Fractionation of native and denatured transforming deoxyribonucleic acid from Bacillus subtilis

1. Native DNA from Bacillus subtilis was fractionated by stepwise elution from methylated albumin, the transforming activity being confined to two out of four fractions. Partial separation of DNA active in transformation for the arginine marker from that showing activity for the histidine and tryptophan markers was achieved. 2. Partial denaturation of DNA at 90 degrees and 93.5 degrees resulted in the preferential destruction of transforming activity for the histidine and tryptophan markers. 3. Denaturation of DNA at 100 degrees followed by chromatography on methylated albumin yielded five fractions, two of which exhibited residual activity. Redenaturation at 100 degrees resulted in the interconversion of four out of the five fractions. Redenaturation of fractions labelled with (15)N and (2)H suggested the presence of a specific component that did not readily take part in the interconversions.     

Transformation in Bacillus subtilis. Fate of newly introduced transforming DNA

Summary Donor deoxyribonucleic acid (molecular weight 5-8×10⁷) introduced into competent cells of Bacillus subtilis is converted to molecules with a weight average molecular weight of 9×10⁶. These molecules, having little transforming activity, constitute in all probability eclipse phase DNA. At least part of the DNA is transiently complexed with a cellular component, changing its buoyant behaviour in CsCl gradients. When shortly after uptake of donor DNA the total DNA extracted from recipient cells is sheared to a molecular weight of 8×10⁶ or less, no eclipse phase is discernable. Donor marker frequencies in sheared, reisolated DNA mixtures decrease by a factor of 4 as a function of time of incubation of the transforming cells. This indicates that only 25% of the irreversibly absorbed DNA is finally integrated into the recipient genome.     

The initial attachment of transforming DNA to competent Bacillus subtilis.

Summary The initial attachment of transforming DNA to competent Bacillus subtilis is temperature independent between 25° and 45°. However, below 15° there is a significant reduction in the amount of DNA attached to competent cells. The DNA that is attached at 4° can lead to transformation or interfere effectively with the subsequent attachment of a distinctive DNA when the cells are shifted to a permissive temperature (37°). These data suggest that the attachment of DNA at 4° is to sites normally involved in the transformation process. The amount of DNA that is initially attached to the bacteria at 4° or 37° after perturbation of the cells by ionic strength changes, repetitive washings, or periodate oxidation varies with the temperature at which the treatment occurs. These results are consistent with a reorientation of the DNA attachment sites upon lowering the temperature to 4°, such that their affinity for DNA and susceptibility inhibitory treatments are reduced.National Institutes of Health Research Career Program Awardee, CA-K3-6487 during a portion of this investigation.     

An endonuclease activity in Bacillus subtilis specific for UV-irradiated DNA

An enzyme activity specific for UV-DNA¹ was found in the extract of $\text{Bacillus subtilis}$(Marburg 168). The enzyme preparation obtained from the extract by ammonium sulfate precipitation acts on UV-DNA endonucleolytically and induces single strand breaks. The number of single strand breaks introduced in DNA is proportional to UV dose.     

一种快速有效的枯草芽孢杆菌染色体的提取方法

枯草芽孢杆菌的膜,壁结构较为特殊,且外分泌酶活力较高,这些给染色体的提取造成一定的困难。根据多次提取枯草芽孢杆菌染色体DNA的经验并参考文献^[1-3],改进后得到一种快速有效的提取枯草芽孢杆菌染色体DNA的方法,这一方法为研究枯草芽孢杆菌染色体DNA,构建基因文库及利用PCR方法调取某个基因提供了坚实的基础。     

Multispecific DNA methyltransferases from Bacillus subtilis phages. Properties of wild-type and various mutant enzymes with altered DNA affinity

Temperate Bacillus subtilis phages SPR, phi 3T, rho 11 and SP beta code for DNA methyltransferases, each having multiple sequence specificities. The SPR wild-type and various mutant methyltransferases were overproduced 1000-fold in Escherichia coli and were purified by three consecutive chromatographic steps. The stable form of these multispecific enzymes in solution are monomers with a relative molecular mass (Mr) of about 50,000. The methyl-transfer kinetics of the SPR wild-type and mutant enzymes were determined with DNA substrates carrying either none or one of the three recognition sequences (GGCC, CCGG, CCATGG). Evaluation of the catalytic properties for DNA and S-adenosylmethionine binding suggested that the NH2-terminal part of the protein is important for both non-sequence-specific DNA binding and S-adenosylmethionine binding as well as transfer of methyl groups. On the other hand, mutations in the COOH-terminal part lead to weaker site-specific interactions of the enzyme. Antibodies raised against the purified SPR enzyme specifically immunoprecipitated the phi 3T, rho 11 and SP beta methyltransferases, bu failed to precipitate the chromosomally coded enzymes from B. subtilis (BsuRI) and B. sphaericus (BspRI). Immunoaffinity chromatography is an efficient purification step for the related phage methyltransferases.