Proton magnetic resonance studies of double helical oligonucleotides. The effect of base sequence on the stability of deoxydinucleotide dimers.

The concentration dependence of the proton magnetic resonance chemical shifts of a series of deoxydinucleotides and deoxydinucleoside monophosphates in neutral H2O solution has been recorded in the 1-100 mM concentration range by the use of pulsed Fourier transform techniques. The self-complementary molecules pdG-dC, dG-dC, pdC-dG, and dC-dG and the complementary mixtures pdG-dG + pdC-dC as well as pdG-dT + pdA-dC interact at low temperatures by the formation of intermolecular hydrogen bonded dimers. Noncomplementary molecules such as pdG-dT, pdT-dG, pdG-dG, pdA-dc, and pdC-dC do not self-associate by the formation of intermolecular hydrogen bonds under the present experimental conditions. The chemical shifts of the amino protons and the base protons are consistent with the interaction of two complementary dinucleotides to form a miniature double helix. An analysis of the chemical shift of the guanine amino proton resonance as a function of dinucleotide concentration has provided approximate dimerization constants. These results show that the stability of the miniature double helices is in the order (pdG-dG)-(pdC-dC) greater than or approximately (pdG-dC)-(pdG-dC) greater than (pdC-dG)-(pdC-dG) greater than (pdG-dT)-(pdA-dC) which reflects the effect of nucleotide sequence (and composition) on helix stability.     

Ethidium bromide-dinucleotide complexes. Evidence for intercalation and sequence preferences in binding to double-stranded nucleic acids.

The solution complexes of ethidium bromide with nine different deoxydinucleotides and the four self-complementary ribodinucleoside monophosphates as well as mixtures of complementary and noncomplementary deoxydinucleotides were studied as models for the binding of the drug to DNA and RNA. Ethidium bromide forms the strongest complexes with pdC-dG and CpG and shows a definite preference for interaction with pyrimidine–purine sequence isomers. Cooperativity is observed in the binding curves of the self-complementary deoxydinucleotides pdC-dG and pdG-dC as well as the ribodinucleoside monophosphates CpG and GpC, indicating the formation of a minihelix around ethidium bromide. The role of complementarity of the nucleotide bases was evident in the visible and circular dichroism spectra of mixtures of complementary and noncomplementary dinucleotides. Nuclear magnetic resonance measurements on an ethidium bromide complex with CpG provided evidence for the intercalation model for the binding of ethidium bromide to double-stranded nucleic acids. The results also suggest that ethidium bromide may bind to various sequences on DNA and RNA with significantly different binding constants.     

Resolution of electronic absorption bands and nucleotide binding processes in actinomycin D

