AFM‐Correlated CSM‐Coupled Raman/Fluorescence Studies on Selective Interactions of Water Soluble Porphyrins with DNA

The Raman and fluorescence spectroscopic properties of water‐soluble oxo‐titanium(IV) mesotetrakis (1‐methyl pyridium‐4‐yl) porphyrin (O=Ti(TMPyP)⁴⁺) bound with calf thymus DNA and artificial DNAs such as double stranded poly[d(A‐T)₂] and poly[d(G‐C)₂] have been investigated on the single DNA molecule basis by AFM‐correlated confocal scanning microscope (CSM)‐coupled Raman and fluorescence spectroscopic techniques as well as the ensemble‐averaged spectroscopy. The ensemble‐averaged spectroscopic studies imply that the porphyrin interacts with DNA in different groove binding patterns depending on the base pairs. AFM‐images of the different DNAs bound with O=Ti(TMPyP)⁴⁺ were measured, and their morphologies are found to depend on kind of base pairs interacting with O=Ti(TMPyP)⁴⁺. Being correlated with the AFM images, the CSM‐coupled Raman and fluorescence spectral properties of the three different single O=Ti(TMPyP)⁴⁺‐DNA complexes were observed to be highly resolved and sensitive to base pair‐dependent axial ligation of Ti‐O bond as compared to the corresponding ensemble‐averaged spectral properties, which affect the groove binding and its strength of the O=Ti(TMPyP)⁴⁺ with DNA. The axial ligation was found to be accompanied by vibration structural change of the porphyrin ring, leading to keep the shape of double stranded poly[d(A‐T)₂] rigid while poly‐[d(G‐C)₂] and calf thymus DNA flexible after binding with the oxo‐titanyl porphyrin. The base pair dependence of the fluorescence decay times of the DNA‐bound porphyrins was also observed, implying that an excited‐state charge transfer takes place in the G‐C rich major groove in calf thymus DNA. These results suggest that binding of O=Ti(TMPyP)⁴⁺ is more preferential with the G‐C rich major groove than with the A‐T rich minor groove in calf thymus DNA so that the morphology of DNA is changed.     

Application of Impedimetric and Voltammetric Genosensor for Detection of a Biological Warfare: Anthrax

A strategy for the detection of anthrax, which is a potential biological weapon by using an electrochemical genosensing technology, is investigated. An alkanathiol‐linked or unlabeled capture probe related to B. anthracis is immobilized onto gold or graphite electrode surface. A 101‐mer anthrax target is used for hybridization. The extent of hybridization between probe and target sequences is determined by using differential pulse voltammetry (DPV) and electrochemical impedance spectrometry (EIS). EIS analysis are based on electron transfer resistance (R_ct) in the presence of [Fe(CN)₆]^3?/4? and DPV measurements are based on transduction of both guanine oxidation and Meldola's blue (MDB) reduction signal as hybridization indicator. The response of the probe‐modified electrodes which was interacted with a noncomplementary sequence was the same as the responses of probe‐modified surface and proved the specifity of the hybridization with the target. According to these results the developed genosensors based on EIS and DPV techniques can be employed for rapid and selective detection of B. anthracis.     

Electrochemical Characteristics of a Novel Pyridinium Salt as a Candidate Drug Molecule and Its Interaction with DNA

