X-ray crystallographic studies of nucleic acids and nucleic acid-drug complexes

Induction into viable but non culturable state and outgrowth heterogeneity of Listeria monocytogenes is affected by stress history and type of growth

Exposure to sublethal stresses related to food-processing may induce a heterogenous mixture of cells that co-exist, comprising healthy, sublethally injured, dormant and dead cells. Heterogeneity in survival capacity and dormancy of single cells may impede the detection of foodborne pathogens. In this study, we exposed Listeria monocytogenes Scott A strain, to peracetic acid (PAA; 20-40 ppm) and to acidic conditions (hydrochloric (HCl) and acetic (AA) acid, adjusted to pH 2.7-3.0, to evaluate the resuscitation capacity and outgrowth kinetics of metabolically active cells in two different media. Injury and the viable-but-non-culturable (VBNC) status of cells were assessed by flow cytometry using CFDA (metabolically active) and PI (dead) staining. Stressed CFDA+PI- cells were sorted on Tryptic Soy (TS) Agar or in TS broth, both supplemented with 0.6 % Yeast Extract (TSAYE or TSBYE), to evaluate culturability. Resuscitation capacity of CFDA+PI-sorted cells (10 events/well) was monitored by visual inspection on TSAYE and by optical density measurement in TSBYE for 5 days. Sorting of L. monocytogenes viable cells (CFDA+PI-) in Ringer's solution on TSAYE and TSBYE showed 100 % recovery in both media (control condition), while the mean lag time in TSBYE was 9.6 h. Treatment with 20 ppm PAA for 90 and 180 min resulted in 74.79 % and 85.82 % of non-culturable cells in TSBYE and increased the average lag time to 41.7 h and 43.8 h, respectively, compared to the control (9.6 h). The longest average lag time (79.5 h) was detected after treatment with 30 ppm PAA for 90 min, while at the same condition sorting of CFDA+PI- cells resulted in 95.05 % and 93.94 % non-culturable cells on TSAYE and TSBYE, respectively. The highest percentage of wells with non-culturable cells (96.17 %) was detected on TSAYE after treatment with 40 ppm PAA for 30 min. Fractions of VBNC cells were detected in TSBYE after treatment with HCl pH 3.0 for 60 and 240 min, and in TSAYE and TSBYE after exposure to AA pH 2.7. Treatment with AA pH 2.7 for 150-300 min increased the range of recorded lag time values compared to 60 min, from 8.6 h up to 13.3 h, as well as the mean lag times in TSBYE. Modelling of the outgrowth kinetics comparing the two types of stress (oxidative vs acid) and the two systems of growth (colonial vs planktonic) revealed that low starting concentrations hindered the detection of viable L. monocytogenes cells, either due to VBNC induction or cell heterogeneity.

DNA staining with the fluorochromes EtBr, DAPI and YOYO-1 in the comet assay with tobacco plants after treatment with ethyl methanesulphonate, hyperthermia and DNase-I

We applied the alkaline version of the single-cell gel electrophoresis (comet) assay to roots and leaves of tobacco (Nicotiana tabacum var. xanthi) seedlings or isolated leaf nuclei treated with: (1) the alkylating agent ethyl methanesulphonate, (2) necrotic heat treatments at 50 degrees C, and (3) DNase-I. All three treatments induced a dose-dependent increase in DNA migration, expressed as percentage of tail DNA. A comparison of the fluorochrome DNA dyes ethidium bromide, DAPI and YOYO-1 demonstrated that for the alkaline version of the comet assay in plants, the commonly used fluorescent dye ethidium bromide can be used with the same efficiency as DAPI or YOYO-1.

