DNase I susceptibility of bent DNA and its alteration by ditercalinium and distamycin

The bending of kinetoplast DNA from Crithidia fasciculata is thought to be related to the periodic distribution of AA or TT cluster sequences. The sensitivity to DNase I of the two strands of this DNA was analyzed at nucleotide resolution by sequencing gel electrophoresis. The effect on the DNase I cleavage pattern of two drugs, ditercalinium and distamycin, that are able to remove bending was analyzed. The same analysis was done on a pBR 322 DNA fragment of random sequence as a control. The periodic distribution of the AA or TT clusters in the bent DNA fragment was first analyzed by computing the autocorrelation function of the AA or TT clusters in the bent DNA fragment. It is shown that the AT tracts are on average 10.5 base pairs apart. This value is almost identical with that of the B-DNA helix pitch in solution [10.5 (Wang, 1979); 10.6 +/- 0.1 (Rhodes & Klug, 1980)]. To reveal the periodic pattern of DNase I cleavage on this bent DNA, alone or in presence of drugs, the cross correlation between the different bands obtained from DNAse I cleavage and the presence of AA or TT sequences was computed. This shows that GC and mixed sequences are the most sensitive regions. These data also suggest that there is a periodic fluctuation in the width of the minor groove in the bent fragment. Ditercalinium and distamycin alter the DNase I cutting pattern of the bent DNA fragment but in an inverse fashion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of sequence selective drugs on the gel mobility of a bent DNA fragment.

The effects of various drugs on the structure of a bent DNA fragment have been investigated by studying DNA mobility in polyacrylamide gels. This DNA fragment has an anomalously slow rate of migration on account of its phased runs of adenines. Nogalamycin and echinomycin increase the gel mobility of kinetoplast DNA suggesting that the bending has been removed. Mithramycin, actinomycin, distamycin and ethidium have either no effect or cause a further reduction in mobility. These results are compared with other, non-bent DNA species which always show a decrease in gel mobility in the presence of DNA binding drugs.     

Phased adenine tracts in double-stranded RNA do not induce sequence-directed bending

Tracts of four to six adenines phased with the DNA helix produce a sequence-directed bending of the helix axis. Here, using gel electrophoresis and electron microscopy (EM), we have asked whether a similar motif will induce bending in a duplex RNA helix. Single-stranded RNAs were transcribed either from short synthetic DNA templates or from Crithidia fasciculata kinetoplast bent DNA, and the complementary single-stranded RNAs were annealed to produce duplex RNA molecules containing blocks of four to six adenines. Electrophoresis on polyacrylamide gels revealed no retardation of the RNAs containing phased blocks of adenines relative to duplex RNAs lacking such blocks. Examination by EM showed most of the molecules to be straight or only slightly bent. Thus, in contrast to DNA duplexes, phased adenine tracts do not induce sequence-directed bending in double-stranded RNA. Analysis of the distribution of molecule shapes for the highly bent C. fasciculata DNA showed that the adenine blocks do not act cooperatively to induce DNA bending and that the molecules must equilibrate between a spectrum of bent shapes.     

A structural analysis of the bent kinetoplast DNA from Crithidia fasciculata by high resolution chemical probing.

The chemical probes potassium permanganate (KMnO4) and diethylpyrocarbonate (DEPC) have been used to study the conformation of bent kinetoplast DNA from Crithidia fasciculata at different temperatures. Chemical reactivity data shows that the numerous short A-tracts of this bent DNA adopt a similar structure at 43 degrees C. This conformation appears to be very similar to the conformation of A-tracts in DNA exhibiting normal gel mobility. The A-tract structure detected by chemical probing is characterized by a high degree of base stacking on the thymine strand, and by an abrupt conformational change at the 3' end of the adenine strand. In general, no major alteration of this A-tract specific structure was detected between 4-53 degrees C. However, probing with KMnO4 revealed two unusual features of the C. fasciculata sequence that may contribute to the highly aberrant gel mobility of this DNA: 1) the B DNA/A-tract junction 5' dC/A3-6 3'. 5' dT3-6/G 3' is disproportionately represented and is conformationally distinct from other 5' end junctions, and 2) low temperature favors a novel strand-specific conformational distortion over a 20 base pair region of the bent kinetoplast DNA. Presence of the minor groove binding drug distamycin had little detectable effect on the A-tract conformation. However, distamycin did inhibit formation of the novel KMnO4 sensitive low temperature structure and partially eliminated the anomalous gel mobility of the kinetoplast DNA. Finally, we describe a simple and reproducible procedure for the production of an adenine-specific chemical DNA sequence ladder.     

