Lack of correlation between intercalation and plasmid curing ability of some tricyclic compounds

Some tricyclic psychotropic drugs are known to have plasmid curing activity. The interaction with DNA of three plasmid curing (chlorpromazine, amitriptyline, imipramine) and four ineffective (methylene blue, 7,8-dioxo-chlorpromazine, thiazinamium, chlorpromazine sulphoxide) compounds was studied by fluorescence polarization and circular dichroism methods. Among the seven compounds three, namely chlorpromazine, 7,8-O2-chlorpromazine, and methylene blue showed an intercalation effect. Other phenothiazines such as chlorpromazine sulphoxide and thiazinamium were not able to intercalate into Escherichia coli DNA, neither did the plasmid curing drugs amitryptyline and imipramine. It is concluded that the plasmid curing ability is not necessarily related to the intercalation ability.     

The role of side chains in the interaction of new antitumor pyrimidoacridinetriones with DNA: molecular dynamics simulations

Pyrimidoacridinetriones (PATs) are a new group of highly active antitumor compounds. It seems reasonable to assume that, like for some other acridine derivatives, intercalation into DNA is a necessary, however not a sufficient condition for antitumor activity of these compounds. Rational design of new compounds of this chemotype requires knowledge about the structure of the intercalation complex, as well as about interactions responsible for its stability. Computer simulation techniques such as molecular dynamics (MD) may provide valuable information about these problems. The results of MD simulations performed for three rationally selected PATs are presented in this paper. The compounds differ in the number and position of side chains. Each of the compounds was simulated in two systems: i) in water, and ii) in the intercalation complex with the dodecamer duplex d(GCGCGCGCGCGC)2. The orientation of the side chain in relation to the ring system is determined by the position of its attachment. Orientation of the ring system inside the intercalation cavity depends on the number and position of side chain(s). The conformations of the side chain(s) of all PATs studied in the intercalation complex were found to be very similar to those observed in water.     

Interaction of paired homologous series of diacridines and triacridines with deoxyribonucleic acid

Viscometric measurements using covalently closed circular DNA and sonicated rod-like DNA fragments were performed to investigate unwinding and extension of the DNA helix associated with binding of paired homologous series of diacridines and triacridines. The maximum interchromophore distance for members of the diacridine series spans from 15.1 to 27.5 A, permitting the largest of these ligands to cover up to 4 or 5 base-pairs, allowing for helical twist and local unwinding in a bisintercalated complex lacking severe bending or kinking of the DNA backbone. Helix unwinding angles and increments in DNA contour length are characteristic of bifunctional reaction for all the diacridines studied, the DNA lattice appearing to saturate with one ligand molecule bound per 4 base-pairs. The triacridines, whose maximum end-to-end interchromophore distances are the same as those of their paired diacridines, have maximum central-to-terminal interchromophore distances covering the range 7.5-13.8 A and thus have the potential to form trisintercalated complexes with one or two base-pairs sandwiched between each chromophore. However, helix extension and unwinding parameters for the triacridines are similar to those of the diacridines, and we find no evidence of a transition from bifunctional to trifunctional reaction as the homologous series is ascended. In general, the binding site size appears to be 5 base-pairs for the triacridines. The stereochemical requirements for trisintercalation of triacridines are discussed with reference to the present findings and to the work of others.     

Intramolecular dynamics of chain molecules monitored by fluctuations in efficiency of excitation energy transfer. A theoretical study.

The fluorescence quantum yield of a polymer molecule to which an energy donor chromophore and an energy acceptor chromophore are attached depends on the distance between the donor and acceptor chromophores. If this distance fluctuates with time, the fluorescence intensity is expected to fluctuate as well, and the time course of the intensity fluctuations will be correlated with the time course of the changes in the interchromophore distance. The intensity fluctuations are experimentally measurable if the number of illuminated molecules is small. A theoretical treatment of such fluorescence intensity fluctuations is presented in terms of a parameter that describes the polymer chain dynamics. Computer simulations were performed to illustrate the dependence of the autocorrelation function of the intensity fluctuations on the polymer chain conformation, the interchromophore energy transfer properties, and the macromolecular dynamics. These simulations demonstrate that the intensity fluctuations due to nonradiative energy transfer between chromophores attached to polymer chains can be large enough to be experimentally useful in the study of intramolecular dynamics of macromolecules.     

