Lesion-induced DNA weak structural changes detected by pulsed EPR spectroscopy combined with site-directed spin labelling

Double electron-electron resonance (DEER) was applied to determine nanometre spin–spin distances on DNA duplexes that contain selected structural alterations. The present approach to evaluate the structural features of DNA damages is thus related to the interspin distance changes, as well as to the flexibility of the overall structure deduced from the distance distribution. A set of site-directed nitroxide-labelled double-stranded DNA fragments containing defined lesions, namely an 8-oxoguanine, an abasic site or abasic site analogues, a nick, a gap and a bulge structure were prepared and then analysed by the DEER spectroscopic technique. New insights into the application of 4-pulse DEER sequence are also provided, in particular with respect to the spin probes’ positions and the rigidity of selected systems. The lesion-induced conformational changes observed, which were supported by molecular dynamics studies, confirm the results obtained by other, more conventional, spectroscopic techniques. Thus, the experimental approaches described herein provide an efficient method for probing lesion-induced structural changes of nucleic acids.     

DNA compaction by mononuclear platinum cancer drug cisplatin and the trisplatinum anticancer agent BBR3464: Differences and similarities

Cisplatin, a mononuclear platinum compound, which is known as a cancer drug for long time, can exhibit considerable side effects and is also not effective in many types of cancer. Therefore, the alternative platinum anticancer agents that can act at a much lower dose limit compared to the dose relevant for cisplatin treatment have been searched for. BBR3464, a trinuclear platinum compound, is found to exhibit cytotoxic effects at 10 to 1000 times lower dose limit, even in cisplatin-resistant cancer cells. The primary cellular target for cisplatin and BBR3464 is thought to be DNA. Herein, we report the nature of DNA structural changes that are induced by cisplatin and BBR3464, considering the same DNA sequence and similar sample deposition methods for comparison purpose. We have applied high-resolution atomic force microscopy (AFM) in order to obtain an idea about the molecular basis of BBR3464's effectiveness at the lower dose limit. We show from the molecularly resolved AFM images that both the compounds can compact the whole dsDNA molecules, though the degree of compaction in case of BBR3464 treatment is significantly higher. Furthermore, local compaction in terms of loop structure formation could be induced by both BBR3464 and cisplatin, though BBR3464 generated microloops and macroloops both, whereas cisplatin could generate primarily the microloops. It is a significant observation that BBR3464 could induce relatively drastic DNA structural changes in terms of loop formation as well as overall DNA compaction at a molar ratio, which is 50 times less than that applied for cisplatin treatment. Implications of such structural changes in cytotoxic effects of the platinum anticancer agents will be mentioned.     

6-Thioguanine in DNA as CD-spectroscopic probe to study local structural changes upon protein binding

A combination of experimental and theoretical circular dichroism (CD) spectroscopy was used to study local deformations of DNA caused by binding of the base flipping DNA methyltransferase M.TaqI. To selectively study the structural changes within the DNA, we replaced single guanine residues at six different positions in duplex DNA with 6-thioguanine (s(6)G), which absorbs at 342 nm where unmodified DNA and the enzyme are transparent. The shape and the transition wavelength of a CD signal around 340 nm in the spectra of the free DNA and the M.TaqI-bound DNA were found to depend on the position of the s(6)G probe. Theoretical rotational strengths were calculated employing the matrix method which is frequently used to model the CD of large biomolecules. The only chromophores in these calculations were the nucleic acid bases. Comparison of the measured and the calculated CD spectra showed that the applied computational method qualitatively reproduces the dominant band observed around 340 nm in all cases. From our results we conclude that the spectral changes observed upon binding of the enzyme to the DNA are indeed predominantly due to structural changes within the DNA and not to other effects caused by the presence of the enzyme.     

Direct Observation of Single DNA Structural Alterations at Low Forces with Surface-Enhanced Raman Scattering

DNA experiences numerous mechanical events, necessitating single-molecule force spectroscopy techniques to provide insight into DNA mechanics as a whole system. Inherent Brownian motion limits current force spectroscopy methods from observing possible bond level structural changes. We combine optical trapping and surface-enhanced Raman scattering to establish a direct relationship between DNA’s extension and structure in the low force, entropic regime. A DNA molecule is trapped close to a surface-enhanced Raman scattering substrate to facilitate a detectable Raman signal. DNA Raman modes shift in response to applied force, indicating phosphodiester mechanical alterations. Molecular dynamic simulations confirm the local structural alterations and the Raman sensitive band identified experimentally. The combined Raman and force spectroscopy technique, to our knowledge, is a novel methodology that can be generalized to all single-molecule studies.     

