Hydrated electrons induce the formation of interstrand cross-links in DNA modified by cisplatin adducts

Double-stranded oligonucleotides containing cisplatin adducts, with and without a mismatched region, were exposed to hydrated electrons generated by gamma-rays. Gel electrophoresis analysis demonstrates the formation of cisplatin-interstrand crosslinks from the cisplatin-intrastrand species. The rate constant per base for the reaction between hydrated electrons and the double-stranded oligonucleotides with and without cisplatin containing a mismatched region was determined by pulse radiolysis to be 7 × 109 and 2 × 109 M-1 s-1, respectively. These results provide a better understanding of the radiosensitizing effect of cisplatin adducts in hypoxic tumors and of the formation of interstrand crosslinks, which are difficult for cells to repair.

Multi-level patterning nucleic acid photolithography

The versatile and tunable self-assembly properties of nucleic acids and engineered nucleic acid constructs make them invaluable in constructing microscale and nanoscale devices, structures and circuits. Increasing the complexity, functionality and ease of assembly of such constructs, as well as interfacing them to the macroscopic world requires a multifaceted and programmable fabrication approach that combines efficient and spatially resolved nucleic acid synthesis with multiple post-synthetic chemical and enzymatic modifications. Here we demonstrate a multi-level photolithographic patterning approach that starts with large-scale in situ surface synthesis of natural, modified or chimeric nucleic acid molecular structures and is followed by chemical and enzymatic nucleic acid modifications and processing. The resulting high-complexity, micrometer-resolution nucleic acid surface patterns include linear and branched structures, multi-color fluorophore labeling and programmable targeted oligonucleotide immobilization and cleavage.

Light-Induced Reversible DNA Ligation of Gold Nanoparticle Superlattices

DNA-mediated self-assembly of nanoparticles has been of great interest because it enables access to nanoparticle superstructures that cannot be synthesized otherwise. However, the programmability of higher order nanoparticle structures can be easily lost under DNA denaturing conditions. Here, we demonstrate that light can be employed as an external stimulus to master the stability of nanoparticle superlattices (SLs) via the promotion of a reversible photoligation of DNA in SLs. The oligonucleotides attached to the nanoparticles are encoded to ligate using 365 nm light, effectively locking the SLs and rendering them stable under DNA denaturing conditions. The reversible process of unlocking these structures is possible by irradiation with light at 315 nm, recovering the structures to their natural state. Our work inspires an alternative research direction toward postassembly manipulation of nanoparticle superstructures using external stimuli as a tool to enrich the library of additional material forms and their application in different media and environments.

Radiation damage during in situ electron microscopy of DNA-mediated nanoparticle assemblies in solution

Oligonucleotide-nanoparticle conjugates, also called programmable atom equivalents, carry promise as building blocks for self-assembled colloidal crystals, reconfigurable or stimuli responsive functional materials, as well as bio-inspired hierarchical architectures in wet environments. In situ studies of the DNA-mediated self-assembly of nanoparticles have so far been limited to reciprocal space techniques. Liquid-cell electron microscopy could enable imaging such systems with high resolution in their native environment but to realize this potential, radiation damage to the oligonucleotide linkages needs to be understood and conditions for damage-free electron microscopy identified. Here, we analyze in situ observations of DNA-linked two-dimensional nanoparticle arrays, along with control experiments for different oligonucleotide configurations, to identify the mechanisms of radiation damage for ordered superlattices of DNA-nanoparticle conjugates. In a biological context, the results point to new avenues for studying direct and indirect radiation effects for small ensembles of DNA in solution by tracking conjugated nanoparticles. By establishing low-dose conditions suitable for extended in situ imaging of programmable atom equivalents, our work paves the way for real-space observations of DNA-mediated self-assembly processes.

A Two-Photon-Photocleavable Linker for Triggering Light-Induced Strand Breaks in Oligonucleotides

We synthesized a two-photon-sensitive photocleavable linker based on the 7-diethylaminocoumarin structure and introduced it successfully into DNA strands. First, we demonstrated the inducibility of strand scissions upon irradiation at 365 nm. To verify and visualize the two-photon activity, we used a fluorescence assay based on a DNA strand displacement immobilized in a hydrogel. Additionally, we investigated its use in a new class of DNA decoys that are able to catch and release nuclear factor κB (NF-κB) by using light as an external trigger signal. In cell culture we were able to show the regulation of NF-κB-controlled transcription of green fluorescent protein.

DNA damage and interstrand cross-link formation upon irradiation of aryl iodide C-nucleotide analogues

The 5-halopyrimidine nucleotides damage DNA upon UV-irradiation or exposure to gamma-radiolysis via the formation of the 2'-deoxyuridin-5-yl sigma-radical. The bromo and iodo derivatives of these molecules are useful tools for probing DNA structure and as therapeutically useful radiosensitizing agents. A series of aryl iodide C-nucleotides were incorporated into synthetic oligonucleotides and exposed to UV-irradiation and gamma-radiolysis. The strand damage produced upon irradiation of DNA containing these molecules is consistent with the generation of highly reactive sigma-radicals. Direct stand breaks and alkali-labile lesions are formed at the nucleotide analogue and flanking nucleotides. The distribution of lesion type and location varies depending upon the position of the aryl ring that is iodinated. Unlike 5-halopyrimidine nucleotides, the aryl iodides produce interstrand cross-links in duplex regions of DNA when exposed to gamma-radiolysis or UV-irradiation. Quenching studies suggest that cross-links are produced by gamma-radiolysis via capture of a solvated electron, and subsequent fragmentation to the sigma-radical. These observations suggest that aryl iodide C-nucleotide analogues may be useful as probes for excess electron transfer and radiosensitizing agents.

Coupling across a DNA helical turn yields a hybrid DNA/organic catenane doubly tailed with functional termini

We describe the synthesis of a hybrid DNA/organic macrocycle that is prepared by formation of an amide linkage across one full turn of DNA. Formation of a catenane proved that the linkage crossed a turn rather than running along the phosphodiester backbone contour. The product, a doubly tailed catenane, contains 5'- and 3'-termini that can be functionalized further or used to incorporate the catenane structure into other DNA assemblies.

