Development of bacteriophage T4 depends on the physiological state of its host cell. Based on previous studies performed under laboratory conditions with different media determining various growth rates of Escherichia coli, a mathematical model was developed which suggested that phage T4 development cannot proceed efficiently in bacteria growing with a doubling time longer than 160 min. Contrary to this prediction, using a chemostat culture system allowing for culturing E. coli at different growth rates without changes in the medium composition, we found that T4 can yield progeny in host cells growing with a doubling time as long as 21 h. Our results indicate that the actual limiting growth rate of the host culture for the development of phage T4 is about 0.033 h(-1) , corresponding to the doubling time of about 21 h.
The use of low concentrations (optimally 2.5 to 3.5 g/ml, depending on top agar thickness) of ampicillin in the bottom agar of the plate allows for formation of highly visible plaques of bacteriophages which otherwise form extremely small plaques or no plaques on Escherichia coli lawns. Using this method, we were able to obtain plaques of newly isolated bacteriophages, propagated after induction of prophages present in six E. coli O157:H ؊ strains which did not form plaques when standard plating procedures were employed.In the second half of 20th century, bacteriophages were among the most important models in molecular biology. However, at the end of that century, after learning principles of molecular biology using bacteriophage models, these viruses became considered less attractive research subjects due to development of sophisticated systems for studying eukaryotic cells. Nevertheless, recent years may be recognized as a new era in bacteriophage biology. This is because of several unexpected findings, which demonstrated that viruses infecting bacterial cells may be very important not only in basic biological studies but also in medicine and biotechnology (for reviews, see references 7 and 38). The breakthroughs included discoveries that many toxins (including the vast majority of verotoxins) produced by bacteria pathogenic to animals and humans are encoded in bacteriophage genomes (20, 37); that bacteriophages can be used in vaccination and in specific kinds of therapy (10); that bacteriophages can be extremely dangerous for bioprocesses based on bacterial activities in biotechnological factories (25, 35) but also may be employed in genetic engineering and biotechnology in a very sophisticated manner (10, 28); and finally that they are the most abundant creatures worldwide, thus playing an extremely important ecological role (9,12,19,39).The growing interest in various aspects of phage biology must be connected to isolation and characterization of newly discovered viruses. However, contrary to well-investigated model bacteriophages, in most cases of newly isolated phages there are problems with their propagation under laboratory conditions. This is partially due to the fact that the number of indicator strains used in laboratories is rather limited and various limitations arise from using nonpermissive or suboptimal hosts. The first step in getting an uncontaminated lysate of a particular bacteriophage strain is obtaining single plaques on the host lawn. However, this first and obligatory stage of analysis may be, in fact, a limiting step as there are many examples (though mostly unpublished) of serious problems with getting plaques of newly discovered bacteriophages. This problem seems to be common in the case of lambdoid bacteriophages (27, 42). We met this problem when investigating phages coding for Shiga toxins, whose genomes are present as prophages in chromosomes of some Escherichia coli strains. For example, phage 24B (⌬stx::cat) (4) and phage ST2-8624 (⌬stx::cat gfp) from E. coli O157:H7 strain 8624...
Increasing multidrug resistance has led to renewed interest in phage-based therapy. A combination of the bacteriophages and antibiotics presents a promising approach enhancing the phage therapy effectiveness. First, phage candidates for therapy should be deeply characterized. Here we characterize the bacteriophage vB_AbaP_AGC01 that poses antibacterial activity against clinical Acinetobacter baumannii strains. Moreover, besides genomic and phenotypic analysis our study aims to analyze phage–antibiotic combination effectiveness with the use of ex vivo and in vivo models. The phage AGC01 efficiently adsorbs to A. baumannii cells and possesses a bacteriolytic lifecycle resulting in high production of progeny phages (317 ± 20 PFU × cell−1). The broad host range (50.27%, 93 out of 185 strains) against A. baumannii isolates and the inability of AGC01 to infect other bacterial species show its high specificity. Genomic analysis revealed a high similarity of the AGC01 genome sequence with that of the Friunavirus genus from a subfamily of Autographivirinae. The AGC01 is able to significantly reduce the A. baumannii cell count in a human heat-inactivated plasma blood model (HIP-B), both alone and in combination with antibiotics (gentamicin (GEN), ciprofloxacin (CIP), and meropenem (MER)). The synergistic action was observed when a combination of phage treatment with CIP or MER was used. The antimicrobial activity of AGC01 and phage-antibiotic combinations was confirmed using an in vivo larva model. This study shows the greatest increase in survival of G. mellonella larvae when the combination of phage (MOI = 1) and MER was used, which increased larval survival from 35% to 77%. Hence, AGC01 represents a novel candidate for phage therapy. Additionally, our study suggests that phages and antibiotics can act synergistically for greater antimicrobial effect when used as combination therapy.
