Synthesis and properties of DNA oligomers containing 2'-deoxynucleoside N-oxide derivatives

Cytosine and adenine N-oxide derivatives have long been known as products resulting from the oxidative damage of DNA by peroxides such as hydrogen peroxide. Although the synthesis and properties of 2'-deoxynucleoside N-oxide derivatives have been well described, little has been reported about the chemical and biochemical behavior of initially formed DNA oligomers containing these N-oxide bases. In this study, we established a convenient method for the solid-phase synthesis of oligodeoxynucleotides incorporating 2'-deoxycytidine N-oxide (dC O) or 2'-deoxyadenosine N-oxide (dA O) by using the postsynthetic oxidation of N-protected DNA oligomers except for the target dC or dA site with m-CPBA in MeOH in a highly selective manner. In this strategy, the benzoyl, phthaloyl, and (4-isopropylphenoxy)acetyl groups proved to serve as base protecting groups to avoid oxidation of adenine, cytosine, and guanine, respectively, at the unmodified sites.     

Silver Ions in Non‐canonical DNA Base Pairs: Metal‐Mediated Mismatch Stabilization of 2′‐Deoxyadenosine and 7‐Deazapurine Derivatives with 2′‐Deoxycytidine and 2′‐Deoxyguanosine

Novel silver‐mediated dA?dC, dA*?dC, and dA*?dG base pairs were formed in a natural DNA double helix environment (dA* denotes 7‐deaza‐dA, 7‐deaza‐7‐iodo‐dA, and 7‐cyclopropyl‐7‐deaza‐dA). 7‐Deazapurine nucleosides enforce silver ion binding and direct metal‐mediated base pair formation to their Watson–Crick face. New phosphoramidites were prepared from 7‐deaza‐dA, 7‐deaza‐7‐iodo‐dA, and 7‐cyclopropyl‐7‐deaza‐dA, which contain labile isobutyryl protecting groups. Solid‐phase synthesis furnished oligonucleotides that contain mismatches in near central positions. Increased thermal stabilities (higher T_m values) were observed for oligonucleotide duplexes with non‐canonical dA*?dC and dA?dC pairs in the presence of silver ions. The stability of the silver‐mediated base pairs was pH dependent. Silver ion binding was not observed for the dA?dG mismatch but took place when mismatches were formed between 7‐deazaadenine and guanine. The specific binding of silver ions was confirmed by stoichiometric UV titration experiments, which proved that one silver ion is captured by one mismatch. The stability increase of canonical DNA mismatches might have an impact on cellular DNA repair.     

Thermodynamic versus kinetic products of DNA alkylation as modeled by reaction of deoxyadenosine.

Alkylating agents that react through highly electrophilic quinone methide intermediates often express a specificity for the weakly nucleophilic exocyclic amines of deoxyguanosine (dG N(2)) and deoxyadenosine (dA N(6)) in DNA. Investigations now indicate that the most nucleophilic site of dA (N1) preferentially, but reversibly, conjugates to a model ortho-quinone methide. Ultimately, the thermodynamically stable dA N(6) isomer accumulates by trapping the quinone methide that is transiently regenerated from collapse of the dA N1 adduct. Alternative conversions of the dA N1 to the dA N(6) derivative by a Dimroth rearrangement or other intramolecular processes are not competitive under neutral conditions, as demonstrated by studies with [6-(15)N]-dA. Both a model quinone methide precursor and its dA N1 adduct yield a similar profile of deoxynucleoside products when treated with an equimolar mixture of dC, dA, dG, and T. Consequently, the most readily observed products of DNA modification resulting from reversible reactions may reflect thermodynamic rather than kinetic selectivity.     

pH‐Independent Recognition of the dG ⋅ dC Base Pair in Triplex DNA: 9‐Deazaguanine N7‐(2′‐Deoxyribonucleoside) and Halogenated Derivatives Replacing Protonated dC

