Preparation of a phage DNA fragment library for whole genome shotgun sequencing

Successful phage-antibiotic therapy of P. aeruginosa implant-associated infection in a Siamese cat

Antibiotic-resistant pathogens are a growing global issue, leading to untreatable infectious diseases in both humans and animals. Personalized bacteriophage (phage) therapy, the use of specific anti-bacterial viruses, is currently a leading approach to combat antibiotic-resistant infections. The implementation of phage therapy has primarily been focused on humans, almost neglecting the impact of such infections on the health and welfare of companion animals. Pets also have the potential to spread resistant infections to their owners or the veterinary staff through zoonotic transmission. Here, we showcase personalized phage-antibiotic treatment of a cat with a multidrug-resistant Pseudomonas aeruginosa implant-associated infection post-arthrodesis surgery. The treatment encompassed a tailored combination of an anti-P. aeruginosa phage and ceftazidime, precisely matched to the pathogen. The phage was topically applied to the surgical wound while the antibiotic was administered intramuscularly. After two treatment courses spanning 7 and 3 weeks, the surgical wound, which had previously remained open for five months, fully closed. To the best of our knowledge, this is the first case of personalized phage therapy application in felines, which provides further evidence of the effectiveness of this approach. The successful outcome paves the way for personalized phage-antibiotic treatments against persistent infections therapy in veterinary practice.

Characterization and genomic analysis of PA-56 Pseudomonas phage from Istanbul, Turkey: Antibacterial and antibiofilm efficacy alone and with antibiotics

Phages are ubiquitous in freshwater, seawater, soil, the human body, and sewage water. They are potent biopharmaceuticals against antimicrobial-resistant bacteria and offer a promising alternative for treating infectious diseases. Also, combining phages with antibiotics enhances the antibiotics' efficacy. This study focused on two Pseudomonas aeruginosa phages isolated from lake and sewage water samples and one of them selected for further investigation. Isolated phages PA-56 and PA-18 infected 92 % and 86 % of the tested 25 clinical Pseudomonas aeruginosa strains, respectively. PA-56 with strong activity was chosen for detailed characterization, antimicrobial studies, and genome analysis. Combining PA-56 with ciprofloxacin or meropenem demonstrated phage-antibiotic synergism and increased antibiofilm efficacy. Genome analysis revealed a GC ratio of 54 % and a genome size of 42.761 bp, with no virulence or antibiotic resistance genes. Notably, PA-56 harboured the toxin-antitoxin protein, MazG. Overall, this study suggests that PA-56 holds promise for future applications in industry or medicine.

The Biological Characteristics of Mycobacterium Phage Henu3 and the Fitness Cost Associated with Its Resistant Strains

Tuberculosis (TB), caused by Mycobacterium tuberculosis, is an infectious disease that seriously affects human life and health. Despite centuries of efforts to control it, in recent years, the emergence of multidrug-resistant bacterial pathogens of M. tuberculosis due to various factors has exacerbated the disease, posing a serious threat to global health. Therefore, a new method to control M. tuberculosis is urgently needed. Phages, viruses that specifically infect bacteria, have emerged as potential biocontrol agents for bacterial pathogens due to their host specificity. In this study, a mycobacterium phage, Henu3, was isolated from soil around a hospital. The particle morphology, biological characteristics, genomics and phylogeny of Henu3 were characterized. Additionally, to explore the balance between phage resistance and stress response, phage Henu3-resistant strains 0G10 and 2E1 were screened by sequence passage and bidirectional validation methods, which significantly improved the sensitivity of phage to antibiotics (cefotaxime and kanamycin). By whole-genome re-sequencing of strains 0G10 and 2E1, 12 genes involved in cell-wall synthesis, transporter-encoded genes, two-component regulatory proteins and transcriptional regulatory factor-encoded genes were found to have mutations. These results suggest that phage Henu3 has the potential to control M. tuberculosis pathogens, and phage Henu3 has the potential to be a new potential solution for the treatment of M. tuberculosis infection.

Isolation and Characterization of Six Novel Fusobacterium necrophorum Phages

Introduction

Fusobacterium necrophorum, a human and animal pathogen, is the primary etiologic agent of bovine liver abscesses and a driving factor for prophylactic antibiotic use in the fed cattle industry. Considering calls to reduce agricultural antibiotic use, we isolated phages capable of killing F. necrophorum as an alternative or complementary biocontrol strategy.

Methods

Six novel phages (φFN37, φRTG5, φKSUM, φHugo, φPaco, and φBB) were isolated from rumen fluid or ruminal F. necrophorum isolates and subjected to host range testing on both F. necrophorum subspecies. Four F. necrophorum subspecies, necrophorum phages, were tested for cross-resistance and host growth inhibition individually and in pairs. Additionally, genomic sequencing, annotation, and analysis were performed.s.

