Selective inhibition of Escherichia coli protein synthesis and growth by nonionic oligonucleotides complementary to the 3' end of 16S rRNA

alpha-DNA X: alpha and beta tetrathymidilates covalently linked to oxazolopyridocarbazolium (OPC): comparative stabilization of oligo beta-[dT]:oligo beta-[dA] and oligo alpha-[dT]:oligo beta-[dA] duplexes by the intercalating agent

The influence of the intercalating oxazolopyridocarbazolium (HOPC) on the stabilization of modified oligonucleotides: alpha-T4c5OPC or beta-T4c5OPC associated to beta-oligo (dA) was studied. It appears that the situation is different from what has been observed for the interaction of these modified oligonucleotides with poly (rA). The higher free energy of formation of the alpha-T4c5OPC :beta-oligo(dA), when compared to beta-T4c5OPC, is essentially due to the overall stability added to this system by the intercalator. This enhanced stability comes from a higher number of binding sites of HOPC for the alpha:beta duplex together with a lower van't Hoff energy of formation of the alpha:beta duplex.

Cholesteryl-conjugated oligonucleotides: synthesis, properties, and activity as inhibitors of replication of human immunodeficiency virus in cell culture

A family of oligonucleotides and phosphorothioate oligonucleotide analogues was synthesized with a cholesteryl group tethered at the 3'-terminal internucleoside link. This modification, introduced to enhance interaction of the polyanions with cell membranes, significantly increases the antiviral activity of the oligomers, as judged by inhibition of syncytia formation and expression of viral proteins p17, p24, and reverse transcriptase for human immunodeficiency virus 1 in Molt-3 cells. In the most favorable case, with a 20-mer cholesteryl-phosphorothioate derivative, complete inhibition by all assays was obtained with an oligomer concentration of 0.2 microM. Even decamers were active, and some antiviral activity was observed for a heptanucleotide cholesteryl-phosphorothioate derivative, which binds very poorly to complementary oligonucleotides. These facts, and the finding that the activity of the phosphorothioate decamers does not correlate with a specific sequence, suggests that a mechanism other than "antisense inhibition" may be operative in these systems.

In situ detection of a heat-shock regulatory element binding protein using a soluble synthetic enhancer sequence

In various studies, enhancer binding proteins have been successfully absorbed out by competing sequences inserted into plasmids, resulting in the inhibition of the plasmid expression. Theoretically, such a result could be achieved using synthetic enhancer sequences not inserted into plasmids. In this study, a double stranded DNA sequence corresponding to the human heat shock regulatory element was chemically synthesized. By in vitro retardation assays, the synthetic sequence was shown to bind specifically a protein in extracts from the human T cell line Jurkat. When the synthetic enhancer was electroporated into Jurkat cells, not only the enhancer was shown to remain undegraded into the cells for up to 2 days, but also it was shown to bind intracellularly a protein. The binding was specific and was modulated upon heat shock. Furthermore, the binding protein was shown to be of the expected molecular weight by UV crosslinking. However, when the synthetic enhancer element was co-electroporated with an HSP 70-CAT reporter construct, the expression of the reporter plasmid was consistently enhanced in the presence of the exogenous synthetic enhancer.

Specific inhibition of lymphokine biosynthesis and autocrine growth using antisense oligonucleotides in Th1 and Th2 helper T cell clones

T helper cells have recently been divided into two subsets. The Th1 subset secretes and responds to IL-2 in an autocrine manner. The Th2 subset upon mitogen or antigen stimulation releases IL-4. Here we describe a novel technology that allowed us to confirm this distinction. We have used synthetic oligonucleotides complementary to the 5' end of mouse IL-2 and IL-4 to specifically block the biosynthesis of IL-2 or IL-4 in two murine helper T cell clones from the Th1 or Th2 subset. We show that the antisense IL-2 oligonucleotide inhibited the proliferation of the Th1 clone and had no effect on the Th2 clone. In parallel experiments, the antisense IL-4 oligonucleotide blocked the proliferation of the Th2 clone and not the proliferation of the Th1 clone. The inhibition was significantly reversed in both cases by the addition of the relevant lymphokine (IL-2 in the case of the Th1 clone, IL-4 in the case of the Th2 clone). Northern analysis, using cDNA probes specific for the two lymphokines, showed a decrease in the steady-state level of the relevant lymphokine mRNA, suggesting the specific degradation of the mRNA by an RNase H-like enzymatic activity. This strategy, which allows the specific blockade of the biosynthesis of a lymphokine, could be useful for future studies on the role of each T helper subset in physiological immune responses.

