Photooxidation of oligodeoxynucleotides by UO2(2+).

Photooxidation and consequent cleavage of oligodeoxynucleotides by the uranyl ion is greatly enhanced in the presence of a terminal 5'- or 3'-phosphate group. This enhanced cleavage is confined to nearby phosphodiester bonds in the case of a 5'-phosphate, but is less localized in the case of a 3'-phosphate. Several attempts to use a complementary oligodeoxynucleotide to direct a uranyl "warhead" against an oligodeoxynucleotide target were unsuccessful. Our results are most easily explained if we suppose that uranyl ions form coordination complexes with terminal phosphates and that, on photoexcitation, coordinated uranyl ions extract a hydrogen atom from the CH bond of a nearby deoxyribose residue.     

Kinetics and thermodynamics of i-DNA formation: phosphodiester versus modified oligodeoxynucleotides.

At slightly acidic or even neutral pH, oligodeoxynucleotides that include a stretch of cytidines have been shown to form a tetrameric structure in which two parallel-stranded duplexes have their hemiprotonated C.C+base pairs face to face and fully intercalated, in a so-called i-motif. Cytosine-rich pyrimidine oligodeoxynucleotides can form an intramolecular i-motif. We have studied the ability of several DNA analogs to fold into this structure. Evidence for folding was provided by thermal denaturation. We have shown that phosphorothioate and phosphodiester oligodeoxynucleotides, but not methylphosphonate or PNA oligomers, may form the i-motif. Four different PS oligodeoxynucleotides were compared with their PO counterparts. In all cases, the melting temperature (Tm) of the phosphorothioate oligomer was equal or slightly inferior (by 2-3 degreesC) to the Tmof the natural oligodeoxynucleotide. For long oligodeoxynucleotides, a small change of pH leads to a completely different melting profile: the curves are reversible at pH 6.4 or lower, and a hysteresis is obtained at pH 6.8 or higher; cooling and heating curves were not superimposed, allowing us to determine the rate constants of association (kon) and dissociation (koff) as a function of the temperature: these rate constants give linear Arrhenius plots, in agreement with the prediction of the two-state model of association-dissociation. The activation energy Eonis strongly negative and, at neutral pH, the phosphorothioate associates and dissociates nine times faster than the phosphodiester oligodeoxynucleotide of identical sequence.     

Stability of XGCGCp, GCGCYp, and XGCGCYp helixes: an empirical estimate of the energetics of hydrogen bonds in nucleic acids

The stabilizing effects of dangling ends and terminal base pairs on the core helix GCGC are reported. Enthalpy and entropy changes of helix formation were measured spectrophotometrically for AGCGCU, UGCGCA, GGCGCCp, CGCGCGp, and the corresponding pentamers XGCGCp and GCGCYp containing the GCGC core plus a dangling end. Each 5' dangling end increases helix stability at 37 degrees C roughly 0.2 kcal/mol and each 3' end from 0.8 to 1.7 kcal/mol. The free energy increments for dangling ends on GCGC are similar to the corresponding increments reported for the GGCC core [Freier, S. M., Alkema, D., Sinclair, A., Neilson, T., & Turner, D. H. (1985) Biochemistry 24, 4533-4539], indicating a nearest-neighbor model is adequate for prediction of stabilization due to dangling ends. Nearest-neighbor parameters for prediction of the free energy effects of adding dangling ends and terminal base pairs next to G.C pairs are presented. Comparison of these free energy changes is used to partition the free energy of base pair formation into contributions of "stacking" and "pairing". If pairing contributions are due to hydrogen bonding, the results suggest stacking and hydrogen bonding make roughly comparable favorable contributions to the stability of a terminal base pair. The free energy increment associated with forming a hydrogen bond is estimated to be -1 kcal/mol of hydrogen bond.     

Facile preparation of nuclease resistant 3' modified oligodeoxynucleotides.

An efficient chemical procedure for the immobilization of carboxylate containing conjugate groups onto controlled pore glass (CPG) is described. The derivatized supports were used in the automated synthesis of an oligodeoxynucleotide (20-mer ODN) containing a 3' phosphodiester linked hexanol, aminohexyl, acridine, or cholesterol group. The stability of the oligomer in a hepatoma cell culture was found to be prolonged two to three fold by the presence of any of the 3' tails. By contrast, an aminohexyl group appended to the 5' terminus of the ODN only marginally improved its nuclease resistance. These data support the notion that antisense ODNs are primarily degraded by 3' exonucleases. Introduction of simple 3' tails which incorporate a normal phosphodiester linkage can increase ODN stability by interfering with these enzymes.     

