Stereochemical complementarity of progesterone, RU486 and cavities between base pairs in partially unwound double stranded DNA assessed by computer modeling and energy calculations

Computer modeling was used to examine the relative fit of progesterone and RU486 in cavities constructed between base pairs in double stranded DNA. Progesterone was capable of forming two stereospecific hydrogen bonds between the carbonyl groups and protonated phosphate groups on adjacent strands. Favorable van der Waals and electrostatic energies were exhibited upon insertion of progesterone into DNA indicating an excellent fit. While RU486 could be accommodated between the base pairs and formed hydrogen bonds, there was a high van der Waals energy in the resulting complex. When the complexes were subjected to energy minimization, the conformation of the DNA was significantly altered in the RU486-DNA complex but not in the progesterone-DNA complex. No mechanistic interpretation of these results is proffered; however, such information may have evolutionary significance and could prove useful in designing new progesterone agonists and antagonists.     

Recognition of base pairs by polar peptides in double stranded DNA.

The resonance Raman spectrum of native DNA has been obtained using excitation at 257 nm. In a first part, the spectral lines are assigned to the different nucleotide bases which provide the resonance effect. In a second part, the interactions of DNA with basic peptides (Arginine Methylester, Lysine Methylester, Arginyl-Arginine) are investigated using excitation at 300 nm and 257 nm, which give complementary information about the DNA. Both Arginine Methylester and Arginyl-arginine recognize the A-T base pairs, the first one in the large groove, the second one in the narrow groove of DNA. The DNA-Lysine Methylester interaction is very likely not specific but can take place in the large groove of DNA.     

Apparent stereochemical complementarity of estrogens and helical cavities between DNA base pairs: implications for the mechanism of action of steroids

The shape of the space occupied by a model of the estrogenic steroid hormone estradiol-17 beta conforms closely to a helical cavity between neighboring base pairs in partially coiled B-DNA. The orientation of estradiol-17 beta when fitted into DNA allows stereochemically complementary hydrogen bonding of both the 3- and 17 beta-hydroxyl groups to phosphate oxygens of the deoxyribose-phosphate backbone on adjacent strands. Changes in the chirality (handedness) of the steroid skeleton or in the absolute stereochemistry of hydrogen bonding groups prevent formation of complementary fits in the DNA. Synthetic estrogens can also adopt conformations which are stereochemically complementary to the cavities between base pairs. The complementary relationships between active estrogens and nucleic acids may be related to constraints on the evolution of the structure and the biological function of steroids.     

The conformation and stability of ribonucleic acids: modeling base sequence effects in double stranded helices

Base sequence effects within double stranded RNA oligomers of A and Z conformations have been studied by molecular modeling using a methodological approach specifically adapted to nucleic acids. Calculations on symmetric oligomers having homonucleotide or dinucleotide repeating base sequences show that sequence changes can produce modifications in overall conformation, influence the degree of internal hydrogen bonding and strongly affect stability.     

The length of a junction between the B and Z conformations in DNA is three base pairs or less

Recently it has been suggested that double-helical complexes formed between the DNA sequences (CG)n(A)m and their conjugates, (T)m(CG)n, would be candidates for the formation of a B-Z junction in aqueous solution at high salt concentrations [Peticolas et al. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 2579-2583]. The junction was predicted to occur between a B-type helix in the d(A)m.d(T)m section and a Z-type helix in the self-complementary (CG)n.(CG)n sequence. In this paper we report Raman experiments on the deoxyoligonucleotides d(CGCGCGCGCGCGAAAAA) and d(CGCGCGAAAAA) and their complements. It is found the latter compound cannot be induced into the Z form in saturated salt solution but that the former sequence goes into a B-Z junction at 5.5 M salt. From a comparison of the relative intensity of the Raman conformational marker bands for B and Z DNA for both the A-T and C-G base pairs, it is shown that in 5.5 M NaCl solution none of the A-T base pairs are in the Z form, but nine of the C-G base pairs are in the Z form. The remaining three C-G base pairs are either in the junction or in the B form. Thus, the junction is formed from three or less C-G base pairs. If the solution is made 95 microM with NiCl2, then the entire duplex goes into the Z form and the Raman bands of the adenine are completely changed into those of the Z form.(ABSTRACT TRUNCATED AT 250 WORDS)     

Energetic analysis of binding of progesterone and 5 beta-androstane-3,17-dione to anti-progesterone antibody DB3 using molecular dynamics and free energy calculations.

