Fragmentation of photomodified oligodeoxynucleotides adducted with metal ions in an electrospray-ionization ion-trap mass spectrometer

We report the effect of metal-ion adduction on the fragmentation of oligodeoxynucleotides (ODNs) bearing DNA photoproducts. When protons on backbone phosphates of ODNs are completely replaced with metal ions, cleavages occur readily within the photoproduct moiety, whereas those cleavages do not occur in photomodified ODNs in which the phosphates are associated with protons. For example, thymine/adenine (TA*) photoproducts revert to their undamaged precursors upon collisional activation, the pyrimidine(6-4)pyrimidone product and its Dewar valence isomer show a characteristic neutral loss of C4H3NO3, and dimeric adenine photoproducts show a distinctive loss of NH2CN from the adenine six-membered ring. The product-ion mass spectra of photodamaged ODNs that are adducted to metal ions are complementary in terms of structure information to those spectra of ODNs in which the phosphates are associated with protons. The results also demonstrate that the energy required for strand cleavages is higher for ODNs adducted with metal ions than that for ODNs bound with protons. Furthermore, the loss of a pyrimidine is more favorable than the loss of a purine in the fragmentation of ODNs associated with metal ions.     

Characterization of labeled oligonucleotides using enzymatic digestion and tandem mass spectrometry

A simple and powerful method for the determination of labeling sites on oligodeoxynucleotides (ODN) has been developed. The method is based on the finding that nuclease P1 (NP1) digestions of label-containing ODNs produce site-specific products: 5′-labeled ODNs produce label-nucleotide (L-N); 3′-labeled ODN produces phosphorylated label (pL); and a label in between the ODN termini produces pL-N. Mass spectrometry spectra of these products from the digestion mixture can be easily utilized for structural verification of labeled ODNs such as DNA probes. We also developed a method for the determination of the labeling sites of ODNs with unknown label structures. In this method, NP1 digestion products generate site-specific fragmentation patterns upon collision-induced dissociation. These patterns can be easily recognized and used for the identification of labeling sites of ODNs with unknown label structures. When an ODN is internally labeled, phosphodiesterase digestion may be used to determine the exact labeling site (sequence location). It was demonstrated that these methods can be applied for ODNs with single or multiple labels, and for ODNs with the same or different labels within an ODN.     

2-Oxoalkyl caged oligonucleotides: one-electron reductive activation into emergence of ordinary hybridization property by hypoxic X-irradiation

Ionizing radiation triggers the activation of caged oligodeoxynucleotides (ODNs) with a 2-oxoalkyl leaving group to give the corresponding normal uncaged strands. We designed and synthesized ODNs caged by a 2-oxopropyl group at a given thymine N(3) position (d(oxo)T) to evaluate their one-electron reduction characteristics. Upon hypoxic X-radiolysis in aqueous solution, the caged ODNs released the 2-oxopropyl group to produce the corresponding uncaged ODNs. Digestion by a restriction enzyme Swa I revealed that caged ODN pre-irradiated in hypoxia could form an ordinary duplex with its complementary strand.     

Versatile introduction of azido moiety into oligonucleotides through diazo transfer reaction

The use of a diazo transfer (DZT) reagent enables clean and efficient conversion of aminated oligodeoxyribonucleotides (ODNs) into their azido counterparts under mild conditions. ODNs bearing an amino tether at the 3', 5', or any internal position could be modified in this manner thus demonstrating the versatility of this reaction. Easy access to such azido-modified ODNs is of great interest for conjugation in particular through copper catalyzed 1,3-dipolar cycloaddition (CuAAC reaction).     