Determination of the free-energy change for repair of a DNA phosphodiester bond

The repair of phosphodiester bonds in nicked DNA is catalyzed by DNA ligases. Ligation is coupled to cleavage of a phosphoanhydride bond in a nucleotide cofactor resulting in a thermodynamically favorable process. A free energy value for phosphodiester bond formation was calculated using the reversibility of the T4 DNA ligase reaction. The relative number of DNA nicks to phosphodiester bonds in a circular plasmid DNA, formed during this reaction at fixed concentrations of ATP to AMP and PP(i), was quantified. At 25 degrees C, pH 7, the equilibrium constant (K(eq)) for the ligation reaction is 3.89 x 10(4) m. This value corresponds to a standard free energy (DeltaG degrees ') of -6.3 kcal mol(-1). By subtracting the known energy contribution due to hydrolysis of ATP to AMP and PP(i), DeltaG degrees ' for the hydrolysis of a DNA phosphodiester bond is -5.3 kcal mol(-1).     

Interactions of oligonucleotide analogs containing methylphosphonate internucleotide linkages and 2'-O-methylribonucleosides.

The interactions of oligonucleotide analogs, 12-mers, which contain deoxyribo- or 2'-O-methylribose sugars and methylphosphonate internucleotide linkages with complementary 12-mer DNA and RNA targets and the effect of chirality of the methylphosphonate linkage on oligomer-target interactions was studied. Oligomers containing a single Rp or Sp methylphosphonate linkage (type 1) or oligomers containing a single phosphodiester linkage at the 5'-end followed by 10 contiguous methylphosphonate linkages of random chirality (type 2) were prepared. The deoxyribo- and 2'-O-methylribo- type 1 12-mers formed stable duplexes with both the RNA and DNA as determined by UV melting experiments. The melting temperatures, Tms, of the 2'-O-methylribo-12-mer/RNA duplexes (49-53 degrees C) were higher than those of the deoxyribo-12mer/RNA duplexes (31-36 degrees C). The Tms of the duplexes formed by the Rp isomers of these oligomers were approximately 3-5 degrees C higher than those formed by the corresponding Sp isomers. The deoxyribo type 2 12-mer formed a stable duplex, Tm 34 degrees C, with the DNA target and a much less stable duplex with the RNA target, Tm < 5 degrees C. In contrast, the 2'-O-methylribo type 2 12-mer formed a stable duplex with the RNA target, Tm 20 degrees C, and a duplex of lower stability with the DNA target, Tm < 5 degrees C. These results show that the previously observed greater stability of oligo-2'-O-methylribonucleotide/RNA duplexes versus oligodeoxyribonucleotide/RNA duplexes extends to oligomers containing methylphosphonate linkages and that the configuration of the methylphosphonate linkage strongly influences the stability of the duplexes.     

Stability of antisense DNA oligodeoxynucleotide analogs in cellular extracts and sera

Antisense DNA oligodeoxynucleotides can selectively inhibit the expression of individual (undesirable) genes and thus, have potential in the treatment of cancer and viral diseases. A prerequisite to their use as therapeutic agents is information on the stability of oligodeoxynucleotides, and their structurally modified analogs, in the biological milieu. To this end, degradation of 5' end and internally [32P] labelled unmodified DNA oligodeoxynucleotide (D-oligo) and analogs containing phosphorothioate (S-oligo), methylphosphonate (MP-oligo), and novel alternating methylphosphonate and phosphodiester (Alt-MP-oligo) internucleoside linkages was studied in Hela cell nuclear extract, S100 cytoplasmic extract, normal human serum and calf serum at 37 degrees C. Both 5' end and internally labelled D-oligos showed complete degradation within 30 min incubation in human serum at 37 degrees C. In any given medium, the D-oligo was the least stable oligodeoxynucleotide to nuclease degradation whereas the Alt-MP, MP and S-oligos were generally of comparable stability and all relatively more stable than D-oligo. Interestingly, MP and Alt-MP-oligos also exhibited greater resistance to phosphatases in cellular extracts compared to D and S-oligos. Under the conditions of the experiments, increasing degradation for any given oligonucleotide was observed in the order: S100 cytoplasmic extract less than nuclear extract less than normal human serum less than calf serum. In a study involving alpha-MEM cell culture medium containing 10% heat inactivated fetal calf serum (heated to 56 degrees C for 1 hour), the D-oligo was found to be rapidly degraded (degradation evident within 10 mins) whereas degradation products for the S-oligo were observed within 1 hour. In contrast, the Alt-MP oligo remained stable throughout the 3 hour experiment. These results indicated that in cell culture medium containing heat inactivated serum Alt-MP oligo was more stable than D- and S-oligos.     