Results

Four of six isolated phages were able to form lysogens, although all six contained lysogeny-related genes. φKSUM and φBB, did not form lysogens and were able to infect both subspecies. Four phages could infect F. necrophorum 8L1 (a liver abscess model challenge strain) in vitro. Genomic analysis showed that these phages belong to class Caudoviricetes with genome sizes ranging from 35 kbp to 111 kbp and GC values ranging from 26% to 36% and have extremely limited similarity to other deposited phage genomes infecting Fusobacterium or other genera.

Conclusions

Although all phages isolated contained sequences bearing similarities to genes implicated in lysogeny, the four selected for use in cocktails showed potential in inhibiting host growth, with several demonstrating promising attributes for biocontrol and therapeutic applications. Phage cocktails that may offer enhanced antibacterial activity were also identified, indicating the potential of some lysogenic phages to be adapted for biocontrol or therapeutic purposes when lytic phages are difficult to obtain.

Genomic and Phenotypic Analysis of Salmonella enterica Bacteriophages Identifies Two Novel Phage Species

Bacteriophages (phages) are potential alternatives to chemical antimicrobials against pathogens of public health significance. Understanding the diversity and host specificity of phages is important for developing effective phage biocontrol approaches. Here, we assessed the host range, morphology, and genetic diversity of eight Salmonella enterica phages isolated from a wastewater treatment plant. The host range analysis revealed that six out of eight phages lysed more than 81% of the 43 Salmonella enterica isolates tested. The genomic sequences of all phages were determined. Whole-genome sequencing (WGS) data revealed that phage genome sizes ranged from 41 to 114 kb, with GC contents between 39.9 and 50.0%. Two of the phages SB13 and SB28 represent new species, Epseptimavirus SB13 and genera Macdonaldcampvirus, respectively, as designated by the International Committee for the Taxonomy of Viruses (ICTV) using genome-based taxonomic classification. One phage (SB18) belonged to the Myoviridae morphotype while the remaining phages belonged to the Siphoviridae morphotype. The gene content analyses showed that none of the phages possessed virulence, toxin, antibiotic resistance, type I-VI toxin-antitoxin modules, or lysogeny genes. Three (SB3, SB15, and SB18) out of the eight phages possessed tailspike proteins. Whole-genome-based phylogeny of the eight phages with their 113 homologs revealed three clusters A, B, and C and seven subclusters (A1, A2, A3, B1, B2, C1, and C2). While cluster C1 phages were predominantly isolated from animal sources, cluster B contained phages from both wastewater and animal sources. The broad host range of these phages highlights their potential use for controlling the presence of S. enterica in foods.

Phage DNA Extraction, Genome Assembly, and Genome Closure

Bacteriophages, or more simply phages, are currently experiencing a renaissance in life science research for their roles in natural microbial communities, their potential use as antimicrobials, and biotechnological applications. In the modern era, one of the primary steps in phage characterization is obtaining the sequence of the complete genome; this information can be used to determine the relationship of the phage to known phages, predict phage lifestyle, and is a prerequisite for many downstream applications. This protocol describes methods for determining the complete sequence of a double-stranded DNA bacteriophage genome, including DNA extraction from a phage lysate, sending the DNA out to a sequencing service, assembly of the sequence raw reads, and completion of the genome sequence.

Phage Milagro: a platform for engineering a broad host range virulent phage for Burkholderia

IMPORTANCE

Burkholderia infections are a significant concern in people with CF and other immunocompromising disorders, and are difficult to treat with conventional antibiotics due to their inherent drug resistance. Bacteriophages, or bacterial viruses, are now seen as a potential alternative therapy for these infections, but most of the naturally occurring phages are temperate and have narrow host ranges, which limit their utility as therapeutics. Here we describe the temperate Burkholderia phage Milagro and our efforts to engineer this phage into a potential therapeutic by expanding the phage host range and selecting for phage mutants that are strictly virulent. This approach may be used to generate new therapeutic agents for treating intractable infections in CF patients.

Host interactions of novel Crassvirales species belonging to multiple families infecting bacterial host, Bacteroides cellulosilyticus WH2