Triplex-forming oligonucleotides (TFOs) containing 9-deazaguanine N⁷-(2′-deoxyribonucleoside) 1a and halogenated derivatives 1b,c were synthesized employing solid-phase oligonucleotide synthesis. For that purpose, the phosphoramidite building blocks 5a – c and 8a – c were synthesized. Multiple incorporations of 1a – c in place of dC were performed within TFOs, which involved the sequence of five consecutive 1a – c ⋅ dG ⋅ dC triplets as well as of three alternating 1a – c ⋅ dG ⋅ dC and dT ⋅ dA ⋅ dT triplets. These TFOs were designed to bind in a parallel orientation to the target duplex. Triplex forming properties of these oligonucleotides containing 1a – c in the presence of Na⁺ and Mg²⁺ were studied by UV/melting-curve analysis and confirmed by circular-dichroism (CD) spectroscopy. The oligonucleotides containing 1a in the place of dC formed stable triplexes at physiological pH in the case of sequence of five consecutive 1a ⋅ dG ⋅ dC triplets as well as three alternating 1a – c ⋅ dG ⋅ dC and dT ⋅ dA ⋅ dT triplets. The replacement of 1a by 9-halogenated derivatives 1b,c further enhanced the stability of DNA triplexes. Nucleosides 1a – c also stabilized duplex DNA.     

Parallel-stranded DNA: enhancing duplex stability by the 'G-clamp' and a pyrrolo-dC derivative

The new pyrrolo-dC derivative 4 tethered with an alkylamino side chain via a triazole linker was synthesized. Oligonucleotides containing the G-clamp 3 or the pyrrolo-dC derivative 4 were prepared. Oligonucleotide synthesis and deprotection under standard conditions led to unwanted side product formation. The side product was identified as an acrylonitrile adduct of the aminoalkyl side chain. Changing the synthesis and work-up conditions to fast-deprotection chemistry and performing β-elimination of the cyanoethyl group on the solid support yielded pure oligonucleotides. Oligonucleotide duplexes with parallel chain orientation were constructed incorporating dA·dT and isoG(d)·dC base pairs. Replacement of dC-residues by the G-clamp 3 led to extraordinarily stable duplexes (ΔT(m) = +11 °C for two incorporations) in ps DNA, while the pyrrolo-dC derivative 4 behaved like dC. Surprisingly, the G-clamp 3 forms an even more stable base pair with 2'-deoxyisoguanosine in DNA with parallel chain orientation than with 2'-deoxyguanosine in aps DNA.     

Nucleoside-metallacarborane conjugates for base-specific metal labeling of DNA

A general approach to the synthesis of nucleoside conjugates between derivatives of thymidine (T), 2'-O-deoxycytidine (dC), 2'-O-deoxyadenosine (dA), and 2'-O-deoxyguanosine (dG), and metallacarborane complexes is described. Metallacarborane-nucleoside derivatives are prepared by reaction of the dioxane-metallacarborane adduct with a base-activated 3',5'-protected nucleoside. In the case of T and dG a mixture of regioisomers, which is easily separable by chromatographic methods, is obtained, thus yielding a series of modifications containing metallacarborane groups at the 2-O, 3-N, 4-O and 1-N, 2-N, 6-O locations, respectively; dC and dA are alkylated at the exo-amino function. The proposed methodology provides a route for the synthesis and study of nucleic acids modified with metallacarboranes at designated locations and a versatile approach to the incorporation of metals into DNA.     

Naphthalene Imide Conjugates: Formation of Supramolecular Assemblies,and the Encapsulation and Release of Dyes through DNA‐Mediated Disassembly

We report the synthesis of two new amphiphilic conjugates 1 and 2 based on naphthalene di‐ and monoimide chromophores and the investigation of their photophysical, self‐assembly and DNA‐binding properties. These conjugates showed aqueous good solubility and exhibited strong interactions with DNA and polynucleotides such as poly(dG?dC)–poly(dG?dC) and poly(dA?dT)–poly(dA?dT). The interaction of these conjugates with DNA was evaluated by photo‐ and biophysical techniques. These studies revealed that the conjugates interact with DNA through intercalation with association constants in the order of 5–8×10⁴ M ^?1. Of these two conjugates, bolaamphiphile 1 exhibited a supramolecular assembly that formed vesicles with an approximate diameter of 220 nm in the aqueous medium at a critical aggregation concentration of 0.4 mM , which was confirmed by SEM and TEM. These vesicular structures showed a strong affinity for hydrophobic molecules such as Nile red through encapsulation. Uniquely, when exposed to DNA the vesicles disassembled, and therefore this transformation could be utilised for the encapsulation and release of hydrophobic molecules by employing DNA as a stimulus.     

