Increased numbers of heat-resistnat spores produced by two strains of Clostridium perfringens bearing temperate phage s9.

Sporulation kinetics and spore heat resistance data were compared for a lysogenic strain of Clostridium perfringens, s9, before and after curing with ultraviolet irradiation. The cured strain showed the same growth rate in broth media as the lysogenic strain but took 6 h longer to form refractile spores. For lysogenized and cured strains the percentages of refractile spores produced that were heat-resistant (80 degrees C for 15 min) were 50 and 0.2, respectively. When reinfected with the temperature phage, the cured strain produced spores in 2 to 3 h, like the original lysogenic culture, and 10% of the spores produced were heat-resistnat.     

Induction of Prophage in Streptococcus lactis C2 by Ultraviolet Irradiation

Streptococcus lactis C2 has been used extensively by many laboratories in studies on the metabolism of lactic streptococci. By using ultraviolet irradiation as the inducing agent, this organism was shown to release a small bacteriophage, indicating that it is a lysogenic strain. The induced phage had a head approximately 40 nm in diameter and a tail length and width of about 180 and 6 nm, respectively. A structure resembling a collar was observed. Attempts to isolate a sensitive indicator strain for the virus were unsuccessful.     

Isolation and Characterization of a Lysogenic Strain of Nocardia erythropolis

A stable phage-carrying strain of Nocardia erythropolis was isolated from an infection with the nocardiophage phiEC. Growth of the strain in phage-specific antiserum for 48 hr produced cured organisms at a frequency of about 0.5%. Spontaneous curing, determined by serial single-colony isolations, was less than 0.4%. The strain could not be infected by phage phiEC nor by a closely related phage, phiC, although the cells were able to adsorb these phages. In cell populations, a frequency of 2.5 x 10(-4) cells spontaneously induced. The growth rate of the strain was comparable to that of the uninfected wild-type N. erythropolis. Ultraviolet irradiation or treatment with mitomycin C induced the strain to produce larger numbers of phage. It was concluded that the isolated strain was lysogenic.     

Prophage Induction of Noninducible Coliphage 186

Coliphage 186 has been regarded as a member of the noninducible group of coliphages. Evidence that prophage 186 is induced by ultraviolet irradiation or by treatment with nalidixic acid or mitomycin C is now presented. The phage yields were similar to those from lysogens of the inducible phage lambda, and the induction required a recA(+) host. A noninducible mutant of 186 was isolated from its heat-inducible derivative, 186cIts, that was no longer inducible by ultraviolet irradiation but remained heat inducible. That zygotic induction of 186 after transfer from a lysogenic male to a non-lysogenic recipient did not occur is indicated by the following findings: (i) there was only a slight increase in phage titer; (ii) similar levels of recombinants were obtained for markers adjacent or distal to the phage integration site, whether the recipient was lysogenic or not, and there was no effect on the gradient of marker transfer; (iii) lysogenic recombinants were readily found and the co-transfer of 186 with adjacent markers was the same to lysogenic or non-lysogenic recipients. Thus, 186 formed an inducible prophage that did not display zygotic induction. Nevertheless, it shared many properties with the noninducible phage P2 as outlined in the discussion.     

Genetic Analysis of tox+ and tox? Bacteriophages of Corynebacterium diphtheriae

A series of mutants derived from the temperate corynebacteriophages beta(tox+), gamma(tox-), and L(tox+) was isolated and characterized. In three-factor crosses between mutant beta phages the relative map order of the genetic markers determining extended host ranges (h and h') and loss of ability to lysogenize (c) was found to be h--c--h'. Recombination between markers was observed in matings between phage beta and the heteroimmune corynebacteriophages gamma and L. In such matings between heteroimmune phages the c markers of phages beta and gamma failed to segregate from the imm markers which determine the specificity of lysogenic immunity in these phages. The factor which directs the synthesis of diphtherial toxin during infection of appropriate corynebacterial hosts by toxinogenic corynebacteriophages is designated tox(+). It was possible to show that the tox(+) determinant of phage beta behaves as a single genetic element which occupies a position between the loci h and imm on the genetic map of this phage. Genetic recombination between mutants of phage beta occurred at very low frequencies in biparental matings performed by mixed infection of Corynebacterium diphtheriae C7(s)(-)(tox-). Considerably higher recombination frequencies were observed when lysogenic bacterial strains carrying one parental phage as prophage were induced by ultraviolet irradiation and then superinfected by the second parental phage. Maximal stimulation of genetic recombination between mutant beta phages was detected when superinfection followed ultraviolet irradiation of the lysogenic cells within a limited period of time. In matings between phages with incomplete genetic homology, the stimulation of recombination by ultraviolet radiation was much less effective.     

