Telomerase can inhibit the recombination-based pathway of telomere maintenance in human cells.

Telomere length can be maintained by telomerase or by a recombination-based pathway. Because individual telomeres in cells using the recombination-based pathway of telomere maintenance appear to periodically become extremely short, cells using this pathway to maintain telomeres may be faced with a continuous state of crisis. We expressed telomerase in a human cell line that uses the recombination-based pathway of telomere maintenance to test whether telomerase would prevent telomeres from becoming critically short and examine the effects that this might have on the recombination-based pathway of telomere maintenance. In these cells, telomerase maintains the length of the shortest telomeres. In some cases, the long heterogeneous telomeres are completely lost, and the cells now permanently contain short telomeres after only 40 population doublings. This corresponds to a telomere reduction rate of 500 base pairs/population doubling, a rate that is much faster than expected for normal telomere shortening but is consistent with the rapid telomere deletion events observed in cells using the recombination-based pathway of telomere maintenance (Murnane, J. P., Sabatier, L., Marder, B. A., and Morgan, W. F. (1994) EMBO J. 13, 4953-4962). We also observed reductions in the fraction of cells containing alternative lengthening of telomere-associated promyelocytic leukemia bodies and extrachromosomal telomere repeats; however, no alterations in the rate of sister chromatid exchange were observed. Our results demonstrate that human cells using the recombination-based pathway of telomere maintenance retain factors required for telomerase to maintain telomeres and that once the telomerase-based pathway of telomere length regulation is engaged, recombination-based elongation of telomeres can be functionally inhibited.

Binding enhancement by tertiary interactions and suicide inhibition of a Candida albicans group I intron by phosphoramidate and 2'-O-methyl hexanucleotides.

Candida albicans is one of many infectious pathogens that are evolving resistance to current treatments. RNAs provide a large class of targets for new therapeutics for fighting these organisms. One strategy for targeting RNAs uses short oligonucleotides that exhibit binding enhancement by tertiary interactions in addition to Watson-Crick pairing. A potential RNA target in C. albicans is the self-splicing group I intron in the LSU rRNA precursor. The recognition elements that align the 5' exon splice site for a ribozyme derived from this precursor are complex [Disney, M. D., Haidaris, C. G., and Turner, D. H. (2001) Biochemistry 40, 6507-6519]. These recognition elements have been used to guide design of hexanucleotide mimics of the 5' exon that have backbones modified for nuclease stability. These hexanucleotides bind as much as 100000-fold more tightly to a ribozyme derived from the intron than to a hexanucleotide mimic of the intron's internal guide sequence, r(GGAGGC). Several of these oligonucleotides inhibit precursor self-splicing via a suicide inhibition mechanism. The most promising suicide inhibitor is the ribophosphoramidate rn(GCCUC)rU, which forms more trans-spliced than cis-spliced product at oligonucleotide concentrations of >100 nM at 1 mM Mg(2+). The results indicate that short oligonucleotides modified for nuclease stability can target catalytic RNAs when the elements of tertiary interactions are complex.

A phosphoramidate substrate analog is a competitive inhibitor of the Tetrahymena group I ribozyme.

BACKGROUND: Phosphoramidate oligonucleotide analogs containing N3'-P5' linkages share many structural properties with natural nucleic acids and can be recognized by some RNA-binding proteins. Therefore, if the N-P bond is resistant to nucleolytic cleavage, these analogs may be effective substrate analog inhibitors of certain enzymes that hydrolyze RNA. We have explored the ability of the Tetrahymena group I intron ribozyme to bind and cleave DNA and RNA phosphoramidate analogs. RESULTS: The Tetrahymena group I ribozyme efficiently binds to phosphoramidate oligonucleotides but is unable to cleave the N3'-P5' bond. Although it adopts an A-form helical structure, the deoxyribo-phosphoramidate analog, like DNA, does not dock efficiently into the ribozyme catalytic core. In contrast, the ribo-phosphoramidate analog docks similarly to the native RNA substrate, and behaves as a competitive inhibitor of the group I intron 5' splicing reaction. CONCLUSIONS: Ribo-N3'-P5' phosphoramidate oligonucleotides are useful tools for structural and functional studies of ribozymes as well as protein-RNA interactions.

Synthetic oligonucleotides as RNA mimetics: 2'-modified Rnas and N3'-->P5' phosphoramidates.

