Radiation induced DNA strand breaks measured by a modified method of gel scanning

Gel electrophoresis is an effective method for assaying plasmid DNA fractions, and UV lights with long wavelengths such as 315 nm is used to image the gel. In the present work, the sensitivities of detecting the fluorescence emitted from ethidium bromide (EB) stained DNA bands in the gel illuminated with UV lights of various wavelengths were compared. It was found that, in the range 245 to 320 nm, shorter excitation wavelength had higher detection sensitivity, thus 260 nm was selected for further studies. With this excitation light, as little as 0.7 ng DNA was detected. The fluorescence of DNA-EB bands had a good linear response to DNA quantity in a wide range. In addition, measured via this modified method, the yield of DNA strand breaks and the second-order rate coefficient of the reaction between DNA and √OH radical were consistent with many previous studies.     

A density functional theory investigation on the formation mechanisms of DNA interstrand crosslinks induced by chloroethylnitrosoureas

Chloroethylnitrosoureas (CENUs) are an important family of alkylating agents used in the clinical treatment of cancer. Their anticancer mechanism primarily involves the formation of DNA interstrand crosslinks (ICLs) induced by the chloroethyldiazonium ion derived from the decomposition of CENUs. In this work, the mechanism for the formation of ICLs was investigated by density functional theory (DFT) with B3LYP, wB97XD, and M062X functinoals using conductor‐like polarizable continuum model solvent model. Three pathways leading to the formation of three types of G–C crosslinks were compared. G(N1)–C(N3) crosslink is predicted to be the dominant crosslinking product other than G(O⁶)–C(N⁴) and G(N²)–C(O²) crosslinks, which is consistent with the previous results obtained from QM/MM computations. The results indicate that the formation of the G(N1)–C(N3) crosslink via pathway A is the most favorable mechanism from both kinetic and thermodynamic standpoints. In this pathway, the chloroethyldiazonium ion alkylates guanine on the O⁶ site followed by intramolecular cyclization to form O⁶,N1‐ethanoguanine ( 4 ). The cytosine then reacts with intermediate 4 on the C^α atom to yield the G(N1)–C(N3) crosslink. This work provides reasonable explanations for the supposed mechanism of CENUs‐induced ICLs formation obtained from experimental investigations. © 2012 Wiley Periodicals, Inc.     

Self-promoted DNA interstrand cross-link formation by an abasic site

The C4'-oxidized abasic site (C4-AP) is produced in DNA as a result of oxidative stress. A recent report suggests that this lesion forms interstrand cross-links. Using duplexes in which C4-AP is produced from a synthetic precursor, we show that the lesion produces interstrand cross-links in which both strands are in tact and cross-links in which the C4-AP containing strand is cleaved. The yields of these products are dependent upon the surrounding nucleotide sequence. When C4-AP is opposed by dA, cross-link formation occurs exclusively with an adjacent dA on the 5'-side. Moreover, formation of the lower molecular weight cross-link is promoted by an opposing adenine. When the opposing dA is replaced by dT, the activity of the adenine can be rescued by adding the free base. This is a rare example in which DNA promotes its own modification, an observation that is all the more important because of the biological significance of the product produced.     

Unique properties of DNA interstrand cross-links of antitumor oxaliplatin and the effect of chirality of the carrier ligand

The different antitumor and other biological effects of the third-generation antitumor platinum drug oxaliplatin [(1R,2R-diamminocyclohexane)oxalatoplatinum(II)] in comparison with those of conventional cisplatin [cis-diamminedichloridoplatinum(II)] are often explained by the ability of oxaliplatin to form DNA adducts of different conformation and consequently to exhibit different cytotoxic effects. This work describes, for the first time, the structural and biochemical characteristics of the interstrand cross-links of oxaliplatin. We find that: 1) DNA bending, unwinding, thermal destabilization, and delocalization of the conformational alteration induced by the cross-link of oxaliplatin are greater than those observed with the cross-link of cisplatin; 2) the affinity of high-mobility-group proteins (which are known to mediate the antitumor activity of platinum complexes) for the interstrand cross-links of oxaliplatin is markedly lower than for those of cisplatin; and 3) the chirality at the carrier 1,2-diaminocyclohexane ligand can affect some important structural properties of the interstrand cross-links of cisplatin analogues. Thus, the information contained in the present work is also useful for a better understanding of how the stereochemistry of the carrier amine ligands of cisplatin analogues can modulate their anticancer and mutagenic properties. The significance of this study is also reinforced by the fact that, in general, interstrand cross-links formed by various compounds of biological significance result in greater cytotoxicity than is expected for monofunctional adducts or other intrastrand DNA lesions. Therefore, we suggest that the unique properties of the interstrand cross-links of oxaliplatin are at least partly responsible for this drug's unique antitumor effects.     

