Characterization of a naturally occurring, cross-linked fraction of DNA. II. Origin of the cross-linkage

Defective Bacteriophage PBSH in Bacillus subtilis: III. Properties of Adenine-16 Marker in Purified Bacteriophage Deoxyribonucleic Acid

The adenine-16 (ade-16) marker (the marker nearest the chromosomal origin of Bacillus subtilis) in purified PBSH deoxyribonucleic acid (DNA) renatured more rapidly and to a greater extent than any other marker in the phage DNA, and more rapidly and to a greater extent than all markers, including ade-16, in bacterial DNA. The renaturation of the phage DNA ade-16 marker followed a first-order reaction, whereas renaturation of bacterial markers was initially a second-order reaction. No cross-linkages were detected in DNA molecules containing the ade-16 marker. Buoyant density measurements and inactivation by heat and micrococcal deoxyribonuclease of the ade-16 marker did not reveal large segments of clusters of the individual bases in these molecules. Alternative mechanisms for the unique renaturation behavior of the ade-16 marker are discussed.

The mode of action of cytotoxic and antitumor 1-nitroacridines. III. In vivo interstrand cross-linking of DNA of mammalian or bacterial cells by 1-nitroacridines

To define a critical lesion in presumable target DNA cause in vivo by the antitumor and cytotoxic 1-nitroacridines, Ehrlich ascites tumor (Eat) cells implanted into mice, HeLa cells grown in monolayer culture or Bacillus subtilis SB 1058 strain cells were exposed to Ledakrin [Nitracrine; 1-nitro-9-(3'-dimethylamino-n-propylamino)acridine], its non-antitumor congeners, or mitomycin C tested for comparison; total intracellular DNA was isolated from control or treated cells and denatured by heat, alkali or formamide, after which the chemically-induced fraction of interstrand cross-linked DNA molecules was assessed by thermal denaturation-renaturation curve analysis, hydroxylapatite column chromatography, or partitioning in a Dextran T500-polyethylene glycol 6000 biphasic system. Ledakrin, as compared to mitomycin C, was a very effective cross-linking agent, inducing one covalent cross-link per approx. 20 X 10(3) (B. subtilis), 56 X 10(3) (HeLa) or 80 X 10(3) (Eat) DNA base pairs. The first cross-links were introduced in B. subtilis cell genomes at minimal bactericidal concentrations of Ledakrin of mitomycin C. Ledakrin failed to induce discernible cross-linking of bihelical DNA when complexed with in cell-free system. Unlike the other two 1-nitroacridines which cross-linked DNA of cultured HeLa or B. subtilis cells, the non-antitumor 2-, 3- or 4-nitroacridines did not cause such effect and diminished cross-linking by Ledakrin or mitomycin C. Hence, upon metabolic activation in mammalian or bacterial cell Ledakrin and, most probably other 1-nitroacridines, become very effective DNA cross-linking agents and such effects appear to be responsible for the antitumor and potent cytotoxic activities of 1-nitroacridines.

Unstable high molecular weight inverted repetitive DNA in human lymphocytes

About 1% of newly synthesized DNA from PHA-stimulated human lymphocytes can be isolated as large (up to 90 kilobase pairs) double stranded fragments that resist sequential alkali and heat denaturation steps but are not closed circular. By electron microscopy about 1% have single-strand hairpin loops at one end and therefore present inverted repetitive sequences (IR-DNA). Most of the remainder have a blunt-appearing double-strand terminus at both ends (78%) or one end (18%). Indirect evidence indicates that these also are inverted complementary structures with terminal hairpin loops too small to be visualized: (1) Treatment with either a 5' or 3' single-strand exonuclease generates essentially only fragments with a single strand at one end; (2) with partial denaturation, the number of fragments with identifiable single-strand hairpin loops increases (to about 20%); (3) after S1 nuclease digestion, greater than 95% can be fully heat denatured. Cot analysis indicates that these fragments are derived from dispersed sites throughout the genome. Up to 25% of DNA released from lymphocytes during growth similarly resists denaturation, and released DNA and IR-DNA are both enriched in the same set of repetitive sequences. Thus at least a portion of IR-DNA appears to be unstable.