Structural basis for the binding affinity of xanthines with the DNA intercalator acridine orange

Caffeine (CAF), a methyl-substituted xanthine, interacts with polyaromatic DNA intercalators and has been hypothesized to interfere with their intercalation into DNA. Optical absorption spectroscopy was used to determine the binding affinities (K(assoc)) and structural effects of a series of methyl-substituted xanthines and a series of methyl-substituted uric acids (8-oxoxanthine) with the known DNA intercalator acridine orange (AO). There is evidence that complexation occurred (K(assoc) > or = 150 M(-1); binding curve saturation approximately > or =50%) between AO and 1,7-dimethylxanthine (155 M(-1)), 1,3-dimethylxanthine (theophylline, 157 M(-1)), 1,3,7-trimethylxanthine (CAF, 256 M(-1)), 1,3-dimethyl-8-chloroxanthine (413 M(-1)), 1,3,7,9-tetramethyl-8-oxyxanthine (tetramethyl uric acid or TMU, 552 M(-1)), and theophylline ethylenediamine (aminophylline, 596 M(-1)). No definitive evidence of complexation occurred between AO and 16 other substituted xanthines or purines, although there was some evidence of weak complexation (K(assoc) < 150 M(-1)) between AO and eight of the sixteen. Three common structural similarities were identified among those compounds found to form significant bonding with AO: (i) the N(1) or N(3) on the xanthine structure must be substituted with a methyl group; (ii) oxygen or chlorine substitution at C(8) increases binding affinity to AO when resonate states remain unchanged; and (iii) K(assoc) increases with an increase in number of methyl group substitutions on the 1- or 3-methylxanthine core structure. These results are explained on the basis of complex stabilization due predominately to hydrophobic attraction, with a contribution from charge transfer between donor and acceptor components. This information can be used in the manipulation of the physical or chemical characteristics of biologically active polyaromatic molecules.

Structure of Poly (U).poly (A).poly (U)

The molecular structure of poly (U).poly (A).poly (U) has been determined and refined using the continuous x-ray intensity data on layer lines in the diffraction pattern obtained from an oriented fiber of the RNA. The final R-value for the preferred structure is 0.24, far lower than that for the plausible alternatives. The polymer forms an 11-fold right-handed triple-helix of pitch 33.5A and each base triplet is stabilized by Crick-Watson-Hoogsteen hydrogen bonds. The ribose rings in the three strands have C3'-endo, C2'-endo and C2'-endo conformations, respectively. The helix derives additional stability through systematic interchain hydrogen bonds involving ribose hydroxyls and uracil bases. The relatively grooveless cylindrical shape of the triple-helix is consistent with the lack of lateral organization.

Structure of poly (I).poly (A).poly (I)

The molecular structure of poly (I).poly (A).poly (I) has been determined and refined using the continuous intensity data on layer lines in the x-ray diffraction pattern obtained from an oriented fiber of this polymorphic RNA complex. The polymer forms a 12-fold right-handed triple-helix of pitch 39.7A and each base-triplet is stabilized by quasi Crick-Watson-Hoogsteen hydrogen bonds. The ribose rings in all the three strands have C3'-endo conformations. The final R-value for this best structure is 0.24 and the x-ray fit is significantly superior to all the alternative structures where the different chains might have different furanose conformations. This all-purine triple-helix, counter-intuitively, has a diameter roughly 3A shorter than that of DNA and RNA triple-helices containing a homopurine and two complementary homopyrimidine strands. Its compact, grooveless cylindrical shape is consistent with the lack of lateral organization.

DNA-binding peptides searched from the solid-phase combinatorial library with the use of the magnetic beads attaching the target duplex DNA

We have exhibited successful and rapid screening of DNA-binding peptide ligands from solid-phase library beads with the use of the target DNA-conjugated magnetic beads. The target duplex DNA (3) has a polyether linker between two complementary sequences (T4A3G-ether linker-CT3A4) and is stable in the duplex form during the selection procedure. Finally, 71 pentapeptide sequences were identified from the solid-phase pentapeptide library. From an analysis of the peptide sequences identified in this study, it has been revealed that peptide ligands contain hydrophobic amino acids as the major component. The synthetic peptides with identified sequences and a combination of the major components have exhibited moderate to high binding affinity to the duplex DNA in competition experiments with ethidium-DNA complexes.

