Supercoils in plant DNA: nucleoid sedimentation studies

Plant nuclei have been studied with respect to the three-dimensional structure of DNA. Nucleoids derived from nuclei by non-ionic detergent and high salt treatment were analysed by sedimentation in a series of sucrose gradients containing increasing amounts of the intercalating agent ethidium bromide. In addition the nucleoid sedimentation behaviour was investigated following gamma irradiation. The results show that plant DNA is supercoiled, as is the DNA from the other eukaryotes studied, and contains approximately the same concentration of superhelical turns but probably relatively fewer DNA superhelical loops. The plant nuclear populations in all cases studied give rise to two distinct nucleoid bands. These have been characterized by electron microscopy and by their DNA and protein content. The possible origin of the two bands is discussed.

Characterisation of multimeric DNA forms associated with tomato golden mosaic virus infection

Homodimeric and trimeric double-stranded DNA forms of both components of the genome of the geminivirus, tomato golden mosaic virus have been isolated from infected Nicotiana tabacum plants and characterised.

Topoisomerase II inhibitors influence simian virus 40 chromatin structure in vivo accompanied with inhibition of replication, transcription and changes in DNA supercoiling

The association of topoisomerase II enzymes with papovavirus-chromatin has been described recently. We used cells infected with simian virus 40 (SV40) to investigate the in vivo effect of the topoisomerase II inhibitors nalidixic acid and novobiocin on the viral chromatin template. Blocking of topoisomerases inhibits DNA and RNA synthesis. The block with the inhibitors resulted in a conversion of a 95- to 75-svedberg chromatin to a 180- to 150-svedberg component accompanied with a variation in the topological linking number of the DNA. The condensed chromatin fractions (180-150 S) from inhibited cells resemble encapsidation intermediates and their DNA has a linking number as the DNA extracted from purified virions. Moreover, the virion DNA has a higher superhelical density compared to intracellular chromatin isolated from untreated cells and argues for a supercoiling activity in the cell.

Size heterogeneity of EBV and mitochondrial DNAs in Burkitt's lymphoma lines

A simple, reproducible affinity chromatography method has been adapted for separation of high molecular weight supercoiled circular molecules from mammalian cells. Electron microscopic analysis of EB viral DNA obtained by this method, from the non-producer Burkitt's lymphoma line Raji, revealed monomer-sized viral molecules only. In contrast, the EB viral episomes from recently established human producer lines BL-8 and LY91 were very heterogeneous in size, some being considerably smaller and others much larger than the monomeric DNA. The former are probably related to defective viral species in the B-cell population, but the origin of the latter are as yet unclear. All cell lines contained both monomers and concatemers of mitochondrial DNA; among the latter, molecules apparently greater than 100 kb were observed in the population.

Structural requirements of DNA used in the Farr assay to detect antibodies directed against double-stranded DNA

The measurement of antibodies to DNA in SLE requires the use of double-stranded DNA (dsDNA), demonstrably free of single-stranded regions. Such dsDNA preparations can, however, contain other structural components. In this study DNA preparations with defined structure, both secondary (single- and double-stranded and random base-paired) and tertiary (superhelical and open circular), were used in the Farr assay to measure the DNA binding of sera from patients with SLE and related connective-tissue diseases. The presence of true single-stranded DNA regions in denatured DNA, native DNA, and dsDNA containing single-stranded regions increased the DNA binding measured in all sera. DsDNA, whether intact or containing small regions of random base-pairing, was bound by sera from the majority of patients with SLE but not by non-SLE sera. Superhelical dsDNA from bacteriophage PM2 was bound by SLE sera to a greater extent than linear dsDNA was. Inhibition experiments suggested that this difference in binding to DNA according to tertiary, as opposed to secondary, structure is because there are fewer available binding sites on superhelical dsDNA. DNA binding, as measured by the Farr assay, can thus be influenced by both secondary and tertiary DNA structure. Using superhelical DNA, advantage can be taken of the dsDNA form plus tertiary structure to enhance DNA binding of SLE sera beyond the levels achieved using linear dsDNA.

