FEDS: a Novel Fluorescence-Based High-Throughput Method for Measuring DNA Supercoiling In Vivo.

DNA supercoiling (DS) is essential for life because it controls critical processes, including transcription, replication, and recombination. Current methods to measure DNA supercoiling in vivo are laborious and unable to examine single cells. Here, we report a method for high-throughput measurement of bacterial DNA supercoiling in vivoFluorescent evaluation of DNA supercoiling (FEDS) utilizes a plasmid harboring the gene for a green fluorescent protein transcribed by a discovered promoter that responds exclusively to DNA supercoiling and the gene for a red fluorescent protein transcribed by a constitutive promoter as the internal standard. Using FEDS, we uncovered single-cell heterogeneity in DNA supercoiling and established that, surprisingly, population-level decreases in DNA supercoiling result from a low-mean/high-variance DNA supercoiling subpopulation rather than from a homogeneous shift in supercoiling of the whole population. In addition, we identified a regulatory loop in which a gene that decreases DNA supercoiling is transcriptionally repressed when DNA supercoiling increases.IMPORTANCE DNA represents the chemical support of genetic information in all forms of life. In addition to its linear sequence of nucleotides, it bears critical information in its structure. This information, called DNA supercoiling, is central to all fundamental DNA processes, such as transcription and replication, and defines cellular physiology. Unlike reading of a nucleotide sequence, DNA supercoiling determinations have been laborious. We have now developed a method for rapid measurement of DNA supercoiling and established its utility by identifying a novel regulator of DNA supercoiling in the bacterium Salmonella enterica as well as behaviors that could not have been discovered with current methods.

Two-Dimensional Gel Electrophoresis to Resolve DNA Topoisomers.

Agarose gel electrophoresis is one of the most straightforward techniques that can be used to differentiate between topoisomers of closed circular DNA molecules. Generally, the products of reactions that monitor the interconversion of DNA between negatively supercoiled and relaxed DNA or positively supercoiled and relaxed DNA can be resolved by one-dimensional gel electrophoresis. However, in more complex reactions that contain both positively and negatively supercoiled DNA, one-dimensional resolution is insufficient. In these cases, a second dimension of gel electrophoresis is necessary. This chapter describes the technique of two-dimensional agarose gel electrophoresis and how it can be used to resolve a spectrum of DNA topoisomers.

Quality assessment of supercoiled minicircle DNA by cadaverine-modified analytical chromatographic monolith.

Minicircle DNA (mcDNA) is the ultimate non-viral DNA vector, presenting higher biosafety and therapeutic effect than conventional plasmid DNA (pDNA). However, given the similarity between mcDNA and its precursor, the parental plasmid (PP), analytical methodologies established for pDNA are unable to distinguish mcDNA from PP. Thus, a new need emerged for the implementation of suitable, rapid and non-expensive analytical methodologies for the characterization of mcDNA samples. Recently, our research group was able to develop a purification strategy for the isolation of supercoiled (sc) mcDNA resorting to cadaverine-modified monolith. Considering the promising results obtained with this strategy, a cadaverine-modified analytical monolith was prepared and explored for mcDNA quantification. Thus, a strategy of three-step increasing NaCl gradient was considered to first elute RNA/protein content, then isolate sc mcDNA and finally eliminate PP and other impurities still bounded to the matrix. A calibration curve was constructed with different sc mcDNA standards within a range of 1-25 µg/mL. Linearity, accuracy, precision and selectivity of this method were validated according to the international guidelines and the limit of detection and the lower limit of quantification were determined as 1 µg/mL. For the first time, to the best of our knowledge, an analytical method for mcDNA quantification is described. Besides ensuring the safety of mcDNA application by assessing the product purity, such methodology can be used in the future to control industrial mcDNA production and purification, perhaps aiding in the establishment of optimized and less expensive biotechnological operations.

Minicircle DNA purification: Performance of chromatographic monoliths bearing lysine and cadaverine ligands.

