Studies on the DNA binding and cleavage activity of a synthesized polyamide containing dipeptide Ser-His

The DNA binding and cleavage activity of a synthetic polyamide containing dipeptide Ser-His has been investigated by spectroscopic techniques, such as electronic absorbance and circular dichroism (CD) spectropolarimetry, as well as gel electrophoresis. The results show that the molecule has a strong interaction with DNA and can improve DNA-cleavage ability about 100 fold as compared with single dipeptide Ser-His.     

DNA-binding Studies of Daunorubicin in the Presence of Methylene Blue by Spectroscopy and Voltammetry Techniques

The interaction of daunorubicin with calf thymus DNA has been investigated with the use of methylene blue dye as a spectral probe by the application of UV-Vis spectrophotometry, spectrofluorometry and voltammetry. The voltammetric behavior of daunorubicin has been investigated at a glassy carbon electrode using cyclic and differential pulse voltammetry. Both UV-vis spectrophotometry and cyclic voltammetry studies confirmed the intercalation reaction. The results showed that both daunorubicin and methylene blue molecules could intercalate into the double helix of DNA. The apparent binding constant of daunorubicin with DNA has been found to be 7.8 ×104 L•mol－1. The fluorescence signal of daunorubicin and methylene blue was quenched with DNA addition. The Stern-Volmer equation was plotted based on the quenching fluorescence signal of daunorubicin.     

Interactions between meso-tetrakis(4-(N-methylpyridiumyl))porphyrin TMPyP4 and DNA G-quadruplex of telomeric repeated sequence TTAGGG

The binding properties between meso-tetrakis(4-(N-methylpyridiumyl))porphyrin (TMPyP4) and the parallel DNA G-quadruplex (G4) of telomeric repeated sequence 5′-TTAGGG-3′ have been characterized by means of circular dichroism,steady-state absorption,steady-state fluorescence and picosecond time-resolved fluorescence spectroscopies. The binding constant and the saturated binding number were determined as 1.29×106 (mol/L)-1 and 3,respectively,according to steady-state absorption spec-troscopy. Based on the findings by the use of time-resolved fluorescence spectroscopic technique,it is deduced that TMPyP4 binds to a DNA G-quadruplex with both the thread-intercalating and end-stacking modes and at the saturated binding state,one TMPyP4 molecule intercalates into the intervals of G-tetrads while the other two stack to the ends of the DNA G-quadruplex.     

DNA structure, binding mechanism and biology functions of polypyridyl complexes in biomedicine

There is considerable research interest and vigorous debate about the DNA binding of polypyridyl complexes including the electron transfer involving DNA. In this review, based on the fluorescence quenching experiments, it was proposed that DNA might serve as a conductor. From the time-interval CD spectra, the different binding rates of A- and A-enantiomer to calf thymus DNA were observed. The factors influencing the DNA-binding of polypyridyl complexes, and the potential bio-functions of the complexes are also discussed.     

Preliminary Screening of Non-platinum Complexes of Schiff Bases as Antitumour Agents Using Fluorimetry

Based on the consistency of the in vivo and in vitro interactions of drugs with DNA, a fluorimetric method has been developed as a new in vitro method for preliminary screening of antitumour agents. This method was tested using Schiff bases synthesized from salicylaldehyde with 1-alanine, 1-asparagine and 1-histidine, and complexes of these Schiff bases with Cu(Ⅱ), Zn(Ⅱ), Ni(Ⅱ) and Sn(Ⅳ) as potential antitumour agents.The study of the interaction of the complexes with DNA by a fluorescence probe ethidium bromide (EthBr)-DNA system indicated the parallelism between the binding constants and antineoplastic ratios. The relationship between structure and antitumonr activity was investigated.     

Study on the Binding Effect between Cordycepin and Calf Thymus DNA by Circular Dichroism

DNA works as hereditary material and plays vital role in life science. The study of the binding of small molecules complex to DNA has been the focus of intense investigation, owning to their stereo and sequence specific interaction with the double helix1-…     

Endonuclease-based Method for Detecting the Sequence Specific DNA Binding Protein on Double-stranded DNA Microarray

The double-stranded DNA (dsDNA) probe contains two different protein binding sites. One is for DNA- binding proteins to be detected and the other is for a DNA restriction enzyme. The two sites were arranged together with no base interval. The working principle of the capturing dsDNA probe is described as follows: the capturing probe can be cut with the DNA restriction enzyme (such as EcoR I) to cause a sticky terminal, if the probe is not bound with a target protein, and the sticky terminal can be extended and labeled with Cy3-dUTP by DNA polymerase. When the probe is bound with a target protein, the probe is not capable to be cut by the restriction enzyme because of space obstruction. The amount of the target DNA binding proteins can be measured according to the variations of fluorescent signals of the corresponding probes.     

