In vitro increases in plasmid DNA supercoiling by hydrostatic pressure

By conducting topoisomerase I-mediating supercoiling assays, effects of elevated pressure on DNA supercoiling were investigated for the first time. It was found that pressure elevations induced a progressive increase in plasmid DNA linking numbers, winding the DNA duplex by a magnitude of 1.1-1.6x10(-3) angular degree/base/MPa. Implications for the findings were discussed in terms of disturbance of the tertiary structure of DNA by elevated pressure.

High-resolution capillary electrophoretic separation of supercoiled plasmid DNAs and their conformers in dilute hydroxypropylmethyl cellulose solutions containing no intercalating agent

The three conformers of plasmid pBR322, linear, supercoiled and nicked circular forms, were separated by capillary electrophoresis (CE) in 0.1% hydroxypropylmethyl cellulose (HPMC) solution in the absence of intercalating agents and the migration order was confirmed by co-migration of enzymatically prepared corresponding DNAs. The previously observed broad peaks of supercoiled DNAs in CE are results of unresolved peaks of topoisomers which differ only in the degrees of twisting. We have demonstrated the separation of an artificial topoisomer ladder made from pBR322 and topoisomerase I. The population of topoisomers of a supercoiled DNA is dependent on sample matrices and separation conditions.

Sequence specificity of illegitimate plasmid recombination in Bacillus subtilis: possible recognition sites for DNA topoisomerase I

Previous work in our group indicated that structural plasmid instability in Bacillus subtilis is often caused by illegitimate recombination between non-repeated sequences, characterized by a relatively high AT content. Recently we developed a positive selection vector for analysis of plasmid recombination events in B. subtilis which enables measurement of recombination frequencies without interference of selective growth differences of cells carrying wild-type or deleted plasmids. Here we have used this system to further analyse the sequence specificity of illegitimate plasmid recombination events and to assess the role of the host-encoded DNA topoisomerase I enzyme in this process. Several lines of evidence suggest that single-strand DNA nicks introduced by DNA topoisomerase I are a major source of plasmid deletions in pGP100. First, strains overproducing DNA topoisomerase I showed increased levels of plasmid deletion. Second, these deletions occurred predominantly (>90% of the recombinants) between non-repeated DNA sequences, the majority of which resemble potential DNA topoisomerase I target sites. Sequence alignment of 66 deletion end-points confirmed the previously reported high AT content and, most importantly, revealed a highly conserved C residue at position -4 relative to the site of cleavage at both deletion termini. Based on these genetic data we propose the following putative consensus cleavage site for DNA topoisomerase I of B.subtilis: 5'-A/TCATA/TTAA/TA/TA-3'.

High-speed separation of linear and supercoiled DNA by capillary electrophoresis. Buffer, entangling polymer, and electric field effects

Capillary electrophoresis in dilute and semidilute (slightly entangled) hydroxyethyl cellulose (HEC) is shown to separate linear double-stranded DNA (ds-DNA) and supercoiled plasmid DNA in the size range 1-16 thousand base pairs in 3 min. The mobilities of linear ds-DNA fragments are stronger functions of electric field strength and buffer concentration than the mobilities of supercoiled plasmids. The effects of HEC concentration and molecular weight are similar for both forms of DNA. The behavioral differences, which are attributed to the greater stiffness of the plasmids, can be used to define conditions that maximize resolution of supercoiled and linear ds-DNA of the same or similar number of base pairs.

Fluorescent dye assay for detection of DNA in recombinant protein products

A homogeneous fluorescence-based DNA detection system has been developed to measure DNA in protein solutions. The technique relies on the increase in fluorescence of a dye molecule when it intercalates into double-stranded (ds) DNA. The increased fluorescence is a direct measurement of the amount of DNA in the sample. The analysis time required per sample is less than 5 min. The dye has absorbance and emission maxima at 485 and 530 nm, respectively. The assay is linear from 98 pg/mL to 200 ng/mL of DNA in buffers containing no proteins with typical relative standard deviation values of less than 2.4%. The assay performance was evaluated under various matrix conditions, including buffers, pH, ionic salts, detergents, denaturants and organic solvents. Each reagent was tested at several concentrations to determine how the slope and linearity (r value) of the standard curve were affected. Even in the presence of matrix components and protein, the assay was able to quantitatively detect picogram to nanogram levels of DNA. The fluorescence can be removed by DNase treatment. This method is specific for dsDNA with RNA emitting less than 2% intensity of an equivalent mass of DNA.