Significant interest in synthetic DNA and RNA oligonucleotides and their analogues has marked the past two decades of research in chemistry and biochemistry. This attention was largely determined by the great potential of these compounds for various therapeutic applications such as antisense, antigene and ribozyme-based agents. Modified oligonucleotides have also become powerful molecular biological and biochemical research tools that allow fast and efficient regulation of gene expression and gene functions in vitro and in vivo. These applications in turn are based on the ability of the oligonucleotides to form highly sequence-specific complexes with nucleic acid targets of interest. This review summarizes recent advances in the design, synthesis, biochemical and structural properties of various RNA analogues. These comprise 3'-modified oligonucleotide N3'-->P5' phosphoramidates, analogues with modifications at the 2'-position of nucleoside sugar rings, or combinations of the two. Among the properties of the RNA minetics reviewed here are the thermal stability of their duplexes and triplexes, hydrolytic resistance to cellular nucleases and biological activity in in vitro and in vivo systems. In addition, key structural aspects of the complexes formed by the RNA analogues, including interaction with water molecules and ions, are analyzed and presented.

Contributions of individual nucleotides to tertiary binding of substrate by a Pneumocystis carinii group I intron.

Pneumocystis carinii is a mammalian pathogen that infects and kills immunocompromised hosts such as cancer and AIDS patients. The LSU rRNA precursor of P. carinii contains a conserved group I intron that is an attractive drug target because humans do not contain group I introns. The oligonucleotide r(AUGACU), whose sequence mimics the 3'-end of the 5'-exon, binds to a ribozyme derived from the intron with a K(d) of 5.2 nM, which is 61000-fold tighter than expected from base-pairing alone [Testa, S. M., Haidaris, G. C., Gigliotti, F., and Turner, D. H. (1997) Biochemistry 36, 9379-9385]. Thus, oligonucleotide binding is enhanced by tertiary interactions. To localize interactions that give rise to this tertiary stability, binding to the ribozyme has been measured as a function of oligonucleotide length and sequence. The results indicate that 4.3 kcal/mol of tertiary stability is due to a G.U pair that forms at the intron's splice junction. Eliminating nucleotides at the 5'-end of r(AUGACU) does not affect intron binding more than expected from differences in base-pairing until r((___)ACU), which binds much more tightly than expected. Adding a C at the 5'- or 3'-end that can potentially form a C-G pair with the target has little effect on binding affinity. Truncated oligonucleotides were tested for their ability to inhibit intron self-splicing via a suicide inhibition mechanism. The tetramer, r((__)GACU), retains similar binding affinity and reactivity as the hexamer, r(AUGACU). Thus oligonucleotides as short as tetramers might serve as therapeutics that can use a suicide inhibition mechanism to inhibit self-splicing. Results with a phosphoramidate tetramer and thiophosphoramidate hexamer indicate that oligonucleotides with backbones stable to nuclease digestion retain favorable binding and reactivity properties.

Synthesis and properties of RNA analogs-oligoribonucleotide N3'-->P5' phosphoramidates.

The synthesis and characterization of RNA mimetics, uniformly modified oligoribonucleotide N3'-->P5' phosphoramidates containing all four natural bases (uracil, cytosine, adenine and guanine) as well as thymidine and 2,6-diaminopurine, are described. These RNA analogs contain N3'-->P5' phosphoramidate internucleotide linkages which replaced natural RNA O3'-->P5' phosphodiester groups. These oligonucleo-tides were constructed from novel monomeric units (2'- t -butyldimethylsilyl)-3'-(monomethoxyltrityl)-amino-nucleoside-5'- phos phoramidites, the preparation of which is also presented. Several mixed base 9-13mer oligoribonucleotide phosphoramidates were synthesized with step-wise coupling yields of 96-98%. Thermal denaturation experiments demonstrated that ribo-N3'-->P5' phosphoramidates form stable duplexes with a complementary RNA strand. Thus, the melting temperature ( T (m)) of a duplex formed by a 13mer ribo-N3'-->P5' phosphoramidate (84 degrees C) was higher than that observed for the isosequential natural RNA oligomer (64.0 degrees C), or for the 2'-deoxy-N3'-->P5' phosphoramidate counterpart (71.7 degrees C). Moreover, substitution of adenine by 2, 6-diaminopurine in an oligoribophosphoramidate pentamer resulted in a very significant increase in the duplex melting temperature ( approximately 7 degrees C per base substitution). The RNA phosphoramidates also showed similar rates of hydrolysis by both RNase A and RNase T(1)as compared to natural RNA oligomers. The data presented indicate that this class of RNA analogs may be used as structural and functional RNA mimetics.

