Photoaddition of 4,6-dimethyltetrahydrobenzoangelicin to thymine in DNA: X-ray studies and experiments with model oligonucleotides

The crystal structures of 4,6-dimethyltetrahydrobenzoangelicin (THBA), a furocoumarin analog, and of its furan-side cis-syn cycloadduct with thymine formed in the photoreaction with DNA, have been determined. The crystal structure of the latter compound contained only one enantiomeric form corresponding to the addition to a 5'-XpT site. Contrary to most psoralen derivatives studied, THBA showed higher photoreactivity toward synthetic oligonucleotides containing that sequence than toward those with the 5'-TpX sequence.     

3,4 AND 4'',5''-PHOTOCYCLOADDUCTS BETWEEN 4''-METHYLANGELICIN AND THYMINE FROM DNA

Abstract— Two C₄-cycloadducts between 4'-methylangelicin and thymine were isolated from the photo-reaction (365 nm) between this furocoumarin and DNA. Their capacity to undergo photoreversion at 254 nm and their spectroscopic and NMR data allowed us to assign furan- and pyrone-side structures, respectively, to these photocompounds. The former adduct has a cis-syn configuration; the latter. which was also isolated from a photoreaction between the furocoumarin and thymine in water-methanol solution, was assigned a cis-anti structure.     

Benzoangelicins: new monofunctional DNA photobinding agents.

4,6-Dimethylbenzoangelicin, obtained by fusing a benzene ring at the furan side of 4,6-dimethylangelicin, was studied in terms of crystal structure and interactions with DNA in both ground and excited states. 4,6-Dimethylbenzoangelicin has a planar structure and forms a molecular complex with DNA, undergoing intercalation inside the double helix. Under UVA irradiation, it photoconjugates covalently with the macromolecule, showing a DNA photobinding rate slightly lower than that of 8-methoxypsoralen, involving however only its 3,4 double bond, i.e. behaving as a pure monofunctional agent. The parameters of dark binding and photobinding were determined, and two C4 cycloadducts with thymine were isolated and characterized.     

MONOFUNCTIONAL3,4-and4',5'-PHOTOCYCLOADDUCTS BETWEEN 4,5'-DIMETHYLANGELICIN and THYMINE

By irradiating (365 nm) an aqueous liquid solution of 4,5'-dimethylangelicin. a monofunctional photosensitizing furocoumarin, in the presence of an excess of thymine, two new compounds, I and II, have been obtained; they do not show fluorescence when observed with Wood's light. The nuclear magnetic resonance data, the marked similarity of UV absorption and fluorescence spectra of these compounds with those of synthetic 3.4-dihydro-4,5'-dimethylangelicin and their capacity to undergo photodissociation (254 nm) yielding the starting thymine and 4,5'-dimethylangelicin in equimolecular amounts, are consistent with C₄-cycloadducts between the 3,4-double bond of the furocoumarin and 5,6-double bond of thymine. Nuclear magnetic resonance data indicate for I and II a head-to-head and a head-to-tail structure, respectively. When irradiation is carried out in the frozen state, two adducts. III and IV, fluorescent at Wood's light, have been obtained other than the two above-mentioned compounds I and II. Compounds III and IV have been identified as 4'.5'-fluorescent adducts between the 4',5'-double bond of the furocoumarin and the 5.6-double bond of thymine; one of them (III) is identical to that formed in the photoreaction between DNA and 4,5'-dimethylangelicin; for this last compound a cis head-to-head structure has been suggested.     

Ferrocenylnaphthalene diimide-based electrochemical detection of methylated gene

Ferrocenylnaphthalene diimide (FND)-based electrochemical hybridization assay was applied to the detection of methylated cytosine of DNA using the products obtained after treatment with bisulfite followed by polymerase chain reaction (PCR), where unmethylated cytosine is converted to thymine and methylated one to cytosine. Twenty-meric DNA probes for the methylated (cytosine) and unmethylated (thymine) types of the part of the promoter region of cyclin D-dependent protein kinase inhibitor, p16, gene (p16^Ink4a) were used to be immobilized on the electrochemical array (ECA) chip. Using 1 μL of 10 ng/μL of methylated sample obtained from the methylation-specific PCR of methylated genome containing 10-times excess of unmethylated one, the methylated PCR sample could be detected by the identical electrochemical signals from the two DNA probes under the settled optimum hybridization conditions.     