Minor groove to major groove, an unusual DNA sequence-dependent change in bend directionality by a distamycin dimer

DNA sequence-dependent conformational changes induced by the minor groove binder, distamycin, have been evaluated by polyacrylamide gel electrophoresis. The distamycin binding affinity, cooperativity, and stoichiometry with three target DNA sequences that have different sizes of alternating AT sites, ATAT, ATATA, and ATATAT, have been determined by mass spectrometry and surface plasmon resonance to help explain the conformational changes. The results show that distamycin binds strongly to and bends five or six AT base pair minor groove sites as a dimer with positive cooperativity, while it binds to ATAT as a weak, slightly anticooperative dimer. The bending direction was evaluated with an in phase A-tract reference sequence. Unlike other similar monomer minor groove binding compounds, such as netropsin, the distamycin dimer changes the directionality of the overall curvature away from the minor groove to the major groove. This distinct structural effect may allow designed distamycin derivatives to have selective therapeutic effects.     

Capillary electrophoresis as a technique to analyze sequence-induced anomalously migrating DNA fragments.

Sequence-induced anomalous migration of double-stranded (ds) DNA in native gel electrophoresis is a well known phenomenon. The retardation of migration is more obvious in polyacrylamide compared with agarose gels, and is greatly affected by the concentration of the gel and the temperature. This anomalous migration results in a difference between calculated and actual sizes of the affected DNA fragments. A low viscosity polymer solution (DNA Fragment Analysis Reagent) under investigation for use in dsDNA analysis by capillary electrophoresis is shown to be useful for the visualization of anomalies in migration of dsDNA fragments. Comparable with traditional slab gel systems, the retardation effect, indicative of bent or curved DNA, is strongly dependent on polymer concentration and separation temperature. These dependencies have implications on the accurate sizing of dsDNA fragments with unknown sequences and secondary structures.     

Conformational correlatives of DNA band compression and bidirectional migration during field inversion gel electrophoresis, detected by quantitative video epifluorescence microscopy.

Individual DNA molecules in the Mb size range were monitored by epifluorescence video microscopy during field inversion gel electrophoresis (FIGE). DNA migrating in an agarose gel gives rise to characteristic V-conformational elements and when doing so exhibits a reduced mobility. When the V-conformational elements per DNA molecule are few, the degree of retardation appears proportional to the number of V's, and since larger DNA species exhibit more V's, to DNA size. For a particular pulse frequency, the proportionality breaks down progressively as the number of V-conformational elements per DNA molecule increases. The loss of proportionality between DNA length and migration rate is being correlated with the macroscopically observed loss of electrophoretic size discrimination known as band compression. For a particular pulsing frequency and size class of DNA, the loss of size discrimination is thought to be due to the different orientations of migration, caused by the asymmetric distribution of V-conformational elements when the number of these elements is moderate. Small and very large DNA by contrast migrate with the direction of the biased field. These events, analyzed by microscopic measurement, are consistent with the known macroscopically observed double-valued mobilities in FIGE.     

Antibiotic induced electrophoretic mobility shifts of DNA restriction fragments.

Several antibiotics, netropsin, distamycin A, actinomycin D, Hoechst 33258 and olivomycin, which demonstrate base specificity in their DNA binding properties have been found to alter the electrophoretic mobility of DNA restriction fragments in native polyacrylamide gels. The antibiotics mostly reduced the migration of larger DNA fragments, but netropsin and Hoechst 33258 were observed to increase the migration rate of several DNA fragments of intermediate size. DNA fragments of similar molecular weight which comigrate as a single gel band can at times be separated as the result of differential mobility shifts promoted by antibiotic DNA complex formations.     

The structure of kinetoplast DNA. 1. The mini-circles of Crithidia lucilae are heterogeneous in base sequence.