Global Changes in DNA Methylation in Seeds and Seedlings of Pyrus communis after Seed Desiccation and Storage

The effects of storage and deep desiccation on structural changes of DNA in orthodox seeds are poorly characterized. In this study we analyzed the 5-methylcytosine (m⁵C) global content of DNA isolated from seeds of common pear (Pyrus communis L.) that had been subjected to extreme desiccation, and the seedlings derived from these seeds. Germination and seedling emergence tests were applied to determine seed viability after their desiccation. In parallel, analysis of the global content of m⁵C in dried seeds and DNA of seedlings obtained from such seeds was performed with a 2D TLC method. Desiccation of fresh seeds to 5.3% moisture content (mc) resulted in a slight reduction of DNA methylation, whereas severe desiccation down to 2–3% mc increased DNA methylation. Strong desiccation of seeds resulted in the subsequent generation of seedlings of shorter height. A 1-year period of seed storage induced a significant increase in the level of DNA methylation in seeds. It is possible that alterations in the m⁵C content of DNA in strongly desiccated pear seeds reflect a reaction of desiccation-tolerant (orthodox) seeds to severe desiccation. Epigenetic changes were observed not only in severely desiccated seeds but also in 3-month old seedlings obtained from these seeds. With regard to seed storage practices, epigenetic assessment could be used by gene banks for early detection of structural changes in the DNA of stored seeds.     

Phenanthroline-Cu(II) cleavage as a probe of rRNA structure

Chemical cleavage is developing into a powerful tool for analysis and characterization of nucleic acids. Phenanthroline-Cu(II) cleavage has been used extensively for studies of DNA for the last two decades, but recently has been applied to structural studies of RNA as well. This approach has been used to study the structure and structural changes occurring in ribosomal RNA within the ribosomes. In this article we discuss the mechanism by which phenanthroline cleaves, the applications possible using this approach, and the results that can be obtained. Protocols for use of phenanthroline are outlined as well.     

Analysis of gamma radiation-induced damage to plasmid DNA using dynamic size-sieving capillary electrophoresis

Bacterial plasmids and the chromosomal DNA of many organisms adopt naturally the negatively supercoiled conformation. Therefore, the irradiation of such plasmids could be used to model conformational changes of chromosomal DNA associated with externally-induced damage. We have applied dynamic size-sieving capillary electrophoresis (CE) to monitor the damage of three DNA plasmids, over an unprecedented base pair (bp) size range (2870–27 500 bp), upon exposure to γ-radiation (20–400 Gy). Predominantly, CE with UV absorbance detection in the absence of DNA intercalating dyes was employed to preclude undesirable, induced plasmid conformational changes. Plasmid samples and their enzymatic digestion products were analyzed using both CE and slab gel electrophoresis (SGE) in order to verify the conformation of sample components. Relative to SGE, CE analyses revealed more fine structural features of plasmid degradation.     

15N labeling of oligodeoxynucleotides for NMR studies of DNA-ligand interactions.

The amino protons of 15N-labeled DNA were studied as a possible structural probe in NMR investigations of the interaction of DNA with various ligands. Since the imino protons are located in the center of the double helix, and variations of their chemical shift values are difficult to interpret in terms of structural changes, these probes are not very useful. Instead, amino protons are located in the major or minor groove of the DNA and are often directly involved in the binding of a ligand. For a selective probing 4-15NH2-2'-deoxycytidine and 6-15NH2-2'-deoxyadenosine were obtained by chemical synthesis. The labeled nucleosides were introduced in distinct positions of oligodeoxynucleotides by large-scale DNA synthesis. Direct 15N NMR and 1H-15N multiple quantum NMR were applied to detect the corresponding 15N labels or protons attached to the 15N labels. Chemical shift values for the cytidine and the adenosine amino nitrogen and proton resonances of a symmetric 18 base pair lac operator sequence are reported.     

