Recombinational-type transfer of viral DNA during bacteriophage 2C replication in Bacillus subtilis

Fluorometric in vivo determination of Bacillus subtilis and phage 2C DNA

The validity of in vivo fluorometric assays was ascertained for phage and bacterial DNA measurements. The following parameters were determined by this simple technique. The DNA content of dividing cells of Bacillus subtilis 168/2 was 2.65 times higher than in resting cells. Assuming that resting cells harbor 1 genomic equivalent, its Mr was estimated to be 4.4 x 10(9) Da. A polymerization rate during growth of 788,000 bp min-1/cell is accounted for by a multifork replication mechanism. Both phage and host DNA could be measured accurately during the lytic cycle. Phage 2C DNA synthesis proceeded at a linear rate of 5.2 genome equivalents min-1.

Spectrofluorometry of dyes with DNAs of different base composition and conformation

The increase in fluorescence, upon interaction with several fluorescent dyes was found to depend on the base composition of DNA. 4',6-Diamidino-2-phenylindole-2 HCl and Hoechst 33258 which bind to AT base pairs show a logarithmic relation. This relation is linear when DNAs interact with mithramycin, chromomycin A3, and olivomycin, which bind to GC base pairs. Deviations from these relationships were observed for T2 DNA, containing hydroxymethylcytosine, and for 2C DNA, containing hydroxymethyluracil. On the basis of these data, a simple technique is proposed for determination of base composition. The presence of abnormal bases can be monitored by the use of given fluorophores. Fluorescence intensities were not modified upon linearization of covalently closed circular plasmid pBR322. Denaturation of lambda DNA was accompanied by a decrease of fluorescence, when complexed with the five dyes tested.

Cloning of DNA segments of phage 2C, which allows autonomous plasmid replication in Bacillus subtilis

The chromosome of Bacillus subtilis phage 2C is a 100-MDa double-stranded DNA molecule, containing hydroxymethyluracil in place of thymine and carrying redundant ends each encompassing 10% of the genome. 2C DNA was cleaved with EcoRI and HindIII, and cloned in the shuttle plasmids pSC 540 and pCP 115, both containing segments originating from B. subtilis and Escherichia coli plasmids. These chimaerical plasmids, carrying the chloramphenicol resistance gene, were unable to replicate in B. subtilis; this ability was restored, however, after the insertion of viral DNA segments. Physical maps of the recombinant plasmids were made; a large deletion of the E. coli-derived segment of pSC 540 was observed (which paralleled a loss of replication in this host), whereas addition of 2C DNA segments in pCP 115 was not accompanied by deletion (replication in E. coli was conserved in this case). Cloned viral segments mapped mostly, but not exclusively, within the redundant ends of 2C DNA. It is suggested that the thirteen recombinant clones carried the replication origin region of phage 2C DNA, and that these sequences originated within or close to the redundant extremities of the viral chromosome.

A microanalytical procedure for determination of the base composition of DNA

A new procedure for the determination of the percentage guanine plus cytosine (% G+C; mol/100 mol) values of microquantities of DNA is described. Its principle is a DNA-polymerase-I-directed nick translation of DNA in the presence of dGTP, dTTP, [3H]dCTP, and [alpha-32P]dATP. Kinetics experiments indicate that the plateau value is reached in about 20 min of incubation under our experimental conditions. Percentage G+C is obtained from the linear relation 1/(% G+C) = 0.01 K [32P]/[3H] + 0.01, where the ratio of trichloroacetic-acid-precipitable radioactivity is taken into account, the K value being determined for each experiment by using a few reference DNAs of known composition. This procedure has proven suitable for analysis of plasmidic, viral and cellular DNAs of different base composition (25-75% G+C), shape (linear and circular double-stranded DNA) and size (100-150 000 base pairs). Usual methods for % G+C analysis (buoyant density and melting temperature determinations) yield unreliable results in the presence of either modified or unusual bases: the double-labeling procedure is still valid under these conditions. The latter is, therefore, the method of choice for analysis or rare DNA species which are available in very small quantities (it requires amounts of DNA as low as 1 ng, i.e. several order of magnitude lower than those used for chromatographic analysis of DNA hydrolysates). Since the obtention of highly purified DNA is an essential prerequisite for the double-labeling procedure, a method for purification of bacterial DNA is detailed in the present work.

