Single base discrimination for ribonuclease H-dependent antisense effects within intact human leukaemia cells.

We have previously demonstrated, in vitro, that phosphodiester and phosphorothioate antisense oligodeoxynucleotides could direct ribonuclease H to cleave non-target RNA sites and that chimeric methylphosphonodiester/phosphodiester analogue structures were substantially more specific. In this report we show that such chimeric molecules can promote point mutation-specific scission of target mRNA by both Escherichia coli and human RNases H in vitro. Intact human leukaemia cells 'biochemically microinjected' with antisense effectors demonstrated efficient suppression of target mRNA expression. It was noted that the chimeric methylphosphonodiester/phosphodiester structures showed single base discrimination, whereas neither the phosphodiester nor phosphorothioate compounds were as stringent. Finally, we show that the antisense effects obtained in intact cells were due to endogenous RNase H activity.     

Properties of circular dumbbell RNA/DNA chimeric oligonucleotides containing antisense phosphodiester oligonucleotides.

We have designed a new class of oligonucleotides, "dumbbell RNA/DNA chimeric phosphodiesters", containing two alkyl loop structures with RNA/DNA base pairs (sense (RNA) and antisense (DNA) in the double helical stem. The reaction of nicked (NDRDON) and circular (CDRDON) dumbbell RNA/DNA chimeric oligonucleotides with RNaseH gave the corresponding antisense phosphodiester oligonucleotide together with the sense RNA cleavage products. The liberated antisense phosphodiester oligodeoxynucleotide was bound to the target 35mer RNA, which gave 35mer RNA cleavage products by treatment with RNaseH. The circular dumbbell RNA/DNA chimeric oligonucleotide showed more nuclease resistance than the linear antisense phosphodiester oligodeoxynucleotide(anti-ODN) and the nicked dumbbell RNA/DNA chimeric oligonucleotide.     

Inhibition of HIV tat-TAR interactions by an antisense oligo-2'-O-methylribonucleoside methylphosphonate

An antisense oligo-2'-O-methylribonucleotide having alternating methylphosphonate/phosphodiester linkages, 1676, whose sequence is complementary to the apical stem-loop of HIV-1 TAR RNA, was prepared to determine its effects on Tat protein-TAR interaction and Tat-mediated gene transactivation in cell culture. This oligomer and its all-phosphodiester analogue, 1707, were shown to: (1) bind to TAR at 37 degrees C with K(d)'s in the low nM concentration range; (2) inhibit Tat-TAR complex formation; and (3) inhibit expression of a chloramphenicol reporter gene under control of the HIV LTR in HeLa HL3T1 cells in culture.     

Nuclease resistance and RNase H sensitivity of oligonucleotides bridged by oligomethylenediol and oligoethylene glycol linkers

The properties of new chimeric oligodeoxynucleotides made of short sequences (tetramers, pentamers, octamers, and decamers) bridged by hexamethylenediol and hexaethylene glycol linkers have been investigated. These chimeric oligonucleotides showed an improved resistance toward snake venom 3'-phosphodiesterase, with an increased stability when a terminal 3'-3'-internucleotide phosphodiester bond is present. It also has been demonstrated that the hybrid complexes formed by bridged oligonucleotides and a complementary 20-mer RNA are able to elicit the activity of ribonuclease H (RNase H) from Escherichia coli. The substrate properties of chimeric oligonucleotides depend on the length of the oligonucleotide fragments bridged by linkers. Introduction of a nonnucleotide spacer into the native oligonucleotide only slightly hampers the extent of the RNA hydrolysis in the hybrid complexes, whereas a modification of the site of reaction is observed as a possible consequence of the steric disturbance due to the aliphatic linkers. Hence, these new chimeric oligonucleotides, namely, short oligonucleotide fragments bridged by nonnucleotide linkers, demonstrate a favorable combination of exonuclease resistance and high substrate activity toward RNase H. As a consequence, these chimeric oligonucleotides could be proposed as new, promising analogs to be used in the antisense strategy.     

Phosphorothioate oligodeoxynucleotides inhibit basic fibroblast growth factor-induced angiogenesis in vitro and in vivo.