DNA polymerase I-mediated repair of 365 nm-induced single-strand breaks in the DNA of Escherichia coli.

Abstract. Irradiation of closed circular phage Λ DNA in vivo at 365 nm results in the induction of single-strand breaks and alkali-labile lesions at rates of 1.1 × 10^-14, and 0.2 × 10^-14/dalton/J/m², respectively. The sum of the induction rates is similar to the rate of induction of single-strand breaks plus alkali-labile lesions (1 × 10^-14/dalton/J/m²) observed in the E. coli genome. Postirradiation incubation of wild-type cells in buffer results in rapid repair of the breaks (up to 80% repaired in 10 min). No repair was observed in a DNA polymerase I-deficient mutant of E. coli.     

Protection of plasmid pBR322 DNA by flavonoids against single-strand breaks induced by singlet molecular oxygen

Flavonoids, the dominant colouring pigments of plants, as well as the related polyphenol tannic acid significantly inhibit single-strand breaks in plasmid pBR322 DNA induced by singlet molecular oxygen (¹O₂). This reactive species of oxygen was generated in an aqueous buffer system by the thermal dissociation of the endoperoxide of 3,3′-(1,4-naphthylene)dipropionate. Among the antioxidants examined, myricetin showed the highest protective ability, followed by tannic acid, (+) catechin, rutin, fisetin, luteolin and apigenin, when the inhibitory abilities were compared at 90 min after incubation. The protective abilities of these compounds were both time and concentration dependent. At equimolar concentrations (100 μM) the antioxidant effect of myricetin was better than that of other known antioxidants such as lipoate, -tocopherol and β-carotene. Data, when analysed in relation to the structures of various compounds, showed a rough correlation with protective abilities. Owing to the abundance of these compounds in our normal diet, they may play significant roles in preventing oxidative damage resulting from potentially deleterious ¹O₂.     

Oxygen independent DNA interstrand cross-link formation by a nucleotide radical

A 5-(2'-Deoxyuridinyl)methyl radical (1) was independently generated from three photochemical precursors and is the first example of a DNA radical that forms interstrand cross-links. Oxygen labeling experiments support generation of 1 by all precursors. Interstrand cross-links are produced upon irradiation of DNA containing any of the precursors. Cross-linking occurs via reaction with the opposing 2'-deoxyadenosine and is independent of O(2). The independence of cross-link formation on O(2) is explained by kinetic analysis, which shows that the radical reacts reversibly with O(2). Examination of the effects of glutathione on cross-link formation under anaerobic conditions suggests that adoption of the syn-conformation by 1 is the rate-limiting step in the process. Interstrand cross-link formation is reversible in the presence of a good nucleophile. The stability of the interstrand cross-link suggests that the isolated molecule is a rearrangement product of that formed in solution. The rearrangement is a consequence of the isolation procedure but also occurs slowly in solution. Oxygen independent cross-link formation may be useful for the purposeful damage of DNA in hypoxic tumor cells, where O(2) is deficient.     

Characterization of the active site of yeast RNA polymerase II by DFT and ReaxFF calculations

Most known DNA-dependent RNA polymerases (RNAPs) share a universal heptapeptide, called the NADFDGD motif. The crystal structures of RNAPs indicate that in all cases this motif forms a loop with an embedded triad of aspartic acid residues. This conserved loop is the key part of the active site. Based on the crystal structures of the yeast RNAP II, we have studied this common active site for three cases: (1) single RNAP, (2) pre-translocation elongation complex, and (3) post-translocation elongation complex. Here we have applied two different modeling methods, the GGA density functional theory method (PBE) of quantum mechanics (QM) and the ReaxFF reactive force field. The QM calculations indicate that the loop shrinks from pre- to post-translocation and expands from post- to pre- translocation. In addition, PBE MD simulations in the gas phase at 310 K shows that the loop in the single-RNAP case is tightly connected to a catalytic Mg ²⁺ ion and that there is an ordered hydrogen bond network in the loop. The corresponding ReaxFF MD simulation presents a less stable loop structure, suggesting that ReaxFF may underestimate the coordinating interactions between carbonyl oxygen and magnesium ion compared to the gas phase QM. However, with ReaxFF it was practical to study the dynamics for a much more detailed model for the post-translocational case, including the complete loop and solvent. This leads to a plausible reactant-side model that may explain the large difference in efficiency of NTP polymerization between RNA and DNA polymerases.     

