Abstract
DNA topology plays essential roles in several fundamental biological processes, such as DNA replication, recombination, and transcription. Typically agarose gel electrophoresis is employed to study DNA topology. Since gel electrophoresis is time-consuming and labor intensive, it is desirable to develop other methods, such as fluorescence-based methods, for such studies. In this paper we report the synthesis of a type of unique fluorescence-labeled DNA molecules that can be used to study DNA topology and topoisomerases by fluorescence resonance energy transfer (FRET). Specifically, we inserted an 82 nt. synthetic DNA oligomer FL905 carrying a 42 nt. AT sequence with fluorescein and dabcyl labels into a gapped DNA molecule to generate relaxed and supercoiled pAB1_FL905. Since the fluorescence intensity of pAB1_FL905 is dependent on its supercoiling status, pAB1_FL905 is a powerful tool to study DNA topology and topoisomerases by FRET. pAB1_FL905 can also be developed into rapid and efficient high-throughput screening assays to identify inhibitors that target various DNA topoisomerases.
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Introduction
DNA supercoiling is a fundamental property of chromosomal DNA and plays critical roles in many essential DNA transactions, such as transcription, DNA replication, and recombination1,2. Usually agarose gel electrophoresis is used to study DNA supercoiling. Since gel electrophoresis is time-consuming and labor intensive, it is desirable to develop other assays, such as fluorescence-based assays, to study DNA topology and topoisomerases. For example, fluorescence dyes, such as PicoGreen3, have been shown to differentially bind to supercoiled (sc) and relaxed (rx) DNA molecules to yield different fluorescence properties. These fluorescence dyes were used to study DNA topoisomerases. However, the difference of the fluorescence intensity of the dyes binding to sc and rx DNA is too small to be widely used to study properties of DNA topoisomerases and to screen inhibitors against these topoisomerases3.
Another type of assays were developed from the utility of a unique property of sc DNA molecules that prefer binding to triplex-form oligomers if the sc plasmids contain one or multiple triplex-forming sequences4,5. Maxwell and coworkers invented a method in which an immobilized triplex-forming oligomer more efficiently captures sc plasmids than rx plasmids4. The captured plasmids can be subsequently quantified by a DNA-binding dye, such as SYBR Green. However, this method requires immobilization of oligomer to a solid surface, filtration, and multiple washing steps. Since streptavidin-coated 1536-well plates are not commercially available, this method is not compatible with ultra-high throughput screening to identify gyrase inhibitors from small compound libraries using 1536-well plates. Another method, also based on the triplex-forming oligomers, was developed by using fluorescence anisotropy for the readout5. Nevertheless, the signal to noise ratio is a concern and an expensive fluorimeter with the capacity to measure fluorescence anisotropy is required5.
More recently, Berger and coworkers made a circular plasmid DNA template that contains a fluorophore (fluorescein) and quencher (dabcyl), and developed a real-time assay to study DNA topological changes with this fluorescently labeled DNA6. However, the production yield of the fluorescently labeled DNA was too low to allow the assay to be widely used6. Additionally, because of the low yield of the DNA substrate, it makes the assay too costly. Here we describe a method to produce a type of fluorescently labeled circular DNA molecules with high yields to study DNA topology and topoisomerases by fluorescence resonance energy transfer (FRET). We also demonstrate that these unique DNA molecules can be used to screen anti-cancer drugs and antibiotics targeting DNA topoisomerases.
