The toxin-producing bacterium Vibrio cholerae can cause severe diarrhea and has caused seven global pandemics. Traditional viable cell counts and phage plaques are commonly used to evaluate the efficacy of virulent phage clearance of V. cholerae, but these operations are time-consuming and labor-intensive, and difficult to provide real-time changes. It is desirable to develop a simple and real-time method to monitor V. cholerae during phage lysis. In this study, a luminescence-generating plasmid pBBR-pmdh-luxCDABE was transformed into three O1 serogroup drug-resistant strains of V. cholerae. The results showed that the luminescence value as a monitoring index correlates well with the traditional viable cell count method. Monitoring the number of live cells of V. cholerae by measuring the luminescence allowed real-time analysis of the number of bacteria remaining during phage lysis. This method enables repeated, interference-free, continuous multiple-time-point detection of the same sample without the time delay of re-culture or plaque formation, facilitating real-time monitoring and analysis of the interaction between the phage and the host bacteria.
Bacteriophages/genetics* ; Luminescence ; Plasmids ; Vibrio cholerae

Bacteriophages bind to the bacteria receptor through the receptor binding proteins (RBPs), a process that requires the involvement of complex atomic structures and conformational changes. In response to bacteriophage infection, bacteria have developed a variety of resistance mechanisms, while bacteriophages have also evolved multiple antagonistic mechanisms to escape host resistance. The exploration of the "adsorption-anti adsorption-escape process" between bacteriophages and bacteria helps us better understand the co-evolution process of bacteriophages and bacteria, which is important for the development of phage therapeutic technologies and phage-based biotechnologies. This review summarizes the bacteriophage adsorption related proteins, how bacteriophages escape host resistance based on the RBP alternations, and the recent progress of RBP-related biotechnologies.
Bacteria ; Bacteriophage Receptors ; Bacteriophages/genetics* ; Carrier Proteins ; Protein Binding

Bacterial multi-drug resistance (MDR) is a global challenge in the fields of medicine and health, agriculture and fishery, ecology and environment. The cross-region spread of antibiotic resistance genes (ARGs) among different species is one of the main cause of bacterial MDR. However, there is no effective strategies for addressing the intensifying bacterial MDR. The CRISPR-Cas system, consisting of clustered regularly interspaced short palindromic repeats (CRISPR) and CRISPR associated proteins, can targetedly degrade exogenous nucleic acids, thus exhibiting high application potential in preventing and controlling bacterial MDR caused by ARGs. This review briefly introduced the working mechanism of CRISPR-Cas systems, followed by discussing recent advances in reducing ARGs by CRISPR-Cas systems delivered through mediators (e.g. plasmids, bacteriophages and nanoparticle). Moreover, the trends of this research field were envisioned, providing a new perspective on preventing and controlling MDR.
Anti-Bacterial Agents ; Bacteriophages/genetics* ; CRISPR-Cas Systems ; Drug Resistance, Bacterial/genetics* ; Plasmids/genetics*

Phages also known as bacteria viruses, are recognized as the most abundant and diverse microbes. This diversity is adapting to the selective pressures such as the prevalence of the phage resistance mechanisms of bacteria. Phages invade and lyse bacterial through six steps (adsorption, injection, replication, transcription translation, assemble, release). Bacteria evolve to many anti-phage mechanisms to avoid phage infection and lysis. This paper focus on a variety of anti-phage mechanisms of bacteria.
Bacteria ; genetics ; virology ; Bacterial Physiological Phenomena ; Bacteriophages ; genetics ; physiology ; DNA Replication ; Evolution, Molecular ; Virus Attachment

