Radial migration of DNA molecules in cylindrical flow. II. The non-draining model and possible application to fractionation

The radial-migration calculation of the preceding paper is extended to the non-draining polymer. The results show an inward radial velocity that depends on the 5/2 power of the molecular weight, assuming gaussian statistics for the chain. This sensitivity to size serves as the basis for a method of separating DNA molecules in solution according to their size. Normal stress (Weissenberg) effects are also discussed.     

Separation of Different Conformations of Plant Mitochondrial DNA Molecules by Field Inversion Gel Electrophoresis

Mitochondrial (mt) DNA structure in higher plants is still unclear as to the circularity or linearity of the genome. We have developed a system to electrophoretically separate distinct populations of mtDNA, with some populations enriched for networked linear and circular DNA molecules. Using field inversion gel electrophoresis (FIGE) and electron microscopy (EM), we have identified four distinct populations of mtDNA from two Brassica species. Using FIGE, two slow migrating mtDNA populations ran faster than a 66 kbp Escherichia coli circular plasmid marker, while these same populations comigrated in the compression zone in contour-clamped homogeneous electrophoretic field (CHEF) gels. A fast-migrating mtDNA population was also resolved by FIGE as a diffuse band between 20 to 70 kbp when compared with linear lambda () markers. FIGE resolved the 66 kbp circular marker into several multimers, while CHEF resolved only open-circular monomers and linears. In agreement with FIGE results, EM analysis indicated the two slow migrating mtDNA populations contained circular (both supercoiled and relaxed circles) and free linear molecules of 10-60 kbp, and networked linear molecules of 45–140 kbp total size that may represent recombination intermediates. The fast migrating population consisted of 10–50 kbp linear molecules. Well-bound mtDNA showed only long linear molecules of 40–150 kbp with no detection of circles or complex/rosette molecules. This report shows that FIGE has clear advantages over CHEF for separating large DNA molecules with different conformations, and may be very useful for studies to characterize genome structure in complex systems such as plant mitochondria.     

Rotor speed dependent sedimentation of circular and linear DNA.

The sedimentation rate of large, linear DNA molecules has been shown to be rotor speed dependent (Rubenstein and Leighton, Biophys. Chem. 1 (1974)). In this communication we report the first studies designed to measure the rotor speed effect with a homogenous, linear viral DNA larger than bacteriophage T2 DNA. We also report the first studies using a homogenous, circular episomal DNA of known molecular weight. For this circular DNA a small rotor speed effect, previously unsuspected, was discovered.     

Rotor speed dependent sedimentation of circular and linear DNA

The sedimentation rate of large, linear DNA molecules has been shown to be rotor speed dependent (Rubenstein and Leighton, Biophys. Chem. 1 (1974)). In this communication we report the first studies designed to measure the rotor speed effect with a homogenous, linear viral DNA larger than bacteriophage T2 DNA. We also report the first studies using a homogenous, circular episomal DNA of known molecular weight. For this circular DNA a small rotor speed effect, previously unsuspected, was discovered.     

Linearization of donor DNA during plasmid transformation in Neisseria gonorrhoeae.

We examined the fate of plasmid DNA after uptake during transformation in Neisseria gonorrhoeae. An 11.5-kilobase plasmid, pFA10, was processed to linear double-stranded DNA during uptake by competent cells, but cleavage of pFA10 was not site specific. A minority of pFA10 entered as open circles. A 42-kilobase plasmid, pFA14, was degraded into small fragments during uptake; no intracellular circular forms of pFA14 were evident. Since pFA10 DNA linearized by a restriction enzyme was not further cut during uptake, the endonucleolytic activity associated with entry of plasmid DNA appeared to act preferentially on circular DNA. Although linear plasmid DNA was taken up into a DNase-resistant state as efficiently as circular DNA, linear plasmid DNA transformed much less efficiently than circular plasmid DNA. These data suggest that during entry transforming plasmid DNA often is processed to double-stranded linear molecules; transformants may arise when some molecules are repaired to form circles. Occasional molecules which enter as intact circles may also lead to transformants.     