Results and Discussion
Experimental strategies to construct relaxed (rx) and supercoiled (sc) pAB1_FL905
As demonstrated previously7,8,9, (-) supercoiling induces localized DNA conformation transitions, such as cruciform formation of inverted repeat sequences. These topology-dependent, structural isomerizations could be used to gauge the superhelicity of the DNA molecules. As shown by Lilley et al.10 and Mirkin et al.11,12,13,14, alternating adenine-thymine sequences [(AT)n] undergo very rapid cruciform formation, as no detectable kinetic barrier prevents rapid interconversion between extruded and unextruded conformations in sc plasmid DNA templates10. We therefore decided to utilize this property of [(AT)n] to monitor supercoiling change of plasmid DNA templates. We designed an 82 nt DNA oligomer FL905 that contains a dabcyl-labeled dT at 29th position from the 5′-end (the 8th position of the AT sequence from the 5′ end; Fig. 1A) and a fluorescein-labeled dT at 55th position from the 5′-end (the 34th position of the AT sequence from the 5′ end, Fig. 1A). Figure S1A shows that FL905 has intrinsic fluorescence before EB staining. We reasoned that if the 42 nt AT sequence adopts the hairpin structure, both the fluorescein and dabcyl are in close proximity in the major groove (~20 Å; Fig. 1B). The fluorescence of fluorescein should be greatly quenched. In contrast, when the 42 nt AT sequence adopts the double-stranded DNA form, the distance between the fluorescein and dabcyl should be more than 88.4 Å for B-form DNA (26 bp × 3.4 Å = 88.4 Å). Indeed, our molecular model shows that the distance between the fluorescein and dabcyl is ~100 Å (Fig. 1C). The fluorescence of fluorescein should not be quenched. Figure S1B shows a fluorescence melting experiment in which a four-fold fluorescence intensity change of fluorescein was observed upon the 42 nt AT hairpin structure was melted. This result demonstrates that fluorescence resonance energy transfer (FRET)15 can be used to study the interconversion between extruded and unextruded conformations of FL905.
Next, we constructed pAB1 by inserting a synthetic double-stranded oligomer FL_AT42, which carries the 42 bp AT sequence (Figure S1C), between the SphI and BamHI sites of pUC18 (Figure S1D). Plasmid pAB1 also contains two nicking edonuclease Nt.BbvCI recongnition sites in the same orientation. In this way, DNA oligomer FL905 can be inserted between the two Nt.BbvCI sites according to a strategy described in Fig. 2A (a similar strategy was used to study DNA recombination by Levene and coworks16 and label large DNA fragments17,18). Because rx pAB1_FL905 is the only theoretical ligation product, the production yeild should be near 100%. Sc pAB1_FL905 can be generated through the treatment of rx pAB1_FL905 by bacterial DNA gyrase in the presence of ATP (Fig. 2B). Rx and sc pAB1_FL905 should be powerful tools to study DNA topology and topoisomerases by FRET.
Fluorescence properties of relaxed, nicked, supercoiled pAB1_FL905
To date, we have produced ~0.5 mg of rx pAB1_FL905 and ~0.6 mg of sc pAB1_FL905 using the strategy described in Fig. 2 and purified by CsCl-EB equilibrium gradient banding with approximately 60% yield. A detailed procedure was provided in “Materails and Methods” and also in Figure S2. Figure S3 shows gel images at various stages of the procedure. As expected, rx and sc pAB1_FL905 have intrinsic fluorescence before EB staining (Figure S3D).
After we obtained rx and sc pAB1_FL905, we compared fluorescence properties of sc, rx, and nicked (nk) pAB1_FL905. Figure 3A shows our results. As expected, the fluorescence intensity of rx or nk pAB1_FL905 is significantly higher than that of the sc pAB1_FL905. Figure 3B–D show kinetic results of pAB1_FL905 reacting with three different enzymes: Nt.BbvCI, E. coli topoisomerase I, and E. coli DNA gyrase. As anticipated, Nt.BbvCI was able to quickly nick sc pAB1_FL905 with a half-life of ~15 seconds (Fig. 3B). This result supports previous conclusions regarding (AT)n that undergoes very rapid cruciform formation, as no detectable kinetic barrier prevents rapid interconversion between extruded and unextruded conformations in sc plasmid DNA templates10. It also suggests that pAB1_FL905 is a good DNA substrate to study DNA topology and topoisomerases by FRET. Similarly, large amounts of E. coli DNA topoisomerase I was able to rapidly relax sc pAB1_FL905 (Fig. 3C). The kinetics of E. coli DNA gyrase was relatively slow (Fig. 3D). Nevertheless, further studies are required to determine kinetic parameters of these enzymes.