Base pairing and replicative processing of the formamidopyrimidine-dG DNA lesion

The 2,6-diamino-4-hydroxy-5-formamidopyrimidine of 2'-deoxyguanosine (FaPydG) is one of the major DNA lesions found after oxidative stress in cells. To clarify the base pairing and coding potential of this major DNA lesion with the aim to estimate its mutagenic effect, we prepared oligonucleotides containing a cyclopentane based analogue of the DNA lesion (cFaPydG). In addition, oligonucleotides containing the cyclopentane analogue of 2'-deoxyguanosine (cdG), and oligonucleotides containing 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxodG) were synthesized. The thermodynamic stability of duplexes containing these building blocks and all canonical counterbases were determined by concentration dependent melting-point measurements (van't Hoff plots). The data reveal that cFaPydG greatly destabilizes a DNA duplex (DeltaDeltaG degrees (298K) approximately 2-4 kcal mol(-1)). The optimal base pairing partner for the cFaPydG lesion is dC. Investigation of duplexes containing dG and cdG shows that the effect of substituting the deoxyribose by a cyclopentane moiety is marginal. The data also provide strong evidence that the FaPydG lesion is unable to form a base pair with dA. Our computational studies indicate that the syn-conformation required for base pairing with dA is energetically unfavorable. This is in contrast to 8-oxodG for which the syn-conformation represents the energetic minimum. Kinetic primer extension studies using S. cerevisiae Pol eta reveal that cFaPydG is replicated in an error-free fashion. dC is inserted 2-3 orders of magnitude more efficiently than dT or dA, showing that FaPydG is a lesion which retains the coding potential of dG. This is also in contrast to 8-oxodG, for which base pairing with dC and dA was established.     

Chemical properties of oxopropenyl adducts of purine and pyrimidine nucleosides and their reactivity toward amino acid cross-link formation

N2-oxopropenyldeoxyguanosine (2) forms in duplex DNA by modification of dG residues with base propenal or malondialdehyde. The pKa of 2 was estimated to be 6.9 from the pH dependence of its ring-closing to the pyrimidopurinone derivative 1. The acidity of 2 may be an important determinant of its miscoding properties and its reactivity to nucleophiles in DNA or protein. To test this hypothesis, analogous N-oxopropenyl derivatives of dA (4), dC (5), and N1-methyl-dG (6) were synthesized and their pKa's were determined by optical titration. The N-oxopropenyl derivatives of dA and dC both exhibited pKa's of 10.5, whereas the N-oxopropenyl derivative of N1-methyldG exhibited a pKa of 8.2. Cross-linking of 2, 4, 5, and 6 to N(alpha)-acetyl-lysine was explored at neutral pH. Adduct 2 did not react with N(alpha)-acetyl-lysine, whereas 4-6 readily formed cross-links. The structures of the cross-links were elucidated, and their stabilities were investigated. The results define the acidity of oxopropenyl deoxynucleosides and highlight its importance to their reactivity toward nucleophiles. This study also identifies the structures of a potential novel class of DNA-protein cross-links.     

In situ synthesis of oligonucleotide arrays by using surface tension

This work describes the in situ synthesis of oligonucleotide arrays on glass surfaces. These arrays are composed of features defined and separated by differential surface tension (surface tension arrays). Specifically, photolithographic methods were used to create a series of spatially addressable, circular features containing an amino-terminated organosilane coupled to the glass through a siloxane linkage. Each feature is bounded by a perfluorosilanated surface. The differences in surface energies between the features and surrounding zones allow for chemical reactions to be readily localized within a defined site. The aminosilanation process was analyzed using contact angle, X-ray photoelectron spectroscopy (XPS), and time-of-flight/secondary ion mass spectroscopy (TOF-SIMS). The efficiency of phosphoramidite-based oligonucleotide synthesis on these surface tension arrays was measured by two methods. One method, termed step-yields-by-hybridization, indicates an average synthesis efficiency for all four (A,G,C,T) bases of 99.9 +/- 1.1%. Step yields measured for the individual amidite bases showed efficiencies of 98.8% (dT), 98.0% (dA), 97.0% (dC), and 97.6% (dG). The second method for determining the amidite coupling efficiencies was by capillary electrophoresis (CE) analysis. Homopolymers of dT (40- and 60mer), dA (40mer), and dC (40mer) were synthesized on an NH(4)OH labile linkage. After cleavage, the products were analyzed by CE. Synthesis efficiencies were calculated by comparison of the full-length product peak with the failure peaks. The calculated coupling efficiencies were 98.8% (dT), 96.8% (dA), and 96.7% (dC).     

