Structure–affinity relationships for the binding of actinomycin D to DNA

Molecular models of the complexes between actinomycin D and 14 different DNA hexamers were built based on the X-ray crystal structure of the actinomycin–d(GAAGCTTC)2 complex. The DNA sequences included the canonical GpC binding step flanked by different base pairs, nonclassical binding sites such as GpG and GpT, and sites containing 2,6-diamino- purine. A good correlation was found between the intermolecular interaction energies calculated for the refined complexes and the relative preferences of actinomycin binding to standard and modified DNA. A detailed energy decomposition into van der Waals and electrostatic components for the interactions between the DNA base pairs and either the chromophore or the peptidic part of the antibiotic was performed for each complex. The resulting energy matrix was then subjected to principal component analysis, which showed that actinomycin D discriminates among different DNA sequences by an interplay of hydrogen bonding and stacking interactions. The structure–affinity relationships for this important antitumor drug are thus rationalized and may be used to advantage in the design of novel sequence-specific DNA-binding agents.     

O6-Alkylguanine DNA Alkyltransferase Mediated Disassembly of a DNA Tetrahedron

Tetrahedron DNA structures were formed by the assembly of three-way junction ( TWJ ) oligonucleotides containing O⁶-2′-deoxyguanosine-alkylene-O⁶-2′-deoxyguanosine (butylene and heptylene linked) intrastrand cross-links (IaCLs) lacking a phosphodiester group between the 2′-deoxyribose residues. The DNA tetrahedra containing TWJs were shown to undergo an unhooking reaction by the human DNA repair protein O⁶-alkylguanine DNA alkyltransferase (hAGT) resulting in structure disassembly. The unhooking reaction of hAGT towards the DNA tetrahedra was observed to be moderate to virtually complete depending on the protein equivalents. DNA tetrahedron structures have been explored as drug delivery platforms that release their payload in response to triggers, such as light, chemical agents or hybridization of release strands. The dismantling of DNA tetrahedron structures by a DNA repair protein contributes to the armamentarium of approaches for drug release employing DNA nanostructures.     

A cationic dye triplet as a unique "glue" that can connect fully matched termini of DNA duplexes

In this study, we propose that three consecutive cationic p‐methylstilbazoles tethered on D ‐threoninols ( Z residues) at 5′ termini act as a unique “glue” connecting DNA duplexes by their interstrand cluster formation. Interstrand clustering of p‐methylstilbazoles ( ZZZ triplets) induces narrowing and hypsochromic shift of bands at 350 nm, which can be assigned to the absorption of p‐methylstilbazole. However, single‐stranded DNA conjugates involving a ZZZ triplet at the 5′ terminus of 8‐mer native nucleotides is found not to induce such large spectral changes, which implies that the intrinsic self‐assembling property of ZZZ triplets is weak. Interestingly, when this conjugate is hybridized with a complementary 8‐mer native oligonucleotide, a remarkable spectral change is observed, indicating the dimerization of a duplex through the interstrand clustering of ZZZ triplets. Dimerization of the duplex is also evidenced by cold‐spray ionization mass spectrometry. This interstrand clustering is observed only when a ZZZ triplet is tethered to a 5′ rather than 3′ terminus. Furthermore, the stability of the interstrand cluster increases by increasing the number of nucleobases of the DNA portion, and when mismatched base pairs are incorporated or when a base next to the Z residue is deleted, the stability substantially drops. When we apply the ZZZ triplet to the formation of a nanowire using two complementary DNA conjugates, each of which has a ZZZ triplet at the 5′ termini as overhang, we demonstrate the successful formation of a nanowire by native PAGE analysis. Since native sticky ends that have three nucleotides do not serve as “glue”, ZZZ triplets with their unique glue‐like properties are prime candidates for constructing DNA‐based nanoarchitectures.     

Importance of model size in quantum mechanical studies of DNA intercalation

The convergence of DFT-computed interaction energies with increasing binding site model size was assessed. The data show that while accurate intercalator interaction energies can be derived from binding site models featuring only the flanking nucleotides for uncharged intercalators that bind parallel to the DNA base pairs, errors remain significant even when including distant nucleotides for intercalators that are charged, exhibit groove-binding tails that engage in noncovalent interactions with distant nucleotides, or that bind perpendicular to the DNA base pairs. Consequently, binding site models that include at least three adjacent nucleotides are required to consistently predict converged binding energies. The computationally inexpensive HF-3c method is shown to provide reliable interaction energies and can be routinely applied to such large models.     

Interactions of single-stranded DNA on microcantilevers

The microcantilever approach has attracted considerable attention in recent years as a means of label-free detection of a variety of biomolecular and chemical reactions. The underlying physics of the intermolecular interactions that result in mechanical motions is yet to be fully explored, but it seems both rich in science and of technological importance. This paper presents an overview of experiments and theories related to interactions of single-stranded DNA immobilized on microcantilevers. Experiments and theories show that, at high grafting density, hydration forces are the dominant factor determining cantilever deflections, not electrostatics or conformational entropy.     