Complexes of actinomycin D with model dexoxynucleoides have been studied by means of absorption spectroscopy and CD spectroscopy and CD spectroscopy. The CD spectra of the complexes of actinomycin D with 5′-dGMP, pdG-dT, pdT-dG, pdG-dA, and pdA-dG, respectively, all resemble one another. It is presumed that in solution the interactions between the guanine residues and actinomycin D in these complexes are the same as found in the crystalling 1:2 actinomycin D:dG complex [Jain, S. C. & Sobell, H. M. (1972) J. Mol. Biol. 68 , 1–20]. The CD spectrum of the Complexes with pdG-dC differs from of the complexes just mentioned, and resembles those of the complexes formed by actinomycin D with calf-thymus DNA and with poly(dG-dC)-poly(dG-dC). These resulls are consisent with, the nontion that pdG-dC froms a double-staranded intercalated complex with actinomycin D, and that the dG-dC sequence is an important binding site for actinomycin D in polydeoxynucleotides. Titrations of actinomycin D with monodeoxynucleotides were monitored at 380, 425, 440,465, and 480, nm in both absorption and CD modes. Comparisons fo saturation profiles at these wavelengths reveal that the curves obtained at various wavelenths do not superimpose with each other, so that they must reflect different titation processes. In complex formation wiht any given nucleotide, the apparent binding affinity monitored at these wavelengths decreases in the order given above. Based on these resulted and on features noted in the CD spectra of certain complexes, it is concluded that a minimum of theree electronic transitions underlie the visible absorption band of actinomycin D, extending earlier findigs. Comparing the titration proffiles obtained with dAMP and dIMP with the result for these systems in mmr titratins [Krugh, T. R. & Chen, Y. C. (1975) Biochemistry 14 , 4912–4922], it is concluded that one transition, centered at 370 nm, monitors preponderantly effects occurring at the 6 (benzenoid) nucleotide binding site and a second transition, located at 490 nm, is sensitive preferentially to processes occurring at the 4 ( quinoid) binding site. The latter is probably closely asscoiated with 2-amino and /or 3-carbonyl substituents. The third transition, identified with the absorption maxium at 420–440 nm, appears to reflect contributions arising in the entire phenoxazone chromophore. Using these band assignments, it is concluded that the benzenoid site binds nucleotides 1.5–3 times more avidly than does the quinoid site. CD titrations resolve these processes more effectively than do abscrption titrations. Aspects of the structures of these complexes formed in solution are discussed.     

Model studies of interactions between nucleic acids and proteins: hydrogen bonding of amides with nucleic acid bases.

The formation of hydrogen bonded complexes between nucleic acid bases and acetamide has been studied by nuclear magnetic resonance in CDC13 at different temperatures. Pairs of hydrogen bonds are formed when acetamide binds to nucleic acid bases. Thermodynamic parameters have been computed and compared to those obtained for the association of carboxylic acids with nucleic acid bases. The role of hydrogen bonded complexes in the association of proteins with nucleic acids is discussed.     

Functionalized oligoanthranilamides: modular and conformationally controlled scaffolds.

This paper describes the use of functionalized oligoanthranilamides as conformationally controlled scaffolds for molecular recognition. Oligomers of anthranilamides are stabilized by the formation of intramolecular six-membered hydrogen bonds in a linear strand conformation. Onto alternate anthranilic acid units, we have attached di- or tripeptide recognition units with the potential to form intramolecular hydrogen bonds to an intercalated peptide strand. Using 1H NMR dilution experiments in CDCl(3), we have observed chemical shift changes that are consistent with the formation of an extended hydrogen bonded sheet dimer. We also demonstrate that the bis-alanine functionalized strands are able to form discrete hydrogen bonded complexes with dipeptide substrates and to bind hexanoyl alanylalanine selectively over its benzyl ester. In the presence of excess hydrogen bond donors and acceptors, the oligoanthranilamide strand retained its linear conformation, pointing to the potential of this modular design as a useful and stable scaffold for molecular recognition studies.     

Ab initio Models for Six-Center Multiple Proton Exchange and Ion Pair Formation Assisted by Lewis Acids

High level ab initio and density functional calculations, extrapolated to QCISD(T)/6-311+G(3df,2p)//MP2/6-31+G^**+ZPE, reveal that cyclic ion pairs can form in the hydrogen bonded complexes of haloboric acids BH_nX_3-n–HX, X=F, Cl, with Lewis bases HX, H₂O, CH₃OH, and NH₃, even in isolation (e.g., in the gas phase). The intrinsic acidities (deprotonation energies) required for protonation of these bases with formation of gas phase ion pairs are calculated to be <295 kcal/mol for water, <301 kcal/mol for methanol, and <306 kcal/mol for ammonia; such values are common for acidic sites in zeolites. All gas phase ion pairs prefer symmetric bidentate or tridentate structures. In the other cases where hydrogen bonded complexes prevail, symmetric ion pair-like transition structures for multiple hydrogen exchange are computed.Supplementary material to this paper is available in electronic form at http://dx.doi.org/10.1007/s0089400060563     

17O NMR investigation of the hydration of L-alanine and L-proline in water/Me2SO mixtures

The hydration state of L-Alanine and L-Proline has been assessed via 17O NMR. At neutral and basic pH, two water molecules are hydrogen bonded at the carboxylate group, one to each oxygen, whereas a third water molecule is hydrogen bonded to the protonated COOH group at acidic pH, via the hydroxyl hydrogen. The possible formation of dimers and/or higher complexes in DMSO is indicated not only from the chemical shift but also from the linewidth of the amino acids.     