In vitro suicide inhibition of self-splicing of a group I intron from Pneumocystis carinii by an N3' --> P5' phosphoramidate hexanucleotide.

Binding enhancement by tertiary interactions is a strategy that takes advantage of the higher order folding of functionally important RNAs to bind short nucleic acid-based compounds tightly and more specifically than possible by simple base pairing. For example, tertiary interactions enhance binding of specific hexamers to a group I intron ribozyme from the opportunistic pathogen Pneumocystis carinii by 1,000- to 100,000-fold relative to binding by only base pairing. One such hexamer, d(AnTnGnAnCn)rU, contains an N3' --> P5' phosphoramidate deoxysugar-phosphate backbone (n) that is resistant to chemical and enzymatic decay. Here, it is shown that this hexamer is also a suicide inhibitor of the intron's self-splicing reaction in vitro. The hexamer is ligated in trans to the 3' exon of the precursor, producing dead-end products. At 4 mM Mg2+, the fraction of trans-spliced product is greater than normally spliced product at hexamer concentrations as low as 200 nM. This provides an additional level of specificity for compounds that can exploit the catalytic potential of complexes with RNA targets.

Oligonucleotide N3'-->P5' phosphoramidates as potential therapeutic agents.

Uniformly modified nucleic acids analogues, oligonucleotide N3'-->P5' phosphoramidates, containing 3'-amino instead of 3'-hydroxyl nucleosides, were synthesized and studied. These compounds form very stable duplexes with complementary native phosphodiester DNA and exceptionally stable duplexes with RNA strands. Increases in duplex melting temperature, deltaTm, relatively to their phosphodiester counterparts, reaches 2.9-3.5 degrees C per modified nucleoside. Moreover, the phosphoramidate compounds form extremely stable triple stranded complexes with single or double stranded DNA oligomers under near physiological salt and pH conditions. Melting temperatures of these triplexes usually exceed that of the isosequential phosphodiester counterparts by up to 35 degrees C. For 11-15-mers 2'-deoxyphosphoramidates are structurally and functionally similar to the native RNA molecules and thus can be used as RNA decoys. They are resistant to enzymatic digestion by nucleases both in vitro and in vivo. Oligonucleotide phosphoramidates apparently are cell permeable, and they have a good bioavailability and biodistribution, while being non-toxic in mice at therapeutically relevant doses. Duplexes of the several studied phosphoramidates with complementary RNA strands apparently are not substrates for RNase H in vitro. Despite that, these compounds exerted high sequence-specific antisense activity in various cell lines and in SCID mice. The observed in vitro lack of RNase H recognition of the RNA:phosphoramidate duplexes may result in better specificity in biological activity of these compounds relative to RNase H inducing oligonucleotides. Experimental results also indicate that oligonucleotide phosphoramidates can be used as efficient and specific modulators of gene expression by an antigene mechanism of action. Finally, the oligo-2'-deoxyphosphoramidate double stranded complexes can structurally mimic native RNA complexes, which could be efficiently and specifically recognized by the RNA binding proteins, such as HIV-1 Rev and Tat.

RNA mimetics: oligoribonucleotide N3'-->P5' phosphoramidates.