Bacteroides, the prominent bacteria in the human gut, play a crucial role in degrading complex polysaccharides. Their abundance is influenced by phages belonging to the Crassvirales order. Despite identifying over 600 Crassvirales genomes computationally, only few have been successfully isolated. Continued efforts in isolation of more Crassvirales genomes can provide insights into phage-host-evolution and infection mechanisms. We focused on wastewater samples, as potential sources of phages infecting various Bacteroides hosts. Sequencing, assembly, and characterization of isolated phages revealed 14 complete genomes belonging to three novel Crassvirales species infecting Bacteroides cellulosilyticus WH2. These species, Kehishuvirus sp. 'tikkala' strain Bc01, Kolpuevirus sp. 'frurule' strain Bc03, and 'Rudgehvirus jaberico' strain Bc11, spanned two families, and three genera, displaying a broad range of virion productions. Upon testing all successfully cultured Crassvirales species and their respective bacterial hosts, we discovered that they do not exhibit co-evolutionary patterns with their bacterial hosts. Furthermore, we observed variations in gene similarity, with greater shared similarity observed within genera. However, despite belonging to different genera, the three novel species shared a unique structural gene that encodes the tail spike protein. When investigating the relationship between this gene and host interaction, we discovered evidence of purifying selection, indicating its functional importance. Moreover, our analysis demonstrated that this tail spike protein binds to the TonB-dependent receptors present on the bacterial host surface. Combining these observations, our findings provide insights into phage-host interactions and present three Crassvirales species as an ideal system for controlled infectivity experiments on one of the most dominant members of the human enteric virome.

Topical phage therapy in a mouse model of Cutibacterium acnes-induced acne-like lesions

Acne vulgaris is a common neutrophil-driven inflammatory skin disorder in which Cutibacterium acnes (C. acnes) is known to play a key role. For decades, antibiotics have been widely employed to treat acne vulgaris, inevitably resulting in increased bacterial antibiotic resistance. Phage therapy is a promising strategy to combat the growing challenge of antibiotic-resistant bacteria, utilizing viruses that specifically lyse bacteria. Herein, we explore the feasibility of phage therapy against C. acnes. Eight novel phages, isolated in our laboratory, and commonly used antibiotics eradicate 100% of clinically isolated C. acnes strains. Topical phage therapy in a C. acnes-induced acne-like lesions mouse model affords significantly superior clinical and histological scores. Moreover, the decrease in inflammatory response was reflected by the reduced expression of chemokine CXCL2, neutrophil infiltration, and other inflammatory cytokines when compared with the infected-untreated group. Overall, these findings indicate the potential of phage therapy for acne vulgaris as an additional tool to conventional antibiotics.

The transcriptional regulator CtrA controls gene expression in Alphaproteobacteria phages: Evidence for a lytic deferment pathway

Pilitropic and flagellotropic phages adsorb to bacterial pili and flagella. These phages have long been used to investigate multiple aspects of bacterial physiology, such as the cell cycle control in the Caulobacterales. Targeting cellular appendages for adsorption effectively constrains the population of infectable hosts, suggesting that phages may have developed strategies to maximize their infective yield. Brevundimonas phage vB_BsubS-Delta is a recently characterized pilitropic phage infecting the Alphaproteobacterium Brevundimonas subvibrioides. Like other Caulobacterales, B. subvibrioides divides asymmetrically and its cell cycle is governed by multiple transcriptional regulators, including the master regulator CtrA. Genomic characterization of phage vB_BsubS-Delta identified the presence of a large intergenic region with an unusually high density of putative CtrA-binding sites. A systematic analysis of the positional distribution of predicted CtrA-binding sites in complete phage genomes reveals that the highly skewed distribution of CtrA-binding sites observed in vB_BsubS-Delta is an unequivocal genomic signature that extends to other pilli- and flagellotropic phages infecting the Alphaproteobacteria. Moreover, putative CtrA-binding sites in these phage genomes localize preferentially to promoter regions and have higher scores than those detected in other phage genomes. Phylogenetic and comparative genomics analyses show that this genomic signature has evolved independently in several phage lineages, suggesting that it provides an adaptive advantage to pili/flagellotropic phages infecting the Alphaproteobacteria. Experimental results demonstrate that CtrA binds to predicted CtrA-binding sites in promoter regions and that it regulates transcription of phage genes in unrelated Alphaproteobacteria-infecting phages. We propose that this focused distribution of CtrA-binding sites reflects a fundamental new aspect of phage infection, which we term lytic deferment. Under this novel paradigm, pili- and flagellotropic phages exploit the CtrA transduction pathway to monitor the host cell cycle state and synchronize lysis with the presence of infectable cells.

Comparative genomics of Acinetobacter baumannii and therapeutic bacteriophages from a patient undergoing phage therapy

In 2016, a 68-year-old patient with a disseminated multidrug-resistant Acinetobacter baumannii infection was successfully treated using lytic bacteriophages. Here we report the genomes of the nine phages used for treatment and three strains of A. baumannii isolated prior to and during treatment. The phages used in the initial treatment are related, T4-like myophages. Analysis of 19 A. baumannii isolates collected before and during phage treatment shows that resistance to the T4-like phages appeared two days following the start of treatment. We generate complete genomic sequences for three A. baumannii strains (TP1, TP2 and TP3) collected before and during treatment, supporting a clonal relationship. Furthermore, we use strain TP1 to select for increased resistance to five of the phages in vitro, and identify mutations that are also found in phage-insensitive isolates TP2 and TP3 (which evolved in vivo during phage treatment). These results support that in vitro investigations can produce results that are relevant to the in vivo environment.