Direct visualization of individual DNA molecules by fluorescence microscopy: characterization of the factors affecting signal/background and optimization of imaging conditions using YOYO

A new series of high-affinity cyanine dyes was tested for the visualization of the dynamics of single DNA molecules through a fluorescence microscope. In particular, YOYO-1 (1,1'-(4,4,7,7-tetramethyl-4,7-diazaundecamethylene)- bis-4-[3-methyl-2,3-dihydro-(benzo-1,3-oxazole)- 2-methylidene]-quinolinium tetraiodide) forms a very stable, highly fluorescent complex with double-stranded DNA and dramatically improves the quality of the images. We have characterized the factors affecting the signal/background in the imaging of single DNA molecules by fluorescence microscopy and compared the results obtained using YOYO-1 with those obtained using standard fluorescent dyes like ethidium bromide or acridine orange.

Stereochemistry of 2'-5' linked nucleic acids: crystal and molecular structure of ammonium adenylyl-2',5'-adenosine tetrahydrate: a core fragment of 2'-5' oligo A's produced by interferon induced adenylate synthetase

The preponderance of 3'-5' phosphodiester links in nucleic acids is well known. Albeit less prevalent, the 2'-5' links are specifically utilised in the formation of 'lariat' in group II introns and in the msDNA-RNA junction in myxobacterium. As a sequel to our earlier study on cytidylyl-2',5'-adenosine we have now obtained the crystal structure of adenylyl-2',5'-adenosine (A2'p5'A) at atomic resolution. This dinucleoside monophosphate crystallizes in the orthorhombic space group P2(1)2(1)2(1) with a = 7.956(3) A, b = 12.212(3) A and c = 36.654(3) A. CuK alpha intensity data were collected on a diffractometer. The structure was sloved by direct methods and refined by full matrix least squares methods to R = 10.8%. The 2' terminal adenine is in the commonly observed anti (chi 2 = 161 degrees) conformation and the 5' terminal base has a syn (chi 1 = 55 degrees) conformation more often seen in purine nucleotides. A noteworthy feature of A2'p5'A is the intranucleotide hydrogen bond between N3 and O5' atoms of the 5' adenine base. The two furanose rings in A2'p5'A show different conformations - C2' endo, C3' endo puckering for the 5' and 2' ends respectively. In this structure too there is a stacking of the purine base on the ribose O4' just as in other 2'-5' dinucleoside structures, a feature characteristically seen in the left handed Z DNA. In having syn, anti conformation about the glycosyl bonds, C2' endo, C3' endo mixed sugar puckering and N3-O5' intramolecular hydrogen bond A2'p5'A resembles its 3'-5' analogue and several other 2'-5' dinucleoside monophosphate structures solved so far. Striking similarities between the 2'-5' dinucleoside monophosphate structures suggest that the conformation of the 5'-end nucleoside dictates the conformation of the 2' end nucleoside. Also, the 2'-5' dimers do not favour formation of miniature classical double helical structures like the 3'-5' dimers. It is conceivable, 2-5(A) could be using the stereochemical features of A2'p5'A which accounts for its higher activity.

The flexibility of A-form DNA

We have determined the rise per base pair and persistence length of A-form DNA in trifluoroethanol solutions for fragments 350-900 base pairs in length that best describe rotational diffusion coefficients determined by transient electric birefringence. The 2.6 A spacing between base pairs found in crystal and fiber A-form structures is preserved in solution. The persistence length is about 1500 A, or about three times longer than for B-form DNA. There is no apparent electrostatic contribution to the persistence length in the salt concentration range 0.2-2.0 mM Na cacodylate. This suggests an even closer association between DNA and its neutralizing counterions than predicted by condensation theory, perhaps due to a sheath of trifluoroethanol excluded water surrounding the A-form helix.

Intercalative binding of ditercalinium to d(CpGpCpG)2: a theoretical study

The structure of the complex formed between ditercalinium, 2,2'-[4,4'-bipiperidine-1,1'-bis-(ethane-1,2-diyl)]bis(10-me thoxy-7H- pyrido[4,3-c]carbazolium) tetramethane sulfonate (NSC 366241), and the self-complementary tetranucleotide duplex d(CpGpCpG)2 has been investigated by means of a novel theoretical approach for modelling the conformational flexibility of nucleic acids. The methodology used is the JUMNA procedure, a molecular mechanics systematics capable of evaluating the internal energy and the interaction energy of a complex formed from a large number of fragments. In the best energy-minimized structures, the piperidinium chains of ditercalinium are located in the major groove of the right-handed oligonucleotide. Calculations show a distortion of the base-paired d(CpGpCpG)2 minihelix consisting of lateral dislocation of one base pair with respect to another along an axis parallel to the long axis; strong propeller twist and tilt of the end base pairs; a collective motion of all base pairs with respect to the helical axis towards the drug; and an overwinding at the exclusion site. The proposed structure of the complex is in good agreement with reported proton NMR data, supporting the feasibility of such model.