Synthesis, spectroscopic characterization and biological activity on newly synthesized copper(II) and nickel(II) complexes incorporating bidentate oxygen-nitrogen hydrazone ligands

We report the synthesis of the hydrazone ligands, 1-(phenyl-hydrazono)-propan-2-one (PHP), 1-(p-tolyl-hydrazono)-propan-2-one (THP), 1-[(4-chloro-hydrazono)]-propan-2-one (CHP), and their Ni(II) and Cu(II) metal complexes. The structure of the ligands and their complexes were investigated using elemental analysis, magnetic susceptibility, molar conductance and spectral (IR, UV, and EPR) measurements. IR spectra indicate that the free ligands exist in the hydrazo-ketone rather than azo-enol form in the solid state. Also, the hydrazo-NH exists as hydrogen bonded to the keto-oxygen either as intra or as intermolecular hydrogen bonding. In all the studied complexes, all ligands behave as a neutral bidentate ligands with coordination involving the hydrazone-nitrogen and the keto-oxygen atoms. The magnetic and spectral data indicate a square planar geometry for Cu²⁺ complexes and an octahedral geometry for Ni²⁺ complexes. The ligands and their metal chelates have been screened for their antimicrobial activities using the disc diffusion method against the selected bacteria and fungi. They were found to be more active against Gram-positive than Gram-negative bacteria. It may be concluded that the antimicrobial activity of the compounds is related to cell wall structure of bacteria.Protonation constant of (PHP) ligand and stability constants of its Cu²⁺ and Ni²⁺ complexes were determined by potentiometric titration method in aqueous solution at ionic strength of 0.1 M sodium nitrate. It has been observed that the hydrazone ligand (PHP) titrated here has one protonation constant. The divalent metal ions Cu²⁺ and Ni²⁺ form with (PHP) 1:1 and 1:2 complexes. The insolubility of (THP) and (CHP) ligands in aqueous medium does not permit the determination of their protonation constants and formation constants of the corresponding complexes in aqueous solution.     

Three-dimensional structures of enzyme-substrate complexes of the hydroxynitrile lyase from Hevea brasiliensis.

The 3D structures of complexes between the hydroxynitrile lyase from Hevea brasiliensis (Hb-HNL) and several substrate and/or inhibitor molecules, including trichloracetaldehyde, hexafluoracetone, acetone, and rhodanide, were determined by X-ray crystallography. The complex with trichloracetaldehyde showed a covalent linkage between the protein and the inhibitor, which had apparently resulted from nucleophilic attack of the catalytic Ser80-Ogamma. All other complexes showed the substrate or inhibitor molecule merely hydrogen bonded to the protein. In addition, the native crystal structure of Hb-HNL was redetermined at cryo-temperature and at room temperature, eliminating previous uncertainties concerning residual electron density within the active site, and leading to the observation of two conserved water molecules. One of them was found to be conserved in all complex structures and appears to have mainly structural significance. The other water molecule is conserved in all structures except for the complex with rhodanide; it is hydrogen bonded to the imidazole of the catalytic His235 and appears to affect the Hb-HNL catalyzed reaction. The observed 3D structural data suggest implications for the enzyme mechanism. It appears that the enzyme-catalyzed cyanohydrin formation is unlikely to proceed via a hemiacetal or hemiketal intermediate covalently attached to the enzyme, despite the observation of such an intermediate for the complex with trichloracetaldehyde. Instead, the data are consistent with a mechanism where the incoming substrate is activated by hydrogen bonding with its carbonyl oxygen to the Ser80 and Thr11 hydroxy groups. A hydrogen cyanide molecule subsequently replaces a water molecule and is deprotonated presumably by the His235 base. Deprotonation is facilitated by the proximity of the positive charge of the Lys236 side chain.     

