Sensitized photomodification of DNA with binary systems of oligonucleotide conjugates. V. Effect of the structure of the target DNA. Quantitative photomodification]

A sensitized photomodification of several single-stranded target DNAs by binary systems of oligonucleotide conjugates complementary to the adjacent regions of DNA was performed. One of the conjugates contained a sensitizer (pyrene, anthracene, or 1,2-benzanthracene), and another conjugate contained a photoreagent 4-azidotetrafluorobenzalhydrazone. The sensitized photomodification is initiated by irradiation at 365-580 nm due to effective energy transfer from the excited sensitizer to the photoreagent in a complementary complex of the binary system with the target DNA where the sensitizer and photoreagent are brought sterically together. Conditions for the quantitative photomodification of a single-stranded DNA by the binary system of oligonucleotide conjugates were found. The maximum degree of photomodification depends on the number of guanosine residues in the (pG)n sequence of the target DNA at the modification site: at n = 1 the yield of covalent adducts was 62-68%, at n = 2, 75-82%, and at n = 4, 98-99%.     

Sensitized photomodification of DNA with binary sysytems of oligonucleotide conjugates. VI. Effect of substituents in the anthracene residue of the sensitizer

Photomodification of ssDNA by binary systems of oligonucleotide conjugates complementary to the adjacent sequences of the target DNA was studied. One of the conjugates comprised a substituted anthracene as a sensitizer; the other, p-azidotetrafluorobenzaldehyde 3-aminopropionylhydrazone as a photoreagent. The sensitized photomodification is initiated by the 365-580-nm light through an efficient energy transfer from the photoexcitated sensitizer onto the photoreagent in a complementary complex of the binary system with the DNA target where the sensitizer and the photoreagent are sterically converged. Influence of substituents in the anthracene residue on the efficiency of the DNA sensitized photomodification was considered. The oligonucleotide conjugate of anthracene-9-al 3-aminopropionylhydrazone allows highly specific initiation of the sensitized photomodification upon irradiation with visible light at > 460 nm in conditions generating no photoreaction in the sensitizer's absence.     

Sensitized photomodification of DNA with binary systems of oligonucleotide conjugates. III. Double-quantum sensitization

Site-specific modification of single-stranded DNA by oligonucleotide derivatives of p-azido-O-(4-aminobutyl)tetrafluorobenzaldoxime sensitized by an oligonucleotide derivative of pyrenylethylamine was studied. Upon irradiation with the long-wave UV light (365-390 nm) of a DNA target-oligonucleotide reagent complementary complex, a considerable increase in the rate of sensitized photomodification at the G11 residue of the target relative to the direct photomodification was observed owing to the singlet-single energy transfer from the sensitizer onto the photoreagent. Upon simultaneous irradiation of the complex with UV and visible light in the region of the triplet-triplet absorption of pyrene (360-580 nm), an additional increase in the modification rate and a change in its site-direction (from the G11 to T13 residue) occurred through the two-photon triplet-triplet sensitization. The total extent of the structure photomodification amounted to 80%.     

Sensitized site-specific photomodification of ssDNA by binary systems of oligonucleotide conjugates: VI. Effect of substituents in the sensitizer anthracene residue

Photomodification of ssDNA by binary systems of oligonucleotide conjugates complementary to the adjacent sequences of the target DNA was studied. One of the conjugates comprised a substituted anthracene as a sensitizer; the other,p-azidotetrafluorobenzaldehyde 3-aminopropionylhydrazone as a photoreagent. The sensitized photomodification is initiated by the 365–580-nm light through an efficient energy transfer from the photoexcitated sensitizer onto the photoreagent in a complementary complex of the binary system with the DNA target where the sensitizer and the photoreagent are sterically converged. Influence of substituents in the anthracene residue on the efficiency of the DNA sensitized photomodification was considered. The oligonucleotide conjugate of anthracene-9-al 3-aminopropionylhydrazone allows highly specific initiation of the sensitized photomodification upon irradiation with visible light at >460 nm in conditions generating no photoreaction in the sensitizer’s absence. For Part V, see [1]; prefix “d” in designations of oligonucleotides is omitted.     