Linear dichroism and polarized fluorescence of dye-complexed DNA fibers

A simple method to obtain well orientated DNA fibers for studying the ordered binding of dyes and fluorochromes by linear dichroism and polarized fluorescence is described. The metachromatic dye toluidine blue and the intercalating fluorochromes ethidium bromide and acridine orange showed a perpendicular alignement to DNA; the minor groove binding fluorochromes 33258 Hoechst and DAPI appeared parallel. Thus, DNA fibers represent a suitable cytochemical test substrate for studying the orientation of bound dyes by polarization methods.

Monomerizing effect of caffeine, o-phenanthroline, and tannin on cationic dyes: a model system to analyze spectral characteristics of the intercalative binding to nucleic acids

If used as co-solutes in concentrated solutions of cationic planar dyes, caffeine, o-phenanthroline, and tannin induce striking hyperchromic and bathochromic shifts in their absorption spectra. Likewise, the fluorescence of acridine orange at high concentration greatly increases in the presence of caffeine, the emission peak appearing at a shorter wave-length. These spectral changes, which are similar to those produced by organic solvents, detergents, and alpha-cyclodextrin, reflect the disaggregating (monomerizing) capacity of the co-solutes on stacked chromophores. After washing with saturated solutions of caffeine or o-phenanthroline, the chromatin fluorescence by intercalating fluorochromes is reduced or abolished, which suggests competition effects for intercalative binding modes. These results support the use of caffeine, o-phenanthroline, and tannin in spectroscopic and histochemical studies of dye-stuff interactions with DNA and chromatin.

NMR studies of tris-intercalation: solution structure and interaction of d(CTTCGCGCGAAG) with an acridine trimer

Tris-intercalation of an acridine trimer into the self-complementary dodecanucleotide d(CTTCGCGCGAAG) has been studied, in solution, by means of 1H and 31P nuclear magnetic resonance. In a first step all the non-exchangeable protons (except H5', H5"), the imino protons and seven of the eleven phosphorus have been assigned. The dodecanucleotide is shown to adopt a double helical B-type structure. Most of the sugar puckers are in the O1'endo range, those of the internal guanosines being closer to C2'endo. Deviations from the canonical B structure are observed in the base stacking and the phosphodiester torsional angles at the 3T4C5G stretch. The addition of an acridine trimer to the base-paired dodecanucleotide leads to the conclusion that the trimer, which is in slow exchange at the NMR time scale, tris-intercalates into the three C(3'-5')G sites of the central core, according to the excluded site model. This is evidenced by the large (1.4 ppm) upfield shift experienced by the imino protons of the three internal guanines and the shielding undergone by the acridine ring protons. Tris-intercalation is also supported by the downfield shift experienced by 6 out of the 22 phosphorus. Two of them are shifted by nearly 2 ppm, a shift range reported for oligonucleotides complexed to actinomycin D; this suggests that the structure of the backbone of the dodecanucleotide is altered.

UV photoelectron spectroscopy and ab initio characterization of valence orbital structures and conformations of neutral phosphate esters

