Non-Watson-Crick structures in oligodeoxynucleotides: self-association of d(TpCpGpA) stabilized at acidic pH

Ionic Strength-Mediated Phase Transitions of Surface-Adsorbed DNA on Single-Walled Carbon Nanotubes

Single-stranded DNA oligonucleotides have unique, and in some cases sequence-specific molecular interactions with the surface of carbon nanotubes that remain the subject of fundamental study. In this work, we observe and analyze a generic, ionic strength-mediated phase transition exhibited by over 25 distinct oligonucleotides adsorbed to single-walled carbon nanotubes (SWCNTs) in colloidal suspension. The phase transition occurs as monovalent salts are used to modify the ionic strength from 500 mM to 1 mM, causing a reversible reduction in the fluorescence quantum yield by as much as 90%. The phase transition is only observable by fluorescence quenching within a window of pH and in the presence of dissolved O₂, but occurs independently of this optical quenching. The negatively charged phosphate backbone increases (decreases) the DNA surface coverage on an areal basis at high (low) ionic strength, and is well described by a two-state equilibrium model. The resulting quantitative model is able to describe and link, for the first time, the observed changes in optical properties of DNA-wrapped SWCNTs with ionic strength, pH, adsorbed O₂, and ascorbic acid. Cytosine nucleobases are shown to alter the adhesion of the DNA to SWCNTs through direct protonation from solution, decreasing the driving force for this phase transition. We show that the phase transition also changes the observed SWCNT corona phase, modulating the recognition of riboflavin. These results provide insight into the unique molecular interactions between DNA and the SWCNT surface, and have implications for molecular sensing, assembly, and nanoparticle separations.

Exploring the mode of binding of the bioflavonoid kaempferol with B and protonated forms of DNA using spectroscopic and molecular docking studies

Mode of binding of kaempferol with B and protonated form of calf thymus DNA.

Molecular aspects on the interaction of protoberberine, benzophenanthridine, and aristolochia group of alkaloids with nucleic acid structures and biological perspectives

Alkaloids occupy an important position in chemistry and pharmacology. Among the various alkaloids, berberine and coralyne of the protoberberine group, sanguinarine of the benzophenanthridine group, and aristololactam-beta-d-glucoside of the aristolochia group have potential to form molecular complexes with nucleic acid structures and have attracted recent attention for their prospective clinical and pharmacological utility. This review highlights (i) the physicochemical properties of these alkaloids under various environmental conditions, (ii) the structure and functional aspects of various forms of deoxyribonucleic acid (DNA) (B-form, Z-form, H(L)-form, protonated form, and triple helical form) and ribonucleic acid (RNA) (A-form, protonated form, and triple helical form), and (iii) the interaction of these alkaloids with various polymorphic DNA and RNA structures reported by several research groups employing various analytical techniques like absorbance, fluorescence, circular dichroism, and NMR spectroscopy; electrospray ionization mass spectrometry, thermal melting, viscosity, and DNase footprinting as well as molecular modeling and thermodynamic studies to provide detailed binding mechanism at the molecular level for structure-activity relationship. Nucleic acids binding properties of these alkaloids are interpreted in relation to their biological activity.

Low ionic strength reduces cytosine photoreactivity in UVC-irradiated isolated DNA

Exposure of DNA to far-UV radiation leads to the formation of several types of dimeric lesions, including cyclobutane dimers and (6-4) photoproducts. In order to gain insights into the main parameters driving DNA photochemistry, the effect of ionic strength on the yield of formation of these photoproducts was investigated in UVC-irradiated samples of isolated genomic DNA. The main consequence of lowering the ionic strength was a decrease in the UVC-induced formation of thymine-cytosine and cytosine-cytosine photoproducts. The reactivity of thymine-thymine and cytosine-thymine doublets was hardly affected. Evidence was obtained against a major role played by duplex denaturation in these observations. A more likely explanation is a change in the DNA structure as the result of a larger extent of protonation at low counter-ions concentration.

Acid titrations of poly(dG-dC).poly(dG-dC) in aqueous solution and in a w/o microemulsion

The model polynucleotide poly(dG-dC).poly(dG-dC) (polyGC) was titrated with a strong acid (HCl) in aqueous unbuffered solutions and in the quaternary w/o microemulsion CTAB/n-pentanol/n-hexane/water. The titrations, performed at several concentrations of NaCl in the range 0.005 to 0.600 M, were followed by recording the modifications of the electronic absorption and of the CD spectra (210< or = lambda < or =350 nm) upon addition of the acid. In solution, the polynucleotide undergoes two acid-induced transitions, neither of which corresponds to denaturation of the duplex to single coil. The first transition leads to the Hoogsteen type synG.C+ duplex, while the second leads to the C+.C duplex. The initial B-form of polyGC was recovered by back-titration with NaOH. The apparent pKa values were obtained for both steps of the titration, at all salt concentrations. A reasonably linear dependence of pKa1 and pKa2 from p[NaCl] was obtained, with both pKa values decreasing with increasing ionic strength. In microemulsion, at salt concentrations < or = 0.300 M, an acid-induced transition was observed, matching the first conformational transition recorded also in solution. However, further addition of acid led to denaturation of the protonated duplex. Renaturation of polyGC was obtained by back-titration with NaOH. At salt concentrations > 0.300 M, polyGC is present as a mixture of B-form and psi- aggregates, that slowly separate from the microemulsion. The acid titration induces at first a conformational transition similar to the one observed at low salt or in solution, then denaturation occurs, which is however preceded by the appearance of a transient conformation, that has been tentatively classified as a left-handed Z double helix.