Nucleic acid chemistry: resolution of supercoiled, intact relaxed, and nicked double-stranded DNAs by formamide-sucrose gradients

A technique which will separate superhelical, intact nonsuperhelical, and damaged mitochondrial DNA molecules by use of sedimentation gradients of formamide-sucrose is described. This technique can be used to detect damage to the mitochondrial DNA helix.

The segment inversion site of herpes simplex virus type 1 adopts a novel DNA structure

The 12-base pair (bp) tandem direct repeat sequences (DR2) at the joint region (a sequence) of herpes simplex virus type 1 (strain F) adopt a new type of DNA conformation under the influence of negative supercoiling. The novel conformation is dependent on the number of the DR2 repeats; the 19 mer (228 bp total) and the 14 mer (168 bp) readily form the alternate structure whereas pentamer, trimer, and dimer repeats show somewhat different properties. S1 and P1 nuclease studies reveal that the new conformation has a major structural aberration at its center and conformational periodicities which are not identical on the complementary strands. Also, the effect of salt and pH, the location of reaction with bromo- and chloroacetaldehyde, the type of sequence (direct repeat) involved, and the nature and extent of supercoil-induced relaxations demonstrate that this structure differs from previously recognized conformations including left-handed Z helices, cruciforms, bent DNA, and slipped structures. We propose the existence of a novel conformation, anisomorphic DNA, with different structures on the complementary strands which elicit a structural aberration at the physical center of the tandem sequences. Since the oligopurine X oligopyrimidine sequence may be inherently inflexible, this supercoil-induced structural change and the physical stress on these inserts in recombinant plasmids tend to deform (crack) the DR2 sequences at their centers. Possible roles for anisomorphic DNA in the functions of this segment of intense biological activity are proposed.

Constitutive function of a positively regulated promoter reveals new sequences essential for activity

A consensus "-10" recognition sequence for RNA polymerase was created at the positively regulated lambda Pre promoter by introducing three single base pair mutations. This altered promoter, Pre*, functions constitutively in vivo and in vitro at high efficiency despite very poor consensus "-35" region sequence homology. We examined the influence of the -35 region sequence information on promoter function by shifting the wild type -35 region +/- 2 base pairs relative to the -10 region consensus sequence and by completely replacing it with alternative DNA sequences. In every case, the altered Pre* promoters retained transcriptional activity although differences in their transcriptional efficiencies were observed. Apparently the Pre* promoter does not require specific -35 region sequences for constitutive promoter activity, although the -35 region sequences can modulate overall promoter strength. In addition, by point mutation analysis we have identified bases immediately upstream of the -10 hexamer which are essential for constitutive function of the Pre* promoter. We propose that these mutants define an extended -10 region at Pre* that compensates for its poor -35 region sequence information by providing critical contacts that stabilize productive RNA polymerase binding.

Isolation of a human genomic fragment, co-amplified with c-Ki-ras, that affects plasmid supercoiling in E. coli

Amplification of cellular proto-oncogenes has been implicated in the development of human malignancies. A library was constructed from genomic DNA extracted from a lung tumour, previously shown to carry an amplified c-Ki-ras 2 gene. Using a v-Ki-ras probe, a fragment with ras homology was isolated and shown to be amplified in the original tumour DNA to the same level as c-Ki-ras. Studies with human hamster hybrids demonstrated that it is normally located on human chromosome 12 (as is c-Ki-ras). The restriction map of the fragment is different from that of the known Ha, Ki or N-ras genes and its sequence shows evolutionary conservation, as demonstrated by hybridisation to the genomic DNA of several mammalian species. A pUC19 subclone (pK42), carrying a 1.3kb insert, shows supercoil heterogeneity in plasmid preparations, as does a second compatible plasmid introduced into the same bacterial host with pK42. It appears therefore that the subclone is encoding a product that affects DNA topoisomerase activity in E. coli.