RNase H-mediated inhibition of translation by antisense oligodeoxyribonucleotides: use of backbone modification to improve specificity.

A sequence of the rabbit alpha-globin mRNA is the primary target for ODN1, an unmodified 15-nucleotide (nt) antisense oligodeoxyribonucleotide (oligo). ODN1 prevented in vitro translation of both alpha- and beta-globin mRNAs in wheat germ extract. Nine secondary sites exhibiting more than 60% complementarity with ODN1 were present in the beta-globin message. The ODN1 inhibition of beta-globin synthesis was shown to be mediated by RNase H cleavage of the beta-globin mRNA at three partially complementary sites. Sandwich-type oligos consisting of a stretch of unmodified nt with a few methylphosphonate residues at both 5' and 3' ends were derived from ODN1. We have demonstrated that one such analogue (ODN2), with five phosphodiester linkages in the central region, exhibited improved specificity for alpha-globin mRNA compared with the unmodified parent 15-mer, due to a reduced ability of RNase H to cleave beta-mRNA/ODN2 mismatched duplexes.     

A cationic derivative of amphotericin B as a novel delivery system for antisense oligonucleotides

A novel approach based on a plasma membrane permeability-disturbing agent was proposed as an antisense oligonucleotide delivery system. AMA, a derivative of the polyene antibiotic amphotericin B, formed a stable complex when mixed with phosphodiester oligodeoxynucleotides and enhanced the intracellular uptake of a 5' fluoresceinated anti-mdr1 20-mer into NIH-MDR-G185 cells. The nonlabeled phosphorothioate form of the oligodeoxynucleotide, complexed to AMA, inhibited P-glycoprotein expression with better efficiency and less nonspecific effects than when vectorized by Lipofectin. AMA may thus be a good agent for antisense strategy.     

Ligase joining of oligodeoxynucleotides on a oligodeoxynucleotide analog matrix containing P-S-C(5')-internucleotide bonds

Joining of oligodeoxynucleotides by T4 polynucleotide ligase on an oligodeoxynucleotide template analogue having P--S--C(5') internucleotide bonds was investigated. The enzyme did ligate the oligodeoxynucleotides but with an extremely low rate. The major product of the enzymatic reaction proved to be the adenylylated intermediate of the 5'-phosphorylated oligodeoxynucleotide, the product of the second stage of the overall ligation reaction. It is noteworthy that this intermediate is not accumulated in ligase reactions under standard conditions when DNA templates rather than template analogues were used.     

Cloning of random-sequence oligodeoxynucleotides

Methods are described for cloning random or highly degenerate nucleotide (nt) sequences. The procedures use synthetically derived mixtures of oligodeoxynucleotides (oligos) whose heterogeneous central portions are bounded at their 5' and 3' ends by sequences recognized by restriction endonucleases. Oligo collections of defined length and nt composition are synthesized by utilizing appropriate concentrations of all four nucleotide precursors during each addition step for the central region. Single-stranded oligos with appropriate 5' and 3' ends can be ligated directly, although inefficiently, into double-stranded (ds) DNA molecules with complementary 5' and 3' extensions produced by restriction endonuclease cleavage. A more general and efficient method is to convert the oligo into a ds form by incubating it with the Klenow (large) fragment of Escherichia coli DNA polymerase I. If the 3' ends are palindromic, two oligo molecules will serve as mutual primers for polymerization. The resulting products are ds molecules containing two oligo units separated by the original 3' restriction site and bounded at each end by the original 5' restriction site. After appropriate restriction endonuclease cleavage, oligo units can be cloned by standard procedures. Analysis of 26 recombinant M13 phages indicates that the nt sequences of the cloned oligos are in good accord with what was expected on a random basis.     

Investigation of some properties of oligodeoxynucleotides containing 4'-thio-2'-deoxynucleotides: duplex hybridization and nuclease sensitivity.