Unwinding of DNA polymerases by the antitumor drug,cis-diamminedichloroplatinum(II)

The helix-turn-helix motifs of the DNA binding domains of human polymerase-alpha and polymerase-kappa are dramatically perturbed upon binding to cisplatin with concomitant release of zinc.     

Effects of geometric isomerism and anions on the kinetics and mechanism of the stepwise formation of long-range DNA interstrand cross-links by dinuclear platinum antitumor complexes

Reported herein is a detailed study of the kinetics and mechanism of formation of a 1,4-GG interstrand cross-link by the dinuclear platinum anticancer compound [15N][{cis-PtCl(NH3)2}2{mu-NH2(CH2)6NH2}]2+ (1,1/c,c (1)). The reaction of [15N]1 with 5'-{d(ATATGTACATAT)2} (I) has been studied by [1H,15N] HSQC NMR spectroscopy in the presence of different concentrations of phosphate. In contrast with the geometric trans isomer (1,1/t,t), there was no evidence for an electrostatic preassociation of 1,1/c,c with the polyanionic DNA surface, and the pseudo-first-order rate constant for the aquation of [(15)N]1 was actually slightly higher (rather than lower) than that in the absence of DNA. When phosphate is absent, the overall rate of formation of the cross-link is quite similar for the two geometric isomers, occurring slightly faster for 1,1/t,t. A major difference in the DNA binding pathways is the observation of phosphate-bound intermediates only in the case of 1,1/c,c. 15 mM phosphate causes a dramatic slowing in the overall rate of formation of DNA interstrand cross-links due to both the slow formation and slow closure of the phosphate-bound monofunctional adduct. A comparison of the molecular models of the bifunctional adducts of the two isomers shows that helical distortion is minimal and globally the structures of the 1,4 interstrand cross-links are quite similar. The effect of carrier ligand was investigated by similar studies of the ethylenediamine derivative [15N]1-en. A pKa value of 5.43 was determined for the [15N]1,1/c,c-en diaquated species. The rate of reaction of [15N]1-en with duplex I is similar to that of 1,1/c,c and the overall conformation of the final adduct appears to be similar. The significance of these results to the development of "second-generation" polynuclear platinum clinical candidates based on the 1,1/c,c chelate (dach) series is discussed.     

Single,double, and multiple double strand breaks induced in DNA by 3-100 eV electrons

Nonthermal secondary electrons with initial kinetic energies below 100 eV are an abundant transient species created in irradiated cells and thermalize within picoseconds through successive multiple energy loss events. Here we show that below 15 eV such low-energy electrons induce single (SSB) and double (DSB) strand breaks in plasmid DNA exclusively via formation and decay of molecular resonances involving DNA components (base, sugar, hydration water, etc.). Furthermore, the strand break quantum yields (per incident electron) due to resonances occur with intensities similar to those that appear between 25 and 100 eV electron energy, where nonresonant mechanisms related to excitation/ionizations/dissociations are shown to dominate the yields, although with some contribution from multiple scattering electron energy loss events. We also present the first measurements of the electron energy dependence of multiple double strand breaks (MDSB) induced in DNA by electrons with energies below 100 eV. Unlike the SSB and DSB yields, which remain relatively constant above 25 eV, the MDSB yields show a strong monotonic increase above 30 eV, however with intensities at least 1 order of magnitude smaller than the combined SSB and DSB yields. The observation of MDSB above 30 eV is attributed to strand break clusters (nano-tracks) involving multiple successive interactions of one single electron at sites that are distant in primary sequence along the DNA double strand, but are in close contact; such regions exist in supercoiled DNA (as well as cellular DNA) where the double helix crosses itself or is in close proximity to another part of the same DNA molecule.     

DNA interstrand crosslinks are induced in cells prelabelled with 5-bromo-2'-deoxyuridine and exposed to UVC radiation

It has been observed previously that 5-bromo-2'-deoxyuridine (BrdU) potentiates the effect of UVC radiation on the level of sister chromatid exchanges. It is not known which type of DNA damage is responsible for this enhancing effect and we have proposed this to be the DNA interstrand crosslink (ICL) which, theoretically, may arise in cells that are labelled with BrdU for one round of replication and exposed to UVC radiation. The aim of the present investigation was to verify if ICLs are indeed formed during this irradiation scenario. CHO-K1 cells were prelabelled with BrdU and exposed to UVC. ICLs were detected by a modified version of the comet assay that relies on the reduction of induced DNA migration in the agarose gel. Carboplatin was used as a positive control. We found that BrdU+UVC treatment indeed results in a reduction of the damage induced by gamma-radiation. Furthermore, we observed that CL-V4B cells exposed to BrdU+UVC, but not to UVC alone, showed a very high level of chromosomal damage. These cells have a deficient Rad51C paralog that renders them extremely sensitive towards ICLs. Interestingly, the cytogenetic results did not correlate with cell survival, where it was found that the CL-V4B cells tolerate BrdU+UVC better than the wild type cells. The possible reasons are discussed. Taken together our results indicate that ICLs are formed in DNA that was prelabelled with BrdU and exposed to UVC radiation.     

