A series of dideoxyribonucleoside methylphosphonate analogues, dNpN and dNpNp, which contain a nonionic 3'--5' methylphosphonyl internucleoside linkage were prepared. The two diastereoisomers, designated isomers 1 and 2, of each dimer differ in configuration of the methylphosphonate group and were separated by column chromatography. The diastereoisomers of each dimer have different conformations in solution as shown by ultraviolet hypochromicity data and their circular dichroism spectra. For example, dApA isomer 1 is more highly stacked than isomer 2, although both isomers are less stacked than the dinucleoside monophosphate, dApA. The circular dichroism spectrum of isomer 1 is very similar to that of dApA, while the CD spectrum of isomer 2 shows a loss of molecular ellipticity, [theta], at 270 nm and a greatly diminished [theta] at 250 nm. These results suggest that the stacked bases of dApA isomer 1 tend to orient in an oblique manner, while those in isomer 2 tend to orient in a parallel manner. This interpretation is verified by the 1H NMR study of these dimers (L. S. Kan, D. M. Cheng, P. S. Miller, J. Yano, and P. O. P. Ts'o, unpublished experiments). Both diastereoisomers of dAaA form 2U:1A and 2T:1A complexes with poly(U) and poly(dT), respectively. The higher Tm (Tm of poly(U)--isomer 1, 15.4 degrees C; Tm of poly(U)--isomer 2, 19.8 degrees C; Tm of poly(dT)--isomer 1, 18.7 degrees C; Tm of poly(dT)--isomer 2, 18.4 degrees C) values of these complexes vs. those of the corresponding dApA--polynucleotide complexes (Tm of poly(U)--dApA, 7.0 degrees C; Tm of poly(dT)--DApA, 9.2 degrees C) result from decreased charge repulsion between the nonionic dimer backbone and the negatively charged polymer backbone. The difference in conformations between dApA isomer 1 and dApA isomer 2 is reflected in the Tm of the isomer 1-poly(U) complex which is 4.4 degrees C lower than that of the isomer 2-poly(U) complex. Since these nonionic oligonucleotide analogues are taken up by cells in culture, they show promise as molecular probes for the function and structure of nucleic acids inside living cells.
Oligodeoxyribonucleoside methylphosphonates with base sequences complementary to the anticodon loop of tRNALys and to the -ACCA-OH amino acid accepting stem of tRNA were prepared by chemical synthesis. Oligodeoxyadenosine methylphosphonates form stable, triple-stranded complexes with both poly(U) and poly(dT). These analogues selectively inhibit cell-free aminoacylation of tRNALys (E. coli) but have no effect on aminoacylation of tRNALys (rabbit). The extent of inhibition is temperature dependent and parallels the ability of the oligomer to bind to poly(U), which suggests that inhibition occurs as a result of oligomer binding to the -UUUU- anticodon loop of tRNALys (E. coli). The failure of the oligodeoxyadenosine methylphosphonates to inhibit tRNALys (rabbit) amino-acylation suggests that there may be a difference between the structure of tRNALys or its interaction with aminoacyl synthetase in the Escherichia coli and rabbit systems. The oligodeoxyadenosine analogues also effectively inhibit polyphenylalanine synthesis in cell-free translation systems derived from both E. coli and rabbit reticulocytes. The extent of inhibition parallels the Tm values of the oligo(A) phosphonate-poly(U) complexes and suggests that the inhibition is a consequence of complex formation with the poly(U) message. Tritium-labeled oligodeoxyribonucleoside methylphosphonates with a chain length of up to nine nucleotidyl units are taken up intact by mammalian cells in culture. All the oligomer analogues tested inhibited, to various extents, colony formation by bacterial, hamster, and human tumor cells in culture.
Oligonucleotides provide novel reagents for inhibition of gene expression because of their high affinity binding to specific nucleotide sequences. We describe a 38 base, single-stranded DNA that forms a triple helix or 'triplex' on progesterone response elements of a target gene. This triplex-forming oligonucleotide binds with a Kd = 100 nM at 37 degrees C and physiological pH, and blocks binding of progesterone receptors to the target. Furthermore, it completely inhibited progesterone receptor-dependent transcription in vitro. To approach in vivo conditions, triplex-forming oligonucleotides were tested in cell transfection studies. The derivation of the oligonucleotides with cholesterol enhanced their cellular uptake and nuclear concentration by at least four-fold. The cholesterol-derivatized triplex-forming oligonucleotide specifically inhibited transcription of the PRE-containing reporter gene in cells when applied to the medium at micromolar concentrations. This is the first demonstration of steroid-responsive gene inhibition by triplex formation and joins the growing body of evidence indicating that oligonucleotides have therapeutic potential.
effectively inhibited MS-2 RNA-directed protein synthesis but they had much less effect on either poly(U) or poly(A)-directed polypeptide synthesis. In the reticulocyte system, these compounds had no significant effect on the translation of globin mRNA. The observation that d[(ApGpGp,) 3HjT)J binds to 70S ribosomes (association constant, 2.0 x 10 M-, 37C) together with the specificity of the inhibitory action of these compounds on protein synthesis strongly suggests that inhibition of translation is a consequence of analogue binding to Shine-Dalgarno sequence of 16S rRNA. The oligonucleoside methylphosphonates inhibited both protein synthesis (without concurrent inhibition of RNA synthesis) and colony formation by E coli ML 308-225 (a permeable mutant) whose cell wall contains negligible quantities of lipopolysaccharide but had no effect on wild-type E. coli B. Our preliminary results on the uptake of oligodeoxyribonucleoside methylphosphonates by E. coli B show that these cells are not permeable to oligomers longer than 4 nucleotidyl units. Although oligodeoxyribonucleoside methylphosphonates are taken up by mammalian cells in culture, this series of analogues had negligible inhibitory effects on colony formation by transformed human cells. This study indicates that this class of nonionic oligonucleotide analogues can be used to probe and regulate the finction and structure of nucleic acids of defined sequence within living cells.Single-stranded exposed regions of cellular nucleic acids are potential target regions for base-pairing interactions with complementary oligonucleotides. Binding of oligonucleotides to these regions can be used to probe and regulate the structure-function relationship of nucleic acids in both biochemical and cellular systems. Deoxyribooligonucleotides complementary to the reiterated 3'-and 5'-terminal nucleotides of Rous sarcoma virus 35S RNA inhibited the translation of the RNA in a cell-free system as well as the virus production of chicken fibroblast tissue cultures (1, 2). Studies in our laboratory have shown that an oligonucleotide ethylphosphotriester complementary to the amino acid-accepting stem of most tRNAs had a transient but specific inhibitory effect on the growth of mammalian cells in culture (3). More recently, we have studied the effects of oligo(dA) methylphosphonate analogues (complementary to the anticodon loop of tRNAIVs) on bacterial and mammalian cells in culture (4). These analogues contain an isosteric 3'-5' linked methylphosphonate group which replaces the normal phosphodiester linkage of nucleic acids.
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