The effect of methylation on the hydrogen-bonding and stacking interaction of nucleic acid bases

Methylated nucleosides play an important role in DNA/RNA function, and may affect republication by interrupting the base-pairing and base-stacking. In order to investigate the effect of methylation on the interaction between nucleic acid bases, this work presents the hydrogen-bonding and stacking interactions between 5-methylcytosine and guanine (G), cytosine (C) and G, 1-methyladenine and thymine (T), as well as adenine and T. Geometry optimization and potential energy surface scan have been performed for the involved complexes by MP2 calculations. The interaction energies, which were corrected for the basis-set superposition error by the full Boys–Bernardi counterpoise correction scheme, were used to evaluate the interaction intensity of these nucleic acid bases. The atoms in molecules theory and natural bond orbital analysis have been performed to study the hydrogen bonds in these complexes. The result shows that the methyl substitute contributes the stability to these complexes because it enhances either the hydrogen bonding or the staking interaction between nucleic acid bases studied.     

稀土氨基酸配合物与核酸的相互作用*

很多抗癌金属药物是以核酸为靶标。阐明小分子与核酸之间的相互作用对筛选具有高效选择性和低毒副作用的抗癌药物有重要意义。近年来,开发新型的具有对核酸序列特异性识别能力的抗癌药物己成为本领域的研究热点。稀土离子具有良好的磁学、光学、电学特性和配位能力,使稀土配合物成为新型药物试剂。然而,稀土离子在中性条件下易水解的特性极大地阻碍了稀土配合物对核酸分子识别的研究。近年来在近生理条件下合成的一系列镧系氨基酸配合物具有结构稳定、溶解性好等优点,解决了镧系离子易水解的问题。本文总结了目前关于镧系氨基酸配合物与核酸的相互作用及其序列选择性等方面的研究进展。     

Complex formation between tryptophan-containing peptides and nucleic acids: Fluorescence decay studies using synchrotron radiation

Synchrotron radiation has been used to determine the fluorescence decay parameters of a tryptophan-containing oligopeptide, Lys-Trp-Lys, bound to nucleic acids. All fluorescence decay curves can be fitted by a sum of two exponentials. The two lifetimes very likely correspond to two conformational states of the oligopeptide. The mean fluorescence lifetime of the peptide is not markedly affected upon binding to nucleic acids even though the fluorescence quantum yield is strongly reduced. A model is presented that accounts for the existing fluorescence data: two consecutive complexes are formed both involving electrostatic interactions. In one of the complexes the tryptophyl ring is stacked with the nucleic acid bases and its fluorescence is completely quenched. The other complex emits a fluorescence having characteristics which are similar to those of the free peptide.     

Hydration and stability of nucleic acid bases and base pairs

Empirical, quantum chemical calculations and molecular dynamics simulations of the role of a solvent on tautomerism of nucleic acid bases and structure and properties of nucleic acid base pairs are summarized. Attention was paid to microhydrated (by one and two water molecules) complexes, for which structures found by scanning of empirical potential surfaces were recalculated at a correlated ab initio level. Additionally, isolated as well as mono- and dihydrated H-bonded, T-shaped and stacked structures of all possible nucleic acid base pairs were studied at the same theoretical levels. We demonstrate the strong influence of a solvent on the tautomeric equilibrium between the tautomers of bases and on the spatial arrangement of the bases in a base pair. The results provide clear evidence that the prevalence of either the stacked or hydrogen-bonded structures of the base pairs in the solvent is not determined only by its bulk properties, but rather by specific hydrophilic interactions of the base pair with a small number of solvent molecules.     

Interactions of Safranin T with Nucleic Acids

The interactions of Safranin T (ST) with several nucleic acids have been investigated by electrochemical, UV‐visible and CD spectroscopic techniques. The form of the nucleic acid‐ST complexes is sensitive to the ratio of the two species. Two electrochemically inactive complexes such as, nucleic acid‐ST and nucleic acid‐2ST, were formed while ST interacts with nucleic acids. Two processes were obtained from spectral experiments: (1) at the high value of R (R is defined as the ratio of the total concentration of ST to that of nucleic acid), ST is groove‐binding with stacking, (2) at the low value of R, ST is groove‐binding without stacking. Intrinsic binding constants were obtained by spectral methods. The experiments also show that electrostatic binding plays an important role in the interaction of ST with nucleic acids.     