In this article, for the first time, the electrochemical properties of a novel pyridine derivative, 4‐(2‐(2‐hydroxybenzylidene) hydrazinyl)‐1‐(3‐phenylpropyl) pyridinium bromide (abbreviated as 4‐Pyri), and its interaction with double stranded DNA (dsDNA) was investigated. The interaction between candidate drug molecule (4‐Pyri) and dsDNA was analyzed by examining 4‐Pyri (+0.6 V and +0.8 V) and guanine (+1.0 V) oxidation signal changes with Differential Pulse Voltammetry (DPV) and Cyclic Voltammetry (CV). Electrochemical Impedance Spectroscopy (EIS) was used to show the resistance changes before and after the interaction between 4‐Pyri and dsDNA. We showed that after the interaction with 4‐Pyri, the oxidation currents of guanine decreased dramatically, whereas the intrinsic oxidation currents of 4‐Pyri dramatically increased. 4‐Pyri oxidation current differences before and after the interaction with dsDNA enabled us to determine such interaction separately from guanine oxidation signals. In addition, resistance differences were observed at before and after the interaction with each other that confirmed the possible interaction. In addition, toxicity effect (S%) value, which is an important parameter for electrochemical studies indicated 4‐Pyri's toxicity to dsDNA. Our results demonstrated that 4‐Pyri interacts with dsDNA, and could be used as a potential candidate drug molecule due to its remarkable impact on dsDNA.     

Carbon Nanotubes Modified Graphite Electrodes for Monitoring of Biointeraction Between 6‐Thioguanine and DNA

In this present study, single‐walled carbon nanotubes (SWCNT) modified disposable pencil graphite electrodes (SWCNT‐PGEs) were developed for the electrochemical monitoring of anticancer drug, and its interaction with double stranded DNA (dsDNA). Under this aim, SWCNT‐PGEs were applied for the first time in the literature to analyse of 6‐Thioguanine (6‐TG), and also to investigate its interaction with DNA by voltammetric and impedimetric methods. The surface morphologies of PGE and SWCNT‐PGE were explored using scanning electron microscopy (SEM) and electrochemical characterization of unmodified/modified electrodes was performed by cyclic voltammetry (CV). Experimental parameters; such as, the concentration of 6‐TG and its interaction time with dsDNA were optimized by using differential pulse voltammetry (DPV). Additionally, the interaction of 6‐TG with dsDNA was studied in case of different interaction times by electrochemical impedance spectroscopy (EIS) in contrast to voltammetric results. The detection limit of 6‐TG was found to be 0.25 μM by SWCNT‐PGE.     

Unwinding DNA and RNA with Synthetic Complexes: On the Way to Artificial Helicases

Synthetic helicases can be designed on the basis of ligands that bind more strongly to single‐stranded nucleic acids than to double‐stranded nucleic acids. This can be achieved with ligands containing phenyl groups, which intercalate into single strands, but due to their small size not into double strands. Moreover, two phenyl rings are combined with a distance that allows bis‐intercalation with only single strands and not double strands. In this respect, such ligands also mimic single‐strand binding (SSB) proteins. Exploration with more than 23 ligands, mostly newly synthesised, shows that the distance between the phenyl rings and between those and the linker influence the DNA unwinding efficiency, which can reach a melting point decrease of almost ΔT_m=50 °C at much lower concentrations than that with any other known artificial helicases. Conformational pre‐organisation of the ligand plays a decisive role in optimal efficiency. Substituents at the phenyl rings have a large effect, and increase, for example, in the order of H<F<Cl<Br, which illustrates the strong role of dispersive interactions in intercalation. Studies with homopolymers revealed significant selectivity: for example, with a ligand concentration of 40 μM at 35 °C, only GC double strands melt (ΔT_m=48 °C), whereas the AT strand remains untouched, and with poly(rA)–poly(rU) as an RNA model one observes unfolding at 29 °C with a concentration of only 30 μM .     

Chitosan/Ionic Liquid Composite Electrode for Electrochemical Monitoring of the Surface‐Confined Interaction Between Mitomycin C and DNA

In the present study a chitosan/ionic liquid modified pencil graphite electrode (CHIT‐IL‐PGEs) was developed for the first time for enhanced electrochemical monitoring of nucleic acid, and the interaction of the anticancer drug Mitomycin C (MC) and calf thymus double stranded DNA (dsDNA) by measuring the oxidation signals of MC and guanine in the same voltammetric scale. Differential pulse voltammetry, cyclic voltammetry and electrochemical impedance spectroscopy techniques were used to evaluate the performance of the CHIT‐IL based biosensor on electrochemical monitoring of DNA, and drug‐DNA interaction. The experimental parameters, IL, dsDNA and MC concentration and the interaction time were then optimized.     