Transformation in Bacillus subtilis with nitrogen mustard crosslinked DNA. Effect on cotransformation and mutation frequencies

Bacillus subtilis DNA was treated in vitro with nitrogen mustard and the crosslinked molecules were purified, after alkali denaturation, by hydroxyapatite chromatography. When tested for the ability to transform the trpC2-hisB2 segment, these molecules exhibited a decrease in the cotransformation index (r) as compared to native or renatured DNA. The decrease in r was not accompanied by an increase in mutagenicity.

Naturally occurring cross-links in yeast chromosomal DNA

Chromosome-size yeast DNA molecules with a number average molecular weight (Mn) of 3-4 X 10(8) were isolated from sucrose gradients after sedimentation of lysed yeast spheroplasts. Resedimentation showed that the molecules were isolated without introducing appreciable single-strand or double-strand breaks. The presence of cross-links in these molecules was suggested by the observation that the apparent Mn in alkali was greater than expected for separated single strands. Since cross-linked molecules would have strands which fail to separate upon denaturation, this was tested more directly. Neutralization of alkaline denaturing conditions resulted in up to 70% of the intact molecules rapidly reforming duplex structures, as shown by equilibrium banding in CsCI. Experiments with larger E. coli DNA molecules (Mn = 5.2 X 10(8)) indicated that the conditions used were sufficient to denature completely molecules of this size. Results of enzyme treatments suggest that the cross-links are not RNA or protein. Experiments with density-labeled yeast DNA molecules showed that the rapid reformation of duplex DNA is not the consequence either of a bimolecular reaction between separated DNA strands or of intrastrand renaturation. The data indicate that when the yeast DNA molecules are completely denatured, the strands fail to separate. Hence they must be cross-linked. Experiments with sheared DNA show that there are small number of cross-links, one to four, permolecule.

Structure of Caulobacter deoxyribonucleic acid

The deoxyribonucleic acid of the dimorphic bacterium Caulobacter crescentus contains a component that renatures with rapid, unimolecular kinetics. This component was present in both swarmer and stalked cells and exhibited the sensitivity to endonuclease S1 expected for hairpin loops. Double-stranded side branches between 100 and 600 nucleotide pairs in length were visible in electron micrographs of rapidly reassociating deoxyribonucleic acid isolated by hydroxyapatite chromatography. No extrachromosomal elements were found in spite of systematic attempts to detect their presence. These results indicate that the rapidly reassociating fraction derives from inverted repeat sequences within the chromosome and not from cross-links or plasmids. We estimate that there are approximately 350 inverted repeat regions per Caulobacter genome. The kinetic complexity of Caulobacter deoxyribonucleic acid, however, is no greater than that of other bacteria.

A study of foldback DNA

Nuclear DNA from eucaryotes contains a significant fraction which forms duplexes very rapidly and also independently of the DNA concentration. This fraction can be isolated by adsorption to hydroxylapatite and has been called foldback DNA (Britten and Smith, 1970). Here we extend previous studies to show that the foldback fraction is due to the existence of a finite number of foldback foci in each genome equivalent of DNA, approximately 10(5) in the case of Xenopus laevis. More significantly, we have isolated the foldback fraction in quantity from DNA of such a size (in one case broken randomly and in another digested with a restriction endonuclease) that only about 10% of the total DNA has foldback properties. If the foldback foci were located in precisely the same positions in all sets of the Xenopus laevis genome, the prediction would be that these foldback fractions would contain sequences representing 20% (random shear) and 10% (restriction endonuclease) of the total genome. In contrast, our results show that in both cases the foldback fraction contains the entire Xenopus laevis DNA sequence. One possible explanation of these observations is that as in procaryotes, eucaryotic DNA is randomly cross-linked. We show that cross-linkage of Xenopus laevis DNA is not sufficient to explain our observations. In consequence, we have adopted the hypothesis that the formation of foldback DNA is mainly an intrastrand phenomenon, but nevertheless occurs at different sites in different sets of the Xenopus laevis genome.