Mechanisms of direct radiation damage in DNA, based on a study of the yields of base damage, deoxyribose damage, and trapped radicals in d(GCACGCGTGC)(2)

Dose-response curves were measured for the formation of direct-type DNA products in X-irradiated d(GCACGCGTGC)(2)prepared as dry films and as crystalline powders. Damage to deoxyribose (dRib) was assessed by HPLC measurements of strand break products containing 3' or 5' terminal phosphate and free base release. Base damage was measured using GC/ MS after acid hydrolysis and trimethylsilylation. The yield of trappable radicals was measured at 4 K by EPR of films X-irradiated at 4 K. With exception of those used for EPR, all samples were X-irradiated at room temperature. There was no measurable difference between working under oxygen or under nitrogen. The chemical yields (in units of nmol/J) for trapped radicals, free base release, 8-oxoGua, 8-oxoAde, diHUra and diHThy were G(total)(fr) = 618 +/- 60, G(fbr) = 93 +/- 8, G(8-oxoGua) = 111 +/- 62, G(8-oxoAde) = 4 +/- 3, G(diHUra) = 127 +/- 160, and G(diHThy) = 39 +/- 60, respectively. The yields were determined and the dose-response curves explained by a mechanistic model consisting of three reaction pathways: (1) trappable-radical single-track, (2) trappable-radical multiple-track, and (3) molecular. If the base content is projected from the decamer's GC:AT ratio of 4:1 to a ratio of 1:1, the percentage of the total measured damage (349 nmol/J) would partition as follows: 20 +/- 16% 8-oxoGua, 3 +/- 3% 8-oxoAde, 28 +/- 46% diHThy, 23 +/- 32% diHUra, and 27 +/- 17% dRib damage. With a cautionary note regarding large standard deviations, the projected yield of total damage is higher in CG-rich DNA because C combined with G is more prone to damage than A combined with T, the ratio of base damage to deoxyribose damage is approximately 3:1, the yield of diHUra is comparable to the yield of diHThy, and the yield of 8-oxoAde is not negligible. While the quantity and quality of the data fall short of proving the hypothesized model, the model provides an explanation for the dose-response curves of the more prevalent end products and provides a means of measuring their chemical yields, i.e., their rate of formation at zero dose. Therefore, we believe that this comprehensive analytical approach, combined with the mechanistic model, will prove important in predicting risk due to exposure to low doses and low dose rates of ionizing radiation.

MALDI MS analysis of oligonucleotides: desalting by functional magnetite beads using microwave-assisted extraction

The presence of alkali cation adductions of oligonucleotides commonly deteriorates matrix-assisted laser desorption/ionization (MALDI) mass spectra. Thus, desalting is required for oligonucleotide samples prior to MALDI MS analysis in order to prevent the mass spectra from developing poor quality. In this paper, we demonstrate a new approach to extract traces of oligonucleotides from aqueous solutions containing high concentrations of salts using microwave-assisted extraction. The C18-presenting magnetite beads, capable of absorbing microwave irradiation, are used as affinity probes for oligonucleotides with the addition of triethylammonium acetate as the counterions. This new microwave-assisted extraction approach using magnetite beads as the trapping agents and as microwave-absorbers has been demonstrated to be very effective in the selective binding of oligonucleotides from aqueous solutions. The extraction of oligonucleotides from solutions onto the C18-presenting magnetite beads takes only 30 s to enrich oligonucleotides in sufficient quantities for MALDI MS analysis. After using this desalting approach, alkali cation adductions of oligonucleotides are dramatically reduced in the MALDI mass spectra. The presence of saturated NaCl (approximately 6 M) in the oligonucleotide sample is tolerated without degrading the mass spectra. The detection limit for d(A)6 is approximately 2.8 fmol.

Microwave assisted rolling circle amplification

The Rolling Circle Amplification is an effective method of DNA amplification having tandem repeated sequences. Firstly, the template sequence is designed to form a circular structure by the annealing with the primer. The thermostable polymerase is catalyzed to primer and circular template DNA. As a result, tandem repetitive olignucleotide of circular template sequence can be obtained. In our recent study, Bst DNA polymerase catalyzed RCA reaction had been elucidated that the oligonucleotides with tandem repeated sequence were obtained as the ladder band and amplified the enough amounts of DNA within short time. On the other hand, we also focused on the microwave technology for advance to the various chemical and biological reactions. In this study, the microwave was irradiated to RCA reaction on controlling the temperature.

Synthesis and pairing properties of alpha-tricyclo-DNA

We describe the synthesis of the phosphoramidite building blocks of alpha-tricyclo-DNA (alpha-tc-DNA) covering all four natural bases, starting from the already known corresponding alpha-tc-nucleosides. These building blocks were used for the preparation of three alpha-tc-oligonucleotide 10-mers representing a homopurine, a homopyrimidine, and a mixed purine/pyrimidine base sequence. The base-pairing properties with complementary parallel and antiparallel oriented DNA and RNA were studied by UV-melting analysis and CD spectroscopy. We found that alpha-tc-DNA binds preferentially to parallel nucleic acid complements through Watson-Crick duplex formation, with a preference for RNA over DNA. In comparison with natural DNA, alpha-tc-DNA shows equal to enhanced affinity to RNA and also pairs to antiparallel DNA or RNA complements, although with much lower affinity. In the mixed-base sequence these antiparallel duplexes are of the reversed Watson-Crick type, while in the homopurine/homopyrimidine sequences Hoogsteen and/or reversed Hoogsteen pairing is observed. Antiparallel duplex formation of two alpha-tc-oligonucleotides was also observed, although the thermal stability of this duplex was surprisingly low. The base-pairing properties of alpha-tc-DNA are discussed in the context of alpha-DNA, alpha-RNA, and alpha-LNA.

UVA-induced degradation of 8-hydroxyguanine in oligonucleotide and the effect on its activities in yeast oligonucleotide transformation assay

UVA-induced conversion of 8-hydroxyguanine in oligonucleotides was studied. By irradiation with 334 nm UVA light, 8-hydroxyguanine was completely changed to unknown compounds. Monomeric nucleoside may be much less labile to UVA. Mutagenic specificities of 8-hydroxyguanine were investigated using yeast oligonucleotide mutation assay. UVA irradiation moderately reduced the activity of the oligonucleotides.