Complexation of phosphatidylcholine lipids with cholesterol

It is postulated that the specific interactions between cholesterol and lipids in biological membranes are crucial in the formation of complexes leading subsequently to membrane domains (so-called rafts). These interactions are studied in molecular dynamics simulations performed on a dipalmitoylphosphatidylcholine (DPPC)-cholesterol bilayer mixture and a dilauroylphosphatidylcholine (DLPC)-cholesterol bilayer mixture, both having a cholesterol concentration of 40 mol %. Complexation of the simulated phospholipids with cholesterol is observed and visualized, exhibiting 2:1 and 1:1 stoichiometries. The most popular complex is found to be 1:1 in the case of DLPC, whereas the DPPC system carries a larger population of 2:1 complexes. This difference in the observed populations of complexes is shown to be a result of differences in packing geometry and phospholipid conformation due to the differing tail length of the two phosphatidylcholine lipids. Furthermore, aggregation of these complexes appears to form hydrogen-bonded networks in the system containing a mixture of cholesterol and DPPC. The CH...O hydrogen bond plays a crucial role in the formation of these complexes as well as the hydrogen bonded aggregates. The aggregation and extension of such a network implies a possible means by which phospholipid:cholesterol domains form.     

Variations in the turn-forming characteristics of N-acyl proline units.

We have examined intramolecular hydrogen bonding in four homologous compounds, N-acetyl-, N-propionyl-, N-i-butyryl-, and N-pivaloyl-proline-methylamide, in methylene chloride, by means of 1H-nmr and ir measurements. At room temperature, the major trans conformer of MeCO-Pro-NHMe appears to be approximately 68% intramolecularly hydrogen bonded, the trans conformers of EtCO-Pro-NHMe and i-PrCO-Pro-NHMe are approximately 75% intramolecularly hydrogen bonded, and t-BuCO-Pro-NHMe is approximately 50% intramolecularly hydrogen bonded. Thus, the internally hydrogen-bonded state (C7 or gamma-turn) is significantly less populated for the N-pivaloyl compound than for the other three molecules in this series. Variable temperature measurements indicate that for each proline derivative there is very little enthalpic difference between the intramolecularly hydrogen-bonded and nonhydrogen bonded states of the trans rotamer. Changing the N-terminal acyl group also affects intramolecular hydrogen bonding (including beta-turn formation) in end-blocked Pro-Gly dipeptides.     

Effect of second-sphere coordination 12. Adduct formation behavior of crown ethers with ammine complexes of ruthenium containing a protic ligand of other type than ammine

Adduct formation of pentaammineruthenium complexes involving a different type of protic ligand, such as imidazole, was investigated for a series of crown ethers with different ring size. Changes in redox potential and in absorption spectra of the complex were measured on addition of crown ether to the complex solution. The magnitude of the change in both properties is dependent on the ring size of crown ethers. ¹H-NMR spectra of the complex were measured in the presence of crown ethers in order to elucidate hydrogen bonding sites. The chemical shifts of NH proton of imidazol and ammine protons were measured at various concentrations of crown ethers. Adduct formation was discussed based on the features of dependences of those chemical shifts on crown ether concentration.     

Interactions of 4-nitroquinoline 1-oxide with deoxyribodinucleotides.