Effective complementarily-addressed photomodification of nucleic acids by oligonucleotide derivatives, containing aromatic azido groups]

Highly effective site-specific photomodification of a DNA-target was carried out with oligonucleotide reagents carrying aromatic azido groups. Oligonucleotide derivatives with a photoactive function R on the 5'-terminal phosphate and at C-5 atom of deoxyuridine were synthesized: R1NH(CH2)3NHpd(TCCACTT) and d(ULNHRCCACTT), where R1 is p-azidotetrafluorobenzoyl, R2 is 2-nitro, 5-azidobenzoyl, R3 is p-azidobenzoyl; LNH = -CH2NH-, -CH2OCH2CH2NH- or -CH2NHCOCH2CH2NH-. The prepared compounds form stable complementary complexes and effect site-specific photomodification of the target DNA. The modification of pentadecanucleotide d(TAAGTGGAGTTTGGC) with the reagents was investigated. Maximum extent of modification strongly depended on the reagent's type, the photoreagent with R1 being the most effective. Whatever the binding site was, this agent provided a 65-70% modification in all cases except LNH = -CH2NH-, when the yield was twice lower. For the reagents bearing R1 the modification sites were identified. Selective modification at the G9 residue was detected in the case of LNH = -CH2OCH2CH2NH- and when a photoactive group was linked to the terminal phosphate.     

Sensitized photomodification of mammalian DNA polymerase beta. A new approach for highly selective affinity labeling of polymerases

To enhance the specificity of polymerase photoaffinity labeling, a novel approach based on sensitized photomodification has been developed. A base-substituted analog of TTP containing a pyrene group (PyrdUTP) was synthesized and used as an active site-bound photosensitizer for photoaffinity modification of DNA polymerase beta (pol beta). 5'-[32P]-labeled primer was elongated in situ by pol beta with a photoreactive analog of TTP (FAB-4-dUTP). The pyrene sensitizer (PyrdUTP), excited by light (365-450 nm), can activate the photoreagent, cross-linking it to pol beta as a result of fluorescence resonance energy transfer. The initial rate of pol beta photomodification was shown to increase by a factor of ten. The selectivity of pol beta photosensitized modification was proved by adding human replication protein A.     

Photomodification of nucleic acids by N-(2-hydroxyethyl)phenazine derivatives of oligonucleotides

Photomodification of a 302-membered single-stranded DNA fragment by 5'-mono- and 3',5'-di-N-(2-oxyethyl)phenazine (Phn) derivatives of oligonucleotides has been investigated. Under strong laser irradiation (lambda 532 nm; power density 2,5 GV/cm2, irradiation dose 30 J) the DNA fragment in the presence of Phn-reagents was significantly destructed (up to 70-95%). The level of complementary addressed modification (24-51%) is a direct function of the length of oligonucleotide address of the photoreagent and the amount of Phn residues, stabilizing the complementary complex. The character of the nonaddressed modification is close to the statistic one, although for a number of photoreagents a rather efficient nonspecific modification of 5'-terminal sequence of target DNA has been detected. Of interest also is an unusually broad positional direction of the DNA fragment photomodification in the area of perfect complementary coupling of 5'-Phn-reagents.     

Chromatin proteins in rat liver cells, interacting with reactive oligothymidylate derivatives]

Upon alkylation of the rat liver chromatin with a hexadecadeoxyribothymidylate derivative bearing 4-(N-2-chloroethyl-N-methylamino)benzylamine residue on the 5'-terminal phosphate two nonhistone proteins were modified under conditions of the reagent's forming complementary complexes with poly(A) sequences in DNA. The sequence-specific nature of the reaction is proved by the competition experiments: free oligothymidylate prevented the proteins from alkylation whereas arbitrary oligonucleotide did not. Modification with the reactive oligonucleotide derivatives can be used for the identification of proteins located in the vicinity of the specific open DNA regions in chromatin.     

Sequence-specific chemical modification of a 365-nucleotide-long DNA fragment with an alkylating oligonucleotide derivative

An aromatic 2-chloroethylamino group was attached to the 5'-terminal phosphate of the oligodeoxyribonucleotide pCCCTCTTTCTT. The oligonucleotide derivative prepared was used for modification of the 365-nucleotide-long DNA fragment. It was found that modification of the fragment proceeds in a sequence-specific way at 3 guanosine residues within the sequence complementary to the oligonucleotide reagent.     

Cooperative Interactions in Photosensitized Modification of DNA with Oligonucleotide-derived Binary Reagents

Quantitative characteristics of thermodynamic and kinetic cooperativity arising in the process of photomodification of a single-stranded DNA fragment with binary systems of oligonucleotide conjugates forming an active site on the target were studied. Oligonucleotides of the binary system were complementary to adjacent segments of the DNA target, and contained arylazide (X) and perylene (S) residues covalently attached to their terminal phosphates. Upon irradiation at the perylene absorption wavelength, the target was modified by the arylazide residue, which was activated owing to the contiguity with the sensitizing perylene group in the tandem complex. Basing on the kinetic data, the constants of association of both derivatives of oligonucleotides with the target were determined: K _x = 1.13 · 10⁶ M^–1, K _s = 1.49 · 10⁴ M^–1. It was determined that association of both oligonucleotides with the target proceeded with a positive cooperativity characterized by parameter = 45. The kinetic cooperativity parameter was found to be approximately equal to 200; this characterized the acceleration of target modification in complex with the binary reagent versus that in the absence of sensitizer.     