Treatment of U937 cells with bufalin induces the translocation of casein kinase 2 and modulates the activity of topoisomerase II prior to the induction of apoptosis

The treatment of human leukemia U937 cells with 10(-8) M bufalin in the absence of serum resulted in the immediate translocation of casein kinase 2 (CK 2) from the cytoplasm to the nucleus, as determined by confocal laser-scanning microscopy. Concomitantly, the activity of topoisomerase (topo) II, as determined by monitoring activities specific to this enzyme such as DNA relaxation, DNA decatenation, and topo II-mediated DNA cleavage, was enhanced. The activity reached a maximum after 3 h and then decreased markedly after treatment with bufalin for 9 h. The amount of a complex of CK 2 and topo IIalpha in U937 cells was estimated by immunoprecipitation with antibodies raised against subunits of CK 2 and against topo IIalpha. The amount increased just after the start of treatment with bufalin and reached a maximum at 6 h. The results suggest that the topo IIalpha in the complex might have been phosphorylated by the translocated CK 2 and that the topo activity was stimulated by such phosphorylation. Apoptotic U937 cells with fragmented nuclei were observed between 9 and 12 h after the start of treatment using 10(-8) M bufalin. Therefore, it appears that the bufalin signal was transmitted to the nucleus by the translocation of CK 2, which formed a complex with topo IIalpha and modulated the activity of this enzyme, leading to the induction of apoptosis.

Quantitation of ethidium-stained closed circular DNA in agarose gels

The fluorescence of ethidium bromide (EB) bound to equimolar amounts of supercoiled form I and unstrained linear form III pBR322, SV40 and PM2 DNA in agarose gels has been measured by scanning a photographic negative of the gel with a microdensitometer. For SV40 and PM2 DNA, commonly used staining conditions cause both forms, i.e. linear and supercoiled, to fluoresce to the same extent. This obviates the need to use a correction factor for the fluorescence of form I DNA when measuring the amount of this form relative to the amounts of unstrained forms in agarose gels. In the case of PBR322 DNA, form I was found to fluoresce approximately 20% more than form III DNA.

Discoordinate gene expression of gyrA and gyrB in response to DNA gyrase inhibition in Escherichia coli

The intracellular level of DNA supercoiling is regulated in Escherichia coli by a homeostatic control mechanism that includes DNA gyrase and topoisomerase I gene expression. Despite several biochemical and genetical evidence that supports the existence of a homeostatic regulation mechanism, there are only few studies focusing gyrA and gyrB gene expression in connection to the mechanism involved in the regulation of DNA supercoiling in vivo. To study DNA gyrase gene expression and to be able to isolate mutants with altered expression of DNA gyrase, we constructed a new chromosomal reporter system based on two translational fusions of gyrA and gyrB to lacZ Using this stable monitor system in a robust wild type, we simultaneously studied the influence of several inhibitors of DNA gyrase (quinolones and coumarins) on gyrA and gyrB gene expression as well as on the intracellular level of DNA supercoiling. Surprisingly, we found a delayed and differential response of gyrA and gyrB gene expression following inhibition of DNA gyrase by quinolones or coumarins. Whereas both groups of drugs were able to increase the expression of gyrA, the gyrB gene expression was only induced by the coumarins. Although the action of the quinolones was able to alter DNA supercoiling, we never observed any induction of gyrB from the chromosome. These results revealed that the gene expressio of gyrA appears to be more sensitive to alterations in DNA supercoiling than the gyrB gene expression and suggest that probably additional regulatory mechanisms on the post-translational level might be involved in the regulation of DNA supercoiling and DNA gyrase gene expression.