Multimodal Measurements of Single-Molecule Dynamics Using FluoRBT

Single-molecule methods provide direct measurements of macromolecular dynamics, but are limited by the number of degrees of freedom that can be followed at one time. High-resolution rotor bead tracking (RBT) measures DNA torque, twist, and extension, and can be used to characterize the structural dynamics of DNA and diverse nucleoprotein complexes. Here, we extend RBT to enable simultaneous monitoring of additional degrees of freedom. Fluorescence-RBT (FluoRBT) combines magnetic tweezers, infrared evanescent scattering, and single-molecule FRET imaging, providing real-time multiparameter measurements of complex molecular processes. We demonstrate the capabilities of FluoRBT by conducting simultaneous measurements of extension and FRET during opening and closing of a DNA hairpin under tension, and by observing simultaneous changes in FRET and torque during a transition between right-handed B-form and left-handed Z-form DNA under controlled supercoiling. We discover unanticipated continuous changes in FRET with applied torque, and also show how FluoRBT can facilitate high-resolution FRET measurements of molecular states, by using a mechanical signal as an independent temporal reference for aligning and averaging noisy fluorescence data. By combining mechanical measurements of global DNA deformations with FRET measurements of local conformational changes, FluoRBT will enable multidimensional investigations of systems ranging from DNA structures to large macromolecular machines.     

Intrinsic Dynamics of Restriction Endonuclease EcoO109I Studied by Molecular Dynamics Simulations and X-Ray Scattering Data Analysis

EcoO109I is a type II restriction endonuclease that functions as a dimer in solution. Upon DNA binding to the enzyme, the two subunits rotate counterclockwise relative to each other, as the two catalytic domains undergo structural changes to capture the cognate DNA. Using a 150-ns molecular dynamics simulation, we investigated the intrinsic dynamics of the DNA-free enzyme in solution to elucidate the relationship between enzyme dynamics and structural changes. The simulation revealed that the enzyme is considerably flexible, and thus exhibits large fluctuations in the radius of gyration. The small-angle x-ray scattering profile calculated from the simulation, including scattering from explicit hydration water, was in agreement with the experimentally observed profile. Principal component analysis revealed that the major dynamics were represented by the open-close and counterclockwise motions: the former is required for the enzyme to access DNA, whereas the latter corresponds to structural changes upon DNA binding. Furthermore, the intrinsic dynamics in the catalytic domains were consistent with motions capturing the cognate DNA. These results indicate that the structure of EcoO109I is intrinsically flexible in the direction of its functional movement, to facilitate effective structural changes for sequence-specific DNA recognition and processing.     

Differential induction of structural changes in the simian virus 40 origin of replication by T antigen.

The ATP-dependent binding of the simian virus 40 (SV40) large tumor antigen (T antigen) to the SV40 origin of replication (ori) results in the structural distortion of two critical elements within flanking regions of ori and the untwisting of the DNA helix. We examined the effect of changes in temperature, ATP concentration, and other reaction parameters on the generation of these DNA structural changes. We found that induction of the two localized structural transitions were highly and differentially sensitive to reaction conditions. Significant distortion of the early palindrome element, shown previously to result from DNA melting, required low levels of ATP (10 to 30 microM) but temperatures above 25 degrees C. Distortion of the AT tract occurred at low temperatures (5 degrees C) but required relatively high concentrations of ATP (greater than 300 microM). Thus, T antigen can induce structural changes within one critical element of ori without generating significant structural distortion within the second element. The response of ori untwisting to reaction conditions generally increased in parallel with or fell intermediate between the inductions of localized structural transitions. We suggest that ori untwisting and localized structural distortions are interdependent consequences of T-antigen binding to ori. These results suggest a model for the structural events occurring during the initial steps of SV40 DNA replication.     

Non-additivity of sequence-specific enzyme-DNA interactions in the EcoRI DNA methyltransferase.