The synthesis and properties of novel RNA mimetics, oligoribonucleotide N3'-->P5' phosphoramidates, are described. These oligonucleotides contain 3'-aminoribonucleosides connected via N3'-->P5' phosphoramidate linkages, replacing the native RNA O3'-->P5' phosphodiester counterparts. The key monomers 2'-t-butyldimethylsilyl-3'-(monomethoxytrityl)-amino-5'-phospho ramidi tes were synthesized and used to prepare the oligonucleotide phosphoramidates using a solid phase methodology based on the phosphoramidite transfer reaction. Oligoribophosphoramidates are very resistant to enzymatic hydrolysis by snake venom phosphodiesterase. These compounds form stable duplexes with complementary natural phosphodiester DNA and RNA strands, as well as with 2'-deoxy N3'-->P5' phosphoramidates. The increase in melting temperature, Delta T m, was 5-14 degrees C relative to the 2'-deoxy phosphoramidates for decanucleotides. Also, the thermal stability of the ribophosphoramidatehomoduplex was noticeably higher (Delta T m +9.5 degrees C) than that for the isosequential 2'-deoxy phosphoramidate complex. Furthermore, the oligopyrimidine ribo N3'-->P5' phosphoramidate formed an extremely stable triplex with an oligopurine/oligopyrimidine DNA duplex with Delta T m +14.3 degrees C relative to the 2'-deoxy N3'-->P5' phosphoramidate counterpart. The properties of the oligoribonucleotide N3'-->P5' phosphoramidates indicate that these compounds can be used as hydrolytically stable structural and functional RNA mimetics.

NMR solution structure of the N3' --> P5' phosphoramidate duplex d(CGCGAATTCGCG)2 by the iterative relaxation matrix approach.

High-resolution 2D NMR spectra of the duplex CGCGAATTCGCG with deoxyribose sugars but with the normal phosphodiester linker replaced by an N3' --> P5' phosphoramidate (NP) group have been used to establish a solution structure for the duplex. Distance, angle, and base pair hydrogen-bonding constraints were used to refine the structure by use of the iterative relaxation matrix approach (IRMA). The phosphoramidate NH proton signal could be observed in DMSO at low temperature but not in H2O and D2O. For this reason, the structure was refined with the -NH in each of the two possible low-energy configurations. The structure with the nitrogen lone pair located between the nonbridging oxygen atoms of the 5'-phosphate group consistently had the lowest energy and RMSD values, consistent with an X-ray analysis of the same duplex [Tereshko, V., Gryaznov, S. , and Egli, M. (1998) J. Am. Chem. Soc. 120, 269-283]. In the refined structure, the sugars are in the C3'-endo conformation with the change from the normal C2'-endo conformation of deoxyribose apparently being driven by the gauche effect and the change in electronegativity from the 3'O to the 3'NH group. In agreement with preliminary studies [Ding, D., Gryaznov, S. M., Lloyd, D. H., Chandrasekaran, S., Yao, S., Ratmeyer, L., Pan, Y., and Wilson, W. D. (1996) Nucleic Acids Res. 24, 354-360], the backbone conformation in the NP duplex is very close to classical A-form values. Comparison of phosphodiester and phosphoramidate structures suggests that their backbones have global conformations that are primarily a function of the low-energy state of the sugar ring. A somewhat more complex situation arises when base pair conformation is analyzed with many of the base pairs having a conformation between those of classical A- and B-form helices. The effects of the 2' substituent are obviously important in specifying the final conformation of the stacked bases in either an A-form or B-form helix. It is clear, however, that conversion of the normal phosphodiester of DNA into a phosphoramidate linkage yields a nucleic acid that behaves much more like RNA than DNA, and it has been shown that NP sequences can bind to RNA-directed proteins [Rigl, C. T., Lloyd, D. H., Tsou, D. S., Gryaznov, S. M., and Wilson, W. D. (1997) Biochemistry 36, 650-659].

The detection of oligonucleotide N3'-->P5' phosphoramidate/RNA duplexes with capillary gel electrophoresis.

Oligonucleotide N3'-->P5' phosphoramidates (3'-phosphoramidates) are DNA analogs that are presently under investigation as potential therapeutic agents. These compounds may also hold promise as a diagnostic tool. Here, we describe a rapid method for the analysis of single-stranded RNA fragments utilizing 3'-phosphoramidate oligonucleotides as probes in conjunction with capillary gel electrophoresis (CGE). 3'-Phosphoramidate 9-mers were mixed with complimentary RNA, and CGE was used to monitor duplex formation. Complimentary strands of RNA and 3'-phosphoramidate formed duplexes that gave unique relative mobilities based on an internal standard. The ability of CGE to discriminate between perfect duplexes and duplexes that contain a base mismatch was also investigated. However, the primary focus of this work was to determine CGE's ability to detect the presence of the 3'-phosphoramidates/RNA duplex under routine electrophoretic running conditions. Polyacrylamide gel electrophoresis analysis was utilized to verify duplex formation.