Molecular dynamics simulations and molecular mechanics-Poisson-Boltzmann surface area (MM-PBSA) free energy calculations were used to study the energetics of the binding of progesterone (PRG) and 5 beta-androstane-3,17-dione (5AD) to anti-PRG antibody DB3. Although the two steroids bind to DB3 in different orientations, their binding affinities are of the same magnitude, 1 nM for PRG and 8 nM for 5AD. The calculated relative binding free energy of the steroids, 8.8 kJ/mol, is in fair agreement with the experimental energy, 5.4 kJ/mol. In addition, computational alanine scanning was applied to study the role of selected amino acid residues of the ligand-binding site on the steroid cross-reactivity. The electrostatic and van der Waals components of the total binding free energies were found to favour more the binding of PRG, whereas solvation energies were more favourable for the binding of 5AD. The differences in the free energy components are due to the binding of the A rings of the steroids to different binding pockets: PRG is bound to a pocket in which electrostatic antibody-steroid interactions are dominating, whereas 5AD is bound to a pocket in which van der Waals and hydrophobic interactions dominate.     

Thermodynamic properties of the specific binding between Ag+ ions and C:C mismatched base pairs in duplex DNA

Metal-mediated base pairs formed by the interaction between metal ions and artificial bases in oligonucleotides have been developed for potential applications in nanotechnology. We recently found that a natural C:C mismatched base pair bound to an Ag(+) ion to generate a novel metal-mediated base pair in duplex DNA. Preparation of the novel C-Ag-C base pair involving natural bases is more convenient than that of metal-mediated base pairs involving artificial bases because time-consuming base synthesis is not required. Here, we examined the thermodynamic properties of the binding between the Ag(+) ion and each of single and double C:C mismatched base pair in duplex DNA by isothermal titration calorimetry. The Ag(+) ion specifically bound to the C:C mismatched base pair at a 1:1 molar ratio with 10(6) M(-1) binding constant, which was significantly larger than those for nonspecific metal ion-DNA interactions. The specific binding between the Ag(+) ion and the single C:C mismatched base pair was mainly driven by the positive dehydration entropy change and the negative binding enthalpy change. In the interaction between the Ag(+) ion and each of the consecutive and interrupted double C:C mismatched base pairs, stoichiometric binding at a 1:1 molar ratio was achieved in each step of the first and second Ag(+) binding. The binding affinity for the second Ag(+) binding was similar to that for the first Ag(+) binding. Stoichiometric binding without interference and negative cooperativity may be favorable for aligning multiple Ag(+) ions in duplex DNA for applications of the metal-mediated base pairs in nanotechnology.     

Zinc finger protein binding to DNA: an energy perspective using molecular dynamics simulation and free energy calculations on mutants of both zinc finger domains and their specific DNA bases

Energy calculations based on MM-GBSA were employed to study various zinc finger protein (ZF) motifs binding to DNA. Mutants of both the DNA bound to their specific amino acids were studied. Calculated energies gave evidence for a relationship between binding energy and affinity of ZF motifs to their sites on DNA. ΔG values were ?15.82(12), ?3.66(12), and ?12.14(11.6) kcal/mol for finger one, finger two, and finger three, respectively. The mutations in the DNA bases reduced the value of the negative energies of binding (maximum value for ΔΔG = 42Kcal/mol for F1 when GCG mutated to GGG, and ΔΔG = 22 kcal/mol for F2, the loss in total energy of binding originated in the loss in electrostatic energies upon mutation (r = .98). The mutations in key amino acids in the ZF motif in positions-1, 2, 3, and 6 showed reduced binding energies to DNA with correlation coefficients between total free energy and electrostatic was .99 and with Van der Waal was .93. Results agree with experimentally found selectivity which showed that Arginine in position-1 is specific to G, while Aspartic acid (D) in position 2 plays a complicated role in binding. There is a correlation between the MD calculated free energies of binding and those obtained experimentally for prepared ZF motifs bound to triplet bases in other reports (), our results may help in the design of ZF motifs based on the established recognition codes based on energies and contributing energies to the total energy.     