DNA codes for nanoscience

The nanometer scale is a special place where all sciences meet and develop a particularly strong interdisciplinarity. While biology is a source of inspiration for nanoscientists, chemistry has a central role in turning inspirations and methods from biological systems to nanotechnological use. DNA is the biological molecule by which nanoscience and nanotechnology is mostly fascinated. Nature uses DNA not only as a repository of the genetic information, but also as a controller of the expression of the genes it contains. Thus, there are codes embedded in the DNA sequence that serve to control recognition processes on the atomic scale, such as the base pairing, and others that control processes taking place on the nanoscale. From the chemical point of view, DNA is the supramolecular building block with the highest informational content. Nanoscience has therefore the opportunity of using DNA molecules to increase the level of complexity and efficiency in self-assembling and self-directing processes.     

Simulations of DNA coiling around a synthetic supramolecular cylinder that binds in the DNA major groove

In this work we present the results of a molecular simulation study of the interaction between a tetracationic bis iron(II) supramolecular cylinder, [Fe2(C25H20N4)3]4+, and DNA. This supramolecular cylinder has been shown to bind in the major groove of DNA and to induce dramatic coiling of the DNA. The simulations have been designed to elucidate the interactions that lead the cylinder to target the major groove and that drive the subsequent DNA conformational changes. Three sets of multi-nanosecond simulations have been performed: one of the uncomplexed d(CCCCCTTTTTCC) d(GGAAAAAGGGGG) dodecamer; one of this DNA complexed with the cylinder molecule; and one of this DNA complexed with a neutralised version of the cylinder. Coiling of the DNA was observed in the DNA-cylinder simulations, giving insight into the molecular level nature of the supramolecular coiling observed experimentally. The cylinder charge was found not to be essential for the DNA coiling, which implies that the DNA response is moderated by the short range interactions that define the molecular shape. Cylinder charge did, however, affect the integrity of the DNA duplex, to the extent that, under some circumstances, the tetracationic cylinder induced defects in the DNA base pairing at locations adjacent to the cylinder binding site.     

Fluorescent hydrophobic zippers inside duplex DNA: interstrand stacking of perylene-3,4:9,10-tetracarboxylic acid bisimides as artificial DNA base dyes

Perylene-3,4:9,10-tetracarboxylic acid bisimides (PBs) were incorporated synthetically into oligonucleotides by using automated DNA building-block chemistry. The 2'-deoxyribofuranoside of the natural nucleosides was replaced by (S)-aminopropan-2,3-diol as an acyclic linker between the phosphodiester bridges that is tethered to one of the imide nitrogen atoms of the PB dye. The S configuration of this linker was chosen to mimic the stereochemical situation at the 3'-position of the natural 2'-deoxyribofuranosides. By using this strategy, up to six PB dyes were incorporated in the middle of 18-mer DNA duplexes by using interstrand alternating sequences of PBs with thymines or an abasic site analogue. Both PB dimers and PB hexamers as artificial base substitutions inside the duplexes yield characteristic excimer-type fluorescence. The stacking properties of the PB chromophores are modulated by the presence or absence of thymines opposite the PB modification site in the counterstrand. The interstrand PB dimers can be regarded as hydrophobically interacting base pairs, which display a characteristic fluorescence readout signal. Hence, for the PB hexamers, we proposed a zipperlike recognition motif that is formed inside duplex DNA. The PB zipper shows characteristic excimer-type emission as a fluorescence readout signal for the pairing interaction.     

DNA amplification fingerprinting using arbitrary oligonucleotide primers

DNA amplification fingerprinting (DAF) is a strategy for genetic typing and mapping that uses one or more very short (≥5 nt) arbitrary oligonucleotides to direct the enzymatic amplification of discrete portions of a DNA template resulting in a spectrum of products characteristic of the DNA starting material. Polymorphisms from simple banding patterns are useful as genetic markers while more complex and informative patterns are suitable for DNA fingerprinting. The use of polyacrylamide gel electrophoresis and silver staining can adequately resolve the spectrum of DAF products into detailed and reproducible patterns.     

Fluorous base-pairing effects in a DNA polymerase active site

We describe selective "fluorous" effects in the active site of a DNA polymerase, by using nucleotide analogues whose pairing edges are perfluorinated. The 5'-triphosphate deoxynucleotide derivatives of DNA base analogues 2,3,4,5-tetrafluorobenzene ((F)B) and 4,5,6,7-tetrafluoroindole ((F)I), as well as hydrocarbon controls benzene (B) and indole (I), were synthesized and studied as substrates for the DNA Polymerase I Klenow fragment (KF exo-). Modified nucleotides were present in the DNA template or were supplied as nucleoside triphosphates in studies of the steady-state kinetics of single nucleotide insertion. When supplied opposite the non-natural bases in the template strand, the hydrophobic nucleoside triphosphates were incorporated by up to two orders of magnitude more efficiently than the natural deoxynucleoside triphosphates. The purine-like fluorinated indole nucleotide ((F)I) was the most efficiently inserted of the four hydrophobic analogues, with the most effective incorporation occurring opposite the pyrimidine-like tetrafluorobenzene ((F)B). In all cases, the polyfluorinated base pairs were more efficiently processed than the analogous hydrocarbon pairs. A preliminary test of polymerase extension beyond these pairs showed that only the (F)B base is appreciably extended; the inefficient extension is consistent with recently published data regarding other nonpolar base pairs. These results suggest the importance of hydrophobicity, stacking, and steric interactions in the polymerase-mediated replication of DNA base pairs that lack hydrogen bonds. These findings further suggest that the enhanced hydrophobicity of polyfluoroaromatic bases could be employed in the design of new, selective base pairs that are orthogonal to the natural Watson-Crick pairs used in replication.     

