Isolation and Characterization of Phages Active against Paenibacillus larvae Causing American Foulbrood in Honeybees in Poland.

The aim of this study was the isolation and characterization, including the phage effect on honeybees in laboratory conditions, of phages active against Paenibacillus larvae, the causative agent of American Foulbrood-a highly infective and easily spreading disease occurring in honeybee larva, and subsequently the development of a preparation to prevent and treat this dangerous disease. From the tested material (over 2500 samples) 35 Paenibacillus spp. strains were obtained and used to search for phages. Five phages specific to Paenibacillus were isolated and characterized (ultrastructure, morphology, biological properties, storage stability, and genome sequence). The characteristics were performed to obtain knowledge of their lytic potential and compose the final phage cocktail with high antibacterial potential and intended use of future field application. Preliminary safety studies have also been carried out on healthy bees, which suggest that the phage preparation administered is harmless.

Phages in Therapy and Prophylaxis of American Foulbrood - Recent Implications From Practical Applications.

American foulbrood is one of the most serious and yet unsolved problems of beekeeping around the world, because it causes a disease leading to the weakening of the vitality of honey bee populations and huge economic losses both in agriculture and horticulture. The etiological agent of this dangerous disease is an extremely pathogenic spore-forming bacterium, Paenibacillus larvae, which makes treatment very difficult. What is more, the use of antibiotics in the European Union is forbidden due to restrictions related to the prevention of the presence of antibiotic residues in honey, as well as the global problem of spreading antibiotic resistance in case of bacterial strains. The only available solution is burning of entire bee colonies, which results in large economic losses. Therefore, bacteriophages and their lytic enzymes can be a real effective alternative in the treatment and prevention of this Apis mellifera disease. In this review, we summarize phage characteristics that make them a potentially useful tool in the fight against American foulbrood. In addition, we gathered data regarding phage application that have been described so far, and attempted to show practical implications and possible limitations of their usage.

Recombinant expression and purification of T4 phage Hoc, Soc, gp23, gp24 proteins in native conformations with stability studies.

Understanding the biological activity of bacteriophage particles is essential for rational design of bacteriophages with defined pharmacokinetic parameters and to identify the mechanisms of immunobiological activities demonstrated for some bacteriophages. This work requires highly purified preparations of the individual phage structural proteins, possessing native conformation that is essential for their reactivity, and free of incompatible biologically active substances such as bacterial lipopolysaccharide (LPS). In this study we describe expression in E. coli and purification of four proteins forming the surface of the bacteriophage T4 head: gp23, gp24, gphoc and gpsoc. We optimized protein expression using a set of chaperones for effective production of soluble proteins in their native conformations. The assistance of chaperones was critical for production of soluble gp23 (chaperone gp31 of T4 phage) and of gpsoc (chaperone TF of E. coli). Phage head proteins were purified in native conditions by affinity chromatography and size-exclusion chromatography. Two-step LPS removal allowed immunological purity grade with the average endotoxin activity less than 1 unit per ml of protein preparation. The secondary structure and stability of the proteins were studied using circular dichroism (CD) spectrometry, which confirmed that highly purified proteins preserve their native conformations. In increasing concentration of a denaturant (guanidine hydrochloride), protein stability was proved to increase as follows: gpsoc, gp23, gphoc. The denaturation profile of gp24 protein showed independent domain unfolding with the most stable larger domain. The native purified recombinant phage proteins obtained in this work were shown to be suitable for immunological experiments in vivo and in vitro.

Effects of tamoxifen on estrogen receptor-α level in immune cells and humoral specific response after immunization of C3H/He male mice with syngeneic testicular germ cells (TGC).