The HeI UV photoelectron spectrum of trimethyl phosphate (TMP) has been measured and interpreted with the aid of SCF molecular orbital calculations carried out with STO-3G, STO-3G* and 4-31G basis functions. The photoelectron spectrum of TMP is more accurately reproduced by results from 4-31G calculations than by results from STO-3G or STO-3G* calculations. However, all three basis sets yield results which predict the same assignment of the photoelectron spectrum. Results at the 4-31G level indicate that whether calculations are based on crystallographic bond angles and bond lengths or on STO-3G optimized geometries has little effect on the energetic ordering of the upper occupied orbitals. The energetic ordering of orbitals is also found to be only weakly dependent upon the torsional angle phi, describing rotation of ester groups about P-O bonds and upon the torsional angle psi, describing rotation of methyl groups about C-O bonds. For trimethyl phosphate, with C3 symmetry, the vertical ionization potentials of the upper occupied orbitals are 10.81 eV (8e), 11.4 eV (9a), 11.93 eV (7e), 12.6-12.9 eV (8a and 6e), 14.4 eV (7a) and 15.0-16.0 eV (5e and 6a). Calculations at the 4-31G level indicate that many of the highest occupied orbitals in neutral dimethyl phosphate and methyl phosphate have energies and electron distributions similar to orbitals in TMP. For TMP, a search for optimized values of phi and psi has been carried out at the STO-3G*level. In agreement with previous NMR studies and with classical potential calculations, the STO-3G* results indicate that both the gauche (phi = 53.1 degrees) and anticlinal (phi = 141.9 degrees) conformations are thermally accessible. Also in agreement with the classical potential calculations, the STO-3G* results predict that in the all gauche conformation energy is minimized when the methyl groups assume a staggered geometry (psi = 60 degrees to 80 degrees) and that an energy maximum occurs for an eclipsed geometry (phi = 0 degrees to 20 degrees). A study of the dependence of optimized values of O-P-O ester bond angles on the torsional angles, phi, was carried out at the STO-3G, STO-3G* and 4-31G levels. The results demonstrate that for C3 symmetry, the coupling of O-P-O angles to phi is influence by repulsive steric interactions.

Nonintercalative binding of proflavin to Z-DNA: structure of a complex between d(5BrC-G-5BrC-G) and proflavin

The crystal structure of a disordered 1:1 complex between the tetradeoxyoligomer d(5BrC-G-5BrC-G) and proflavin has been determined and refined to an R factor of 26.9% for 474 reflections initially in space group P6(5) and to an R factor of 22.2% for 475 reflections in space group P2(1), both at 2-A resolution with Fobsd greater than or equal to 4.0. The unit cell constants are a = b = 17.9 A, c = 44.5 A, and gamma = 120 degrees. The final models are essentially the same in the two space groups with greater disorder in space group P6(5). In space group P2(1), the asymmetric unit is a tetranucleotide duplex, two sandwiched proflavin molecules, and four "outside-bound" proflavins. The tetranucleotide duplex is in the Z conformation and is located at the origin of the unit cell with a pair of proflavins sandwiched between the tetranucleotides. Thus, the tetranucleotides and proflavin dimers stack alternatively forming a quasi-continuous helix with the helix axis coincident with the c axis. The structure analysis revealed the presence of outside-bound proflavins as well. It is interesting that one type of outside-bound proflavins occupies a similar environment as the cobalt hexaammines in their complex with the decadeoxyoligomer d(CGTACGTACG) [Brennan, R. G., Westhof, E., & Sundaralingam, M. (1986) J. Biomol. Struct. Dyn. 3, 649]. Crystals of the latter are isomorphous to the present complex. The outside-bound proflavins penetrate the deep minor groove, thereby closing it off, and provide a visualization of a quasi-internal mode of binding of proflavin to a nucleic acid.

DNA structure and perturbation by drug binding

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Hydration of nucleic acid crystals

Can we make any generalizations from examination of the crystal structures in hand? The results of study of the very well-determined high-resolution structures indicate that the counterions have a very strong effect on organizing the water structure and that these counterions are bonded in a sequence-specific manner. Hence, the sodium ion bonds in the minor groove of ApU and only to the phosphate backbone in GpC. Not surprisingly then, the water network in ApU is predominantly in its minor groove. Similarly, the negative sulfate counterion in the major groove of the 3:2 complex between proflavine and CpG has a significant influence on the water structure in that crystal. The crystallization of two positive proflavine molecules with two negative nucleic acid chains obviates the need for inorganic ions and may provide additional insight about nucleic acid water structure. The presence of the charged aromatic hydrocarbon appears to provide the correct mixture of hydrophilicity and hydrophobicity that allows for both the gathering and ordering of water molecules around the nucleic acid molecule, not unlike what was previously observed in the semiclathrate structures. This same type of hydrophobic aggregation might pertain along the major groove side of structures containing the appropriate arrangement of methyl-containing thymine bases. Although it is very tempting at this point to make further rules and predictions, experience has shown that, especially in the case of nucleic acids, such prognostications would be premature. What is clearly needed are some more high-quality crystal structures of a variety of sequences under different and controlled conditions. Analyses of these may then put us in a position to successfully predict both the structure of water and its effects on nucleic acid conformation.

