICTV taxonomy, MA9V-3 belongs to the class Caudoviricetes, and the phage’s biocontrol efficacy and inhibitory capacity were evaluated at different multiplicity of infection (MOI s). The results showed that the highest titer recorded at 1.6 × 10¹⁰ PFU/mL. Whole-genome sequencing revealed that MA9V-3 is a double-stranded circular DNA virus, with a genome length of 103,203 bp, GC content of 34.29%, and 150 open reading frames (ORFs), one of which is related to tRNA. Only 13 of these ORFs encode known functional sequences, likely due to the limited available gene data for such phages in the database, with additional details on hypothetical proteins yet to be uncovered. Comparative database analysis confirmed that the phage genome contains no antibiotic resistance or toxin-related genes. Phage therapy experiments were performed using MA9V-3 and two other phages screened in our laboratory. The experimental results showed that phage MA9V-3 may be a potential candidate for effectively controlling the infection of Panax notoginseng by C. indologenes MA9, and offering valuable insights into the potential application of phage therapy for managing bacterial plant diseases. Full article

In response to the alarming rise in antimicrobial resistance, bacteriophages have re-emerged as a promising alternative to conventional antibiotic therapy. The main objective of this paper was to characterize a newly isolated phage (vB_SEC_3) in the context of its suitability for phage therapy against MDR E. coli, which is considered a priority pathogen. The phage was characterized at the morphological, genomic, and biological levels relevant to phage therapy. TEM analyses revealed a non-enveloped icosahedral capsid lacking tail structure. Phylogenetic and tANI analyses placed the phage within the α3 phages (genus Alphatrevirus) of the less-studied family Microviridae and revealed <95% similarity to its closest relatives, suggesting vB_SEC_3 is a putative novel species within this genus. The genome (6085 bp, GC content 45.3%) displayed the conserved organization typical for these phages, including overlapping genes. No known genes associated with lysogeny, antibiotic resistance, or virulence were detected. Briefly, vB_SEC_3 was able to effectively lyse two MDR strains of E. coli (S1 and B5, EOP 0.735 and 0.961, respectively). Tolerance to a wide pH range (4–10.5) and to temperatures up to 80 °C was established. Six-month storage of the crude lysate at 4 °C resulted in a slight decrease (<0.16 log₁₀ PFU/mL) in phage titer. This study provides additional insights into the biology and diversity of Microviridae phages and offers a basis for future investigations into their potential relevance in the context of combating MDR bacteria. Full article

Bacillus cereus is a major foodborne pathogen responsible for food spoilage and foodborne illness, including strains producing emetic toxins. In this study, two bacteriophages, PBC_MG88 and PBC_MG99, were isolated from wastewater using emetic B. cereus strains as hosts and were comprehensively characterized. Both phages formed clear plaques with halos and exhibited siphovirus morphology. Host range analysis against 172 B. cereus strains showed that PBC_MG88 and PBC_MG99 infected 50 and 60 strains, respectively. One-step growth experiments revealed efficient lytic activity, with latent periods of 20–25 min and burst sizes of 59–63 PFU per infected cell. More than 90% of phage particles adsorbed to host cells within 15 min. Both phages were stable across a wide temperature range (4–55 °C) and pH values (4–11). Genome sequencing revealed ~37 kb double-stranded DNA genomes lacking antibiotic resistance or virulence genes; however, the presence of lysogeny-related genes suggests a temperate lifestyle. Comparative genomic analyses indicated that both phages represent novel species within the genus Lwoffvirus. Biofilm assays demonstrated significant inhibition of B. cereus biofilm formation and reduction of pre-established biofilms. Overall, this study expands knowledge of B. cereus phage diversity and highlights the importance of genomic characterization in phage-based biocontrol research. Full article