Sequence verification of oligonucleotides containing multiple arylamine modifications by enzymatic digestion and liquid chromatography mass spectrometry (LC/MS)

An analytical method for the structure differentiation of arylamine modified oligonucleotides (ODNs) using on-line LC/MS analysis of raw exonuclease digests is described. Six different dodeca ODNs derived from the reaction of N-acetoxy-N-(trifluoroacetyl)-2-aminofluorene with the dodeca oligonucleotide 5'-CTCGGCGCCATC-3' are isolated and sequenced with this LC/MS method using 3'- and 5'-exonucleases. When the three products modified by a single aminofluorene (AF) are subjected to 3'-exonuclease digestion, the exonuclease will cleave a modified nucleotide but when di-AF modified ODNs are analyzed the 3'-exonuclease ceases to cleave nucleotides when the first modification is exposed at the 3'-terminus. Small abundances of ODN fragments formed by the cleavage of an AF-modified nucleotide were observed when two of the three di-AF modified ODNs were subjected to 5'-exonuclease digestion. The results of the 5'-exonuclease studies of the three di-AF modified ODNs suggest that as the number of unmodified bases between two modifications in an ODN sequence increases, the easier it becomes to sequence beyond the modification closest to the 5'-terminus. The results of this study indicate that the LC/MS method described here would be useful in sequencing ODNs modified by multiple arylamines to be used as templates for site-specific mutagenesis studies.     

Detection of secondary structures in 17-mer Ru(II)-labeled single-stranded oligonucleotides from luminescence lifetime studies

The emission properties of a non intercalating complex, [Ru(TAP)2(dip)]2+ (TAP = 1,4,5,8-tetraazaphenanthrene; dip = 4,7-diphenyl-1,10-phenanthroline), tethered to 17-mer single-stranded oligodeoxyribonucleotides (ODNs) either in the middle or at the 5'-end of the sequence, are determined. The results highlight the fact that the luminescence of this metallic compound is sufficiently sensitive to its microenvironment to probe self-structuration of these short single-stranded ODNs. It is shown that the weighted averaged emission lifetimes (tau(M)) along with the quenching rate constants of luminescence by oxygen reflect particularly well different structures adopted by the different ODNs sequences. The determination of these parameters thus offers an elegant way to examine possible structurations of synthetic single-stranded ODNs that play important roles in biological applications.     

Multiple-pyrene residues arrayed along DNA backbone exhibit significant excimer fluorescence

Oligodeoxyribonucleotides (ODNs) carrying multi-pyrene clusters were chemically prepared by introducing a novel nucleoside-pyrene conjugate into ODNs. The multi-pyrene residues arrayed on DNA strands induced significant excimer fluorescence and the intensity was exponentially increased as the number of pyrene residues in clusters increased. The excimer fluorescence of the arrays was stable and was not quenched by duplex formation.     

Oligo-2'-deoxyribonucleotides containing uracil modified at the 5-position with linkers ending with guanidinium groups

We report here the synthesis and binding studies of oligo-2'-deoxyribonucleotides (ODNs) containing 2'-deoxyuridines, modified at the 5-position by linkers ending with either one or two guanidinium groups. Comparison was made with ODNs containing 2'-deoxyuridines modified at the 5-position with linkers ending with either two or one amino groups. One or two modified 2'-deoxyuridines were incorporated into pyrimidine strands, and their influence on the stability of duplex (with both DNA and RNA targets) and triplex structures was studied. The strongest stabilization was obtained with modified ODNs containing guanidinium groups. This result confirms that the reduction of the global negative charge number on one strand is an important parameter in the stability of duplex and triplex structures.     

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.     

Solid-phase synthesis, thermal denaturation studies, nuclease resistance, and cellular uptake of (oligodeoxyribonucleoside)methylborane phosphine-DNA chimeras