Objective: To isolate and purify a bacteriophage against methicillin-resistant Staphylococcus aureus (MRSA), and to analyze its genomic information and biological characteristics. Methods: The experimental research methods were adopted. MRSA (hereinafter referred to as host bacteria) solution was collected from the wound of a 63-year-old female patient with the median sternum incision infection admitted to the Second Affiliated Hospital of Army Medical University (the Third Military Medical University). The bacteriophage, named bacteriophage SAP23 was isolated and purified from the sewage of the Hospital by sewage co-culture method and double-layer agar plate method, and the plaque morphology was observed. The morphology of bacteriophage SAP23 was observed by transmission electron microscope after phosphotungstic acid negative staining. The whole genome of bacteriophage SAP23 was sequenced with NovaSeq PE15 platform after its DNA was prepared by sodium dodecyl sulfonate/protease cleavage scheme, and genomic analysis including sequence assembly, annotation, and phylogenetic tree were completed. The bacteriophage SAP23 solution was co-incubated with the host bacterial solution for 4 h at the multiplicity of infection (MOI) of 10.000 0, 1.000 0, 0.100 0, 0.010 0, 0.001 0, and 0.000 1, respectively, and then the bacteriophage titer was measured by the drip plate method to select the optimal MOI, with here and the following sample numbers of 3. The bacteriophage SAP23 solution was co-incubated with the host bacterial solution at the optimal MOI for 5, 10, and 15 min, respectively, and the bacteriophage titer was measured by the same method as mentioned above to select the optimal adsorption time. After the bacteriophage SAP23 solution was co-incubated with the host bacterial solution at the optimal MOI for the optimal adsorption time, the bacteriophage titers were measured by the same method as mentioned above at 0 (immediately), 5, 10, 15, 20, 30, 40, 50, 60, 80, 100, and 120 min after culture, respectively, and a one-step growth curve was drawn. The bacteriophage SAP23 solution was incubated at 4, 37, 50, 60, 70, and 80 ℃ and pH 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, and 12 for 1 h, respectively, to determine its stability. A total of 41 MRSA strains stored in the Department of Microbiology of Army Medical University (the Third Military Medical University) were used to determine the host spectrum of bacteriophage SAP23. Results: The bacteriophage SAP23 could form a transparent plaque on the host bacteria double-layer agar plate. The bacteriophage SAP23 has a polyhedral head with (88±4) nm in diameter and a tail with (279±21) nm in length and (22.6±2.6) nm in width. The bacteriophage SAP23 has a linear, double-stranded DNA with a full length of 151 618 bp and 11 681 bp long terminal repeats sequence in the sequence ends. There were 220 open reading frames predicted and the bacteriophage could encode 4 transfer RNAs, while no resistance genes or virulence factors were found. The annotation function of bacteriophage SAP23 genes could be divided into 5 groups. The GenBank accession number was MZ427930. According to the genomic collinearity analysis, there were 5 local collinear blocks in the whole genome between the bacteriophage SAP23 and the chosen 6 Staphylococcus bacteriophages, while within or outside the local collinear region, there were still some differences. The bacteriophage SAP23 belonged to the Herelleviridae family, Twortvirinae subfamily, and Kayvirus genus. The optimal MOI of bacteriophage SAP23 was 0.010 0, and the optimal adsorption time was 10 min. The bacteriophage SAP23 had a latent period of 20 min, and a growth phase of 80 min. The bacteriophage SAP23 was able to remain stable at the temperature between 4 and 37 ℃ and at the pH values between 4 and 9. The bacteriophage SAP23 could lyse 3 of the 41 tested MRSA strains. Conclusions: The bacteriophage SAP23 is a member of the Herelleviridae family, Twortvirinae subfamily, and Kayvirus genus. The bacteriophage SAP23 has a good tolerance for temperature and acid-base and a short latent period, and can lyse MRSA effectively. The bacteriophage SAP23 is a new type of potent narrow-spectrum bacteriophage without virulence factors and resistance genes.
Bacteriophages/genetics* ; Genomics ; Humans ; Methicillin-Resistant Staphylococcus aureus/genetics* ; Middle Aged ; Phylogeny ; Sternum

Tumor is a serious threat to human health. At present, surgical resection, chemoradiotherapy, targeted therapy and immunotherapy are the main therapeutic strategies. Monoclonal antibody has gradually become an indispensable drug type in the clinical treatment of cancer due to its high efficiency and low toxicity. Phage antibody library technology (PALT) is a novel monoclonal antibody preparation technique. The recombinant immunoglobulin variable region of heavy chain (VH)/variable region of light chain (VL) gene is integrated into the phage vector, and the antibody is expressed on the phage surface in the form of fusion protein to obtain a diverse antibody library. Through the process of adsorption-elution-amplification, the antibody library can be screened to obtain the antibody molecule with specific binding antigen as well as its gene sequence. PALT has the advantages of short antibody production cycle, strong plasticity of antibody structure, large antibody yield, high diversity and direct production of humanized antibodies. It has been used in screening tumor markers and preparation of antibody drugs for breast cancer, gastric cancer, lung cancer and liver cancer. This article reviews the recent progress and the application of PALT in tumor therapy.
Humans ; Bacteriophages/genetics* ; Immunoglobulin Variable Region/genetics* ; Gene Library ; Antibodies, Monoclonal/therapeutic use* ; Immunotherapy ; Peptide Library