Sedimentation velocity properties of catenated DNA molecules from HeLa cell mitochondria

Catenated molecules of closed circular DNA have been isolated from the mitochondrial DNA of HeLs cells. The sedimentation coefficients of several purified species have been investigated. The catenated dimer, made up of two interlocked duplex circles, sediments at 51 S in its superhelical (closed) form. Treatment with pancreatic DNase to relax the duplex circles converts the 51 S doubly closed dimer to a 42 S singly open species, then to a 36 S doubly open catenated dimer. The triply closed trimer sediments at 63 S and is converted to a 45 S triply open form by DNase. Electron microscopy of the DNA samples before and after DNase treatment shows that under the conditions used DNase does not change the catenated nature of the DNA. The measured sedimentation coefficients, have been compared with those estimated from previously proposed correlations of sedimentation coefficient and molecular weight, and with the sedimentation coefficients for catenated DNA presented by Wang. When all the interlocked circles in a catenane are relaxed, the DNA sediments about 5–10% faster than a relaxed multiple-length circular molecule of the same molecular weight. The sedimentation coefficient, 36 S, of the fully relaxed catenated dimer is 1.4 times that of the relaxed monomer.     

Use of a Ring Chromosome and Pulsed-Field Gels to Study Interhomolog Recombination, Double-Strand DNA Breaks and Sister-Chromatid Exchange in Yeast

We describe a system that uses pulsed-field gels for the physical detection of recombinant DNA molecules, double-strand DNA breaks (DSB) and sister-chromatid exchange in the yeast Saccharomyces cerevisiae. The system makes use of a circular variant of chromosome III (Chr. III). Meiotic recombination between this ring chromosome and a linear homolog produces new molecules of sizes distinguishable on gels from either parental molecule. We demonstrate that these recombinant molecules are not present either in strains with two linear Chr. III molecules or in rad50 mutants, which are defective in meiotic recombination. In conjunction with the molecular endpoints, we present data on the timing of commitment to meiotic recombination scored genetically. We have used x-rays to linearize circular Chr. III, both to develop a sensitive method for measuring frequency of DSB and as a means of detecting double-sized circles originating in part from sister-chromatid exchange, which we find to be frequent during meiosis.     

Episomal Viral DNA in a Herpesvirus saimiri-Transformed Lymphoid Cell Line

The lymphoid cell line #1670 has been derived from the infiltrated spleen of a tumor-bearing marmoset monkey infected with Herpesvirus saimiri. The cells contain both types of H. saimiri DNA, unique light (L-) DNA (36% cytosine plus guanine) and repetitive heavy (H-) DNA (71% cytosine plus guanine), without producing infectious virus. Viral DNA was found to persist in these cells as nonintegrated circular DNA molecules. Closed circular superhelical viral DNA molecules were isolated by three subsequent centrifugation steps: (i) isopycnic centrifugation in CsCl, (ii) sedimentation through glycerol gradients, and (iii) equilibrium centrifugation in CsCl-ethidium bromide. The isolated circles had a molecular weight of 131.5 +/- 3.6 x 10(6). This is significantly higher than the molecular weight of linear DNA molecules isolated from purified H. saimiri virions (about 100 x 10(6)). Partial denaturation mapping of circular molecules from #1670 lymphoid cells showed uniform arrangement of H- and L-DNA sequences in all circles. All denatured molecules contained two L-DNA regions (molecular weights of 54.0 +/- 1.8 x 10(6) and 31.5 +/- 1.3 x 10(6)) and two H-DNA regions (molecular weight of 25.6 +/- 1.9 x 10(6) and 20.0 +/- 0.8 x 10(6)) of constant length. Maps of both L-regions suggested that the sequences of the shorter L-DNA region were a subset of those of the longer region. The sequences of both L-regions had the same orientation. Circular molecules from H. saimiri-transformed lymphoid cell line #1670 appeared to represent defective genomes, containing only 75% of the genetic information present in L-DNA of H. saimiri virions.     

Covalently closed circular duplex DNA of Epstein-Barr virus in a human lymphoid cell line.