We describe a novel strategy to characterize protein-DNA interactions involving monomeric enzymes such as DNA methyltransferases (Mtases). This strategy is applied to our investigation of the EcoRI DNA Mtase, which binds its double stranded recognition site 5'-G-AATTC-3' and methylates the central adenosine of each strand using S-adenosyl-L-methionine as the methyl donor. We show that prior methylation of adenosine in either strand does not perturb catalysis. In contrast, substrates substituted with deoxyinosine at either guanosine position (T-BMI5 and TI5-BM) show the minor groove residing N2 amino group of both guanosines contribute to DNA recognition since specificity constants for the modified substrates are reduced 13 and 39 fold. Similar analysis of a substrate containing deoxyinosine at both positions (TI5-BMI5) clearly shows that some communication occurs between the sites. To determine the extent to which structural changes in the DNA alone contribute to this lack of additivity, we performed DNA melting analysis of the singly and doubly substituted substrates, and also found non-additivity. Although our functional and structural analyses suggest that deoxyinosine incorporation causes long range conformational effects, the similarity of KmAdoMet for all substrates suggests that no large-scale structural changes occur in the Mtase-DNA-AdoMet complex. Our results support the following conclusions: 1) The non-additivity shown in this system contrasts with the widespread demonstration of additivity involving repressors [Lehming et al., 1990; Takeda et al., 1989; Ebright et al., 1987], suggesting that sequence discrimination by enzymes may involve more complex mechanisms. Further, this non-additivity precludes quantitative assignment of individual interactions and we suggest that future analyses of this and related enzyme systems with base analogs include detailed information about the long range structural consequences of individual substitutions. 2) Although TI5-BM and T-BMI5 are shown to be radically different by thermodynamic analysis, the similar specificity constants with the Mtase suggest that the underlying structural differences (e.g., altered helical parameters of the DNA) are not critical for sequence-recognition. 3) The significance of minor groove Mtase-DNA interactions to specificity is confirmed.     

Nanoscale mechanical and dynamical properties of DNA single molecules

Experimental evidence suggests DNA mechanical properties, in particular intrinsic curvature and flexibility, have a role in many relevant biological processes. Systematic investigations about the origin of DNA curvature and flexibility have been carried out; however, most of the applied experimental techniques need simplifying models to interpret the data, which can affect the results. Progress in the direct visualization of macromolecules allows the analysis of morphological properties and structural changes of DNAs directly from the digitised micrographs of single molecules. In addition, the statistical analysis of a large number of molecules gives information both on the local intrinsic curvature and the flexibility of DNA tracts at nanometric scale in relatively long sequences. However, it is necessary to extend the classical worm-like chain model (WLC) for describing conformations of intrinsically straight homogeneous polymers to DNA. This review describes the various methodologies proposed by different authors.     

Study of local changes in the structure of phage DNA by electron microscopy

DNA of defective bacteriophage PBSX was studied by electron microscopy. The presence and distribution of sites containing local structure changes were revealed using antibodies specific for the DNA molecules modified in situ. These structural changes are related to the capsid geometry, but not to the DNA primary sequence.     

Freezing shortens the lifetime of DNA molecules under tension

DNA samples are commonly frozen for storage. However, freezing can compromise the integrity of DNA molecules. Considering the wide applications of DNA molecules in nanotechnology, changes to DNA integrity at the molecular level may cause undesirable outcomes. However, the effects of freezing on DNA integrity have not been fully explored. To investigate the impact of freezing on DNA integrity, samples of frozen and non-frozen bacteriophage lambda DNA were studied using optical tweezers. Tension (5–35 pN) was applied to DNA molecules to mimic mechanical interactions between DNA and other biomolecules. The integrity of the DNA molecules was evaluated by measuring the time taken for single DNA molecules to break under tension. Mean lifetimes were determined by maximum likelihood estimates and variances were obtained through bootstrapping simulations. Under 5 pN of force, the mean lifetime of frozen samples is 44.3 min with 95% confidence interval (CI) between 36.7 min and 53.6 min while the mean lifetime of non-frozen samples is 133.2 min (95% CI: 97.8–190.1 min). Under 15 pN of force, the mean lifetimes are 10.8 min (95% CI: 7.6–12.6 min) and 78.5 min (95% CI: 58.1–108.9 min). The lifetimes of frozen DNA molecules are significantly reduced, implying that freezing compromises DNA integrity. Moreover, we found that the reduced DNA structural integrity cannot be restored using regular ligation process. These results indicate that freezing can alter the structural integrity of the DNA molecules.     