Complete Genome Sequence of Stenotrophomonas maltophilia Phage Philippe

Stenotrophomonas maltophilia is emerging as an opportunistic multidrug-resistant pathogen. S. maltophilia podophage Philippe has a 74,717-bp genome which is related broadly to the N4-like phage group, including Stenotrophomonas phage Pokken. The low sequence identity to other described phages suggests that Philippe is an unclassified member of the N4-like subfamily Rothmandenesvirinae.

Complete Genome Sequence of Stenotrophomonas maltophilia Siphophage Siara

Stenotrophomonas maltophilia is associated with an increasing incidence of nosocomial infections. Here, we describe the isolation and genome annotation of S. maltophilia siphophage Siara. Its 61,427-bp genome is currently related only to one phage in the NCBI database, namely, S. maltophilia phage Salva, and is not related to any prophages.

Complete Genome Sequence of Stenotrophomonas maltophilia Podophage Pepon

Stenotrophomonas maltophilia is an opportunistic bacterium that is commonly associated with respiratory infections in immunocompromised patients, including cystic fibrosis patients. In this report, we introduce the complete genome sequence of S. maltophilia podophage Pepon, which is a T7-like phage closely related to the previously reported phage Ponderosa.

Complete Genome Sequence of Alcaligenes faecalis Phage Piluca

Alcaligenes faecalis is an opportunistic pathogen exhibiting drug resistance. Here, the 35,451-bp genome of A. faecalis phage Piluca is described. Piluca is not closely related to any isolated phages in the NCBI database. Piluca possesses genes encoding CI-like and Cro-like repressors and a tyrosine integrase, suggesting its temperate lifestyle.

Complete Genome Sequence of Enterococcus faecalis Siphophage Sigurd

Enterococcus faecalis is associated with antibiotic-resistant infections, and this study presents E. faecalis siphophage Sigurd. The 41,811-bp Sigurd genome is divided into two arms defined by long convergent predicted transcription units that are separated by a bidirectional rho-independent terminator. Sigurd has a small terminase that is closely related to Bacillus subtilis cos phage phi105.

Complete Genome Sequence of Stenotrophomonas maltophilia Podophage Paxi

Stenotrophomonas maltophilia is a multidrug-resistant nosocomial pathogen that can cause life-threatening infections among immunocompromised populations. This report presents the complete 74,962-bp genome of S. maltophilia podophage Paxi, an N4-like phage sharing 85.3% nucleotide similarity to S. maltophilia podophage Pokken.

Complete Genome Sequence of Burkholderia cenocepacia Phage Paku

Burkholderia cenocepacia is able to cause infections in cystic fibrosis patients. B. cenocepacia phage Paku has a 42,727-bp genome sharing a phiKMV-like genome arrangement. T7-like tail components were identified in parallel with a tyrosine integrase, suggesting that Paku might exhibit a temperate lifestyle, an atypical feature for an Autographiviridae phage.

Complete Genome Sequence of Stenotrophomonas maltophilia Siphophage Sonora

Phage Sonora is a siphophage that was isolated against the opportunistic human pathogen Stenotrophomonas maltophilia. The genome of phage Sonora is 63,825 bp long and is not related to that of any phage at the nucleotide level. Sonora shares 46 of 97 total proteins with the Bordetella phages CN2, MW2, and FP1.

Complete Genome Sequence of Stenotrophomonas maltophilia Podophage Piffle

Stenotrophomonas maltophilia is an emerging multidrug-resistant opportunistic human pathogen causing various nosocomial infections. Here, we characterize the genome of S. maltophilia podophage Piffle. Its 76,332-bp genome is most closely related to the N4-like S. maltophilia podophage Pokken, with over 86% genome-wide nucleotide identity and 84 shared proteins.

Complete Genome Sequence of Stenotrophomonas maltophilia Siphophage Silvanus

Stenotrophomonas maltophilia is an opportunistic Gram-negative bacterium capable of causing respiratory infections. S. maltophilia siphophage Silvanus was isolated, and its 45,678-bp genome is not closely related to known phages based on whole-genome comparative genomics analysis. It is predicted to use cos-type packaging due to the similarity of its large terminase subunit to that of phage HK97.

