Combining ligation reaction and capillary gel electrophoresis to obtain reliable long DNA probes

New DNA amplification methods are continuously developed for sensitive detection and quantification of specific DNA target sequences for, e.g. clinical, environmental or food applications. These new applications often require the use of long DNA oligonucleotides as probes for target sequences hybridization. Depending on the molecular technique, the length of DNA probes ranges from 40 to 450 nucleotides, solid-phase chemical synthesis being the strategy generally used for their production. However, the fidelity of chemical synthesis of DNA decreases for larger DNA probes. Defects in the oligonucleotide sequence result in the loss of hybridization efficiency, affecting the sensitivity and selectivity of the amplification method. In this work, an enzymatic procedure has been developed as an alternative to solid-phase chemical synthesis for the production of long oligonucleotides. The enzymatic procedure for probe production was based on ligation of short DNA sequences. Long DNA probes were obtained from smaller oligonucleotides together with a short sequence that acts as bridge stabilizing the molecular complex for DNA ligation. The ligation reactions were monitored by capillary gel electrophoresis with laser-induced fluorescence detection (CGE-LIF) using a bare fused-silica capillary. The capillary gel electrophoresis-LIF method demonstrated to be very useful and informative for the characterization of the ligation reaction, providing important information about the nature of some impurities, as well as for the fine optimization of the ligation conditions (i.e. ligation cycles, oligonucleotide and enzyme concentration). As a result, the yield and quality of the ligation product were highly improved. The in-lab prepared DNA probes were used in a novel multiplex ligation-dependent genome amplification (MLGA) method for the detection of genetically modified maize in samples. The great possibilities of the whole approach were demonstrated by the specific and sensitive detection of transgenic maize at percentages lower than 1%.     

DNA‐Computer — Superrechner der Zukunft?: Chemie und Informatik

A new method for utilizing the outstanding qualities of natural information systems has been developed. The data processing elements of the computers consist of desoxyribonucleic acid (DNA). DNA computers facilitate tridimensional and parallel information processing. Due to the numerous parallel chemical reactions, a DNA computer can master problems which can not be solved with conventional electronic computers. DNA computers offer many possibilities. Since a DNA computer can simulate any given Turing machine computation, a DNA computer is able to execute every program.     

Performance of the ForenSeqTM DNA Signature Prep kit on highly degraded samples

Next generation sequencing (NGS) is the emerging technology in forensic genomics laboratories. It offers higher resolution to address most problems of human identification, greater efficiency and potential ability to interrogate very challenging forensic casework samples. In this study, a trial set of DNA samples was artificially degraded by progressive aqueous hydrolysis, and analyzed together with the corresponding unmodified DNA sample and control sample 2800 M, to test the performance and reliability of the ForenSeq^TM DNA Signature Prep kit using the MiSeq Sequencer (Illumina). The results of replicate tests performed on the unmodified sample (1.0 ng) and on scalar dilutions (1.0, 0.5 and 0.1 ng) of the reference sample 2800 M showed the robustness and the reliability of the NGS approach even from sub‐optimal amounts of high quality DNA. The degraded samples showed a very limited number of reads/sample, from 2.9–10.2 folds lower than the ones reported for the less concentrated 2800 M DNA dilution (0.1 ng). In addition, it was impossible to assign up to 78.2% of the genotypes in the degraded samples as the software identified the corresponding loci as “low coverage” (< 50x). Amplification artifacts such as allelic imbalances, allele drop outs and a single allele drop in were also scored in the degraded samples. However, the ForenSeq^TM DNA Sequencing kit, on the Illumina MiSeq, was able to generate data which led to the correct typing of 5.1–44.8% and 10.9–58.7% of 58 of the STRs and 92 SNPs, respectively. In all trial samples, the SNP markers showed higher chances to be typed correctly compared to the STRs. This NGS approach showed very promising results in terms of ability to recover genetic information from heavily degraded DNA samples for which the conventional PCR/CE approach gave no results. The frequency of genetic mistyping was very low, reaching the value of 1.4% for only one of the degraded samples. However, these results suggest that further validation studies and a definition of interpretation criteria for NGS data are needed before implementation of this technique in forensic genetics.     