The thermal stabilities of the duplexes formed between 4'-thio-modified oligodeoxynucleotides and their DNA and RNA complementary strands were determined and compared with those of the corresponding unmodified oligodeoxynucleotides. A 16mer oligodeoxynucleotide containing 10 contiguous 4'-thiothymidylate modifications formed a less stable duplex with the DNA target (deltaTm/modification -1.0 degrees C) than the corresponding unmodified oligodeoxynucleotide. However, when the same oligodeoxynucleotide was bound to the corresponding RNA target, a small increase in Tm was observed (deltaTm/modification +0.16 degrees C) when compared with the unmodified duplex. A study to identify the specificity of an oligodeoxynucleotide containing a 4'-thiothymidylate modification when forming a duplex with DNA or RNA containing a single mismatch opposite the modification found the resulting Tms to be almost identical to the wild-type duplexes, demonstrating that the 4'-thio-modification in oligodeoxynucleotides has no deleterious effect on specificity. The nuclease stability of 4'-thio-modified oligodeoxynucleotides was examined using snake venom phosphodiesterase (SVPD) and nuclease S1. No significant resistance to degradation by the exonuclease SVPD was observed when compared with the corresponding unmodified oligodeoxynucleotide. However, 4'-thio-modified oligodeoxynucleotides were found to be highly resistant to degradation by the endonuclease S1. It was also demonstrated that 4'-thio-modified oligodeoxynucleotides elicit Escherichia coli RNase H hydrolysis of the RNA target only at high enzyme concentration.     

Site-specific laser modification (cleavage) of oligodeoxynucleotides

Sequence-specific photomodification of oligodeoxynucleotide pAGAGTATTGACTTA ("a target") has been carried out with the aid of complementary fluorescent probes. Such a probe consisted of oligodeoxynucleotide pAATACTCT and a chromophore group attached to its 5' end. Three different derivatives of ethidium bromide were used as a chromophore. The photomodification was induced by nitrogen laser radiation (337 nm, 15 MW/cm2). The irradiation induces the following photodamages: target cleavage at the specific binding site with a cutting off of the 8-mer from its 5' end (yield up to 12%), formation of specific covalent adduct target-probe with a yield of 20-70%, and piperidine-sensitive target modifications with a 7-27% yield (for different chromophores). The total yield of specific photodamages of all kinds is 50-80%. The target cleavage and generation of piperidine-sensitive modifications are optically nonlinear processes. Piperidine treatment of the irradiated samples led to specific cleavage of the target with the yield up to 40%. All kinds of observed modifications are not influenced by high concentrations of free radical scavengers: 1.3M tBuOH and 10 mM cystamine. The pattern of cleavage indicates that the most probable position of the chromophore is between T8 and G9 of the target, i.e., the chromophore stacks on top of the last A.T base pair of the duplex. The aggregate of evidence is in agreement with the mechanism of nonlinear photomodification (the cleavage and generation of piperidine-sensitive modifications) based on the transfer of two-photon excitation energy from the chromophore to the target.     

Triple-helix formation and cooperative binding by oligodeoxynucleotides with a 3'-3' internucleotide junction.

Triple-helix formation by oligodeoxynucleotides in a sequence-specific manner is limited to polypurine tracts of duplex DNA. To increase the number of biologically relevant targets for triple-helix formation, we have utilized oligodeoxynucleotides containing a 3'-3' internucleotide junction to allow for binding to opposite strands of duplex DNA. Molecular modeling was used to aid in the design of the xylose dinucleoside linker 1 that is rigid and minimizes the number of conformers to minimize the entropy of binding. Thermal denaturation studies show that a 3'-3'-linked oligodeoxynucleotide, bearing nine nucleotides on each side of the linker, has a higher Tm (47.6 degrees C) than that of a 21-mer binding to a single polypurine tract (45.3 degrees C). Binding domain minimization studies and sequence-specific alkylation of a target duplex demonstrate a high degree of cooperativity between the two triple-helix binding domains, thus allowing for an increase in the number of biologically relevant targets for triple-helix formation.     

Thermodynamic parameters for DNA sequences with dangling ends

The thermodynamic contributions to duplex formation of all 32 possible single-nucleotide dangling ends on a Watson-Crick pair are reported. In most instances, dangling ends are stabilizing with free energy contributions ranging from +0.48 (GT(A)) to-0.96 kcal/mol (). In comparison, Watson-Crick nearest-neighbor increments range from -0. 58 (TA/AT) to -2.24 (GC/CG) kcal/mol. Hence, in some cases, a dangling end contributes as much to duplex stability as a Watson-Crick A-T base pair. The implications of these results for DNA probe design are discussed. Analysis of the sequence dependence of dangling-end stabilities show that the nature of the closing base pair largely determines the stabilization. For a given closing base pair, however, adenine dangling ends are always more or equally as stable as the other dangling nucleotides. Moreover, 5' dangling ends are more or equally as stabilizing as their 3' counterparts. Comparison of DNA with RNA dangling-end motifs shows that DNA motifs with 5' dangling ends contribute to stability equally or more than their RNA counterparts. Conversely, RNA 3' dangling ends contribute to stability equally or more than their DNA counterparts. This data set has been incorporated into a DNA secondary structure prediction algorithm (DNA MFOLD) (http://mfold2.wustl.edu/mfold/dna/for m1.cgi) as well as a DNA hybridization prediction algorithm (HYTHERtrade mark) (http://jsl1.chem.wayne.edu/Hyther/hythermenu .html).     