Properties of Haemophilus influenzae mutants that are slightly recombination deficient and carry a mutation in the rec-1 gene region.

The highly recombination-deficient rec-1 mutants of Haemophilus influenzae are, as far as tested, equivalent to recA mutants of Escherichia coli. By selection for mutations in the rec-1 gene of H. influenzae, mutants designated ird (intermediary recombination-deficient) mutants were isolated; these mutants were much less recombination deficient (degree of transformability, 0.2 to 30% of wild-type value) than previously isolated rec-1 mutants (degree of transformability, 0.0001% of wild-type value). The ird mutants were more sensitive to ultraviolet irradiation and mytomycin C treatment than the wild type, but less sensitive than rec-1 mutants. Spontaneous production of phage HP1c1 by lysogenic MC11 cells and prophage induction by mitomycin C or ultraviolet irradiation were the same as in the wild type. In the ird mutants endogenous deoxyribonucleic acid was degraded both spontaneously and after ultraviolet irradiation to the same extent as in the wild type. Examination of one of the ird mutants revealed that recombination could be enhanced by ultraviolet irradiation, possibly because of an increased synthesis of the rec-1 gene product induced by ultraviolet irradiation.     

Integration and Induction of Phage P22 in a Recombination-deficient Mutant of Salmonella typhimurium

Phage P22 can integrate as prophage into a recombination-deficient (Rec(-)) strain of Salmonella typhimurium. At 37 C, the integration efficiency is only 10% that in Rec(+) infection, but at 25 C the efficiencies in Rec(-) and Rec(+) hosts are similar. Rec(-) lysogens cannot be induced by ultraviolet irradiation or by treatments with the chemical inducing agents streptonigrin or mitomycin C. Heat induction of Rec(-) cells lysogenic for a temperature-sensitive c(2) mutant (ts c(2)) is normal, showing that the Rec(-) cell has the machinery necessary for prophage excision. Ultraviolet irradiation of Rec(-) (ts c(2)) lysogens prior to heat induction does not prevent the formation of infective centers after temperature shift. Thus, the noninducibility of Rec(-) lysogens is not due to destruction of the prophage as a result of ultraviolet irradiation. Deoxyribonucleic acid-ribonucleic acid (RNA) hybridization experiments demonstrate that no increase in phage-specific RNA synthesis occurs after ultraviolet irradiation of a Rec(-) (c(+)) lysogen. The Rec(-) mutant appears to lack part of the mechanism required to destroy the phage repressor and allow the initiation of early phage functions such as messenger RNA synthesis. A similar conclusion was reached previously for an Escherichia coli Rec(-) strain.     

Studies on Temperate Phages of Lactobacillus salivarius

Comparative studies were carried out on the mode of action of the defective temperate phage 208 against the homologous lysogenic strain S-208 and a nonlysogenic strain S-161 of Lactobacillus salivarius. Treatment of both strains with phage 208 led to a specific inhibition of protein synthesis, cell killing without any reversion of protein synthesis, and of viable counts by treatment with trypsin. Killing action of phage 208 followed a single hit kinetics for nonlysogenic S-161 and S-208 No. 006, which is a cured strain of S-208, whereas, two to five hit kinetics was obtained for lysogenic S-208. Phage particles exposed to ultraviolet light (5.7 kergs/cm²) also killed S-161 with a single hit kinetics and S-208 with a 3-hit kinetics. However, the kinetics of killing approached a single hit when the protein synthesis of S-208 was inhibited by chloramphenicol prior to the phage addition. Based upon these results, the possible mechanisms of immunity breakdown and of subsequent cell killing were discussed.     

Effects of Mitomycin C and Thymidine Deprivation on Lysogenic and Sensitive Strains of Bacillus megaterium

A triple auxotroph of Bacillus megaterium strain KM was lysogenized with a phage suspension from B. megaterium 899a. The lysogenic and phage-sensitive derivatives of KM were found to die at the same exponential rate during thymineless incubation, despite the fact that the lysogenic strain became induced. The lysogenic strain was also induced by mitomycin C, and died at an exponential rate which was approximately twice that of the sensitive strain. With both strains, the lethality of mitomycin C was the same in the presence and absence of thymidine; thymidine was required for maximal phage production. Mitomycin C preferentially inhibited deoxyribonucleic acid (DNA) synthesis of both strains for the first 60 min. The (DNA) synthetic ability of the lysogenic strain was subsequently restored, due to phage production. Since there was no evidence that sensitive strains of KM contained other inducible elements (prophage or probacteriocins), it is concluded that both thymineless death and mitomycin C death can occur via mechanisms not involving induction.     

Lysogenic Conversion in Staphylococcus aureus to Leucocidin Production

A Staphylococcus aureus strain was successively cured of three prophages. A lysogenic conversion by a group A phage to production of Panton-Valentine leucocidin and by a group F phage to staphylokinase production could be demonstrated.     