STUDIES ON THE PHOTO-C4-CYCLO-ADDITION REACTIONS BETWEEN SKIN-PHOTOSENSITIZING FUROCOUMARINS AND NUCLEIC ACIDS*

Abstract— Among the natural or synthetic furocoumarins (psoralens) a group exists which has interesting biological properties, the best known of which is skin-photosensitization. The mechanism of action has remained unclarified for a long time. Furocoumarins lack photooxidative properties; they act by a mechanism that does not require oxygen and are therefore different from photodynamic substances. Photosensitizing furocoumarins when irradiated at 365 nm react with nucleic acids to give a C₄-cyclo-addition to the 5,6-double bond of the pyrimidine bases engaging their 3,4- or 4‵,5‵-double bond. Differences exist in the behaviour of the various furocoumarins; psoralen reacts equally well with native DNA, with denatured DNA and with RNA, whereas bergapten, xanthotoxin and 8-methylpsoralen at room temperature react to a much greater extent with native DNA than with denatured DNA and with RNA. A temperature effect has also been observed. In the case of native DNA an intercalation, occurring in the dark, of furocoumarins between two adjacent base pairs of the double helix is suggested as the first step in the reaction. The photoreaction is not accompanied by breaks in the polynucleotide chain or by conformational modifications of the macromolecule. A parallelism was observed between the order of activity of the substances of this group for photoreaction with native DNA and for skin-photosensitization. Ehrlich ascites tumor cells lose completely their capacity of transmitting the tumor after irradiation in the presence of psoralen, bergapten and xanthotoxin. By hydrolysis of DNA extracted from Ehrlich ascites tumor cells irradiated in the presence of psoralen a photoadduct between psoralen and thymine was isolated.     

PHOTOCHEMISTRY OF 4-THIOURIDINE AND THYMINE

Abstract— When thymine is irradiated in aqueous solution with monochromatic 334-nm UV radiation in the presence of 4-thiouridine a photoproduct of thymine is formed, as shown by thin-layer chromatography and autoradiography. The quantum yield for the formation of thymine photoproduct (θ=0.017) is greater than that for cytosine photoproduct formation (θ= 0.0015). The identity of the photoproduct is not known: one possibility is the formation of an adduct between the sensitizer and the base yielding a pyrimidine-pyrimidone type of photoproduct.     

核酸水解产物嘌呤、嘧啶碱基在BDS柱上的分离及测定

 用高效液相色谱法测定了核酸水解的中间产物及最终产物 6种嘌呤、嘧啶碱基 ,探讨了色谱柱、流动相等对其分离的影响 ,确定了最佳色谱条件为 :HypersilBDS C18柱 ,乙腈 0 1mol/LKH2 PO4 (H3 PO4 调节 pH至4 0 5 ) (体积比为 2∶98)作流动相 ,紫外检测器在 2 6 0nm波长下检测。方法的精密度在 3%以内 ,回收率在 82 %～ 114%。方法应用于酵母核酸样品的测定中 ,取得了很好的结果。     

Optimum geometries and relative energies for cytosine,thymine, uracil,the imino tautomer of cytosine,the enol tautomer of thymine,and the enol tautomer of uracil by the MINDO/2 SCF MO method

A MINDO /2 SCF MO geometry optimization of cytosine (C), thymine (T), uracil (U), the imino tautomer of cytosine (C*), the enol tautomer of thymine (T*), and the enol tautomer of uracil (U*)was made. The optimized geometries for cytosine, thymine, and uracil agree well with crystallographic data. The optimized geometries for the tautomers show the correct trends in bond lengthening and bond angle except for the C4—O4 length and C4—O4—H angle of T* and U*. The energies of tautomerization were found to be 10.3, ?9.0, and ?14.2 kcal/mol for C?C*, T?T*, and U?U*, respectively, when optimized geometries are used. The overestimation of the C4—O4—H angle is speculated to arise because of an inadequacy in the parametrization of the one-center integrals in MINDO /2.     

