An improved method for the synthesis and deprotection of methylphosphonate oligonucleotides.

The methylphosphonate oligonucleotide synthesis methods described here give the desired products in good yield. Superior amounts of product are achieved by modifying both the DNA synthesis program and the reagent to compensate for the unstable methylphosphonite intermediate. Deprotection conditions have also been altered to maximize the recovery of oligonucleotide from DNA synthesis supports and to minimize the amount of base modification. Mass-spectrometry analysis of our oligonucleotides has verified their purity and confirmed the absence of modified bases. When compared to standard DNA synthesis methods, this procedure uses only about one-third the usual amount of monomer. Using these procedures, it should be possible to synthesize reliably methylphosphonate oligonucleotides at 1- and 15-mumol scales.

Structural study of a DNA.RNA hybrid duplex with a chiral phosphorothioate moiety by NMR: extraction of distance and torsion angle constraints and imino proton exchange rates.

The solution structure of the thiophosphate-modified DNA.RNA hybrid duplex d(GCTATAApsTGG).r(CCAUUAUAGC) has been studied by NMR. Two samples with pure stereochemistry in the modified phosphate have been investigated. Two-dimensional NMR (2D NMR) methods have been applied to assign nearly all the resonances in both duplexes. Scalar coupling constants have been determined by comparing quantitative simulations with experimental double-quantum filtered COSY (DQF-COSY) cross-peaks. More than 300 distance constraints have been obtained from two-dimensional nuclear Overhauser spectroscopy (2D NOE) spectra recorded in D2O and H2O by using a complete relaxation matrix analysis as implemented in the program MARDIGRAS. This hybrid duplex presents a heteronomous structure. Riboses in the RNA strand are found in a N-type conformation typical of the A-form family as shown by the lack of H1'-H2' cross-peaks in DQF-COSY spectra and confirmed by the measured interproton distances. In contrast, the DNA strand adopts a different conformation with sugar puckers partially in the S-type domain, which is not in agreement with the A-family of structures. Coupling constants in deoxyriboses are not consistent with any single sugar conformation. Therefore, sugar pucker pseudorotation parameters are calculated according to a two-state dynamic equilibrium between N- and S-type conformers. In general, the population of major S conformer is lower than in double-stranded DNA duplexes, indicating that hybrid duplexes may be more flexible than pure DNA or RNA. The only differences observed in the spectra between the two stereoisomers studied originate from resonances of protons located near the modified phosphate. No significant differences in interproton distance have been detected, and only a slight difference of sugar pucker in the 5' neighbor has been found. The sulfur atom appears to be well-accommodated without further changes in the structure of the hybrid.

Kinetic analysis of Escherichia coli RNase H using DNA-RNA-DNA/DNA substrates.

The kinetic properties of Escherichia coli ribonuclease H (RNase H) were investigated using oligonucleotide substrates that consist of a short stretch of RNA, flanked on either side by DNA (DNA-RNA-DNA). In the presence of a complementary DNA strand, RNase H cleavage is restricted to the short ribonucleotide stretch of the DNA/RNA heteroduplex. The DNA-RNA-DNA substrate utilized for kinetic studies: (formula; see text) is cleaved at a single site (decreases) in the presence of a complementary DNA strand, to generate (dT)7-(rA)2-OH and p-(rA)2-(dT)9. Anion exchange high performance liquid chromatography was used to separate and quantitate the cleavage products. Under these conditions, RNase H-specific and nonspecific degradation products could be resolved. Kinetic parameters were measured under conditions of 100% hybrid formation (1.2-1.5 molar excess of complementary DNA, T much less than Tm). A linear double reciprocal plot was obtained, yielding a Km of 4.2 microM and a turnover number of 7.1 cleavages per s per RNase H monomer. The kinetic properties of substrate analogs containing varying lengths of RNA (n = 3-5) and 2'-O-methyl modifications were also investigated. Maximal turnover was observed with DNA-RNA-DNA substrates containing a minimum of four RNA residues. Kcat for the rA3 derivative was decreased by more than 100-fold. The Km appeared to decrease with the size of the internal RNA stretch (n = 3-5). No significant difference in turnover number of Km was observed when the flanking DNA was replaced with 2'-O-methyl RNA, suggesting that RNase H does not interact with this region of the heteroduplex.