Antisense binding enhanced by tertiary interactions: binding of phosphorothioate and N3'-->P5' phosphoramidate hexanucleotides to the catalytic core of a group I ribozyme from the mammalian pathogen Pneumocystis carinii.

Pneumocystis carinii is the most common lethal opportunistic pathogen infecting Acquired Immune Deficiency Syndrome (AIDS) patients, and more effective therapeutics for it are needed. P. carinii, but not humans, contain RNA self-splicing group I introns, so these functionally important RNAs are potential anti-fungal targets. In vitro, d(ATGACT), which mimics the 3' end of the 5' exon of a conserved ribosomal RNA group I intron from mouse-derived Pneumocystis carinii binds to a ribozyme that is a truncated form of this intron. The binding is about 30,000 times tighter than expected for simple base-pairing because binding is enhanced by tertiary interactions. Here we report the effects of modifying the phosphodiester backbone of d(ATGACT) with phosphorothioate and of d(ATGAC)rU with N3'-->P5' phosphoramidate linkages. The enhancement of binding by tertiary interactions is not substantially decreased, and in some cases is increased when single Rp and Sp phosphorothioate substitutions are made, although overall binding is weaker by up to 6-fold. A mixture of 5' exon mimic isomers that each contain five phosphorothioate linkages binds to the ribozyme at least 14-fold less tightly than the corresponding phosphodiester mimic. In contrast, the 5' exon mimic with five internal N3'-->P5' phosphoramidate linkages binds 4-fold more tightly than d(ATGAC)rU. This increased binding is largely due to more favorable base-pairing, but tertiary interactions still enhance binding by more than 2, 000-fold. These results indicate that chemically modified, nuclease stable 5' exon mimics can act as antisense agents with binding enhanced by tertiary interactions (BETI). This strategy permits design of short antisense agents with high specificity.

alpha-Oligodeoxyribonucleotide N3'-->P5' phosphoramidates: synthesis and duplex formation.

The synthesis and hybridization properties of novel nucleic acid analogs, alpha-anomeric oligodeoxyribonucleotide N3'-->P5' phosphoramidates, are described. The alpha-3'-aminonucleoside building blocks used for oligonucleotide synthesis were synthesized from 3'-azido-3'-deoxythymidine or 3'-azido-2',3'-dideoxyuridine via acid catalyzed anomerization or transglycosylation reactions. The base-protected alpha-5'-O-DMT-3'-aminonucleosides were assembled into dimers and oligonucleotides on a solid support using the oxidative phosphorylation method.1H NMR analysis of the alpha-N3'-->P5' phosphoramidate dimer structures indicates significant differences in the sugar puckering of these compounds relative to the beta-N3'-->P5' phosphoramidates and to the alpha-phosphodiester counterparts. Additionally, the ability of the alpha-oligonucleotide N3'-->P5' phosphoramidates to form duplexes was studied using thermal denaturation experiments. Thus the N3'-->P5' phosphoramidate decamer containing only alpha-thymidine residues did not bind to poly(A) and exhibited lower duplex thermal stability with poly(dA) than that for the corresponding beta-anomeric phosphoramidate counterpart. A mixed base decamer alpha-CTTCTTCCTT formed duplexes with the RNA and DNA complementary strands only in a parallel orientation. Melting temperatures of these complexes were significantly lower, by 34-47 or 15-25 degrees C, than for the duplexes formed by the isosequential beta-phosphoramidates in antiparallel and parallel orientations respectively. In contrast, the alpha-decaadenylic N3'-->P5' phosphoramidate formed duplexes with both RNA and DNA complementary strands with a stability similar to that of the corresponding beta-anomeric phosphoramidate. Moreover, the self-complementary oligonucleotide alpha-ATATATATAT did not form an alpha:alpha homoduplex. These results demonstrate the effects of 3'-aminonucleoside anomeric configuration on sugar puckering and consequently on stability of the duplexes.

Zwitterionic oligodeoxyribonucleotide N3'-->P5' phosphoramidates: synthesis and properties.