The interactions of 4-nitroquinoline 1-oxide (NQO), a potent mutagen and carcinogen, with several self- and non-self-complementary deoxydinucleotides were probed by using absorption spectra of the charge transfer bands and 1H and 13C NMR spectra. Absorption spectra were analyzed by using Benesi-Hildebrand-type equations to yield stoichiometries and equilibrium constants of complex formation. Non-self complementary dimers form weak l:1 complexes [dpTpG:NQO, K(25 degrees C) = 22 M-1] while self-complementary dimers form strong 2:1 complexes [dpCpG)2:NQO, K(25 degrees C) = 2.2 X 10(4) M-2]. A mixture of dpTpG and dpCpA with NQO gives a 2:1 complexes [dpCpG)2:NQO, K(25 degrees C) = 2.2 X 10(4) M-2]. A mixture of dpTpG and dpCpA, K(25 degrees C) = 8.6 X 10(3) M-2]. Analyses of the changes in 13C and 1H NMR chemical shifts with complex formation gave approximate orientations for the intercalation of NQO with self-complementary dimer minihelixes. In the (dpCpG)2:NQO and (dpGpC)2:NQO complexes, the NO2 group of NQO probably lies in the major grove and the NO2, NO containing NQO ring is stacked near the purine imidazole ring. In the (dpTpA)2:NQO and (dpApT)2NQO complexes, the NO2 seems to project into the minor grove and the NQO benzenoid ring is over the purine imidazole ring.     

Actinomycin D-deoxynucleotide complexes as models for the actinomycin D-DNA complex. The use of nuclear magnetic resonance to determine the stoichiometry and the geometry of the complexes.

The use of proton and carbon-13 magnetic resonance spectroscopy for the determination of the geometry and the stoichiometry of the actinomycin D-deoxyguanosine 5'-monophosphate complex is outlined. The dimerization of actinomycin D has been reexamined by recording the proton magnetic resonance spectrum of actinomycin D to much lower concentrations through the use of Fourier transform nuclear magnetic resonance techniques. The effect of the actinomycin D dimerization on the observed chemical shifts that results from the additon of nucleotides to an actinomycin D solution is directly demonstrated by comparing the actinomycin D-nucleotide titrations at both low (approximately 0.3 mM) and high (approximately 12 mM) concentrations of actinomycin D. In the presence of excess nucleotide the chemical shifts of the actinomycin D groups were essentially the same for both the low and high concentration titrations. The complexes of actinomycin D with pdG-dC, dG-dC, deoxyguanosine 3'-monophosphate, G-C, C-G, dIMP(5'), 2, 6-diaminopurine deoxyribose, and other nucleotides were also investigated by proton magnetic resonance and visible spectral titrations. These data were interpreted in terms of the molecular geometry of the complexes and in terms of the effect of the structure of the nucleotide base on the relative binding affinity of the nucleotides for the two nucleotide binding sites of actinomycin D. The carbon-13 chemical shifts of dGMP(5') were measured as a function of concentration over the concentration range of 0.5-0.025 M. The infinite dilution carbon-13 chemical shifts were graphically estimated from the dilution curves. These values were used to calculate the changes in the chemical shifts of the dGMP carbons that result from the formation of an actinomycin D-(dGMP)2 complex. It was not possible to interpret these carbon-13 chemical shift changes in terms of only ring current effects, which thus rules out the use of carbon-13 spectroscopy in the determination of the geometries of the actinomycin D complexes with the mono- and dinucleotides. The induced chemical shifts in the proton spectra may be used in the determination of the geometries of the complexes. A consideration of these data for the above nucleotide series shows that the predominant complex formed is one in which the guanine rings in the two nucleotide binding sites of actinomycin D are oriented in a manner very similar to that observed in the cocrystalline complex of actinomycin D with deoxyguanosine.     