Negative ion fast atom bombardment mass spectrometry of oligodeoxynucleotide carbamate analogs

Oligonucleotide analogs, in which carbamate rather than phosphodiester linkages form the backbone, have been analyzed by negative ion fast atom bombardment mass spectrometry. These oligodeoxynucleotides, dimers (982.4 daltons) to 11-mers (4356.5 daltons), show intense [M - H]- ions and some degree of cleavage of the sugar-carbamate backbone structure in repeating fashion on both sides of the carbonyl groups. Sequencing of the shorter chain oligonucleotide analogs, up to six bases long, is demonstrated by complete 3' and 5' terminal sequence fragment ions. Longer chain oligomers show partial sequencing information.

Comparative inhibition of chloramphenicol acetyltransferase gene expression by antisense oligonucleotide analogues having alkyl phosphotriester, methylphosphonate and phosphorothioate linkages

Several classes of oligonucleotide antisense compounds of sequence complementary to the start of the mRNA coding sequence for chloramphenicol acetyl transferase (CAT), including methylphosphonate, alkyltriester, and phosphorothioate analogues of DNA, have been compared to "normal" phosphodiester oligonucleotides for their ability to inhibit expression of plasmid-directed CAT gene activity in CV-1 cells. CAT gene expression was inhibited when transfection with plasmid DNA containing the gene for CAT coupled to simian virus 40 regulatory sequences (pSV2CAT) or the human immunodeficiency virus enhancer (pHIVCAT) was carried out in the presence of 30 microM concentrations of analogue. For the oligo-methylphosphonate analogue, inhibition was dependent on both oligomer concentration and chain length. Analogues with phosphodiester linkages that alternated with either methylphosphonate, ethyl phosphotriester, or isopropyl phosphotriester linkages were less effective inhibitors, in that order. The phosphorothioate analogue was about two-times more potent than the oligo-methylphosphonate, which was in turn approximately twice as potent as the normal oligonucleotide.

Oligodeoxyribonucleoside methylphosphonates. NMR and UV spectroscopic studies of Rp-Rp and Sp-Sp methylphosphonate (Me) modified duplexes of (d[GGAATTCC])2

1H NMR chemical shift assignments for the title compounds were made for most of the 1H signals using two-dimensional nuclear Overhauser effect (2D-NOE) data, which were also used to establish the absolute configuration at the modified phosphorus. The chemical shifts were similar to those reported [Broido, M.S., et al. (1985) Eur. J. Biochem. 150, 117-128] for the unmodified, parent, B-type duplex [d(GGAATTCC)]2. Differences in chemical shifts were mostly localized to the nucleotides on the 5'- and 3'-sides of the modified phosphorus. The Rp-Rp isomers exhibited UV-derived Tm values similar to that of the parent duplex. On the other hand, the Sp-Sp isomers generally exhibited lower Tm values which correlated with P-CH3--H3' (n-1 nucleotide) cross peak intensities and 31P spectral parameters. The combined data argue for increased steric interactions with the Sp-P-Me methyl group as the modification position is moved toward the center of the oligomer. All of the Tm results can be explained in terms of three factors which result from replacement of a phosphate by a methylphosphonate group: reduction of oligomer charge; electronic and other substituent effects; steric interactions.

Specific antiviral activity of a poly(L-lysine)-conjugated oligodeoxyribonucleotide sequence complementary to vesicular stomatitis virus N protein mRNA initiation site

Antisense oligonucleotides represent an interesting tool for selective inhibition of gene expression, but their efficient introduction within intact cells proved to be difficult to realize. As a step toward this goal, small (13- or 15-mer) synthetic oligodeoxyribonucleotides have been coupled at their 3' ends to epsilon-amino groups of lysine residues of poly(L-lysine) (Mr, 14,000). A 15-mer oligonucleotide-poly(L-lysine) conjugate complementary to the initiation region of vesicular stomatitis virus (VSV) N-protein mRNA specifically inhibits the synthesis of VSV proteins and exerts an antiviral activity against VSV when added in the cell culture medium at doses as low as 100 nM. Neither synthesis of cellular proteins nor multiplication of encephalomyocarditis virus was affected significantly by this oligonucleotide conjugate. The data suggest that oligonucleotide-poly(L-lysine) conjugates might become effective for studies on gene expression regulation and for antiviral chemotherapy.