Integrated massively parallel sequencing of 15 autosomal STRs and Amelogenin using a simplified library preparation approach

Massively parallel sequencing (MPS) technologies, also termed as next‐generation sequencing (NGS), are becoming increasingly popular in study of short tandem repeats (STR). However, current library preparation methods are usually based on ligation or two‐round PCR that requires more steps, making it time‐consuming (about 2 days), laborious and expensive. In this study, a 16‐plex STR typing system was designed with fusion primer strategy based on the Ion Torrent S5 XL platform which could effectively resolve the above challenges for forensic DNA database‐type samples (bloodstains, saliva stains, etc.). The efficiency of this system was tested in 253 Han Chinese participants. The libraries were prepared without DNA isolation and adapter ligation, and the whole process only required approximately 5 h. The proportion of thoroughly genotyped samples in which all the 16 loci were successfully genotyped was 86% (220/256). Of the samples, 99.7% showed 100% concordance between NGS‐based STR typing and capillary electrophoresis (CE)‐based STR typing. The inconsistency might have been caused by off‐ladder alleles and mutations in primer binding sites. Overall, this panel enabled the large‐scale genotyping of the DNA samples with controlled quality and quantity because it is a simple, operation‐friendly process flow that saves labor, time and costs.     

Determination of DNA Hypermethylation Using Anti‐cancer Drug‐Temozolomide

An electrochemical drug‐DNA biosensor was developed for the detection of interaction between the anti‐cancer drug, Temozolomide (TMZ), and DNA sequences by using Differential Pulse Voltammetry at the graphite electrode surfaces. TMZ is a pro‐drug and an alkylating agent that crosses the blood‐brain barrier, so it is mainly used for brain cancers treatment. In this study, we aim to develop a‐proof‐of‐concept study to investigate the effect of TMZ on formerly methylated DNA sequences since TMZ shows its anti‐cancer activity by methylating the DNA. Interaction between TMZ and DNA causes localized distortion of DNA away from an idealized B‐form, resulting in a wider major groove and greater steric accessibility of functional groups in the base of the groove. According to the results, TMZ behaves as a ‘hybridization indicator’ because of its different electrochemical behavior to different strands of DNA. After interaction with TMZ, hybrid (double stranded DNA‐dsDNA) signals decreased dramatically whereas probe (single stranded DNA‐ssDNA) and control signals remain almost unchanged. The signal differences enabled us to distinguish ssDNA and dsDNA without using a label or tag. It is the first study to demonstrate the interaction between the TMZ and dsDNA created from probe and target. We use specific oligonucleotides sequences instead of using long dsDNA sequences.     

Synthesis of Peptide Hormones using Recombinant DNA Techniques

Recombination of genetic material enables the creation of new bacterial strains which can synthesize specific proteins in large amounts. Such bacteria permit the production of previously inaccessible proteins. They can therefore be used as starting materials for the production of drugs which will open up new paths for therapy. Several proteins produced by bacteria after DNA recombination are presently undergoing clinical trials while others are already being produced on a large scale. Thus, in the area of recombinant DNA techniques the transition from the research laboratory to industrial exploitation has occurred much faster than was anticipated several years ago. The methods, possibilities and problems encountered in the synthesis of peptide hormones by bacteria after DNA recombination are outlined, using insulin, somatostatin, and growth hormone as examples. Great emphasis is placed on the molecular biological aspects of this approach.     

Isometric artifacts from polymerase chain reaction-massively parallel sequencing analysis of short tandem repeat loci: An emerging issue from a new technology?

The recent introduction of polymerase chain reaction (PCR)-massively parallel sequencing (MPS) technologies in forensics has changed the approach to allelic short tandem repeat (STR) typing because sequencing cloned PCR fragments enables alleles with identical molecular weights to be distinguished based on their nucleotide sequences. Therefore, because PCR fidelity mainly depends on template integrity, new technical issues could arise in the interpretation of the results obtained from the degraded samples. In this work, a set of DNA samples degraded in vitro was used to investigate whether PCR-MPS could generate “isometric drop-ins” (IDIs; i.e., molecular products having the same length as the original allele but with a different nucleotide sequence within the repeated units). The Precision ID GlobalFiler NGS STR panel kit was used to analyze 0.5 and 1 ng of mock samples in duplicate tests (for a total of 16 PCR-MPS analyses). As expected, several well-known PCR artifacts (such as allelic dropout, stutters above the threshold) were scored; 95 IDIs with an average occurrence of 5.9 IDIs per test (min: 1, max: 11) were scored as well. In total, IDIs represented one of the most frequent artifacts. The coverage of these IDIs reached up to 981 reads (median: 239 reads), and the ratios with the coverage of the original allele ranged from 0.069 to 7.285 (median: 0.221). In addition, approximately 5.2% of the IDIs showed coverage higher than that of the original allele. Molecular analysis of these artifacts showed that they were generated in 96.8% of cases through a single nucleotide change event, with the C > T transition being the most frequent (85.7%). Thus, in a forensic evaluation of evidence, IDIs may represent an actual issue, particularly when DNA mixtures need to be interpreted because they could mislead the operator regarding the number of contributors. Overall, the molecular features of the IDIs described in this work, as well as the performance of duplicate tests, may be useful tools for managing this new class of artifacts otherwise not detected by capillary electrophoresis technology.     