Inhibitory action of virginiamycin components on cell-free systems for polypeptide formation from Bacillus subtilis

Although virginiamycin components VM and VS are known to exert in vivo a synergistic inhibition of bacterial growth and viability, in cell-free systems only VM has proven active. In the present work, the in vivo and in vitro activities of VM and VS on Bacillus subtilis have been compared. Peptide formation in homogenates of bacteria previously incubated with either VM or VS was found strongly repressed; the 2 components acted synergistically. Ribosomes were fully responsible for this effect, as shown by mixed reconstitution experiments. On the other hand, cytoplasm from control bacteria disrupted in 10 mM Mg2+ buffer was refractory to in vitro inhibition by virginiamycin, whereas ribosomes prepared in 1 mM Mg2+ were sensitive to VM. VS was inactive on poly(U)-directed poly(phenylalanine) formation, and displayed some activity on the poly(A)-poly(lysine) system. In a cell-free system from Bacillus subtilis infected with phage 2C, both VM and VS were active and blocked synergistically protein synthesis in vitro. When the host cells were incubated with VS and the corresponding homogenate was then treated with VM, a complete inhibition of protein synthesis was observed. The present work, thus, describes the techniques for investigating the in vivo and in vitro action of synergimycins on the same organism, and for reproducing in vitro the synergistic interaction of type A and B components previously observed only in vivo.

Comparison of the physical maps and redundant ends of the chromosomes of phages 2C, SP01, SP82 and phi e

The physical map of 2C DNA (cf. following paper in this journal) was compared to the maps of SP01, SP82 and phi e (three other Bacillus subtilis phages containing hydroxymethyluracil in place of thymine in their DNA). The overall organization of the four genomes was remarkably similar, as indicated by the topology of HaeIII and SalI cleavage segments. The proof was gathered for the presence in the four phage DNAs of large redundant ends carrying a single HaeIII recognition site. The location of the latter proved identical for 2C and SP01, but was shifted in the DNAs of SP82 and phi e. Since the redundant end components of these hydroxymethyluracil genomes are colinear, as shown by cross-hybridization studies, the shifting of the HaeIII cleavage site is presumably due to two base substitutions, suppressing an endonuclease recognition site and establishing a new site elsewhere. Relatedness between the genomes of this family of viruses was evaluated from the fraction of conserved restriction fragments. According to these calculations, 6% base substitutions have occurred within the four viral DNAs, in the course of evolution. However, specific segments of 2C DNA were not present in SP01 and phi e DNA, as shown by cross-hybridization with restriction fragments. These data indicate the occurrence of deletions, in addition to base substitutions, as evolutionary mechanisms prevailing in the genomes of this family of phages.

Physical map of phage 2 C DNA: evidence for the existence of large redundant ends

The chromosome of the Bacillus subtilis phage 2C, a linear molecule of double-stranded DNA of about 10(8) Da, in which thymine is completely replaced by hydroxymethyluracil, was cleaved by different endonucleases. In some cases restriction segments were much fewer than expected, suggesting a possible interference of the unusual base with the recognition mechanism of endonucleases. The physical map of 2C DNA was established by use of SalI and HaeIII restriction endonucleases, which yielded a limited number of fragments. The expected number of fragments was 240 for HaeIII and 23 for SalI; in reality, five segments were observed upon cleavage with HaeIII and four with SalI. The terminal fragments of the genome were first identified; the other fragments were ordered by hybridization and molecular weight determination of restriction fragments obtained by cleavage with the two endonucleases. In addition, hybridization of restriction fragments showed the presence of homologous regions at the ends of the 2C genome. The structure of these direct repetitive sequences was analyzed by cleavage with HaeIII and hybridization with EcoRI restriction fragments. Their size (9.2 MDa) was found to be about 1/11 of that of the whole chromosome.

Antibiotics of the virginiamycin family, inhibitors which contain synergistic components

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