Screening of threading bis-intercalators binding to duplex DNA by electrospray ionization tandem mass spectrometry

The DNA binding of novel threading bis-intercalators V1, trans-D1, and cis-C1, which contain two naphthalene diimide (NDI) intercalation units connected by a scaffold, was evaluated using electrospray ionization mass spectrometry (ESI-MS) and DNAse footprinting techniques. ESI-MS experiments confirmed that V1, the ligand containing the -Gly3-Lys- peptide scaffold, binds to a DNA duplex containing the 5'-GGTACC-3' specific binding site identified in previous NMR-based studies. The ligand formed complexes with a ligand/DNA binding stoichiometry of 1:1, even when there was excess ligand in solution. Trans-D1 and cis-C1 are new ligands containing a rigid spiro-tricyclic scaffold in the trans- and cis- orientations, respectively. Preliminary DNAse footprinting experiments identified possible specific binding sites of 5'-CAGTGA-5' for trans-D1 and 5'-GGTACC-3' for cis-C1. ESI-MS experiments revealed that both ligands bound to DNA duplexes containing the respective specific binding sequences, with cis-C1 exhibiting the most extensive binding based on a higher fraction of bound DNA value. Cis-C1 formed complexes with a dominant 1:1 binding stoichiometry, whereas trans-D1 was able to form 2:1 complexes at ligand/DNA molar ratios >or=1 which is suggestive of nonspecific binding. Collisional activated dissociation (CAD) experiments indicate that DNA complexes containing V1, trans-D1, and cis-C1 have a unique fragmentation pathway, which was also observed for complexes containing the commercially available bis-intercalator echinomycin, as a result of similar binding interactions, marked by intercalation in addition to hydrogen bonding by the scaffold with the DNA major or minor groove.     

Functional monomers and polymers. CXXXI.. Synthesis and interaction studies on polyacrylamide and polymethacrylamide derivatives containing nucleic acid bases

Acrylamide and methacrylamide derivatives of nucleic acid bases were prepared from the corresponding aminoethyl derivatives. Free-radical polymerization of these monomers in water or in organic solvents gave their polymers. From the studies of the polymer complex formation by UV spectroscopy, it was found that extremely stable polymer complexes were formed between complementary polymers containing nucleic acid bases.     

Functional monomers and polymers. LXXI. Conformation and interaction studies of poly-L-lysine derivatives with pendant nucleic acid bases

Copolymers of L -lysine and L -lysine derivatives which contained nucleic acid bases substituted on the N^ε position were synthesized by grafting nucleic acid derivatives onto poly-L -lysine. The conformation and interaction of these copolymers in solution were studied by using spectroscopic measurements. They existed in helical conformation at neutral pH values, and the polymer complex formation among them was examined by ultraviolet (UV) measurements in organic solvents. A decrease in the nucleic acid base content of the copolymers resulted in a decrease in helical structures and also in interactions with the polymer-containing complementary bases.     

ESI-MS characterization of a novel pyrrole-inosine nucleoside that interacts with guanine bases

Based on binding studies undertaken by electrospray ionization-mass spectrometry, a synthetic pyrrole-inosine nucleoside, 1, capable of forming an extended three-point Hoogsteen-type hydrogen-bonding interaction with guanine, is shown to form specific complexes with two different quadruplex DNA structures [dTG₄T]₄ and d(T₂G₄)₄ as well as guanine-rich duplex DNA. The binding interactions of two other analogs were evaluated in order to unravel the structural features that contribute to specific DNA recognition. The importance of the Hoogsteen interactions was confirmed through the absence of specific binding when the pyrrole NH hydrogen-bonding site was blocked or removed. While 2, with a large blocking group, was not found to interact with virtually any form of DNA, 3, with the pyrrole functionality missing, was found to interact non-specifically with several types of DNA. The specific binding of 1 to guanine-rich DNA emphasizes the necessity of careful ligand design for specific sequence recognition.     