DNA methylation-based age prediction with bloodstains using pyrosequencing and random forest regression

The use of DNA methylation to predict chronological age has shown promising potential for obtaining additional information in forensic investigations. To date, several studies have reported age prediction models based on DNA methylation in body fluids with high DNA content. However, it is often difficult to apply these existing methods in practice due to the low amount of DNA present in stains of body fluids that are part of a trace material. In this study, we present a sensitive and rapid test for age prediction with bloodstains based on pyrosequencing and random forest regression. This assay requires only 0.1 ng of genomic DNA and the entire procedure can be completed within 10 h, making it practical for forensic investigations that require a short turnaround time. We examined the methylation levels of 46 CpG sites from six genes using bloodstain samples from 128 males and 113 females aged 10–79 years. A random forest regression model was then used to construct an age prediction model for males and females separately. The final age prediction models were developed with seven CpG sites (three for males and four for females) based on the performance of the random forest regression. The mean absolute deviation was less than 3 years for each model. Our results demonstrate that DNA methylation-based age prediction using pyrosequencing and random forest regression has potential applications in forensics to accurately predict the biological age of a bloodstain donor.     

Application of Single—labelled Probe—primer in PCR Amplification to the Detection of Hepatitis B Virus DNA

A new method based on the incorporation of a single-lablled probe-primer into polymerase chain reaction(PCR) for the detection of PCR-amplified DNA in a closed system is reported.The probeprimerc consists of a specific probe sequence on the 5‘‘‘‘‘‘‘‘-end and a primer sequence on the 3‘‘‘‘‘‘‘‘-end.A flurophore is located at the 5‘‘‘‘‘‘‘‘end.The primeR-quencher is an oligonucleotide,which is complementary to the probe sequence of probe-primer and labelled with a quencher at the 3‘‘‘‘‘‘‘‘-end.In the duplex formed by probe-primer and primer-quencher.the fluorophore and quencher are kept in close proximity to each other.Therefore the fluorescence is quenched.During PCR amplificatio,the specific probe sequence of probeprimer binds to its complement within the same strand of DNA,and is cleaved by Taq DNA polymerase,resulting in the restoration of fluorescence.This system has the same energy transfer mechanism as molecular beacons,and a good quenching effciency can be ensured.Following optimization of PCR conditions,this method was used to detect hepatitis b virus(HBV) dna in patient sera.This technology eliminates the risk of carry-over contamination,simplifies the amplification assay and opens up new possibilities for the real-time detection of the amplified DNA.     

Potentiometric DNA Sensor Based on Electropolymerized Phenothiazines for Protein Detection

Novel method of potentiometric detection of DNA‐protein interactions has been proposed. For this purpose, polymeric phenothiazine dyes, methylene blue (MB) and methylene green (MG), were electrochemically deposited onto the glassy carbon electrode and covered with double stranded DNA (dsDNA) as a target for antibodies (DNA‐sensor) or DNA aptamer specific to human α‐thrombin (aptasensor). The biosensors were consecutively incubated at pH 7.5 and 3.0 and the difference in potentials, ΔE, was used as a measure of protein concentration. The potentiometric DNA‐sensors were tested in standard serum of autoimmune disease patients (systemic lupus erythemathosus (SLE) and autoimmune thyroidites). It was shown, that the ΔE value of DNA‐sensor depends on the dilution of serum in the range from 1 : 1 to 1 : 100. Nonthermostated serum exhibited bell‐shape dependence of ΔE on serum dilution due to interfering effect of serine proteins at maximum dilution between 1 : 20 and 1 : 50. For SLE serum thermostated at 56 °C the ΔE linearly decreased as a function of serum dilution and reached saturation at dilution 1 : 20. Similarly the changes in the potential of aptasensor allowed us to determine the α‐thrombin in the range from 1 nM to 1 μM. The Faradic impedance spectra measured at presence of redox probe [Fe(CN)₆]^4?/3? revealed changes in the resistance and capacitance attributed to the shielding effect of anti‐DNA antibodies and an increase in the electron transfer. The developed potentiometric biosensors can be used for preliminary diagnostics of autoimmune diseases and thrombin detection with sensitivity comparable to traditional methods. The developed assay is, however simpler and cheaper in comparison with commonly used methods.     