We also designed three similar fluorescence-labeled oligomers. FL919 and FL920 contain a dabcyl-labeled dT at 27th and 31st position, and a fluorescein-labeled dT at 57th and 53th position from the 5′-end, respectively. In other words, the distance between the dabcyl and fluorescein is different for FL905, FL919, and FL920. FL924 carries a BHQ2-labeled dT at 29th position from the 5′-end (the 8th position of the AT sequence from the 5′ end; Figure S5) and a TAMRA-labeled dT at 55th position from the 5′-end (the 34th position of the AT sequence from the 5′ end, Figure S5). These three oligomers were inserted between the two Nt.BbvCI sites of pAB1 to yield rx and sc pAB1_FL919, pAB1_FL920, and pAB1_FL924. Figures S4 and S5 show fluorescence properties of these DNA molecules. Similar to pAB1_FL905, the fluorescence intensity of rx pAB1_FL919, pAB1_FL920, and pAB1_FL924 is significantly higher than that of the sc DNA molecules (Figures S4 and S5). However, the FRET efficiency of pAB1_FL919 and pAB1_FL920 is lower than that of pAB1_FL905. This result demonstrated that FL905 has the optimal distance between dabcyl and fluorescein for studying supercoiling-dependent transitions of pAB1 by FRET. As expected, the fluorescence intensity of pAB1_FL924 is lower than that of pAB1_FL905 although the FRET efficiency is similar for both DNA molecules.
Potential applications
Rx or sc fluorescently labeled pAB1_FL905 or similar DNA molecules should have many potential applications. As shown above, they can be used to study supercoiling-dependent DNA topological changes or determine biochemical properties and kinetics of various DNA topoisomerases. Neverteless, in our opinion, the most important application of these DNA molecules is to screen inhibitors or compounds targeting different DNA topoisomerases since many of these compounds are either anticancer drugs, such as doxorubicin19, or antibiotics, such as ciprofloxacin20. Figure S6A shows a strategy for identifying bacterial DNA gyrase inhibitors. In the absence of gyrase inhibitors, bacterial DNA gyrase is capable of converting rx DNA templates into sc DNA molecules. As demonstrated above, this conversion results in quenching of fluorescence of pAB1_FL905. However, DNA gyrase inhibitors should inhibit this conversion. In this way, the fluorescence intensity of rx pAB1_FL905 should not be changed. A titration experiment should also yeild an inhibition IC50 for the gyrase inhibitor. According to this strategy, we performed titration experiments in which different concentrations of novobiocin and ciprofloxacin were added into DNA supercoiling assays. Figure 4 shows our results. Novobiocin and ciprofloxacin potently inhibited the activities of DNA gyrase with an estimated IC50 of 0.48 ± 0.14 and 2.57 ± 1.62 μM, respectively. Agarose gel electrophoresis confirmed that these antibiotics indeed potently inhibited DNA gyrases activities (Figure S6B). Due to simplicity, this FRET assay can be easily to adapt into a high throughput format to identify gyrase inhibitors from millions of compounds found in small molecule libraries. Similar assays may be used to identify inhibitors targeting other DNA topoisomerase, such human DNA topoisomerase I and II. Furthermore, fluorescently labeled sc or rx plasmid DNA molecules may be used to study DNA recombination16 or other supercoiling-dependent structural transitions, such as supercoiling-induced G-quadruplex21.
In summary, we have invented a novel method to produce a type of fluorescence-labeled rx or sc DNA molecule, such as pAB1_FL905 in the milligram range. This type of DNA molecules could be developed into powerful tools to study DNA topology and topoisomerases. Since only a few nano grams of pAB1_FL905 are needed for 384-well or 1536-well plates for detection, these DNA molecules could be used to develop rapid and efficient high-throughput screening assays to identify inhibitors from the millions of compounds found in small molecule libraries that may target DNA topoisomerases, such as bacterial DNA gyrase and human DNA topoisomerase I & II.