Angiogenesis is regulated by heparin-binding growth factors, such as basic fibroblast growth factor (bFGF). We investigated the effects of phosphorothioate-mediated oligodeoxynucleotides (PS-ODN) on bFGF-induced angiogenesis. Because PS-ODN are polyanions, they can also bind many heparin-binding proteins. On a basement matrix using a Matrigel matrix, we observed <50% tube formation by human umbilical endothelial cells with 10 microM bFGF, vascular endothelial growth factor, or nuclear factor-kappaB (NF-kappaB) antisense and sense PS-ODN, while phosphodiester oligodeoxynucleotides (PO-ODNs) were not affected. The PS-ODN, but not the PO-ODN, inhibited the bFGF-induced rabbit corneal neovascularization. In albino rats, the NF-kappaB antisense PS-ODN showed a low rescue score for bFGF-dependent photoreceptor rescue because of their degradation by constant light exposure. However, antisense PS-ODN active against bFGF inhibited angiogenesis more strongly than did the antisense NF-kappaB PS-ODN. Because of the important role bFGF plays in angiogenesis, some PS-ODN may serve as potent antiangiogenic compounds that act through a combination of polyanionic phosphorothioate effects and a sequence-specific antisense mechanism.     

Identification of a good c-myc antisense oligodeoxynucleotide target site and the inactivity at this site of novel NCH triplet--targeting ribozymes.

A region of c-myc mRNA was identified which permitted very efficient antisense effects to be achieved in living cells using chimeric methylphosphonate--phosphodiester antisense effectors. Novel inosine--containing ribozymes (which cleave after NCH triplets) were directed to an ACA triplet within this region and delivered into living cells. No ribozyme intracellular activity could be identified. Very low ribozyme function was also observed in in vitro assays using a 1700nt substrate RNA.     

Expression of c-myc is not critical for cell proliferation in established human leukemia lines

Background

A study was undertaken to resolve preliminary conflicting results on the proliferation of leukemia cells observed with different c-myc antisense oligonucleotides.

Results

RNase H-active, chimeric methylphosphonodiester / phosphodiester antisense oligodeoxynucleotides targeting bases 1147–1166 of c-myc mRNA downregulated c-Myc protein and induced apoptosis and cell cycle arrest respectively in cultures of MOLT-4 and KYO1 human leukemia cells. In contrast, an RNase H-inactive, morpholino antisense oligonucleotide analogue 28-mer, simultaneously targeting the exon 2 splice acceptor site and initiation codon, reduced c-Myc protein to barely detectable levels but did not affect cell proliferation in these or other leukemia lines. The RNase H-active oligodeoxynucleotide 20-mers contained the phosphodiester linked motif CGTTG, which as an apoptosis inducing CpG oligodeoxynucleotide 5-mer of sequence type CGNNN (N = A, G, C, or T) had potent activity against MOLT-4 cells. The 5-mer mimicked the antiproliferative effects of the 20-mer in the absence of any antisense activity against c-myc mRNA, while the latter still reduced expression of c-myc in a subline of MOLT-4 cells that had been selected for resistance to CGTTA, but in this case the oligodeoxynucleotide failed to induce apoptosis or cell cycle arrest.

Conclusions

We conclude that the biological activity of the chimeric c-myc antisense 20-mers resulted from a non-antisense mechanism related to the CGTTG motif contained within the sequence, and not through downregulation of c-myc. Although the oncogene may have been implicated in the etiology of the original leukemias, expression of c-myc is apparently no longer required to sustain continuous cell proliferation in these culture lines.     

Selecting optimal oligonucleotide composition for maximal antisense effect following streptolysin O-mediated delivery into human leukaemia cells.

It is widely accepted that most cell types efficiently exclude oligonucleotides in vitro and require specific delivery systems, such as cationic lipids, to enhance uptake and subsequent antisense effects. Oligonucleotides are not readily transfected into leukaemia cell lines using cationic lipid systems and streptolysin O (SLO) is used to effect their delivery. We wished to investigate the optimal oligonucleotide composition for antisense efficacy and specificity following delivery into leukaemia cells using SLO. For this study the well characterised chronic myeloid leukaemia cell line KYO-1 was selected and oligonucleotides (20mers) were targeted to an empirically identified accessible site of c- myc mRNA. The efficiency and specificity of antisense effect was measured 4 and 24 h after SLO-mediated delivery of the oligonucleotides. C5-propyne phosphodiester and phosphorothioate compounds were found to present substantial non-specific effects at 20 microM but were inactive at 0.2 microM. Indeed, no antisense-specific effect was noted at any concentration at either time. All of the other oligonucleotides tested induced some measurable antisense effect, except 7 (chimeric, all-phosphorothioate, 2'-methoxyethoxy termini) which was essentially inactive at 20 microM. The rank efficiency order of the remaining antisense compounds was 4 = 3 >> 9 >> 10 = 8 = 5 = 6 > 11. The efficient antisense effects induced by the chimeric methylphosphonate-phosphodiester compounds were found to be highly specific. Increased phosphorothioate content in the oligonucleotide backbone correlated with reduced antisense activity (efficacy: 2'-methoxyethoxy series 9 >> 8 >> 7, 2'-methoxytriethoxy series 10 > 11). No consistent evidence was obtained for increased activity correlating with increased oligonucleotide-mRNA heteroduplex thermal stability. In conclusion, the chimeric methylphosphonate-phosphodiester oligodeoxynucleotides present the most favourable characteristics of the compounds tested, for efficient and specific antisense suppression of gene expression following SLO-mediated delivery.     