Optical sensors based on hybrid DNA/conjugated polymer complexes

Single-stranded DNA (ss-DNA) can specifically bind to various targets, including a complementary ss-DNA, ions, proteins, drugs, and so forth. When binding takes place, the oligonucleotide probe often undergoes a conformational transition. This conformational change of the negatively charged ss-DNA can be detected by using a water-soluble, cationic polythiophene derivative, which transduces the complex formation into an optical (colorimetric or fluorometric) signal without any labeling of the probe or the target. This simple and rapid methodology has enabled the specific and sensitive detection of nucleic acids and human thrombin. This new biophotonic tool can easily be applied to the detection of various other biomolecules and is also useful in the high-throughput screening of new drugs.     

Capillary zone electrophoretic studies of interactions of some quaternary isoquinoline alkaloids with DNA constituents and DNA

Capillary zone electrophoresis was applied for the investigation of interactions of some quaternary isoquinoline alkaloids, namely sanguinarine, chelerythrine, berberine, and jatrorrhizine, with DNA constituents and with DNA. None of these alkaloids attach covalently to nucleotides or to the whole DNA under physiological conditions. The interaction with DNA constituents is a noncovalent complexation based on weak intermolecular forces. Electrostatic attraction participates in the interaction but other types of intermolecular forces are involved as well. Cations were identified as the most probable interacting forms of the alkaloids. The interaction with compounds derived from purine was always stronger than those derived from pyrimidine. All alkaloids behaved analogously and similarly to ethidium bromide, the classic DNA intercalator. Stability constants K (in l.mol(-1)) for sanguinarine and chelerythrine in phosphate buffer of pH 7.4 (I(S) = 30 mM) ranged from tens to hundreds.     

DNA and surfactants in bulk and at interfaces

Recent investigations of the DNA interactions with cationic surfactants and catanionic mixtures are reviewed. Several techniques have been used such as fluorescence microscopy, dynamic light scattering, electron microscopy, and Monte Carlo simulations.

The conformational behaviour of large DNA molecules in the presence of cationic surfactant was followed by fluorescence microscopy and also by dynamic light scattering. These techniques were in good agreement and it was possible to observe a discrete transition from extended coils to collapsed globules and their coexistence for intermediate amphiphile concentrations. The dependence on the surfactant alkyl chain was also monitored by fluorescence microscopy and, as expected, lower concentrations of the more hydrophobic surfactant were required to induce DNA compaction, although an excess of positive charges was still required.

Monte Carlo simulations on the compaction of a medium size polyanion with shorter polycations were performed. The polyanion chain suffers a sudden collapse as a function of the concentration of condensing agent, and of the number of charges on the polycation molecules. Further increase in the concentration increases the degree of compaction. The compaction was found to be associated with the polycations promoting bridging between different sites of the polyanion. When the total charge of the polycations was lower than that of the polyanion, a significant translational motion of the compacting agent along the polyanion was observed, producing only a small-degree of intrachain segregation, which can explain the excess of positive charges necessary to compact DNA.

Dissociation of the DNA–cationic surfactant complexes and a concomitant release of DNA was achieved by addition of anionic surfactants. The unfolding of DNA molecules, previously compacted with cationic surfactant, was shown to be strongly dependent on the anionic surfactant chain length; lower amounts of a longer chain surfactant were needed to release DNA into solution. On the other hand, no dependence on the hydrophobicity of the compacting agent was observed. The structures of the aggregates formed by the two surfactants, after the interaction with DNA, were imaged by cryogenic transmission electron microscopy. It is possible to predict the structure of the aggregates formed by the surfactants, like vesicles, from the phase behaviour of the mixed surfactant systems.

Studies on the interactions between DNA and catanionic mixtures were also performed. It was observed that DNA does not interact with negatively charged vesicles, even though they carry positive amphiphiles; however, in the presence of positively charged vesicles, DNA molecules compact and adsorb on their surface.

Finally Monte Carlo simulations were performed on the adsorption of a polyelectrolyte on catanionic surfaces. It was observed that the mobile charges in the surface react to the presence of the polyelectrolyte enabling a strong degree of adsorption even though the membrane was globally neutral. Our observations indicate that the adsorption behaviour of the polyelectrolyte is influenced by the response given by the membrane to its presence and that the number of adsorbed beads increases drastically with the increase of flexibility of the polymer. Calculations involving polymers with three different intrinsic stiffnesses showed that the variation is non-monotonic. It was observed also that a smaller polyanion typically adsorbs more completely than the larger one, which indicates that the polarisation of the membrane becomes less facilitated as the degree of disruption increases.