Methods
Materials
Restriction enzymes Nt.BbvCI, SphI, BamHI, E. coli DNA gyrase, and T4 DNA ligase were purchased from New England Biolabs (Beverly, MA, USA). E. coli DNA topoisomerase I was purified as described previously22. The following synthetic oligonucleotides were purchased from MWG-Biotech, Inc. (Huntsville, AL): FL882 (5′-CCCTCAGCCCGACAGCACGAGACGATATATATATATATATATATATATATATATATATATATATATGGGCCAACCAACCAGCCCCTCAGCG-3′), FL883 (5′-GATCCGCTGAGGGGCTGGTTGGTTGGCCCATATATATATATATATATATATATATATATATATATATATATCGTCTCGTGCTGTCGGGCTGAGGGCATG-3′), FL905 (5′-TCAGCCCGACAGCACGAGACGATATATA[Dab-dT]ATATATATATATATATATATATATA[Fl-dT]ATATATATGGGCCAACCAACCAGCCCC-3′), FL919 (5′-TCAGCCCGACAGCACGAGACGATATA[Dab-dT]ATATATATATATATATATATATATATATA[Fl-dT]ATATATGGGCCAACCAACCAGCCCC-3′), FL920 (5′-TCAGCCCGACAGCACGAGACGATATATATA[Dab-dT]ATATATATATATATATATATA[Fl-dT]ATATATATATGGGCCAACCAACCAGCCCC-3′), and FL924 (5′-TCAGCCCGACAGCACGAGACGATATATA[BHQ2-dT]ATATATATATATATATATATATATA[TAM-dT]ATATATATGGGCCAACCAACCAGCCCC-3′) where Dab-dT, Fl-dT, BHQ2-dT, and TAM-dT represent dabcyl-dT, fluorescein-dT, BHQ2-dT, and TAMRA-dT, respectively. QIAquick Nucleotide Removal Kit and QIAquick Gel Extraction Kit were obtained from Qiagen, Inc (Valencia, CA).
Plasmids
Plasmid pAB1 (2,757 bp) was constructed by inserting a 95 bp synthetic DNA fragment FL_AT42 (the annealing product of FL882 and FL883) between the SphI and BamHI sites of pUC18. DNA sequencing was used to verify the inserted DNA sequence.
Synthesis of relaxed (rx) and supercoiled (sc) pAB1_FL905, pAB1_FL919, pAB1_FL920, and pAB1_FL924
For a typical small scale of reaction, 10 μg of pAB1 (~5.7 pmol) was digested by 25 units of Nt.BbvCI in 200 μL of 1 × CutSmart Buffer (50 mM KAc, 20 mM Tris-Ac, 10 mM Mg(AC)2, 100 μg/mL BSA, pH 7.9). After the digestion, 80 pmol of phosphorylated FL905 was added into the reaction mixture. The reaction mixture was incubated at 90 °C in a 4-liter water bath for one minute and then cooled down to room temperature in the water bath (~4 to 5 hours; usually this step was carried out overnight). To generate rx pAB1_FL905, 300 units of T4 DNA ligase were added into the reaction mixtures in the presence of 10 mM of DTT and 2 mM of ATP (final concentrations). The reaction mixtures were incubated at 37 °C to seal the nicks and yield rx pAB1_FL905. The rx pAB1_FL905 was separated by 1% agarose gel electrophoresis and purified by QIAquick Gel Extraction Kit. Typically, we were able to obtain ~6 μg of rx pAB1_FL905 (~60% yield). To produce sc pAB1_FL905, 1 μg of rx pAB1_FL905 was treated with 5 units of E. coli DNA gyrase for 1 hour at 37 °C. The sc pAB1_FL905 can be purified by QIAquick Nucleotide Removal Kit or separated by 1% agarose gel and purified by QIAquick Gel Extraction Kit. An alternative procedure was also used to produce sc pAB1_FL905. First, the annealed product of the Nt.BbvCI digested pAB1 and FL905 was purified by QIAquick Nucleotide Removal Kit. The purified DNA sample (~1 μg) was ligated with 300 units of T4 DNA ligase in the presence of 5 units of DNA gyrase. The sc and rx pAB1_FL905 were separated by using a 1% agarose gel and purified by using QIAquick Gel Extraction Kit. Rx and sc pAB1_FL919, pAB1_FL920, and pAB1_FL924 were also generated similarly.