Minicircle DNA (mcDNA) technology is in the vanguard of vectors designed for gene therapy, since the absence of prokaryotic sequences confers to mcDNA higher biosafety in comparison to other DNA vectors. However, the presence of other isoforms and non-recombined parental molecules hampers the isolation of supercoiled (sc) mcDNA with the chromatographic methods already established for plasmid purification. In this work, two monolithic supports were modified with lysine and its decarboxylated derivative, cadaverine, to explore their performance in the sc mcDNA purification. Increasing NaCl gradients and different pH values (from 6 to 9) were tested in both modified monoliths. In general, cadaverine modified support established stronger interactions with mcDNA than lysine modified monolith, at acidic pH. For instance, at pH 6.0 the retention time for RNA and DNA molecules in lysine modified monolith was 11.58 and 14.59, respectively, while for cadaverine modified monolith was 20.32 and 27.12, respectively. The lysine modified monolith was able to successfully isolate sc mcDNA from the lysate sample. However, recovery yield was significantly sacrificed to guarantee high purity levels of sc mcDNA. The cadaverine modified monolith showed better selectivity than the previous monolith, achieving the successful sc mcDNA isolation from the lysate sample. The final sc mcDNA sample, obtained by the column that showed the best performance, was characterized by real-time PCR, presenting 98.4% purity and 78.6% recovery yield. The impurities content, namely genomic DNA, proteins and endotoxins, was found within the criteria established by regulatory agencies. Overall, a simple and practical chromatographic strategy to purify sc mcDNA was for the first time implemented by exploring a modified monolithic column, with no significant reduction on the purity and recovery and without resorting to backbone modification or specific enzymatic digestion. Such features will surely be crucial in the industrial scale-up of this chromatographic strategy since it will not be associated with significant cost-increase.

DoE to improve supercoiled p53-pDNA purification by O-phospho-l-tyrosine chromatography.

P53 is implicated in various cellular functions and several studies have shown that transfection of cancer cells with wild-type p53-expressing plasmids could directly drive cells into growth arrest and/or apoptosis. In the present work, the 6.07 kbp pcDNA3-FLAG-p53 plasmid, which encodes the p53 tumor suppressor, was produced and recovered from a recombinant cell culture of Escherichia coli DH5α. Following plasmid biosynthesis, the O-phospho-l-tyrosine chromatographic matrix was explored to purify the supercoiled p53-encoding plasmid. In order to quickly determine the optimal chromatographic performance and to obtain the required purity degree, maximizing the recovery yield of the supercoiled plasmid DNA, the Composite Central Face design was applied. The model revealed to be statistically significant (p-value < 0.05), with coefficient of determination of 0.9434 for the recovery yield and 0.9581 for purity and the central point was successfully validated. After the chromatographic process optimization by using the design of experiments tool, 49.7% of the supercoiled p53-encoding plasmid was recovered with 98.2% of purity, when a decreasing ammonium sulphate gradient was applied. The dynamic binding capacity of the O-phospho-l-tyrosine agarose column was 0.35 ±â€¯0.02 mg pDNA/mL matrix at 50% of the breakthrough. Finally, the purified sample was analysed to assess the content of endotoxins, proteins and genomic DNA, showing that all these impurity levels were below the recommendations of the regulatory agencies.

Arginine homopeptides for plasmid DNA purification using monolithic supports.

Purification of plasmid DNA targeting therapeutic applications still presents many challenges, namely on supports and specific ligand development. Monolithic supports have emerged as interesting approaches for purifying pDNA due to its excellent mass transfer properties and higher binding capacity values. Moreover, arginine ligands were already described to establish specific and preferential interactions with pDNA. Additionally, some studies revealed the ability of arginine based cationic peptides to condense plasmid DNA, which increased lengthening can result in strongest interactions with higher binding capacities for chromatographic purposes of large molecules such as pDNA. In this work, arginine homopeptides were immobilized in monolithic supports and their performance was evaluated and compared with a single arginine monolithic column regarding supercoiled (sc) plasmid DNA purification. Specific interactions of arginine based peptides with several nucleic acids present in a clarified Escherichia coli lysate sample showed potential for the sc pDNA purification. Effectively, the immobilization of the arginine homopeptides became more functional compared with the single arginine amino acid, showing higher binding capacities, which was also reflected in the intensity of the interactions. The combination of structural versatilities of monoliths with the specificity of arginine peptides raised as a promising strategy for sc pDNA purification.

A rapid high-resolution method for resolving DNA topoisomers.