Structural evidence for the order of preference of inorganic substrates in mammalian heme peroxidases: crystal structure of the complex of lactoperoxidase with four inorganic substrates,SCN-, I-, Br– and Cl-

Lactoperoxidase (LPO) is a member of the family of mammalian heme peroxidases. It catalyzes the oxidation of halides and pseudohalides in presence of hydrogen peroxide. LPO has been co-crystallized with inorganic substrates, SCN^-, I^-, Br^- and Cl^-. The structure determination of the complex of LPO with above four substrates showed that all of them occupied distinct positions in the substrate binding site on the distal heme side. The bound substrate ions were separated from each other by one or more water molecules. The heme iron is coordinated to His-351 N^ϵ2 on the proximal side while it is coordinated to conserved water molecule W-1 on the distal heme side. W-1 is hydrogen bonded to Br^- ion which is followed by Cl^- ion with a hydrogen bonded water molecule W-5′ between them. Next to Cl^- ion is a hydrogen bonded water molecule W-7′ which in turn is hydrogen bonded to W-8′ and N atom of SCN^-. W-80 is hydrogen bonded to W-9′ which is hydrogen bonded to I^-. SCN^- ion also interacts directly with Asn-230 and through water molecules with Ser-235 and Phe-254. Therefore, according to the locations of four substrate anions, the order of preference for binding to lactoperoxidase is observed as Br^- > Cl^- > SCN^- > I^-. The positions of anions are further defined in terms of subsites where Br^- is located in subsite 1, Cl^- in subsite 2, SCN^- in subsite 3 and I^- in subsite 4.     

Metal complexes of N-hydroxy-imino-di-α-propionic acid and related ligands

N-hydroxy-imino-di-α-propionic acid, the ligand present in the natural oxovanadium(IV) complex ‘amavadin’ which occurs in the toadstool Amanita muscaria, has been synthesised, as well as two related ligands—N-hydroxy-iminodiacetic acid and imino-di-α-propionic acid—useful for comparison purposes. The formation of complexes of these ligands with VO²⁺, Ni²⁺ has been studied and their stability constants have been determined.The two N-hydroxy-substituted ligands, of low basicity, form ML₂ complexes with VO²⁺, unlike the more basic derivatives of iminodiacetic acid. Since substitution of ligands bonded to the apical site trans to the oxo ligand is very fast and the formation of ML₂ complexes of VO²⁺ exposes that apical site to the reaction media, this may be the reason why oxovanadium(IV) and the unusual derivative of iminodiacetic acid present in ‘amavadin’ were selected for the biological role that this complex plays in the toadstool.     

13C- and 31P-NMR studies of the conformation of carcinogen-modified nucleic acid dimers

The effect of the carcinogen acetylaminofluorene (AAF) on nucleic acid structure was examined using ¹³C- and ³¹P-NMR spectroscopies. Conformational effects were compared in two AAF-modified dinucleoside monophosphates (ApG and GpA) and two AAF-modified deoxydinucleotides (dpApG and dpGpA). Changes in adenine ¹³C chemical shifts on formation of the AAF-adduct and as a function of temperature provided evidence of base stacking. Differences in fluorene ¹³C chemical shifts between the AAF-modified dimer and AAF-modified monomer provided evidence of fluorene stacking. The effect of forming the adduct on the phosphate backbone was examined using ³¹P-NMR. A correlation was demonstrated between the degree of adenine-fluorene stacking on one hand and the change in conformation of the backbone conformation on the other.     

Platinum(II) complexes of pyrimidine-derived ligands

A series of new Pt(II) complexes of hydrazinouracils were synthesized and studied. The complexes have the general formula [Pt₂L2^?Cl₂]nH₂O, where L^? is a deprotonated molecule of a ligand, n = 1?3 and there are two bridging chloride ions. The ligands are bonded through the amino group of the hydrazine residue and the nitrogen atom of the pyrimidine cycle. From ¹H NMR data it is concluded that the preferred type of coordination is Pt- N(3), hydrazine chelation, which is characteristic for solid complexes. Although the participation of the N(1) atom in formation on the polynuclear complexes is possible, it may be that N(1) coordination occurs only in solutions.