A thermodynamic investigation on the binding of phenothiazinium dyes azure A and azure B to double stranded RNA polynucleotides

The thermodynamics of the reactions of the two phenothiazinium dyes azure A and azure B with the three double stranded ribonucleic acids, poly(A).poly(U), poly(C).poly(G), poly(I).poly(C) were investigated using DSC and ITC. The bound dyes stabilized the RNAs against thermal strand separation. The binding of azure A to the RNAs was predominantly enthalpy dominated while the binding of azure B was favoured by both negative enthalpy and favourable entropy changes. Although electrostatic interaction had a significant role in the binding, non-polyelectrolytic forces dominated the binding process. The negative values of heat capacity changes for the binding suggested a substantial hydrophobic contribution to the binding process. The overall binding affinity of both the dyes to the RNAs varied in the order, poly(A).poly(U) > poly(C).poly(G) > poly(I).poly(C).     

Voltammetric Studies on the Recognition of a Copper Complex to Single‐ and Double‐Stranded DNA and Its Application in Gene Biosensor

A mixed‐ligands copper complex [Cu(phendione)(DAP)]SO₄ (phendione=1,10‐phenanthroline‐5,6‐dione, DAP=2,3‐diaminophenazine) was synthesized. Cyclic voltammetry showed that the complex underwent an obvious decrease of redox peak currents and positive shift of formal potential after interaction with double‐stranded DNA (dsDNA), suggesting that the copper complex behaved as a typical metallointercalator for dsDNA, The recognition properties of the copper complex to single‐stranded DNA (ssDNA) and dsDNA were assessed using surface‐based electrochemical methods and the results suggested that the complex had obviously different redox signals at ssDNA and dsDNA modified electrodes. The copper complex was further used as an electroactive indicator for the detection of cauliflower mosaic virus (CaMV) 35S promoter gene.     

Investigation of Metal Ion Effect on Specific DNA Sequences and DNA Hybridization

In this article, we investigated the sequence specific interaction of single (ssDNA) and double stranded (dsDNA) with silver ions (Ag⁺) with electrochemical methods. We, for the first time, examined the effect of base sequences, base content and physiochemical properties of different DNA sequences on interaction with Ag⁺ in detail. We used different base contents to show how the composition of nucleic acid influences the electrochemical signals. We first immobilized ssDNA probes on bare graphite electrodes. Then, we showed the sequence effect on oxidation signals of AgDNA complex by sensing Ag⁺ to the probe coated surfaces to interact with different ssDNA sequences. Furthermore, we investigated the effect of Ag⁺ on dsDNA. We measured the oxidation signals obtained from Ag⁺‐ssDNA and Ag⁺‐dsDNA complex at approximately 0.2 V and 1.0 V (vs Ag/AgCl), respectively with Differential Pulse Voltammetry (DPV). We showed that the oxidation signals of the AgDNA complex obtained from dsDNA‐modified electrodes is higher than the electrodes modified with ssDNA. More importantly, we showed that Ag⁺‐ssDNA and Ag⁺ ion‐dsDNA exhibit different electrochemical behaviors.     

A Photoreactive G‐Quadruplex Ligand Triggered by Green Light

A photoreactive molecular dye targeting the G‐quadruplex nucleic acid (G4) of the human telomeric sequence Tel22, and several mutated analogues, was activated by green light (λ=532 nm). Highly selective covalent modification of G4 versus single‐stranded and double‐stranded DNA was achieved with efficiency up to 64 %. The phenoxyl radical was generated and detected by laser‐flash photolysis as a reactive intermediate that targeted loop thymine residues. These insights may suggest a non‐invasive tool for selective nucleic acid tagging and “pull‐down” cellular applications.     