Modulation of CpG oligodeoxynucleotide-mediated immune stimulation by locked nucleic acid (LNA)

Locked nucleic acid (LNA) is an RNA derivative that when introduced into oligodeoxynucleotides (ODN), mediates high efficacy and stability. CpG ODNs are potent immune stimulators and are recognized by toll-like receptor-9 (TLR9). Some phosphorothioate antisense ODNs bearing CpG dinucleotides have been shown to possess immune modulatory capacities. We investigated the effects of LNA substitutions on immune stimulation mediated by antisense ODN G3139 or CpG ODN 2006. LNA ODNs were tested for their ability to stimulate cytokine secretion from human immune cells or TLR9-dependent signaling. Phosphorothioate chimeric LNA/DNA antisense ODNs with phosphodiester-linked LNA nucleobases at both ends showed a marked decrease of immune modulation with an increasing number of 3' and 5' LNA bases. In addition, guanosine-LNA and cytosine-LNA or simply cytosine-LNA substitutions in the CpG dinucleotides of ODN 2006 led to strong decrease or near complete loss of immune modulation. TLR9-mediated signaling was similarly affected. These data indicate that increasing amounts of LNA residues in the flanks or substitutions of CpG nucleobases with LNA reduce or eliminate the immune stimulatory effects of CpG-containing phosphorothioate ODN.     

Biotinylated antisense methylphosphonate oligodeoxynucleotides. Inhibition of spliceosome assembly and affinity selection of U1 and U2 small nuclear RNPs.

Methylphosphonate (PC) backbone oligodeoxynucleotides complementary to the 5'-terminal nucleotides of U1 and U2 small nuclear (sn) RNAs do not elicit RNase H action under conditions in which natural (phosphodiester) oligodeoxynucleotides yield extensive RNase H cleavage. We show here that antisense PC oligonucleotides can mask sites in U1 and U2 snRNPs that are required for spliceosome formation. We further report that biotinylated derivatives of antisense PC oligos can be used for affinity selection of U1 and U2 snRNPs.     

Marek's disease virus (MDV) ICP4, pp38, and meq genes are involved in the maintenance of transformation of MDCC-MSB1 MDV-transformed lymphoblastoid cells.

An antisense strategy has been used to identify genes important for the maintenance of transformation of MDCC-MSB1 (MSB1) Marek's disease virus-transformed lymphoblastoid cells. Oligodeoxynucleotides antisense to the predicted translation initiation regions of ICP4 and pp38 mRNAs inhibited proliferation of MSB1 cells but not MDCC-CU91 (CU91) reticuloendotheliosis virus-transformed cells. Control oligodeoxynucleotides having the same base composition but a different sequence did not inhibit MSB1 cell proliferation. In addition, ICP4 and pp38 antisense oligodeoxynucleotides resulted in 77- and 100-fold reductions in colony formation by MSB1 cells in soft agar, respectively. To extend and corroborate these results, a novel system based on efficiently regulated expression of eukaryotic genes by a chimeric mammalian transactivator, LAP267 (S. B. Baim, M. A. Labow, A. J. Levine, and T. Shenk, Proc. Natl. Acad. Sci. USA 88:5072-5076, 1991), was used. MSB1-derived stably transfected cell lines in which RNA antisense to Marek's disease virus ICP4, pp38, or meq could be induced by treatment of the cells with isopropyl-beta-D-thiogalactopyranoside (IPTG) were constructed. Control cell lines in which expression of ICP4 sense or pUC19 sequences could be induced by IPTG were also constructed. Induction of the cell lines indicated that ICP4 antisense RNA, but not ICP4 sense RNA or pUC19 RNA, inhibited proliferation of MSB1 cells. Induction of ICP4, meq, or pp38 antisense RNAs, but not ICP4 sense or pUC19 RNAs, had a dramatic effect on relative colony formation by MSB1 cells in soft agar. These results indicate that ICP4, pp38, and Meq are all involved in the maintenance of transformation of MSB1 cells.     