A non-integrated form of Epstein-Barr virus DNA was purified from the Burkitt lymphoma-derived human lymphoid cell line Raji by CsCl density gradient centrifugation and neutral glycerol gradient centrifugation. This intracellular form of the virus DNA sediments at a rate typical of a covalently closed circular DNA molecule of the size of the virus genome in both neutral and alkaline solution. Treatment with low doses of X-rays leads to a discontinuous conversion of the molecules to a form with the sedimentation properties of open circular DNA (a circular duplex molecule containing one or more single-strand breaks). The direct observation of large circular DNA molecules by electron microscopy further confirms the covalently closed circular duplex structure of part of the intracellular viral DNA. Such circular molecules were not detected in corresponding DNA fractions from Epstein-Barr virus-negative human lymphoid cell lines. In ethidium bromide/CsCl density gradient centrifugation experiments, the purified non-integrated virus DNA behaves as twisted, covalently closed DNA circles with the same initial superhelix density as polyoma virus DNA. The latter additional purification technique permits the isolation of intracellular Epstein-Barr virus DNA in > 90% pure form from non-producer cells. The molecular weight of the circular virus DNA from Raji cells, determined by contour length measurements, is the same within experimental error as that of the linear DNA from virus particles.     

The effect of divalent cations on the mode of action of DNase I. The initial reaction products produced from covalently closed circular DNA

The effect of different divalent metal ions on the hydrolysis of DNA by DNase I was studied with an assay which distinguishes between cleavage of one or both strands of the DNA substrate during initial encounters between enzyme and DNA. Using covalently closed superhelical SV40(I) DNA as substrate, initial reaction products consisting of relaxed circles or unit-length linears are resolved by electrophoresis of radioactively labeled DNA in agarose gels. Only in the presence of a transition metal ion, such as Mn2+ or Co2+, and only under certain reaction conditions, is DNase I able to cut both DNA strands at or near the same point, generating unit-length linears. This ability to cut both DNA strands is inhibited by such factors as temperature decrease, the addition of a monovalent ion or another divalent cation which is not a transition metal ion, or a reduction in the number of superhelical turns in the DNA substrate. All of these factors lead to a winding of the duplex helix and antagonize the unwinding of the duplex promoted by transition metal ion binding. Transition metal ions may thus convert the DNA substrate locally to a form in which DNase I can introduce breaks into both strands. In the presence of Mg2+, DNase I introduces single strand nicks into SV40(I), generating exclusively the covalently open, relaxed circular SV40(II) as the initial product of the reaction. In the presence of Mn2+, DNase I generates as initial products a mixture of SV40(II) and unit-length SV40 linear DNA molecules, formed by two nicks in opposite strands at or near the same point in the duplex. These circular SV40(II) molecules consist of two types. A minority class is indistinguishable from the nicked SV40(II) produced by DNase I in the presence of Mg2+. The majority class consists of molecules containing a gap in one of the two strands, the mean length of the gap being 11 nucleotides. The SV40(L) molecules produced in the presence of Mn2+ appear to have single strand extensions at one or both ends.     

Most chloroplast DNA of maize seedlings in linear molecules with defined ends and branched forms

We used pulsed-field gel electrophoresis, restriction fragment mapping, and fluorescence microscopy of individual DNA molecules to analyze the structure of chloroplast DNA (cpDNA) from shoots of ten to 14 day old maize seedlings. We find that most of the cpDNA is in linear and complex branched forms, with only 3-4% as circles. We find the ends of linear genomic monomers and head-to-tail (h-t) concatemers within inverted repeat sequences (IRs) near probable origins of replication, not at random sites as expected from broken circles. Our results predict two major and three minor populations of linear molecules, each with different ends and putative origins of replication. Our mapping data predict equimolar populations of h-t linear concatemeric molecules differing only in the relative orientation (inversion) of the single copy regions. We show how recombination during replication can produce h-t linear concatemers containing an inversion of single copy sequences that has for 20 years been attributed to recombinational flipping between IRs in a circular chromosome. We propose that replication is initiated predominantly on linear, not circular, DNA, producing multi-genomic branched chromosomes and that most replication involves strand invasion of internal regions by the ends of linear molecules, rather than the generally accepted D-loop-to-theta mechanism. We speculate that if the minor amount of cpDNA in circular form is useful to the plant, its contribution to chloroplast function does not depend on the circularity of these cpDNA molecules.     