DNA interstrand cross-link formation initiated by reaction between singlet oxygen and a modified nucleotide

DNA is the target of many anti-cancer therapies. These agents damage the biopolymer by oxidation or by alkylation. Interstrand DNA cross-links are believed to be the source of cytotoxicity of anti-tumor agents, such as mitomycin C, which alkylate the biopolymer. In contrast, deoxyguanosine oxidation is the result of reaction between DNA and singlet oxygen, which is the damaging species produced in photodynamic therapy. We have shown that, upon oxidation by singlet oxygen, an analogue of thymidine (2) rearranges to a methide, which forms DNA-DNA interstrand cross-links. This novel process suggests that 2 may be a useful adjuvant in photodynamic therapy.     

Synthesis and antitumor activity of DNA binding cationic porphyrin-platinum(II) complexes

A new series of DNA binding 5,10,15-tri(N-methyl-4-pyridiniumyl)porphyrin (TrisMPyP)-platinum(II) conjugates was synthesized, in which different spacer ligands were used for appropriate coordination to platinum(II) complexes. Compound 9b exhibited in vivo antitumor activity (T/C%, 294) superior to cisplatin (T/C%, 184) against the leukemia L1210 cell line.     

Reversible DNA condensation induced by a tetranuclear nickel(II) complex

DNA condensing agents play a critical role in gene therapy. A tetranuclear nickel(II) complex, [Ni^II₄(L?2H)(H₂O)₆(CH₃CH₂OH)₂] ? 6NO₃ (L=3,3',5,5'‐tetrakis{[(2‐hydroxyethyl)(pyridin‐2‐ylmethyl)amino]methyl}biphenyl‐4,4'‐diol), has been synthesized as a nonviral vector to induce DNA condensation. X‐ray crystallographic data indicate that the complex crystallizes in the monoclinic system with space group P2₁/n, a=10.291(9), b=24.15(2), c=13.896(11) Å, and β=98.175(13)°. The DNA condensation induced by the complex has been investigated by means of UV/Vis spectroscopy, fluorescence spectroscopy, circular dichroism spectroscopy, dynamic light scattering, atomic force microscopy, gel electrophoresis assay, and zeta potential analysis. The complex interacts strongly with DNA through electrostatic attraction and induces its condensation into globular nanoparticles at low concentration. The release of DNA from its compact state has been achieved using the chelator ethylenediaminetetraacetic acid (EDTA) for the first time. Other essential properties, such as DNA cleavage inactivity and biocompatibility, have also been examined in vitro. In general, the complex satisfies the requirements of a gene vector in all of these respects.     

A theoretical study of the mechanism of the nucleotidyl transfer reaction catalyzed by yeast RNA polymerase II

The mechanism of the nucleotidyl transfer reaction catalyzed by yeast RNA polymerase II has been investigated using molecular mechanics and quantum mechanics methods.Molecular dynamics(MD) simulations were carried out using the TIP3 water model and generalized solvent boundary potential(GSBP) by CHARMM based on the X-ray crystal structure.Two models of the ternary elongation complex were constructed based on CHARMM MD calculations.All the species including reactants,transition states,intermediates,and products were optimized using the DFT-PBE method coupled with the basis set DZVP and the auxiliary basis set GEN-A2.Three pathways were explored using the DFT method.The most favorable reaction pathway involves indirect proton migration from the RNA primer 3’-OH to the oxygen atom of-phosphate via a solvent water molecule,proton rotation from the oxygen atom of-phosphate to the-phosphate side,the RNA primer 3’-O nucleophilic attack on the-phosphorus atom,and P-O bond breakage.The corresponding reaction potential profile was obtained.The rate limiting step,with a barrier height of 21.5 kcal/mol,is the RNA primer 3’-O nucleophilic attack,rather than the commonly considered proton transfer process.A high-resolution crystal structure including crystallographic water molecules is required for further studies.