INFLUENCE OF pH AND OXYGEN ON 315 mμ INACTIVATION AND THYMINE DIMERIZATION IN MUTANTS OF BACTERIOPHAGE T4

Abstract— 1. Irradiation with 315 mμ light inactivates phage T4v-x C, and T4v^-x- , and forms thymine dimers in their DNA.
2. Both the rates of inactivation and of thymine dimerization depend upon pH and gaseous environment during irradiation. The U.V. sensitivities are: 1 (pH 7, N₂, 03, 2.2 (pH 3.5, Oz), 3.3 (pH 3–5, N₂; and the corresponding rates of thymine dimerization 1: 2.5: 5.2. The number of thymine dimers per lethal hit observed withT4v-x + are: 5.7 (pH 7, N₂, O₂, 5.4 (pH 3.5, O₂, 10.9 (pH 3.5, N₂); and forT4v-x-: 4.6, 3.4, and 7.1 with the same sequence of conditions.
3. Also the photoreactivable sectors depend upon the environmental conditions at 315 mp inactivation. In T4v-x f this sector amounts to about 50 per cent at pH 7, 18 per cent at pH 3.5, O., and 29 per cent at pH 3.5, N, respectively.
4. The molecular basis of these findings is discussed. It is concluded that, besides thymine dimer, at least one other lethal photoproduct (probably a photoproduct of cytosine) is involved in photoreactivation.     

Investigation of proton transport tautomerism in clusters of protonated nucleic acid bases (cytosine, uracil, thymine, and adenine) and ammonia by high-pressure mass spectrometry and ab initio calculations

The energetics of the ion-molecule interactions and structures of the clusters formed between protonated nucleic acid bases (cytosine, uracil, thymine, and adenine) and ammonia have been studied by pulsed ionization high-pressure mass spectrometry (HPMS) and ab initio calculations. For protonated cytosine, uracil, thymine, and adenine with ammonia, the measured enthalpies of association with ammonia are -21.7, -27.9, -22.1, and -17.5 kcal mol-1, respectively. Different isomers of the neutral and protonated nucleic acid bases as well as their clusters with ammonia have been investigated at the B3LYP/6-31+G(d,p) level of theory, and the corresponding binding energetics have also been obtained. The potential energy surfaces for proton transfer and interconversion of the clusters of protonated thymine and uracil with ammonia have been constructed. For cytosine, the experimental binding energy is in agreement with the computed binding energy for the most stable isomer, CN01-01, which is derived from the enol form of protonated cytosine, CH01, and ammonia. Although adenine has a proton affinity similar to that of cytosine, the binding energy of protonated adenine to ammonia is much lower than that for protonated cytosine. This is shown to be due to the differing types of hydrogen bonds being formed. Similarly, although uracil and thymine have similar structures and proton affinities, the binding energies between the protonated species and ammonia are different. Strikingly, the addition of a single methyl group, in going from uracil to thymine, results in a significant structural change for the most stable isomers, UN01-01 and TN03-01, respectively. This then leads to the difference in their measured binding energies with ammonia. Because thymine is found only in DNA while uracil is found in RNA, this provides some potential insight into the difference between uracil and thymine, especially their interactions with other molecules.     

