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.     

Qualitative analysis of sequence specific binding of flavones to DNA using restriction endonuclease activity assays

Flavones, found in nature as secondary plant metabolites, have shown efficacy as anti‐cancer agents. We have examined the binding of two flavones, 5,7‐dihydroxy‐3,6,8‐trimethoxy‐2‐phenyl‐4H‐chromen‐4‐one (5,7‐dihydroxy‐3,6,8‐trimethoxy flavone; FlavA) and 3,5‐dihydroxy‐6,7,8‐trimethoxy‐2‐phenyl‐4H‐chromen‐4‐one (3,5‐dihydroxy‐6,7,8‐trimethoxy flavone; FlavB), to phiX174 RF DNA using restriction enzyme activity assays employing the restriction enzymes Alw44, AvaII, BssHII, DraI, MluI, NarI, NciI, NruI, PstI, and XhoI. These enzymes possess differing target and flanking sequences allowing for observation of sequence specificity analysis. Using restriction enzymes that cleave once with a mixture of supercoiled and relaxed DNA substrates provides for observation of topological effects on binding. FlavA and FlavB show differing sequence specificities in their respective binding to phiX. For example, with relaxed DNA, FlavA shows inhibition of cleavage with DraI (reaction site ^5′TTTAAA) but not BssHII (^5′GCGCGC) while FlavB shows the opposite results. Evidence for tolological specificity is also observed, Molecular modeling and conformational analysis of the flavones suggests that the phenyl ring of FlavB is coplanar with the flavonoid ring while the phenyl ring of FlavA is at an angle relative to the flavonoid ring. This may account for aspects of the observed sequence and topological specificities in the effects on restriction enzyme activity. © 2013 Wiley Periodicals, Inc. Biopolymers 99: 530–537, 2013.     

DNA binding of iron(II) complexes with 1,10-phenanthroline and 4,7-diphenyl-1,10-phenanthroline: salt effect,ligand substituent effect,base pair specificity and binding strength

The DNA binding of iron(II) mixed-ligand complexes containing 1,10-phenanthroline(phen) and 4,7-diphenyl-1,10-phenanthroline(dip), [Fe(phen)(3)](2+), [Fe(phen)(2)(dip)](2+) and [Fe(phen)(dip)(2)](2+) has been characterized by spectrophotometric titration and melting temperature measurements. The salt concentration dependence of the binding constant has allowed us to dissect the DNA-binding constant and free energy change of each iron(II) complex into the nonelectrostatic and polyelectrolyte contributions. A comparison of the nonelectrostatic components in the binding free energy changes among iron(II) complexes has made it possible to rigorously evaluate the contribution of the ligand substituents to the DNA-binding event. The peripheral substitution of phen by two phenyl groups increases the nonelectrostatic binding constant of the iron(II) complex more than 20 times, which is equivalent to approximately 7.5 kJ mol(-1) of more favorable contribution to the DNA binding. In general, the iron(II) complexes studied have higher affinity towards the more facile A-T sequence than the G-C sequence. This preferential binding may be attributed to the steric effect induced by the ancillary part of the ligands in the course of DNA binding. The binding of disubstituted iron(II) complex to DNA is quite strong as reflected in the modest increase in the denaturation temperature (T(m)) of double helical DNA upon the interaction with the iron(II) complex.     

The effects of substituted pyrimidines in DNAs on cleavage by sequence-specific endonucleases.