Estrogens and estrogen receptors (ERs) are potent regulators of the immune response. Disruption of ERα or modulation of its function by selective ligands during experimental autoimmune conditions changes the course of disease by influencing specific humoral and cellular responses. However, it is not known whether fluctuation in the ERα level and the variable accessibility to its ligands in immune cells influence the development of specific immune responses against auto-antigens. This study was designed to evaluate the expression level of ERα in splenic immune cells and the specific humoral immune response in male C3H/He/W mice immunized with syngeneic testicular germ cells (TGC) in the presence of tamoxifen. Levels of ERα protein in immune cell subpopulations of immunized mice (assessed by flow cytometry) increased in MHCII(+)CD86(+), MHCII(+)CD86(- ), F4/80(+)MHCII(+), immature macrophages (F4/80(+)/MHCII(- )), and CD3(+)CD4(+) T cells. Addition of tamoxifen decreased the level of ERα in MHCII(+)CD86(+), MHCII(+)CD86(- ), F4/80(+)MHCII(+), immature macrophages (F4/80(+)/MHCII(- )), and the CD19(+)CD3(- ) cell subpopulation of immunized mice. Therefore, immunization with syngeneic antigen and tamoxifen treatment evoked cell-type specific changes in the level of ERα. Irrespective of tamoxifen treatment the humoral response in immunized animals toward TGCs was similar, suggesting that modulation of the level of ERα in immune cells is not directly related to specific auto-antibody production.

Antitumor effect of combined treatment of mice with cytostatic agents and bacteriophage T4.

The past few years have shown significant resurgent interest in the old concept of bacteriophage therapy. Some research groups continue to develop whole bacteriophage preparations as alternatives to antibiotic antibacterial treatment. However, improvements in the methods of purification of phage preparations open new opportunities in the successful treatment of antibiotic-resistant bacterial infections. An open question remains on whether bacteriophage preparations (BP) can be safely applied in antibacterial treatment of patients suffering from infections as a consequence of immunosuppression caused by anticancer chemotherapy. The aim of this study was to evaluate the potential modulating effect of bacteriophage T4 preparations administered to mice bearing s.c. or i.v. inoculated B16 melanoma and treated with conventional anticancer drugs, i.e. cyclophosphamide (CY), cisplatin (CPt) or 5-fluorouracil (5-FU). Treatment of mice with (BPT) T4 preparation slightly potentiated the antimetastatic effect of CY. Importantly, no combination of phage-cytostatic treatment resulted in a decrease in the antimetastatic or antitumour effects of an applied drug. This suggests the possibility of safe combination of bacteriophage preparations with popular antitumour drugs.

The effect of bacteriophages T4 and HAP1 on in vitro melanoma migration.

BACKGROUND: The antibacterial activity of bacteriophages has been described rather well. However, knowledge about the direct interactions of bacteriophages with mammalian organisms and their other, i.e. non-antibacterial, activities in mammalian systems is quite scarce. It must be emphasised that bacteriophages are natural parasites of bacteria, which in turn are parasites or symbionts of mammals (including humans). Bacteriophages are constantly present in mammalian bodies and the environment in great amounts. On the other hand, the perspective of the possible use of bacteriophage preparations for antibacterial therapies in cancer patients generates a substantial need to investigate the effects of phages on cancer processes. RESULTS: In these studies the migration of human and mouse melanoma on fibronectin was inhibited by purified T4 and HAP1 bacteriophage preparations. The migration of human melanoma was also inhibited by the HAP1 phage preparation on matrigel. No response of either melanoma cell line to lipopolysaccharide was observed. Therefore the effect of the phage preparations cannot be attributed to lipopolysaccharide. No differences in the effects of T4 and HAP1 on melanoma migration were observed. CONCLUSION: We believe that these observations are of importance for any further attempts to use bacteriophage preparations in antibacterial treatment. The risk of antibiotic-resistant hospital infections strongly affects cancer patients and these results suggest the possibility of beneficial phage treatment. We also believe that they will contribute to the general understanding of bacteriophage biology, as bacteriophages, extremely ubiquitous entities, are in permanent contact with human organisms.

Bacteriophage preparation inhibition of reactive oxygen species generation by endotoxin-stimulated polymorphonuclear leukocytes.