OBJECTIVE: Agarose gel electrophoresis has been the mainstay technique for the analysis of DNA samples of moderate size. In addition to separating linear DNA molecules, it can also resolve different topological forms of plasmid DNAs, an application useful for the analysis of the reactions of DNA topoisomerases. However, gel electrophoresis is an intrinsically low-throughput technique and suffers from other potential disadvantages. We describe the application of the QIAxcel Advanced System, a high-throughput capillary electrophoresis system, to separate DNA topoisomers, and compare this technique with gel electrophoresis. RESULTS: We prepared a range of topoisomers of plasmids pBR322 and pUC19, and a 339 bp DNA minicircle, and compared their separation by gel electrophoresis and the QIAxcel System. We found superior resolution with the QIAxcel System, and that quantitative analysis of topoisomer distributions was straightforward. We show that the QIAxcel system has advantages in terms of speed, resolution and cost, and can be applied to DNA circles of various sizes. It can readily be adapted for use in compound screening against topoisomerase targets.

Accurate quantification of supercoiled DNA by digital PCR.

Digital PCR (dPCR) as an enumeration-based quantification method is capable of quantifying the DNA copy number without the help of standards. However, it can generate false results when the PCR conditions are not optimized. A recent international comparison (CCQM P154) showed that most laboratories significantly underestimated the concentration of supercoiled plasmid DNA by dPCR. Mostly, supercoiled DNAs are linearized before dPCR to avoid such underestimations. The present study was conducted to overcome this problem. In the bilateral comparison, the National Institute of Metrology, China (NIM) optimized and applied dPCR for supercoiled DNA determination, whereas Korea Research Institute of Standards and Science (KRISS) prepared the unknown samples and quantified them by flow cytometry. In this study, several factors like selection of the PCR master mix, the fluorescent label, and the position of the primers were evaluated for quantifying supercoiled DNA by dPCR. This work confirmed that a 16S PCR master mix avoided poor amplification of the supercoiled DNA, whereas HEX labels on dPCR probe resulted in robust amplification curves. Optimizing the dPCR assay based on these two observations resulted in accurate quantification of supercoiled DNA without preanalytical linearization. This result was validated in close agreement (101~113%) with the result from flow cytometry.

A cell engineering strategy to enhance supercoiled plasmid DNA production for gene therapy.

With the recent revival of the promise of plasmid DNA vectors in gene therapy, a novel synthetic biology approach was used to enhance the quantity, (yield), and quality of the plasmid DNA. Quality was measured by percentage supercoiling and supercoiling density, as well as improving segregational stability in fermentation. We examined the hypothesis that adding a Strong Gyrase binding Site (SGS) would increase DNA gyrase-mediated plasmid supercoiling. SGS from three different replicons, (the Mu bacteriophage and two plasmids, pSC101 and pBR322) were inserted into the plasmid, pUC57. Different sizes of these variants were transformed into E. coli DH5α, and their supercoiling properties and segregational stability measured. A 36% increase in supercoiling density was found in pUC57-SGS, but only when SGS was derived from the Mu phage and was the larger sized version of this fragment. These results were also confirmed at fermentation scale. Total percentage supercoiled monomer was maintained to 85-90%. A twofold increase in plasmid yield was also observed for pUC57-SGS in comparison to pUC57. pUC57-SGS displayed greater segregational stability than pUC57-cer and pUC57, demonstrating a further potential advantage of the SGS site. These findings should augment the potential of plasmid DNA vectors in plasmid DNA manufacture. Biotechnol. Bioeng. 2016;113: 2064-2071. © 2016 The Authors. Biotechnology and Bioengineering Published by Wiley Periodicals, Inc.

Chromosomal position shift of a regulatory gene alters the bacterial phenotype.