Driven polymer transport through a nanopore controlled by a rotating electric field: off-lattice computer simulations

The driven translocation kinetics of a single strand polynucleotide chain through a nanopore is studied using off-lattice Monte Carlo simulations, by which the authors demonstrate a novel method in controlling the driven polymer transport through a nanopore by a rotating electric field. The recorded time series of blockade current from the driven polynucleotide transport are used to determine the sequence of polynucleotides by implementing a modified Monte Carlo algorithm, in which the energy landscape paving technique is incorporated to avoid trapping at deep local minima. It is found that only six-time series of block current are required to completely determine the polynucleotide sequence if the average missing rate (AMR) of current signals in these time series is smaller than 20%. For those time series with AMR greater than 20%, the error rate in sequencing an unknown polynucleotide decreases rapidly by increasing the number of time series. To find the most appropriate experimental conditions, the authors have investigated the dependence of AMR of current signals and qualified rate of measured time series of blockade current on various controllable experimental variables.

Reactivity of 2'-deoxyuridin-1'-yl radical in various DNA structures

DNA C1' radicals formed by hydrogen atom abstraction from the C1' position of the sugar backbone lead to the production of 2'-deoxyribonolactone as a DNA damage lesion. Although DNA C1' radicals may be involved in a variety of DNA damage processes, there is very little information on the molecular basis of DNA structure dependence in the reactions of C1' radicals. Here, we describe a detailed study of the reactivity of 2'-deoxyuridin-1'-yl radicals in single- and double-stranded B-form DNA and G-quartets in the formation of 2'-deoxyribonolactone, using the unnatural precursor 1'-pivaloyl-2'-deoxyuridine (1).

Switching of charge transport in DNA by regulated triplex formations at the dual sites

A functionality of on/off switching to regulate conductivity should be among the prerequisites for the utilization of DNA duplex as a conducting material. We have reported that variation of temperatures can regulate the triplex formation and dissociation, thereby regulating charge transport in DNA. Based on this result, the on/off switching of conductivity at dual triplex forming sites in DNA was attempted, using two types of oligonucleotide (ODNs) with different strand lengths. Variation of temperatures produced DNA duplexes without any triplex site and with single and double triplex sites, by which the intramolecular charge transport in DNA duplex could be regulated at the respective triplex-forming sites. This may promote the utility of DNA duplex as a potential constituent of electronic nanodevices.

Pyrimidine (6-4) pyrimidone photoproduct mapping after sublethal UVC doses: nucleotide resolution using terminal transferase-dependent PCR

UVC irradiation of genomic DNA induces two main types of potentially mutagenic base modifications: cyclobutane pyrimidine dimers (CPDs) and the less frequent (15-30% of CPD levels) pyrimidine (6-4) pyrimidone photoproducts (6-4PP). Ligation-mediated PCR (LMPCR), a genomic sequencing technique, allows CPD mapping at nucleotide resolution following irradiation with sublethal doses of UVB or UVC for most cell types. In contrast, a dose of 80 J/m(2) of UVC that is lethal for the majority of cell types is necessary to map 6-4PP by the LMPCR technique. This compromises the use of LMPCR to study the repair of 6-4PP. To date, no other techniques have been developed to study 6-4PP repair at nucleotide resolution. We have therefore adapted a recently developed technique for the mapping of 6-4PP: terminal transferase-dependent PCR (TDPCR). TDPCR is in many ways similar to LMPCR. This technique is more sensitive and allows the mapping of 6-4PP at UVC doses as low as 10 J/m(2) in genomic DNA and in living cells.

A new photoactive building block for investigation of DNA backbone interactions: photoaffinity labeling of human DNA polymerase beta

The cross-linking of target proteins or nucleic acids to light-activatable ligands is an important tool for elucidating molecular interactions. Through the use of photoaffinity-labeling reagents, several new insights into nucleic acid interactions have been obtained, for example in DNA replication and repair. In most known photoprobes, the applied light-sensitive functionalities are placed directly at the nucleobase or are attached via linkers to either the nucleobase or the phosphate backbone. Here we describe the first photoprobe that bears a light-sensitive aryl(trifluoromethyl)diazirine at the sugar moiety of a DNA oligonucleotide. We devised a route for the synthesis of the modified nucleoside and its incorporation into an oligonucleotide. The photoactive species was proven to be stable under the conditions employed in routine automated DNA synthesis. The modified oligonucleotide was shown by subsequent photolabeling studies of human DNA polymerase beta to form a covalent complex to the enzyme upon irradiation with near-UV light.

Chemical synthesis of oligonucleotides containing damaged bases for biological studies

Since nucleic acids are organic molecules, even DNA, which carries genetic information, is subjected to various chemical reactions in cells. Alterations of the chemical structure of DNA, which are referred to as DNA damage or DNA lesions, induce mutations in the DNA sequences, which lead to carcinogenesis and cell death, unless they are restored by the repair systems in each organism. Formerly, DNA from bacteria and bacteriophages and DNA fragments treated with UV or gamma radiation, alkylating or crosslinking agents, and other carcinogens were used as damaged DNA for biochemical studies. With these materials, however, it is difficult to understand the detailed mechanisms of mutagenesis and DNA repair. Recent progress in the chemical synthesis of oligonucleotides has enabled us to incorporate a specific lesion at a defined position within any sequence context. This method is especially important for studies on mutagenesis and translesion synthesis, which require highly pure templates, and for the structural biology of repair enzymes, which necessitates large amounts of substrate DNA as well as modified substrate analogs. In this review, the various phosphoramidite building blocks for the synthesis of lesion-containing oligodeoxyribonucleotides are described, and some examples of their applications to molecular and structural biology are presented.

Regulating gene expression with light-activated oligonucleotides

Since the development of light-responsive amino acids, the activity of numerous biomolecules has been photomodulated in biochemical, biophysical, and cellular assays. Biological problems of even greater complexity motivate the development of quantitative methods for controlling gene activity with high spatial and temporal resolution, using light as an external trigger. Photoresponsive DNA and RNA oligonucleotides would optimally serve this purpose, but have proven difficult to expand from proofs-of-concept to in vivo experiments. Until recently, the development of this technology was limited by the synthesis of oligonucleotides whose function could be significantly modulated with near-UV light. New synthetic protocols and strategies for both up- and down-regulating gene activity finally make it possible to address biological considerations. In the near future, we can expect photoresponsive DNA and RNA molecules that are relatively non-toxic, nuclease-resistant, and maintain their specificity and activity in vivo. Quantitative, laser-initiated methods for controlling DNA and RNA function will illuminate new areas in cell and developmental biology.