Supercoiling facilitates lac operator-repressor-pseudooperator interactions

The binding affinity of the Escherichia coli lactose repressor to operator-containing plasmids was increased by negative supercoiling of the DNA. The increased affinities observed were dependent on the sequence context of the DNA as well as the degree of supercoiling. Dissociation rate constants for plasmids containing a single operator site decreased as a function of the negative supercoil density. However, the presence of pseudooperators in the plasmid DNA in addition to the primary operator sequence resulted in a significant decrease in the operator-plasmid dissociation rate at higher negative supercoil densities. Approximately eight ionic interactions were determined for both the supercoiled plasmids and the linear DNAs examined. These results suggest that the stabilization provided by the topology of supercoiled DNA affects the nonionic component of the protein-DNA interaction. The ability to form a ternary complex of protein with two DNA segments is increased by the presence of multiple operator-like sites on the DNA. Furthermore, supercoiling DNA with multiple operator-like sequences profoundly diminishes the dissociation rate and results in a remarkably stable ternary, presumably looped complex (t1/2 approximately 28 h). These data suggest a critical role in vivo for DNA topology and pseudooperator(s) in transcriptional regulation of the lac operon.

Characterization of a supercoil-dependent S1 sensitive site 5' to the Drosophila melanogaster hsp 26 gene

We have analyzed the prominent supercoil-dependent S1 nuclease cleavage site 5' to hsp 26 in the plasmid 88B13, which contains 11.7 kilobases from the Drosophila locus 67B1. The double stranded cleavage product is generated by initial nicking on the purine strand, six preferred sites occurring between positions -96 and -90 (relative to the start of transcription) with weaker ones extending to position -84, followed by cleavage on the pyrimidine strand at positions -86 and -84. A derivative of 88B13, 88B13-X, was generated by insertion of an Xho I linker at position -84; this does not affect the positions or strand specificity of the S1 cleavage in that region. A small deletion, delta 41.1, removes the homopurine/homopyrimidine stretch from positions -86 to -132 and is no longer sensitive to cleavage by S1 nuclease 5' to hsp 26. Mung bean and P1 nucleases recognize the same site 5' to hsp 26 and give the same general pattern of cleavage. All three nucleases show an initial cleavage of 88B13 DNA at this site at pH 5.5 but not at pH 6.5, indicating that the DNA structure there may be pH dependent in vitro.

Thermodynamic parameters are sequence-dependent for the supercoil-induced B to Z transition in recombinant plasmids

The entropy and enthalpy changes which contribute to the thermodynamics of the B to Z transition were determined for three recombinant plasmids containing a (dC-dG)16 tract and for a plasmid containing a pair of (dT-dG)20 regions. For each base pair which adopts a left-handed conformation in the plasmids with (dC-dG)16 sequences, the delta HBZ and delta SBZ are -2.1 kcal/mol bp and -8.8 cal/K-mol bp, respectively. In the plasmid containing the (dT-dG)20 tracts, however, the delta HBZ and delta SBZ values are 0.58 kcal/mol bp and -0.76 cal/K-mol bp, respectively. Also, these determinations show that for each B-Z junction that forms in the plasmids containing the (dC-dG), the enthalpy and entropy changes are 24 kcal/mol junction and 65 cal/K-mol junction, whereas for the (dT-dG) plasmid, the enthalpy and entropy changes are -1.8 kcal/mol junction and -22 cal/K-mol junction, respectively. Those values for the enthalpy and entropy changes for the formation of a BZ junction in (dC-dG) and (dT-dG) plasmids suggest that the properties and possibly the structures of the junctions are different. Calculations using the enthalpy and entropy changes determined in this study reveal that the B to Z transition in plasmids containing (dC-dG) blocks are more temperature-dependent than the transitions in plasmids with (dT-dG) blocks. Surprisingly, at temperatures above 60 degrees C, calculations indicate that the B to Z transitions in (dT-dG) plasmids should be energetically favored over that transition in (dC-dG) plasmids.