Syntheses of alternating oligo-2'-O-methylribonucleoside methylphosphonates and their interactions with HIV TAR RNA

Oligonucleotide analogues 15-20 nucleotides in length have been prepared, whose sequences are complementary to nucleotides in the upper hairpin of HIV TAR RNA. These alternating oligonucleoside methylphosphonates, mr-AOMPs, contain 2'-O-methylribonucleosides and alternating methylphosphonate and phosphodiester internucleotide linkages. The methylphosphonate and phosphodiester linkages of these oligomers are highly resistant to hydrolysis by exonuclease activity found in mammalian serum and to endonucleases, such as S1 nuclease. The oligomers were prepared using automated phosphoramidite chemistry and terminate with a 5'-phosphate group, which provides an affinity handle for purification by strong anion exchange HPLC. A 15-mer mr-AOMP, 1676, that is complementary to the 5'-side of the TAR RNA hairpin, including the 3-base bulge and 6-base loop region, forms a 1:1 duplex with a complementary RNA 18-mer, mini-TAR RNA. The T(m) of this duplex is 71 degrees C, which is similar to that of the duplex formed by the corresponding all phosphodiester 15-mer. Introduction of two mismatched bases reduces the T(m) by 17 degrees C. The apparent dissociation constant, K(d), for the 1676/mini-TAR RNA duplex as determined by an electrophoretic mobility shift assay at 37 degrees C is 0.3 nM. Oligomer 1676 also binds tightly to the full length TAR RNA target under physiological conditions (K(d) = 20 nM), whereas no binding was observed by the mismatched oligomer. A 19-mer that is complementary to the entire upper hairpin also binds to TAR RNA with a K(d) that is similar to that of 1676, a result that suggests only part of the oligomer binds. When two of the methylphosphonate linkages in the region complementary to the 6-base loop are replaced with phosphodiester linkages, the K(d) is reduced by approximately a factor of 10. This result suggests that interactions between TAR RNA and the oligomer occur initially with nucleotides in the 6-base loop, and that these interactions are sensitive to presence and possibly the chirality of the methylphosphonate linkages in the oligomer. The high affinities of mr-AOMPs for TAR RNA and their resistance to nuclease hydrolysis suggests their potential utility as antisense agents in cell culture.     

Binding of phosphorothioate oligodeoxynucleotides to basic fibroblast growth factor, recombinant soluble CD4, laminin and fibronectin is P-chirality independent.

Antisense oligodeoxynucleotides can selectively inhibit the expression of individual genes and thus have potential applications in anticancer and antiviral therapy. A critical prerequisite to their use as therapeutic agents is the understanding of their non-specific interactions with biological structures, e.g. proteins. In this study we examined the interactions of P-chiral phosphorothioate oligodeoxynucleotides with several proteins. The Rp- and Sp- diastereomers, and racemic machine-made mixtures, or M-oligodeoxynucleotides were used independently as competitors of the binding of a probe, phosphodiester oligodeoxynucleotide bearing a 5' alkylating moiety, to rsCD4, bFGF and laminin. These oligodeoxynucleotides were also used as competitors of the binding of a non-alkylating probe M-phosphorothioate oligodeoxynucleotide, 5'-32P-SdT18 to fibronectin. The average values of and quantitative estimates for the IC50 of competition and the constant of competition (Kc) of Rp-, Sp- and M-stereoisomers of several homo- and heteropolymer oligodeoxynucleotides were determined and compared. Surprisingly, in the proteins we studied, the values of IC50 and Kc for the Rp-, Sp- and M-oligodeoxynucleotides were essentially identical. Thus, the ability of the phosphorothioate oligodeoxynucleotides we employed, to bind to the proteins studied in this work, is virtually independent of P-chirality. Our results also imply that the role of the purine and pyrimidine bases in oligodeoxynucleotide-protein interactions, as well as the nature of the contact points (sulfur versus oxygen) between the oligomer and the protein, may be relatively unimportant.