Deoxynucleic guanidine; synthesis and incorporation of purine nucleosides into positively charged DNG oligonucleotides

The synthesis of purine nucleosides capable of making the guanidinium linkage is described for the first time starting from the corresponding 2'-deoxynucleosides. The positively charged mixed base DNG oligomer containing guanine was synthesized on solid-phase using CPG as support from 3' to 5' direction using the precursor building block nucleosides.     

Ribonucleic guanidine demonstrates an unexpected marked preference for complementary DNA rather than RNA

Replacement of the phosphodiester linkages of DNA and RNA by guanidinium linkages provides DNG and RNG. We report here the order of stability of mixed duplexes (RNG-U5.DNA-A5>RNA-U5.RNA-A5>RNG-U5.RNA-A5>RNA-U5.DNA-A5>DNA-T5.DNA-A5). The considerable stability of RNG.DNA compared to RNG.RNA is shown to be due to the rigid backbone of RNG existing only in B-form and therefore lowering its affinity for A-RNA. RNG oligomers are putative antigene agents which are specific for DNA and would have minimal competitive binding to ncRNA.     

Solid-phase synthesis of positively charged deoxynucleic guanidine (DNG) modified oligonucleotides containing neutral urea linkages: effect of charge deletions on binding and fidelity

A solid-phase synthesis for a DNA analogue with a mixed guanidinium and urea backbone is reported. This material is nearly identical in structure to deoxynucleic guanidine (DNG) but the neutral urea internucleoside linkages can be used to attenuate the overall positive charge on the oligomer. The opposite charge attraction between urea containing DNG oligomers (DNGUs) and complimentary DNA can be controlled so that the affinity of DNG for DNA does not overwhelm the base-pairing discrimination necessary for specific binding. Octameric DNGU containing between 1 and 3 urea substitutions covered the range between very tight and very weak bonding. Each deletion of a positive charge reduced the thermal denaturation temperature (Tm) by approximately 5 degrees C. Mismatches in the DNA oligomers reduced the Tm values by 3 to 5 degrees C for each of the DNGU oligomers. DNGUs were found to bind in a 2:1 fashion to complimentary DNA in the same manner as DNG.     

Solid-phase synthesis of positively charged deoxynucleic guanidine (DNG) oligonucleotide mixed sequences

Positively charged DNG oligonucleotide mixed sequences containing A/T bases were prepared by solid-phase synthesis. Synthesis proceeds in 3'-->5' direction and involves coupling of 3'-Fmoc protected thiourea in the presence of HgCl(2)/TEA with the corresponding 5'-amine of the growing oligo chain. DNG binding characteristics with complementary DNA and with itself have been evaluated.     

Solid-phase synthesis of oligopurine deoxynucleic guanidine (DNG) and analysis of binding with DNA oligomers

The first stepwise solid-phase synthesis of deoxynucleic guanidine (DNG), a positively charged DNA analog, using controlled pore glass as the solid support is reported. For the first time, purine bases have been incorporated into the DNG oligomer and DNG has been synthesized using a solid-phase method, proceeding in the 3′→5′ direction, that is compatible with the cleavage conditions used in the solid-phase synthesis of DNA. A DNG sequence containing a pentameric tract of adenosine nucleosides has been synthesized and the thermal denaturation temperature of its complexes with complementary thymidyl DNA oligomers was 79°C. Binding of thymidyl DNA oligomers to adenyl DNG oligomers is 2:1, as seen in thymidyl and adenyl DNA triplexes. No binding of adenyl DNG with octameric cytidyl DNA was observed, indicating that the positive charge does not overcome base pairing fidelity.     

Binding properties of positively charged deoxynucleic guanidine (DNG), AgTgAgTgAgT and DNG/DNA chimeras to DNA

The melting properties of hexameric oligonucleotide AgTgAgTgAgT, in which the phosphodiester linkages of the DNA have been replaced by guanidium linkages, have been evaluated. Using the juvenile esterase gene as a target, the binding of a 20-mer DNG/DNA chimera that includes AgTgAgTgAgT is more than 10(5.7) stronger than the binding of 20-mer composed solely of DNA.     