Genomic Characterisation of UFJF_PfDIW6: A Novel Lytic Pseudomonas fluorescens-Phage with Potential for Biocontrol in the Dairy Industry

In this study, we have presented the genomic characterisation of UFJF_PfDIW6, a novel lytic Pseudomonas fluorescens-phage with potential for biocontrol in the dairy industry. This phage showed a short linear double-stranded DNA genome (~42 kb) with a GC content of 58.3% and more than 50% of the genes encoding proteins with unknown functions. Nevertheless, UFJF_PfDIW6’s genome was organised into five functional modules: DNA packaging, structural proteins, DNA metabolism, lysogenic, and host lysis. Comparative genome analysis revealed that the UFJF_PfDIW6’s genome is distinct from other viral genomes available at NCBI databases, displaying maximum coverages of 5% among all alignments. Curiously, this phage showed higher sequence coverages (38–49%) when aligned with uncharacterised prophages integrated into Pseudomonas genomes. Phages compared in this study share conserved locally collinear blocks comprising genes of the modules’ DNA packing and structural proteins but were primarily differentiated by the composition of the DNA metabolism and lysogeny modules. Strategies for taxonomy assignment showed that UFJF_PfDIW6 was clustered into an unclassified genus in the Podoviridae clade. Therefore, our findings indicate that this phage could represent a novel genus belonging to the Podoviridae family.

Complete Genome Sequence of Stenotrophomonas maltophilia Myophage Marzo

Stenotrophomonas maltophilia is a Gram-negative opportunistic bacterium that is increasingly being associated with infections. Here, we report the complete genome of the S. maltophilia myophage Marzo, with a 159,384-bp genome encoding 268 proteins, 23 tRNAs, and 1 transfer-messenger RNA. Marzo is closely related to S. maltophilia phages IME-SM1 and Mendera.

Complete Genome Sequence of Stenotrophomonas maltophilia Siphophage Suso

Phage Suso is a temperate siphophage of Stenotrophomonas maltophilia with a 44,659-bp genome. This phage is closely related to Stenotrophomonas phage SM171, sharing 92% overall nucleotide identity as determined by BLASTn, and it shares 14 similar proteins (BLASTp, E value < 0.001) with some Pseudomonas phages from the genus Beetrevirus.

Complete Genome Sequence of Stenotrophomonas maltophilia Podophage Ptah

Stenotrophomonas maltophilia is an opportunistic pathogen demonstrating increasing drug resistance. Here, the genome of the T7-like S. maltophilia podophage Ptah is described. Its 42,593-bp genome is closely related to previously reported T7-like S. maltophilia podophages, including phage Ponderosa.

Complete Genome Sequence of Stenotrophomonas maltophilia Siphophage Suzuki

Stenotrophomonas maltophilia is a Gram-negative bacterium known to cause respiratory tract infections and other diseases in humans. Here, we describe the isolation and genome annotation of S. maltophilia siphophage Suzuki. Its 56,042-bp genome has 83 predicted protein-coding genes and demonstrates similarity with Xylella phages Sano and Salvo.

Complete Genome Sequence of Stenotrophomonas maltophilia Siphophage Summit

Stenotrophomonas maltophilia is an opportunistic pathogen exhibiting resistance to multiple antimicrobials. This study reports the complete genome of an S. maltophilia siphophage, Summit. Its genome of 95,728 bp has 148 protein-coding genes and 5 tRNAs, including 1 predicted suppressor tRNA. Possible target genes for the suppressor tRNA are not identified.

Complete Genome Sequence of Pseudomonas Phage Zikora

Pseudomonas aeruginosa is a major pathogen in humans and other animals, frequently harboring mechanisms of resistance to commonly used antimicrobials. Here, we describe the isolation of Pseudomonas bacteriophage Zikora. The full 65,837-bp genome was annotated and demonstrates similarity to Pbunavirus phages, making Zikora a new member of this genus of the Myoviridae family.

Comparative Genomics of Three Novel Jumbo Bacteriophages Infecting Staphylococcus aureus

The majority of previously described Staphylococcus aureus bacteriophages belong to three major groups: P68-like podophages, Twort-like or K-like myophages, and a more diverse group of temperate siphophages. Here we present three novel S. aureus "jumbo" phages: MarsHill, Madawaska, and Machias. These phages were isolated from swine production environments in the United States and represent a novel clade of S. aureus myophage. The average genome size for these phages is ∼269 kb with each genome encoding ∼263 predicted protein-coding genes. Phage genome organization and content is similar to known jumbo phages of Bacillus, including AR9 and vB_BpuM-BpSp. All three phages possess genes encoding complete virion and non-virion RNA polymerases, multiple homing endonucleases, and a retron-like reverse transcriptase. Like AR9, all of these phages are presumed to have uracil-substituted DNA which interferes with DNA sequencing. These phages are also able to transduce host plasmids, which is significant as these phages were found circulating in swine production environments and can also infect human S. aureus isolates. Importance of work: This study describes the comparative genomics of three novel S. aureus jumbo phages: MarsHill, Madawaska, and Machias. These three S. aureus myophages represent an emerging class of S. aureus phage. These genomes contain abundant introns which show a pattern consistent with repeated acquisition rather than vertical inheritance, suggesting intron acquisition and loss is an active process in the evolution of these phages. These phages have presumably hypermodified DNA which inhibits sequencing by several different common platforms. Therefore, these phages also represent potential genomic diversity that has been missed due to the limitations of standard sequencing techniques. In particular, such hypermodified genomes may be missed by metagenomic studies due to their resistance to standard sequencing techniques. Phage MarsHill was found to be able to transduce host DNA at levels comparable to that found for other transducing S. aureus phages, making them a potential vector for horizontal gene transfer in the environment.