The therapeutic potential of antisense oligonucleotides

Specific inhibition of gene expression by antisense agents provides the basis for rational drug discovery based on molecular targets. Due to the specificity of Watson-Crick base-pair hybridization, antisense oligodeoxynucleotides have been used extensively in attempts to inhibit gene expression in both in vitro and in vivo models. Analogues modified from normal phosphodiester oligodeoxynucleotides have entered clinical trials against diseases including AIDS and cancer. Although the precise mechanism of action of these drugs has not been clarified, these oligodeoxynucleotides offer considerable promise as novel molecular therapeutics. We review the recent attempts to harness the therapeutic potential of these oligodeoxynucleotides and appraise the near-term prospects for antisense technology.     

Oligodeoxynucleotide analogs with 5'-linked anthraquinone

We report here the synthesis of novel 5'-linked oligodeoxynucleotides, both normal phosphodiester and phosphorothioate analogs, in which a covalently attached group at the 5'-terminus is an anthraquinone. These compounds represent a new class of antisense compounds in which the base sequence of the oligodeoxynucleotide serves to deliver a nuclease-resistant reactive drug-like molecule to a cellular target nucleic acid (mRNA or DNA).     

RNase H is responsible for the non-specific inhibition of in vitro translation by 2'-O-alkyl chimeric oligonucleotides: high affinity or selectivity, a dilemma to design antisense oligomers.

Ribonuclease H (RNase H) which recognizes and cleaves the RNA strand of mismatched RNA-DNA heteroduplexes can induce non-specific effects of antisense oligonucleotides. In a previous paper [Larrouy et al. (1992), Gene, 121, 189-194], we demonstrated that ODN1, a phosphodiester 15mer targeted to the AUG initiation region of alpha-globin mRNA, inhibited non-specifically beta-globin synthesis in wheat germ extract due to RNase H-mediated cleavage of beta-globin mRNA. Specificity was restored by using MP-ODN2, a methylphosphonate-phosphodiester sandwich analogue of ODN1, which limited RNase H activity on non-perfect hybrids. We report here that 2'-O-alkyl RNA-phosphodiester DNA sandwich analogues of ODN1, with the same phosphodiester window as MP-ODN2, are non-specific inhibitors of globin synthesis in wheat germ extract, whatever the substituent (methyl, allyl or butyl) on the 2'-OH. These sandwich oligomers induced the cleavage of non-target beta-globin RNA sites, similarly to the unmodified parent oligomer ODN1. This is likely due to the increased affinity of 2'-O-alkyl-ODN2 chimeric oligomers for both fully and partly complementary RNA, compared to MP-ODN2. In contrast, the fully modified 2'-O-methyl analogue of ODN1 was a very effective and highly specific antisense sequence. This was ascribed to its inability (i) to induce RNA cleavage by RNase H and (ii) to physically prevent the elongation of the polypeptide chain.     

Identification of a Good C-MYC Antisense Oligodeoxynucleotide Target Site and the Inactivity at This Site of Novel NCH Triplet-Targeting Ribozymes

Abstract

A region of c-myc mRNA was identified which permitted very efficient antisense effects to be achieved in living cells using chimeric methylphosphonate-phosphodiester antisense effectors. Novel inosine—containing ribozymes (which cleave after NCH triplets) were directed to an ACA triplet within this region and delivered into living cells. No ribozyme intracellular activity could be identified. Very low ribozyme function was also observed in in vitro assays using a 1700nt substrate RNA.     

Complementary oligodeoxynucleotide mediated inhibition of tobacco mosaic virus RNA translation in vitro.

Two different "antisense" oligodeoxynucleotides and their RNA analogues, each complementary to non-overlapping sequences of 51 bases near the 5' end of TMV RNA, inhibit in vitro translation of the genomic RNA in a rabbit reticulocyte lysate. Inhibition is dependent upon complementarity, concentration, and hybridization of the oligomers with TMV RNA. Inhibition is observed at molar ratios of TMV RNA to antisense oligomers as low as 1:1.5. A plateau of inhibition at which 10-25% of the control signal remains is achieved by molar ratios of TMV RNA:antisense DNA or RNA greater than or equal to 1:15. The extent of inhibition is not increased by the simultaneous presence of both complementary fragments. Oligodeoxynucleotides and their RNA analogues identical to the same regions of TMV RNA have no direct effect on translation, however, they can block inhibition by the antisense fragments. Translation of BMV RNA is not affected by any of the oligodeoxynucleotides. Polyacrylamide gel electrophoresis shows translation of TMV p126 is selectively inhibited. We conclude that the observed inhibition of translation is due to direct interference with ribosome function.     