Changes in DNA and surface properties of peripheral blood leukocytes in monkeys after total gamma irradiation

Changes of Macaca nemestrina and Rhesus blood DNA have been studied up to 5 days after the total uniform gamma-irradiation in doses 6.2 and 6.5 Gy. The content of nucleotide ATrich DNA has been evaluated in the fractions of leucocytes with the various surface adherence properties. The dynamics of the content nucleotide AT-DNA and blood leucocytes were similar at the both monkey species. The evaluation of structural state DNA in the blood nucleotide with the fluorescent dyes (ethidium bromide and 4; 6-diamidine-2-phenylindole) demonstrated that the important changes in the polynucleotide structure occurred from 6 to 24 h after irradiation and maintained up to 5 days. Adhesive capacity changes were reversible but they preceded the DNA structural changes. At 24 h postirradiation non-adhesive cells with relative higher AT-DNA content were found.     

Induction of unique structural changes in guanine-rich DNA regions by the triazoloacridone C-1305, a topoisomerase II inhibitor with antitumor activities

We recently reported that the antitumor triazoloacridone, compound C-1305, is a topoisomerase II poison with unusual properties. In this study we characterize the DNA interactions of C-1305 in vitro, in comparison with other topoisomerase II inhibitors. Our results show that C-1305 binds to DNA by intercalation and possesses higher affinity for GC- than AT-DNA as revealed by surface plasmon resonance studies. Chemical probing with DEPC indicated that C-1305 induces structural perturbations in DNA regions with three adjacent guanine residues. Importantly, this effect was highly specific for C-1305 since none of the other 22 DNA interacting drugs tested was able to induce similar structural changes in DNA. Compound C-1305 induced stronger structural changes in guanine triplets at higher pH which suggested that protonation/deprotonation of the drug is important for this drug-specific effect. Molecular modeling analysis predicts that the zwitterionic form of C-1305 intercalates within the guanine triplet, resulting in widening of both DNA grooves and aligning of the triazole ring with the N7 atoms of guanines. Our results show that C-1305 binds to DNA and induces very specific and unusual structural changes in guanine triplets which likely plays an important role in the cytotoxic and antitumor activity of this unique compound.     

Inhibition of structural changes in the simian virus 40 core origin of replication by mutation of essential origin sequences.

Mutation of the simian virus 40 (SV40) origin of replication (ori) has revealed the presence of three critical domains needed for DNA replication. The outer two domains, the AT tract and early palindrome element (EP), colocalize with DNA regions that become structurally altered in the presence of the SV40 large tumor antigen (T antigen) and ATP. Mutations within each domain were examined for their effect on the distortion of ori DNA by T antigen, as assayed by the sensitivity of DNA to KMnO4 oxidation. We have found that mutations in the AT tract that inhibit SV40 DNA replication also inhibit the distortion of the AT tract. Similarly, mutations in the EP inhibited the generation of structural changes in this element by T antigen. Although AT-tract mutations or mutations on the late side of ori affected structural changes only in the AT tract, certain EP mutations or mutations on the early side of ori also inhibited AT-tract distortion. Mutation of the flanking regions did not significantly affect either the affinity of T antigen for ori or the rate of binding to ori. We conclude from these results that the primary function of the flanking ori domains is to undergo structural changes required during the initiation of SV40 DNA replication. Moreover, our results suggest that the efficiency of replication initiation is significantly affected by the degree to which the flanking elements undergo a structural transition.     

Compacting effect of BBR3464, a new-generation trisplatinum anticancer agent,on DNA

BBR3464 is a trinuclear platinum compound of formula [{trans-PtCl(NH₃)₂}₂-μ-trans-Pt(NH₃)₂{NH₂(CH₂)₆NH₂}₂]⁴⁺. It is a new-generation platinum chemotherapeutic agent that exhibits cytotoxicity at ten to thousand times lower dose limit compared to the well-known platinum drug cisplatin, in cisplatin-sensitive as well as in cisplatin-resistant cells. DNA is thought to be the primary cellular target of BBR3464. In this work, we have applied high-resolution atomic force microscopy (AFM) for the first time, to obtain direct information on BBR3464-induced structural changes of DNA. It is found that the DNA molecules get compacted after treatment with BBR3464, for the drug:DNA molar ratio and the drug treatment period of 0.01 and 48 h, respectively. These values of molar ratio and incubation period have been obtained previously, as a result of biochemical optimization studies carried out for achieving maximum drug effects. The DNA structural changes, as observed in AFM topographs, have been correlated to the bulk level spectroscopic information. A remark on the significance of BBR3464-induced DNA compaction with respect to the available AFM reports on DNA modification by cisplatin has been made.