SEPARATION OF THE TRANSFORMING AND VIRAL DEOXYRIBONUCLEIC ACIDS OF A TRANSDUCING BACTERIOPHAGE OF BACILLUS SUBTILIS

Transduction-like gene transfer in the methanogen Methanococcus voltae

Strain PS of Methanococcus voltae (a methanogenic, anaerobic archaebacterium) was shown to generate spontaneously 4.4-kbp chromosomal DNA fragments that are fully protected from DNase and that, upon contact with a cell, transform it genetically. This activity, here called VTA (voltae transfer agent), affects all markers tested: three different auxotrophies (histidine, purine, and cobalamin) and resistance to BES (2-bromoethanesulfonate, an inhibitor of methanogenesis). VTA was most effectively prepared by culture filtration. This process disrupted a fraction of the M. voltae cells (which have only an S-layer covering their cytoplasmic membrane). VTA was rapidly inactivated upon storage. VTA particles were present in cultures at concentrations of approximately two per cell. Gene transfer activity varied from a minimum of 2 x 10(-5) (BES resistance) to a maximum of 10(-3) (histidine independence) per donor cell. Very little VTA was found free in culture supernatants. The phenomenon is functionally similar to generalized transduction, but there is no evidence, for the time being, of intrinsically viral (i.e., containing a complete viral genome) particles. Consideration of VTA DNA size makes the existence of such viral particles unlikely. If they exist, they must be relatively few in number;perhaps they differ from VTA particles in size and other properties and thus escaped detection. Digestion of VTA DNA with the AluI restriction enzyme suggests that it is a random sample of the bacterial DNA, except for a 0.9-kbp sequence which is amplified relative to the rest of the bacterial chromosome. A VTA-sized DNA fraction was demonstrated in a few other isolates of M. voltae.

Restriction and modification of bacteriophage SP10 DNA by Bacillus subtilis Marburg 168: stabilization of SP10 DNA in restricting hosts preinfected with a heterologous phage, SP18

SP10 phage cannot propagate in Bacillus subtilis Marburg 168 containing the wild-type allele of either gene nonA or gene nonB. The latter gene codes for the intrinsic cellular restriction activity. SP10 DNA was degraded in nonB+ derivatives of Marburg 168. The degree of degradation depended upon the previous host in which SP10 was propagated. In the case of SP10 grown in B. subtilis W23 (a nonrestricting, nonmodifying bacterium), 90% of the phage DNA was hydrolyzed to acid solubles, and the residual acid-precipitable material was recovered as 0.5- to 1-megadalton fragments. In contrast, if SP10 was propagated in B. subtilis PS9W7 (a nonA nonB derivative of Marburg 168 that retains modifying activity), 40 to 50% of the input DNA was degraded to acid solubles, and most of the remainder was recovered as 15- to 20-megadalton fragments. In nonA+ nonB cells, SP10 DNA was conserved as unit-length molecules (ca. 80 megadalton). Prior infection of nonB+ cells with SP18 protected superinfecting SP10 DNA, even when rifampin or chloramphenicol was added before the primary infection. The data are discussed in terms of the following conclusions. (i) The nonB gene product of B. subtilis Marburg 168 is required for restriction of SP10 DNA. (ii) Some sites on SP10 DNA are sensitive to both the restricting and modifying activities, whereas other sites are nonmodifiable even though they are sensitive to the restriction enzyme. (iii) In some manner, SP18 antagonizes the action of the nonB gene product.

Bacteriophages of Bacillus subtilis

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Transduction in Bacillus subtilis by bacteriophage SPP1

Lysates of the virulent bacteriophage SPP1 were shown to be capable of mediating generalized transduction. Suppressible mutants of this bacteriophage (sus) were capable of transduction at a lower multiplicity of infection than virulent SPP1. Linkage analysis demonstrated that bacteriophage SPP1 transduced segments of the genome equal in size to that transferred by SP10. This bacteriophage should be useful in analyzing the regions of the genome where PBS1 appears to give anomalous results.

Transduction mechanisms of bacteriophage epsilon 15. I. General properties of the system

Bacteriophageεγis capable of transduction both by replacement of a genetic segment of the recipient by the homologous genetic material from the donor strain and by the formation of defective transducing particles capable of lysogenizing the recipient strain ofS. anatum.

The isolation of strains carrying such prophages, which have incorporated the lactose or arabinose operons, is reported. Lysogenic strains, carrying both normal and defective transducing prophage, form high-frequency transducing lysates. Other strains, carrying only defective prophage, show evidence that the association of prophage genes and transduced materials is stable since the loss of one frequently entails loss of the other.