Effect of the deletion of the sigma 32-dependent promoter (P1) of the Escherichia coli topoisomerase I gene on thermotolerance

Topoisomerase I and DNA gyrase are the major topoisomerase activities responsible for the regulation of DNA supercoiling in the bacterium Escherichia coli. The P1 promoter of topA has previously been shown to be a delta 32-dependent heat-shock promoter. A mutant strain with a deletion of P1 was constructed. This mutant is > 10-fold more sensitive to heat treatment (52 degrees C) than the wild type. After brief treatment at 42 degrees C, wild-type Escherichia coli acquires an enhanced resistance to the effects of a subsequent 52 degrees C treatment. This is not the case for the P1 deletion mutant, which, and under these conditions, is about 100-fold less thermotolerant than the wild type. The presence of a plasmid expressing topoisomerase I restored the heat-survival level of the mutant to that of the wild type. During heat shock, the superhelical density of a plasmid with the heat-inducible rpoD promoter is increased in the P1 deletion mutant. We also note that the pulse-labelling pattern of proteins at 42 C (displayed on SDS-polyacrylamide gels) is different in the mutant, and, most notably, the amounts of DnaK and of GroEL protein are reduced. A model is proposed in order to unify these observations.

Plasmid-like replicative intermediates of the Epstein-Barr virus lytic origin of DNA replication

During the lytic phase of herpesviruses, intermediates of viral DNA replication are found as large concatemeric molecules in the infected cells. It is not known, however, what the early events in viral DNA replication that yield these concatemers are. In an attempt to identify these early steps of DNA replication, replicative intermediates derived from the lytic origin of Epstein-Barr virus, oriLyt, were analyzed. As shown by density shift experiments with bromodeoxyuridine, oriLyt replicated semiconservatively soon after induction of the lytic cycle and oriLyt-containing DNA is amplified to yield monomeric plasmid progeny DNA (besides multimeric forms and high-molecular-weight DNA). A new class of plasmid progeny DNA which have far fewer negative supercoils than do plasmids extracted from uninduced cells is present only in cells undergoing the lytic cycle of Epstein-Barr virus. This finding is consistent with plasmid DNAs having fewer nucleosomes before extraction. The newly replicated plasmid DNAs are dependent on a functional oriLyt in cis and support an efficient marker transfer into Escherichia coli as monomeric plasmids. Multimeric forms of presumably circular progeny DNA of oriLyt, as well as detected recombination events, indicate that oriLyt-mediated DNA replication is biphasic: an early theta-like mode is followed by a complex pattern which could result from rolling-circle DNA replication.

The effect of novobiocin on solvent production by Clostridium acetobutylicum

Cells of Clostridium acetobutylicum treated with novoblocin, a DNA gyrase inhibitor, produced higher butyrate levels and lower solvent levels with acetone being the most affected. Seven enzyme activities involved in acid and solvent production were analyzed. Among them, only CoA transferase, required for acetone formation and acid uptake, experienced a significant decrease in activity. As in Escherichia coli and Bacillus subtilis, DNA from C. acetobutylicum became less negatively supercoiled in the early stationary phase (solventogenic stage), as shown by analysis of linking number of a reporter plasmid by agarose gel electrophoresis in the presence of chloroquine.

Sequence-specific labeling of superhelical DNA by triple helix formation and psoralen crosslinking

Site-specific labeling of covalently closed circular DNA was achieved by using triple helix-forming oligonucleotides 10, 11 and 27 nt in length. The sequences consisted exclusively of pyrimidines (C and T) with a reactive psoralen at the 5'-end and a biotin at the 3'-end. The probes were directed to different target sites on the plasmids pUC18 (2686 bp), pUC18/4A (2799 bp) and pUC1 8/4A-H 1 (2530 bp). After triple helix formation at acid pH the oligonucleotides were photocrosslinked to the target DNAs via the psoralen moiety, endowing the covalent adduct with unconditional stability, e.g. under conditions unfavorable for preservation of the triplex, such as neutral pH. Complex formation was monitored after polyacrylamide gel electrophoresis by streptavidin-alkaline phosphatase (SAP)-induced chemiluminescence. The yield of triple helix increased with the molar ratio of oligonucleotide to target and the length of the probe sequence (27mer > 11mer). The covalent adduct DNA were visualized by scanning force microscopy (SFM) using avidin or streptavidin as protein tags for the biotin group on the oligonucleotide probes. We discuss the versatility of triple helix DNA complexes for studying the conformation of superhelical DNA.