On the Formation of Cyclobutane Pyrimidine Dimers in UV‐irradiated DNA: Why are Thymines More Reactive?¶

The reaction pathways for thermal and photochemical formation of cyclobutane pyrimidine dimers in DNA are explored using density functional theory techniques. Although it is found that the thermal [2 + 2] cycloadditions of thymine + thymine (T + T --> T x T), cytosine + cytosine (C + C --> C x C) and cytosine + thymine (C + T --> C x T) all are similarly unfavorable in terms of energy barriers and reaction energies, the excited-state energy curves associated with the corresponding photochemical cycloadditions display differences that--in line with experimental findings--unanimously point to the predominance of T x T in UV-irradiated DNA. It is shown that the photocycloaddition of thymines is facilitated by the fact that the S1 state of the corresponding reactant complex lies comparatively high in energy. Moreover, at a nuclear configuration coinciding with the ground-state transition structure, the excited-state energy curve displays an absolute minimum only for the T + T system. Finally, the T + T system is also associated with the most favorable excited-state energy barriers and has the smallest S2-S0 energy gap at the ground-state transition structure.     

Far-UV-lnduced Dimeric Photoproducts in Short Oligonucleotides: Sequence Effects

Cyclobutane pyrimidine dimers and pyrimidine(6-4)pyrimidone adducts represent the two major classes of far-UV-induced DNA photoproducts. Because of the lack of appropriate detection methods for each individual photoproduct, little is known about the effect of the sequence on their formation. In the present work, the photoproduct distribution obtained upon exposure of a series of dinucleoside monophosphates to 254 nm light was determined. In the latter model compounds, the presence of a cytosine, located at either the 5′- or the 3′- side of a thymine moiety, led to the preferential formation of (6-4) adducts, whereas the cis-syn cyclobutane dimer was the main thymine-thymine photoproduct. In contrast, the yield of dimeric photoproducts, and particularly of (6-4) photoadducts, was very low upon irradiation of the cytosine–cytosine dinucleoside monophosphate. However, substitution of cytosine by uracil led to an increase in the yield of (6-4) photoproduct. It was also shown that the presence of a phosphate group at the 5′- end of a thymine-thymine dinucleoside monophosphate does not modify the photoproduct distribution. As an extension of the studies on dinucleoside monophosphates, the trinucleotide TpdCpT was used as a more relevant DNA model. The yields of formation of the thymine-cytosine and cytosine–thymine (6-4) photoproducts were in a 5:1 ratio, very close to the value obtained upon photolysis of the related dinucleoside monophosphates. The characterization of the two TpdCpT (6-4) adducts was based on H NMR, UV and mass spectroscopy analyses. Additional evidence for the structures was inferred from the analysis of the enzymatic digestion products of the (6-4) adducts of TpdCpT with phosphodiesterases. The latter enzymes were shown to induce the quantitative release of the photoproduct as a modified dinucleoside monophosphate in a highly sequence-specific manner.     

PHOTOADDUCTS OF 8-METHOXYPSORALEN TO CYTOSINE IN DNA

Abstract— The isolation and partial characterization of several photoadducts formed between 8-methoxypsoralen (8-MOP) and cytosine is described. The formation of these adducts was analysed in E. coli DNA containing ³H-labeled cytosine and/or ¹⁴C-labeled thymine, and in oligonucleotides of defined sequence. The major initial adduct has been identified as an 8-MOP cytosine monoadduct, most likely forming at the pyrone end of the 8-MOP molecule. Further irradiation converts this adduct to several other species, including both cytosine:cytosine and cytosine:thymine diadducts, as well as a number of derivative monoadducts. One isomer of the C:T diadduct appears to undergo a reversible isomerization under the conditions normally used to analyse adduct mixtures by HPLC. The isomerization can cause this adduct to exhibit a retention time on reversed-phase HPLC closely resembling either that of a thymine-thymine crosslink or a thymine monoadduct.     

Synthesis of Janus type nucleoside analogues and their preliminary bioactivity

Novel Janus type nucleoside analogues 1a and 1b were synthesized in seven steps from 2-amino-4,6-dihydroxypyrimidine and 4,6-dihydroxypyrimidine. The base moiety of 1a has one face with a Watson-Crick donor-donor-acceptor (DDA) H-bond array of guanine and the other face with an acceptor-acceptor-donor (AAD) array of cytosine, which might lead to its base pairing with either cytosine or guanine due to the rotating of the glycosyl bond. This property may enable Janus type nucleoside analogues to act as an antiviral compound in a similar way to ribavirin. Both 1a and 1b were screened by a vitro HBV DNA replication inhibition test and indeed 1a showed a great potential with IC(50) = 10 μM and SI = 78.9 for antiviral drug development.     