Theoretical study of fast repair of DNA damage by cistanoside C and analogs: Mechanism and docking

Experiments show that the natural substances phenylpropanoid glycosides (PPGs) extracted from pelicularis spicata are capable of repairing DNA damaged by oxygen radicals. Based on kinetic measurements and experiments on tumor cells, a theoretical study of the interaction between PPG molecules and isolated DNA bases, as well as a DNA fragment has been performed. An interaction mechanism reported early has been refined. The docking calculations performed using junction minimization of nucleic acids (JUMNA) software showed that the PPG molecules can be docked into the minor groove of DNA and form complexes with the geometry suitable for an electron transfer between guanine radical and the ligand. Such complexes can be formed without major distortions of DNA structure and are further stabilized by the interaction with the rhamnosyl side-groups.     

Functional Monomers and Polymers Containing Nucleic Acid Bases: Experiments on Template Polymerization

In order to see how the specific base-base interactions observed between complementary nucleic acid bases can be realized for free-radical polymerization systems, the template polymerization of methacrylate type monomers containing nucleic acid bases in the presence of template polymers containing complementary bases was studied. Stereoregular polymers were chosen as the template polymers. The radical copolymerization of the monomers containing complementary nucleic acid bases was also studied in different solvents.     

PHOTOCHEMICAL REACTIONS OF THYMINE WITH CARBOXYLIC ACIDS. A MODEL FOR NUCLEIC ACID-PROTEIN PHOTOCROSSLINKING

When nucleic acid bases are UV-irradiated in the presence of carboxylic acids or carboxylate anions new photoproducts are formed as compared to the bases irradiated in the absence of carboxylic acids. The behavior of thymine and thymidine has been examined in detail. At least four photoproducts are formed in the presence of propionic acid and three in the presence of butyric acid. None of them appears to be a cyclobutyl dimer. From the concentration dependence of the rate of photoproduct formation it is concluded that the reactive excited species is the first excited singlet state of thymine. When ¹⁴C-labelled thymine is irradiated in the presence of polyglutamic acid an important part of the radioactive material is covalently linked to the polymer. Photochemical reaction of thymine with glutamic (or aspartic) acid could thus induce crosslinks between proteins and nucleic acids. It is also shown that these photoproducts are stable under usual conditions of acidic hydrolysis of UV-irradiated DNA.     

Protein-induced DNA bending: the role of phosphate neutralisation

An important component of protein–nucleic acid interactions is the formation of salt bridges between cationic amino acid side chains and the anionic phosphate groups of the nucleic acid. We have used molecular mechanics to study the energetic and conformational impact of such interactions. Firstly, crystallographic protein–nucleic acid complexes from the Protein Data Bank were analysed in terms of DNA curvature and the presence of salt bridges. For complexes where the DNA is significantly bent, the contribution of salt bridges to this curvature was modelled by studying the effect of neutralising the appropriate phosphate groups. The number and the distribution of salt bridges vary widely for different DNA binding motifs and appear to have very different effects on DNA. In the case of homeodomain, bZIP and helix–loop–helix proteins, salt bridges induce DNA bending, whereas for prokaryotic helix–turn–helix proteins the number of salt bridges is much smaller and little bending is found. By analysing the components of the DNA deformation energy involved in protein binding we show that salt bridges consistently increase the flexibility of the DNA backbone. Received: 1 September 2000 / Accepted: 5 January 2001 / Published online: 3 May 2001     

A chloride-anion insensitive colorimetric chemosensor for trinitrobenzene and picric acid