Proflavin binding to poly[d(A-T)] and poly[d(A-br5U)]: triplet state and temperature-jump kinetics

The delayed fluorescence properties of proflavin have been exploited in studies of the excited-state binding kinetics of the dye to poly[d(A-T)] and its brominated analogue poly[d(A-br5U)] at room temperature and pH 7. The two analyzed luminescence decay times of the DNA-dye complex are dependent on the total nucleic acid concentration. This dependence is shown to reflect a temporal coupling of the intrinsic delayed emission decay rates with the dynamic chemical kinetic binding processes in the excited state. Temperature-jump kinetic studies conducted on the brominated polymer and corresponding information on poly[d(A-T)] from a previous study [Ramstein, J., Ehrenberg, M., & Rigler, R. (1980) Biochemistry 19, 3938-3948] provide complementary information about the ground state. In the ground state, the poly[d(A-T)]-proflavin complex has one chemical relaxation time, which reaches a plateau at high DNA concentrations. The brominated DNA-dye complex exhibits two relaxation times: a faster relaxation mode that behaves similarly to that for the unhalogenated DNA and a slower relaxation mode that is apparent at high DNA concentrations. The ground-state kinetic data are analyzed in terms of two alternative models incorporating series and parallel reaction schemes. The former consists of two sequential binding steps--a fast bimolecular process followed by a monomolecular step--while the latter consists of two coupled bimolecular steps. A similar analysis for the excited-state data yields reasonable kinetic constants only for the series model, which, in accordance with previous proposals for acridine intercalators, consists of a fast outside binding step followed by intercalation of the dye. A comparison of the ground- and excited-state kinetic parameters reveals that the external binding process is much stronger and the intercalation is much weaker in the excited state. That the excited-state data are only consistent with the series model suggests that delayed luminescence studies may provide a general tool for distinguishing between the two kinetic mechanisms. In particular, we demonstrate the use of delayed luminescence spectroscopy as a tool for probing dynamic DNA-ligand interactions in solution.

The binding of 9-aminoacridine to calf thymus DNA in aqueous solution. Electronic spectral studies

Absorption, circular dichroism and steady-state fluorescence spectra were determined of 9-aminoacridine solutions in the presence of DNA at an ionic strength of 0.001 mol dm-3. Up to a dye/DNA phosphorus ratio of about 0.2 the results are fully consistent with the requirements and predictions of a binding model already shown to apply to the binding of other aminoacridines to DNA. The apparently anomalous spectroscopic behaviour of the 9-aminoacridine/DNA system compared with proflavine/DNA, for example, can be satisfactorily explained from a consideration of the magnitudes of exciton interactions between dyes bound to DNA.

Design of anticancer drugs using modeling techniques

Flexibility of intercalation site geometries within a B-DNA helix was investigated in the twist-shift plane using energy minimization methods. The parameters optimized included sugar conformation, the glycosidic angles and phosphodiester torsion angles. Our calculations show several regions of energetically favorable intercalation geometries in the twist-shift plane. Modeling studies using interactive computer graphics and electrostatic potential surface compatibility provided initial hypotheses for the structures of the drug-DNA complexes. These hypotheses were supported and extended by energy minimizations of these complexes. Binding positions, conformational features and relative minimum binding energies of two anticancer drugs, mitoxantrone and bisantrene, were computed for intercalation complexes with DNA in the theoretically defined intercalation sites. Mitoxantrone intercalates DNA from the minor groove and the side chain OH or NH groups are involved in hydrogen bonds with the main chain phosphate groups of DNA, thereby cross-linking the complementary strands. The hydroxyl groups of mitoxantrone can also participate in hydrogen bonding with phosphate oxygens of another chain, thereby cross-linking DNA helices. Bisantrene intercalates DNA favorably from the major groove and the NH group of the dihydroimidazole ring can participate in hydrogen bonding with the phosphate oxygens of the backbone. These models are consistent with the physicochemical and electron microscopic studies of the interaction of mitoxantrone and bisantrene with DNA. Our results are now being used to guide the design of novel anticancer drugs that should interact with DNA in a manner similar to that proposed for our representative drugs.