Complete Genome Sequence of Klebsiella pneumoniae Podophage Pone

Klebsiella pneumoniae is a Gram-negative pathogen that has become increasingly antibiotic resistant. Phage therapy is potentially a useful approach to controlling this pathogen. Here, we present the genome sequence of the phiKMV-like K. pneumoniae podophage Pone.

Complete Genome Sequence of Burkholderia gladioli Myophage Mana

Burkholderia gladioli is known to cause respiratory tract infections in cystic fibrosis patients. Here, we describe the annotation of the 38,038-bp genome sequence of Mana, a P2-like phage of B. gladioli Understanding the genomic characteristics of phages infecting pathogens like B. gladioli can lead to advancements in phage therapy.

Complete Genome Sequence of Stenotrophomonas maltophilia Siphophage Salva

Stenotrophomonas maltophilia is a Gram-negative pathogen causing severe and often refractory illnesses such as pneumonia and bacteremia. We present the genome of phage Salva, a novel S. maltophilia phage that is not closely related to any phages currently deposited in GenBank. The genome is 60,789 bp, containing 102 putative protein-coding genes.

Stenotrophomonas maltophilia is a Gram-negative pathogen causing severe and often refractory illnesses such as pneumonia and bacteremia. We present the genome of phage Salva, a novel S. maltophilia phage that is not closely related to any phages currently deposited in GenBank. The genome is 60,789 bp, containing 102 putative protein-coding genes.

Characterization and complete genome sequence of Privateer, a highly prolate Proteus mirabilis podophage

The Gram-negative bacterium Proteus mirabilis causes a large proportion of catheter-associated urinary tract infections, which are among the world's most common nosocomial infections. Here, we characterize P. mirabilis bacteriophage Privateer, a prolate podophage of the C3 morphotype isolated from Texas wastewater treatment plant activated sludge. Basic characterization assays demonstrated Privateer has a latent period of ~40 min and average burst size around 140. In the 90.7 kb Privateer genome, 43 functions were assigned for the 144 predicted protein-coding genes. Genes encoding DNA replication proteins, DNA modification proteins, four tRNAs, lysis proteins, and structural proteins were identified. Cesium-gradient purified Privateer particles analyzed via LC-MS/MS verified the presence of several predicted structural proteins, including a longer, minor capsid protein apparently produced by translational frameshift. Comparative analysis demonstrated Privateer shares 83% nucleotide similarity with Cronobacter phage vB_CsaP_009, but low nucleotide similarity with other known phages. Predicted structural proteins in Privateer appear to have evolutionary relationships with other prolate podophages, in particular the Kuraviruses.

Complete Genome Sequence of Burkholderia cenocepacia Phage Mica

Burkholderia cenocepacia is a multidrug-resistant Gram-negative pathogen known to colonize patients with chronic granulomatous disease and cystic fibrosis. Here, we describe Burkholderia phage Mica, which is predicted to be a lysogenic myophage based on the similarity of its structural proteins to Enterobacteria phage P2 and Burkholderia phage KL3.

Complete Genome Sequence of Burkholderia cenocepacia Phage Magia

Burkholderia cenocepacia is a Gram-negative bacterium that is implicated in respiratory infections. The 44,942-bp genome of Magia, a phage infecting B. cenocepacia, does not appear to have strong overall similarity to other known phages. The Magia genome encodes a Cro-like transcriptional regulator, a C2-like immunity repressor, and an integrase, suggesting that it is a temperate phage.

Complete Genome Sequence of Klebsiella aerogenes Myophage Metamorpho

The bacterium Klebsiella aerogenes is an opportunistic pathogen that often infects hospitalized patients and those who are immunocompromised. K. aerogenes in some cases can become resistant to antibiotic treatment. Being a potential therapeutic, Metamorpho is a T4-like myophage targeting K. aerogenes.

The bacterium Klebsiella aerogenes is an opportunistic pathogen that often infects hospitalized patients and those who are immunocompromised. K. aerogenes in some cases can become resistant to antibiotic treatment. Being a potential therapeutic, Metamorpho is a T4-like myophage targeting K. aerogenes.