A new receptor, the bisTTF-calix[2]thiophene[2]pyrrole derivative 3, has been prepared from the Lewis acid-catalyzed condensation of 2,5-bis(1-hydroxymethylethyl)thiopheno-TTF and pyrrole. This new system is found to form complexes with the electron-deficient guests, trinitrobenzene (TNB) and picric acid (PA), which serve as models for nitroaromatic explosives. The binding phenomenon, which has been studied in organic solution using proton nuclear magnetic resonance and absorption spectroscopies, results in an easy-to-visualize color change in chloroform that is independent of the presence of chloride anion, a known interferant for an earlier tetrakisTTF-calix[4]pyrrole TNB chemosensor. Support for the proposed binding mode comes from a preliminary solid state structure of the complex formed from TNB, namely TNB⊂3. A color change is also observed when dichloromethane solutions of chemosensor 3 are added to solvent-free samples of TNB, PA, and 2,4,6-trinitrotoluene supported on silica gel. Figure A new bis-tetrathiafulvalene calix[2]thiophene[2]pyrrole derivative has been prepared that gives rise to an easy-to-visualize color change in the presence of the model nitroaromatic explosives trinitrobenzene and picric acid. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.

Stacking interactions and the twist of DNA

The importance of stacking interactions for the Twist and stability of DNA is investigated using the fully ab initio van der Waals density functional (vdW-DF). Our results highlight the role that binary interactions between adjacent sets of base pairs play in defining the sequence-dependent Twists observed in high-resolution experiments. Furthermore, they demonstrate that additional stability gained by the presence of thymine is due to methyl interactions with neighboring bases, thus adding to our understanding of the mechanisms that contribute to the relative stability of DNA and RNA. Our mapping of the energy required to twist each of the 10 unique base pair steps should provide valuable information for future studies of nucleic acid stability and dynamics. The method introduced will enable the nonempirical theoretical study of significantly larger pieces of DNA or DNA/amino acid complexes than previously possible.     

Adsorption of thymine and uracil on 1:1 clay mineral surfaces: comprehensive ab initio study on influence of sodium cation and water

This computational study performed using the density functional theory shows that hydrated and non-hydrated tetrahedral and octahedral kaolinite mineral surfaces in the presence of a cation adsorb the nucleic acid bases thymine and uracil well. Differences in the structure and chemistry of specific clay mineral surfaces led to a variety of DNA bases adsorption mechanisms. The energetically most predisposed positions for an adsorbate molecule on the mineral surface were revealed. The target molecule binding with the surface can be characterized as physisorption, which occurs mainly due to a cation-molecular oxygen interaction, with hydrogen bonds providing an additional stabilization. The adsorption strength is proportional to the number of intermolecular interactions formed between the target molecule and the surface. From the Atoms in Molecules analysis and comparison of binding energy values of studied systems it is concluded that the sorption activity of kaolinite minerals for thymine and uracil depends on various factors, among which are the structure and accessibility of the organic compounds. The adsorption is governed mostly by the surface type, its properties and presence of cation, which cause a selective binding of the nucleobase. Adsorbate stabilization on the mineral surface increases only slightly with explicit addition of water. Comparison of activity of different studied kaolinite mineral models reveals the following order for stabilization: octahedral-Na-water > octahedral-Na > tetrahedral-Na > tetrahedral-Na-water. Further investigation of the electrostatic potentials helps understanding of the adsorption process and confirmation of the active sites on the kaolinite mineral surfaces. Based on the conclusions that clay mineral affinity for DNA and RNA bases can vary due to different structural and chemical properties of the surface, a hypothesis on possible role of clays in the origin of life was made.     