Photoinduced reductive repair of thymine glycol: implications for excess electron transfer through DNA containing modified bases

Photoinduced reduction of thymine glycol in oligodeoxynucleotides was investigated using either a reduced form of flavin adenine dinucleotide (FADH(-)) as an intermolecular electron donor or covalently linked phenothiazine (PTZ) as an intramolecular electron donor. Intermolecular electron donation from photoexcited flavin (FADH(-)) to free thymidine glycol generated thymidine in high yield, along with a small amount of 6-hydroxy-5,6-dihydrothymidine. In the case of photoreduction of 4-mer long single-stranded oligodeoxynucleotides containing thymine glycol by *FADH(-), the restoration yield of thymine was varied depending on the sequence of oligodeoxynucleotides. Time-resolved spectroscopic study on the photoreduction by laser-excited N,N-dimethylaniline (DMA) suggested elimination of a hydroxyl ion from the radical anion of thymidine glycol with a rate constant of approximately 10(4) s(-1) generates 6-hydroxy-5,6-dihydrothymidine (6-HOT(*)) as a key intermediate, followed by further reduction of 6-HOT(*) to thymidine or 6-hydroxy-5,6-dihydrothymdine (6-HOT). On the other hand, an excess electron injected into double-stranded DNA containing thymine glycol was not trapped at the lesion but was further transported along the duplex. Considering redox properties of the nucleobases and PTZ, competitive excess electron trapping at pyrimidine bases (thymine, T and cytosine, C) which leads to protonation of the radical anion (T(-)(*), C(-)(*)) or rapid back electron transfer to the radical cation of PTZ (PTZ(+)(*)), is presumably faster than elimination of the hydroxyl ion from the radical anion of thymine glycol in DNA.     

Na+, Mg2+, and Zn2+ binding to all tautomers of adenine, cytosine, and thymine and the eight most stable keto/enol tautomers of guanine: a correlated ab initio quantum chemical study

Interactions of adenine, cytosine, guanine, and thymine with Na(+), Mg(2+), and Zn(2+) cations were studied using an approximate resolution of identity correlated second-order MP2 (RI-MP2) method with the TZVPP ([5s3p2d1f/3s2p1d]) basis set. All existing tautomers of adenine, cytosine, and thymine and the eight most stable keto/enol tautomers of guanine were considered. Cations bind mostly in a bidentate manner, and stabilization energies of these complexes are larger than those in the case when cations bind in a unidentate manner. The cation...Y (Y equal to N or O) distances for divalent metals are shorter than those for Na(+) and for Zn(2+) are mostly shorter than the Mg(2+)...Y distance. The intermolecular distances between the cation and the base for complexes containing adenine and cytosine are systematically shorter than those for complexes containing guanine and thymine. Only for cytosine the canonical keto/amino tautomer structure with ions represents the global minimum. For guanine, the metalated canonical form is again the most stable, but its stabilization energy is within less than 5% of the stabilization energies of the two other rare tautomers, which indicates that the canonical form and these two rare tautomers could coexist. The canonical structures of adenine and thymine in the presence of ions are considerably less stable (by more than 10%) than the complexes of the rare tautomers. It can be concluded that the interaction of Na(+), Mg(2+), and Zn(2+) cations with cytosine in the gas phase will not induce the change of the canonical form to the rare tautomeric form. In the case of isolated guanine, the equilibrium of the canonical form with rare tautomers can be found. For isolated adenine and thymine the presence of rare tautomers is highly probable.     