Aqueous hydration of nucleic acid constituents: Monte Carlo computer simulation studies

Monte Carlo computer simulations were performed on dilute aqueous solutions of thymine, cytosine, uracil, adenine, guanine, the dimethyl phosphate anion in the gauche-gauche conformation and a ribose and deoxyribose derivative. The aqueous hydration of each molecule was analysed in terms of quasi-component distribution functions based on the Proximity Criterion, and partitioned into hydrophobic, hydrophilic and ionic contributions. Color stereo views of selected hydration complexes are also presented. A preliminary discussion of the transferability of functional group coordination numbers is given. The results enable to comment on two current problems related to the hydration of nucleic acids: a) the theory of Dickerson and coworkers on the role of water in the relative stability of the A and B form of DNA and b) the idea of water bridges and filaments emerging from the computer simulation results on the hydration of DNA fragments by Clementi.

Deoxyguanosine-deoxyadenosine pairing in the d(C-G-A-G-A-A-T-T-C-G-C-G) duplex: conformation and dynamics at and adjacent to the dG X dA mismatch site

Nuclear magnetic resonance (NMR) has been used to monitor the conformation and dynamics of the d-(C1-G2-A3-G4-A5-A6-T6-T5-C4-G3-C2-G1) self-complementary dodecanucleotide (henceforth called 12-mer GA) that contains a dG X dA purine-purine mismatch at position 3 in the sequence. These results are compared with the corresponding d(C-G-C-G-A-A-T-T-C-G-C-G) dodecamer duplex (henceforth called 12-mer) containing standard Watson-Crick base pairs at position 3 [Patel, D.J., Kozlowski, S.A., Marky, L.A., Broka, C., Rice, J.A., Itakura, K., & Breslauer, K.J. (1982) Biochemistry 21, 428-436]. The dG X dA interaction at position 3 was monitored at the guanosine exchangeable H-1 and nonexchangeable H-8 protons and the nonexchangeable adenosine H-2 proton. We demonstrate base-pair formation between anti orientations of the guanosine and adenosine rings on the basis of nuclear Overhauser effects (NOE) observed between the H-2 proton of adenosine 3 and the imino protons of guanosine 3 (intra base pair) and guanosines 2 and 4 (inter base pair). The dG(anti) X dA(anti) pairing should result in hydrogen-bond formation between the guanosine imino H-1 and carbonyl O-6 groups and the adenosine N-1 and NH2-6 groups, respectively. The base pairing on either side of the dG X dA pair remains intact at low temperature, but these dG X dC pairs at positions 2 and 4 are kinetically destabilized in the 12-mer GA compared to the 12-mer duplex. We have estimated the hydrogen exchange kinetics at positions 4-6 from saturation-recovery measurements on the imino protons of the 12-mer GA duplex between 5 and 40 degrees C. The measured activation energies for imino proton exchange in the 12-mer GA are larger by a factor of approximately 2 compared to the corresponding values in the 12-mer duplex. This implies that hydrogen exchange in the 12-mer GA duplex results from a cooperative transition involving exchange of several base pairs as was previously reported for the 12-mer containing a G X T wobble pair at position 3 [Pardi, A., Morden, K.M., Patel, D.J., & Tinoco, I., Jr. (1982) Biochemistry 21, 6567-6574]. We have assigned the nonexchangeable base protons by intra and inter base pair NOE experiments and monitored these assigned markers through the 12-mer GA duplex to strand transition.(ABSTRACT TRUNCATED AT 400 WORDS)

Structural and sequence-dependent aspects of drug intercalation into nucleic acids

Information gained from X-ray crystallographic studies on drug-nucleic acid complexes is described, with emphasis on the intercalation process. Relevant data from NMR experiments are examined in order to highlight similarities and differences between solution and solid-state structures. Theoretical analyses of intercalation complexes are also discussed and evaluated, with respect to the structural methods, with special reference being made to nucleic acid conformation and positions of drug molecules in the binding sites.