Voltammetric determination of gamma radiation-induced DNA damage

Homopolydeoxyribonucleotides, poly[dGuo], poly[dAdo], poly[dThd], and poly[dCyd], and calf thymus single-stranded DNA (ssDNA) and double-stranded DNA (dsDNA) aqueous solutions previously exposed to gamma radiation doses between 2 and 35 Gy, were studied by differential pulse voltammetry using a glassy carbon electrode. The interpretation of the voltammetric data was also supported by the electrophoretic migration profile obtained for the same ssDNA and dsDNA gamma-irradiated samples by nondenaturing agarose gel electrophoresis. The generation of 8-oxo-7,8-dihydroguanine, 2,8-dihydroxyadenine, 5-formyluracil, base-free sites, and single- and double-stranded breaks in the gamma-irradiated DNA samples was detected voltammetrically, with the amount depending on the irradiation time. It was found that the current peaks obtained for 8-oxoguanine increase linearly with the radiation dose applied to the nucleic acid sample, and values between 8 and 446 8-oxo-7,8-dihydroguanine (8-oxoGua) per 10(6) guanines per Gy were obtained according to the nucleic acid sample. The results showed that voltammetry can be used for monitoring and simultaneously characterizing different kinds of DNA damage caused by gamma radiation exposure.

Chemical basis of DNA sugar-phosphate cleavage by low-energy electrons

DNA damage by low-energy electrons (LEE) was examined using a novel system in which thin solid films of oligonucleotide tetramers (CGTA and GCAT) were irradiated with monoenergetic electrons (10 eV) under ultrahigh vacuum. The products of irradiation were examined by HPLC. These analyses permitted the quantitation of 16 nonmodified nucleobase, nucleoside, and nucleotide fragments of each tetramer resulting from the cleavage of phosphodiester and N-glycosidic bonds. The distribution of nonmodified products suggests a mechanism of damage involving initial electron attachment to nucleobase moieties, followed by electron transfer to the sugar-phosphate backbone, and subsequent dissociation of the phosphodiester bond. Moreover, virtually all the nonmodified fragments contained a terminal phosphate group at the site of cleavage. These results demonstrate that the phosphodiester bond breaks by a distinct pathway in which the negative charge localizes on the phosphodiester bond giving rise to nonmodified fragments with an intact phosphate group. Conversely, the radical must localize on the sugar moiety to give as yet unidentified modifications. In summary, the reaction of LEE with simple tetramers involved dissociative electron attachment leading to phosphodiester bond cleavage and the formation of nonmodified fragments.

Location and base selectivity on fragmentation of brominated oligodeoxynucleotides

Bromine-modified oligodeoxynucleotides (ODNs) were fragmented in the electrospray source to study the influence of brominated bases on fragmentation. Several 13-mer ODNs containing a brominated pyrimidine base, BrdU (5-bromodeoxyuridine) or BrdC (5-bromodeoxycytidine), were analyzed. Low cone voltage fragmentation yields a loss of the brominated base with a preferential loss for the brominated base closer to the 5'-end (2-position > 4-position > 12-position) as well as a preferential loss of BrdU over BrdC. Higher cone voltage produces backbone fragmentation with complementary a(n)-base and w(m) ions close to the brominated base. On the basis of these observations, we located the brominated base in the sequence for all of the ODNs studied.

Characterization of activation energy distribution for ultraviolet irradiation of T-rich oligonucleotide using high-performance liquid chromatography electrospray ionization mass spectrometry tandem mass spectrometry

Exposure to solar UV radiation gives rise to mutations that may lead to skin cancer of human being. Series of experiments were carried out in order to reveal activation energy distribution of DNA mutation caused by UV radiation. The T-rich oligonucleotides were exposed to UV radiation with increasing intensity for different durations. Photoproducts of T-rich oligonucleotide were investigated using ion-pair reversed-phase high-performance liquid chromatography/tandem electrospray ionization mass spectrometry (IP-RP-HPLC/ESI-MS) at room temperature. Two photoproducts of T-rich oligonucleotide were cis-syn cyclobutane pyrimidine dimmer (T[c,s]T) and the pyrimidine(6,4)pyrimidone product (T[6,4]T). Activation energy distribution of DNA mutation was calculated using a commercial kinetics analysis programs by Robert L. Braun and Alan K. Burnham , Lawrance Livermore International Laboratory (version 2.4.1). To use the software for deriving the kinetics parameters, the factor T (temperature) in the software was substituted with k1R, in which k1 is a factor, R is radiation intensity. The activation energy derived ranges from 55 to 110 kJ mol(-1). By the same software, those kinetics parameters were extrapolated to natural UV radiation process to predict DNA damage degree without the DNA repair process.

4-aminometyl-3-nitrobenzoic acid--a photocleavable linker for oligonucleotides containing combinatorial libraries

We detail the design, synthesis, and characterization of an o-nitrobenzyl-based photolabile linker containing amine and carboxyl anchor groups. A model nucleoside monomer modified with an imidazole residue and a precursor unit linked to a heterocyclic base through a photolabile tether is constructed Upon UV irradiation (313- 365 nm), the imidazole containing part of this molecule is released.

Microwaves synthesis of solid supports for the synthesis of 3'-aminoalkyl oligodeoxynucleotides

Phthalimido-alkyl alcohol solid supports were rapidly prepared from solid supported phthalic anhydride and amino alcohol condensation induced by microwaves. These supports were used to synthesize 13-aminoalkyl oligodeoxynucleotides allowing a two step deprotection necessary to avoid aminolink alkylation.

Molecular beacon probes of photodamage in thymine and uracil oligonucleotides

Molecular beacons (MB) are becoming more common as sequence-selective detectors of nucleic acids. Although they can easily detect single-base mismatches, they have never been used to directly detect DNA or RNA damage. To measure the degree of ultraviolet (UV) light damage in oligonucleotides, we report a novel MB approach for general detection of photoproducts in UV-irradiated rU17 and dT17 oligonucleotides. With monochromatic UV light irradiation at ca 280 nm under anoxic conditions, the oligonucleotide absorption decays with a single-exponential time constant of 123+/-1 min for rU17 and with double-exponential time constants of 78+/-0.5 min (99%) and 180+/-5 min (0.05%) for dT17 oligonucleotides. Under the same conditions, the MB fluorescence decays more quickly, with single-exponential time constants of 19+/-2 and 26+/-3 min for rU17 and dT17, respectively. Similar kinetics were observed with broadband UV light irradiation of oligonucleotides. The differences in the UV damage kinetics of dT17 and rU17 and their detection by absorption and fluorescence techniques will be discussed in the context of differential instabilities introduced in the nucleic acid-MB duplex by the different photoproducts formed.