Electrochemical Determination of the Effect of Caffeic Acid onto the Interaction between Idarubicin and DNA by Single‐use Disposable Electrodes

Now it is well known, antioxidant may affect the interaction of anticancer drugs and DNA. This study aims to investigate the interaction between Idarubicin and DNA and the effect of caffeic acid on this interaction. Disposable, inexpensive, easy handle electrodes were used in this study to investigate the interaction of idarubicin and DNA electrochemically. Idarubicin (IDR) is an anthracyline antitumor antibiotic, which used against one or more types of leukemia. Electrochemical behaviour of IDR was investigated by using cyclic voltammetry. The interaction between anticancer drug, IDR and calf thymus double‐stranded DNA (ctdsDNA) was investigated by using differential pulse voltammetry (DPV) technique in the absence and presence of caffeic acid.     

On the stability of double stranded nucleic acids

We present the first pressure-versus-temperature phase diagram for the helix-to-coil transition of double stranded nucleic acids. The thermodynamic stability of a nucleic acid duplex is a complex function of temperature and pressure and strongly depends on the denaturation temperature, T(M), of the duplex at atmospheric pressure. Depending upon T(M), pressure, and temperature, the phase diagram shows that pressure may stabilize, destabilize, or have no effect on the conformational state of DNA. To verify the phase diagram, we have conducted high-pressure UV melting experiments on poly(dIdC)poly(dIdC), a DNA duplex, poly(rA)poly(rU), an RNA duplex, and poly(dA)poly(rU), a DNA/RNA hybrid duplex. The T(M) values of these duplexes have been modulated by altering the solution ionic strength. Significantly, at low salt, these three duplexes have helix-to-coil transition temperatures of 50 degrees C or less. In agreement with the derived phase diagram, we found that the polymeric duplexes were destabilized by pressure if the T(M) is < approximately 50 degrees C. However, these duplexes were stabilized by pressure if the T(M) is > approximately 50 degrees C. The DNA/RNA hybrid duplex, poly(dA)poly(rU), with a T(M) of 31 degrees C in 20 mM NaCl undergoes a pressure-induced helix-to-coil transition at room temperature. This is the first report of pressure-induced denaturation of a nucleic acid duplex and provides new insights into the molecular forces stabilizing these structures.     

Graphene oxide integrated sensor for electrochemical monitoring of mitomycin C-DNA interaction

We present a graphene oxide (GO) integrated disposable electrochemical sensor for the enhanced detection of nucleic acids and the sensitive monitoring of the surface-confined interactions between the anticancer drug mitomycin C (MC) and DNA. Interfacial interactions between immobilized calf thymus double-stranded (dsDNA) and anticancer drug MC were investigated using differential pulse voltammetry (DPV) and electrochemical impedance spectroscopy (EIS) techniques. Based on three repetitive voltammetric measurements of 120 μg mL(-1) DNA immobilized on GO-modified electrodes, the RSD % (n = 3) was calculated as 10.47% and the detection limit (DL) for dsDNA was found to be 9.06 μg mL(-1). EIS studies revealed that the binding of the drug MC to dsDNA leads to a gradual decrease of its negative charge. As a consequence of this interaction, the negative redox species were allowed to approach the electrode, and thus increase the charge transfer kinetics. On the other hand, DPV studies exploited the decrease of the guanine signal due to drug binding as the basis for specifically probing the biointeraction process between MC and dsDNA.     

DNA and RNA noncovalent interaction of platinum(II) polypyridine complexes

A comparative investigation of the noncovalent interaction of the platinum(II) polypyridine complexes [Pt(dipy)(n-Rpy)2]2+ and [Pt(4,4'-Me2dipy)(2-Rpy)2]2+ (dipy = 2,2'-dipyridine; Me = CH3; n = 2-4; R = H or CH3) with double-helical DNA (calf thymus) and RNA [poly(A).poly(U)] has been conducted. With the exception of [Pt(dipy)(2-Mepy)2]2+, all of the complexes interact strongly, by intercalation, with both nucleic acids giving rise to large changes in the electronic spectra and induced circular dichroism signals; in addition, viscosity experiments on rodlike DNA and RNA show that both biopolymers elongate upon interaction with the complexes. The binding constant values, KB, determined at 25 degrees C, indicate that, at 0.101 M ionic strength, the affinity for poly(A).poly(U) is strongly dependent on the complexes nature, while for DNA it is leveled off. [Pt(dipy)(2-Mepy)2]2+ binds to DNA but does not interact appreciably with poly(A).poly(U).     