1,1-Dihydroperoxycyclododecane as a new, crystalline non-hygroscopic oxidizer for the chemical synthesis of oligodeoxyribonucleotides

A new oxidation method for DNA synthesis was developed by the use of 1,1-dihydroperoxycyclododecane in CH₂Cl₂-EtOAc under anhydrous conditions. This new oxidizer was successfully applied to the synthesis of oligodeoxyribonucleotides that involves an oxidation step for conversion of phosphite intermediates to phosphate derivatives.     

Synthesis of Nucleobase‐Functionalized Carbon Nanotubes and Their Hybridization with Single‐Stranded DNA

For the first time ssDNA (25‐aptamer of mixed dA, dT, dG, and dC) was wrapped around functionalized single‐walled carbon nanotubes (SWCNTs), whose external surfaces were attached to multiple triazole‐(ethylene glycol)‐dA ligands. This method of hybridization involved the formation of hydrogen bonds between dT of ssDNA and dA of functionalized SWCNTs. It deviates from the reported π–π stacking between the nucleobases of DNA and the external sidewalls of nanotubes. The structural properties of the functionalized SWCNTs and its ssDNA complex were characterized by spectroscopic (including CD and Raman), thermogravimetric, and microscopic (TEM) methods. The results thus obtained establish a new platform of DNA delivery by use of nanotubes as a new vehicle with great potential in biomedical applications and drug development.     

Synthesis and incorporation of a furan-modified adenosine building block for DNA interstrand crosslinking

2'-O-(3-(Furan-2-yl)propyl)adenosine was synthesized and evaluated for interstrand crosslink (ICL) formation in DNA duplexes. In situ oxidation of the furan moiety with NIS showed rapid crosslink formation to dA and dC, while dT and dG were inactive.     

Photoswitchable Formation of a DNA Interstrand Cross‐Link by a Coumarin‐Modified Nucleotide

A coumarin‐modified pyrimidine nucleoside ( 1 ) has been synthesized using a Cu^I‐catalyzed click reaction and incorporated into oligodeoxynucleotides (ODNs). Interstrand cross‐links are produced upon irradiation of ODNs containing 1 at 350 nm. Cross‐linking occurs through a [2+2] cycloaddition reaction with the opposing thymidine, 2′‐deoxycytidine, or 2′‐deoxyadenosine. A much higher reactivity was observed with dT than dC or dA. Irradiation of the dT‐ 1 and dC‐ 1 cross‐linked products at 254 nm leads to a reversible ring‐opening reaction, while such phenomena were not observed with dA‐ 1 adducts. The reversible reaction is ultrafast and complete within 50–90 s. Consistent photoswitching behavior was observed over 6 cycles of irradiation at 350 nm and 254 nm. To the best of our knowledge, this is the first example of photoswitchable interstrand cross‐linking formation induced by a modified pyrimidine nucleoside.     

Efficient synthesis of 5-hydroxymethylcytosine containing DNA

5-Hydroxymethylcytosine ((5-HOMe)dC) was recently discovered as the sixth base in the mammalian genome. The development of a new phosphoramidite building block is reported, which allows efficient synthesis of (5-HOMe)dC containing DNA. Key steps of the synthesis are a palladium-catalyzed formylation and the simultaneous protection of a hydroxyl and amino group as a cyclic carbamate. DNA synthesis is possible under standard conditions, and deprotection can be carried out with dilute NaOH.     