Recent studies strongly suggest that in bacterial cells the order of genes along the chromosomal origin-to-terminus axis is determinative for regulation of the growth phase-dependent gene expression. The prediction from this observation is that positional displacement of pleiotropic genes will affect the genetic regulation and hence, the cellular phenotype. To test this prediction we inserted the origin-proximal dusB-fis operon encoding the global regulator FIS in the vicinity of replication terminus on both arms of the Escherichia coli chromosome. We found that the lower fis gene dosage in the strains with terminus-proximal dusB-fis operons was compensated by increased fis expression such that the intracellular concentration of FIS was homeostatically adjusted. Nevertheless, despite unchanged FIS levels the positional displacement of dusB-fis impaired the competitive growth fitness of cells and altered the state of the overarching network regulating DNA topology, as well as the cellular response to environmental stress, hazardous substances and antibiotics. Our finding that the chromosomal repositioning of a regulatory gene can determine the cellular phenotype unveils an important yet unexplored facet of the genetic control mechanisms and paves the way for novel approaches to manipulate bacterial physiology.

An improved assay for the detection of alterations in bacterial DNA supercoiling in vivo.

Due to the increasing prevalence of antibiotic resistance and the yet low output of the genomics-based drug discovery approach novel strategies are urgently needed to detect new antibiotics. One such strategy uses known ubiquitous targets like DNA topoisomerases. However, to detect inhibitors of these enzymes by an in vitro assay time-consuming isolation of enzymes and DNA followed by electrophoretic separation of topoisomers are required. Instead, this study aimed at developing an in vivo assay for the detection of alterations in DNA supercoiling indicative of topoisomerase inhibition by a reporter gene assay. A pair of plasmids was developed which carry the reporter gene luc for firefly luciferase under control of either promoter ptopA (pPHB90) or pgyrA (pPHB91), whose activities are reciprocally affected by alterations of the supercoiling degree. Each plasmid is individually transferred into E. coli cells. The quotient of the luciferase activities determined using cells with either plasmid was taken as relative measure of the global supercoiling degree Qsc (quotient of supercoiling). Using isogenic reference strains with known alterations of the global DNA supercoiling degree due to mutations in either gyrB or topA, the reporter gene system was able to detect both a decrease and an increase of the negative supercoiling degree compared to the isogenic parent strain. Treating cells with known inhibitors of DNA gyrase, like fluoroquinolones, novobiocin as well as simocyclinone D8 from Streptomyces antibioticus which has been identified as an inhibitor of DNA gyrase in vitro, also caused decreases of the Qsc value in vivo. The suitability of this reporter gene system to screen for anti-topoisomerase I and II compounds from various natural sources like plant extracts by sensing alterations of the DNA supercoiling was demonstrated and offers a new application to identify novel compounds active against bacterial topoisomerases I and gyrase.

Real-time detection of DNA topological changes with a fluorescently labeled cruciform.

Topoisomerases are essential cellular enzymes that maintain the appropriate topological status of DNA and are the targets of several antibiotic and chemotherapeutic agents. High-throughput (HT) analysis is desirable to identify new topoisomerase inhibitors, but standard in vitro assays for DNA topology, such as gel electrophoresis, are time-consuming and are not amenable to HT analysis. We have exploited the observation that closed-circular DNA containing an inverted repeat can release the free energy stored in negatively supercoiled DNA by extruding the repeat as a cruciform. We inserted an inverted repeat containing a fluorophore-quencher pair into a plasmid to enable real-time monitoring of plasmid supercoiling by a bacterial topoisomerase, Escherichia coli gyrase. This substrate produces a fluorescent signal caused by the extrusion of the cruciform and separation of the labels as gyrase progressively underwinds the DNA. Subsequent relaxation by a eukaryotic topoisomerase, human topo IIα, causes reintegration of the cruciform and quenching of fluorescence. We used this approach to develop a HT screen for inhibitors of gyrase supercoiling. This work demonstrates that fluorescently labeled cruciforms are useful as general real-time indicators of changes in DNA topology that can be used to monitor the activity of DNA-dependent motor proteins.

Rapid quantification of supercoiled plasmid deoxyribonucleic acid using a monolithic ion exchanger.