A new technique to prevent self-ligation of DNA

The most widely used technique for preventing self-ligation (self-circularization and concatenation) of DNA is dephosphorylation of the 5'-end, which stops DNA ligase from catalyzing the formation of phosphodiester bonds between the 3'-hydroxyl and 5'-phosphate residues at the DNA ends. The 5'-dephosphorylation technique cannot be applied to both DNA species to be ligated and thus, the untreated DNA species remains capable of self-ligation. To prevent this self-ligation, we replaced the 2'-deoxyribose at the 3'-end of the untreated DNA species with a 2',3'-dideoxyribose. Self-ligation was prevented at the replaced 3'-end, while the 5'-phosphate remaining at the 5'-end permitted ligation with the 3'-hydroxyl end of the 5'-dephosphorylated DNA strand. We successfully applied this 3'-replacement technique to gene cloning, adapter-mediated polymerase chain reaction and messenger RNA fingerprinting. The 3'-replacement technique is simple and not restricted by sequence or conformation of the DNA termini and is thus applicable to a wide variety of methods involving ligation.     

Complexation of single strand telomere and telomerase RNA template polyanions by deoxyribonucleic guanidine (DNG) polycations: plausible anticancer agents

Cancerous cell immortality is due to relatively high concentrations of telomerase enzyme which maintains telomere sequence during cell division. Deoxyribonucleic guanidine (DNG) is a positively charged DNA analog in which guanidine replaces the phosphordiester linkage of DNA. Mixed sequences of DNG and DNA oligonucleotides are referred to as chimera. Complexation of DNG and chimeric polycations with the complementary negatively charged non-coding telomere single strand d(5'-TTAGGG-3')(n) and the 11-base telomeric RNA template (5'-CUAACCCUAAC-3') in the active site of telomerase has been studied. Calculated by ensemble sampling simulations in GBMV solvent model, we found that binding of complementary DNG hexamer with telomere is favored over that of DNA-telomere by approximately 10(6)-fold and binding of chimera hexamer is favored by approximately 10(4)-fold. Binding of complementary DNG with telomeric RNA is favored by 43 kcal/mol over telomere substrate binding with telomeric RNA.     

Incorporation of positively charged deoxynucleic S-methylthiourea linkages into oligodeoxyribonucleotides.

Oligodeoxyribonucleic acids (15- and 18-mers) containing both negatively charged phosphate and positively charged S-methyl thiourea internucleoside linkages (DNmt/DNA chimera) have been synthesized. DNA binding characteristics and nuclease resistance of DNmt/DNA chimera have been evaluated.     

Comparison of positively charged DNG with DNA duplexes: a computational approach

Molecular dynamics is used to investigate the structural properties of the cationic DNA analogue deoxynucleic guanidine (DNG), in which a guanidinium group replaces the phosphate moiety of DNA. This study examines the DNG duplex dodecamers d(Ag)(12).d(Tg)(12) and d(Gg)(12).d(Cg)(12), as well as their DNA counterparts. Watson-Crick base-pairing is maintained in the solvated DNG duplex models during the 5ns simulations. The idealized DNG dodecamers assume many parameters characteristic of the corresponding native DNA, assuming B-DNA conformations. Several helical parameters are rather unique to DNG, including buckle, slide, inclination, propeller, and X-displacement. Fewer transitions in backbone torsions occur in the DNG duplexes compared to those of the DNA, which may result from the greater rigidity of the sp(2) hybridized guanidinium group verses the flexible sp(3) phosphate group. The DNG helices have exceptionally shallow major grooves and very deep minor grooves. The major and minor groove widths of DNG are narrower than those of the respective DNA counterparts.     

Synthesis and hybridization properties of oligonucleotides containing (2S,3R)-9-(2,3,4-trihydroxybutyl)adenine

The synthesis and properties of oligonucleotides (ONs) containing 9-(2,3,4-trihydroxybutyl)adenine, A(C2) and A(C3), are described. The ON containing A(C2) involves the 3'-->4' and 3-->5' phosphodiester linkages in the strand, whereas that containing A(C3) possesses the 3'-->4' and 2'-->5' phosphodiester linkages. It was found that incorporation of the analogs, A(C2) or A(C3), into ONs significantly reduces the thermal and thermodynamic stabilities of the ON/DNA duplexes, but does not largely decrease the thermal and thermodynamic stabilities of the ON/RNA duplexes as compared with the case of the ON/DNA duplexes. It was revealed that the base recognition ability of A(C2) is greater than that of A(C3) in the ON/RNA duplexes.     

