Direct plasmid transfer from replica-plated E. coli colonies to competent B. subtilis cells. Identification of an E. coli clone carrying the hisH and tyrA genes of B. subtilis.

We have cloned the hisH tyrA wild-type genes of Bacillus subtilis with the aid of the chimeric plasmid pBJ194, which replicates both in B. subtilis and Escherichia coli. Primary cloning was done in E. coli. The original E. coli clone, carrying the recombinant plasmid (pGR1) which complements hisH tyrA mutants of B. subtilis, was selected directly from a mixture of plated E. coli clones by replicaplating these clones onto minimal agar plates without tyrosine, spread just before with competent B. subtilis cells. After overnight incubation clusters of small colonies had developed exclusively in the E. coli [pGR1] colony prints. The Tyr+ minicolonies were shown to be B. subtilis carrying pGR1 because (i) their appearance depended linearly on the number of B. subtilis cells plated, (ii) they produced extracellular protease and amylase and (iii) plasmids could be reisolated from the minicolonies and used to transform B. subtilis recE4 tyrA1 both to Cmr and Tyr+. Plasmid pGR1 transfer through replica plating was compared with plasmid transfer in liquid. Both systems depended on transformable B. subtilis strains and were sensitive to DNAseI. However, whereas integration of the tyrA+ gene into the chromosome and concomitant loss of plasmids occurred frequently during regular plasmid transformation of Rec+ B. subtilis, this was a rare event during plasmid transfer through replica plating.

Involvement of single-strand breaks in complex formation between single-stranded DNA and nucleoids of Bacillus subtilis.

RNase-unfolded chromosomes of competent Bacillus subtilis are able to take up single-stranded homologous donor DNA fragments in vitro to form donor-recipient DNA complexes (Van Randen and Venema 1981). The unfolded chromosomes behave as supercoiled DNA molecules. X-irradiation increased the formation of unstable and stable complexes between donor and recipient DNA during incubation at 37 degrees C. The complex-forming ability of the unfolded chromosomes increased linearly with increasing X-ray dose, even after complete relaxation of the unfolded chromosomes had occurred. Limited DNase I action increased the complex-forming ability of the chromosomes as effectively as X-irradiation. Unstable donor-recipient DNA complexes can be distinguished from stable ones by their dissociation upon density gradient centrifugation in CsCl at pH 11.2. They are stable at pH 10 (Van Randen et al. 1982a). At an intermediate pH value during isopycnic centrifugation, a fraction of the unstable complexes were stable, suggesting that a range of stabilities existed among the unstable complexes. The donor moiety of the stable donor-recipient DNA complexes was far more resistant to nuclease S1 treatment than that of the unstable ones.

Effect of 4,5',8-trimethylpsoralen interstrand cross-links present in recipient Bacillus subtilis on the integration of transforming DNA.

When recipient Bacillus subtilis carrying chromosomal trimethylpsoralen cross-links were transformed, the donor marker activity decreased with the extent of cross-linking. Additional donor marker activity was lost upon incubation of the reextracted DNA with nuclease S1, particularly at higher levels of cross-linking. Physical analysis of the reextracted DNA showed that the donor DNA was progressively excluded from heteroduplex formation as the frequency of cross-links in the recipient DNA increased. In the donor-recipient complexes still being formed, increasing amounts of donor DNA became susceptible to nuclease S1 digestion under these conditions. These results suggest that resident interstrand cross-links interfere both with initiation of recombination and with the completion of heteroduplex formation.

Unstable association in vitro between donor and recipient DNA in Bacillus subtilis.