To determine the lysis spectrum of Yersinia enterocolitica bacteriophage phiYe-F10 and to analyze the relationship between the lysis ability of phiYe-F10 and the virulence gene of Yersinia enterocolitica. To observe the lysis ability of the phage phiYe-F10 to the different Yersinia strains with the double-layer technique. The strains used in this study including 213 of Yersinia enterocolitica and 36 of Yersinia pseudotuberculosis and 1 of Yersinia pestis. The virulence genes of these Yersinia enterocolitica (attachment invasion locus (ail) and enterotoxin (ystA, ystB) and yersinia adhesin A (yadA), virulence factor (virF), specific gene for lipopolysaccharide O-side chain of serotype O : 3 (rfbc) were all detected. Among the 213 Yersinia enterocolitica, 84 strains were O : 3 serotype (78 strains with rfbc gene), 10 were serotype O : 5, 13 were serotype O : 8, 34 were serotype O : 9 and 72 were other serotypes. Of these, 77 were typical pathogenic Yersinia enterocolitica harboring with virulence plasmid (ail+, ystA+, ystB-, yadA+, virF+), and 15 were pathogenic bacterial strains deficiency virulence plasmid (ail+, ystA+, ystB-, yadA-, virF-) and the rest 121 were non pathogenic genotype strains. PhiYe-F10 lysed the 71 serotype O : 3 Yersinia enterocolitica strains which were all carried with rfbc+, including 52 pathogenic Yersinia enterocolitica, 19 nonpathogenic Y. enterocolitica. The phiYe-F10 can not lysed serotype O : 5, O : 9 and other serotype Y. enterocolitica, the lysis rate of serotype O : 3 was as high as 84.5%. The phiYe-F10 can not lysed Yersinia pseudotuberculosis and Yersinia pestis. Yersinia phage phiYe-F10 is highly specific for serotype O : 3 Yersinia enterocolitic at 25 degrees C, which showed a typical narrow lysis spectrum. Phage phiYe-F10 can lysed much more pathogenic Y. enterocolitica than nonpathogenic Y. enterocolitica.
Bacterial Proteins ; genetics ; metabolism ; Bacteriophages ; genetics ; isolation & purification ; physiology ; Host Specificity ; Virulence Factors ; genetics ; metabolism ; Yersinia enterocolitica ; genetics ; metabolism ; virology

Bacteria are often infected by large numbers of phages, and host bacteria have evolved diverse molecular strategies in the race with phages, with abortive infection (Abi) being one of them. The toxin-antitoxin system (TA) is expressed in response to bacterial stress, mediating hypometabolism and even dormancy, as well as directly reducing the formation of offspring phages. In addition, some of the toxins' sequences and structures are highly homologous to Cas, and phages even encode antitoxin analogs to block the activity of the corresponding toxins. This suggests that the failure of phage infection due to bacterial death in abortive infections is highly compatible with TA function, whereas TA may be one of the main resistance and defense forces for phage infestation of the host. This review summarized the TA systems involved in phage abortive infections based on classification and function. Moreover, TA systems with abortive functions and future use in antibiotic development and disease treatment were predicted. This will facilitate the understanding of bacterial-phage interactions as well as phage therapy and related synthetic biology research.
Anti-Bacterial Agents ; Antitoxins/chemistry* ; Bacteria/genetics* ; Bacterial Proteins/chemistry* ; Bacterial Toxins/genetics* ; Bacteriophages/genetics* ; Toxin-Antitoxin Systems/genetics*

Bacterial Outer Membrane Proteins ; chemistry ; genetics ; physiology ; Bacteriophages ; chemistry ; Humans ; Receptors, Virus ; chemistry ; Vibrio cholerae ; virology

Bacteriolysis ; physiology ; Bacteriophages ; genetics ; isolation & purification ; physiology ; England ; Gram-Negative Bacteria ; virology ; Humans ; International Cooperation