Structural properties of hybrid triplex of polycation deoxyribonucleic S-methylthiourea (DNmt) strands with a complementary DNA strand, probed by nanosecond molecular dynamics

The replacement of phosphodiester linkages of the polyanion DNA with S-methylthiourea linkers provides the polycation deoxyribonucleic S-methylthiourea (DNmt). Molecular dynamics studies to 1,220 ps of the hybrid triplex formed from octameric DNmt strands d(Tmt)8 with a complementary DNA oligomer strand d(Ap)8 have been carried out with explicit water solvent and Na+Cl- counterions under periodic boundary conditions using the CHARMM force field and the Ewald summation method. The Watson-Crick and Hoogsteen hydrogen-bonding patterns of the A/T tracts remained intact without any structural restraints for triplex structures throughout the simulation. The duplex portion of the triplex structure equilibrated at a B-DNA conformation in terms of the helical rise and other helical parameters. The dynamic structures of the DNmt x DNA x DNmt triplex were determined by examining histograms from the last 800 ps of the dynamics run. These included the hydrogen-bonding pattern (sequence recognition), three-centered bifurcating occurrences, minor groove width variations, and bending of tracts for the hybrid triplex structures. Together with the Watson-Crick hydrogen-bondings, the strong Hoogsteen hydrogen-bondings, the partially maintained three-centered bifurcatings in the Watson-Crick pair, and the medium-strength three-centered bifurcatings in the Hoogsteen pair suggest that the hybrid triplex is energetically favorable as compared to a duplex with similar base stacking, van der Waals interactions, and helical parameters. This is in agreement with our previously reported thermodynamic study, in which only triplex structures were observed in solution. The bending angle measured between the local axis vectors of the first and last helical axis segments is about 20 degrees for the Watson-Crick portion of the averaged structure. Propeller twist (associated with three-centered hydrogen-bonding) up to -30 degrees, native to DNA AT base pairing, was also observed for the triplex structure. The sugar pseudorotation phase angles and the ring rotation angles for the DNA strand are within the C3'-endo domain and C2'-endo domain for the DNmt strand. Water spines are observed in both minor and major grooves throughout the dynamics run. The molecular dynamics simulations of the structural properties of DNmt x DNA x DNmt hybrid triplex is compared to the DNG x DNA x DNG hybrid triplex (In DNG the -O-(PO2-)-O- linkers in DNA is replaced by -NH-C(=N+H2)-NH-).     

Self-replication of chemical systems based on recognition within a double or a triple helix: a realistic hypothesis.

A scenario is proposed by which non-enzymatic self-replication of short RNA molecules could occur. The hypothesis is illustrated for the self-replication of an oligopyrimidine (Y) strand. The successful replication of Y requires a series of plausible steps. The first, experimentally feasible, step involves the template-directed polynucleotide synthesis, based on Watson-Crick base pairing, of an oligopurine (R) strand using Y as the template, and chemically activated mononucleotides as the building blocks. This step will result in the formation of an oligopyrimidine.oligopurine (YR) double helix. The second step requires the use of the double helix as the template for the synthesis of a second oligopyrimidine (Y') strand from activated pyrimidine monomers. This synthesis could be facilitated by the binding of the monopyrimidines in the major groove of the YR double helix, via Hoogsteen-type base pairing with the R strand, establishing in that sense triple helix recognition. This step, if successful, should result in the formation of a new strand, Y', that runs parallel to the oligopurine strand. Y' differs from Y in that all 3'-5' phosphodiester linkages in Y are replaced by 5'-3' linkages in Y'. The resulting triple helix (YRY') is in dynamic equilibrium with YR and free Y'. In subsequent steps, unassociated Y' directs the synthesis of the complementary oligopurine (R') strand forming a new double helix Y'R' that may direct the synthesis of an oligopyrimidine strand, Y, that is expected to be identical to the first strand that started the whole sequence. An attempt is made to generalize the above hypothesis to mixed oligonucleotides containing all four bases and identify the limitations of this hypothesis.     