DNA of a Human Hepatitis B Virus Candidate

Particles containing DNA polymerase (Dane particles) were purified from the plasma of chronic carriers of hepatitis B antigen. After a DNA polymerase reaction with purified Dane particle preparations treated with Nonidet P-40 detergent, Dane particle core structures containing radioactive DNA product were isolated by sedimentation in a sucrose density gradient. The radioactive DNA was extracted with sodium dodecyl sulfate and isolated by band sedimentation in a preformed CsCl gradient. Examination of the radioactive DNA band by electron microscopy revealed exclusively circular double-stranded DNA molecules approximately 0.78 mum in length. Identical circular molecules were observed when DNA was isolated by a similar procedure from particles that had not undergone a DNA polymerase reaction. The molecules were completely degraded by DNase 1. When Dane particle core structures were treated with DNase 1 before DNA extraction, only 0.78-mum circular DNA molecules were detected. Without DNase treatment of core structures, linear molecules with lengths between 0.5 and 12 mum, in addition to the 0.78-mum circles were found. These results suggest that the 0.78-mum circular molecules were in a protected position within Dane particle cores and the linear molecules were not within core structures. Length measurements on 225 circular molecules revealed a mean length of 0.78 +/- 0.09 mum which would correspond to a molecular weight of around 1.6 x 10(6). The circular molecules probably serve as primer-template for the DNA polymerase reaction carried out by Dane particle cores. Thermal denaturation and buoyant density measurements on the Dane particle DNA polymerase reaction product revealed a guanosine plus cytosine content of 48 to 49%.     

Size of the intracellular circular Epstein-Barr virus DNA molecules in infectious mononucleosis-derived human lymphoid cell lines.

The size of non-integrated circular Epstein-Barr virus (EBV) DNA molecules isolated from seven different human lymphoblastoid cell lines of infectious mononucleosis origin has been determined by sedimentation analysis and by direct contour length measurements on electron micrographs. Six lines had intracellular circular EBV genomes of the same size as linear virion DNA molecules. The seventh line, established with the B95-8 strain of EBV, was the only one found to have circular EBV DNA molecules significantly smaller than virion DNA. The data show that intracellular EBV DNA circles of reduced size do not generally occur in infectious mononucleosis-derived cell lines.     

Identification of the site of interruption in relaxed circles producing during bacteriophage lambda DNA circle replication.

The DNA that accumulates in the lambda infection restricted to the early (circular) stage of replication consists of approximately two-thirds covalently closed circles and one-third relaxed circles bearing a single interruption in either strand of the duplex. The latter molecules are presumed to be a unique class in that the interruption is not repairable by DNA polymerase and ligase. Preferential radioisotopic labeling of the region immediately adjacent to the interruption, followed by hybridization to sheared fragments of the lambda chromosome with varying guanine plus cytosine content, suggested that the nick resides at the position of the mature molecular ends of the lambda chromosome. Digestion of the labeled molecules with restriction enzymes and reconstruction experiments in which Hershey circles were generated by annealing of interrupted strands isolated from the relaxed circles support this interpretation. The results indicate that the relaxed circles consist of a population containing one interruption in either of the two strands of the duplex jointly representing the two "nicks" contained in Hershey circles (in which the cohesive ends are annealed). These molecules could result from the inability of the maturation function to make the required staggered endonucleolytic cuts when the DNA substrate is a monomeric circle rather than a multimeric linear molecule. Alternatively, this interruption could be the result of an endonucleolytic cutting event critical to DNA replication.     

Sequence organization and expression of a yeast plasmid DNA.

Saccharomyces cerevisiae strain A364A D5 contains circular double-stranded DNA molecules of 6230 +/- 30 base pairs (2mu DNA) which are present in 68 copies per cell and make up 2.4% of the haploid genome. About 0.4% of non-poly A containing yeast RNA hybridizes to the yeast DNA circles. When denatured and then self-annealed, the DNA molecules assume a characteristic "dumbbell" shape in the electron microscope indicating that each circle possesses a non-tandem inverted repeat sequence of 630 +/- 10 base pairs. Eco-RI digestion of purified 2mu DNA yields 4 fragments on an agarose gel whose combined molecular mass is twice that of the monomer circle, suggesting that there are 2 populations of circles, each of the same molecular weight. Representatives of each population have been separated by cloning in Escherichia coli via the bacterial plasmid pSC101. Heteroduplex analysis of the cloned circles show that the 2 different populations arise because of intramolecular recombination between the inverted repeat sequences. Acrylamide gel patterns of polypeptides synthesized in bacterial mini-cells containing the hybrid plasmids between 2mu DNA and pSC101 are significantly different than the pattern obtained from mini-cells containing pSC101 alone.     