In addition to stable donor-recipient DNA complexes, unstable complexes between donor and recipient DNA were formed in vitro with Bacillus subtilis. Whereas the stable complexes survived CsCl gradient centrifugation at pH 11.2 and phenol plus sodium p-aminosalicylate extraction with 0.17 M NaCl, the unstable complexes dissociated during these manipulations. The donor moiety from the unstable complexes remained associated with the recipient DNA during phenol plus sodium p-aminosalicylate treatment at 0.85 M NaCl. The unstable complexes could be stabilized artificially by cross-linking with 4,5',8-trimethylpsoralen. Dissociation of the complexes during CsCl gradient centrifugation could be prevented by centrifuging at pH 10. Heterologous DNA fragments derived from phage H1 DNA appeared to be unable to form complexes with the recipient B. subtilis DNA. Unstable complexes were also formed with Escherichia coli DNA, although under all conditions tested, more complex was detectable by using homologous B. subtilis DNA.

Initiation of recombination during transformation of Bacillus subtilis requires no extensive homologous sequences.

Lysates obtained shortly after entry of transforming DNA to Bacillus subtilis contain donor-recipient DNA complexes, in which the donor moiety is associated with the recipient DNA in an unstable way. The complexes could be artificially stabilized by crosslinking with 4,5',8-trimethylpsoralen. The unstable complexes dissociated upon helix-destabilizing treatments, such as heating at 70 degrees C, and CsCl gradient centrifugation at pH 11.2, but remained stable during CsCl gradient centrifugation at pH 10. Donor-recipient DNA complexes were not formed after entry of heterologous pUB110 DNA. These observations suggest that base-pairing is involved in the unstable association. The donor moiety of the unstable complexes was completely, or almost completely, digestible by nuclease S1, indicating that the donor and recipient base-sequences are only paired over very short distances. The unstable donor-recipient DNA complexes are true recombination intermediates because (i) strain 7G224 (recE4) was impaired in the formation of the unstable complexes, and (ii) the unstable complexes were rapidly converted to stable complexes in recombination proficient strains, whereas their conversion was delayed in the recombination deficient strain 7G84. Unstable complexes were also formed with Escherichia coli donor DNA, but to a lesser extent. Apparently a limited degree of base-sequence homology is sufficient to initiate recombination.

Assimilation of single-stranded donor deoxyribonucleic acid fragments by nucleoids of competent cultures of Bacillus subtilis.

Lysates containing folded chromosomes of competent Bacillus subtilis were prepared. The chromosomes were supercoiled, as indicated by the biphasic response of their sedimentation rates to increasing concentrations of ethidium bromide. Limited incubation of the lysates with increasing concentrations of ribonucleases resulted in a gradual decrease in the sedimentation velocity of the deoxyribonucleic acid (DNA) until finally a constant S value was reached. Incubation with sonicated, 4,5',8-trimethylpsoralen-monoadducted, denatured, homologous donor DNA molecules at 37 degrees C and concomitant irradiation with long-wave ultraviolet light of the nucleoid-containing lysates resulted in the formation of complexes of the donor DNA molecules and the recipient chromosomes. This complex formation was stimulated when nucleoids were previously (i) unfolded by ribonuclease incubation, (ii) (partially) relaxed by X irradiation, or (iii) subjected to both treatments. Monoadducts were not essential. On the other hand, the complex-forming capacity of recipient chromosomes previously cross-linked by 4,5',8-trimethylpsoralen diadducts was greatly reduced, suggesting that strand separation of the recipient molecule was involved in the formation of the complex. None of these effects has been observed when heterologous (Escherichia coli) donor DNA has been used. When the same kind of experiments were carried out at 70 degrees C, donor-recipient DNA complexes were also formed and required strand separation and homology similar to donor-recipient complex formation at 37 degrees C. However, in contrast to what was found at 37 degrees C, unfolding plus relaxation of the nucleoids, as well as the absence of monoadducts in the donor DNA fragments, resulted in a decrease in complex formation. On the basis of these results, we assume that superhelicity can promote the in vitro assimilation of single-stranded donor DNA fragments by nucleoids of competents B. subtilis cells at 70 degrees C, but that at 37 degrees C a different mechanism is involved.