For a typical large scale of reaction, 1 mg of pAB1 (~570 pmol) was digested by 2,500 units of Nt.BbvCI in 20 mL of 1 × CutSmart Buffer for one hour at 37 °C. After the digestion, 8,000 pmol of phosphorylated FL905 was added into the reaction mixture. The reaction mixture was incubated at 90 °C in a 4-liter water bath for two minutes and then cooled down to room temperature in the water bath (~4 to 5 hours; usually this step was carried out overnight). To generate rx pAB1_FL905, 25,000 units of T4 DNA ligase were added into the reaction mixtures in the presence of 10 mM of DTT and 2 mM of ATP (final concentrations). The reaction mixtures were incubated at 37 °C to seal the nicks and yield the relaxed pAB1_FL905. The unpurified rx pAB1_FL905 sample was extracted with 20 mL of phenol, precipitated with ethanol, and washed once with 70% ethanol. Rx pAB1_FL905 was purified by CsCl-EB equilibrium gradient banding. A total of 486 μg of rx pAB1_FL905 was produced by this procedure. To generate sc pAB1_FL905, the ligation reaction was carried out in the presence of 25 μM of ethidium bromide. The unpurified sc pAB1_FL905 sample was extracted twice with 20 mL of phenol, precipitated with ethanol, and washed once with 70% ethanol. Sc pAB1_FL905 was purified by CsCl-EB equilibrium gradient banding. Alternatively, after phenol extraction and ethanol precipitation, the unpurified rx pAB1_FL905 sample was treated with E. coli DNA gyrase in the presence of 2 mM of ATP at 37 °C for one hour to yield sc pAB1_FL905. Sc pAB1_FL905 was purified by CsCl-EB equilibrium gradient banding. A total of 571 μg of sc pAB1_FL905 was obtained.
Fluorescence spectroscopy
Fluorescence measurements were preformed using an ISS, Inc., PC1 photo counting spectrofluorimeter with an excitation wavelength of 470 nm and bandwidth resolution of ±4 nm or a Biotek Synergy H1 Hybrid Plate Reader with an excitation wavelength of 482 nm.
Gyrase inhibition assay
DNA gyrase inhibition assays were performed in 50 μL of 1× gyrase buffer (35 mM Tris-HCl, 24 mM KCl, 4 mM MgCl2, 2 mM DTT, 1.75 mM ATP, 5 mM spermidine, 0.1 mg/mL BSA, 6.5% glycerol, pH7.5) containing 560 ng of of rx pAB1_FL905 and equilibrated to 37 °C. 20 units of DNA gyrase was used to supercoil the rx pAB1_FL905 in the presence of different concentrations of novobiocin and ciprofloxacin. The fluorescence intensity at λem = 521 nm was monitored with λex = 494 nm in a microplate reader. The IC50 values were estimated by nonlinear fitting of the following equation: where F is the fluorescence intensity at the x concentration of an inhibitor. Fmax and Fmin are the maximum and minimum fluorescence of the DNA sample, respectively. P is a slope parameter.
Molecular Modeling
DNA molecular models are generated using HyperChem 8.0.
Additional Information
How to cite this article: Gu, M. et al. Fluorescently labeled circular DNA molecules for DNA topology and topoisomerases. Sci. Rep. 6, 36006; doi: 10.1038/srep36006 (2016).
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Acknowledgements
This work was supported by grant 1R15GM109254-01A1 from the National Institutes of Health (to F.L.).
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F.L. designed research; M.G., A.B., W.G.G. and F.L. performed research; F.L. constructed the molecular models; F.L., J.M. and J.W.C. analyzed data; F.L. wrote the paper.
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Gu, M., Berrido, A., Gonzalez, W. et al. Fluorescently labeled circular DNA molecules for DNA topology and topoisomerases. Sci Rep 6, 36006 (2016). https://doi.org/10.1038/srep36006
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