The rates of cleavage of DNAs containing substituents at position 5 of thymine or cytosine have been measured for a variety of sequence-specific endonucleases, so as to determine which features in the DNA sequence are being probed. Phage phi e DNA fully substituted with 5-hydroxymethyluracil is cleaved more slowly by enzymes whose recognition sequences contain A-T base pairs than are DNAs containing thymine, but both types of DNA are cleaved at similar rates by enzymes recognizing sequences composed only of G-C base pairs. Phage PBS2 DNA with uracil completely substituted for thymine is cleaved slowly by several enzymes which recognize sequences containing A-T base pairs (endonucleases Hpa I, HindII, and HindIII), while the rates of cleavage by other enzymes (endonucleases EcoRI and BamHI) are not affected. Phage lambda- and P22 DNAs containing 5-bromouracil are cleaved more slowly by several enzymes (endonucleases HindIII, Hpa I, BamHI) than are thymine-containing DNAs. Enzymes that recognize sequence isomers with the composition G:C:2A:2T (endonucleases EcoRI, Hpa I, HindIII) are not equally affected by substitution at position 5 of thymine, suggesting that they differ in their contacts with A-T base pairs. DNA containing glucosylated 5-hydroxymethylcytosine in place of cytosine is resistant to cleavage by all the endonucleases examined.     

Theoretical Study of the Sequence Selectivity of Isolexins,Isohelical DNA Groove Binding Ligands. Proposal for the GC Minor Groove Specific Compounds

Abstract

Atheoretical study is presented of complex formation between DNA fragments of different base sequences and isolexins, “isohelical base reading polymers”, formed of heteroaromatic pentagonal rings joined by appropriate linkers. Extensive computations are performed for the isolexin composed of the furan-pyrrole-furan sequence. They involve charged ligands with propioamidinium groups at both ends as well eis neutral molecules with terminal methyl, carbonyl and amino groups. Two different groups (C=O and NH) are used as linkers between the base reading moieties. The role of these elements on the binding preference of the ligands has been examined. The results show that the mere possibility of formation of hydrogen bonds between a ligand and the nucleic acid bases is not sufficient to ensure its binding specificity which is determined largely by the interplay of electrostatic factors. Thus the dicationic isolexins uniformly prefer AT sequences. For the neutral isolexins the nature of the groups forming the linkers is a major factor in defining the specificity, although these groups do not participate directly in the interaction with DNA The C=O linkers favour binding to AT sequence while the N-H linkers permit preferential binding to the GAG sequence. Finally, for the first time in theoretical computations, a ligand is proposed which should bind preferentially to the minor groove of GC sequences: this ligand is a neutral isolexin composed of three furan rings linked by two N-H groups. This ligand is considered as an improvable prototype. Altogether the results presented open the path for the designing of minor groove ligands specific for any desirable DNA base sequence.     

7-Azido-actinomycin D: a photoaffinity probe of the sequence specificity of DNA binding by actinomycin D

Actinomycin D (ActD) is a DNA-binding antitumor antibiotic that appears to act in vivo by inhibiting RNA polymerase. The mechanism of DNA binding of ActD has attracted much attention because of its strong preference for 5'-dGpdC-3' sequences. Binding is thought to involve intercalation of the tricyclic aromatic phenoxazone ring into a GC step, with the two equivalent cyclic pentapeptide lactone substituents lying in the minor groove and making hydrogen bond contacts with the 2-amino groups of the nearest neighbor guanines. Recent studies have indicated, however, that binding is also influenced by next-nearest neighboring bases. We have examined this higher order specificity using 7-azido-actinomycin-D as a photoaffinity probe, and DNA sequencing techniques to quantitatively monitor sites of covalent photoaddition. We found that GC doublets were strongly preferred only if the 5'-flanking base was a pyrimidine and the 3'-flanking base was not cytosine. In addition we observed a previously unreported preference for binding at a GG doublet in the sequence 5'-TGGG-3'.     