Mechanism of site-specific psoralen photoadducts formation in triplex DNA directed by psoralen-conjugated oligonucleotides

Triplex-formation oligonucleotides attached with a photoreactive psoralen molecule (psoTFO) can be used to induce site-specific DNA damage and to control gene expression. Inhibition of transcription by psoralen-cross-linked triplexes results in both arrest and termination of RNA Pol II transcriptional complexes during elongation. To understand the relationship between triplex psoralen cross-linking products and the fate of RNA Pol II elongation complexes, it is important to delineate the mechanism for creating site-specific psoralen photoadducts in a target duplex DNA. To investigate the mechanism of photoadduct-formation by psoralen photo-cross-linking, triplex structures were generated by targeting a DNA duplex with psoTFOs of different lengths. The psoralen photoadducts were then analyzed after UV irradiation, which initiates the psoralen cross-linking reaction. Our results demonstrated that UV irradiation of triplexes formed between a psoTFO and a DNA duplex generated two distinct groups of psoralen photoadducts: monoadducts and psoralen interstrand cross-link products. The formation of these psoralen photoadducts was also photoreversible through exposure to short wavelength UV irradiation. The length of a psoTFO was shown to establish the position at which psoralen was added to the target DNA duplex and determined which photoadducts products formed predominantly. Kinetic experiments that monitored the formation of the psoralen photoadducts also suggested that the length of the psoTFO influenced which photoadducts were preferentially formed at faster rates. Taken together, these studies provide new insight into the mechanism associated with the formation of psoralen photoadducts that are directed by psoTFO during triplex formation.

Genotyping SNPs using a UV-photocleavable oligonucleotide in MALDI-TOF MS

Matrix-assisted laser desorption time-of-flight mass spectrometry coupled with allele-specific primer extension is a proven method for typing single nucleotide polymorphisms (SNPs). A novel modification upon this methodology is the incorporation of a photocleavable linker within the extension primer. After completion of the primer extension reaction, photocleavage of the extension products results in two deoxyribonucleic acid (DNA) fragments of lower mass. Typically, the smaller cleavage product, which contains the genotyping information, is in the range of 1000-3000 Daltons. The decrease in primer mass allows for higher sensitivity in mass spectrometric measurement and increases the potential for higher levels of multiplexing. The disturbing mass spectrometric analysis peaks caused by salt adducts and doubly charged ions are diminished when analyzing lower-mass DNA fragments. Here, we illustrate the methodology for using photocleavable modified extension primers for detection of SNPs located on the Y chromosome. Genomic templates were prepared from anonymous male donors. Five regions of the Y chromosome containing the SNP markers M9, M42, M45, M89, and M96 were amplified by polymerase chain reaction, treated with shrimp alkaline phosphatase, and subjected to primer extension reactions using primers containing a photocleavable building block at specific sites. After elongation, the extension primers were desalted and subjected to ultraviolet irradiation to cleave the products at the photocleavable site. Subsequently, the small fragments derived from the 3' ends of the molecules containing the genotype information were analyzed by matrix-assisted laser desorption ionization time-of-flight using a 3-hydroxypicolinic acid matrix.

Efficient generation of 2'-deoxyuridin-5-yl at 5'-(G/C)AA(X)U(X)U-3' (X = Br, I) sequences in duplex DNA under UV irradiation

The photoreactivity of 5-halouracil-containing DNA was investigated using 450 base pair DNA fragments under 302 nm irradiation. Heat-dependent cleavage selectively occurs at 5'-(G/C)AAXUXU-3' and 5'-(G/C)AXUXU-3' (X = Br, I) sequences in double-stranded DNA. HPLC product analysis indicated that 2'-deoxyribonolactone residues are effectively generated at these sequences. These observations will be useful in studying the molecular basis of the sequence-dependent DNA-damaging process in UV-irradiated 5-halouracil-containing DNA.

Modified DNA analogues that sense light exposure with color changes

We report the discovery of a new class of light-sensing molecules. These light sensors are composed of fluorophore oligomers assembled on a DNA backbone. A combinatorial library of tetrafluorophores consisting of over 14 000 compounds was synthesized and screened for rapid responses toward light exposure. Among the most light-sensitive molecules, at least three tetramers were found to respond to light exposure with apparent color changes, rather than simple photobleaching.

Interstrand cross-links: a new type of gamma-ray damage in bromodeoxyuridine-substituted DNA

Interstrand cross-links (ICL) represent one of the most toxic types of DNA damage for dividing cells. They are induced both by natural products (e.g., psoralens + UVA) and by several chemical agents, some of which are used in chemotherapy (e.g., carboplatin and mitomycin C). Although repair mechanisms exist for interstrand cross-links, these lesions can induce mutations, chromosomal rearrangements, and cell death. Here, we report, for the first time, the formation of ICL by gamma-rays in brominated DNA. It is well established that the radiosensitization properties of bromodeoxyuridine (BrdUrd) result primarily from the electrophilic nature of the bromine, making it a good leaving group and leading to the irreversible formation of a uridinyl radical (dUrd(*)) or uridinyl anion (dUrd-) upon addition of an electron. We observe that the radiolytic loss of the bromine atom is greatly suppressed in double-stranded compared to single-stranded DNA. We have used a model DNA containing a bulge, formed by five mismatched bases, and have observed a linear dose-response for the formation of strand breaks on the single-stranded regions of both the brominated strand and the opposite nonbrominated strand. Surprisingly, we have observed the formation of interstrand cross-links exclusively in the mismatched region. Thus, we propose that the radiosensitization effects of bromodeoxyuridine in vivo will almost certainly be limited to single strand regions such as found in transcription bubbles, replication forks, mismatched DNA, and possibly the loop region of telomeres. Our results suggest that interstrand cross-links may contribute to the radiosensitization effects of BrdUrd. These findings may have profound implications for the clinical use of bromodeoxyuridine as a radiosensitizer, as well as for the development of targeted radiosensitizers.