Amplification of the complete polyomavirus JC genome from brain, cerebrospinal fluid and urine using pre-PCR restriction enzyme digestion

A method is described for amplification of the complete genome of the human polyomavirus JC (JCV) from progressive multifocal leukuencephalopathy (PML) brain, cerebrospinal fluid (CSF) of PML patients, and from the urine of controls without neurological disease. Efficient amplification with the 'long PCR' method is achieved with primers overlapping the single BamHI or EcoRI site following digestion of the DNA sample with the restriction enzyme BamHI or EcoRI, respectively. Cutting of the supercoiled JCV genome allows full separation of the strands during the denaturation step, and permits primer annealing to compete successfully with reassociation of the genomic DNA. With this method a single PCR amplification allows restriction fragment length polymorphism (RFLP) analysis and direct cycle sequencing of any part of the viral genome. RFLP analysis of JCV amplified from CSF has identified a new mutant sequence. Sequencing of clinical samples is useful for typing of JC virus isolates as Type 1 or Type 2 and for characterization of the JCV regulatory region as archetypal or rearranged.

Capillary gel electrophoresis as a method to determine ligation efficiency

A capillary gel electrophoresis (CGE) method is described for detection of the formation of circular DNA ligation products as an aid in the prediction of ligated DNA competent cell transformation efficiency. The separation is based upon the differences in the relative migrations of linear and circular DNA molecules of the same size. In CGE, circular ligation products are shifted significantly from linear DNA fragments of comparable size (to 40-42 min from 32-33 min migration time) in the presence of an intercalating dye. CGE separation and detection of circularized DNA can be correlated with transformation efficiencies of > 10(6) colony-forming units (CFU, colonies/micrograms/ml) or the high efficiency desired for phagemid display and cell expression libraries. CGE has several advantages over slab gel electrophoresis: (i) only a minute quantity (approximately 250 CFU or 0.02%) of the total library is sacrificed for analysis, (ii) verification of the circularized ligation products is easier by CGE, and (iii) CGE analysis of ligation success can be accomplished in less than 2 h, prior to transforming competent cells.

Molecular cloning of Indian tomato leaf curl virus genome following a simple method of concentrating the supercoiled replicative form of viral DNA

DNA-A and DNA-B components of the genome of a whitefly transmitted virus causing yellowing and leaf curl in tomato (ITLCV) were cloned following a simple procedure for isolation of the double stranded replicative form of viral DNA from infected tomato plants. The method is based on extraction of total DNA from infected plants followed by concentration of the double stranded replicative form of viral DNA by an alkaline denaturation procedure identical to that used for isolation of plasmid DNA from Escherichia coli. The attempted cloning of DNA showed that 95% of the transformants contained plasmids with an insert of either DNA-A (2.75 kb) or DNA-B (2.55 kb). Cloned DNA-A and DNA-B when used as probes could detect DNA-A/DNA-B in total nucleic acid obtained from fresh diseased tissue. Both DNA-A and DNA-B are needed for infection and they have a common region of 166 bases with about 94% nucleotide sequence homology, a characteristic of all bipartite geminiviruses. Comparison of the amino acid sequence of the putative coat protein product of ITLCV with some other mono- and bipartite geminiviruses revealed a maximum of 86% homology with Indian cassava mosaic virus.

Studies of bacteriophage P2 DNA replication: localization of the cleavage site of the A protein

Bacteriophage P2 replicates via a modified rolling circle-type of mechanism, where the P2 A protein acts as an initiator of the replication by inducing a single-stranded cut at the origin of replication (ori). The exact location of the cut induced by the A protein in vivo is determined in this report by: (i) restriction analysis; (ii) DNA sequence analysis; and (iii) primer extensions. It is located 89.2% from the left end of the P2 genome, which is within the coding part of the A gene, in a region devoid of secondary structures. The A gene has been cloned into an expression vector, and the A protein has been purified. The purified A protein does not bind to double-stranded ori containing DNA, but it cleaves single-stranded ori containing DNA, which indicates that a special DNA structure and/or protein is required to make the ori accessible for the A protein.

