Influence of environmental variables in the efficiency of phage therapy in aquaculture.

Aquaculture facilities worldwide continue to experience significant economic losses because of disease caused by pathogenic bacteria, including multidrug-resistant strains. This scenario drives the search for alternative methods to inactivate pathogenic bacteria. Phage therapy is currently considered as a viable alternative to antibiotics for inactivation of bacterial pathogens in aquaculture systems. While phage therapy appears to represent a useful and flexible tool for microbiological decontamination of aquaculture effluents, the effect of physical and chemical properties of culture waters on the efficiency of this technology has never been reported. The present study aimed to evaluate the effect of physical and chemical properties of aquaculture waters (e.g. pH, temperature, salinity and organic matter content) on the efficiency of phage therapy under controlled experimental conditions in order to provide a basis for the selection of the most suitable protocol for subsequent experiments. A bioluminescent genetically transformed Escherichia coli was selected as a model microorganism to monitor real-time phage therapy kinetics through the measurement of bioluminescence, thus avoiding the laborious and time-consuming conventional method of counting colony-forming units (CFU). For all experiments, a bacterial concentration of ≈ 10(5) CFU ml(-1) and a phage concentration of ≈ 10(6-8) plaque forming unit ml(-1) were used. Phage survival was not significantly affected by the natural variability of pH (6.5-7.4), temperature (10-25 °C), salinity (0-30 g NaCl l(-1) ) and organic matter concentration of aquaculture waters in a temperate climate. Nonetheless, the efficiency of phage therapy was mostly affected by the variation of salinity and organic matter content. As the effectiveness of phage therapy increases with water salt content, this approach appears to be a suitable choice for marine aquaculture systems. The success of phage therapy may also be enhanced in non-marine systems through the addition of salt, whenever this option is feasible and does not affect the survival of aquatic species being cultured.

Characterization of new furocoumarin derivatives by their dark and light-mediated action on RNA bacteriophage MS2.

The monofunctional and bifunctional furocoumarin derivatives 8-methyl-3-carbethoxypsoralen (8Me3CPs) and 8-methoxypsoralen (8MOP) as well as their thiosubstituted derivatives (2-thio-8Me3CPs and 2-thio-8MOP) were compared in terms of their reactivities towards a ribonucleoprotein, the bacteriophage MS2. The order of their photoreactivities differed from that measured with nuclear DNA and mitochondrial DNA. Besides their widely investigated photoreactivity, their biological activity in the dark and after pre-irradiation was quantified. A parameter was defined which compares the number of molecules acting in the dark for 1 h with the number of absorbed photons which lead to the same degree of inactivation. The parameter for the furocoumarin derivatives examined, including 3-carbethoxypsoralen (3CPs) and 4'-aminomethyl-4,5',8-trimethylpsoralen (AMT), was in the following order: AMT greater than 3CPs greater than 8MOP greater than 8Me3CPs greater than 8Me3CPsS approximately 8MOPS. A similar parameter was also determined for the dark effect of pre-irradiated compounds.

Growth and reactivation of single stranded DNA phage phiX174 in E. coli undergoing "thymineless death".

The thymine requirement of the E. coli strain HF 4704 (uvr A-, rec A+) is thermosensitive i.e. these cells require for their growth 2 microng thymine per ml at 37 degrees C but not at 30 degrees C. Such cells when starved for thymine for 3 h at 37 degrees C are capable of sustaining growth of single stranded DNA phage phiX174 without any diminution of burst size under nonpermissive conditions. Thymine starved HF 4704 cells also reactivate UV-irradiated phiX174 by about 3fold. To test if the thymine necessary for phage growth under "thymineless" conditions was supplied by host DNA degradation products, the transfer of 32P label from the host DNA to mature progeny phages was measured by means of sucrose density gradient analysis. It was found that only about 0.7% of 32P of the host DNA was transferred to the progeny phages growing in normal cells whereas the corresponding value was 7.8% in the case of thymine starved cells.

Photobiological behaviour of bacteria and phages supplemented with aza-analogoues of nucleic acid bases.

The photochemical stability of anomalous nucleic acid bases of the azatype, 5-azacytosine (I), 5-azacytidine (II), 6-azacytosine (III), 6-azacytidine (IV), 6-azathymine (V), 6-azauracil (VI), and 8-aza-adenine (VII) to U. V. light of the wavelength 254 nm differs from the U. V. stability of the normal constituents. Changes of the U.V. inactivation of Escherichia coli K12 C600, E. coli B, Bacillus cereus, as well as E. coli phages gamma cb2 and gamma b2b5 supplemented with azaderivatives prior to irradiation were investigated. It was found that I, II, III, IV, and VII are more, V and VI less sensitive to U. V. light compared with corresponding natural nucleic acid bases. Their changed U. V. sensitivities are reflected in the survival curves after U. V. -irradiation in as far as azabases are incorporated into the nucleic acids in vivo. This explains the increase in U.V. sensitivity of E. coli K12 C600, E. coli B, and B. cereus supplemented with I, II, III, IV, and VII and the decrease in U.V. sensitivity of Streptococcus faecalis supplemented with V (the latter information was taken from Gunther and Prusoff 1967). The lack of any significant influence on inactivation curves of E. coli K12 C600 by V and VI, and on E. coli phages gamma cb2 and gamma c2b5 by II, is discussed in terms of too small incorporation rates. No discrimination was put forward with respect to DNA and RNA incorporation.