Effects of neutralization pattern and stereochemistry on DNA bending by methylphosphonate substitutions.

Asymmetric phosphate neutralization has been hypothesized to play a role in DNA bending by proteins. Neutralization is thought to involve salt bridges between the negatively charged phosphate backbone of duplex DNA and the cationic amino acids of an approaching protein. According to this model, the resulting unbalanced charge distribution along the duplex DNA induces the double helix to collapse toward the neutralized surface. Previous work has confirmed that DNA bending is induced by the asymmetric incorporation of racemic methylphosphonate linkages creating a neutral region on one face of duplex DNA. Neutralization was accomplished by substitution of three consecutive phosphodiesters on each strand, arranged across one minor groove of the DNA (a total of six neutralized phosphates). We now measure DNA bending induced by a more diffuse patch of neutralization (alternating neutralized and anionic phosphates) and explore the effect of methylphosphonate stereochemistry. DNA duplexes with patches of alternating methylphosphonate and phosphodiester linkages are less bent than DNAs wherein consecutive phosphates are neutralized. Furthermore, duplexes neutralized by incorporation of pure (RP)-methylphosphonate isomers are bent approximately 30% less than duplexes neutralized by racemic methylphosphonates.

Effect of excess water on the desilylation of oligoribonucleotides using tetrabutylammonium fluoride.

The most commonly available 2' hydroxyl protecting group used in the synthesis of oligoribonucleotides is the tert-butyldimethylsilyl moiety. This protecting group is generally cleaved with 1 M tetrabutylammonium fluoride (TBAF) in tetrahydrofuran (THF). The efficiency of this reaction was tested on ribonucleotidyldeoxythymidine dinucleotides (AT, CT, GT, and UT). We have found that the efficiency of desilylation of uridine and cytidine is greatly dependent on the water content of the TBAF reagent. Conversely, the water content of the TBAF reagent [up to 17% (w/w)] had no detectable effect on the rate of desilylation of adenosine and guanosine. It was concluded that for effective desilylation of pyrimidine nucleosides the water content of the TBAF reagent must be 5% or less, which is readily achieved using molecular sieves. TBAF dried in such a manner was shown to be effective in deprotecting an oligoribonucleotide containing both purine and pyrimidine residues.

A non-nucleotide-based linking method for the preparation of psoralen-derivatized methylphosphonate oligonucleotides.

A method is reported for conjugating an analog of 4'-(aminomethyl)-4,5',8- trimethylpsoralen to methylphophonate oligonucleotides. This method enables the psoralen moiety to be coupled to the phosphonate backbone between any two desired bases in a sequence. When hybridized to a target mRNA, the psoralen moiety can be directed toward a uridine base and, in turn, can undergo a photo-addition reaction with the target under UV irradiation at 365 nm. Several different non-nucleotide-based amino-linker reagents have been prepared for incorporation into methylphosphonate oligonucleotides by standard phosphonamidite chemistry. In addition, an N-hydroxysuccinimide activated ester analog of 4'-[(3-carboxypropionamido)methyl]-4,5',8- trimethylpsoralen has been synthesized for conjugation to the amino-linker moieties. Using this approach, we have prepared a number of psoralen-methylphosphonate-oligonucleotide conjugates which are complementary to the chimeric bcr/abl mRNA associated with chronic myelogenous leukemia. Solution hybridization studies with a 440-base subfragment of the bcr/abl RNA have shown that the psoralen moiety does not adversely affect duplex stability. Polyacrylamide gel electrophoresis analyses have demonstrated that the psoralen-oligonucleotide conjugates undergo photo-addition to the RNA in a sequence-specific manner. Optimal photo-addition occurs when the psoralen moiety is inserted adjacent to one or more adenine residues in the oligonucleotide sequence, particularly between adenine and thymine (5'-3'). This internal labeling approach greatly increases the number of potential target sites available for photo-cross-linking experiments.

Interstrand complex formation of purine oligonucleotides and their nonionic analogs: the model system of d(AG)8 and its complement, d(CT)8.