Bordetella pertussis bacteriophage

For the first time Bordetella pertussis bacteriophage was isolated, and its presence was confirmed by electron microscopy and by agar layer titration. The lysogenic strains were activated by their treatment with mitomycin C in a dose of 4.5 mg/ml. The phage system of the Bordetella genus, heretofore unknown, has been revealed: Bordetella pertussis phage lyzed all the tested strains of Bordetella parapertussis (25 strains) and could be passaged in these strains. The phage formed turbid and transparent negative colonies 0.1 mm and 0.15 mm in size. The phage titer (e. g., in strain No. 3865) was 1 X 10(10). The lysogenic variants of Bordetella pertussis, capable of spontaneous release of the phage, were obtained. These variants were characterized by changes in some of their phenotypical properties, e.g., the increased content of certain toxic substances and increased virulence.     

Ultraviolet reactivation of lambda phage: assay of infectivity of DNA molecules by spheroplast transfection

Prior irradiation of non-lysogenic bacteria by ultraviolet light leads to an increase in the viability of infecting irradiated λ phage (ultraviolet reactivation). Similarly, u.v. irradiation of wild type or uvrD bacteria lysogenic for λcIind^? increased the fraction of closed circular duplex phage DNA molecules formed after infection with u.v.-irradiated λ phage. The closed circular molecules isolated from the irradiated lysogens were shown to be free from u.v. damage by a spheroplast transfection assay. The increase of closed circular molecules is sufficient to explain the ultraviolet reactivation observed by the increase of viability of irradiated phage.In ultraviolet reactivation, damage must be erased on irradiated DNA molecules and the repair is independent of total replication of phage genomes, exchange of sister chromatids or recombination between phage genomes. Protein synthesis is necessary to increase the level of closed circular molecules of irradiated λ phage after irradiation of bacteria.     

Prophage Curing in Lactobacillus casei by Isolation of a Thermoinducible Mutant

To eliminate the occurrence of virulent phage in industrial fermentation, attempts were made to obtain prophage-cured derivatives from Lactobacillus casei lysogenic strain S-1. A thermoinducible mutant lysogen was isolated from mutagenized strain S-1, since S-1 cannot be induced under laboratory conditions. The mutation responsible for thermoinducibility was located on the prophage. Prophage-cured strains were selected after heat induction of the mutant. These cured strains did not produce the virulent phage and should be valuable for industrial fermentation.     

Role of the ø11 Phage Genome in Competence of Staphylococcus aureus

Both phage ?11 and 83A, when present as prophage or when used as helper phage, induce competence for transfection and transformation to the same level in Staphylococcus aureus, strain 8325-4. Cells lysogenized with certain temperature-sensitive (ts) mutants of phage ?11 show competence at the nonpermissive temperature (41 C) without production of infectious phages. Phage ?11ts allele 31 can neither as a prophage nor as a helper phage develop competence under nonpermissive conditions. This mutant appears, therefore, to be mutated in the region of the phage genome controlling competence. The competence level for both transfection and transformation is increased by superinfecting strain 8325-4 (?11) or 8325-4 (83A) at high multiplicities with phage ?11 with some of its mutants or with phage 83A. This superinfection enhancement appears to require protein synthesis but not deoxyribonucleic acid synthesis as judged from studies with inhibitors of macromolecular synthesis. Besides the phage particle, no extracellular or cell-bound factors so far detected can induce competence. The phage-induced product conferring competence is rapidly synthesized by strain 8325-4 (ts?11(31)) after shift to permissive conditions, but requires deoxyribonucleic acid and protein synthesis to be expressed. Recombination between the sus mutants of phage ?11 of Kretschmer and Egan and ts?11(31) indicate that competence is controlled by an early gene in the lytic cycle which may be expressed also in lysogenic cells. The phage product inducing competence appears to have a half-life of 10 to 15 min in the conditional lethal mutant at shift to nonpermissive temperature. Ultraviolet inactivation of phage ?11 infectivity occurs more rapidly than inactivation of competence induction. In fact, the number of transformants is increased at low doses of irradiation. Competence induction is, however, decreased at high does of ultraviolet irradiation.     