The major hurdle associated with utilizing oligodeoxyribonucleotides for therapeutic purposes is their poor delivery into cells coupled with high nuclease susceptibility. In an attempt to combine the nonionic nature and high nuclease stability of the P-C bond of methylphosphonates with the high membrane permeability, low toxicity, and improved gene silencing ability of borane phosphonates, we have focused our research on the relatively unexplored methylborane phosphine (Me-P-BH(3)) modification. This Article describes the automated solid-phase synthesis of mixed-backbone oligodeoxynucleotides (ODNs) consisting of methylborane phosphine and phosphate or thiophosphate linkages (16-mers). Nuclease stability assays show that methylborane phosphine ODNs are highly resistant to 5' and 3' exonucleases. When hybridized to a complementary strand, the ODN:RNA duplex was more stable than its corresponding ODN:DNA duplex. The binding affinity of ODN:RNA duplex increased at lower salt concentration and approached that of a native DNA:RNA duplex under conditions close to physiological saline, indicating that the Me-P-BH(3) linkage is positively charged. Cellular uptake measurements indicate that these ODNs are efficiently taken up by cells even when the strand is 13% modified. Treatment of HeLa cells and WM-239A cells with fluorescently labeled ODNs shows significant cytoplasmic fluorescence when viewed under a microscope. Our results suggest that methylborane phosphine ODNs may prove very valuable as potential candidates in antisense research and RNAi.     

Template directed reversible photochemical ligation of oligodeoxynucleotides

We demonstrated that 5-vinyldeoxyuridine ((V)U) and 5-carboxyvinyldeoxyuridine ((CV)U) can be used to photoligate a longer oligonucleotide (ODN) from smaller ODNs on a template. By performing irradiation at 366 nm, these artificial nucleotides make photoligated ODNs with high efficiency without any side reactions. Moreover, by performing irradiation at 312 nm, these photoligated ODNs were reversed to the original ODN. (V)U needs to be irradiated 366 nm for 6 h, but (CV)U needs to be irradiated at 366 nm for 15 min. Finally, we made a self-assembled structure with an ODN containing (CV)U and observed the photoligated ODN by photoirradiation.     

Determination of photomodified oligodeoxynucleotides by exonuclease digestion, matrix-assisted laser desorption/ionization and post-source decay mass spectrometry

A fast method to detect and sequence photomodified oligodeoxynucleotides (ODNs) by exonuclease digestion and matrix-assisted laser desorption/ionization (MALDI) mass spectrometry (MS) is reported. Upon treatment of modified ODNs with both phosphodiesterase I and phosphodiesterase II, the digestion stops at the sites of photomodification. Post-source decay (PSD) of MALDI-produced ions from two enzymatic digestion end products distinguishes isomers such as 5'-d(T[cis-syn]TAAGC) and 5'-d(CGAAT[cis-syn]T), which have symmetrical or identical compositions at the 3' and 5' ends, respectively. Studies have also been done to follow the kinetics for enzyme degradation of photomodified ODNs. The calculated rate constants from a mathematical treatment of the time-dependent MALDI data clearly show that the enzymatic digestion rate slows as the enzyme approaches the modified site.     

Hydrogel formation via hybridization of oligonucleotides derivatized in water-soluble vinyl polymers

Succinimido-copolymers, poly(N,N-dimethylacrylamide-co-N-acryloyloxysuccinimide)s, were coupled with 5′-terminal-amino-modified oligodeoxyribonucleotides (ODNs) to produce water-soluble copolymers partially derivatized with ODNs in their side chains. The mixing and thermal melting measurements of dilute mixed aqueous solutions of an ODN-derivatized copolymer and their complementary ODN and mixed solutions of complementary ODN-derivatized copolymers were monitored by ultraviolet spectroscopy. The results showed that hybrids were formed with their complementary ODNs at room temperature, but dissociated at high temperature. Based on the hybridization between complementary base pairs of nucleic acids and its thermal dissociation characteristics, two types of thermoresponsive hydrogels were prepared: (1) a hydrogel formed via hybridization between an oligodeoxythymidylate (oligoT)-derivatized copolymer and an oligodeoxyadenylate (oligoA), and (2) a hydrogel formed by hybridization between complementary oligoT- and oligoA-derivatized copolymers. Thus, selfassociation due to specific intermolecular hydrogen bonding between nucleic acid base pairs enabled the preparation of a novel thermoresponsive hydrogel.     