Chemical reactions in double-stranded nucleic acids. The nature of the bond formed during chemical ligation using a cis-diol group

Chemical and enzymatic ligation between the 5'-terminal phosphate of one oligonucleotide and the 3'-terminal 2',3'-cis-diol group of the other oligonucleotide on a complementary template was studied. Carbodiimide, imidazolide and N-hydroxybenzotriazole ester methods were used for chemical activation of the phosphate group, and T4 DNA ligase for enzymatic ligation. All the chemical activation methods produced 3',5'- and 2',5'-phosphodiester bonds (40-45 and 55-60%, resp.), whereas enzymatic ligation gave the product only with 3',5'-phosphodiester bond.     

Synthesis and high stability of complementary complexes of N-(2-hydroxyethyl)phenazinium derivatives of oligonucleotides.

Two simple methods for the synthesis of oligonucleotides bearing a N-(2-hydroxyethyl)phenazinium (Phn) residue at the 5'- and/or 3'-terminal phosphate groups are proposed. By forming complexes between a dodecanucleotide d(pApApCpCpTpGpTpTpTpGpGpC), a heptanucleotide d(pCpCpApApApCpA), and Phn derivatives of the latter, it is shown that the introduction of a dye at the end of an oligonucleotide chain strongly stabilizes its complementary complexes. The Tmax and the thermodynamic parameters (delta H, delta S, delta G) of complex formation were determined. According to these data, coupling of a dye with the 5'-terminal phosphate group is the most advantageous: delta G(37 degrees C) is increased by 3.59 +/- 0.04 kcal/mol compared to 2.06 +/- 0.04 kcal/mol for 3'-Phn derivatives. The elongation of the linker, which connects the dye to the oligonucleotide, from a dimethylene up to a heptamethylene usually leads to destabilization of the oligonucleotide complex. The complementary complex formed by the 3',5'-di-Phn derivative of the heptanucleotide was found to be the most stable among all duplexes investigated. Relative to the unmodified complex the increase in free energy was 4.96 +/- 0.04 kcal/mol. The association constant of this modified complex at 37 degrees C is 9.5 x 10(6) M-1, whereas the analogous value for the unmodified complex is only 3 x 10(3) M-1.     

Fluorescent-labeled oligonucleotides that exhibit a measurable signal in the presence of complementary DNA.

Oligonucleotide derivatives with a fluorescent dye were designed for exhibiting a measurable signal only when they bind to complementary DNA in aqueous solution. The oligonucleotide with a dansyl group at the specific 2'-sugar residue was synthesized by using the protected 2'-dansylaminouridine phosphorobisamidite. The dansyl-oligonucleotide conjugate binds to its complementary DNA to form duplex with a normal stability and exhibits enhanced fluorescence together with a blue-shift in emission maxima after the hybridization. Another possible candidate involved the use of pyrene-excimer emission upon forming ternary complex between two pyrene-labeled oligonucleotide probes with target DNA. A new and general method for introduction of a pyrene fluorophore into the 3'- or 5'-terminal hydroxyl group of oligonucleotides via different linkers was developed.     

Ligation of oligonucleotides to nucleic acids or proteins via disulfide bonds.

We have developed general methods for joining together, via cleavable disulfide bonds, either two unprotected polynucleotides or a polynucleotide and a peptide or protein. To join two oligonucleotides, each is first converted to an adduct in which cystamine is joined to the 5'-terminal phosphate of the oligonucleotide by a phosphoramidate bond. The adducts are mixed and reduced with dithiothreitol. The dithiothreitol is then removed by dialysis. Oxidation by atmospheric oxygen occurs to yield the required dimer. To join an oligonucleotide to a cysteine-containing peptide or protein, the 5'-cystamine oligomer is first converted to a 2'-pyridyldisulfide adduct and then reacted with an excess of the peptide or protein. If the peptide does not contain a free cysteine residue, it is first treated with iminothiolane to introduce one or more sulfhydryl groups. We have used these procedures to join a 16 mer deoxynucleotide probe and MDV-1 RNA, a substrate of Q beta RNA polymerase. This adduct hybridizes with a complementary target DNA. We have also joined a 16mer probe to peroxidase and MDV-1 RNA to human IgG. The probe-peroxidase adduct maintains enzymatic activity and the MDV-1 RNA-IgG adduct binds to a complementary anti-IgG.     