Bacteriophages (phages) are common and diverse viruses that specifically infect bacteria. Although their potential to suppress bacterial pathogens was recognized a century ago, their broader use remained limited for decades. Today, renewed interest in phages is rapidly expanding beyond medical use into agriculture, where they are being explored as environmentally friendly tools for managing bacterial plant diseases. Despite growing interest, our understanding of phage biology and genetics remains limited. This review focuses on phages that specifically infect Xanthomonas campestris pv. campestris (Xcc), a bacterial pathogen that seriously challenges the production of commercially valuable crops such as cabbage and broccoli. Phages could provide a much-needed addition to the current management practices that often fail to provide consistent results, especially when environmental conditions favor disease development. Here we summarize the currently available knowledge on Xcc phages, including their morphology, growth parameters, and stability under various environmental conditions, genomic features and basic genetic characteristics. Given recent changes in phage taxonomy, we also outline the newly adopted genome-based classification system, which has led to the reclassification of all officially recognized Xcc phages. A summary of practical applications provides encouraging results and paves the way for future research on phages of various plant pathogenic bacteria and their potential commercial use. Full article

Escherichia coli is a major pathogen responsible for urinary tract infections, septicemia, and other clinically relevant conditions, with increasing multidrug resistance (MDR) limiting available treatment options. In this context, bacteriophages represent a valuable resource for exploring novel antimicrobial and biotechnological tools. Here, we report the isolation and genomic characterization of BorMax, a novel lytic phage infecting multiple MDR E. coli. Transmission electron microscopy revealed a tailed morphology consistent with Dhillonvirus. Whole genome sequencing and de novo assembly showed a linear double-stranded DNA genome of 45,502 bp, encoding 70 predicted coding sequences (CDSs) and lacking tRNAs. Bioinformatic analyses confirmed the absence of lysogeny-associated genes, as well as virulence and antimicrobial resistance determinants. Comparative genomics using classified BorMax within the genus Dhillonvirus as a new species, sharing <77% intergenomic similarity with known members. Notably, predictions using PaCRISPR and AcRanker identified four CDSs with strong anti-CRISPR (Acr) potential, representing previously undescribed Acr candidates in this group. These genomic features highlight the novelty, safety, and potential biotechnological relevance of BorMax and contribute to the expanding genomic and functional diversity of Dhillonvirus and E. coli-infecting phages. Full article

While Escherichia coli can be found in the bladders of females without lower urinary tract symptoms, its presence is often associated with urinary tract infections (UTIs). The genomic plasticity of E. coli, including urogenital strains, is largely shaped by the integration of prophages. Although genomic and metagenomic analyses of urinary E. coli and the urinary microbiome suggest that prophages are abundant, many represent uncharacterized species. Sequence analysis suggests that these prophages represent temperate phages. This study aimed to fill this gap, isolating and characterizing temperate phages from urinary E. coli strains. We assessed phage host range across a panel of urinary isolates, providing a critical first step for future work investigating their putative role in shaping E. coli populations within the urinary community. In total, 20 temperate urinary phages were evaluated. Phage morphology and genic content of these phages were determined via transmission electron microscopy (TEM) and whole-genome sequencing, respectively. Together, these analyses provide insight into the diversity, infectivity, and genomic composition of temperate coliphages from the female urinary tract. Full article

Multidrug-resistant (MDR) Escherichia coli (E. coli) at the poultry–human interface motivates evaluating strictly lytic bacteriophages as targeted biocontrol candidates. A lytic E. coli phage (GADS24) was isolated from poultry waste in Saudi Arabia. Plaque formation and host range were assessed against 10 clinical E. coli isolates. Virion morphology was examined by transmission electron microscopy (TEM). Whole-genome sequencing (Illumina) and annotation (Prokka/RAST) were followed by comparative genomics (BLASTn 2.15.0, ANI JSpeciesWS: 2014–2025 Ribocon GmbH—Version: 5.0.3, dDDH GGDC: GGDC 3.0 and phylogenetic/proteomic analyses for taxonomic placement. GADS24 formed clear plaques and lysed 5 of 10 clinical E. coli isolates tested. TEM revealed an icosahedral capsid (~72.6 nm) and a contractile tail (~131.7 nm), consistent with Tevenvirinae/Mosigvirus morphology. The dsDNA genome is 168,896 bp (GC 43.8%) with 268 predicted ORFs and two tRNA genes (tRNA-Arg and tRNA-Met); no lysogeny-related genes were detected. The closest relative was Escherichia phage JN02 (98.44% ANI; 57.8% dDDH), supporting assignment to Mosigvirus while indicating a genome-resolved distinct lineage. The genome is available in GenBank (OQ703618). GADS24 represents a genome-resolved, strictly lytic Mosigvirus with in vitro biocontrol-relevant phenotyping against E. coli, supporting follow-up development for poultry-associated infection control and deeper phage–host interaction studies. Full article