Molecular basis for sequence-specific DNA alkylation by CC-1065

CC-1065 is a potent antitumor antibiotic that binds covalently to N3 of adenine in the minor groove of DNA. The CC-1065 molecule is made up of three repeating pyrroloindole subunits, one of which (the left-hand one or A subunit) contains a reactive cyclopropyl function. The drug reacts with adenines in DNA in a highly sequence-specific manner, overlapping four base pairs to the 5'-side of the covalently modified base. Concomitant with CC-1065 covalent binding to DNA is an asymmetric effect on local DNA structure which extends more than one helix turn to the 5'-side of the covalent binding site. The DNA alkylation, sequence specificity, and biological potency of CC-1065 and a select group of trimeric synthetic analogues were evaluated. The results suggest that (a) noncovalent interactions between this series of compounds and DNA do not lead to the formation of complexes stable enough to be detected by footprinting methods, (b) sequence specificity and alkylation intensity can be modulated by the substituents on the nonreactive middle and right-hand segments, and (c) biological potency correlates well with ability to alkylate DNA. In addition, the extent and the sequence specificity of covalent adduct formation between linear DNA fragments and three analogues comprised of the CC-1065 alkylating subunit linked to zero (analogue A), one (analogue AB), or two (analogue ABC) nonreactive indole subunits were compared.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pairs of fluorescent dyes as probes of DNA and chromosomes.

If two fluorescent dyes with different binding or fluorescence specificities are used simultaneously to stain DNA or chromosomes, the ratio of their fluorescent signals can provide information about base composition or base analogue substitution. Energy transfer between such dye pairs, possible if the fluorescence spectrum of one overlaps the absorption spectrum of the other, can modify observed fluorescence. Microfluorometric measurements were used to document the occurrence of energy transfer between quinacrine or 33258 Hoechst as energy donor and ethidium or 7-aminoactinomycin D as acceptor when used jointly to stain cytologic preparations of human metaphase chromosomes. Use of 7-aminoactinomycin D, a dye with G-C binding specificity, as energy acceptor permitted the identification of human chromosome regions presumptively enriched for clusters of A-T base pairs, based on the resistance of A-T specific fluorescence, from quinacrine or 33258 Hoechst, to energy transfer dependent quenching. The results provide information about basic structural features of metaphase chromosomes, and the associated methodology may prove useful in accentuating specific fluorescent polymorphic chromosome regions.     

Comparison of the sequence specificity of bleomycin cleavage in two slightly different DNA sequences.

The sequence specificity of bleomycin damage was investigated utilising 340 bp alpha-DNA (a middle repetitive sequence in the human genome) as a target sequence. The following significant facts were found:- i) The dinucleotides GT and GC were cleaved on all occasions, GA most of the time, and AT, AC, GG and AA cleaved some of the time; ii) The base immediately 5' to the purine-pyrimidine dinucleotides was found to be statistically highly significant in determining the degree of damage caused by bleomycin, while other nearest neighbour bases had no significant effect; iii) The sequence specificity of bleomycin damage was determined on both strands and it was found that damage on either strand follows the above dinucleotide preference and is independent of the extent of damage on the opposite strand; iv) Bleomycin damage was compared between genomic 340 bp alpha-DNA and a cloned alpha-DNA with eleven base substitutions relative to the "consensus" sequence. There were forty-nine detectable differences in intensity of damage between these two DNA molecules. Although four of the differences can be directly attributed to changes in base sequence, the remaining differences were not at the base substitution sites. Some of the differences were over fifty base pairs from the nearest base substitution. We propose that the majority of these differences are due to microvariation in the structure of DNA with a slightly different DNA sequence.     

Interaction of unfused tricyclic aromatic cations with DNA: a new class of intercalators