Solid-phase syntheses of oligodeoxyribonucleoside methylphosphonates

Oligodeoxyribonucleoside methylphosphonates of defined sequence of the type d-Np(NP)nN, where n is 6-13, are readily prepared on insoluble polystyrene supports by use of protected 5'-(dimethoxytrityl)deoxyribonucleoside 3'-(methylphosphonic imidazolides) as synthetic intermediates. The imidazolides are prepared in situ by reaction of protected 5'-(dimethoxytrityl)deoxyribonucleoside with methylphosphonic bis(imidazolide) and can be stores in the reaction solution for up to 2 weeks at 4 degrees C with no loss in activity. The condensation reaction is accelerated by the presence of tetrazole, which appears to act as an acid catalyst. The half-life for dimer formation on the polystyrene support is 5 min, and the reaction is 95% complete after 60 min. Although similar kinetics are observed when controlled pore glass is used as the support, the extent of the reaction does not go beyond 78%, even after prolonged incubation. In order to simplify purification and sequence analysis of the oligomer, the 5'-terminal nucleoside unit is linked via a phosphodiester bond. This linkage may be introduced by either an o-chlorophenyl phosphotriester method or a cyanoethyl phosphoramidite method. The latter procedure simplifies the deprotection step, since the cyanoethyl group is readily cleaved by ethylenediamine, which also removes the base protecting groups and cleaves the oligomer from the support. The singly charged oligomers are easily purified by affinity chromatography on DEAE-cellulose. The chain lengths of the oligomers were confirmed after 5'-end labeling with polynucleotide kinase by partial hydrolysis of the methylphosphonate linkages with 1 M aqueous piperidine followed by polyacrylamide gel electrophoresis of the hydrolysate.(ABSTRACT TRUNCATED AT 250 WORDS)

Antiviral effect of an oligo(nucleoside methylphosphonate) complementary to the splice junction of herpes simplex virus type 1 immediate early pre-mRNAs 4 and 5

Selective inhibition of regulatory immediate early (IE) genes of herpes simplex virus type 1 (HSV-1) should inhibit virus growth. Treatment of HSV-1-infected cells with the oligo(nucleoside methylphosphonate) d(TpCCTCCTG) (deoxynucleoside methylphosphonate residues in italic), which is complementary to the acceptor splice junction of HSV-1 IE pre-mRNA 4 and 5, before (1-24 hr) or at the time of infection caused a dose-dependent inhibition in virus replication. Virus titers were decreased 50% and 90% in cells treated with 25 microM and 75 microM oligomer, respectively; at 300 microM, a 99% reduction in virus production was observed. Viral DNA synthesis was reduced 70-75% and there was a 90% reduction in synthesis of viral proteins, including other IE species and viral functional (130-kDa major DNA-binding) and structural (glycoprotein gB) proteins. In the same concentration range, d(TpCCTCCTG) caused a minimal reduction (0-30%) in protein synthesis and growth rates (less than 40%) of uninfected cells. The data suggest that oligo(nucleoside methylphosphonate)s may be effective in antiviral chemotherapy.

Specific inhibition of mRNA translation by complementary oligonucleotides covalently linked to intercalating agents

Synthetic oligodeoxynucleotides that are covalently linked at their 3' end to an acridine derivative and are complementary to the repeated sequence UUAAAUUAAAUUAAA adjacent to the ribosome binding site of the gene 32-encoded mRNA from phage T4 have been used to regulate the synthesis of gene 32-encoded protein in vitro. These modified, synthetic oligonucleotides specifically block the translation of gene 32-encoded mRNA with a higher efficiency than the homologous unsubstituted oligonucleotides. The inhibition produced by these short "anti-messengers" is due to the formation of specific mRNA . oligodeoxynucleotide hybrids that are stabilized by the intercalation of the acridine ring in the RNA . DNA duplex.

Hybridization arrest of globin synthesis in rabbit reticulocyte lysates and cells by oligodeoxyribonucleoside methylphosphonates

Oligodeoxyribonucleoside methylphosphonates which are complementary to the 5' end, the initiation codon regions, or the coding regions of rabbit globin mRNA were synthesized. These oligomers were shown to interact with their complementary mRNA binding sites by their ability to serve as primers for reverse transcriptase. In several cases, the priming efficiency of the oligomers was enhanced when the oligomer was preannealed with the mRNA. This behavior correlates with the predicted secondary structure of the mRNA and suggests that some oligomer binding sites occur in hydrogen-bonded stem regions of the mRNA. Methylphosphonate oligomers inhibit translation of globin mRNA in reticulocyte lysates. Inhibition is due to the interaction of the oligomers with mRNA. The extent of inhibition is affected by the sequence and chain length of the oligomer, the location of the oligomer binding site on the mRNA, and the secondary structure of the binding site. Oligomers which bind to the 5' end and initiation codon regions of beta-globin mRNA inhibit both alpha- and beta-globin synthesis whereas oligomers which bind to the coding region of alpha-globin mRNA or the coding region of beta-globin mRNA inhibit translation of their target mRNA in a specific manner. Oligodeoxyribonucleoside methylphosphonates inhibit globin synthesis in rabbit reticulocytes. The effects of various oligomers on cellular globin synthesis are similar to those in the lysate system and suggest that the conformation of globin mRNA is the same in both systems during translation.