Restoration induced by catalase in irradiated microorganisms

1. E. coli, strain K-12, and B. megatherium 899, irradiated in strict but still undefined physiological conditions with certain heavy doses of ultraviolet light, are efficiently restored by catalase, which acts on or fixes itself upon the bacteria in a few minutes. This restoration (C. R.), different from photorestoration, is aided by a little visible light. 2. At 37° the restorability lasts for about 2 hours after UV irradiation; the restored cells begin to divide at the same time as the normal survivors. 3. C. R. is not produced after x-irradiation. 4. B. megatherium Mox and E. coli, strain B/r show little C. R.; E. coli strain B shows none. None of these three strains is lysogenic, whereas the two preceding catalase-restorable strains are. 5. Phage production in the system "K-12 infected with T2 phage" is restored by catalase after UV irradiation, whereas phage production in the system "infected B" is not. 6. With K-12, catalase does not prevent the growth of phage and the lysis induced by UV irradiation (Lwoff's phenomenon). 7. Hypotheses are discussed concerning: (a) the chemical nature of this action of catalase; (b) a possible relation between C. R. and lysogenicity of the sensitive bacteria; (c) the consequences of such chemical restorations on the general problem of cell radiosensitivity.     

Interactions of Lactobacillus bulgaricus Temperate Bacteriophage 0448 with Host Strains

Lactobacillus bulgaricus LT4(0448) is a lysogenic strain from which a temperate bacteriophage can be induced by mitomycin C or UV irradiation. Lactobacillus lactis CNRZ 326 is an indicator strain for the temperate phage 0448, but this strain lyses only in the presence of Ca²⁺ ions. A resistant culture developed secondarily after phage lysis and grew normally in MRS broth but again lysed abruptly if Ca²⁺ ions were added after two or three transfers. This behavior of the secondary culture and its subcultures is explained by a heterogeneous and fluctuating bacterial population, including clones identical to L. lactis 326, which were sensitive to 0448 and which formed rough colonies, as does the indicator. The proportion of these clones increased in the course of transfers in MRS, explaining lysis when Ca²⁺ was added. The population also included clones which formed smooth colonies (S clones). SI clones, which could not be induced by mitomycin C, were the major type in the initial culture, although they were sensitive to temperate phage 0448. The SI population then decreased and was gradually replaced by SII clones, inducible by mitomycin C and resistant to 0448. These SII clones were lysogenized clones, 326(0448), whose stability was confirmed by growth in the presence of an antiphage serum. When L. bulgaricus LT4(0448) was treated with mitomycin C, several cured LT4 clones were obtained that were related to the clones of the indicator L. lactis 326; they formed rough colonies. They also became sensitive to lytic phages or temperate phages active against L. lactis 326 and insensitive to lytic phages which lysed L. bulgaricus LT4(0448). This suggests that phage 0448 can lead to a lysogenic conversion of host strain LT4.     

Properties of the cured oncogenic strain 37400 ofAgrobacterium tumefaciens

The properties of the 37400 oncogenic strain ofAgrobacterium tumefaciens are described. This strain was derived from the VI lysogenic strain originally isolated by Hamilton from aZinnia elegans tumour. Strain 37400 has a number of properties which render it suitable for quantitative and genetic studies. It is cured of prophages and can serve as a universal sensitive indicator for a number of phages isolated from various lysogenic strains ofAgrobacterium tumefaciens. Its good growth properties in synthetic media and at elevated temperatures enable the isolation of auxotrophic mutants and temperature sensitive phage mutants. Preliminary experiments show that strain 37400 will serve as suitable starting material for conjugation experiments under defined conditions.     

Thermal Reversal of Ultraviolet-Irradiation Damage in Salmonella typhimurium

Effects of ultraviolet irradiation on lysogenic and nonlysogenic Salmonella typhimurium grown at 25 C are partially reversed by shifting cultures to 43 C immediately after irradiation.     

New waterborne bacteriophages active on Yersinia enterocolitica.

Seven bacteriophages active on Yersinia enterocolitica (YE) were isolated from surface water samples collected in Granada, Spain. A comparison of the respective host ranges of these new phages and of reference phages used for YE phage typing showed that YE strains belonging to various phage types, grown at either 37 or 25 degrees C, expressed susceptibility to reference sewage water phages whereas susceptibility to new waterborne phages, as well as to reference phages from lysogenic YE, was only demonstrated in YE strains grown at 25 degrees C. A YE strain isolated by stool culture from a pig was lysogenic for a bacteriophage which behaved like waterborne phages and reference phages from lysogenic YE strains. The possibility that the isolation of waterborne bacteriophages might, in certain circumstances, reflect the presence of lysogenic YE was raised.     

Characterisation of Streptococcus thermophilus CNRZ1205 and its cured and re-lysogenised derivatives

Streptococcus thermophilus CNRZ1205 is the lysogenic host for the temperate phage phi O1205. A derivative of CNRZ1205 was isolated which was cured of phi O1205 and this strain was used to construct a re-lysogenised derivative. Pulse field gel electrophoresis and sequencing of the attachment site regions confirmed that excision and re-integration of the phage was a site-specific event. Interestingly, cells from the cured, as well as its re-lysogenised derivative, were found to have a very long chain length.