Structural Effects on Arthrobacter Methylene Hydroxylase Activity

Arthrobacter 4-44-2 (ATCC 25581), capable of subterminal oxidation of n-hexadecane to 2-, 3-, and 4-alcoholic and ketonic products, was examined for the ability of this methylene hydroxylase capability to be induced and repressed and for structural relationships influencing methylene function oxidation. Induction was best carried out by use of n-alkanes from 10 to 16 carbons in length and was especially strong with methylcyclohexane among cyclic compounds tested. Induction was not observed with several related alcohols, 1-unsaturated compounds, or methoxy and ethoxy compounds tested. After induction, n-alkanes 14 and 16 carbons in length were transformed to the corresponding internal oxidation products; however, no activity was observed with even-carbon alkanes of shorter chain length. Hexadecene-1 and all alcohols tested, including cyclododecanol, were transformed to corresponding ketonic or aldehydic products. Cyclic compounds tested, including cyclododecane, were not oxidized by induced cells, suggesting that a methyl group plays a role in orientation of the substrate for the methylene hydroxylation but that the methyl function was not as critical after completion of the hydroxylation step regardless of structural configuration. Acetate strongly repressed induction of n-hexadecane methylene hydroxylase activity. Inducibility of methylene hydroxylase activity was confirmed by use of cell-free systems with methylcyclohexane as an inducer. A stimulation of methylene hydroxylase activity by addition of reduced pyridine nucleotides and ferrous ion was indicated.     

The intercalation of imidazoacridinones into DNA induces conformational changes in their side chain

Imidazoacridinones (IAs) are a new group of highly active antitumor compounds. The intercalation of the IA molecule into DNA is the preliminary step in the mode of action of these compounds. There are no experimental data about the structure of an intercalation complex formed by imidazoacridinones. Therefore the design of new potentially better compounds of this group should employ the molecular modelling techniques. The results of molecular dynamics simulations performed for four IA analogues are presented. Each of the compounds was studied in two systems: i) in water, and ii) in the intercalation complex with dodecamer duplex d(GCGCGCGCGCGC)2. Significant differences in the conformation of the side chain in the two environments were observed for all studied IAs. These changes were induced by electrostatic as well as van der Waals interactions between the intercalator and DNA. Moreover, the results showed that the geometry of the intercalation complex depends on: i) the chemical constitution of the side chain, and ii) the substituent in position 8 of the ring system.     

Attempts to observe through-chain energy transfer and electron transfer on α-helical polypeptide chain

Singlet singlet energy transfer between the two terminal chromophores attached to an α-helical polypeptide chain has been studied. The transfer efficiency was satisfactorily explained by Förster's theory when the interchromophore distance was calculated from the α-helical structure. Therefore, it was concluded that no particular effect from the possible energy band structure of the α-helical conformation was detected in the end-to-end energy transfer. Similarly, end-to-end electron transfer was attempted between the electron donor acceptor pair attached to the ends of α-helcial polypeptide chain. However, no intramolecular interaction was found between the donor acceptor pair, indicating that the exciton structure of the α-helical polypeptides is not effective enough to realize through-chain electron transfer.     

Mechanisms of chromosome banding

A thorough understanding of the mechanisms of R-, C-and G-banding will come only from studies of the binding of Giemsa dyes to isolated and characterized preparations of heterochromatin and euchromatin. Since such studies require an exact knowledge of the optical characteristics of Giemsa, the spectral adsorption curves and extinction coefficients of Giemsa and its component dyes at various concentrations in the presence and absence of DNA were determined. — Although Giemsa is a complex mixture of thiazin dyes plus eosin; methylene blue, and azure A, B or C alone gave good banding. Thionin, with no methyl groups, gave poor or no banding. Eosin was not a necessary component for banding. — The most striking characteristic of the thiazin dyes is that they are strongly metachromatic, i.e., their adsorption spectra and extinction coefficients change as the concentration of the dye increases or as they bind to positively charged compounds (chromotropes). These changes, especially for methylene blue, are described in detail and allow a distinction between concentration dependent binding to DNA by intercalation and binding by side stacking.     

The binding of DNA intercalating and non-intercalating compounds to A-form and protonated form of poly(rC).poly(rG): spectroscopic and viscometric study

Polymorphic RNA conformations may serve as potential targets for structure specific antiviral agents. As an initial step in the development of such drugs, the interaction of a wide variety of compounds which are characterized to bind to DNA through classical or partial intercalation or by mechanism of groove binding, with the A-form and the protonated form of poly(rC).poly(rG), been evaluated by multifaceted spectroscopic and viscometric techniques. Results of this study suggest that (i) ethidium intercalates to the A-form of RNA, but does not intercalate to the protonated form, (ii) methylene blue intercalates to the protonated form of the RNA but does not intercalate to the A-form, (iii) actinomycin D does not bind to either conformations of the RNA, and (iv) berberine binds to the protonated form by partial intercalation process, while its binding to the A-form is very weak. The DNA groove binder distamycin A has much higher affinity to the protonated form of the RNA compared to the A-form and binds to both structures by non-intercalative mechanism. We conclude that the binding affinity characteristics of these DNA binding molecules to the RNA conformations are vastly different and may serve as data for the development of RNA based antiviral drugs.     