Quantitative hybridization-arrest of mRNA in Xenopus oocytes using single-stranded complementary DNA or oligonucleotide probes

The expression of heterologous mRNA in Xenopus oocytes was quantitatively inhibited by coinjection of single-stranded complementary DNA or synthetic complementary oligonucleotides. The lymphokines Interleukin-2 (IL-2) and Interleukin-3 (IL-3) were used as model systems to test the effectiveness of this procedure. Messenger RNA samples were hybridized to single stranded complementary DNA or oligonucleotides, injected into oocytes and the oocyte incubation medium assayed for the presence or absence of specific translation products 48 hours later. When IL-2 mRNA was hybridized to a large excess of long (490 bases) single stranded complementary DNA, the expression of IL-2 was effectively blocked (greater than 98%). Complementary oligonucleotides (18-23 bases) were almost as effective as the polynucleotide in inhibiting IL-2 activity (greater than 95%). Oligonucleotides derived from the 5' end, middle or 3' end of the coding sequence were all effective in arresting IL-2 mRNA translation. Oligonucleotide hybrid-arrest was effective even when no NaCl was present in the hybridization buffer, indicating that the annealing reaction could occur within the oocyte after injection. Definite proof that hybrid-arrest could occur in vivo was shown by the fact that oligonucleotides injected before or after mRNA injection, while not as effective as co-injection, still showed substantial inhibition of specific mRNA translation. The oligonucleotide hybrid-arrest method was equally effective in the case of IL-3, demonstrating its general applicability.

Injected anti-sense RNAs specifically block messenger RNA translation in vivo

As a test for a method to analyze gene function in embryogenesis, the translation of a specific mRNA has been blocked in vivo by microinjection of complementary (anti-sense) RNA. RNA complementary to globin mRNA was synthesized in vitro by transcription of an inverted globin cDNA clone. After injection into frog oocyte cytoplasm, the anti-sense globin RNA forms a hybrid with globin mRNA and selectively prevents its translation. Deletion mapping of the anti-sense RNA shows that the 5' region of the globin mRNA must be covered in order to block translation. This method may allow one to study the function of many genes for which DNA clones are available by preventing the expression of the endogenous gene as protein.

Preparation of oligodeoxyribonucleoside methylphosphonates on a polystyrene support

An efficient procedure is described for synthesizing deoxyribonucleoside methylphosphonates on polystyrene polymer supports which involves condensing 5'-dimethoxytrityldeoxynucleoside 3'-methylphosphonates. The oligomers are removed from the support and the base protecting groups hydrolyzed by treatment with ethylenediamine in ethanol, which avoids hydrolysis of the methylphosphonate linkages. Two types of oligomers were synthesized: those containing only methylphosphonate linkages, d-Np(Np)nN, and those which terminate with a 5' nucleotide residue, dNp (Np)nN. The latter oligomers can be phosphorylated by polynucleotide kinase, and are separated by polyacrylamide gel electrophoresis according to their chain length. Piperdine randomly cleaves the oligomer methylphosphonate linkages and generates a series of shorter oligomers whose number corresponds to the length of the original oligomer. Apurinic sites introduced by acid treatment spontaneously hydrolyze to give oligomers which terminate with free 3' and 5' OH groups. These reactions may be used to characterize the oligomers.

Use of methylphosphonic dichloride for the synthesis of oligonucleoside methylphosphonates

Methylphosphonic dichloride was used to prepare protected deoxyribonucleoside 3'-methylphosphonate beta-cyanoethyl esters, d-[(MeO)2Tr]NpCNEt, and protected oligonucleoside methylphosphonates in solution. Reaction of d-[(MeO)2Tr]N with methylphosphonic dichloride gives d-[(MeO)2Tr]NpCl. The phosphonylation and subsequent esterification or condensation reactions are each complete within 60 min. The products are readily purified by "flash chromatography" on silica gel columns. d-[(MeO)2Tr]NpCl, or its tetrazole derivative, d-[(MeO)2Tr]Nptet, were tested as intermediates for the synthesis of oligothymidine methylphosphonates on a silica gel polymer support. The average yield per coupling step was 76% and did not increase with addition of more d-[(MeO)2Tr]TpCl. The formation of (5'-5') linked thymidine dimers indicated that the thymidine monomers are clustered closely together on the support. When N is ibuG, the yield for the coupling step on the support is very low. This may be due to steric hindrance of the 3'-phosphonate group by the N-2 isobutryl protecting group.