Synthesis of the 3'-thio-nucleosides and subsequent automated synthesis of oligodeoxynucleotides containing a 3'-S-phosphorothiolate linkage

Oligodeoxynucleotides containing 3'-S-phosphorothiolate (3'-PS) linkages have become useful tools for probing enzyme-catalyzed cleavage processes in DNA. This protocol describes the synthesis of the phosphorothioamidite monomers derived from thymidine and 2'-deoxycytidine, and their application to a fully automated procedure for synthesising oligodeoxynucleotides containing 3'-PS linkages. The synthesis of the 5'-protected-3'-amidites is achievable in 2 weeks with the DNA synthesis and purification taking another 1 week.     

Phosphodiester-mediated reaction of cisplatin with guanine in oligodeoxyribonucleotides

The cancer chemotherapeutic agent cis-diamminedichloroplatinum(II) or cisplatin reacts primarily with guanines in DNA to form 1,2-Pt-GG and 1,3-Pt-GNG intrastrand cross-links and, to a lesser extent, G-G interstrand cross-links. Recent NMR evidence has suggested that cisplatin can also form a coordination complex with the phosphodiester internucleotide linkage of DNA. We have examined the effects of the phosphodiester backbone on the reactions of cisplatin with oligodeoxyribonucleotides that lack or contain a GTG sequence. Cisplatin forms a stable adduct with TpT that can be isolated by reversed phase HPLC. The cis-Pt-TpT adduct contains a single Pt, as determined by atomic absorption spectroscopy (AAS) and by electrospray ionization mass spectrometry (ESI-MS), and is resistant to digestion by snake venom phosphodiesterase. Treatment of the adduct with sodium cyanide regenerates TpT. Similar adduct formation was observed when T(pT)(8) was treated with cisplatin, but not when the phosphodiester linkages of T(pT)(8) were replaced with methylphosphonate groups. These results suggest that the platinum may be coordinated with the oxygens of the thymine and possibly with those of the phosphodiester group. As expected, reaction of a 9-mer containing a GTG sequence with cisplatin yielded an adduct that contained a 1,3-Pt-GTG intrastrand cross-link. However, we found that the number and placement of phosphodiesters surrounding a GTG sequence significantly affected intrastrand cross-link formation. Increasing the number of negatively charged phosphodiesters in the oligonucleotide increased the amount of GTG platination. Surrounding the GTG sequence with nonionic methylphosphonate linkages inhibited or eliminated cross-link formation. These observations suggest that interactions between cisplatin and the negatively charged phosphodiester backbone may play an important role in facilitating platination of guanine nucleotides in DNA.     

Oligonucleotides with conjugated dihydropyrroloindole tripeptides: base composition and backbone effects on hybridization.

The ability of conjugated minor groove binding (MGB) residues to stabilize nucleic acid duplexes was investigated by synthesis of oligonucleotides bearing a tethered dihydropyrroloindole tripeptide (CDPI3). Duplexes bearing one or more of these conjugated MGBs were varied by base composition (AT- or GC-rich oligonucleotides), backbone modifications (phosphodiester DNA, 2'-O-methyl phosphodiester RNA or phosphorothioate DNA) and site of attachment of the MGB moiety (5'- or 3'-end of either duplex strand). Melting temperatures of the duplexes were determined. The conjugated CDPI3 residue enhanced the stability of virtually all duplexes studied. The extent of stabilization was backbone and sequence dependent and reached a maximum value of 40-49 degrees C for d(pT)8. d(pA)8. Duplexes with a phosphorothioate DNA backbone responded similarly on CDPI3 conjugation, although they were less stable than analogous phosphodiesters. Modest stabilization was obtained for duplexes with a 2'-O-methyl RNA backbone. The conjugated CDPI3 residue stabilized GC-rich DNA duplexes, albeit to a lesser extent than for AT-rich duplexes of the same length.     