Complete Genome Sequence of Burkholderia gladioli Phage Maja

Burkholderia gladioli is a Gram-negative bacterium associated with cystic fibrosis infections. Here, we describe the genome sequence of B. gladioli phage Maja. Maja is most related to another Burkholderia phage, BcepF1, and may be a temperate phage, despite the absence of repressor or integrase homologs in its genome sequence.

Burkholderia gladioli is a Gram-negative bacterium associated with cystic fibrosis infections. Here, we describe the genome sequence of B. gladioli phage Maja. Maja is most related to another Burkholderia phage, BcepF1, and may be a temperate phage, despite the absence of repressor or integrase homologs in its genome sequence.

Complete Genome Sequence of Bradyrhizobium japonicum Podophage Paso

Bradyrhizobium japonicum is a nitrogen-fixing, Gram-negative bacterium that forms a symbiotic relationship with leguminous plants. This announcement describes the isolation and genome annotation of B. japonicum T7-like podophage Paso. Genomic analysis reveals genes that are associated with both the T5 and T7 modes of genomic DNA (gDNA) entry into the host.

Bradyrhizobium japonicum is a nitrogen-fixing, Gram-negative bacterium that forms a symbiotic relationship with leguminous plants. This announcement describes the isolation and genome annotation of B. japonicum T7-like podophage Paso. Genomic analysis reveals genes that are associated with both the T5 and T7 modes of genomic DNA entry into the host.

Complete Genome Sequence of Klebsiella pneumoniae Jumbo Phage Miami

Bacteriophage Miami infects Klebsiella pneumoniae, a Gram-negative pathogen that is becoming an increasing threat to public health due to its multidrug resistance. Here, we describe the annotation of the 253,383-bp jumbo phage Miami genome sequence and its similarity to other myophages.

Bacteriophage Miami infects Klebsiella pneumoniae, a Gram-negative pathogen that is becoming an increasing threat to public health due to its multidrug resistance. Here, we describe the annotation of the 253,383-bp jumbo phage Miami genome sequence and its similarity to other myophages.

Complete Genome Sequence of Rhizobium phaseoli Podophage Palo

Here, we present the genome of Palo, a T7-like podophage of Rhizobium phaseoli The genome is 46.3 kb and contains 58 predicted protein-coding genes, including a novel signal-anchor-release (SAR) endolysin, a homolog of the T5 A1 protein required for DNA transfer, and a dual-start holin/antiholin pair.

Complete Genome Sequence of Klebsiella aerogenes Siphophage Solomon

Klebsiella aerogenes is a bacterium that can cause a variety of infections. Phage-based biotechnologies may be useful for controlling antibiotic-resistant strains of this bacterium. The characterization of K. aerogenes phage Solomon is described here. Solomon has a 51,775-bp genome, with structural components closely resembling those of Escherichia coli siphophage T1.

Klebsiella aerogenes is a bacterium that can cause a variety of infections. Phage-based biotechnologies may be useful for controlling antibiotic-resistant strains of this bacterium. The characterization of K. aerogenes phage Solomon is described here. Solomon has a 51,775-bp genome, with structural components closely resembling those of Escherichia coli siphophage T1.

Complete Genome Sequence of Rhizobium japonicum Podophage Pasto

Rhizobium japonicum is a Gram-negative bacterium of interest for research into nitrogen fixation in legumes. This article describes the isolation, sequencing, and annotation of R. japonicum podophage Pasto. While it shows no significant similarity to identified phages, genomic analysis indicates that Pasto may be temperate and is a novel T7-like podophage.

Rhizobium japonicum is a Gram-negative bacterium of interest for research into nitrogen fixation in legumes. This article describes the isolation, sequencing, and annotation of R. japonicum podophage Pasto. While it shows no significant similarity to identified phages, genomic analysis indicates that Pasto may be temperate and is a novel T7-like podophage.

Complete Genome Sequence of Klebsiella pneumoniae Myophage Muenster

Klebsiella pneumoniae is associated with antibiotic-resistant nosocomial infections. Here, we present the annotated genome sequence of the Klebsiella jumbo phage Muenster. The Muenster genome sequence (346,937 bp) encodes 6 tRNAs and 561 putative protein-coding genes, including 9 tail fibers, suggesting a genetic mechanism to broaden the host range.