Chemical ligation as a method for the assembly of double-stranded nucleic acids: Modifications and local structure studies

A new procedure was developed as an alternative to the enzymatic assembly of natural and modified double-stranded DNAs using chemical reagent (chemical ligation). BrCN was suggested as an efficient coupling reagent, which induces superfast reactions in DNA duplexes. The physicochemical properties and the structure of new types of DNA duplexes, which are the substrates for chemical ligation, with breaks in phosphodiester chains, including concatemers, were studied. Chemical ligation was applied to prepare biologically active 17–200 base-pair double-stranded DNAs and DNA-RNA block-copolymers, to incorporate various modifications into DNA duplexes including pyrophosphate and phosphoramidate unnatural internucleotide bonds. The unique possibilities of this approach were demonstrated in the development of methods for circularization of oligodeoxy ribonucleotides and assembly of branched DNAs. The structural-kinetic concept of chemicalligation was created and the relationship between the reactivity of interacting groups and sequence-dependent local conformation of the ligation site in B-DNA was established. The lesser efficiency of chemical ligation of RNA fragments in comparison to that of DNA analogs was demonstrated and rationalized. This approach was used as a sensitive monitor of a stable double helix formation and third-strand binding to a DNA duplex.Translated from Izvestiya Akademii Nauk. Seriya Khimicheskaya, No. 8, pp. 1889–1911, August, 1996.     

Electrochemical Study of the Interaction of the Alkylating Agent Busulfan with Double Strand DNA

Damage of salmon sperm double strand ss dsDNA in solution or immobilized on screen‐printed carbon electrode (SPCE) induced by incubation of DNA with the antineoplastic alkylating agent busulfan (BUS) at various conditions was detected for the first time by simple electrochemical methods. Chemical changes in DNA bases can be detected through the altered electroactivity of the DNA. Electrochemical voltammetric sensing of damage caused by BUS to dsDNA in solution was monitored by the appearance of peaks diagnostic of the oxidation of guanine and adenine. Moreover, crystal violet, which interacts with the DNA immobilized on SPCEs, was used as an effective electroactive indicator, in combination with cyclic voltammetry and differential pulse voltammetry techniques to monitor the cross‐links or damage to DNA. The interaction between BUS and DNA were determined by the changes in the voltammetric peak of crystal violet. The effects of various conditions upon the crystal violet signal were investigated.     

Crystallization of DNA‐Capped Gold Nanoparticles in High‐Concentration,Divalent Salt Environments

The multiparametric nature of nanoparticle self‐assembly makes it challenging to circumvent the instabilities that lead to aggregation and achieve crystallization under extreme conditions. By using non‐base‐pairing DNA as a model ligand instead of the typical base‐pairing design for programmability, long‐range 2D DNA–gold nanoparticle crystals can be obtained at extremely high salt concentrations and in a divalent salt environment. The interparticle spacings in these 2D nanoparticle crystals can be engineered and further tuned based on an empirical model incorporating the parameters of ligand length and ionic strength.     

DNA Dyes—Highly Sensitive Reporters of Cell Quantification: Comparison with Other Cell Quantification Methods

Cell quantification is widely used both in basic and applied research. A typical example of its use is drug discovery research. Presently, plenty of methods for cell quantification are available. In this review, the basic techniques used for cell quantification, with a special emphasis on techniques based on fluorescent DNA dyes, are described. The main aim of this review is to guide readers through the possibilities of cell quantification with various methods and to show the strengths and weaknesses of these methods, especially with respect to their sensitivity, accuracy, and length. As these methods are frequently accompanied by an analysis of cell proliferation and cell viability, some of these approaches are also described.     

Differential DNA Recognitions of Benzimidazole Based Astemizole,Omeprazole, Lansoprazole,and Thiabendazole

Well known benzimidazole based drugs – astemizole, omeprazole, lansoprazole, and thiabendazole – are studied whether those can bind with two different oligonucleotides sequences or not. Molecular docking study and further molecular dynamics are employed to find out the capability of these drugs toward different DNA sequences. The substitution at N2 with different atoms/group or heterocyclic moieties favors the binding in the major groove of DNA in most of the cases. The substitutions at N1 beside N2 position clearly increase the binding possibility of astemizole as compared to the rest. Various functional possibilities of known drugs through DNA recognitions may be explored in drug repurposing purposes in virtue of present study.     