We have investigated the role of purines in interstrand complex formation with regard to substitution of the negatively-charged, phosphodiester backbone by a nonionic, internucleoside linkage. Using the purine oligomer, d(AG)8, its methylphosphonate analog, d(AG)8, and the complementary pyrimidine oligomer, d(CT)8, as a model system, the stoichiometry, conformation, and stability of complexes formed at pH 8 were studied by spectroscopic and electrophoretic methods. When there is only one oligomer species in solution, d(AG)8 behaves as a single-stranded molecule. In contrast, the d(AG)8 oligomer readily forms an intermolecular self-complex, particularly in the presence of magnesium ion. Using either purine oligomer, duplexes can form with the d(CT)8 strand which differ in terms of their conformation and in the dependence of their thermal stability on sodium and magnesium ions. All studies show that a stable triplex forms with a 1:2 d(CT)8:d(AG)8 stoichiometry which does not require high concentrations of sodium or magnesium ions. Triplex formation between the d(CT)8 strand and two d(AG)8 strands was not observed. Native gel electrophoresis suggests that a 1:1:1 d(CT)8:d(AG)8:d(AG)8 complex may be formed. In regard to triplex formation, the advantage of the methylphosphonate backbone on the purine strand is clearly demonstrated.

Deprotection of methylphosphonate oligonucleotides using a novel one-pot procedure.

Deprotection of methylphosphonate oligonucleotides with ethylenediamine was evaluated in a model system. Methylphosphonate sequences of the form 5'-TTTNNTTT, where N was either N4-bz-dC, N4-ibu-dC, N2-ibu-O6-DPC-dG, N2-ibu-dG, N6-bz-dA, or T, were used to determine the extent of modifications that occur during deprotection. Up to 15% of N4-bz-dC was found to transaminate at the C4 position when treated with ethylenediamine. A similar displacement reaction with ethylenediamine was observed at the O6 position of N2-ibu-O6-DPC-dG, and to a much lesser extent of N2-ibu-dG. Side reactions were not observed when oligonucleotides containing N4-ibu-dC, N6-bz-dA, or T were treated with ethylenediamine. A novel method of deprotecting methylphosphonate oligonucleotides was developed from these studies. The method incorporates a brief treatment with dilute ammonia for 30 minutes followed by addition of ethylenediamine for 6 hours at room temperature to complete deprotection in a one-pot format. The solution is then diluted and neutralized to stop the reaction and prepare the crude product for chromatographic purification. This method was used to successfully deprotect a series of oligonucleotides at the 1, 100, and 150 mumole scales. These deprotection results were compared to a commonly used two-step method and found to be superior in yield of product by as much as 250%.

Triple-strand-forming methylphosphonate oligodeoxynucleotides targeted to mRNA efficiently block protein synthesis.

Antisense oligonucleotides are ordinarily targeted to mRNA by double-stranded (Watson-Crick) base recognition but are seldom targeted by triple-stranded recognition. We report that certain all-purine methylphosphonate oligodeoxyribonucleotides (MPOs) form stable triple-stranded complexes with complementary (all-pyrimidine) RNA targets. Modified chloramphenicol acetyltransferase mRNA targets were prepared with complementary all-pyrimidine inserts (18-20 bp) located immediately 3' of the initiation codon. These modified chloramphenicol acetyltransferase mRNAs were used together with internal control (nontarget) mRNAs in a cell-free translation-arrest assay. Our data show that triple-strand-forming MPOs specifically inhibit protein synthesis in a concentration-dependent manner (> 90% at 1 microM). In addition, these MPOs specifically block reverse transcription in the region of their complementary polypyrimidine target sites.

Synthesis and thermodynamics of oligonucleotides containing chirally pure R(P) methylphosphonate linkages.

Methylphosphonate (MP) oligodeoxynucleotides (MPOs) are metabolically stable analogs of conventional DNA containing a methyl group in place of one of the non-bonding phosphoryl oxygens. All 16 possible chiral R(P) MP dinucleotides were synthesized and derivatized for automated oligonucleotide synthesis. These dimer synthons can be used to prepare (i) all-MP linked oligonucleotides having defined R(P) chirality at every other position (R(P) chirally enriched MPOs) or (ii) alternating R(P) MP/phosphodiester backbone oligonucleotides, depending on the composition of the 3'-coupling group. Chirally pure dimer synthons were also prepared with 2'-O-methyl sugar modifications. Oligonucleotides prepared with these R(P) chiral methylphosphonate linkage synthons bind RNA with significantly higher affinity than racemic MPOs.