Growth and cultivation of the unusual generalized transducing Bacillus bacteriophage SP-15

Additional properties of SP-15, a generalized transducing bacteriophage notable for the ability to transfer an unusually large fragment of deoxyribonucleic acid (DNA) to Bacillus subtilis and B. licheniformis, are presented together with improved methods that enhance its utility. Simple means have been found to provide the rigid control over moisture that is necessary for the assay of plaque-forming units (PFU). Reproducible procedures for propagating transducing phage, which depend upon an appropriate mixing of PFU with uninfected bacteria, have replaced less reliable methods that utilized infected spores. Transduction of B. subtilis W-23 increased linearly when MgSO(4) in recipient cell-SP-15 mixtures was increased from 0.005 to 0.03 m. Methods have been developed that protect SP-15 from the damaging effects of CsCl and of osmotic shock subsequent to dilution. Evidence that the PFU and transducing particles of lysates decay at the same slow rate during extended storage suggests that the decay is a result of damage to protein rather than to DNA. One-step growth experiments, in which SP-15 was propagated on B. subtilis W-23-S(r)/1 mg, indicated a latent period of 100 min, a rise period of 60 min, and a burst size of 25 to 34 PFU per infected cell. These findings suggest explanations for some of the technical difficulties SP-15 has presented.

Cotransduction and cotransformation of genetic markers in Bacillus subtilis and Bacillus licheniformis

Bacteriophage SP-15, a large generalized transducing phage of Bacillus, was compared with phages PBS-1 and SP-10 for the ability to cotransduce pairs of genetic markers exhibiting different degrees of linkage. When auxotrophs of B. subtilis W-23 were used as recipients, SP-15 and PBS-1 effected a much higher frequency of cotransduction than did SP-10 with markers that were not closely linked. With more closely linked loci, the differences were not as great. SP-15 cotransduced linked markers at a higher mean frequency than PBS-1, suggesting that SP-15 is able to transfer a larger fragment of the Bacillus genome than any phage heretofore described. The frequency of the joint transfer of genetic markers in B. licheniformis was lower via transforming deoxyribonucleic acid than by transduction with phage SP-10. The availability of three procedures for genetic exchange-transduction by SP-15 and SP-10 as well as transformation-each of which reveals a different degree of linkage, makes B. licheniformis 9945A especially amenable to genetic analysis.

Infectivity of Bacillus subtilis bacteriophage deoxyribonucleic acids extracted from mature particles and from lysogenic hosts

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Productive Infection of Bacillus subtilis 168, with Bacteriophage SP-10, Dependent upon Inducing Treatments

Strains of Bacillus that harbor defective phage PBSX were found to be insensitive to SP-10(C), although the phage adsorbed to these insensitive strains. Strains that did not carry the phage were sensitive to SP-10(C). B. subtilis 168 ind − , which can be tranduced by SP-10(C) but is nonpermissive for the phage, was rendered phage-sensitive after treatment with ultraviolet (UV) light or mitomycin C. After induction with UV light, maximal sensitivity to SP-10(C) was obtained at a multiplicity of infection (MOI) of approximately 14; with mitomycin C induction, an MOI of approximately 1.0 was required. Phage maturation in sensitized cells was followed by plating infected streptomycin-sensitive cells in the presence of streptomycin at various stages during phase development. The latent period was estimated at 60 to 75 min. We suggest that the resistance of B. subtilis 168 to SP-10 is controlled, at least in part, by the presence of a defective prophage.

Productive infection of Bacillus subtilis 168, with bacteriophage SP-10, dependent upon inducing treatments

Strains of Bacillus that harbor defective phage PBSX were found to be insensitive to SP-10(C), although the phage adsorbed to these insensitive strains. Strains that did not carry the phage were sensitive to SP-10(C). B. subtilis 168 ind(-), which can be tranduced by SP-10(C) but is nonpermissive for the phage, was rendered phage-sensitive after treatment with ultraviolet (UV) light or mitomycin C. After induction with UV light, maximal sensitivity to SP-10(C) was obtained at a multiplicity of infection (MOI) of approximately 14; with mitomycin C induction, an MOI of approximately 1.0 was required. Phage maturation in sensitized cells was followed by plating infected streptomycin-sensitive cells in the presence of streptomycin at various stages during phase development. The latent period was estimated at 60 to 75 min. We suggest that the resistance of B. subtilis 168 to SP-10 is controlled, at least in part, by the presence of a defective prophage.