Persistence of a Stx-Encoding Bacteriophage in Minced Meat Investigated by Application of an Improved DNA Extraction Method and Digital Droplet PCR

Shiga toxin-producing Escherichia coli (STEC) are important food-borne pathogens with Shiga toxins as the main virulence factor. Shiga toxins are encoded on Shiga toxin-encoding bacteriophages (Stx phages). Stx phages may exist as free bacteriophages in the environment or in foods or as prophages integrated into the host genome. From a food safety perspective, it is important to have knowledge on the survival and persistence of Stx phages in food products since these may integrate into the bacterial hosts through transduction if conditions are right. Here, we present the results from a study investigating the survival of a Stx phage in minced meat from beef stored at a suboptimal temperature (8°C) for food storage along with modifications and optimizations of the methods applied. Minced meat from beef was inoculated with known levels of a labeled Stx phage prior to storage. Phage filtrates were used for plaque assays and DNA extraction, followed by real-time PCR and digital droplet PCR (ddPCR). The results from the pilot study suggested that the initial DNA extraction protocol was not optimal, and several modifications were tested before a final protocol was defined. The final DNA extraction protocol comprised ultra-centrifugation of the entire phage filtrate for concentrating phages and two times phenol–chloroform extraction. The protocol was used for two spiking experiments. The DNA extraction protocol resulted in flexibility in the amount of DNA available for use in PCR analyses, ultimately increasing the sensitivity of the method used for quantification of phages in a sample. All three quantification methods employed (i.e., plaque assays, real-time PCR, and ddPCR) showed similar trends in the development of the phages during storage, where ddPCR has the benefit of giving absolute quantification of DNA copies in a simple experimental setup. The results indicate that the Stx phages persist and remain infective for at least 20 days under the storage conditions used in the present study. Stx phages in foods might represent a potential risk for humans. Although it can be speculated that transduction may take place at 8°C with subsequent forming of STEC, it can be expected to be a rare event. However, such an event may possibly take place under more optimal conditions, such as an increase in storage temperature of foods or in the gastrointestinal tract of humans.

Complete Genome Sequence of Achromobacter xylosoxidans Myophage Mano

Achromobacter spp. are ubiquitous Gram-negative bacteria, some of which can cause respiratory tract infections in patients with autoimmune disorders and cystic fibrosis. Bacteriophages have therapeutic and biotechnological potential to combat Achromobacter sp. infections. This announcement details the 42.5-kb genome sequence of the temperate Achromobacter xylosoxidans myophage Mano.

Complete Genome Sequence of Streptomyces Siphophage Sycamore

Streptomyces sp. strain Mg1 is a competitive soil-dwelling bacterium that secretes antibiotics that inhibit growth of Bacillus subtilis. Here, we present the genome sequence of Sycamore, a 44,694-bp Streptomyces sp. Mg1 siphophage with 66 predicted protein-coding genes, that is similar to phage genome sequences in the Lomovskayavirus genus.

Streptomyces sp. strain Mg1 is a competitive soil-dwelling bacterium that secretes antibiotics that inhibit growth of Bacillus subtilis. Here, we present the genome sequence of Sycamore, a 44,694-bp Streptomyces sp. Mg1 siphophage with 66 predicted protein-coding genes, that is similar to phage genome sequences in the Lomovskayavirus genus.

Complete Genome Sequence of Streptomyces Phage Spernnie

Streptomyces spp. are Gram-positive soil bacteria that have been reported in some cases to cause acute and chronic infections, including mycetomas, pneumonia, and septicemia. Here, we present Streptomyces sp. strain Mg1 phage Spernnie. Spernnie is a temperate siphophage containing 89 predicted coding genes in a 50,834-bp genome sequence.

Streptomyces spp. are Gram-positive soil bacteria that have been reported in some cases to cause acute and chronic infections, including mycetomas, pneumonia, and septicemia. Here, we present Streptomyces sp. strain Mg1 phage Spernnie. Spernnie is a temperate siphophage containing 89 predicted coding genes in a 50,834-bp genome sequence.

Complete Genome Sequence of Streptomyces Phage Shaeky

Here, we present the genome of siphophage Shaeky, infecting the Gram-positive bacterium Streptomyces sp. strain Mg1. Shaeky has very low sequence identity to other phages, with phage phiC31 being the most closely related in the NCBI database. The Shaeky genome is 45,617 bp with 77 protein-coding genes and 16 tRNAs.

Here, we present the genome of siphophage Shaeky, infecting the Gram-positive bacterium Streptomyces sp. strain Mg1. Shaeky has very low sequence identity to other phages, with phage phiC31 being the most closely related in the NCBI database. The Shaeky genome is 45,617 bp with 77 protein-coding genes and 16 tRNAs.

Complete Genome Sequence of Streptomyces Phage Sentinel

The Streptomyces genus produces over two-thirds of clinically useful, natural antibiotics. Here, we describe the isolation and genome annotation of siphophage Sentinel, which utilizes Streptomyces sp. strain Mg1 as a host. It has a 50,272-bp genome and 83 protein-coding genes and shows similarity to other Streptomyces phages in the Arequatrovirus genus.

The Streptomyces genus produces over two-thirds of clinically useful, natural antibiotics. Here, we describe the isolation and genome annotation of siphophage Sentinel, which utilizes Streptomyces sp. strain Mg1 as a host. It has a 50,272-bp genome and 83 protein-coding genes and shows similarity to other Streptomyces phages in the Arequatrovirus genus.