Dosimetry and risk from low- versus high-LET radiation of Auger events and the role of nuclide carriers

PURPOSE

To analyse the lethality to mammalian cells of (125)I-decays in DNA, in antipyrine in the whole cell and in oligodeoxynucleotides in the nucleus outside DNA as a function of Auger event-site and number.

MATERIALS AND METHODS

Auger events cause both low- and high-linear energy transfer energy depositions including charge neutralization at the daughter nuclide. Microdosimetry allows the expression of absorbed dose to a defined micromass and the number of such events at given sites. Published data were used to relate micromass dose and event number to the dose to reduce survival to 37% of the initial survival (D37).

RESULTS

The D37 of (125)I-decays in DNA was 0.1 Gy in terms of absorbed dose to the cell nucleus and about 30 in terms of average decays per nucleus or whole cell. The D37 of (125)I-decays in antipyrine was 1.5 Gy for absorbed dose to the cell nucleus, about 250 in terms of average decays per nucleus and about 2 x 10(3) for average decays per whole cell. (125)I-decays in oligodeoxynucleotides were much less toxic than (125)I-decays in antipyrine by a factor of about 25 in terms of average absorbed dose to the cell nucleus, by a factor or about 40 in terms of average decays per cell nucleus and by a factor of six in terms of average decays per whole cell.

CONCLUSION

The unexpected low toxicity of (125)I-decays in nuclear oligodeoxynucleotides outside the DNA in comparison with (125)I-decays in antipyrine in the nucleus or the whole cell demands further attention on the role of oligodeoxynucleotides in altering cellular radiation sensitivity.

Electron transfer in DNA duplexes containing 2-methyl-1,4-naphthoquinone

2-methyl-1,4-naphthoquinone (menadione, MQ) was linked to synthetic oligonucleotides and exposed to near-UV light to generate base radical cations in DNA. This model system of electron transfer induced alkali-labile breaks at GG doublets, similar to anthraquinone and metallointercalators systems. In sharp contrast to other systems, the photolysis of MQ-DNA duplexes gave interstrand cross-links and alkali-labile breaks at bases on the complementary strand opposite the MQ moiety. For sequences with an internal MQ, the formation of cross-links with A and C opposite the MQ moiety was 2- to 3-fold greater than that with G and T. The yield of cross-links was more than 10-fold greater than that of breaks opposite MQ, which in turn was more than 2-fold greater than breaks at GG doublets. The yield of damage at GG doublets greatly increased for a sequence with a terminal MQ. The distribution of base damage was measured by enzymatic digestion and HPLC analysis (dAdo > dThd > dGuo > dCyd). The formation of novel products in MQ-DNA duplexes was attributed to the ability of excited MQ to generate the radical cations of all four DNA bases; thus, this photochemical reaction provides an ideal model system to study the effects of ionizing radiation and one-electron oxidants.

Effects of the C4'-oxidized abasic site on replication in Escherichia coli. An unusually large deletion is induced by a small lesion

The C4'-oxidized abasic site (C4-AP) is produced in DNA as a result of oxidative stress by a variety of agents. For instance, the lesion accounts for approximately 40% of the DNA damage produced by the antitumor antibiotic bleomycin. The effect of C4-AP on DNA replication in Escherichia coli was determined using the restriction endonuclease and postlabeling (REAP) method. Three-nucleotide deletion products are the sole products observed following replication of plasmids containing C4-AP under SOS conditions in wild-type cells. Full-length products are formed in varying amounts depending upon the local sequence in wild-type cells under non-SOS-induced conditions. The "A-rule" is followed for the formation of substitution products. C4-AP is the first example of a DNA lesion that produces significant levels of three-nucleotide deletions in a variety of sequence contexts. Experiments carried out in cells lacking specific polymerases reveal that formation of three-nucleotide deletion products results from a coordinated effort involving pol II and pol IV. This is the first example in which these SOS inducible polymerases are shown to work in concert during lesion bypass. Three-nucleotide deletions are not observed during the replication of other abasic lesions, and are rarely produced by bulky adducts. The effect of C4-AP on DNA replication suggests a significant role for this lesion in the cytotoxicity of bleomycin. Formation of the C4-AP lesion may also be responsible for the formation of mutant proteins containing single-amino acid deletions that exhibit altered phenotypes.

3-nitro-3-deaza-2'-deoxyadenosine as a versatile photocleavable 2'-deoxyadenosine mimic

A new photocleavable 2'-deoxyadenosine mimic, 3-nitro-3-deaza-2'-deoxyadenosine (NidA), was prepared and introduced into DNA fragments via its 6-O-trimethylphenyl precursor phophoramidite. Photocleavage of the resulting oligonucleotide is highly efficient in single and double strands. Hybridization properties of NidA are very similar to those of deoxyadenosine.

Long-lived charge-separated state leading to DNA damage through hole transfer

The hole transfer causes the long-lived charge-separated state in DNA during the photosensitized one-electron oxidation of DNA. The combination of the transient absorption measurement and DNA damage quantification by HPLC clearly demonstrated that the yield of the DNA damage correlates well with the lifetime of the charge-separated state.

Arrhenius activation parameters for the loss of neutral nucleobases from deprotonated oligonucleotide anions in the gas phase

Arrhenius activation parameters (E(a) and A) for the loss of neutral nucleobase from a series of doubly deprotonated oligodexoynucleotide 10-mers of the type XT(9), T(9)X, and T(5)XT(4), where X = A, C, and G, have been determined using the blackbody infrared radiative dissociation technique. At temperatures of 120 to 190 degrees C, the anions dissociate exclusively by the loss of a neutral nucleobase (XH), followed by cleavage of the sugar 3' C-O bond leading to (a-XH) and w type ions or, in the case of the T(9)X(2-) ions, the loss of H(2)O. The dissociation kinetics and energetics are sensitive to the nature and position of X. Over the temperature range investigated, the kinetics for the loss of AH and GH were similar, but approximately 100 times faster than for the loss of CH. For the loss of AH and GH, the values of E(a) are sensitive to the position of the base. The order of the E(a)s for the loss of XH from the 5' and 3' termini is: C > G > A; while for T(5)XT(4) the order is: C > A > G. The trends in the values of E(a) do not parallel the trend in deprotonation enthalpies or proton affinities of the nucleobases in the gas phase, indicating that the energetic differences do not simply reflect differences in their gas phase acidity or basicity. The pre-exponential factors (A) vary from 10(10) to 10(15) s(-1), depending on the nature and position of X. These results suggest that the reactivity of individual nucleobases is influenced by stabilizing intramolecular interactions.