A universal and effective method for long-term storage of bacteriophages has not yet been described. We show that randomly selected tailed phages could be stored inside the infected cells at -80°C without a major loss of phage and host viability. Our results suggest the suitability of this method as a standard for phage preservation.
The use of bacteriophages, instead of antibodies, in the ELISA-based detection of bacterial strains was tested. This procedure appeared to be efficient, and specific strains of Salmonella enterica and Escherichia coli could be detected. The sensitivity of the assay was about 105 bacterial cells/well (106/ml), which is comparable with or outperforms other ELISA tests detecting intact bacterial cells without an enrichment step. The specificity of the assay depends on the kind of bacteriophage used. We conclude that the use of bacteriophages in the detection and identification of bacteria by an ELISA-based method can be an alternative to the use of specific antibodies. The advantages of the use of bacteriophages are their environmental abundance (and, thus, a possibility to isolate various phages with different specificities) and the availability of methods for obtaining large amounts of phage lysates, which are simple, rapid, cheap, and easy.
Objectives: Shiga toxin-producing Escherichia coli (STEC) are pathogenic strains, whose virulence depends on induction of Shiga toxin-converting prophages and their subsequent lytic development. We explored which factors or conditions could inhibit development of these phages, potentially decreasing virulence of STEC. Materials and Methods: Lytic development of Shiga toxin-converting bacteriophages was monitored after mitomycin C-provoked prophage induction under various conditions. Phage DNA replication efficiency was assessed by measurement of DNA amount in cells using quantitative polymerase chain reaction. Results: We demonstrated that the use of citrate delayed Shiga toxin-converting phage development after prophage induction. This effect was independent on efficiency of prophage induction and phage DNA replication. However, an excess of glucose reversed the effect of citrate. Amino acid starvation prevented the phage development in bacteria both able and unable to induce the stringent response. Conclusions: Lytic development of Shiga toxin-converting bacteriophages can be inhibited by either the presence of citrate or amino acid starvation. We suggest that the inhibition caused by the latter condition may be due to a block in prophage induction or phage DNA replication or both. Applications: Our findings may facilitate development of procedures for treatment of STEC-infected patients.
Zinc oxide (ZnO) is a semiconductor compound with a potential for wide use in various applications, including biomaterials and biosensors, particularly as nanoparticles (the size range of ZnO nanoparticles is from 2 to 100 nm, with an average of about 35 nm). Here, we report isolation of novel ZnO-binding peptides, by screening of a phage display library. Interestingly, amino acid sequences of the ZnO-binding peptides reported in this paper and those described previously are significantly different. This suggests that there is a high variability in sequences of peptides which can bind particular inorganic molecules, indicating that different approaches may lead to discovery of different peptides of generally the same activity (e.g., binding of ZnO) but having various detailed properties, perhaps crucial under specific conditions of different applications.
Arthrobacter spp. are coryneform Gram-positive aerobic bacteria, belonging to the class Actinobacteria. Representatives of this genus have mainly been isolated from soil, mud, sludge or sewage, and are usually mesophiles. In recent years, the presence of Arthrobacter spp. was also confirmed in various extreme, including permanently cold, environments. In this study, 36 psychrotolerant and metalotolerant Arthrobacter strains isolated from petroleum-contaminated soil from the King George Island (Antarctica), were screened for the presence of plasmids. The identified replicons were thoroughly characterized in order to assess their diversity and role in the adaptation of Arthrobacter spp. to harsh Antarctic conditions. The screening process identified 11 different plasmids, ranging in size from 8.4 to 90.6 kb. A thorough genomic analysis of these replicons detected the presence of numerous genes encoding proteins that potentially perform roles in adaptive processes such as (i) protection against ultraviolet (UV) radiation, (ii) resistance to heavy metals, (iii) transport and metabolism of organic compounds, (iv) sulfur metabolism, and (v) protection against exogenous DNA. Moreover, 10 of the plasmids carry genetic modules enabling conjugal transfer, which may facilitate their spread among bacteria in Antarctic soil. In addition, transposable elements were identified within the analyzed plasmids. Some of these elements carry passenger genes, which suggests that these replicons may be actively changing, and novel genetic modules of adaptive value could be acquired by transposition events. A comparative genomic analysis of plasmids identified in this study and other available Arthrobacter plasmids was performed. This showed only limited similarities between plasmids of Antarctic Arthrobacter strains and replicons of other, mostly mesophilic, isolates. This indicates that the plasmids identified in this study are novel and unique replicons. In addition, a thorough meta-analysis of 247 plasmids of psychrotolerant bacteria was performed, revealing the important role of these replicons in the adaptation of their hosts to extreme environments.
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