Re-replication of SV40 minichromosomes is inhibited at the stage of chain elongation

The template activities of protein-free SV40 DNA and SV40 minichromosomes for DNA re-replication are compared in in vitro replication assays. Density substitution experiments and two-dimensional gel electrophoresis show that protein-free DNA can replicate for at least two cycles whereas salt-treated minichromosomes replicate only once. Re-replication of minichromosomes is blocked at the stage of replicative chain elongation suggesting that replicatively assembled chromatin has structural features that prevent a second round of replication.

Replication intermediates of rice tungro bacilliform virus DNA support a replication mechanism involving reverse transcription

Rice tungro bacilliform virus (RTBV) replication intermediates have been studied in rice plants infected with the virus. Unencapsidated virus-specific molecules were identified which had open circular, linear, supercoiled (SC), strong-stop, single-stranded, linear double-stranded hairpin, and double-stranded with single-stranded extension DNA forms. The structures of these different DNA forms were consistent with the replication model of cauliflower mosaic virus and support other results that reverse transcription is involved in the replication of RTBV. The existence of nonspecific and defective (+)-strand priming is suggested. The relative amount of SC DNAs differs in various tissues of the same plant and in the same tissue at different ages. This indicates host regulation of the virus replication cycle and a feedback regulatory mechanism in controlling the SC DNA level. There are no obvious differences in the composition of the replication intermediates between insect-infected and agroinoculated rice plants.

Thermoregulation in Yersinia enterocolitica is coincident with changes in DNA supercoiling

Yersinia enterocolitica is a facultative intracellular parasite, displaying the ability to grow saprophytically or invade and persist intracellularly in the mammalian reticuloendothelial system. The transition between such diverse environments requires the co-ordinated regulation of specific sets of genes on both the chromosome and virulence plasmid. Temperature has a profound pleiotropic effect on gene expression and phenotypically promotes alterations in cell morphology, outer-membrane protein synthesis, urease production, lipopolysaccharide synthesis, motility, and synthesis of genes involved in invasion of eukaryotic host cells. By examining thermoregulated flagella biosynthesis, we have determined that motility is repressed at 25 degrees C (permissive temperature) with subinhibitory concentrations of novobiocin. These conditions also induce virulence gene expression suggesting novobiocin addition simulates, at least partially, a high-temperature environment. Furthermore, temperature-shift experiments, using Y. enterocolitica containing pACYC184 as a reporter plasmid, indicate that thermo-induced alterations of DNA supercoiling coincide with temperature-induced phenotypic changes. A class of putative DNA gyrase mutant (novobiocin resistant) likewise demonstrates the 37 degrees C phenotype when cultured at 25 degrees C; it is non-motile, urease negative, calcium growth dependent, and positive for Yop expression. These results support a model implicating DNA topology as a contributing factor of Y. enterocolitica thermoregulation.

5-Aminolevulinic acid induces single-strand breaks in plasmid pBR322 DNA in the presence of Fe2+ ions

5-Aminolevulinic acid (ALA), a heme precursor accumulated in chemical and inborn porphyrias, has been demonstrated to produce reactive oxygen species upon metal-catalyzed aerobic oxidation and to cause oxidative damage to proteins, liposomes and subcellular structures. Exposure of plasmid pBR322 DNA to ALA (0.01-3 mM) in the presence of 10 microM Fe2+ ions causes DNA single-strand breaks (ssb), revealed by agarose gel electrophoresis as an increase in the proportion of the open circular form (75 +/- 7.5% at 3 mM ALA) at the expense of the supercoiled form. Addition of either anti-oxidant enzymes such as superoxide dismutase (10 micrograms/ml) and catalase (20 micrograms/ml), or a metal chelator (DTPA, 2.5 mM), or a HO. scavenger (mannitol, 100 mM) inhibited the damage (by 30, 45, 55, and 81%, respectively), evidencing the involvement of O2-., H2O2 and HO. (by the Haber-Weiss reaction) in this process. Hydrogen peroxide (100 microM) or Fe2+ (10 microM) alone were of little effect on the extent of DNA ssb. The present data may shed light on the correlation reported between primary liver-cell carcinoma and intermittent acute porphyria.