Unfused tricyclic aromatic ring systems 1-6 with one or two cationic side chains have been synthesized and their interactions with DNA and synthetic polymers probed with a variety of techniques. Molecular mechanics calculations indicate that the torsional angle between ring planes in the minimum energy conformation of the tricyclic molecules can range from 0 degree to as high as 50 degrees depending on the type of rings and substituents. Viscometric titrations with linear and supercoiled DNA, linear dichroism, and NMR studies indicated that all compounds with torsional angles of approximately 20 degrees or less bind to DNA by intercalation. The more highly twisted intercalators caused significant perturbation of DNA structure. Unfused intercalators with twist angles of approximately 20 degrees have reduced binding constants, suggesting that they could not form an optimum interaction with the DNA base pairs. Unfused intercalators with twist less than 20 degrees formed strong complexes with DNA. The structures of these unfused intercalators are more analogous to typical groove-binding molecules, and an analysis of their interaction with DNA provides a better understanding of the subtle differences between intercalation and groove-binding modes for aromatic cations. The results indicate that intercalation and groove-binding modes should be viewed as two potential wells on a continuous energy surface. The results also suggest design strategies for intercalators that can optimally complement DNA base pair propeller twist or that can induce bends in DNA at the intercalation site.     

Fluorescent DNA probes for flow cytometry. Considerations and prospects.

Techniques employing base specific deoxyribonucleic acid (DNA)-binding fluorochromes and flow cytometry (FCM) are potentially useful for obtaining information of the compositional features of chromatin or chromosomes of mammalian cells. Fluorescent compounds which form complexes preferentially at the A-T rich regions (i.e., DNA-reactive Hoechst dyes) or the G-C rich regions (i.e., mithramycin, chromomycin, olivomycin) in DNA are available and compatible with current FCM technology as are other compounds (i.e., ethidium bromide, propidium iodide) which show little or no base specificity and bind by intercalation in the double stranded regions of helical DNA. Energy transfer between appropriate DNA-bound dyes is a reflection of the quantity and proximity of regions containing the respective base pair segments. Since extrinsic fluorescent probes provide only a measure of available binding sites or regions unobstructed by chromatin-associated or chromosomal-associated proteins, interpretations of fluorescence measurements need to be substantiated by adequate control measures.     

7-Azido-Actinomycin D: A Photoaffinity Probe of the Sequence Specificity of DNA Binding by Actinomycin D

Abstract

Actinomycin D (ActD) is a DNA-binding antitumor antibiotic that appears to act in vivo by inhibiting RNA polymerase. The mechanism of DNA binding of ActD has attracted much attention because of its strong preference for 5′-dGpdC-3′ sequences. Binding is thought to involve intercalation of the tricyclic aromatic phenoxazone ring into a GC step, with the two equivalent cyclic pentapeptide lactone substituents lying in the minor groove and making hydrogen bond contacts with the 2-amino groups of the nearest neighbor guanines. Recent studies have indicated, however, that binding is also influenced by next-nearest neighboring bases. We have examined this higher order specificity using 7-azido-actinomycin-D as a photoaffinity probe, and DNA sequencing techniques to quantitatively monitor sites of covalent photoaddition. We found that GC doublets were strongly preferred only if the 5′- flanking base was a pyrimidine and the 3′-flanking base was not cytosine. In addition we observed a previously unreported preference for binding at a GG doublet in the sequence 5′- TGGG-3′.     

Frameshift mutagenesis by eucaryotic DNA polymerases in vitro

The frequency and specificity of frameshift errors produced during a single round of in vitro DNA synthesis by DNA polymerases-alpha, -beta, and -gamma (pol-alpha, -beta, and -gamma, respectively) have been determined. DNA polymerase-beta is the least accurate enzyme, producing frameshift errors at an average frequency of one error for each 1,000-3,000 nucleotides polymerized, a frequency similar to its average base substitution accuracy. DNA polymerase-alpha is approximately 10-fold more accurate, producing frameshifts at an average frequency of one error for every 10,000-30,000 nucleotides polymerized, a frequency which is about 2- to 6-fold lower than the average pol-alpha base substitution accuracy. DNA polymerase-gamma is highly accurate, producing on the average less than one frameshift error for every 200,000-400,000 nucleotides polymerized. This represents a more than 10-fold higher fidelity than for base substitutions. Among the collection of sequenced frameshifts produced by DNA polymerases-alpha and beta, both common features and distinct specificities are apparent. These specificities suggest a major role for eucaryotic DNA polymerases in modulating frameshift fidelity. Possible mechanisms for production of frameshifts are discussed in relation to the observed biases. One of these models has been experimentally supported using site-directed mutagenesis to change the primary DNA sequence of the template. Alteration of a pol-beta frameshift hotspot sequence TTTT to CTCT reduced the frequency of pol-beta-dependent minus-one-base errors at this site by more than 30-fold, suggesting that more than 97% of the errors at the TTTT run involve a slippage mechanism.     