It has been known that administration of antibiotics may lead to excessive release of bacterial endotoxins and complicate clinical course of patients with Gram-negative infections. This concern may also apply to phages. Endotoxin may in turn activate neutrophils to produce reactive oxygen species (ROS) that are believed to play an important role in the pathogenesis of multiple organ dysfunction in the course of sepsis. We showed that a purified T4 phage preparation with low-endotoxin content could significantly diminish the luminol-dependent chemiluminescence (CL) of peripheral blood polymorphonuclear leukocytes (PMNs) both stimulated by lipopolysaccharides (LPSs) isolated from different Escherichia coli strains. This effect was also observed for live bacteria used for PMNs stimulation and was independent of bacterial susceptibility for T4-mediated lysis. Our data suggest, that phage-mediated inhibition of LPS- or bacteria-stimulated ROS production by PMNs may be attributed not only to phage-PMNs interactions, but also to phage-LPS interactions and bacterial lysis (in case of homologous phage). Interestingly, the T4 preparation did not influence ROS formation by PMNs stimulated with PMA. This suggests that the observed phenomena are also dependent upon the nature of activator. Bacteriophage-mediated inhibition of ROS formation by cells exposed to endotoxin provides new evidence for possible interactions between phages and mammalian cells. It helps in understanding the role of phages in our environment and may also be of important clinical significance.

Hoc protein regulates the biological effects of T4 phage in mammals.

We previously investigated the biological, non-antibacterial effects of bacteriophage T4 in mammals (binding to cancer cells in vitro and attenuating tumour growth and metastases in vivo); we selected the phage mutant HAP1 that was significantly more effective than T4. In this study we describe a non-sense mutation in the hoc gene that differentiates bacteriophage HAP1 and its parental strain T4. We found no substantial effects of the mutation on the mutant morphology, and its effects on electrophoretic mobility and hydrodynamic size were moderate. Only the high ionic strength of the environment resulted in a size difference of about 10 nm between T4 and HAP1. We compared the antimetastatic activity of the T2 phage, which does not express protein Hoc, with those of T4 and HAP1 (B16 melanoma lung colonies). We found that HAP1 and T2 decreased metastases with equal effect, more strongly than did T4. We also investigated concentrations of T4 and HAP1 in the murine blood, tumour (B16), spleen, liver, or muscle. We found that HAP1 was rapidly cleared from the organism, most probably by the liver. Although HAP1 was previously defined to bind cancer cells more effectively (than T4), its rapid elimination precluded its higher concentration in tumours.

Bacteriophage translocation.

The occurrence of phages in the human body, especially in the gastrointestinal tract, raises the question of their potential role in the physiology and pathology of this system. Especially important is the issue of whether phages can pass the intestinal wall and migrate to lymph, peripheral blood, and internal organs and, if so, the effects such a phenomenon could have (such passage by bacteria, known as bacterial translocation, has been shown to cause various disturbances in humans, from immune defects to sepsis). Available data from the literature support the assumption that phage translocation can take place and may have some immunomodulatory effects. In addition, phages of the gut may play a protective role by inhibiting local immune reactions to antigens derived from gut flora.

Effects of bacteriophages on free radical production and phagocytic functions.

Reactive oxygen species (ROS) play a major role in mediating antibacterial functions of phagocytic cells. However, excessive ROS production may cause oxidative stress and tissue damage. Uncompensated ROS release has been implicated in a variety of disorders. Novel means of controlling elevated ROS production are urgently needed. We showed that homologous but not the heterologous phages inhibited, in a dose dependent manner, the degree of chemiluminescence in phagocytes induced by Escherichia coli. Treatment of the cells with the phages alone resulted in a small increase in ROS production. Homologous phages also facilitated phagocytosis when preincubated with bacteria. On the other hand, both homologous and heterologous phages inhibited phagocytosis following preincubation with phagocytic cells. The treatment of infected and uninfected mice with phages did not significantly alter the rate of phagocytosis by blood granulocytes and monocytes. In conclusion, we showed that bacteriophages can decrease ROS production by phagocytes. Although in some in vitro experimental models the phages tended to diminish phagocytosis, this phenomenon may be of little significance in clinical situations, since the process of eliminating bacteria in phage-treated patients is predominantly accomplished by both phages and phagocytes.