Spectrofluorometry of Ions and Small Molecules Based on Conformational Changes of Specific Oligonucleotides with o-Phthalaldehyde-β-mercaptoethanol

Specific oligonucleotides such as telomere DNA and aptamer often undergo conformational changes upon ligand binding. Composite reagent composed of o-phthalaldehyde and β-mercaptoethanol(OPAME) has been extensively applied to fluorescent detection of amino compounds based on the reaction of primary amino-group, herein we proposed a general spectrofluorometry for ions and small molecules due to conformational changes upon ligand binding taking K+ and ATP as examples. In a borate controlled buffer medium, telomere DNA could react with OPAME, giving a thio-subtituted isoindole compound with strong fluorescence emission at 455 nm when excited at 340 nm. It was found that however, the fluorescence emission was greatly reduced in the presence of K+ since the formation of the quadruplex structure inhibits the reaction activity of amino-groups of telomere DNA. In order to testify the general application of OPAME reagent based on the conformational change of oligonucleotides, we further proposed a sensitive method of ATP based on its highly selective interaction with ATP-aptamer. The above mentioned applications show that the spectrofluorometry with the aid of OPAME reagent is simple, label free that is expected to be potentially general for DNA conformational change-based target detection.     

Microdialysis-liquid chromatographic study on competitive binding of drugs to protein

A new method to determine the interaction between drug and protein has been developed by utilizing the technique of microdialysis sampling with the ketoprofen and the human serum albumin (HSA) as the model of drug and protein.Two kinds of binding sites of HSA to ketoprofen have been observed.The binding constants and number of binding sites obtained by the Scatchard equation are 0.799,3.18×106 mol-1 L and 2.15,2.01×105 mol-1 L,respectively The displacement binding of drugs to HSA has also been studied.The strong displacement of competitive binding of ibuprofen with ketoprofen to HSA was observed,which means that the primary binding site of HSA to ketoprofen and that to ibuprofen are the same.However,only a weaker displacement of warfarin for the association of ketoprofen with HSA was observed,which may suggest that the primary binding site of HSA to ketoprofen is different from that to warfarin.Such a displacement effect for competitive binding of drugs to HSA was explained by the displacement model i     

A Novel Toxicological Evaluation of TiO2 Nanoparticles on DNA Structure0

TiO2 has been tested to be toxic to DNA under the photo-irradiation of ultraviolet A （UVA）. However, in the dark conditions, after several days of treatment with TiO2 in aqueous solution, the interaction between TiO2 and two types of DNA was detected and the mechanisms were studied by the methods of gel-electrophoresis, IR spectroscopy and TEM. The results showed that the DNA would be bound to TiO2; the ratio of binding was related to the concentration and the treating time; the mechanism of binding is related to phosphate groups of DNA. Besides, DNA with different structure showed different degree of binding. These findings showed a new possible way through which the TiO2 nanoparticles interact with DNA.     

诺氟沙星-DNA复合物的分子动力学模拟

采用分子模建的方法构建了诺氟沙星-DNA复合物的初始结构, 通过2 ns的分子动力学(MD)模拟研究表明: 诺氟沙星能够和双螺旋d[ATATCGATAT]₂形成稳定的复合物, 药物分子可紧密结合在DNA的小沟区域, 并且能够与DNA的鸟嘌呤碱基形成两个稳定的氢键. 在分子水平上提供了诺氟沙星直接与双螺旋DNA相互作用的结构及复合物的动态变化情况.     

Affinity labeling of a single guanine bulge

We have developed a conceptually new method for the selective labeling of duplex DNA containing a guanine bulge with a masked form of fluorescent 2-amino-1,8-naphthyridine. A naphthyridine derivative 2 tethering DNA-alkylating epoxide was synthesized from (S)-epichlorohydrin and naphthyridine derivative 1, which selectively binds to the guanine bulge duplex. HPLC analysis of the labeling reaction of bulge duplex d(GTT GTGTTG GA)/d(CAA CA A ACC T) (TGT/A_A) with 2 showed a formation of 2-TGT adduct for the guanine bulge. The reaction proceeded for the guanine bulge and a reduced efficiency for the cytosine bulge, but not at all for adenine and thymine bulges. The site of covalent bond formation in 2-TGT was unambiguously identified at the guanine two bases away from the bulge by the use of MALDI-TOF MS analysis of the oligomer fragments produced by strand scission. The labeling reaction was also observed for the guanine bulge flanking two G-C base pairs (CGC/G_G), producing a 2:1 adduct (2.2-CGC). Upon hydrolysis of 2-TGT and 2.2-CGC with concentrated hydrogen chloride, a release of fluorescent 2-aminonaphthyridine from the adduct was clearly detected, verifying a concept of an affinity labeling of the guanine bulge with a masked fluorescent chromophore. The affinity labeling targeting of the guanine bulge is a conceptually novel method for the postsynthetic labeling of DNA. Hybridization, to the target sequence, of a probe DNA possessing one extra guanine especially between two cytosines provides a unique site for the labeling by masked fluorophore 2. The technique may have broad application in genetic typing without using a conventional synthesis of fluorescent-labeled DNA oligomers.     