Voltammetric behaviour of DNA bases at a screen-printed carbon electrode and its application to a simple and rapid voltammetric method for the determination of oxidative damage in double stranded DNA

Screen-printed carbon electrodes (SPCEs) have been investigated as possible sensors to identify gamma-irradiation induced oxidative damage in double stranded (ds) DNA. Studies were undertaken to explore the possibility of using both cyclic voltammetry and differential pulse voltammetry to identify changes due to oxidative damage. Initially, guanine, adenine and 8-oxoguanosine were examined and it was found possible to differentiate them from their voltammetric responses. The voltammetric response of 8-oxoguanosine was found to be linear over the concentration range 1-400 microM, with a slope of 0.0296 microA microM(-1) (R2 value of 0.9984), in the presence of 2mM concentrations of guanine and adenine. Investigations were made into harnessing these findings to identify oxidative damage in gamma-irradiated dsDNA. The presence of oxidative damage in these samples was readily identifiable, and the magnitude of the voltammetric response was found to be dose dependant (R2=0.9919). A simple sample preparation step involving only the dissolution of double stranded DNA sample in the optimised electrolyte (0.1M acetate buffer pH 4.5) was required. This report appears to be first describing the use of a SPCE to detect DNA damage which can be related to the dose of gamma-radiation used.     

MitoAnalyzer, a computer program and interactive web site to determine the effects of single nucleotide polymorphisms and mutations in human mitochondrial DNA

MitoAnalyzer provides information about the effects of single nucleotide polymorphisms (SNPs) and mutations in human mitochondrial DNA (mtDNA). This program determines if a single base pair (bp) change is in the non-coding or coding region, in the first, second or third bp of the codon, in a rRNA, tRNA or a protein, causes an amino acid (aa) change, the nature of that change, the position of the aa change in the protein, and the new aa sequence of the changed protein. Mutations associated with published mitochondrial diseases are noted. This program, thus, facilitates rapid analysis and evaluation of SNPs and mutations in human mtDNA.     

Recognition of 5-methyl-CG and CG base pairs in duplex DNA with high stability using antiparallel-type triplex-forming oligonucleotides with 2-guanidinoethyl-2′-deoxynebularine

The formation of triplex DNA is a site-specific recognition method that directly targets duplex DNA. However, triplex DNA formation is generally formed for the GC and AT base pairs of duplex DNA, and there are no natural nucleotides that recognize the CG and TA base pairs, or even the 5-methyl-CG (^5mCG) base pair. Moreover, duplex DNA, including ^5mCG base pairs, epigenetically regulates gene expression in vivo, and thus targeting strategies are of biological importance. Therefore, the development of triplex-forming oligonucleotides (TFOs) with artificial nucleosides that selectively recognize these base pairs with high affinity is needed. We recently reported that 2′-deoxy-2-aminonebularine derivatives exhibited the ability to recognize ^5mCG and CG base pairs in triplex formation; however, this ability was dependent on sequences. Therefore, we designed and synthesized new nucleoside derivatives based on the 2′-deoxy-nebularine (dN) skeleton to shorten the linker length connecting to the hydrogen-bonding unit in formation of the antiparallel motif triplex. We successfully demonstrated that TFOs with 2-guanidinoethyl-2′-deoxynebularine (guanidino-dN) recognized ^5mCG and CG base pairs with very high affinity in all four DNA sequences with different adjacent nucleobases of guanidino-dN as well as in the promoter sequences of human genes containing ^5mCG base pairs with a high DNA methylation frequency.     

Competition between anaerobic covalent linkage of neocarzinostatin chromophore to deoxyribose in DNA and oxygen-dependent strand breakage and base release

Treatment of poly(dA-dT) X poly(dA-dT) with the nonprotein chromophore of neocarzinostatin in the presence of sulfhydryls resulted in both direct and alkali-dependent base release, indicative of DNA sugar oxidation. Covalent chromophore-DNA adducts were also formed. Under anaerobic conditions, base release was strongly inhibited; however, adduct formation was not inhibited and in some cases was markedly enhanced. In the presence of dithiothreitol, anoxia increased adduct formation by a factor of 2, and a particularly stable adduct species was formed, which was recovered from nuclease digests of the treated DNA as a highly fluorescent compound with structure chromophore-d(TpApT). Acid hydrolysis of chromophore-d(TpApT) released free adenine base and both 3'dTMP and 5'dTMP, leaving a compound that contained only chromophore and the deoxyadenosine sugar. These results conclusively confirm that the chromophore forms a covalent adduct with deoxyribose in DNA. Thus, even in the absence of oxygen, activation of the chromophore by sulfhydryls results in the formation of a species capable of reacting with deoxyribose. Several other adduct species were also formed, some of which were nonfluorescent and relatively hydrophilic, but all of which were produced in increased amounts under anoxia. This inverse relation between sugar oxidation and adduct formation suggests that the two lesions share a common precursor. In the presence of other thiols, the effects of anoxia were somewhat different. With glutathione, anoxia markedly enhanced adduct formation, but the total adduct formed was considerably less than with dithiothreitol. With 2-mercaptoethanol, anoxia had no effect on total adduct formation, but the distribution of adduct species was altered.(ABSTRACT TRUNCATED AT 250 WORDS)     

Charge calculations in molecular mechanics 6: the calculation of partial atomic charges in nucleic acid bases and the electrostatic contribution to DNA base pairing.