Detection of the factor V Leiden mutation by a modified photo-cross-linking oligonucleotide hybridization assay

BACKGROUND

Our previously developed assay for detection of the factor V Leiden mutation (G1691A) based on a nucleic acid photo-cross-linking technology used two allele-specific capture probes and six fluorescein-modified signal-generating reporter probes. We wished to improve the sensitivity and performance of the method.

METHODS

We developed new reporter probes with approximately 10-fold more fluorescein molecules than the original probes. The single, cross-linker-modified capture probe was replaced by a three-probe system, separating the probe-target cross-linking function and the allelic differentiation function. The capture probe cross-linked to either or both of two flanking probes through stem structures at the capture-probe/flanking-probe junctions. The flanking probes cross-linked to target DNA through two cross-linking sites each. Genomic DNA was extracted from 0.2 mL of whole blood and restriction-enzyme digested to create a defined 677 bp target sequence. Preliminary genotype ranges were determined for the assay by testing of pre-typed samples. We then tested 1054 clinical samples, using an automated sample processor.

RESULTS

The new assay had a 10-fold increase in signal-to-background ratio. Genotype results for 1039 of 1054 clinical samples (98.6%) agreed with those of a PCR-based method. Of the 15 remaining samples, 10 produced an indeterminate result outside the defined genotype ranges, 2 yielded insufficient signal to be genotyped, and 3 gave a discordant result. All 15 samples were genotyped correctly after re-extraction of genomic DNA and retesting.

CONCLUSION

The modified photo-cross-linking assay for factor V Leiden detection is a sensitive non-PCR-based assay with potential for use in high-throughput clinical laboratories.

Identification and characterization of an intermediate in the alkali degradation of (6-4) photoproduct-containing DNA

The (6-4) photoproduct formed by ultraviolet light is known as an alkali-labile DNA lesion. Strand breaks occur at (6-4) photoproducts when UV-irradiated DNA is treated with hot alkali. We have analyzed the degradation reaction of this photoproduct under alkaline conditions using synthetic oligonucleotides. A tetramer, d(GT(6-4)TC), was prepared, and its degradation in 50 mm KOH at 60 degrees C was monitored by high performance liquid chromatography. A single peak with a UV absorption spectrum similar to that of the starting material was detected after the reaction, and this compound was regarded as an intermediate before the strand break. The formation of this intermediate was compared with intermediates from the degradation of other alkali-labile lesions such as the abasic site, thymine glycol, and 5,6-dihydrothymine. The results strongly suggested that the first step of the alkali degradation of the (6-4) photoproduct was the hydrolysis between the N3 and C4 positions of the 5'-pyrimidine component. Analyses by NMR spectroscopy and mass spectrometry supported the chemical structure of this product. Assays of the complex formation with XPC.HR23B and the translesion synthesis by DNA polymerase eta revealed that the biochemical properties are indistinguishable between the intact and hydrolyzed photoproducts.

Survival of the fittest before the beginning of life: selection of the first oligonucleotide-like polymers by UV light

BACKGROUND

A key event in the origin of life on this planet has been formation of self-replicating RNA-type molecules, which were complex enough to undergo a Darwinian-type evolution (origin of the "RNA world"). However, so far there has been no explanation of how the first RNA-like biopolymers could originate and survive on the primordial Earth.

RESULTS

As condensation of sugar phosphates and nitrogenous bases is thermodynamically unfavorable, these compounds, if ever formed, should have undergone rapid hydrolysis. Thus, formation of oligonucleotide-like structures could have happened only if and when these structures had some selective advantage over simpler compounds. It is well known that nitrogenous bases are powerful quenchers of UV quanta and effectively protect the pentose-phosphate backbones of RNA and DNA from UV cleavage. To check if such a protection could play a role in abiogenic evolution on the primordial Earth (in the absence of the UV-protecting ozone layer), we simulated, by using Monte Carlo approach, the formation of the first oligonucleotides under continuous UV illumination. The simulations confirmed that UV irradiation could have worked as a selective factor leading to a relative enrichment of the system in longer sugar-phosphate polymers carrying nitrogenous bases as UV-protectors. Partial funneling of the UV energy into the condensation reactions could provide a further boost for the oligomerization.

CONCLUSION

These results suggest that accumulation of the first polynucleotides could be explained by their abiogenic selection as the most UV-resistant biopolymers.

Light-directed 5'-->3' synthesis of complex oligonucleotide microarrays

Light-directed synthesis of high-density microarrays is currently performed in the 3'-->5' direction due to constraints in existing synthesis chemistry. This results in the probes being unavailable for many common types of enzymatic modification. Arrays that are synthesized in the 5'-->3' direction could be utilized to perform parallel genotyping and resequencing directly on the array surface, dramatically increasing the throughput and reducing the cost relative to existing techniques. In this report we demonstrate the use of photoprotected phosphoramidite monomers for light-directed array synthesis in the 5'-->3' direction, using maskless array synthesis technology. These arrays have a dynamic range of >2.5 orders of magnitude, sensitivity below 1 pM and a coefficient of variance of <10% across the array surface. Arrays containing >150,000 probe sequences were hybridized to labeled mouse cRNA producing highly concordant data (average R(2) = 0.998). We have also shown that the 3' ends of array probes are available for sequence-specific primer extension and ligation reactions.

Cyclobutylpyrimidine dimer base flipping by DNA photolyase

DNA Photolyase is a flavoprotein that uses light to repair cyclobutylpyrimidine dimers in DNA. From considerations of the crystal structure of the protein, it has been hypothesized that the dimer lesion is flipped out of the DNA double helix into the substrate binding pocket. We have used a fluorescent adenine analog, 2-aminopurine (2-Ap), as a probe of local double helical structure upon binding of the substrate to the protein. Our results show that the local structure around the thymidine lesion changes dramatically upon binding to Photolyase. This is consistent with base flipping of the lesion into the protein binding cavity with concomitant destacking of the opposing complementary 2-Ap nucleotide.