Co-solubility of saturated cholesteryl esters: a comparison of calculated and experimental binary phase diagrams

Based on ideal solution theory, phase diagrams are calculated for binary compositions of cholesteryl esters and compared to experimental data from pairwise combinations in a saturated acyl chain series from caprylate to arachidate, which encompasses three crystal packing motifs in the solid state. Within a crystal structure class, nearly ideal co-solubility is found for binary solids, where the acyl chain lengths of the pure components differ by one methylene group. Beyond this chain length difference, nonideal solutions occur until fractionation occurs at e.g., six methylene unit increments between the components. The observed liquidus lines of the eutectic are near the theoretical curves when the combinations of two compounds packing in the same crystal structure fractionate. Fractionation also is found when liquids composed of two esters which favor different crystal structures are solidified from the melt, no matter what the chain length difference is; the liquidus curves for re-heated solids, however, are not necessarily predicted by the Schr?der equation. In general, co-miscibility can be found in mesophases formed from compounds with two different crystal structures.     

Structure-activity relationships of the peptide deformylase inhibitor BB-3497: modification of the methylene spacer and the P1' side chain

Structural modifications to the peptide deformylase inhibitor BB-3497 are described. In this paper, we describe the initial SAR around this lead for modifications to the methylene spacer and the P1' side chain. Enzyme inhibition and antibacterial activity data revealed that the optimum distance between the N-formyl hydroxylamine metal binding group and the P1' side chain is one unsubstituted methylene unit. Additionally, lipophilic P1' side chains that closely mimic the methionine residue in the substrate provided compounds with the best microbiological profile.     

Interaction of DNA with actinocin amides containing cationoid centers in the amide groups

Complexes of DNA with actinocin derivatives containing ω-dialkylaminoalkyl groups in the1 and/or 9 positions of the chromophore were studied by spectrophotometric titration, circular dichroism, and viscometry. Induced circular dichroism (ICD) spectra of the DNA-ligand complexes were compared for the cases of the complexes of known structure established by other methods. It was shown that the presence of an isoelliptic point in the long-wavelength absorption band of the ICD spectra of the ligand under monomeric binding conditions could indicate intercalation of the actinocin chromophore into DNA. The separation of the cationoid center and the chromosphore upon elongation of the methylene chain increases the aggregability of the ligand pn the surface of the DNA double helix, which prevents the intercalation of the chromophore.     

Synthesis and evaluation of bifunctional nitrocatechol inhibitors of pig liver catechol-O-methyltransferase

Bifunctional compounds were tested in vitro as potential inhibitors of pig liver catechol-O-methyltransferase (COMT) with respect to the catechol substrate 4-[(3,4-dihydroxyphenyl)azo]benzenesulfonate. The bifunctional compounds were a composite of either two nitrocatechols or one nitrocatechol and one phenol, linked by amide bonds to a spacer unit comprising two to five methylene groups. The unsymmetrical compounds N-[2-(4-hydroxybenzoylamine)ethyl]-3,4-dihydroxy-5-nitrobenzamide], N-[3-(4-hydroxybenzoyl-amine)propyl]-3,4-dihydroxy-5-nitrobenzamide] and N-[5-(4-hydroxybenzoylamine)pentyl]-3,4-dihydroxy-5-nitrobenzamide] demonstrated strong inhibitory action against COMT with K(i) values in the 100 nM range. In comparison, the monofunctional nitrocatechol analogues of these compounds had K(i) values that were significantly higher.     

Viscometric analysis of the interaction of bisphenanthridinium compounds with closed circular supercoiled and linear DNA.

The interaction with closed circular supercoiled and linear DNA of bisphenanthridinium compounds substituted through both the meta and para positions of the 6-phenyl group, along with appropriate monomer intercalators as controls, has been investigated by viscometric titration. When CPK models for the phenanthridinium rings of the three bis-compounds are oriented in a parallel manner as a model for intercalation, their ring plane to ring plane distances are approximately 7 to 8 A (SR 2430), 11 A (SR 2193), and 15 A (SR 2166). In SR 2430 the two phenanthridines are linked through the para positions of the 6-phenyl group; this chain allows intercalation of the two rings at adjacent binding sites in DNA, but is not long enough to accommodate an excluded site. The viscometric titrations with both superhelical and linear DNA clearly indicate that SR 2430 gives results close to those of the monomer control compounds while SR 2193 and SR 2166 have approximately twice the unwinding angle and DNA length increase on binding to DNA as the monomer compounds. These phenanthridinium compounds, therefore, are capable of bisintercalation only if their linking groups are of sufficient length to allow an excluded binding site between base pairs. This conclusion is supported by DNA thermal denaturation experiments in the presence of these compounds.     