Synthesis of nucleoside mono- and triphosphates bearing oligopyridine ligands, their incorporation into DNA and complexation with transition metals

Modified nucleoside mono- (dA(R)MPs and dC(R)MPs) and triphosphates (dA(R)TPs and dC(R)TPs) bearing bipyridine or terpyridine ligands attached via acetylene linker were prepared by single-step aqueous-phase Sonogashira cross-coupling of 7-iodo-7-deaza-dAMP or -dATP, and 5-iodo-dCMP or -dCTP with the corresponding bipyridine- or terpyridine-linked acetylenes. The modified dN(R)TPs were successfully incorporated into the oligonucleotides by primer extension experiment (PEX) using different DNA polymerases and the PEX products were used for post-synthetic complexation with Fe(2+).     

A new strategy for the synthesis of oligodeoxynucleotides directed towards perfect O-selective internucleotidic bond formation without base protection

Deoxyadenosine and deoxycytidine have nucleophilic amino groups so that the undesired N-phosphitylation of these amino groups occurred in the previous phosphoramidite methods without base protection. We report that the N-phosphitylation could be considerably suppressed in our new HOBt-mediated coupling strategy via phosphite intermediates as reactive species. Thus, 99.7-99.9% O-selective internucleotidic bond formation was achieved.     

Improved synthesis and mutagenicity of oligonucleotides containing 5-hydroxymethylcytosine, 5-formylcytosine and 5-carboxylcytosine

5-Formylcytosine (fC or (5-CHO)dC) and 5-carboxylcytosine (caC or (5-COOH)dC) have recently been identified as constituents of mammalian DNA. The nucleosides are formed from 5-methylcytosine (mC or (5-Me)dC) via 5-hydroxymethylcytosine (hmC or (5-HOMe)dC) and are possible intermediates of an active DNA demethylation process. Here we show efficient syntheses of phosphoramidites which enable the synthesis of DNA strands containing these cytosine modifications based on Pd(0)-catalyzed functionalization of 5-iododeoxycytidine. The first crystal structure of fC reveals the existence of an intramolecular H-bond between the exocyclic amine and the formyl group, which controls the conformation of the formyl substituent. Using a newly designed in vitro mutagenicity assay we show that fC and caC are only marginally mutagenic, which is a prerequisite for the bases to function as epigenetic control units.     

SUBSTRATE DEPENDENCE OF THE ACTION SPECTRUM FOR PHOTOENZYMATIC REPAIR OF DNA

Abstract— The absolute action spectrum has been determined for photoenzymatic splitting of cyclobutadipyrimidines ("pyrimidine dimers") from natural DNA, and from the synthetic polydeoxyribonucleotides poly(dA)·poly(dT) (forming only cyclobutadithymine) and poly(dG)·poly(dC) (forming only cyclobutadicytosine). These action spectra differ strikingly from each other, even when using the same enzyme preparations. On the other hand, the action spectrum for splitting cyclobutadithymine in natural DNA containing "dimers" of only this one type closely resembles the action spectrum for splitting the total mixture of "dimer" types in natural DNA, and is entirely different from the spectrum for splitting of the same photoproduct from poly(dA)·poly(dT). These results mean that the action spectrum is not simply the absorption spectrum of a chromophore carried by the photoreactivating enzyme, nor is it solely determined by the nature of the substrate photoproduct. It is at least partly determined by the over-all polynueleotide structure (viz. exact helical dimensions, pattern of neighboring bases to the "dimers," or both), affecting a ground state interaction between the enzyme and substrate in the enzyme-substrate complex.     

Oligonucleotide incorporation of 8-thio-2'-deoxyguanosine

[reaction: see text] 8-Thio-2'-deoxyguanosine (SdG) is a useful analogue of the abundant promutagen 8-oxo-2'-deoxyguanosine (OdG). Its synthesis and DNA incorporation using standard phosphoramidite chemistry is reported. To prevent oxidation during DNA synthesis, the sulfur was protected as a 2-(trimethylsilyl)ethyl sulfide. Subsequent treatment with TBAF yielded the desired 8-thiocarbonyl functionality. Melting studies with SdG revealed almost equal stabilities of SdG:dC and SdG:dA base pairs, lending insight into the base-pairing preferences of OdG.