K Wiersma scite author profile

In DNA binding-deficient mutants of Bacillus subtilis a competence-specific protein with a subunit molecular weight of 18,000 was absent. The native protein containing this subunit was purified from B. subtilis membranes by chromatography on hydroxyapatite, DEAE-cellulose, and Sephacryl S-200. This protein appeared to be complexed with a second protein of slightly lower molecular weight (17,000) and a different isoelectric point. The native protein complex (apparent molecular weight, 75,000) contained approximately equal amounts of the two polypeptides and showed a strong DNA-binding activity. Incubation of the complex with plasmid and bacteriophage DNA revealed nuclease activity, specifically directed toward double-stranded DNA. Predominantly single-stranded nicks and a limited number of double-stranded breaks were introduced in the presence of Mg2+ ions. In the presence of Mn2+ ions the complex produced low-molecular-weight breakdown products from the DNA.

Transformation in Bacillus subtilis: a 75,000-dalton protein complex is involved in binding and entry of donor DNA

Smith¹,

Wiersma²,

Venema³

et al. 1984

A 75,000-dalton protein complex involved in DNA binding during transformation was purified from membranes of competent Bacillus subtilis cells. Previous results (Smith et al., J. Bacteriol. 156:101-108, 1983) showed that the complex contained two polypeptides, polypeptide a (molecular weight, 18,000; isoelectric point, 5.0) and polypeptide b (molecular weight, 17,000; isoelectric point, 4.7) in approximately equal amounts. In the present experiments the two polypeptides were extracted from two-dimensional gels and studied separately and in combination with respect to DNA binding and nuclease activities. For DNA binding the interaction of both polypeptides was required. DNA binding occurred efficiently in the presence of EDTA. Nuclease activity was restricted to polypeptide b. The nucleolytic properties of b were identical to those of the native 75,000-dalton complex. Polypeptide a affected b by reducing its nuclease activity. Analysis of the nuclease subunit b on DNA-containing polyacrylamide gels revealed nuclease activities at four different molecular weight positions. These activities were identical to the major competence-specific nuclease activities which were previously implicated in the entry of donor DNA during transformation (Mulder and Venema, J. Bacteriol. 152:166-174, 1982). These results indicate that the 75,000-dalton protein complex is composed of two different competence-specific polypeptides involved in both binding and entry of donor DNA. The possible roles of the two polypeptides in the transformation of B. subtilis are discussed.

Transformation in Bacillus subtilis: further characterization of a 75,000-dalton protein complex involved in binding and entry of donor DNA

Smith¹,

Wiersma²,

Venema³

et al. 1985

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

Randen¹,

Wiersma²,

Venema³

1982

Mol Gen Genet

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.

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

Randen¹,

Wiersma²,

Venema³

1982

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.