para-Substituted N-nitroso-N-oxybenzenamine ammonium salts: a new class of redox-sensitive nitric oxide releasing compounds

N-Nitroso-N-oxybenzenamine ammonium salts with -OMe, -Me, -H, -F, -Cl, -CF3, and -SO2Me substituents at the para position of the phenyl ring constitute a new class of-redox sensitive nitric oxide (NO) releasing compounds. These compounds yield nitric oxide and the corresponding nitrosobenzene derivatives by a spontaneous dissociation mechanism after undergoing a one electron oxidation. Oxidation of these compounds can be achieved through chemical, electrochemical and enzymatic methods. It was observed electrochemically that the amount of NO generated was dependent on the substituent effect and the applied oxidation potential. Electron-withdrawing substituents increase the oxidation potential of the compound. A linear correlation was observed when the peak potentials for the oxidation were graphed versus the Hammett substituent constant. Density functional theory calculations were also performed on this series of compounds. The theoretical oxidation energies of the corresponding anions show a strong linear correlation with the experimental potentials. Furthermore, enzymatic oxidation using horseradish peroxidase showed a similar substituent effect. These results indicate that substitution at the para position of the phenyl ring has a profound effect on the stability, oxidation potential and enzymatic kinetic properties of the compounds. Thus para-substituted N-nitroso-N-oxybenzenamine salts comprise a new class of redox-sensitive nitric oxide releasing agents.     

Exploring the substituent effects on a novel series of C1'-dimethyl-aryl Delta8-tetrahydrocannabinol analogs

The synthesis and characterization of novel C1'-phenyl-substituted Delta(8)-THC analogs were previously reported by our laboratory. Within this small series of compounds, the C1'-dimethyl phenyl group was found to impart 13.5-fold selectivity for the CB2 receptor with a K(i) 0.91 nM. The current study expands on the previous report by evaluating the effects of aromatic ring substitution on CB1 and CB2 receptor subtype binding and selectivity. The ring substituents synthesized in this study include aliphatic, halogen, nitrile, and acetamido functional groups. In addition, the isosteric replacement of the phenyl group by thiophene was evaluated. The anti-glioma activities of selected compounds were evaluated in vitro and compared to the lead compound 2.     

Suppressible and nonsuppressible +1 G-C base pair insertions induced by ICR-170 at the his4 locus in Saccharomyces cerevisiae.

Fifteen independent ICR-170-induced his4 mutations in Saccharomyces cerevisiae were examined by DNA sequence analysis. All of the mutations contained a +1 G-C base pair addition in the HIS4 coding region. Eleven different sites of insertion were identified. Combined with previous DNA sequence data, 21 ICR-170-induced his4 mutations distributed at 16 different sites were analyzed. The insertions were always located in a consecutive run of two or more G-C base pairs, with all base pairs in each run having identical orientation. Long consecutive G-C runs were preferred target sites over short runs. Although some consecutive G-C runs appeared to be preferred target sites over others of identical length, such preference was not due to any particular type of nucleotide pair immediately adjacent to a given target site. In addition, DNA sequence analyses of the his4 mutations provided a basis for examining the mechanism of mRNA sequence recognition by extragenic suppressors of ICR-170-induced mutations. The implications of these results for mechanisms of frameshift suppression are discussed.     