[Age-related structural and functional changes in the DNA of human lymphocytes]

Characteristic changes of DNA winding and repair are detected in human peripheral lymphocytes with advancing donor age between 20 and 90 years, suggesting a progressively undifferentiated cell state. From a model approach it appears likely that the existence of immature lymphocytes favors aging as a general dysdifferentiation of somatic cells.

Infectious mutants of cassava latent virus generated in vivo from intact recombinant DNA clones containing single copies of the genome

Intact recombinant DNAs containing single copies of either component of the cassava latent virus genome can elicit infection when mechanically inoculated to host plants in the presence of the appropriate second component. Characterisation of infectious mutant progeny viruses, by analysis of virus-specific supercoiled DNA intermediates, indicates that most if not all of the cloning vector has been deleted, achieved at least in some cases by intermolecular recombination in vivo between DNAs 1 and 2. Significant rearrangements within the intergenic region of DNA 2, predominantly external to the common region, can be tolerated without loss of infectivity suggesting a somewhat passive role in virus multiplication for the sequences in question. Although packaging constraints might impose limits on the amount of DNA within geminate particles, isolation of an infectious coat protein mutant defective in virion production suggests that packaging is not essential for systemic spread of the viral DNA.

Possible role of oxygen radicals in cell transformation by diethylstilbestrol and related compounds

Diethylstilbestrol (DES) and four derivatives, viz. tetrafluoro-DES, 3'-hydroxy-DES, Z,Z-dienestrol and hexestrol, were examined for their abilities to form superoxide radicals and to induce DNA strand breaks in the presence of horseradish peroxidase/hydrogen peroxide metabolism in a cell-free system. Furthermore, the induction of strand breaks by these compounds was tested in Syrian hamster embryo (SHE) cells in vitro. Formation of superoxide radicals could be demonstrated by reduction of nitro blue tetrazolium for DES but not for its derivatives. With isolated superhelical DNA, induction of strand breaks in the presence of Fe3+ was observed for DES, tetrafluoro-DES and 3'-hydroxy-DES, while hexestrol and Z,Z-dienestrol were ineffective. In SHE cells, alkaline elution technique showed that DNA strand breaks were induced by DES and all derivatives tested, although only at cytotoxic concentrations. It is concluded that DES, under conditions of peroxidative metabolism, can give rise to superoxide generation and DNA strand breaks, and that these events may play a role in the process of DES-induced cell transformation.

Appearance of viral RNA transcripts in the early stage of duck hepatitis B virus infection

Sequential analysis of duck hepatitis B virus (DHBV) DNA and RNA transcripts in the liver of the early stage of infection was carried out using 1-day-old ducklings inoculated with DHBV-positive serum. Using Southern blot analysis, a band of supercoiled DHBV DNA was detectable at 6 hr, when DHBV-specific poly[A]+RNA was also observed by Northern blot analysis as a faint smear below 3-kb. Bands of RNA at 3.5, 2.7, and 2.5 kb were detected at 12 hr, just before single-stranded viral DNA was detected. A prominent increase in the amount of viral RNA was demonstrated (between 12 hr and 3 days) prior to the increase of DHBV DNA (between 3 and 6 days). Our results suggest that 3.5-kb DHBV-specific RNA synthesized from supercoiled DNA may act as a template of reverse transcription, and that all steps of the replication pathway proposed by Summers and Mason (1982, Cell, 29, 403-415) are completed during 3 days.

Dynamics of the B-to-Z transition in supercoiled DNA

The sequence (dC-dG)16, inserted into the polylinker of plasmid pUC8, adopts a left-handed Z-DNA conformation at "natural" supercoil density. The radioactively labeled monoclonal antibody Z-D11, which has a very high affinity for this DNA conformation, provides a convenient sensitive tool to measure selectively the amount of Z-DNA. Chloroquine reversibly changes the supercoil density of plasmid DNA and thereby the equilibrium between right- and left-handed double-helical DNA. The time-dependent formation or disappearance of Z-DNA was measured by using the antibody either as a fast indicator of Z-DNA or as an additional effector of the B-to-Z equilibrium. In the middle of the transition, a relaxation time of about 1 hr is observed in 0.1 M NaCl at 22 degrees C. The kinetic data are compatible with an all-or-none transition between the two conformations. The overall rate constant for Z-DNA formation, kBZ, decreases with the square of the chloroquine concentration, while the reverse one, kZB, increases with about the fourth power.