Zwitterionic, net neutral oligonucleotides containing alternating negatively charged N3'-->P5' phosphoramidate monoester and positively charged phosphoramidate diester groups were synthesized. The ability of zwitterionic phosphoramidates to form complexes with complementary DNA and RNA was evaluated. Stoichiometry and salt dependency of these complexes were determined as a function of the nature of the heterocyclic bases of the zwitterionic compounds. Unlike the melting temperatures of the natural phosphodiester-containing oligomers, the T m of the duplexes formed with the zwitterionic oligothymidylates was salt concentration independent. The thermal stability of these duplexes was much higher with Delta T m values of 20-35 degrees C relatively to phosphodiester counterparts at low salt concentrations. The zwitterionic oligoadenylate formed only 2Py:1Pu triplexes with complementary poly(U) or poly(dT) strands. The thermal stability of these complexes was dependent on salt concentration. Also, the T m values of the complexes formed by the zwitterionic oligoadenylate with poly(U) were 6-41 degrees C higher than for the natural phosphodiester counterpart. Triplexes of this compound with poly(dT) were also more stable with a Delta T m value of 22 degrees C at low salt concentrations. Complexes formed by the zwitterionic oligonucleotides with complementary RNAs were not substrates for RNase H. Surprisingly, the duplex formed by the all anionic alternating N3'-->P5'phosphoramidate-phosphodiester oligothymidylate and poly(A) was a good substrate for RNase H.

A physico-chemical study of triple helix formation by an oligodeoxythymidylate with N3'--> P5' phosphoramidate linkages.

Non-denaturing gel retardation assay, DNA melting experiments and FTIR spectroscopy were used to characterize the triple helix formed by a 15mer 2'-deoxythymidylate with N3'-->P5'phosphoramidate linkages with its target sequence. The results indicate that: (i) the pentadecadeoxythymidylate with phosphoramidate linkages [dT15(np)] is highly potent to form a triple helix with a dT15*dA15target duplex through Hoogsteenbase-pairing; (ii) it forms a dT15(np)*dA15xdT15(np) triplex with the single-stranded oligo-2'-deoxyadenylate (dA15) without detectable double-helical intermediate; (iii) it does not only form a triple helix on the dT15*dA15target duplex, but also partially displaces the dT15 strand from the dT15*dA15duplex to form a dT15(np)*dA15xdT15(np) complex.

Hydration effects on the duplex stability of phosphoramidate DNA-RNA oligomers.

Recent studies on uniformly modified oligonucleotides containing 3'-NHP(O)(O-)O-5'internucleoside linkages (3'amidate) and alternatively modified oligonucleotides containing 3'-O(O-)(O)PNH-5'internucleoside linkages (5'amidate) have shown that 3'amidate duplexes, formed with DNA or RNA complementary strands, are more stable in water than those of the corresponding phosphodiesters. In contrast, 5'amidates do not form duplexes at all. There is no steric reason that the 5'amidate duplex should not form. We demonstrate that these differences arise from differential solvation of the sugar-phosphate backbones. By molecular dynamics calculations on models of 10mer single-stranded DNA and double-stranded DNA-RNA molecules, both with and without the phosphoramidate backbone modifications, we show that the single-stranded 3'amidate and 5'amidate backbones are equally well solvated, but the 5'amidate backbone is not adequately solvated in an A-form duplex. These results are supported by quantum chemical free energy of solvation calculations which show that the 3'amidate backbone is favored relative to the 5'amidate backbone.

Structural RNA mimetics: N3'-->P5' phosphoramidate DNA analogs of HIV-1 RRE and TAR RNA form A-type helices that bind specifically to Rev and Tat-related peptides.

An attractive strategy for the development of anti-retroviral drugs is the exploration of compounds that mimic RNA control regions of the viral genome and act as "decoys" to sequester viral gene regulatory proteins. Decoys consisting of RNA, however, are chemically unstable and readily degraded by cellular nucleases. DNA decoys, which are slightly more stable, also might not be appropriate because of possible structural differences between RNA and DNA helices and the complexes they form with proteins. It was recently reported, however, that DNA analogs with modified N3'-->P5' phosphoramidate sugar-phosphate backbones are stable and nuclease-resistant and exist predominately as A-form helices in solution [Gryaznov, S., et al. (1995) Proc. Natl. Acad. Sci. U.S.A. 92, 5798-5802]. We now report that oligonucleotide N3'-->P5' phosphoramidates DNA analogs of HIV-1 RRE IIB and TAR RNA form stable duplexes that exist in the A form as judged by circular dichroism (CD). Moreover, gel shift assays demonstrate that these phosphoramidates can specifically bind to peptides derived from HIV-1 Rev and Tat proteins. Isosequential phosphodiester DNA duplexes, existing in the B form by CD, do not bind to the respective peptides under the experimental conditions used. These results suggest the possibility that nuclease-resistant oligonucleotide N3'-->P5' phosphoramidates might serve as RNA-like decoys and disrupt specific viral RNA/protein interactions such as RRE/Rev and TAR/Tat in HIV-1.