Antimicrobial resistance is a growing global health threat, necessitating alternatives to conventional antibiotics. Bacteriophages, viruses that specifically target bacteria, represent a promising option, and phage-loaded electrospun fibers have recently gained attention as wound dressings for localized phage therapy. However, the influence of phage morphology and scaffold design has been largely overlooked. This study investigates how phage morphology and structure, in conjunction with scaffold design and processing conditions, may influence the biological performance of electrospun scaffolds. A bilayer scaffold was developed comprising a supportive polycaprolactone (PCL)/gelatin (70:30) layer and a polyvinyl alcohol (PVA) top layer loaded with bacteriophages. Two phage types, short-tailed podovirus APTC-SL.1 and long-tailed myovirus APTC-Efa.20, were incorporated into PVA fibers to evaluate their antibacterial activity against Staphylococcus lugdunensis and Enterococcus faecalis, respectively. The fibers were characterized using XRD, FTIR, TGA, optical microscopy, SEM, TEM, wettability analysis, and in vitro degradation tests. Biological assessments included antimicrobial testing, phage viability, and phage release. The bilayer scaffold containing short-tailed phages preserved phage viability and produced clear zones of lysis against S. lugdunensis, with ≈8.15% viability retained after electrospinning and relatively controlled release, whereas long-tailed phages showed no antibacterial activity. These results suggest that phage structure and morphology, together with electrospinning conditions and scaffold architecture, may play an important role in maintaining phage functionality in wound dressing applications, while acknowledging that host–phage interactions may also contribute to the observed differences. Full article

Exudative epidermitis (EE), caused by Staphylococcus hyicus, represents an issue for swine production, particularly due to antimicrobial resistance. In this project, we isolated bacteriophages using S. hyicus as host and studied them as a potential alternative to antibiotic treatment in Quebec, Canada. Three phages, STAE-4, STAF-3, and STAM-1, were isolated from swine farm samples using a single S. hyicus strain (SC366) as the host. Transmission electron microscopy revealed that all three phages exhibited a siphovirus-like morphology, and RAPD-PCR profiling indicated that the phages were genetically distinct. Whole genome sequencing confirmed these differences and showed that the three phages were closely related to each other, and, more importantly, highly similar to phages previously described as infecting Staphylococcus chromogenes, a species closely related to S. hyicus. Host range analysis confirmed that the three phages preferentially infected the S. chromogenes strains included in the study, exhibiting minimal to no lytic activity against other strains of S. hyicus or Staphylococcus agnetis, another closely related species. The only exception was the host S. hyicus strain SC366, which was effectively infected by all three phages, albeit less efficiently than the most sensitive S. chromogenes strain (SC385). Adsorption tests further supported these observations, showing that phages bound to strain SC366 much more quickly than to SC385, despite the lower lytic activity observed. Taken together, these results highlight that while the phages retain some capacity to infect S. hyicus, their biological properties point to a stronger adaptation to S. chromogenes, indicating that they are not suitable candidates for controlling EE. Full article