Circular DNA of 3T6R50 double minute chromosomes

In pulsed field gradient gel electrophoresis (PFGE) the intact deproteinized circular DNA of Mycoplasma (800 kb) and Escherichia coli (4700 kb) remains trapped in the slot. We show here that gamma-irradiation of the DNA in agarose plugs is a convenient method to partially convert these circles into full-length linears, migrating with the expected mobility in PFGE. We have used this method to study the structure of Double Minute chromosomes (DMs) from the methotrexate (MTX)-resistant mouse cell line 3T6R50. Intact deproteinized DM DNA is immobile in these gels, but is converted into a single band of about 2500 kb by either gamma-irradiation, DNaseI in the presence of Mn2+, or restriction enzymes. We conclude that the DM DNA in 3T6R50 cells consists of a homogeneous population of 2500-kb circles.     

Rapid screening for plasmid DNA

Summary A procedure is described for demonstrating plasmid DNA and its molecular weight, based on rate zonal centrifugation of unlabelled DNA in neutral sucrose gradients containing a low concentration of ethidium bromide. Each DNA species is then visualized as a discrete fluorescent band when the centrifuge tube is illuminated with ultra-violet light. Plasmids exist as closed circular and as relaxed circular molecules, which sediment separately, but during preparation of lysates, closed circular molecules are nicked so that each plasmid forms only a single band of relaxed circles within the gradient.     

Circular forms of Uukuniemi virion RNA: an electron microscopic study.

Because the ribonucleoprotein forms of the segments of the Uukuniemi virus genome have previously been characterized as circular, we examined the isolated RNAs by electron microscopy under conditions of increasing denaturation. After spreading under moderately denaturing conditions (50 or 60% formamide), 50 to 70% of the molecules were circular. Increasing the formamide concentration to 70 and 85% decreased the number of circular forms, and only linear forms were observed after incubation of the RNA at 60 degrees C for 15 min in 99% formamide. When spread from 4 M urea-80% formamide--another condition known to denature RNA--only 5 to 30% circular molecules were observed. Pretreatment of the RNA with 0.5 M glyoxal at 37 degrees C for 15 min prior to spreading from 50% formamide gave less than 5% cirucular forms. Length measurement of the molecules showed that they were not significantly degraded by any of the methods employed. The circular molecules were destroyed by treatment with pancreatic RNase, but were unaffected by DNase or proteinase K treatment. After complete denaturation of the RNA, the circles could be reformed under reannealing conditions. We conclude that the three size classes of RNA that comprise the Uukuniemi virus genome are circular molecules probably maintained in that form by base pairing between inverted complementary sequences at the 3'' and 5'' ends of linear molecules.     

Persistence and replication of plasmid DNA microinjected into early embryos of Xenopus laevis

The persistence and replication of defined circular and linear plasmid DNA molecules microinjected into fertilized eggs of Xenopus laevis were analyzed. For all plasmids tested, a small fraction of microinjected circular molecules was replicated; however, the overall copy numbers of either free form I or form II molecules usually did not increase through blastulation. In contrast, extensive amplification of input DNA sequences was seen whenever the microinjected DNA was assembled into high molecular weight concatemers. Moreover, the appearance and subsequent replication of injected sequences in high molecular weight DNA were enhanced when linear (form III), rather than circular, molecules were microinjected. The injected form III DNA was rapidly converted into long linear concatemers. All possible orientations of monomeric molecules within the concatemers were observed although, on occasion, head-to-tail orientations were favored. Long linear concatemers were replicated very efficiently, irrespective of the sequence of the input DNA. Form I and form II DNA molecules were also formed in the embryo from microinjected form III DNA. A small fraction of these circular forms was replicated, although overall copy numbers did not increase significantly. Form III molecules that remained monomeric were not observed to be replicated at all within our limits of detection. In some batches of embryos, form I and form II DNA molecules were replicated to the extent that overall copy number increased. Even in these cases, however, the amplification of long linear concatemers of the input DNA sequences was more efficient.