Bulged Guanine is Uniquely Sensitive to Damage Caused by Visible‐Light Irradiation of Ethidium Bound to DNA: A Possible Role in Mutagenesis

The interaction of ethidium bromide (=3,8‐diamino‐5‐ethyl‐6‐phenylphenanthridinium bromide; EB) with a series of duplex DNA oligomers having single‐base bulges and single‐base mis‐pairs was investigated (Fig. 1). Physical and spectroscopic analysis reveals no definitive evidence for selective binding of EB at the bulge or mis‐pair. However, irradiation of the bound EB with VIS light leads to lesions in the DNA selectively in the sequence having a bulged guanine. This reaction is attributed to the formation of an exciplex between the lowest excited singlet state of the EB and the bulged guanine. The exciplex is trapped by H₂O, which initiates a sequence of reactions that lead to piperidine‐requiring strand cleavage at this site. Significantly, the damaged bulged guanine is not recognized by E. coli formamidopyrimidine glycosylase (Fpg), which is part of a base‐excision repair system for oxidative damage to DNA. Thus, DNA containing a bulged guanine and having a bound intercalator may be irreparably damaged by exposure to VIS light, even though normal duplex DNA is relatively inert under these conditions.     

Reactivity of ferrocenylcarbodiimide with DNA duplex containing single-mismatched base pairs.

Ferrocenylcarbodiimide (1), which is known to react with a guanine (G) or thymine (T) base of single stranded DNA, was allowed to react with DNA duplex having a single mismatched base pair of G-T, T-T, or T-cytosine (C). Electrophoreograms of the reaction mixture showed that 1 could react with G or T base of the mismatched sites on the DNA duplex. However, 1 also reacted with the G base of the terminal site on the DNA duplex. This showed that 1 can react with an unpaired base or unstable base pair such as a terminal or mismatched base on the DNA duplex. Electrochemical mismatch detection could be achieved after hybridization of the ferrocenylated mismatched DNA duplex with a selected DNA probe-immobilized electrode. These results revealed that 1 has a potentiality of serving as a labeling reagent of mismatched bases on the DNA duplex, which is important in the search for heterozygous single nucleotide polymorphisms (SNPs).     

Observation of a single-stranded DNA/pyrrolobenzodiazepine adduct

Pyrrolobenzodiazepine (PBD) antitumor agents have, to date, only been observed to bind to duplex DNA, apparently requiring a minor groove environment for covalent bond formation between their C11-position and the C2-NH(2) functionality of a guanine base. Using an HPLC/MS assay we have now observed and isolated for the first time PBD adducts with single-stranded DNA fragments. Surprisingly, these adducts could only be formed through dissociation of duplex DNA adducts and not by direct interaction of PBDs with single-stranded DNA. They were sufficiently stable for characterization by MALDI-TOF-MS and remained intact after storing at -20 °C for at least 20 days, although the PBD became detached from the DNA within 7 days if stored at room temperature. Furthermore, addition of a complementary strand allowed the duplex adduct to reform. The relative stability of single-stranded PBD/DNA adducts despite a complete loss of minor groove structure was further confirmed by CD spectroscopic analysis. The CD signal induced by the presence of a PBD molecule in the single-stranded adducts remained prominent despite heating for 2 h at 50-60 °C, thus indicating their relatively robust nature.     