Toward an Understanding of the Chemical Etiology for DNA Minor‐Groove Recognition by Polyamides

Crescent‐shaped polyamides composed of aromatic amino acids, i.e., 1‐methyl‐1H‐imidazole Im , 1‐methyl‐1H‐pyrrole Py , and 3‐hydroxy‐1H‐pyrrole Hp , bind in the minor groove of DNA as 2 : 1 and 1 : 1 ligand/DNA complexes. DNA‐Sequence specificity can be attributed to shape‐selective recognition and the unique corners or pairs of corners presented by each heterocycle(s) to the edges of the base pairs on the floor of the minor groove. Here we examine the relationship between heterocycle structure and DNA‐sequence specificity for a family of five‐membered aromatic amino acids. By means of quantitative DNase‐I footprinting, the recognition behavior of polyamides containing eight different aromatic amino acids, i.e., 1‐methyl‐1H‐pyrazole Pz , 1H‐pyrrole Nh , 5‐methylthiazole Nt , 4‐methylthiazole Th , 3‐methylthiophene Tn , thiophene Tp , 3‐hydroxythiophene Ht , and furan Fr , were compared with the polyamides containing the parent‐ring amino acids Py, Im , and Hp for their ability to discriminate between the four Watson? Crick base pairs in the DNA minor groove. Analysis of the data and molecular modeling showed that the geometry inherent to each heterocycle plays a significant role in the ability of polyamides to differentiate between DNA sequences. Binding appears sensitive to changes in curvature complementarity between the polyamide and DNA. The Tn / Py pair affords a modest 3‐fold discrimination of T?A vs. A?T and suggests that an S‐atom in the thiophene ring prefers to lie opposite T not A.     

LASER CROSS-LINKING OF PROTEINS TO NUCLEIC ACIDS: PHOTODEGRADATION AND ALTERNATIVE PHOTOPRODUCTS OF THE BACTERIOPHAGE T4 GENE 32 PROTEIN

Pulsed laser cross-linking provides a means of introducing a covalent bond between proteins and the nucleic acids to which they are bound. This rapid cross-linking effectively traps the equilibrium that exists at the moment of irradiation and thus allows examination of the protein-nucleic acid interactions that existed. Laser irradiation may also induce photodestruction of protein and we have used the bacteriophage T4 gene 32 protein to investigate this phenomenon. Our results show that both nonspecific and specific photoproducts can occur, specifically at wavelengths where the peptide backbone of proteins is known to absorb. These results demonstrate that nonspecific photodegradation can be correlated with the formation of a specific photodegradation product. The formation of this product was monitored to show that product yield is nonlinearly dependent on laser power and wavelength. We have also investigated an unexpected photoproduct whose formation is dependent on the length of the polynucleotide to which the gene 32 protein binds and that further demonstrates the complexities of analyzing protein-nucleic acid interactions through the use of UV laser cross-linking. These data provide essential information for the establishment of appropriate conditions for future studies that use UV cross-linking of protein-nucleic acid complexes.     

How well can new-generation density functional methods describe stacking interactions in biological systems?

We compare the performance of four recently developed DFT methods (MPW1B95, MPWB1K, PW6B95, and PWB6K) and two previous, generally successful DFT methods (B3LYP and B97-1) for the calculation of stacking interactions in six nucleic acid bases complexes and five amino acid pairs and for the calculation of hydrogen bonding interactions in two Watson-Crick type base pairs. We found that the four newly developed DFT methods give reasonable results for the stacking interactions in the DNA base pairs and amino acid pairs, whereas the previous DFT methods fail to describe interactions in these stacked complexes. We conclude that the new generation of DFT methods have greatly improved performance for stacking interaction as compared to previously available methods. We recommend the PWB6K method for investigating large DNA or protein systems where stacking plays an important role.     

Identifying nonspecific ligand binding in electrospray ionization mass spectrometry using the reporter molecule method

The application of the reporter molecule (M_rep) method for identifying nonspecific complexes in the ES-MS analysis of protein-ligand and DNA-ligand interactions in vitro is described. To test the reliability of the method, it was applied to the ES-MS analysis of protein-carbohydrate complexes originating from specific interactions in solution and from nonspecific interactions in the ES process. These control experiments confirm the basic assumptions underlying the M_rep method, namely that nonspecific ligand binding is a random process, and that the ES droplet histories for specific and nonspecific complexes are distinct. The application of the M_rep method to the ES-MS analysis of the sequential binding of the ethidium cation, a DNA intercalator, to single and double strand oligodeoxynucleotides is also described, and highlights the general utility of the method.