The bisnaphthalimides as new active lead compounds against Plasmodium falciparum

The bisquaternary bisnaphthalimides are a versatile class of compounds being active against the malaria parasite Plasmodium falciparum in the lower nanomolar range of concentration combined with no cytotoxicity. The series of compounds is designed as choline analogues and interfering agents of the phosphatidylcholine biosynthesis. The qualitative analysis of the structure–activity relationships (SAR) revealed the importance of a long methylene middle chain of at least 8 methylene groups between the two bisquaternary naphthalimides or a monoquaternary naphthalimide consisting of a long alkyl chain attached to the positively charged nitrogen atom. Since the SARs are different from reported biscationic antimalarial drugs the mode of action remains to be elucidated.     

Purification and characterization of the methylene tetrahydromethanopterin dehydrogenase MtdB and the methylene tetrahydrofolate dehydrogenase FolD from Hyphomicrobium zavarzinii ZV580

Recently, it has been shown that heterotrophic methylotrophic Proteobacteria contain tetrahydrofolate (H(4)F)- and tetrahydromethanopterin (H(4)MPT)-dependent enzymes. Here we report on the purification of two methylene tetrahydropterin dehydrogenases from the methylotroph Hyphomicrobium zavarzinii ZV580. Both dehydrogenases are composed of one type of subunit of 31 kDa. One of the dehydrogenases is NAD(P)-dependent and specific for methylene H(4)MPT (specific activity: 680 U/mg). Its N-terminal amino acid sequence showed sequence identity to NAD(P)-dependent methylene H(4)MPT dehydrogenase MtdB from Methylobacterium extorquens AM1. The second dehydrogenase is specific for NADP and methylene H(4)F (specific activity: 180 U/mg) and also exhibits methenyl H(4)F cyclohydrolase activity. Via N-terminal amino acid sequencing this dehydrogenase was identified as belonging to the classical bifunctional methylene H(4)F dehydrogenases/cyclohydrolases (FolD) found in many bacteria and eukarya. Apparently, the occurrence of methylene tetrahydrofolate and methylene tetrahydromethanopterin dehydrogenases is not uniform among different methylotrophic alpha-Proteobacteria. For example, FolD was not found in M. extorquens AM1, and the NADP-dependent methylene H(4)MPT dehydrogenase MtdA was present in the bacterium that also shows H(4)F activity.     

Binding of a distamycin-ellipticine hybrid molecule to DNA and chromatin: spectroscopic, biochemical, and molecular modeling investigations.

A bifunctional molecule in which an ellipticine chromophore is attached to a distamycin residue via a diaminopropyl tether has been designed and synthesized in the expectation of creating a hybrid molecule capable of bidentate binding to DNA by both intercalation and minor-groove interactions. The strength and mode of binding to DNA of this conjugate have been studied by means of circular and linear dichroism as well as by stopped-flow kinetics and measurements of reactivity toward a chemical probe. The results converge to reveal that the ellipticine moiety of the hybrid largely dominates the binding reaction with DNA. In the presence of chromatin, the hybrid molecule binds preferentially to the internucleosomal DNA, a preference dictated by its intercalating chromophore. Theoretical computations were performed on the comparative complexation energies of distamycin, the ellipticine derivative, and the hybrid ligand with a B-representative octanucleotide, d(GCATATGC)2. The best binding configuration of the ellipticine derivative locates its aminoalkyl side chain in the minor groove where distamycin is also present. The molecular modeling analysis fully supports the involvement of a bimodal binding process for the hybrid and reveals that the binding of the conjugate to DNA favors a pronounced bending toward the minor groove. This effect is attributed to intercalation of the ellipticine chromophore. An interesting link is established between the DEPC reactivity experiments and the theoretical computations, suggesting that DEPC can be used as a probe for drug-induced DNA bending. On the basis of these results, we propose the design of a new hybrid ligand bearing an additional positively-charged amidine side chain to confer higher DNA-binding affinity.     