Differential expression of bacteriophage genomes in vegetative and sporulating cells of Bacillus subtilis

Two antigenically distinct bacteriophages, beta3 and beta22, have been isolated and characterized with Bacillus subtilis strain W23 as a host. They differ in plaque morphology, single-step growth characteristics, host range, and thermal stability. The deoxyribonucleic acids isolated from beta3 and beta22 differ in base composition, density in CsCl and Cs(2)SO(4), sedimentation coefficient, molecular weight, and thermal denaturation temperature. These phages have been used to analyze the ability of B. subtilis to sporulate despite infection by virulent phages. When development of phages beta3 and beta22 in sporulating cultures was compared with that in log cultures, an increase in the latent periods of infection and a decrease in the burst sizes for the two phages were observed. Sporulating cultures infected with beta3 yielded the usual percentage (85%) of mature spores; 80% of these contained phage determinants and 20% were uninfected. However, cultures infected with beta22 lysed. Of the small fraction (0.01%) which sporulated, 83% were uninfected and 17% were infected. Phage beta3-infected and uninfected spores were examined to distinguish any chemical or physical differences. Preparations of both types of spore contained 81.4 mug of dipicolinic acid per mg (dry weight), and examination by phase-contrast microscopy gave no evidence of any difference in outward appearance. A 20% decrease in infected spore count was observed upon heating at 80 C for 10 min. Differences in the infection processes of the two phages prompted an analysis of the transcription process after infection. Deoxyribonucleic acid-ribonucleic acid hybrid analysis of relative amounts of phage-specific and host-specific messenger ribonucleic acid (mRNA) present in infected cells suggested that beta3 was unable to repress the synthesis of host mRNA and that beta3-specific mRNA synthesis was repressed in sporulation-phase cultures. Phage beta22, in contrast, was able to repress host-specific mRNA synthesis in both log-infected and sporulation-infected cells. The results suggest that the differential expression of the phage genomes is due to the relative ability of the phages to repress the host genome.

Concurrent changes in transducing efficiency and content of transforming deoxyribonucleic acid in Bacillus subtilis bacteriophage SP-10

Taylor, Martha J. (Fort Detrick, Frederick, Md.), and Curtis B. Thorne. Concurrent changes in transducing efficiency and content of transforming deoxyribonucleic acid in Bacillus subtilis bacteriophage SP-10. J. Bacteriol. 91:81-88. 1966.-Spores of Bacillus subtilis W-23-S(r) infected with transducing phage SP-10 served as convenient inocula for broth cultures from which transducing phage was harvested. Methods are described for producing highly infected spores. The inoculum level of infected spores in nutrient broth-yeast extract-glucose medium affected the transducing efficiency of SP-10 in lysates of these cultures. Phage in lysates of cultures inoculated with about 10(5) or fewer spores per milliliter transduced 20- to 350-fold more efficiently than did phage in lysates from cultures inoculated with 10(6) to 10(7) spores per milliliter. Transduction frequencies in the order of 10(-5) per plaque-forming unit were obtained routinely, and some infected-spore preparations yielded phage that gave frequencies as high as 10(-4). The combination of inoculum level and incubation time required to produce the best transducing phage had to be determined empirically for each batch of infected spores. Several possible explanations for the difference between lysates having high (HTE) and those having low (LTE) transducing efficiency were ruled out by special experiments. The hypothesis is presented that some cultural condition resulting from a relatively low inoculum of phage-infected spores favors the incorporation by phage particles of bacterial deoxyribonucleic acid (DNA) in the manner required for the production of transducing phage. Support for this hypothesis is a demonstration, through transformation experiments with DNA extracted from HTE and LTE phage particles, that populations of HTE phage particles yielded significantly more (7 to 27 times) transforming activity per microgram of DNA than did populations of LTE phage.

BACILLUS SUBTILIS DEOXYRIBONUCLEIC ACID TRANSFER IN PBS2 TRANSDUCTION

Mahler , I. (Brandeis University, Waltham, Mass.), M. Cahoon, and J. Marmur . Bacillus subtilis deoxyribonucleic acid transfer in PBS2 transduction. J. Bacteriol. 87: 1423–1428. 1964.—Lysates of the general transducing bacteriophage PBS2 grown on Bacillus subtilis SB19 were fractionated by preparative CsCl density-gradient centrifugation. Five distinct and separate bands which varied in their ability to transduce three nutritional markers were obtained by this procedure. Deoxyribonucleic acid (DNA) samples prepared from unfractionated lysates and from each of the separate bands were examined by analytical CsCl density-gradient centrifugation. In addition to a major band (density, 1.723 g/cc) identified as PBS2 DNA, a satellite band of lighter density was detectable in the nucleic acids obtained from whole lysates and those bands that possessed transducing activity. The biological activity of the purified nucleic acids, determined by transformation experiments, was found to reside in the light satellite band (1.703 g/cc) characteristic of B. subtilis DNA. In view of the correlation between general transducing ability of phage particles and the presence of bacterial DNA which appears not to be physically associated with the phage DNA, it is suggested that transduction by bacteriophage PBS2 does not depend upon areas of homology between the phage genome and the host chromosome but resides in specific particles which have incorporated segments of bacterial DNA.