In vivo acetylation of HMG1 protein enhances its binding affinity to distorted DNA structures

The postsynthetic acetylation of HMG1 protein has been known for more than 20 years, but the effect of this modification on the properties of the protein has not been studied so far. Acetylated HMG1 was isolated from cells grown in the presence of sodium n-butyrate and identified as a monoacetylated protein, modified at lysine 2. Acetylated and parental forms of HMG1 were compared relative to their binding affinity to distorted DNA structures. By using mobility shift assay to determine the dissociation constants, we show that acetylation enhanced the ability of HMG1 to recognize UV light- or cisplatin-damaged DNA and four-way junctions. Since the modified lysine lies adjacent to the HMG1 DNA-binding domain, the results obtained were attributed to acetylation-induced conformational change in HMG1. The potential role of acetylation in modulating the interactions of HMG1 with both damaged DNA and other proteins is discussed.

Unique response of double-stranded oligonucleotides containing a single 8-oxo-7,8-dihydroguanine to gamma rays in the frozen aqueous state at 77 K

Two kinds of double-stranded oligonucleotides containing a single 8-oxo-7,8-dihydroguanine were labeled with (32)P at their 5' ends and exposed to gamma rays in the frozen aqueous state at 77 K, where both direct and quasi-direct effects of ionizing radiation predominate. Analysis of the oligonucleotides with 20% denaturing polyacrylamide gel electrophoresis revealed no difference in the immediate induction of strand breaks between oligonucleotides containing 8-oxo-7,8-dihydroguanine and their corresponding oligonucleotides with normal guanine, but piperidine-sensitive damage was induced more frequently in the former than in the latter. Sequence analysis of irradiated oligonucleotides showed that not only 8-oxo-7,8-dihydroguanine but also its neighboring bases and the cytosine residue that is paired to it became piperidine-sensitive in both oligonucleotides. These results suggest that 8-oxo-7,8-dihydroguanine, its neighboring bases and the opposite cytosine are candidates for radiation damage hot spots.

Products from polycrystalline DNA constituents after X-irradiation and heavy-ion bombardment: formation of the 5,6-dihydroadduct in thymidine 5'-monophosphate and release of unaltered bases in nucleotides

PURPOSE

The major products from polycrystalline purine and pyrimidine DNA nucleotides after low- and high-LET irradiation were investigated quantitatively by HPLC and 1H-NMR spectroscopy.

MATERIALS AND METHODS

Solid nucleotide samples were either X-irradiated as cylindrical pellets or heavy-ion bombarded (LET range of 100-12,500 keV/microm) as very thin tablets at 300K. Product analysis was performed by HPLC and 1H-NMR.

RESULTS

For TMP the 5,6-dihydroadduct was found to be formed as product of electron reaction. In addition, all four DNA nucleotides showed a radiation-induced base release, which is probably connected with the oxidative radiation action. The formation of the products was linear with dose up to 300 kGy for X-irradiation or 200 kGy for heavy-ion bombardment. The estimation of the radiation chemical yields revealed G-values of about 10(-7) mol x J(-1) and were typically smaller for irradiation with charged particles than those for X-rays. After heavy-ion bombardment the G-values first increased with increasing LET and decreased for very heavy ions.

CONCLUSIONS

The yields for base release from both purine and pyrimidine nucleotides are comparable in magnitude. The 5,6-dihydroadduct from TMP is a major radiation induced product with larger yields than found for base release after X-irradiation and comparable yields after heavy-ion bombardment. The LET dependence of the G-values for base release in nucleotides is similar and resembles the double strand break formation in DNA. The observed similarity in the LET dependence of the G-values might derive from an inhomogeneous distribution of energy deposition resulting in 'clustered damage'.

Damage induced by 1-30 eV electrons on thymine- and bromouracil-substituted oligonucleotides

The impact of low-energy (1-30 eV) electrons on self-assembled monolayers of heterogeneous oligonucleotides chemisorbed on a gold surface has been investigated by mass spectrometry of desorbed neutral species in an attempt to understand the consequences of secondary electron damage in a short sequence of a DNA single strand. We demonstrate that the most intense observable neutral species (CN, OCN and/or H(2)NCN) desorbed from Cy(6)-Th(3) and Cy(6)-(BrdU)(3) oligos are related to primary fragmentation of the bases induced by electron impact. The dependence of the neutral species desorption on electron energy shows typical signatures of dissociative electron attachment initiated by the formation of shape- and core-excited resonances (i.e. single-electron and two-electron- one-hole transitory anions, respectively). Substitution of dTh by BrdU increases the production of neutral fragments by as much as a factor of about 3 for the entire electron energy range. When the distribution of secondary electrons along radiation tracks in H(2)O is taken into account, we show that the probability for electron damage to heterogeneous oligonucleotides is enhanced by a factor of 2.5-3 for electron energies below 20 eV for both sensitized and unsensitized strands.

Mass spectral characterization of a protein-nucleic acid photocrosslink

A photocrosslink between basic fibroblast growth factor (bFGF155) and a high affinity ssDNA oligonucleotide was characterized by positive ion electrospray ionization mass spectrometry (ESIMS). The DNA was a 61-mer oligonucleotide photoaptamer bearing seven bromodeoxyuridines, identified by in vitro selection. Specific photocrosslinking of the protein to the oligonucleotide was achieved by 308 nm XeCl excimer laser excitation. The cross-linked protein nucleic acid complex was proteolyzed with trypsin. The resulting peptide crosslink was purified by PAGE, eluted, and digested by snake venom phosphodiesterase/alkaline phosphatase. Comparison of the oligonucleotide vs. the degraded peptide crosslink by high performance liquid chromatography coupled to an electrospray ionization triple quadrupole mass spectrometer showed a single ion unique to the crosslinked material. Sequencing by collision induced dissociation (MS/MS) on a triple quadrupole mass spectrometer revealed that this ion was the nonapeptide TGQYKLGSK (residues 130-138) crosslinked to a dinucleotide at Tyr133. The MS/MS spectrum indicated sequential fragmentation of the oligonucleotide to uracil covalently attached to the nonapeptide followed by fragmentation of the peptide bonds. Tyr133 is located within the heparin binding pocket, suggesting that the in vitro selection targeted this negative ion binding region of bFGF155.