Synthesis and hybridization properties of oligonucleotide-perylene conjugates: influence of the conjugation parameters on triplex and duplex stabilities

We report here the synthesis of oligo-2'-deoxyribonucleotides (ODNs) conjugated with perylene. Introduction of perylene, coupled either directly or via a propyl linker to the anomeric position of a 2'-deoxyribose residue, induces the formation of two anomers. Single incorporations of each pure anomer of these sugar-perylene units have been performed at either the 5'-end or an internal position of a pyrimidic pentadecamer. The binding properties of these modified ODNs with their single- and double-stranded DNA targets were studied by absorption spectroscopy. Double incorporations of the sugar-perylene unit most efficient at stabilizing the triplex and duplex structures (the beta-anomer involving the propyl linker) have been performed at both the 5'-end and at an internal position (or both the 5'- and 3'-ends) of the ODN chain. Comparison has been made with ODN-perylene conjugates involving either one or two perylenes attached via a longer polymethylene chain to either the 5'- or 3'- (or both the 5'-and 3'-) terminal phosphate groups. The ODNs involving two perylenes are more efficient at stabilizing the triplex and the duplex structures than the ODNs involving only one perylene and, among these, the ODN-perylene conjugate involving two sugar-perylene units attached at both termini is the most efficient. The results of the fluorescence studies have shown an important increase in the intensity of the fluorescent signal upon hybridization of the ODNs involving two perylenes with either the single- or the double-stranded targets. This increase in the intensity of the fluorescent signal could be used as proof of the hybridization.     

Formation of spectral intermediate G-C and A-T anion complex in duplex DNA studied by pulse radiolysis

The dynamics of electron adducts of 2'-deoxynucleotides and oligonucelotides (ODNs) were measured spectroscopically by nanosecond pulse radiolysis. The radical anions of the nucleotides were produced within 10 ns by the reaction of hydrated electrons (e(aq)(-)) and were protonated to form the corresponding neutral radicals. At pH 7.0, the radical anion of deoxythymidine (dT(*-)) was protonated to form the neutral radical dT(H)(*) in the time range of microseconds. The rate constant for the protonation was determined as 1.8 x 10(10) M(-1) s(-1). In contrast, the neutral radical of dC(H)(*) was formed immediately after the pulse, suggesting that the protonation occurs within 10 ns. The transient spectra of excess electrons of the double-stranded ODNs 5'-TAATTTAATAT-3' (AT) and 5'-CGGCCCGGCGC-3' (GC) differed from those of pyrimidine radicals (C and T) and their composite. In contrast, the spectra of the electron adducts of the single-stranded ODNs GC and AT exhibited characteristics of C and T, respectively. These results suggest that, in duplex ODNs, the spectral intermediates of G-C and A-T anions complex were formed. On the microsecond time scale, the subsequent changes in absorbance of the ODN AT had a first-order rate constant of 4 x 10(4) s(-1), reflecting the protonation of T.     

Application of Elimination Voltammetry to the Resolution of Adenine and Cytosine Signals in Oligonucleotides II. Hetero‐Oligodeoxynucleotides with Different Sequences of Adenine and Cytosine Nucleotides

Elimination voltammetry with linear scan (EVLS) was applied to the resolution of reduction signals of adenine (A) and cytosine (C) residues in short synthetic hetero‐oligodeoxynucleotides (ODNs) with different sequences of A and C. The EVLS evaluation required linear sweep voltammograms measured on a hanging mercury drop electrode (HMDE) at different scan rates. Compared to linear sweep voltammetry (LSV) and usual voltammetric methods the EVLS is capable of resolving the overlapped A and C signals, specifically by using the elimination function which eliminates the charging and kinetic currents (I_c, I_k) and conserves the diffusion current (I_d). Since for an adsorbed electroactive substance this elimination function yields a well readable peak–counterpeak signal, the adsorptive stripping (AdS) procedure was favorably used. The adsorption of ODNs was carried out at ?0.1 V for accumulation time of 120 s under stirring. It was found that heights and potentials of LSV signals were affected by ODNs concentrations, pH, scan rates, time of accumulation, and stirring speed during the adsorption. While on LSV curves the only one reduction peak of A and C residues was observed in all ODNs, the EVLS yielded two separated peaks in dependence on A, C sequences and pH. Our results showed that the EVLS in connection with the AdS procedure is a useful tool for qualitative and quantitative studies of short ODNs and a promising sensitive method for the development of electrochemical sensor following the ODN sequences.     