Molecular nature of mammalian cell DNA in alkaline sucrose gradients

Mammalian cell DNA that exhibited anomalous sedimentation in alkaline sucrose gradients was examined directly by electron microscopy. Its appearance was that of duplex DNA. In addition, some duplex DNA was observed under conditions in which the sedimentation anomaly was no longer apparent. Persistence of double-stranded DNA under denaturing conditions suggests caution in the interpretation of changes in the molecular weight or conformation of DNA based solely on analysis of sedimentation profiles.

Hydroxyapatite chromatography and formamide denaturation of adenovirus DNA

Denatured adenovirus DNA was retained by hydroxyapatite columns under conditions generally used for selective retention of double-stranded DNA, probably due to several partially complementary sequences within single-stranded DNA. It was found that addition of formamide reduced the fraction of sonically treated, denatured adenovirus DNA bound to hydroxyapatite from about 30% to less than 1%. This led to a study of the effect of formamide on the melting temperature (T(m)) of double-stranded DNA in solution or bound to hydroxyapatite. The T(m) of DNA decreases 0.56 C/1% formamide, a value determined in buffered solutions with purified formamide.

Chromatographically fractionated complementary strands of Bacillus subtilis deoxyribonucleic acid: biological properties

Biological, physical, and chromatographic properties of methylated albuminkieselguhr (MAK)-fractionated complementary strands, designated as light (L) and heavy (H), of Bacillus subtilis deoxyribonucleic acid (DNA) are presented. The pattern of transforming activity along the MAK elution profile of alkilidenatured DNA shows that the residually active molecules selectively fractionated ahead of the L strand fraction, whereas the most active self-annealed molecules fractionated preferentially at the trailing end of the H strand fraction. The restoration rate of transforming activity in the late-eluting H molecules was rapid and independent of concentration during the annealing reaction. The data suggest that the self-annealing activity in the H strand is due in part to the formation of intrastrand secondary structures. Hydroxyapatite chromatography of self-annealed L and H strands yielded a major fraction (I) of highly purified strand preparations devoid of transforming activity and hypochromicity, and a minor "nativelike" fraction (II). Sedimentation velocity measurements show that, in addition to the mutual complementary nature of the L and H fractions, they differ in molecular size and possibly configuration.

Natural occurrence of cross-linked vaccinia virus deoxyribonucleic acid

The molecular weight of native vaccinia deoxyribonucleic acid (DNA) is 1 to 1.17 times that of native T4 DNA. Sedimentation of denatured vaccinia DNA through alkaline sucrose gradients yields an apparent molecular weight greater than twice that of denatured T4 DNA, implying that the complementary strands of vaccinia DNA do not separate upon denaturation. When alkali-denatured vaccinia DNA is neutralized, it has the physical chemical properties of native DNA when tested by sedimentation through neutral sucrose gradients, banding in CsCl, and by hydroxylapatite chromatography. We conclude that almost all mature vaccinia DNA molecules contain a small number of naturally occurring cross-links.

Kinetic and spectrophotometric studies on the renaturation of deoxyribonucleic acid

The kinetics of the renaturation of Escherichia coli DNA in 0.4-1.0m-sodium chloride at temperatures from 60 degrees to 90 degrees have been studied. The extent of renaturation was a maximum at 65 degrees to 75 degrees and increased with ionic strength, and the rate constant increased with both ionic strength and temperature. The energy and entropy of activation of renaturation were calculated to be 6-7kcal.mole(-1) and -40cal.deg.(-1)mole(-1) respectively. It has been shown that renaturation is a second-order process for 5hr. under most conditions. The results are consistent with a reaction in which the rate-controlling step is the diffusion together of two separated complementary DNA strands and the formation of a nucleus of base pairs between them. The kinetics of the renaturation of T7-phage DNA and Bordetella pertussis DNA have also been studied, and their rates of renaturation related quantitatively to the relative heterogeneity of the DNA samples. By analysis of the spectra of DNA at different stages during renaturation it was shown that initially the renatured DNA was rich in guanine-cytosine base pairs and non-random in base sequence, but that, as equilibrium was approached, the renatured DNA gradually resembled native DNA more closely. The rate constant for the renaturation of guanine-cytosine base pairs was slightly higher than for adenine-thymine base pairs.