Oligo-2'-fluoro-2'-deoxynucleotide N3'-->P5' phosphoramidates: synthesis and properties.

Uniformly modified oligodeoxyribonucleotide N3'-->P5' phosphoramidates containing 2'-fluoro-2'-deoxy-pyrimidine nucleosides were synthesized using an efficient interphase amidite transfer reaction. The 3'-amino group of solid phase-supported 2'-fluoro-2'-deoxynucleoside was used as an acceptor and 5'-diisopropylamino phosphoramidite as a donor of a phosphoramidite group in the tetrazole-catalyzed exchange reaction. Subsequent oxidation with aqueous iodine resulted in formation of an internucleoside phosphoramidate diester. The prepared oligo-2'-fluoro-nucleotide N3'-->P5' phosphoramidates form extremely stable duplexes with complementary nucleic acids: relative to isosequential phosphodiester oligomers, the melting temperature Tm of their duplexes with DNA or RNA was increased approximately 4 or 5 degrees C per modification respectively. Moreover, these compounds are highly resistant to enzymatic hydrolysis by snake venom phosphodiesterase and they are 4-5 times more stable in acidic media (pH 2.2-5.3) than the parent oligo-2'-deoxynucleotide N3'-->P5' phosphoramidates. The described properties of the oligo-2'-fluoronucleotide N3'-->P5' phosphoramidates suggest that they may have good potential for diagnostic and antisense therapeutic applications.

Stable triple helices formed by oligonucleotide N3'-->P5' phosphoramidates inhibit transcription elongation.

Oligonucleotide analogs with N3'-->P5' phosphoramidate linkages bind to the major groove of double-helical DNA at specific oligopurine.oligopyrimidine sequences. These triple-helical complexes are much more stable than those formed by oligonucleotides with natural phosphodiester linkages. Oligonucleotide phosphoramidates containing thymine and cytosine or thymine, cytosine, and guanine bind strongly to the polypurine tract of human immunodeficiency virus proviral DNA under physiological conditions. Site-specific cleavage by the Dra I restriction enzyme at the 5' end of the polypurine sequence was inhibited by triplex formation. A eukaryotic transcription assay was used to investigate the effect of oligophosphoramidate binding to the polypurine tract sequence on transcription of the type 1 human immunodeficiency virus nef gene under the control of a cytomegalovirus promoter. An efficient arrest of RNA polymerase II was observed at the specific triplex site at submicromolar concentrations.

Analysis of a ribonuclease H digestion of N3'-->P5' phosphoramidate-RNA duplexes by capillary gel electrophoresis.

Phosphodiester oligonucleotides (ODNs) and their analogs are presently being investigated as potential antisense therapeutics in the treatment of viral infections and various forms of cancer. here, we would like to report results from an investigation of activity for a ribonuclease H (RNase H) mediated RNA digestion assay in the duplexes formed by an ODN or the ODN analog, N3'-->P5' phosphoramidate (3'-phosphoramidate), and complimentary RNA strands. Capillary gel electrophoresis (CGE) proved to be an effective method for determining RNA hydrolysis in the presence of RNase H. RNA and an ODN or RNA and a 3'-phosphoramidate were hybridized in a Tris-HCl, MgCl2 buffer at room temperature (RT) and incubated with RNase H. Digestions were carried out at RT or at 37 degrees C. Control samples were unhybridized RNA with RNase H, RNA without RNase H, and duplexes (RNA-ODN or 3'-phosphoramidate) without RNase H. All controls were incubated in Tris-HCl, MgCl2 buffer, and sample aliquots were analyzed at various time intervals. A homodecamer, (dT)10, was used as an internal standard to determine the relative migration time of the RNA strand. The final digestion products for the duplexes and the various controls were monitored by CGE. In addition, polyacrylamide gel electrophoresis (PAGE) was used in conjunction with Stains-All (staining) and a densitometric analysis to verify CGE results.