The use of base pair specific DNA binding agents as affinity labels for the study of mammalian chromosomes

The fluorochromes Hoechst 33258 and olivomycin are base pair specific DNA binding agents. The fluorescence enhancement of Hoechst 33258 and olivomycin in the presence of DNA can be directly related to the A-T and G-C content of the interacting DNA respectively. Cytological observations of metaphase chromosomes treated with these two compounds suggest that the fluorescent banding patterns produced are the reverse of one another. —Non-fluorescent base pair specific DNA binding agents have been used as counterstains in chromosome preparations to enhance the contrast of the banding patterns produced by the base specific fluorochromes. The non-fluorescent G-C specific antibiotic actinomycin-D enhanced the resolution of fluorescent bands produced by the A-T specific fluorochrome Hoechst 33258. Similarly the non-fluorescent A-T specific antibiotic netropsin was found to enhance resolution of the bands produced by the G-C specific fluorochrome olivomycin. Netropsin was also found to increase the differential fluorescent enhancement of complexes of olivomycin with DNAs of various base composition in solution. These findings suggest that counterstaining agents act through a base sequence dependent inhibition of subsequent binding by base pair specific fluorochromes.—The base specific DNA binding agents have been used to differentiate different types of constitutive heterochromatin in mammalian species, and to facilitate chromosome identification in somatic cell hybrids.     

Ethidium binding sites on plasmid DNA determined by photoaffinity labeling

Photoaffinity labeling of pBR322 with ethidium monoazide (8-azido-3-amino-5-ethyl-6-phenylphenanthridinium chloride) was used to provide evidence for the sequence specificity of ethidium binding to native DNA. DNA-drug interactions were examined at concentrations of eight covalently bound ethidium drugs per molecule of pBR322 (4363 base pairs). Restriction enzyme cutting was blocked by the covalent binding of a drug molecule at (or near) the enzyme recognition sequence. This phenomenon was observed with all restriction enzymes tested and was not limited to specific regions of the pBR322 molecule. Double-digestion experiments indicated that a drug molecule may bind 2 to 3 base pairs outside the recognition sequence and still block restriction enzyme digestion. Intact plasmid was treated with [3H]ethidium monoazide and digested with restriction enzymes. The amount of covalently-linked ethidium analog was quantitated for different restriction fragments and the G-C content of each fragment was determined from the DNA sequence. In approximately half of the fragments the drug appeared to preferentially bind at a G-C base pair. However, no preference for specific sequences such as 5'-C-G-3' was detected, as had been suggested by previous modeling studies with ethidium bromide. The other fragments were located in specific map regions of the plasmid and did not bind drug with a strict dependence on GC content suggesting that binding specificity may depend on more than one structural feature of the DNA.     

Determination of the spectrum of mutations induced by defined-wavelength solar UVB (313-nm) radiation in mammalian cells by use of a shuttle vector.

Mutations induced by UVB (313-nm) radiation, a wavelength in the region of peak effectiveness for sunlight-induced skin cancer in humans, have been analyzed at the sequence level in simian cells by using a plasmid shuttle vector (pZ189). We find that significant differences exist between the types of mutations induced by this solar wavelength and those induced by nonsolar UVC (254-nm) radiation. Compared with 254-nm radiation, 313-nm radiation induces more deletions and insertions in the region sequenced. In addition, although the types of base substitutions induced by the two wavelengths are broadly similar (in both cases, the majority of changes occur at G-C base pairs and the G-C to A-T transition is predominant), an analysis of the distribution of these base changes within the supF gene following irradiation at 313 nm reveals additional hot spots for mutation not seen after irradiation at 254 nm. These hot spots are shown to arise predominantly at sites of mutations involving multiple base changes, a class of mutations which arises more frequently at the longer solar wavelength. Lastly, we observed that most of the sites at which mutational hot spots arise after both UVC and UVB irradiation of the shuttle vector are also sites at which mutations arise spontaneously. Thus, a common mechanism may be involved in determining the site specificity of mutations, in which the DNA structure may be a more important determinant than the positions of DNA photoproducts.