Highly selective chemical modification of cruciform loops by diethyl pyrocarbonate

Diethyl pyrocarbonate reacts with the single-stranded loops of cruciform structures with great selectivity. Adenine bases are carbethoxylated, as a result of which the backbone may be cleaved with piperidine, and the level of chemical modification at each base may be determined. We have studied the ColE1 and (A-T)34 cruciforms of pColIR315 and pXG540. In each case we observe maximal modification at the most central adenosine of the loop, and an overall pattern of modification corresponding to a total loop size of about six bases. The results may be interpreted in terms of a model in which the loop has a defined tertiary structure. No modification was detected at either cruciform four-way junction, suggesting that this region is fully base-paired.

Persistence of cruciform structure and preferential location of nucleosomes on some regions of pBR322 and ColE 1 DNAs

Inverted repeats of pBR322 and ColE 1 DNAs have been analyzed for the presence of cruciform structures upon formation of nucleosomes, using S1, P1 and restriction enzyme analysis. In both cases the fraction of molecules showing nuclease-sensitive sites is unaffected by the DNA relaxation, owing to the formation of nucleosomes. A kinetic mechanism, based on the freezing of cruciform structures on the nucleosome surface or nearby, is proposed. This hypothesis is supported by a preferential location of nucleosomes at the DNA sequences containing the nuclease-sensitive sites, as indicated by restriction enzyme analysis and electron microscopy visualization after psoralen cross-linking.

High frequency excision of Ty elements during transformation of yeast

Yeast (Saccharomyces cerevisiae) transposons (Ty elements) are excised from up to 20% of supercoiled plasmids during transformation of yeast cells. The excision occurs by homologous recombination across the direct terminal repeats (deltas) of the Ty element, leaving behind a single delta in the transforming plasmid. Only the initial transforming plasmid is susceptible to excision, and no high frequency excision is observed in plasmids that have become established in transformed cells or in plasmids that are resident in cells undergoing transformation. High frequency excision from plasmids during yeast transformation is not specific for Ty elements and can be observed with other segments of plasmid DNA bounded by direct repeats. The frequency of Ty excision from supercoiled plasmids is greatly reduced when the host yeast cells contain the rad52 mutation, a defect in double-strand DNA repair. When linear or ligated-linear plasmid DNAs containing a Ty element are used for transformation, few or no excision plasmids are found among the transformant colonies. These results suggest that when a yeast cell is transformed with a supercoiled plasmid, the plasmid DNA is highly susceptible to homologous recombination for a short period of time.

DNA supercoiling of recombinant plasmids in mammalian cells

We have used chloroquine/agarose gel electrophoresis and a blot-hybridization technique to study the modulation of superhelicity of extrachromosomal DNA in mammalian cells. The high sensitivity of the procedure has allowed us to measure the change in the specific linking difference or superhelical density (sigma) of a plasmid, psvo alpha 1p3d, after its introduction into COS-7 cells by DNA transfection. Because the molecular weight of psvo alpha 1p3d is approximately the same as that of simian virus 40 (SV40) DNA, the latter can be used as a standard for estimating the average linking difference or number of superhelical turns (tau) of psvo alpha 1p3d after separation of the different supercoiled species on chloroquine/agarose gels. It was found that transfection of monkey cells with either fully supercoiled psvo alpha 1p3d isolated from bacteria (tau = -27 +/- 1, sigma congruent to -0.051) or its relaxed form after treatment with DNA topoisomerase I yields psvo alpha 1p3d samples of the same tau and sigma values of -20 +/- 1 and -0.038, respectively. The difference between the tau values of psvo alpha 1p3d and SV40 in COS-7 cells, in which both plasmids undergo rounds of replication, corresponds to an average difference of 5 +/- 1 superhelical turns. Plasmid psvo alpha 1p3d remains at this lower level of superhelicity for at least 72 hr. The distribution in linking numbers of the topoisomers of psvo alpha 1p3d isolated from transfected COS cells is also more heterogeneous than that of SV40 DNA. These results suggest that the regulation of DNA supercoiling and chromatin assembly may be closely associated with specific DNA sequences. The approach presented here should have a wide application in the study of the regulation and functional role(s) of DNA supercoiling of plasmids in mammalian cells.