Activity of bacteriophages in murine tumor models depends on the route of phage administration.

Previously we investigated the anticancer activity of bacteriophage preparations in various murine tumor models. We demonstrated the antimetastatic activity of purified and nonpurified bacteriophage preparations injected intraperitoneally (IP). However, in solid tumors we observed antitumor activity of purified bacteriophages, but the lysates (raw preparations obtained by culturing phages with bacteria) stimulated tumor growth. In this article we present a comparison of the antitumor activity of bacteriophages after oral (per os, PO) and IP administration of lysates and purified preparations. Our observations indicate that PO application of a bacteriophage preparation is safer and at least as effective as IP. Stimulation of solid tumors by lysates administered orally was not observed, and bacteriophages applied PO were more effective in inhibiting metastases formation. These observations are of great importance in any consideration of possible therapeutic applications of bacteriophages. The role of the route of bacteriophage administration should be considered in the context of the effectiveness and safety of such therapies.

Anticancer activity of bacteriophage T4 and its mutant HAP1 in mouse experimental tumour models.

BACKGROUND: Previously, we have shown the ability of the bacteriophage T4 and its substrain HAP1 (selected for a higher affinity to melanoma cells) to reveal antimetastatic activity in a mouse melanoma model. Here, we investigated the potential phage anticancer activity in primary tumour models. MATERIALS AND METHODS: Mice were inoculated subcutaneously with B16 or LLC cells (collected from in vitro culture). Bacteriophages T4 and HAP1 were injected intraperitoneally daily (8 x 10(8)pfu/mouse, except the experiment concerning the dose-dependence). RESULTS: Treatment with purified preparations of bacteriophage T4 resulted in significant reduction of tumour size, the effect being dose-dependent. HAP1 was more effective than T4 and its activity was also dose-dependent. Parallel experiments with non-purified bacteriophage lysates resulted in significant stimulation of tumour growth. CONCLUSION: These data suggest that purified bacteriophages may inhibit tumour growth, a phenomenon with potentially important clinical implications in oncology.

New insights into the possible role of bacteriophages in host defense and disease.

BACKGROUND: While the ability of bacteriophages to kill bacteria is well known and has been used in some centers to combat antibiotics - resistant infections, our knowledge about phage interactions with mammalian cells is very limited and phages have been believed to have no intrinsic tropism for those cells. PRESENTATION OF THE HYPOTHESIS: At least some phages (e.g., T4 coliphage) express Lys-Arg-Gly (KGD) sequence which binds beta3 integrins (primarily alphaIIbbeta3). Therefore, phages could bind beta3+ cells (platelets, monocytes, some lymphocytes and some neoplastic cells) and downregulate activities of those cells by inhibiting integrin functions. TESTING THE HYPOTHESIS: Binding of KGD+ phages to beta3 integrin+ cells may be detected using standard techniques involving phage - mediated bacterial lysis and plaque formation. Furthermore, the binding may be visualized by electron microscopy and fluorescence using labelled phages. Binding specificity can be confirmed with the aid of specific blocking peptides and monoclonal antibodies. In vivo effects of phage - cell interactions may be assessed by examining the possible biological effects of beta3 blockade (e.g., anti-metastatic activity). IMPLICATION OF THE HYPOTHESIS: If, indeed, phages can modify functions of beta3+ cells (platelets, monocytes, lymphocytes, cancer cells) they could be important biological response modifiers regulating migration and activities of those cells. Such novel understanding of their role could open novel perspectives in their potential use in treatment of cardiovascular and autoimmune disease, graft rejection and cancer.