Direct enzymic detection of endogenous oxidative base damage in human lymphocyte DNA

The endogenous production of oxidative damage in DNA by free radicals released as a by-product of respiration is a likely cause of mutations which, if they occur in appropriate genes, may lead to cancer. Using an endonuclease specific for oxidized pyrimidines, in conjunction with the highly sensitive method of single cell gel electrophoresis, we have detected significant oxidative damage in untreated, freshly isolated lymphocytes from normal, healthy individuals.

Immunochemical probing of DNA structure with monoclonal antibody to OsO4/2,2'-bipyridine adduct

Chemical modification with osmium tetroxide (OsO4) in the presence of 2,2'-bipyridine was employed for selective labeling of certain non-B DNA structures. A murine monoclonal antibody (IgG1) specific for deoxythymidine adduct of the modification was produced. It was demonstrated that the level of single-stranded DNA can be evaluated by enzyme-linked immunosorbent assay using the modification and monoclonal antibody. Site-specific OsO4-bipyridine modification followed by dot-blotting was used for probing of some unusual conformations occurring in supercoiled plasmids. The cruciform structures, B-Z junctions, and intramolecular triplex and long (A-T)n inserts were targets for the modification and small quantities of the labeled plasmids can be immunodetected. The method enabled to catch certain structural transitions within the same plasmid in vitro and to detect the left-handed Z DNA labeled inside bacteria. The antibody was also shown to recognize specifically the in situ modified DNA in cell nuclei and polytene chromosomes isolated from Drosophila melanogaster. Preferentially S1-nuclease-sensitive (single-stranded) regions of the nuclear and chromosomal DNA were stained by indirect immunofluorescence after the modification.

Distinction between supercoiled and linear DNA in transverse agarose pore gradient gel electrophoresis

Four species of linear DNA and the first four members of a linking series, generated by treatment of plasmid DNA (PUC19, 2.7 kb) with mitochondrial topoisomerase I, were differentiated by transverse agarose pore gradient gel electrophoresis. The experimental curves of migration distance vs. agarose concentration (Ferguson curves) of supercoiled DNA exhibit a steeper trajectory than those of linear DNA of the same size range. As a consequence, the four supercoiled species exhibit an increase in apparent size (relative to linear DNA standards) with increasing agarose concentration. Both the crossing of the Ferguson curves with those of linear standards as well as the apparent size increase with agarose concentration can serve to detect supercoiled plasmid-sized DNA in mixtures with linear DNA.

Dideoxynucleoside triphosphates inhibit a late stage of SV40 DNA replication in vitro

The role of DNA polymerases in the replication of SV40 DNA was studied using a T-antigen-dependent assay supplemented with a human KB cell extract. Inhibition of DNA polymerase alpha by addition of aphidicolin or monoclonal antibodies prevented DNA synthesis, confirming the requirement for this enzyme in replication. The replication process was unaffected by ddTTP at a concentration (5 microM) inhibitory to DNA polymerases beta and gamma, however, higher concentrations of ddTTP (200 microM) caused an apparent accumulation of relaxed circular plasmid with a concomitant decrease in DNA synthesis. An analysis of this replication intermediate indicated that it was formed during the replication reaction and that the replicative cycle was nearly complete. A kinetic study of ddTTP inhibition strongly suggested DNA polymerase epsilon (PCNA-independent DNA polymerase delta) was the target of the inhibitor and that this enzyme functions during the final stages of DNA replication.

Z-DNA as a probe for localized supercoiling in vivo

Biological processes such as transcription are expected to generate local variations in DNA supercoiling. The existence of localized supercoiling was recently demonstrated in Escherichia coli by using the supercoil-driven B-to-Z transition as a superhelicity probe. This new methodology is described and its extension to other biological systems discussed.