The demand for high-purity supercoiled plasmid DNA to be applied as a vector for new therapeutic strategies, such as gene therapy or DNA vaccination has increased in the last years. Thus, it is necessary to implement an analytical technique suitable to control the quality of the supercoiled plasmid as a pharmaceutical product during the manufacturing process. The present study describes a new methodology to quantify and monitor the purity of supercoiled plasmid DNA by using a monolithic column based on anion-exchange chromatography. This analytical method with UV detection allows the separation of the plasmid isoforms by combining a NaCl stepwise gradient. The specificity, linearity, accuracy, reproducibility and repeatability of the method have been evaluated, and the lower quantification and detection limits were also established. The validation was performed according to the guidelines, being demonstrated that the method is precise and accurate for a supercoiled plasmid concentration up to 200µg/mL. The main advantage achieved by using this monolithic column is the possibility to quantify the supercoiled plasmid in a sample containing other plasmid topologies, in a 4min experiment. This column also permits the assessment of the supercoiled plasmid DNA present in more complex samples, allowing to control its quality throughout the bioprocess. Therefore, these findings strengthen the possibility of using this monolithic column associated with a powerful analytical method to control the process development of supercoiled plasmid DNA production and purification for therapeutic applications.

Novel method for quantifying radiation-induced single-strand-break yields in plasmid DNA highlights 10-fold discrepancy.

The widely used agarose gel electrophoresis method for assessing radiation-induced single-strand-break (SSB) yield in plasmid DNA involves measurement of the fraction of relaxed-circular (C) form that migrates independently from the intact supercoiled (SC) form. We rationalized that this method may underestimate the SSB yield since the position of the relaxed-circular form is not altered when the number of SSB per DNA molecule is >1. To overcome this limitation, we have developed a novel method that directly probes and quantifies SSBs. Supercoiled (3)H-pUC19 plasmid samples were irradiated with γ-rays, alkali-denatured, dephosphorylated, and kinated with γ-[(32)P]ATP, and the DNA-incorporated (32)P activities were used to quantify the SSB yields per DNA molecule, employing a standard curve generated using DNA molecules containing a known number of SSBs. The same irradiated samples were analyzed by agarose gel and SSB yields were determined by conventional methods. Comparison of the data demonstrated that the mean SSB yield per plasmid DNA molecule of [21.2±0.59]×10(-2)Gy(-1) as measured by direct probing is ~10-fold higher than that obtained from conventional gel-based methods. These findings imply that the SSB yields inferred from agarose gels need reevaluation, especially when they were utilized in the determination of radiation risk.

Secalonic acid D as a novel DNA topoisomerase I inhibitor from marine lichen-derived fungus Gliocladium sp. T31.

CONTEXT: DNA topoisomerase I (topo I) is an essential enzyme which regulates the conformational changes in DNA topology by cleaving and rejoining DNA strands during normal cell growth. The inhibitors of topo I represent a major class of anticancer drugs. In our projects to isolate new anticancer agents from marine-derived fungi, secalonic acid D (SAD) with inhibitory activity on topo I was isolated from the fermentation broth of marine lichen-derived fungus Gliocladium sp. T31, which was collected from marine sediments in South Pole. OBJECTIVE: The inhibitory activity of SAD on topo I was investigated for the first time. MATERIALS AND METHODS: The inhibitory effect of SAD on topo I was determined via in vitro supercoil relaxation assays and electrophoretic mobility shift assay (EMSA) using plasmid substrate, pBR322. RESULTS: SAD displays a considerable inhibition on topo I in a dose-dependent manner with the minimum inhibitory concentration (MIC) of 0.4 µM. Unlike the prototypic DNA topo I poison camptothecin (CPT), SAD inhibits the binding of topo I to DNA but does not induce the formation of topo I-DNA covalent complexes. DISCUSSION AND CONCLUSION: SAD is an excellent topo I inhibitor and thus a significantly potential anticancer candidate.

Supercoiled plasmid quality assessment by analytical arginine-affinity chromatography.

Supercoiled plasmids are an important component of gene-based delivery vehicles, applied in new therapeutic strategies such as gene therapy or DNA vaccination. However, aiming at the general distribution of plasmid DNA (pDNA) therapeutics requires a procedure to easily and efficiently assess the purity and recovery yield of the supercoiled (sc) plasmid isoform. Based on affinity interactions between amino acids and nucleic acids, an arginine affinity methodology with UV detection was established to quantify and to control the quality of sc plasmid biopharmaceuticals. The fact that this new technique allows to distinguish between plasmid isoforms represents an advantage, since it allows the selective quantification of the biologically active pDNA topology, and a more accurate analysis of the quality of the isolated plasmid. The analytical experiments were performed in 12 min and the method was found to be accurate, precise, reproducible and linear for a sc plasmid concentration range between 2 and 150 µg/mL. In comparison with other established methods used in the quantification of native pDNA (oc+sc), the main advance introduced by this new method is the possibility to quantify the sc plasmid in a sample containing other plasmid topologies, ensuring the purity of plasmid products to be therapeutically applied.