Triplex formation by psoralen-conjugated chimeric oligonucleoside methylphosphonates

Interactions between nuclease-resistant, 5'-psoralen-conjugated, chimeric methylphosphonate oligodeoxyribo- or oligo-2'-O-methylribo-triplex-forming oligomers (TFOs) and a purine tract found in the envelope gene of HIV proviral DNA (env-DNA) were investigated by gel mobility shift assays or by photo-cross-linking experiments. These chimeric TFOs contain mixtures of methylphosphonate and phosphodiester internucleotide bonds. A pyrimidine chimeric TFO composed of thymidine and 5-methyl-2'-deoxycytidine (C), d-PS-TpCpTpCpTpCpTpTpTpTpTpTpCpTpC (1mp) where PS is trimethylpsoralen and p is methylphosphonate, forms a stable triplex with env-DNA whose dissociation constant is 1. 3 microM at 22 degrees C and pH 7.0. The dissociation constant of chimeric TFO 2mp, d-PS-UpCpTpCpTpCpTpUpTpUpTpUpCpTpC, decreased to 400 nM when four of the thymidines in 1mp were replaced by 5-propynyl-2'-deoxyuridines (U), a result consistent with the increased stacking interactions and hydrophobic nature of 5-propynyl-U. An even greater decrease, 470 -50 nM, was observed for the all-phosphodiester versions of 1mp and 2mp. The differences in behavior of the chimeric versus the all-phosphodiester oligomers may be related to differences in the conformations between the propynyl-U-substituted versus the nonsubstituted TFOs. Thus, in the chimeric oligomer, the stabilizing effect of the propynyl-U's may be offset by the reduced ability of the methylphosphonate backbone to assume an A-type conformation, a conformation that appears to be preferred by propynyl-U-containing TFOs. A chimeric oligo-2'-O-methylribopyrimidine with the same sequence as 1mp also formed a stable triplex, K(d) = 1.4 microM, with env-DNA. In contrast to the behavior of the pyrimidine TFOs, antiparallel A/G oligomers and parallel or antiparallel T/G oligomers did not form triplexes with env-DNA, even at oligomer concentrations of 10 microM. This lack of binding may be a consequence of the low G content (33%) of the triplex binding site. Irradiation of triplexes formed between the pyrimidine TFOs and env-DNA resulted in formation of photoadducts with either the upper-strand C or the lower-strand T at the 5'-CpA-3' duplex/triplex junction. No interstrand cross-links were observed. The presence of a 5-propynyl-U at the 5'-end of the oligomer caused a reduction in the amount of upper-strand photoadduct but had no effect on photoadduct formation with the lower strand, suggesting that increased stacking interactions caused by the presence of the 5-propynyl-U change the orientation of psoralen with respect to the upper-strand C. The ability of chimeric methylphosphonate TFOs to bind to DNA, combined with their resistance to degradation by serum 3'-exonucleases, suggests that they may have utility in biological experiments.     

Synthesis, characterization, and biological properties of small branched RNA fragments containing chiral (Rp and Sp) 2',5'-phosphorothioate linkages

Synthetic branched RNA fragments were prepared to examine the stereochemical requirements for hydrolysis of RNA lariats by the yeast debranching enzyme (yDBR). Specifically, two branched trinucleoside diphosphates and a tetranucleoside triphosphate containing a 2',5'-linked phosphorothioate linkage of defined stereochemistry, namely Rp-A(2'ps5'G)pC, Sp-A(2'ps5'G)pC and Sp-ApA(2'ps5'G)pC, were prepared via solution-phase methods. Unlike the all-phosphodiester control, A(2'p5'G)pC, the Rp-thioated trimer was not cleaved by yDBR, demonstrating that changing the pro-Rp oxygen at the 2',5' phosphodiester bond averts hydrolysis by the enzyme. In contrast, the Sp branched compounds (trimer and tetramer) were cleaved yDBR, albeit with reduced efficiency relative to the corresponding all-phosphodiester branched compounds. Furthermore, the small branched RNAs (5 nt) were not cleaved as efficiently as a 18-nt bRNA, suggesting that the enzyme appears to have a stronger preference for larger bRNA substrates. The non-hydrolyzable branched RNA fragments prepared during these studies may be promising candidates for the future co-crystallization and X-ray analyses of DBR:bRNA complexes.