We have analysed limit digests of mini-circles from kinetoplast DNA of Crithidia luciliae by gel electrophoresis. Endonucleases HapII and AluI cut the circles into at least 37 and 21 fragments, respectively, and leave no circles intact. In both cases the added molecular weights of the fragments, estimated from mobility in gels, exceeds 18 X 10(6), i.e. more than 12 times the molecular weight of the mini-circle DNA. Endonucleases HindII + III, EcoRI and HpaI cut only part of the circles. These results show that the mini-circles are heterogeneous in base sequence. Different sequence classes are present in different amounts. DNA-DNA renaturation analysis of mini-circle DNA yields a complexity of about 3 X 10(6), i.e. twice the molecular weight on one mini-circle. The delta tm of native and renatured duplexes is about 1 degree C, showing that the sequence heterogeneity is a micro-heterogeneity. Electron microscopy, gel electrophoresis and sedimentation analysis show that the circles that are not cut by endonucleases HindII + III remain catenated in very large associations. These associations lack the 'rosette' structures and the long edge loops characteristic of intact kinetoplast DNA. This suggests that the mini-circle classes cut by endonucleases HindII + III are present throughout the network and that the maxi-circle component of the network (see accompanying paper) is not essential to hold the network together. Prolonged electrophoresis on 1.5% or 2% agarose gels resolves the open mini-circles into three and linearized mini-circles into four bands, present in different amounts. We conclude that the mini-circles are also heterogeneous in size, the difference in size between the two extreme size classes being 4% of the contour length. Digestion with endonuclease HapII shows that at least three out of these four bands differ in sequence. Possible mechanisms that could account for the micro-heterogeneity in sequence of mini-circles are discussed.     

DNA Packaging-Associated Hyper-Capsid Expansion of Bacteriophage T3

Evidence that in vivo bacteriophage T3 DNA packaging includes capsid hyper-expansion that is triggered by lengthening of incompletely packaged DNA (ipDNA) is presented here. This evidence includes observation that some of the longer ipDNAs in T3-infected cells are packaged in ipDNA-containing capsids with hyper-expanded outer shells (HE ipDNA-capsids). In addition, artificially induced hyper-expansion is observed for the outer shell of a DNA-free capsid. Detection and characterization of HE ipDNA-capsids are based on two-dimensional, non-denaturing agarose gel electrophoresis, followed by structure determination with electron microscopy and protein identification with SDS-PAGE/mass spectrometry. After expulsion from HE ipDNA-capsids, ipDNA forms sharp bands during gel electrophoresis. The following hypotheses are presented: (1) T3 has evolved feedback-initiated, ATP-driven capsid contraction/hyper-expansion cycles that accelerate DNA packaging when packaging is slowed by increase in the packaging-resisting force of the ipDNA and (2) each gel electrophoretic ipDNA band reflects a contraction/hyper-expansion cycle.     

Mammalian topoisomerase II activity is modulated by the DNA minor groove binder distamycin in simian virus 40 DNA

DNA topoisomerases II are nuclear enzymes that have been identified recently as targets for some of the most active anticancer drugs. Antitumor topoisomerase II inhibitors such as teniposide (VM-26) produce enzyme-induced DNA cleavage and inhibition of enzyme activity. By adding to such reactions distamycin, a compound whose effects on DNA have been extensively characterized, we investigated the effects of drug binding upon topoisomerase II-mediated DNA cleavage induced by VM-26. We have found a correspondence between distamycin binding (determined by footprinting analysis) and topoisomerase II-mediated cleavage of SV40 DNA (determined by sequencing gel analysis). Distamycin binding potentiated the cleavage of specific sites in the near proximity of distamycin-binding sites (within at least 25 base pairs), which indicates that DNA secondary structure is involved in topoisomerase II-DNA interactions. That distamycin potentiated cleavage only at sites that were recognized in the absence of distamycin and suppressed cleavage directly at distamycin-binding sites indicates that topoisomerase II recognizes DNA on the basis of primary sequence. In addition, distamycin stimulated topoisomerase II-mediated DNA relaxation and antagonized the inhibitory effect of VM-26. These results show that the DNA sequence-specific binding of distamycin produces local and propagated effects in the DNA which markedly affect topoisomerase II activity.     

Visualization of the bent helix in kinetoplast DNA by electron microscopy

Kinetoplast DNA minicircles from the trypanosomatid Crithidia fasciculata contain a segment of approximately 200 bp which is probably more highly bent than any other DNA previously studied. Electron microscopy (EM) of relaxed minicircles (2.5 kb) revealed 200-300 bp loops within the larger circles, and the loops could also be detected on full-length linear molecules. Examination by EM of a 219 bp cloned fragment which contains the bent helix revealed that up to 70% of the molecules appeared circular whether or not the ends were cohesive. In contrast, a 207 bp fragment from pBR322 showed no circles and the fragments in general appeared much straighter than the kinetoplast fragments. Treatment of the 219 bp bent kinetoplast fragment with the drug distamycin caused a striking reduction in curvature.     

Curved DNA fragments display retarded elution upon anion exchange HPLC.