Analysis of supercoiled DNA by agarose gel electrophoresis using low-conducting sodium threonine medium.

We describe a new low-ionic-strength sodium threonine (STh) medium with the advantage of avoiding relative DNA band migration changes following electrophoresis of supercoiled DNA in agarose gel when substituted for the standard conductive medium of TBE (Tris-boric acid-ethylenediaminetetraacetic acid [EDTA]) or TAE (Tris-acetic acid-EDTA) or the low-ionic-strength sodium boric acid medium. Low-ionic-strength STh medium provided better resolution, less heat generation, and prevention of relative migration order changes among linear, covalently closed circular-, and open circular-formed DNA in the range of 2-10 kilobase pairs in 1% agarose gel electrophoresis.

Measuring mtDNA damage using a supercoiling-sensitive qPCR approach.

Compromised mitochondrial DNA structural integrity can have functional consequences for mitochondrial gene expression and replication leading to metabolic and degenerative diseases, aging, and cancer. Gel electrophoresis coupled with Southern blot and probe hybridization and long PCR are established methods for detecting mtDNA damage. But each has its respective shortcomings: gel electrophoresis is at best semi-quantitative and long PCR does not offer information on the structure. To overcome these limitations, we developed a new method with real-time PCR to accurately quantify the mtDNA structural damage/repair and copy number change. We previously showed that the different mtDNA structures (supercoiled, relaxed circular, and linear) have profound influences on the outcome of the real-time PCR amplification. The supercoiled structure is inhibitory to the PCR amplification, while relaxed structures are readily amplified. We will illustrate the use of this new method by quantifying the kinetics of mtDNA damage and repair in LNCaP prostate cancer cells induced by exogenous H2O2 treatments. The use of this new method on clinical samples for spontaneous mtDNA damage level will also be highlighted.

Interplay of DNA supercoiling and catenation during the segregation of sister duplexes.

The discrete regulation of supercoiling, catenation and knotting by DNA topoisomerases is well documented both in vivo and in vitro, but the interplay between them is still poorly understood. Here we studied DNA catenanes of bacterial plasmids arising as a result of DNA replication in Escherichia coli cells whose topoisomerase IV activity was inhibited. We combined high-resolution two-dimensional agarose gel electrophoresis with numerical simulations in order to better understand the relationship between the negative supercoiling of DNA generated by DNA gyrase and the DNA interlinking resulting from replication of circular DNA molecules. We showed that in those replication intermediates formed in vivo, catenation and negative supercoiling compete with each other. In interlinked molecules with high catenation numbers negative supercoiling is greatly limited. However, when interlinking decreases, as required for the segregation of newly replicated sister duplexes, their negative supercoiling increases. This observation indicates that negative supercoiling plays an active role during progressive decatenation of newly replicated DNA molecules in vivo.

Analysis of DNA supercoiling induced by DNA-protein interactions.

Certain DNA-interacting proteins induce a pronounced bending in the double helix and cause topological stresses that are compensated by the formation of supercoils in DNA. Such supercoils, when forming on a circular plasmid, give rise to a series of topoisomers that run at different speeds during electrophoresis. The number of supercoils introduced in the plasmid can provide information on the protein; it can for example help determine the number of nucleosomes that are assembled on the plasmid or indicate whether the DNA-bending activity of a transcription factor is important enough to cause a topological stress. Because a DNA-protein activity can lead to either an overwinding or an underwinding of the helix, supercoiling can occur in either direction. Determining whether a plasmid contains positively or negatively supercoiled DNA is possible, thanks to an agarose gel containing an intercalating agent known to positively supercoil DNA, such as chloroquine. The speed of migration of the topoisomers varies in a characteristic way in the presence and absence of the agent. Topoisomer standards can furthermore be generated to allow the easy evaluation of the number of supercoils induced in a plasmid by a DNA-protein interaction.