Bacteriophage P1 Cre-loxP site-specific recombination. Site-specific DNA topoisomerase activity of the Cre recombination protein

Site-specific recombination in bacteriophage P1 occurs between two loxP sites in the presence of the Cre recombination protein. The structure of the 34-base pair loxP site consists of two 13-base pair inverted repeats separated by an 8-base pair spacer region. A mutation in the loxP site has been constructed which deletes one of the internal bases of the spacer region at the axis of dyad symmetry. This mutant loxP site shows a 10-fold reduction in recombination activity with a wild-type site both in vivo and in vitro. This low level of intramolecular recombination between a wild-type loxP site and the mutant loxP501 site is observed in vitro only when the DNA substrate is supercoiled. The majority of the supercoiled substrate is relaxed by the Cre protein, and on longer incubations, single-stranded nicks accumulate in the DNA. We have determined that these nicks occur in both the wild-type and the mutant sites. The positions of these nicks correspond to the positions of cleavage found during recombination of two wild-type sites, suggesting that the Cre protein is attempting to carry out recombination with the mutant site but most of the time this reaction is abortive. We have determined that the Cre protein relaxes a supercoiled topoisomer of a DNA substrate containing one wild-type site and one mutant site to yield a distribution of topoisomers whose linking numbers differ by steps of one, indicating that Cre can act as a type I topoisomerase.

Analysis of Z-DNA in fixed polytene chromosomes with monoclonal antibodies that show base sequence-dependent selectivity in reactions with supercoiled plasmids and polynucleotides

Five monoclonal anti-Z-DNA antibodies were characterized with respect to their binding of synthetic nucleic acid polymers and of supercoiled circular plasmid DNA. All of the antibodies reacted only with DNA in the Z-conformation; however, they fell into two classes on the basis of sequence specificity. One class, with broad specificity, reacted well with all sequences in the Z-form, including poly(dG-dC), poly(dG-dm5C), and poly (dG-dBr5C) in linear polymers and poly(dG-dC)n and poly[(dC-dA)n.(dT-dG)n] sequences in supercoiled plasmids. The other class bound only Z-DNA formed by poly(dG-dC). Binding of the monoclonal antibodies specifically to inserts of Z-DNA-forming sequences in plasmids was mapped directly by cross-linking of antibody to the DNA, digestion with restriction nuclease, and electrophoretic analysis of both the unbound fragments and the bound fragments recovered from immune complexes. The monoclonal antibodies were used for indirect immunofluorescence staining of Drosophila polytene chromosomes fixed by two procedures. One procedure yielded chromosomes with Z-specific antibody binding in many interbands, a few specific bands, and parts of some puffs. On chromosomes fixed by the second procedure, antibody staining appeared to follow the DNA concentration, staining all bands brightly. For each fixation procedure, chromosomes showed the same staining pattern with each of the broad specificity monoclonal antibodies that had been seen with polyclonal antibodies. The antibodies that reacted only with poly(dG-dC) and poly (dG-dC)n plasmid inserts did not stain chromosomes fixed by either protocol. We conclude that stretches of poly(dG-dC)n sequences do not contribute significantly to the presence of Z-DNA in fixed polytene chromosomes of Drosophila melanogaster.