Determination of Electrochemical Interaction between 2‐(1H‐benzimidazol‐2‐yl) Phenol and DNA Sequences

A benzimidazole derivate, 2‐(1H‐benzimidazol‐2‐yl) phenol (2‐Bip) and its interaction mechanism with sequence specific DNA was examined with Differential Pulse Voltammetry (DPV). We, for the first time, investigated the effect of 2‐Bip on sequence specific DNA with electrochemical methods by evaluating both guanine and 2‐Bip oxidation signal changes. In the study, probe sequences were immobilized to the surface of the electrodes and then hybridization was achieved by sending the complementary target onto the probe modified electrodes. Following the hybridization, 2‐Bip solution was interacted with probe and hybrid sequences to see the effect of 2‐Bip on different DNA sequences. The binding constant (K), toxicity (S%) and thermodynamic parameters, i. e., Gibbs free energy (ΔG°) of 2‐Bip‐DNA complexes were evaluated. K was calculated as 5×10⁵ and the change in the ΔG° was found as ?32.50 kJ mol^?1, which are consistent well with the literature. Furthermore, S% showed that 2‐Bip is moderately toxic to single stranded DNA (ssDNA) and toxic to double stranded DNA (dsDNA). From our experimental data, we made four conclusions (i) 2‐Bip affects both ssDNA and dsDNA, (ii) 2‐Bip interaction mode with DNA could be non‐covalent interactions, (iii) 2‐Bip could be used as new DNA hybridization indicator due to its distinct effects on ssDNA and dsDNA, (iv) 2‐Bip could be used as a drug molecule for its DNA effect.     

High performance separations of nucleic acids using capillary electrophoresis and high-performance liquid chromatography

High resolution separations of nucleic acids have been performed using high performance capillary electrophoresis (HPCE) and high performance liquid chromatography (HPLC). Electropherograms showing HPCE separations of single and double stranded DNA are presented and compared with HPLC separations. Single base resolution of poly(dA) oligonucleotides in the size range of 12 to 60-mers was achieved in 35 min using HPCE. Plate numbers for HPCE are in the hundreds of thousands and reproducibility is about 1–2 % (RSD). In comparison with HPLC separations, the resolution of nucleic acids obtained using HPCE is much better than that using HPLC, while reproducibility of HPCE is comparable with that of HPLC.     

Luminescent Cyclometalated Platinum(II) Complex Forms Emissive Intercalating Adducts with Double‐Stranded DNA and RNA: Differential Emissions and Anticancer Activities

Luminescent metallo‐intercalators are potent biosensors of nucleic acid structure and anticancer agents targeting DNAs. There are few examples of luminescent metallo‐intercalators which can simultaneously act as emission probes of nucleic acid structure and display promising anticancer activities. Herein, we describe a luminescent platinum(II) complex, [Pt(C^N^N)(C≡NtBu)]ClO₄ ( 1 a , HC^N^N= 6‐phenyl‐2,2′‐bipyridyl), that intercalates between the nucleobases of nucleic acids, accompanied by an increase in emission intensity and/or a significant change in the maximum emission wavelength. The changes in emission properties measured with double‐stranded RNA (dsRNA) are different from those with dsDNA used in the binding reactions. Complex 1 a exhibited potent anticancer activity towards cancer cells in vitro and inhibited tumor growth in a mouse model. The stabilization of the topoisomerase I–DNA complex with resulting DNA damage by 1 a is suggested to contribute to its anticancer activity.     