The effect of varied ion distributions on long-range DNA charge transport

Long-range oxidative damage to DNA was utilized as a probe to delineate the effects of different ion distributions on DNA charge transport. DNA assemblies were constructed, containing a tethered rhodium intercalating photooxidant, spatially separated from two 5'-GG-3' sites of oxidative damage, with either an A6-tract or a mixed DNA sequence intervening between the guanine doublets; the extent of charge transport was assessed through measurements of the ratio of yields of damage at the guanine doublet distal versus that proximal to the metal binding site. The distal/proximal damage ratios were compared after photooxidation of otherwise identical Rh-tethered assemblies, except for 32P-labeling either at the 5'- or 3'-end; this labeling difference corresponds, in the absence of charge neutralization by condensed counterions, to a shift in negative charge from one end of the duplex to the other. Both with assemblies containing the mixed sequence and the A6-tract, we observed that moving the negative charges to the proximal end of the duplex significantly decreased hole transport to the distal end. We propose that these results reflect variations in the thermodynamic potential at the proximal and distal guanine sites because of the change in charges at the termini of the oligomer. High values for the internal dielectric constant of the stacked base pairs are suggested by these data. Hence, the longitudinal polarizability of DNA may be important to consider in mechanisms for long-range DNA charge transport.     

Electrochemical study of thymine dimer based on DNA charge transfer

Differential pulse voltammetry was used to study the formation and level of thymine dimer in DNA duplex modified on a gold electrode. The electrochemical signal of methylene blue coupled with ferricyanide can be obtained via DNA mediated electron transfer, which would be blocked during the formation of thymine dimer. DNA duplexes with different sequences differ in the level of thymine dimer under the same UV irradiation. Futhermore, the presence of guanine base directly preceding -TT- can effectively decrease the level of thymine dimer, possibly due to the self-repair process in which guanine participates. The proposed method can be further applied to DNA self-repair analysis.     

Inter- and intrastrand DNA crosslinks by 2-fluoro-substituted pyrrolobenzodiazepine dimers: stability, stereochemistry and drug orientation

A 2-fluoro-substituted pyrrolo[2,1-c][1,4]benzodiazepine (PBD) dimer with a 1,4-di-n-propyl piperazine linker was studied with respect to its binding and crosslinking capability towards double-helical DNA targets. Duplex thermal stabilizations upon drug binding as measured by UV melting experiments suggest that two guanine bases separated by four AT base pairs constitute the favorable binding site for the PBD dimer. Large stabilizations were observed for the self-complementary duplex d(AACAATTGTT)(2) as well as for the non-self-complementary duplex d(AAGAATTGTT)·d(AACAATTCTT) with both guanines located on the same strand. Formation of interstrand and intrastrand crosslinks by the covalent binding of both PBD moieties of the dimer to the exocyclic 2-amino group of the two guanine bases within the duplex minor groove was confirmed by NMR structural studies. In both the symmetric and non-symmetric DNA-PBD adducts the newly created stereogenic center at C11 of the tricyclic PBD subunits favors an S configuration. Different orientations of the PBD aromatic A-ring with respect to the covalently modified guanine as observed in the non-symmetric complex are shown to result in characteristic changes of PBD H11 and H11a proton chemical shifts. Based on a compilation of available NMR data on various PBD complexes, these differences may be used as valuable probes for the identification of PBD orientational preferences in DNA-PBD adducts.     

Charge separation in a ruthenium-quencher conjugate bound to DNA

A novel tris heteroleptic dipyridophenazine complex of ruthenium(II), [{Ru(phen)(dppz)(bpy'-his)}{Ru(NH3)5}]5+, containing a covalently tethered ruthenium pentammine quencher coordinated through a bridging histidine has been synthesized and characterized spectroscopically and biochemically in a DNA environment and in organic solvent. Steady-state and time-resolved luminescence measurements indicate that the tethered Ru complex is quenched relative to the parent complexes [Ru(phen)(dppz)(bpy')]2+ and [Ru(phen)(dppz)(bpy'-his)]2+ in DNA and acetonitrile, consistent with intramolecular photoinduced electron transfer. Intercalated into guanine-containing DNA, [{Ru(phen)(dppz)(bpy'-his)}{Ru(NH3)5}]5+, upon excitation and intramolecular quenching, is capable of injecting charge into the duplex based upon the EPR detection of guanine radicals. DNA-mediated charge transport is also indicated using a kinetically fast cyclopropylamine-substituted base as an electron hole trap. Guanine damage is not observed, however, in measurements using the guanine radical as the kinetically slower hole trap, indicating that back electron-transfer reactions are competitive with guanine oxidation. Moreover, transient absorption measurements reveal a novel photophysical reaction pathway for [{Ru(phen)(dppz)(bpy'-his)}{Ru(NH3)5}]5+ in the presence of DNA that is competitive with the intramolecular flash-quench process. These results illustrate the remarkably rich redox chemistry that can occur within a bimolecular ruthenium complex intercalated in duplex DNA.