Synthesis and biochemical properties of novel mRNA 5' cap analogs resistant to enzymatic hydrolysis

A series of new dinucleotide cap analogs with methylene groups replacing oxygens within the pyrophosphate moieties have been synthesized. All the compounds were resistant to the human scavenger decapping hydrolase, DcpS. Binding constants of the modified caps to eIF4E are comparable to those obtained for m7GpppG. This suggests these methylene modifications in the pyrophosphate chain do not significantly affect cap-binding at least for eIF4E. These cap analogs are also good inhibitors of in vitro translation. mRNAs capped with novel analogs were translated similarly to the mRNA capped with the parent m7GpppG.     

Methylene substitution at the alpha-beta bridging position within the phosphate chain of dUDP profoundly perturbs ligand accommodation into the dUTPase active site

dUTP pyrophosphatase, a preventive DNA repair enzyme, contributes to maintain the appropriate cellular dUTP/dTTP ratio by catalyzing dUTP hydrolysis. dUTPase is essential for viability in bacteria and eukaryotes alike. Identification of species-specific antagonists of bacterial dUTPases is expected to contribute to the development of novel antimicrobial agents. As a first general step, design of dUTPase inhibitors should be based on modifications of the substrate dUTP phosphate chain, as modifications in either base or sugar moieties strongly impair ligand binding. Based on structural differences between bacterial and human dUTPases, derivatization of dUTP-analogous compounds will be required as a second step to invoke species-specific character. Studies performed with dUTP analogues also offer insights into substrate binding characteristics of this important and structurally peculiar enzyme. In this study, alpha,beta-methylene-dUDP was synthesized and its complex with dUTPase was characterized. Enzymatic phosphorylation of this substrate analogue by pyruvate kinase was not possible in contrast to the successful enzymatic phosphorylation of alpha,beta-imino-dUDP. One explanation for this finding is that the different bond angles and the presence of the methylene group may preclude formation of a catalytically competent complex with the kinase. Crystal structure of E. coli dUTPase:alpha,beta-methylene-dUDP and E. coli dUTPase:dUDP:Mn complexes were determined and analyzed in comparison with previous data. Results show that the "trans" alpha-phosphate conformation of alpha,beta-methylene-dUDP differs from the catalytically competent "gauche" alpha-phosphate conformation of the imino analogue and the oxo substrate, manifested in the shifted position of the alpha-phosphorus by more than 3 A. The three-dimensional structures determined in this work show that the binding of the methylene analogue with the alpha-phosphorus in the "gauche" conformation would result in steric clash of the methylene group with the protein atoms. In addition, the metal ion cofactor was not bound in the crystal of the complex with the methylene analogue while it was clearly visible as coordinated to dUDP, arguing that the altered phosphate chain conformation also perturbs metal ion complexation. Isothermal calorimetry titrations indicate that the binding affinity of alpha,beta-methylene-dUDP toward dUTPase is drastically decreased when compared with that of dUDP. In conclusion, the present data suggest that while alpha,beta-methylene-dUDP seems to be practically nonhydrolyzable, it is not a strong binding inhibitor of dUTPase probably due to the altered binding mode of the phosphate chain. Results indicate that in some cases methylene analogues may not faithfully reflect the competent substrate ligand properties, especially if the methylene hydrogens are in steric conflict with the protein.     

The interaction of substituted and rigidly linked diquinolines with DNA

Viscometric measurements with circular and sonicated rodlike DNA fragments were used to explore whether ring substituents or conformationally restricted linkers promote bifunctional intercalation amongst a series of binuclear 4-aminoquinolines bridged via their 4-amino group. We find that ligands comprising unsubstituted quinolines and piperazine or pyrazole linkages bisintercalate. Quinoline-substituted alkyl-linked dimers intercalate in either a mixed monofunctional-bifunctional mode or bind with only one of their chromophores intercalated depending on the nature of the substituents. Equilibrium dialysis measurements show that the binding affinity for calf thymus DNA of the compounds studied ranges from (1.2-12) . 10(4) M-1 in buffer of ionic strength 0.1. Both co-operative and antico-operative binding isotherms were obtained and there is evidence for a second binding mode for the piperazine-linked diquinoline at saturating binding levels. For this compound the high-affinity association constant decreases with increasing ionic strength, 3.4 cations being released per bound ligand molecule. Partition dialysis measurements with DNAs of differing base composition indicate that the compounds studied are either AT selective or sequence neutral depending on ligand structure. For example, the pyrazole linker imparts a marked specificity for binding to AT-rich DNA, whereas the piperazine linker does not. Kinetic measurements using the surfactant-sequestration method reveal that DNA-diquinoline complexes dissociate very rapidly by complex mechanisms with rate constants greater than 100 s-1 in buffer of ionic strength 0.1.