Facile synthesis of dumbbell‐shaped dendritic‐linear‐dendritic triblock copolymer via reversible addition‐fragmentation chain transfer polymerization

We report the first instance of facile synthesis of dumbbell‐shaped dendritic‐linear‐dendritic triblock copolymer, [G‐3]‐PNIPAM‐[G‐3], consisting of third generation poly(benzyl ether) monodendrons ([G‐3]) and linear poly(N‐isopropylacrylamide) (PNIPAM), via reversible addition‐fragmentation chain transfer (RAFT) polymerization. The key step was the preparation of novel [G‐3]‐based RAFT agent, [G‐3]‐CH₂SCSSCH₂‐[G‐3] (1), from third‐generation dendritic poly(benzyl ether) bromide, [G‐3]‐CH₂Br. Due to the bulky nature of [G‐3]‐CH₂Br, its transformation into trithiocarbonate 1 cannot go to completion, a mixture containing ～80 mol % of 1 and 20 mol % [G‐3]‐CH₂Br was obtained. Dumbbell‐shaped [G‐3]‐PNIPAM₃₁₀‐[G‐3] triblock copolymer was then successfully obtained by the RAFT polymerization of N‐isopropylacylamide (NIPAM) using 1 as the mediating agent, and trace amount of unreacted [G‐3]‐CH₂Br was conveniently removed during purification by precipitating the polymer into diethyl ether. The dendritic‐linear‐dendritic triblock structure was further confirmed by aminolysis, and fully characterized by gel permeation chromatography (GPC) and ¹H‐NMR. The amphiphilic dumbbell‐shaped triblock copolymer contains a thermoresponsive PNIPAM middle block, in aqueous solution it self‐assembles into spherical nanoparticles with the core consisting of hydrophobic [G‐3] dendritic block and stabilized by the PNIPAM central block, forming loops surrounding the insoluble core. The micellar properties of [G‐3]‐PNIPAM₃₁₀‐[G‐3] were then fully characterized. © 2006 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 45: 1432–1445, 2007     

Spectral and Electrochemical Investigation of Intercalations of Adrenaline and CT－DNA

A strong interaction between double stranded calf-thymus DNA (ds-DNA) and adrenaline in solution, but no interaction between single stranded calf-thymus DNA (ss-DNA) and adrenaline was observed by the use of UV-visible spectroscopy and voltammetric techniques. It is suggested that the interaction leads to an intercalation of adrenaline molecules into the groove of ds-DNA and the formation of ds-DNA (adrenallne)n complex. The binding site size of the interaction of adrenaline with CT-DNA in nucleotide phosphate [ NP] has been determined as 25. The interaction of different concentration adrenaline with DNA modified GCE shows that the DNA modified GCE can be a good tool to detect lower concentration adrenaline.     

Retention of nucleic acids in ion‐pair reversed‐phase high‐performance liquid chromatography depends not only on base composition but also on base sequence

The study on nucleic acid retention in ion‐pair reversed‐phase high‐performance liquid chromatography mainly focuses on size‐dependence, however, other factors influencing retention behaviors have not been comprehensively clarified up to date. In this present work, the retention behaviors of oligonucleotides and double‐stranded DNAs were investigated on silica‐based C₁₈ stationary phase by ion‐pair reversed‐phase high‐performance liquid chromatography. It is found that the retention of oligonucleotides was influenced by base composition and base sequence as well as size, and oligonucleotides prone to self‐dimerization have weaker retention than those not prone to self‐dimerization but with the same base composition. However, homo‐oligonucleotides are suitable for the size‐dependent separation as a special case of oligonucleotides. For double‐stranded DNAs, the retention is also influenced by base composition and base sequence, as well as size. This may be attributed to the interaction of exposed bases in major or minor grooves with the hydrophobic alky chains of stationary phase. In addition, no specific influence of guanine and cytosine content was confirmed on retention of double‐stranded DNAs. Notably, the space effect resulted from the stereostructure of nucleic acids also influences the retention behavior in ion‐pair reversed‐phase high‐performance liquid chromatography.