The binding of DNA intercalating and non-intercalating compounds to A-form and protonated form of poly(rC).poly(rG): spectroscopic and viscometric study

Polymorphic RNA conformations may serve as potential targets for structure specific antiviral agents. As an initial step in the development of such drugs, the interaction of a wide variety of compounds which are characterized to bind to DNA through classical or partial intercalation or by mechanism of groove binding, with the A-form and the protonated form of poly(rC).poly(rG), been evaluated by multifaceted spectroscopic and viscometric techniques. Results of this study suggest that (i) ethidium intercalates to the A-form of RNA, but does not intercalate to the protonated form, (ii) methylene blue intercalates to the protonated form of the RNA but does not intercalate to the A-form, (iii) actinomycin D does not bind to either conformations of the RNA, and (iv) berberine binds to the protonated form by partial intercalation process, while its binding to the A-form is very weak. The DNA groove binder distamycin A has much higher affinity to the protonated form of the RNA compared to the A-form and binds to both structures by non-intercalative mechanism. We conclude that the binding affinity characteristics of these DNA binding molecules to the RNA conformations are vastly different and may serve as data for the development of RNA based antiviral drugs.

Protonated structures of naturally occurring deoxyribonucleic acids and their interaction with berberine

Protonation-induced conformational changes in natural DNAs of diverse base composition under the influence of low pH, low temperature, and low ionic strength have been studied using various spectroscopic techniques. At pH3.40, 10mM [Na+], and at 5 degrees C, all natural DNAs irrespective of base composition adopted an unusual and stable conformation remarkably different from the canonical B-form conformation. This protonated conformation has been characterized to have unique absorption and circular dichroic spectral characteristics and exhibited cooperative thermal melting profiles with decreased thermal melting temperatures compared to their respective B-form counterparts. The nature of this protonated structure was further investigated by monitoring the interaction of the plant alkaloid, berberine that was previously shown from our laboratory to differentially bind to B-form and H(L)-form of poly[d(G-C)] [Bioorg. Med. Chem.2003, 11, 4861]. Binding of berberine to protonated conformation of natural DNAs resulted in intrinsic circular dichroic changes as well as generation of induced circular dichroic bands for the bound berberine molecule with opposite signs and magnitude compared with B-form structures. Nevertheless, the binding of the alkaloid to both the B and protonated forms was non-linear and non-cooperative as revealed from Scatchard plots derived from spectrophotometric titration data. Steady state fluorescence studies on the other hand showed remarkable increase of the rather weak intrinsic fluorescence of berberine on binding to the protonated structure compared to the B-form structure. Taken together, these results suggest that berberine can detect the formation of significant population of H(L)-form structures under the influence of protonation irrespective of heterogeneous base compositions in natural DNAs.

Does DNA acid fixation produce left-handed Z structure?

The effects of acetic acid (HCOOCH3) on the solution structure of calf-thymus DNA are studied at pH 7.3-2.5 with acid/DNA(P) (phosphate) molar ratios (r) of 1/40, 1/20, 1/10, 1, 2, 10, 20 and 40. Fourier Transform infrared (FTIR) difference spectroscopy is used to establish correlations between spectral changes and base protonation, DNA conformational transition and structural variations of the acid-DNA complexes in aqueous solution. The FTIR difference spectroscopic results showed that protonation of cytosine and subsequent unpairing of the G-C base pairs begins at pH 4-3 and continues up to pH 2.5, where a complete base separation and base unstacking occur. Similarly, protonation of A-T base pairs starts at pH 4-3 and is completed at pH 2.5, where base separation and base unstacking are observed. The protonation of the G-C base pair leads to the formation of Hoogsteen-type H-bonding, before a complete G-C disruption. The biopolymer protonation leads to the formation of several non-B-DNA structures, including left-handed Z conformation.

DNA polymorphism under the influence of low pH and low temperature

The polymorphic behaviour on the conformation of a alternating GC polymer and its methylated analogue has been studied under the influence of low pH, low temperature and low ionic strength from the measurements of UV-absorption and circular dichroic spectroscopy. Studies indicate that both the polymers isomerize to a stable left handed type conformations. The duplex nature of these conformations were inferred from thermal denaturation curves and the temperature dependence of the CD spectra. In natural DNA, the influence of low pH and low temperature also shows a defined conformational change, characterized by two positive CD bands. This conformational status is achieved in all DNAs irrespective of base composition or sequence of base pairs. Further evidence to this altered polymorphic state of natural DNAs is inferred from ethidium binding study.

Minor-groove binding models for acetylaminofluorene modified DNA

Minimized potential energy calculations have been employed to locate and evaluate energetically a number of different models for DNA modified at carbon-8 of guanine by acetylaminofluorene (AAF). Three different duplex nonamer sequences were investigated. In addition to syn guanine models which have some denaturation and a Z-DNA model, we have found two new types of structures in which guanine remains syn and the AAF is placed in the minor groove of a B-DNA helix. One type features Hoogsteen base pairing between the modified guanine and protonated cytosine, with a sharply bent helix. The other (here termed the "wedge" model because the aromatic amine is wedged into the minor groove) maintains a single hydrogen bond between O6 of the modified guanine and N3 of protonated cytosine, with much less deformation of the helix, and close Van der Waals contacts between the AAF and the walls of the minor groove. Both types of structures (as well as the related forms produced by deprotonation of cytosine) are energetically important in all three sequences examined. The wedge-type model, which is most favored except in alternating G-C sequences, has been previously observed in a combined NMR and computational characterization of an aminofluorene (AF) modified guanine opposite adenine in a DNA duplex undecamer (D. Norman, P. Abuaf, B.E. Hingerty, D. Live, D. Grunberger, S. Broyde and D.J. Patel, Biochemistry 28, 7462 (1989)).