Template-directed DNA photoligation via alpha-5-cyanovinyldeoxyuridine

[reaction: see text] We describe an efficient template-directed photoligation of oligodeoxynucleotides (ODNs) using alpha-5-cyanovinyldeoxyuridine (alpha(C)U). An efficient photoligation was produced by photoirradiation of an ODN containing alpha(C)U at the 3' end with an ODN containing thymine at the 5' end in the presence of a template ODN. This photoligation method is a new and efficient way to synthesize branched ODNs.     

A versatile modification of on-column oligodeoxynucleotides using a copper-catalyzed oxidative acetylenic coupling reaction

We report herein a versatile postsynthetic modification of on-column oligodeoxynucleotides (ODNs) using a copper-catalyzed oxidative acetylenic coupling reaction. Hexamers supported on resins via a methylamino-modified linker were prepared, and on-column modifications of ODNs were examined. ArgoPore resin proved to be the best choice for the modification, and introduction of functional molecules, such as anthraquinone, biotin, and fluorescein, resulted in good yields at not only the 5'-terminal but also the internal 3'-end of the ODNs. This method is applicable to the modification of 12mer ODN consisting of a random sequence. The resulting ODN9 possessing fluorescein at its 5'-terminal acts as a non-RI primer for primer extension assays using the Klenow fragment.     

Identification of unexpected modifications of fluorescein-labeled oligodeoxynucleotides by nuclease P1 digestion and mass spectrometric techniques

Fluorescein-labeled oligodeoxynucleotides (ODNs) from automated synthesis commonly produce multiple peaks in high performance liquid chromatography (HPLC) chromatograms. We found that these peaks are due to chemical modifications of the ODNs instead of the common perception of isomers. To identify the modifications, a model ODN, fluorescein-T(25), was synthesized and five compounds were isolated. Nuclease P1 (NP1) digestion was employed to cleave these compounds into nucleotides and fluorescein-nucleotides in order that the modifications be determined by mass spectrometry (MS). Analyses of NP1 digestion products containing fluorescein by MS revealed the expected product F1-T (M) and four unexpected compounds with MWs at M-1, M-17, M-16 and M + 16, respectively. Collision-induced dissociation (CID) spectra of these digestion products indicate that all modifications occur on the thiourea linkage [-NH-C( = S)-NH-] to the fluorescein moiety and the adjacent phosphate group, and the modifications were determined. The modifications were also confirmed by accurate mass measurement with Fourier transform mass spectrometry (FT-MS), by the synthesis of a reference compound, and by a mechanistic study using model compounds. These results demonstrate the power of the mass spectrometric techniques by determining the structures of two pairs of ODNs with MW difference of 1 Da. The results also suggest that fluorescein phosphoramidite with a thiourea linkage is not appropriate for the automated synthesis of fluorescein-labeled ODNs of high purity.     

Facile photocyclization chemistry of 5-phenylthio-2'-deoxyuridine in duplex DNA

We report here the synthesis of 5-phenylthio-2'-deoxyuridine (d(PhS)U), its incorporation into oligodeoxynucleotides (ODNs), and its photocyclization chemistry. Irradiation of dinucleoside monophosphate d((PhS)UG) and d(PhS)U-bearing duplex ODNs with 254 nm light results in the facile formation of a cyclic product where the C6 of uracil is covalently bonded to the C2 of the phenyl ring. The chemistry reported here may serve as the basis for the efficient preparation of a new class of duplex DNA with an extended pi system. [reaction: see text]