Restriction fragments containing established curved regions, such as the pBR322 tn3 region, the phage lambda attP region and the SV40 T-antigen and terminus of replication regions, exhibit systematically retarded elution upon anion exchange based HPLC. Using this method, we were able to detect readily other SV40 curved regions, exhibiting also the polyacrylamide gel electrophoresis retardation anomaly, including several RNA polymerase initiation sites. Unlike gel retardation, HPLC retardation exhibited by curved DNA persists at 55 degrees C and is observed for fragments ranging from 150 bp up to 5 kb. The observed preferential attachment of DNA fragments containing curved DNA to the ionic groups of the column suggests a common dipole character of these regions due to the local accumulation of charges resulting apparently from the compression in the minor groove of curved DNA.     

Conformational analysis of site-specific DNA cross-links of cisplatin-distamycin conjugates

The requirement for novel platinum antitumor drugs led to the concept of synthesis of novel platinum drugs based on targeting cisplatin to various carrier molecules. We have shown [Loskotova, H., and Brabec, V. (1999) Eur. J. Biochem. 266, 392-402] that attachment of DNA minor-groove-binder distamycin to cisplatin changes several features of DNA-binding mode of the parent platinum drug. Major differences comprise different conformational changes in DNA and a considerably higher interstrand cross-linking efficiency. The studies of the present work have been directed to the analysis of oligodeoxyribonucleotide duplexes containing single, site-specific adducts of platinum-distamycin conjugates. These uniquely modified duplexes were analyzed by Maxam-Gilbert footprinting, phase-sensitive gel electrophoresis bending assay and chemical probes of DNA conformation. The results have indicated that the attachment of distamycin to cisplatin mainly affects the sites involved in the interstrand cross-links so that these adducts are preferentially formed between complementary guanine and cytosine residues. This interstrand cross-link bends the helix axis by approximately 35 degrees toward minor groove, unwinds DNA by approximately 95 degrees and distorts DNA symmetrically around the adduct. In addition, CD spectra of restriction fragments modified by the cisplatin-distamycin conjugates have demonstrated that distamycin moiety in the interstrand cross-links of these compounds interacts with DNA. This interaction facilitates the formation of these adducts. Hence, the structural impact of the specific interstrand cross-link detected in this study deserves attention when biological behavior of cisplatin derivatives targeted by oligopeptide DNA minor-groove-binders is evaluated.     

Electrophoretic analysis of covalently closed SV40 DNA: Boltzmann distributions of DNA species.

Covalently closed relaxed SV40 DNA [SV40(I')] generated by polynucleotide ligase closure of nicked circular SV40 DNA was analyzed by agarose gel electrophoresis. The DNA can be resolved into a series of bands differing in superhelical density whose intensities are approximately symmetrical about a central most intense band. Densitometric analysis of the gel pattern has revealed that the distribution of DNA species conforms to a Boltzmann distribution and has enabled us to derive an equation for the free energy of superhelix formation for SV40 DNA. We believe the observed bands reflect the time-averaged distribution of thermally induced fluctuations in DNA chain conformation in solution at the time of ligase catalyzed phosphodiester bond formation. Densitometric analysis of native supercoiled SV40 DNA, partially unwound in the presence of ethidium bromide, demonstrates that the separation between adjacent bands is approximately half that seen with SV40(I'). Agarose gel electrophoresis was also used to measure the change in average base rotation angle as a function of temperature by a procedure independent of ethidium dye binding.     

Physical characterization of a kinetoplast DNA fragment with unusual properties

A 414-base pair fragment from a Leishmania tarentolae kinetoplast DNA minicircle has unusual physical properties. We reported previously that in comparison to phi X174 and pBR322 control fragments, the kinetoplast fragment behaves in gel electrophoresis, gel filtration, and electric dichroism experiments as if it has an unusually compact conformation. We accounted for these unusual properties by proposing that the fragment is a systematically bent helix (Marini, J.C., Levene, S.D., Crothers, D.M., and Englund, P.T. (1982) Proc. Natl. Acad. Sci. U.S.A. 79, 7664-7668). In this paper, we further explore the properties of the kinetoplast fragment. Because of its compact conformation, the kinetoplast fragment has difficulty in snaking through polyacrylamide gels and therefore migrates unusually slowly in electrophoresis experiments. Warming (53 degrees C) and ethanol (5-20%) partially normalize gel migration; glyoxal treatment results in denatured strands with electrophoretic mobility close to that expected for their size. In vivo modification does not appear to be responsible for the fragment's properties; its anomalous electrophoretic behavior persists after proteinase K treatment, phenol extraction, or after cloning into pBR322 and reisolation. Velocity sedimentation experiments rule out fragment aggregation. Secondary structure, such as a cruciform, is not detectable by S1 or mung bean nuclease digestion. The kinetoplast fragment has circular dichroism spectra characteristic of a B-type helix. With increasing temperature, there is an increase in the 270/280 ellipticity ratio. Circular dichroism spectra taken in the presence of ethanol show a B to A helix transition at unusually low ethanol concentrations (between 44 and 54% (w/w]. Thermal denaturation reveals a triphasic melting curve.     