Hybridization of antisense oligonucleotides with the 3'part of tRNA(Phe)

The interaction of antisense oligodeoxyribonucleotides with yeast tRNA(Phe) was investigated. 14-15-mers complementary to the 3'-terminal sequence including the ACCA end bind to the tRNA under physiological conditions. At low oligonucleotide concentrations the binding occurs at the unique complementary site. At higher oligonucleotide concentrations, the second oligonucleotide molecule binds to the complex due to non-perfect duplex formation in the T-loop stabilized by stacking between the two bound oligonucleotides. In these complexes the acceptor stem is open and the 5'-terminal sequence of the tRNA is accessible for binding of a complementary oligonucleotide. The results prove that the efficient binding of oligonucleotides to the 3'-terminal sequence of the tRNA occurs through initial binding to the single-stranded sequence ACCA followed by invasion in the acceptor stem and strand displacement.     

Interaction of cholesterol-conjugated alkylating oligonucleotide derivatives with cellular biopolymers.

Interactions of oligonucleotide derivatives with mammalian cells and cellular biopolymers have been investigated. The derivatives were oligonucleotides bearing an alkylating 2-chloroethylamino group at the 3'-end and a cholesterol residue at the 5'-terminal phosphate. These compounds are readily taken up by cells and react with cellular DNA, RNA and some proteins which may play a role in delivery of the compounds into cells.     

Synthesis of oligodeoxyribonucleotide derivatives, containing perfluoroarylazide group at C8-atom of deoxyadenosine and their use in photomodification of DNA fragments

Heptadeoxynucleotides were obtained that contained an aliphatic amino group in position 8 of the deoxyadenosine residue: ALNH2 CTTTCT, CTCALNH2 CTT, and ACACTCALNH2 where L = NH(CH2)n, n = 3, 5, or 7. A 4-azidotetrafluorobenzoyl residue was attached to the amino group in the oligonucleotides, and photomodification of a DNA target by the resulting reagents was carried out. It was shown that the length of the spacer influences the photomodification extent of the target; a spacer with n = 5 is optimum. The maximum modification extent (65%) was reached when a reagent containing a photoreactive group at the 5'-terminal deoxyadenosine residue was used.     

An efficient, sequence-specific method for crosslinking complementary oligonucleotides using binuclear platinum complexes.

The binuclear PtII complexes [(trans-Pt(NH3)2Cl)2 (NH2(CH2)nNH2)]Cl2 (n = 4, 5 or 6), crosslink oligodeoxynucleotide-5'-phosphorothioates rapidly, specifically and efficiently to complementary single-stranded oligodeoxynucleotide targets. In the case that we investigated in detail, the most abundant crosslink is formed to the G residue complementary to the 5'-terminal C residue of the phosphorothioate. Less efficient crosslinking occurs to many other residues of the target. The same PtII complexes also bring about crosslinking efficiently to the polypurine tract in triple-helical DNA.     

Complementary addressed modification of single-stranded DNA using a [Fe-EDTA] derivative of oligonucleotide

A one-tube synthesis scheme for coupling EDTA residue to the 5'-terminus of unprotected oligonucleotides via propylenediamine linker is described. The EDTA derivative of oligonucleotide d(pTGACCCTCTTCCC)A forms a kinetically stable complex with Fe2+ ion. In the presence of ascorbic acid with O2 limiting, this complex modifies single-stranded DNA (a 302-mer) in a site-specific way near the target complementary nucleotide sequence. The DNA fragment can be then cleaved predominantly at modified pyrimidine nucleotides (hidden breaks) by hot piperidine treatment, whereas few direct breaks (i.e. without piperidine) occurs at this site. No autocleavage of the [Fe.EDTA]-oligonucleotide derivative is observed under the experiment's conditions.     

Action of Escherichia coli and human 5'----3' exonuclease functions at incised apurinic/apyrimidinic sites in DNA.

The 5'----3' exonuclease activity of E. coli DNA polymerase I and a related enzyme activity in mammalian cell nuclei, DNase IV, are unable to catalyse the excision of free deoxyribose-phosphate from apurinic/apyrimidinic (AP) sites incised by an AP endonuclease. Instead, the sugar phosphate residue is slowly released as part of a short oligonucleotide. These products have been characterised as dimers and trimers by comparison of their retention time on reverse-phase HPLC with reference compounds prepared by acid depurination of a dinucleotide, trinucleotide and tetranucleotide containing a 5'-terminal dAMP residue. The similar mode of action of these enzymes at 5'-incised AP sites provides an explanation for the minority of repair patches larger than one nucleotide observed when AP sites are repaired by E. coli and mammalian cell extracts in vitro and strengthens the functional analogy between the two activities.