Electrochemical detection of DNA methylation using a glassy carbon electrode modified with a composite made from carbon nanotubes and β-cyclodextrin

We describe a method for detecting DNA methylation. It is based on direct oxidation of DNA bases at a glassy carbon electrode (GCE) modified with film of a multiwalled carbon nanotube-β-cyclodextrin composite. This nano-structured film causes a strong enhancement on the oxidation current of DNA bases due to its large effective surface area and extraordinary electronic properties. Well-defined peaks were obtained as a result of electro-oxidation of guanine (at 0.67 V), adenine (at 0.92 V), thymine (at 1.11 V), cytosine (at 1.26 V), and 5-methylcytosine (at 1.13 V; all data vs. saturated calomel electrode (SCE)). The potential difference between 5-methylcytosine and cytosine (130 mV) is large enough to enable reliable simultaneous determination and analysis. The interference by thymine can be eliminated by following the principle of complementary pairing between purine and pyrimidine bases in DNA. The modified electrode was successfully applied to the evaluation of 5-methylcytosine in a fish sperm DNA, the methylation level of cytosine was found to be 7.47 %, and the analysis process took less than 1 h.     

Structural basis for bifunctional zinc(II) macrocyclic complex recognition of thymine bulges in DNA

The zinc(II) complex of 1-(4-quinoylyl)methyl-1,4,7,10-tetraazacyclododecane (cy4q) binds selectively to thymine bulges in DNA and to a uracil bulge in RNA. Binding constants are in the low-micromolar range for thymine bulges in the stems of hairpins, for a thymine bulge in a DNA duplex, and for a uracil bulge in an RNA hairpin. Binding studies of Zn(cy4q) to a series of hairpins containing thymine bulges with different flanking bases showed that the complex had a moderate selectivity for thymine bulges with neighboring purines. The dissociation constants of the most strongly bound Zn(cy4q)-DNA thymine bulge adducts were 100-fold tighter than similar sequences with fully complementary stems or than bulges containing cytosine, guanine, or adenine. In order to probe the role of the pendent group, three additional zinc(II) complexes containing 1,4,7,10-tetraazacyclododecane (cyclen) with aromatic pendent groups were studied for binding to DNA including 1-(2-quinolyl)methyl-1,4,7,10-tetraazacyclododecane (cy2q), 1-(4-biphenyl)methyl-1,4,7,10-tetraazacyclododecane (cybp), and 5-(1,4,7,10-tetraazacyclododecan-1-ylsulfonyl)-N,N-dimethylnaphthalen-1-amine (dsc). The Zn(cybp) complex binds with moderate affinity but little selectivity to DNA hairpins with thymine bulges and to DNA lacking bulges. Similarly, Zn(dsc) binds weakly both to thymine bulges and hairpins with fully complementary stems. The zinc(II) complex of cy2q has the 2-quinolyl moiety bound to the Zn(II) center, as shown by (1)H NMR spectroscopy and pH-potentiometric titrations. As a consequence, only weak (500 μM) binding is observed to DNA with no appreciable selectivity. An NMR structure of a thymine-bulge-containing hairpin shows that the thymine is extrahelical but rotated toward the major groove. NMR data for Zn(cy4q) bound to DNA containing a thymine bulge is consistent with binding of the zinc(II) complex to the thymine N3(-) and stacking of the quinoline on top of the thymine. The thymine-bulge bound zinc(II) complex is pointed into the major groove, and there are interactions with the guanine positioned 5' to the thymine bulge.     

Precise recognition of nucleotides and their derivatives through hydrogen bonding in water by poly(vinyldiaminotriazine)

In water, poly(2-vinyl-4,6-diamino-1,3,5-triazine)(PVDAT) selectively binds the derivatives of thymine and uracil through the formation of three hydrogen bonds with the diaminotriazine (DAT) residues. The nucleotides and dinucleotides are bound much more strongly than are nucleic acid bases, due to the additional interactions of their phosphates with the DAT residues. The binding constant of the thymidine 5′-monophosphate-PVDAT adduct (5400 M^-1) is one of the largest values ever reported for the artificial receptors in protic solvents. In contrast, cytosine and its monophosphate are hardly bound to PVDAT. A water-soluble vinyldiaminotriazine–acrylamide copolymer also forms hydrogen bonds with thymine in water, whereas the corresponding monomers do not. A polymer effect is predominantly important for the molecular recognition through hydrogen bonding in water.