Intramolecular DNA melting between stable helical segments: melting theory and metastable states.

Melting of DNA in a segment bounded at both ends by regions of greater stability during electrophoresis in denaturing gradient gels show complex properties, not accommodated with standard melting theory. Compact bands of some DNA molecules become anomalously broadened at the retardation level in a denaturing gradient, or double bands may appear in a uniform denaturant concentration. These properties are associated only with molecules for which the distribution of stability calculated by the Poland-Fixman-Freire algorithms indicates that the region of lowest stability does not extend to an end of the molecule. Retention of helicity at the ends is shown by the difference in the effect of base substitution in the end domains and in the least stable domain. Both the appearance of double bands and band broadening can be explained by invoking a hypothetical metastable intermediate in melting, which is converted into the equilibrium melted form at a relatively slow rate, depending on both denaturant concentration and field strength. A kinetic model permits plausible rate constants to be inferred from the patterns. Despite the increased band width, sequence variants with base changes in the least stable domain result in readily detectable band shifts in the gradient.     

Bending of DNA by gene-regulatory proteins: construction and use of a DNA bending vector

The binding of a protein to its specific sequence, borne on a DNA fragment, retards the mobility of the fragment in a characteristic way during gel electrophoresis. If the protein induces bending in the DNA, the contortion can also be monitored by gel electrophoresis, because the amount of retardation of the mobility of the DNA-protein complex is dependent upon the position and the degree of the bend induced in the DNA fragment [Wu and Crothers, Nature 308 (1984) 509-513]. We have constructed a plasmid, pBend2, which can generate a large number of DNA fragments of identical length in which the protein-binding nucleotide sequence is located in circular permutations. The vector contains two identical DNA segments containing 17 restriction sites in a direct repeat spanning a central region containing cloning sites. The protein-binding sequence is inserted at one of these cloning sites. To investigate the functional significance of bending, we have compared, using pBend2, the cAMP.cAMP-receptor protein (CPR)-induced bending of CRP-binding sites found in five different genes of Escherichia coli. We have also shown that the bacteriophage lambda 0R1 operator DNA is bent when complexed with the CI or Cro repressor of the phage.     

Fractionation and characterization of DNA at sites of replication from rat liver nuclei

Regenerating rat liver nuclei when sonicated and centrifuged in a Cs2SO4 gradient were fractionated into three distinct bands. These bands were designated as light band (LB), middle band (MB), and heavy band (HB) according to their density. LB and MB were shown to consist of large granular particles with varying electron densities, but LB also contained remnants of nuclear membrane. When analysed by gel electrophoresis, LB and MB displayed more than 35 bands of proteins. The third fraction, HB, consisted largely of small chromatin fibers and its proteins were predominantly the four histones of the nucleosomal core particle. Following short pulses with [3H]thymidine in vivo, the specific activity of DNA in LB and MB was significantly higher than that of bulk DNA contained in HB. DNA in all three fractions became equally labelled as the duration of the labelling interval increased beyond 30 min. Newly synthesized DNA was characterized by electrophoresis on analytical 1.7% acrylamide -0.5% agarose composite gels. After a 1-min labelling interval in vivo, 17% of the rapidly labelled DNA from LB and MB was stationary at the gel origin like replication forks from E. coli, but only 3% of HB DNA had zero mobility. Electron microscopy confirmed the presence of DNA replication forks in LB, MB, and HB. With increasing time of synthesis the proportion of labelled DNA exhibiting zero mobility decreased in all three fractions. Denaturation of DNA or digestion of single-stranded DNA with S1 nuclease released newly synthesized DNA from the gel origin. Ribonuclease was without effect. DNA recovered from LB and MB also had a higher molecular weight than the HB DNA. Together these results indicate (1) that LB and MB are enriched in newly replicated DNA; (2) that an increased proportion of newly replicated DNA in LB and MB is associated with DNA replication forks; and (3) that the replicating DNA recovered in LB and MB may be associated with other nuclear constituents in situ because this DNA appears to be protected from the more frequent chain breaks introduced into the bulk of chromatin (HB) by sonication.