Electrochemical oxidation of morin and interaction with DNA

A poly (tetrafluroethylene)-deoxyribonucleate acid (PTFE-DNA) film-modified glassy carbon electrode (GCE) has been fabricated. The electrochemical oxidation behaviors of morin as well as its interaction with DNA have been studied at PTFE-DNA film-modified GCE and bare GCE by electrochemical methods. This modified electrode shows an enhanced effectiveness towards the oxidation of morin. Importantly, as to the interaction between morin and DNA in solution, characteristic parameters such as the binding stoichiometry and association equilibrium constant according to the Hill model for cooperative binding have been determined on the basis of linear sweep voltammetry and chronocoulometry.     

A Case Study of the Likes and Dislikes of DNA and RNA in Self‐Assembly

Programmed self‐assembly of nucleic acids (DNA and RNA) is an active research area as it promises a general approach for nanoconstruction. Whereas DNA self‐assembly has been extensively studied, RNA self‐assembly lags much behind. One strategy to boost RNA self‐assembly is to adapt the methods of DNA self‐assembly for RNA self‐assembly because of the chemical and structural similarities of DNA and RNA. However, these two types of molecules are still significantly different. To enable the rational design of RNA self‐assembly, a thorough examination of their likes and dislikes in programmed self‐assembly is needed. The current work begins to address this task. It was found that similar, two‐stranded motifs of RNA and DNA lead to similar, but clearly different nanostructures.     

New DNA Technology and the DNA Biosensor

Abstract

Recently there has been an increasing demand to produce systems for the detection of specific DNA sequences that are amenable to non-specialised laboratories. This demand has led to many innovative and novel approaches to DNA analysis which may collectively be termed ′new DNA technology′. Here, we review these advances in relation to their applicability for the production of a DNA biosensor. The present state of the art is described and future possibilities are considered.     

Theoretical study of the interaction between a high-valent manganese porphyrin oxyl-(hydroxo)-Mn(IV)-TMPyP and double-stranded DNA

Cationic porphyrin derivatives such as meso-tetrakis(4-N-methylpyridinium)porphyrin, TMPyP, have been shown to interact with double-stranded DNA. The manganese derivative, Mn(III)-TMPyP, activated by an oxygen donor like potassium monopersulfate, provides an efficient DNA-cleaving system. Previous experimental work1 has shown that DNA cleavage by the Mn(III)-TMPyP/KHSO(5) system was due to an oxidative attack, within the minor groove of B-DNA, at the C5' or C1' carbons of deoxyribose units. The aim of this study was to use molecular modeling to elucidate the specificity of the interactions between the transient active species oxyl-Mn(IV)-TMPyP and the DNA target. Geometric parameters, charges, and force field constants consistent with the AMBER 98 force field were calculated by DFT methods. Molecular modeling (mechanics and dynamic simulations) were performed for oxyl-(hydroxo)-Mn(IV)-TMPyP bound in the minor groove of the dodecamer d(5'-TCGTCAAACCGC)-d(5'-GCGGTTTGACGA). Geometry, interactions, and binding energy of the metalloporphyrin located at the A.T triplet region of the dodecamer were analyzed. These studies show no significant structural change of the DNA structure upon ligand binding. Mobility of the metalloporphyrin in the minor groove was restrained by the formation of a hydrogen bond between the hydroxo ligand trans to the metal-oxyl and a DNA phosphate, restricting the access of the oxyl group to the (pro-S) H atom at C5'.     

Reversible Reconfiguration of DNA Origami Nanochambers Monitored by Single‐Molecule FRET

Today, DNA nanotechnology is one of the methods of choice to achieve spatiotemporal control of matter at the nanoscale. By combining the peculiar spatial addressability of DNA origami structures with the switchable mechanical movement of small DNA motifs, we constructed reconfigurable DNA nanochambers as dynamic compartmentalization systems. The reversible extension and contraction of the inner cavity of the structures was used to control the distance‐dependent energy transfer between two preloaded fluorophores. Interestingly, single‐molecule FRET studies revealed that the kinetics of the process are strongly affected by the choice of the switchable motifs and/or actuator sequences, thus offering a valid method for fine‐tuning the dynamic properties of large DNA nanostructures. We envisage that the proposed DNA nanochambers may function as model structures for artificial biomimetic compartments and transport systems.