A previously described scheme for the direct calculation of the partial atomic charges in molecules (CHARGE2) is applied to the nucleic acid bases. It is shown that inclusion of the omega-technique for the calculation of HMO derived pi charges is of particular importance for these highly polar systems. The molecular dipole moments obtained for the resulting charges are in very good agreement with the observed values for a variety of substituted purine and pyrimidine bases. The partial atomic charges for cytosine, thymine, guanine and adenine (as the 1-methyl and 9-methyl forms) are given and compared with values calculated by a variety of molecular orbital and empirical schemes. All the schemes reproduce the same general trends, with the possible exception of those calculated by the Del Re method, though the charges given by Kollman are in general somewhat larger than the others. The electrostatic contribution to the Watson-Crick base pair interaction energies are calculated using these partial atomic charges. The electrostatic contributions obtained from the M.O. derived atomic charges are less than half the observed values, as are those obtained by the Gasteiger method. The electrostatic contributions calculated from the CHARGE2 atomic charges and those of Kollman are in reasonable agreement with the observed values. The influence of a distant-dependent dielectric constant is examined, but no clear pattern emerges.     

A method for determining the relative effect of ligands on A-T and G-C base pairs in DNA: applications to metal ions, protons and two amino acids.

A new method is described for the study of specific interactions of low-molecular ligands with the base pairs of DNA. This method is based on the comparative analysis of melting temperature changes in DNAs of different GC-content in the presence of low molecular weight ligands. In this paper, the method is applied to Mn2+, Ni2+, Co2+ ions, deprotonation, amino acids, beta-alanine and gamma-aminobutyric acid (gamma-ABA). Differences in Tm are affected not only by the changes of relative stability of AT- and GC-pairs, but also by other factors. A theoretical analysis of the sequence specificity of low-molecular ligands on the base pairs in DNA molecules characterized by a high degree of sequence heterogeneity is also presented.     

Measurement of degree of chlorophyll fluorescence polarization in relation to the regulation of excitation energy transfer between Photosystems I and II in pea chloroplasts

The degree of chlorophyll fluorescence polarization (p) at 740 nm was measured at room temperature for pea chloroplasts subjected to various conditions. (1) In agreement with previous published observations, p decreased when the Photosystem (PS) II traps were closed by illumination in the presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea. (2) Under these conditions, the magnitude of p was also sensitive to the presence of salts. Under conditions when ‘spillover’ of the excitation energy from PS II to PS I was low, p was also low, being consistent with increased migration of energy between the PS II light-harvesting chlorophylls. In contrast, when spillover was at a maximum p increased. (3) The change in p in the presence of salts was dependent on the concentration and valency of the cations in such a way as to suggest the changes were mediated through electrostatic forces. The dependency of p on ionic composition of the experimental medium was closely related to the associated changes in fluorescence yield. (4) Membrane stacking, caused by lowering pH of the chloroplast suspension, did not induce a significant change in p, suggesting that this pH-induced process is different from the membrane stacking brought about by manipulating the salt levels. (5) Incubation of thylakoids with ATP induces light-dependent phosphorylation of the light-harvesting chlorophyll-protein complexes, and regulates excitation energy transfer between PS I and PS II (Bennett, J., Steinback, K.R. and Arntzen, C.J. (1980) Proc. Natl. Acad. Sci. U.S.A. 77, 5253–5257). Under conditions which bring about this phosphorylation it was found that p increased to a value indicative of spillover.     

Chiral recognition in the binding of helicenediamine to double strand DNA: interactions between low molecular weight helical compounds and a helical polymer

Binding of a helicene, 5,8-bis(aminomethyl)-1,12-dimethylbenzo[c]phenanthrene, to calf thymus DNA was studied using UV, CD, and fluorescence spectroscopy as well as calorimetry. The enantiomeric helicenes strongly bound to the double strand DNA possessing the right-handed helical structure. In addition, chiral recognition was observed in the binding, where the (P)-helicene with the right-handed helicity formed more stable complex than the (M)-helicene with the left-handed helicity. The binding studies of the helicenes and natural nucleosides by 1H NMR spectroscopy also revealed the higher affinity to the (P)-helicene. Both monomeric and polymeric nucleic acids thus turned out to favor the (P)-helicity.