Chromosome targeting at short polypurine sites by cationic triplex-forming oligonucleotides

Triplex-forming oligonucleotides (TFOs) bind specifically to duplex DNA and provide a strategy for site-directed modification of genomic DNA. Recently we demonstrated TFO-mediated targeted gene knockout following systemic administration in animals. However, a limitation to this approach is the requirement for a polypurine tract (typically 15-30 base pairs (bp)) in the target DNA to afford high affinity third strand binding, thus restricting the number of sites available for effective targeting. To overcome this limitation, we have investigated the ability of chemically modified TFOs to target a short (10 bp) site in a chromosomal locus in mouse cells and induce site-specific mutations. We report that replacement of the phosphodiester backbone with cationic phosphoramidate linkages, either N,N-diethylethylenediamine or N,N-dimethylaminopropylamine, in a 10-nucleotide, psoralen-conjugated TFO confers substantial increases in binding affinity in vitro and is required to achieve targeted modification of a chromosomal reporter gene in mammalian cells. The triplex-directed, site-specific induction of mutagenesis in the chromosomal target was charge- and modification-dependent, with the activity of N,N-diethylethylenediamine > N,N-dimethylaminopropylamine phosphodiester, resulting in 10-, 6-, and <2-fold induction of target gene mutagenesis, respectively. Similarly, N,N-diethylethylenediamine and N,N-dimethylaminopropylamine TFOs were found to enhance targeting at a 16-bp G:C bp-rich target site in a chromatinized episomal target in monkey COS cells, although this longer site was also targetable by a phosphodiester TFO. These results indicate that replacement of phosphodiester bonds with positively charged N,N-diethylethylenediamine linkages enhances intracellular activity and allows targeting of relatively short polypurine sites, thereby substantially expanding the number of potential triplex target sites in the genome.     

Abasic site recognition by two apurinic/apyrimidinic endonuclease families in DNA base excision repair: the 3' ends justify the means

DNA damage occurs unceasingly in all cells. Spontaneous DNA base loss, as well as the removal of damaged DNA bases by specific enzymes targeted to distinct base lesions, creates non-coding and lethal apurinic/apyrimidinic (AP) sites. AP sites are the central intermediate in DNA base excision repair (BER) and must be processed by 5' AP endonucleases. These pivotal enzymes detect, recognize, and cleave the DNA phosphodiester backbone 5' of, AP sites to create a free 3'-OH end for DNA polymerase repair synthesis. In humans, AP sites are processed by APE1, whereas in yeast the primary AP endonuclease is termed APN1, and these enzymes are the major constitutively expressed AP endonucleases in these organisms and are homologous to the Escherichia coli enzymes Exonuclease III (Exo III) and Endonuclease IV (Endo IV), respectively. These enzymes represent both of the conserved 5' AP endonuclease enzyme families that exist in biology. Crystal structures of APE1 and Endo IV, both bound to AP site-containing DNA reveal how abasic sites are recognized and the DNA phosphodiester backbone cleaved by these two structurally unrelated enzymes with distinct chemical mechanisms. Both enzymes orient the AP-DNA via positively charged complementary surfaces and insert loops into the DNA base stack, bending and kinking the DNA to promote flipping of the AP site into a sequestered enzyme pocket that excludes undamaged nucleotides. Each enzyme-DNA complex exhibits distinctly different DNA conformations, which may impact upon the biological functions of each enzyme within BER signal-transduction pathways.     

Acidic residues in the nucleotide-binding site of the bacteriophage T7 DNA primase

DNA primases catalyze the synthesis of oligoribonucleotides to initiate lagging strand DNA synthesis during DNA replication. Like other prokaryotic homologs, the primase domain of the gene 4 helicase-primase of bacteriophage T7 contains a zinc motif and a catalytic core. Upon recognition of the sequence, 5'-GTC-3' by the zinc motif, the catalytic site condenses the cognate nucleotides to produce a primer. The TOPRIM domain in the catalytic site contains several charged residues presumably involved in catalysis. Each of eight acidic residues in this region was replaced with alanine, and the properties of the altered primases were examined. Six of the eight residues (Glu-157, Glu-159, Asp-161, Asp-207, Asp-209, and Asp-237) are essential in that altered gene 4 proteins containing these mutations cannot complement T7 phage lacking gene 4 for T7 growth. These six altered gene 4 proteins can neither synthesize primers de novo nor extend an oligoribonucleotide. Despite the inability to catalyze phosphodiester bond formation, the altered proteins recognize the sequence 5'-GTC-3' in the template and deliver preformed primer to T7 DNA polymerase. The alterations in the TOPRIM domain result in the loss of binding affinity for ATP as measured by surface plasmon resonance assay together with ATP-agarose affinity chromatography.