Agrobacterium tumefaciens, a destructive pathogen causing crown gall disease, results in substantial agricultural losses. Traditional chemical and existing biocontrol methods are limited by environmental pollution, pesticide resistance, and low efficacy, while bacteriophages emerge as a promising alternative due to their high host specificity, environmental compatibility, and low resistance risk. In this study, we isolated and characterized a lytic phage (PAT-A) targeting A. tumefaciens, evaluating its biological traits, genomic features, and biocontrol potential. The host strain A. tumefaciens CL-1 was isolated from cherry crown gall tissue and identified by 16S rDNA sequencing. Phage PAT-A was recovered from orchard soil via the double-layer agar method, showing a tadpole-shaped morphology (60 nm head diameter, 30 nm tail length) under transmission electron microscopy (TEM). Nucleic acid analysis confirmed a double-stranded DNA genome, susceptible to DNase I but resistant to RNase A and Mung Bean Nuclease. PAT-A exhibited an optimal MOI of 0.01, tolerated wide pH and temperature ranges, but was sensitive to UV (titer declined after 15 min of irradiation) and chloroform (8% survival at a 5% concentration). Whole-genome sequencing revealed a 44,828 bp genome with a compact structure, and phylogenetic/collinearity analyses placed it in the Atuphduvirus genus (Autographiviridae). Biocontrol experiments on tobacco plants demonstrated that PAT-A significantly reduced crown gall incidence. Specifically, simultaneous inoculation of PAT-A and A. tumefaciens CL-1 resulted in the lowest tumor incidence (12.0%), while pre-inoculation of PAT-A 2 days before pathogen exposure achieved an incidence rate of 33.3%. In conclusion, PAT-A is a novel strictly lytic phage with favorable biological properties and potent biocontrol efficacy against A. tumefaciens, enriching phage resources for crown gall management and supporting phage-based agricultural biocontrol strategies. Full article

Rapid isolation of therapeutic bacteriophages from environmental sources is essential for personalized phage therapy, particularly when appropriate phages are unavailable in existing banks. However, comprehensive characterization of all candidate phages is resource-intensive, especially when plaque morphologies are similar and fail to discriminate between distinct phages. Here, we present an upstream screening approach that utilizes co-culture growth curve analysis to rapidly triage phage isolates during the early isolation process. We extracted seven biologically meaningful features that capture lysis kinetics, lysis efficiency, and post-lysis dynamics from bacterial growth curves and applied unsupervised clustering algorithms for phage discrimination. Validation using T-phages at a multiplicity of infection of 0.01 demonstrated superior clustering performance (Adjusted Rand Index = 0.881 ± 0.057) compared to established metrics including the Virulence Index and Centroid Index. Application to phages isolated from sewage successfully identified all three genomically distinct species present (sampling score = 1.0), enabling targeted selection of representative phages for downstream characterization. This approach reduced candidates requiring detailed analysis by two-thirds (from 21 to 7 isolates) while maintaining complete species coverage, thereby providing an efficient and scalable screening tool that reduces workload for downstream analyses and accelerates discovery of novel therapeutic phages for clinical applications. Full article

In this study, we characterized the holin-like protein ORF70 from the cyanophage MaMV-DC, offering valuable insights into its role in phage-mediated host cell lysis. ORF70 shares key features with class III holins, such as a hydrophobic transmembrane domain and membrane-associated localization, which are crucial for its bacteriolytic activity. Subcellular localization studies suggested its association with the membrane, supporting its classification as a holin-like protein. Overexpression of ORF70 in E. coli resulted in significant growth inhibition, increased β-galactosidase leakage, and visual confirmation of cell death through live/dead staining. Additionally, ORF70’s sensitivity to the energy toxin 2,4-dinitrophenol (DNP) further indicated its holin-like activity by promoting membrane depolarization. Transmission electron microscopy and Gram staining revealed characteristic morphological changes in E. coli cells, including membrane disruption, consistent with damage caused by holins. These results suggest that ORF70 acts as a holin-like protein that disrupts the host membrane, leading to bacterial cell death. Our study provides evidence supporting the holin-like activity of ORF70 from cyanophage MaMV-DC. This research significantly enhances our understanding of phage-host interactions and opens new avenues for developing phage-based therapies, offering promising alternatives to traditional antibiotics amidst the growing challenge of antibiotic resistance. Full article