Autolytic processing of a phosphorothioate diester bond.

A small satellite RNA of tobacco ringspot virus replicates in tissues infected with tobacco ringspot virus and accumulates in virus capsids, forming virus-like particles. Previous research showed that multimeric forms of this satellite RNA have tandem repeats of the "monomeric" satellite RNA sequence of 359 or 360 nucleotide residues. The multimeric RNAs undergo autolytic processing at a specific CpA phosphodiester bond, the junction, to generate the monomeric RNA. We substituted phosphorothioate diester bonds for various sets of phosphodiester bonds, in dimeric and truncated forms of the satellite RNA. The degree of reduction in autolytic cleavage varied both with the sites of substitution and the size of the RNA molecules. Analyses of a product of the autolysis reaction suggest that one phosphorothioate diester bond most strongly interferes with processing, the one introduced at the CpA junction during its synthesis from adenosine-5'-0-(1-thiotriphosphate). However, extensive introduction of phosphorothioate diester bonds elsewhere in the molecule also decreased processing, possibly by altering conformation.     

Kinetic parameters of hydrolysis of CpA and UpA sequences in an oligoribonucleotide by compounds functionally mimicking ribonuclease A

Kinetic parameters of cleavage of CpA and UpA sequences in an oligoribonucleotide under the action of artificial ribonuclease ABL3C1 were measured. The compounds were built of RNA-binding domain B, catalytic fragment C, linker L3 comprising 3 methylene groups, and aliphatic fragment A. The rate of cleavage of phosphodiester bonds in CpA sequence within decaribonucleotide UUCAUGUAAA was shown to be 3.4 +/- 0.2 times higher than in UpA sequence. The rate of cleavage of phosphodiester bonds were found to depend on substrate length: a thousandfold increase in cleavage rate constant was observed for CpA sequence in decaribonucleotide as compared with diribonucleotide monophosphate CpA. A slight decrease in the cleavage rates was observed for the reactions proceeding in different buffers at pH 7.0: imidazole > HEPES > phosphate > cacodylate. At the same time, the ratio of cleavage rates for CpA and UpA sequences remained constant.     

Two autolytic processing reactions of a satellite RNA proceed with inversion of configuration.

Both polarities of the satellite RNA of tobacco ringspot virus occur in infected cells in multimeric forms which are capable of autolytic processing, using different sequences and structures [Feldstein, P.A., et al., Proc. Nat. Acad. Sci. USA (1990) 87 (in press)]. These transesterification reactions generate a 2',3'-cyclophosphate and a 5'-hydroxyl as the two new end groups. Cleavage is at a CpA for the (+) polarity RNA and at an ApG for the (-) polarity RNA. We enzymically synthesized oligoribonucleotides with processing capability and with specific 35S-labeled phosphorothioate diesters in the Rp configuration. After processing had occurred, the terminal nucleoside-2',3'-cyclophosphorothioate diester residues were recovered from the appropriate product by digestion with nuclease and phosphatase. Comparisons with specially prepared endo- and exoisomer reference compounds by thin layer chromatography and autoradiography revealed that the [35S]cytidine- and [35S]adenosine-2',3'-cyclophosphorothioate both were endo-isomers. The results are consistent with transesterification occurring by an inline SN2(P) attack of the 2'-hydroxyl group in the autolytic processing reactions of both polarities of the satellite RNA.     

Self-cleavage of p2Sp1 RNA with Mg2+ and non-ionic detergent (Brij 58)

The precursor of an RNA molecule from T4-infected E. coli cells (p2Sp1 RNA) has the capacity to cleave itself at specific positions [(UpA (139-140) and CpA (170-171)], within a putative loop and stem structure. This sequence-specific cleavage requires at least a monovalent cation and non-ionic detergents. We studied the self-cleavage reaction of an RNA fragment (GUUUCGUACAAAC) (R1) with the sequence corresponding to the p2Sp1 RNA in the presence of Mg2+ and non-ionic detergents. It requires Mg2+ and is aided by a non-ionic detergent, Brij 58. The cleavage reaction is time, temperature, and pH-dependent. The cleavage occurs at the phosphodiester bond between UpA and CpA on the RNA fragment (GUUUCGUACAAAC) (R1). Furthermore, the maximum of cleavage of R1 occurs at a very low Mg2+ concentration (< or = 5 mM).     

A catalytic 13-mer ribozyme.

A 13-mer oligoribonucleotide can act as a ribozyme for the specific self-cleavage of a 41-mer oligoribonucleotide substrate in the presence of Mg2+. The two sequences involved correspond to the self-cleavage hammerhead structure of the virusoid of lucerne transient streak virus. The Michaelis-menten kinetic parameters for the reaction were; Km 1.3 microM, Vmax 0.012 microM min-1, kcat 0.5 min-1. The 13-mer RNA is the smallest ribozyme so far reported. A DNA analogue of the 13-mer can not substitute for the RNA in the reaction.     

Anti-HIV-1 activity of an antisense phosphorothioate oligonucleotide bearing imidazole and primary amine groups

We have previously shown that RNA cleaving reagents with imidazole and primary amine groups on the 5'-end of antisense oligodeoxyribonucleotides could site-specifically cleave CpA as the target sequence of the substrate tRNA in vitro. In this study, a RNA cleaving reagent, composed of imidazole and primary amine groups on an antisense phosphorothioate oligonucleotide (Im-anti-s-ODN), was synthesized and evaluated for anti-HIV-1 activity in MT-4 cells. The sequence of the Im-anti-s-ODN was designed to be complementary to the HIV-1 gag-mRNA and to bind adjacent to the CpA cleavage site position. Im-anti-s-ODN encapsulated with the transfection reagent, DMRIE-C, had higher anti-HIV-1 activity than the unmodified antisense phosphorothioate oligonucleotide (anti-s-ODN) at a 2 microM concentration. Furthermore, the Im-anti-ODN encapsulated with DMRIE-C conferred sequence-specific inhibition.     

Kinetic Parameters of Cleavage of CpA and UpA Sequences in an Oligoribonucleotide by Compounds Functionally Mimicking Ribonuclease A

Kinetic parameters of cleavage of CpA and UpA sites in an oligoribonucleotide under the action of artificial ribonuclease ABL3C1 were measured. The compounds were built of RNA-binding domain B, catalytic fragment C, linker L3 comprising 3 methylene groups, and aliphatic fragment A. The rate of cleavage of phosphodiester bonds in the CpA site within decaribonucleotide UUCAUGUAAA was shown to be 3.4 ± 0.2 times higher than in UpA. The rate of cleavage of phosphodiester bonds was found to depend on substrate length: a thousandfold increase in cleavage rate constant was observed for the CpA site in decaribonucleotide as compared with diribonucleoside monophosphate CpA. A slight decrease in the cleavage rates was observed for the reactions proceeding in different buffers at pH 7.0: imidazole > HEPES > phosphate > cacodylate. At the same time, the ratio of cleavage rates for CpA and UpA sites remained constant.     

Arabinosylnucleoside 5'-triphosphate inhibits DNA primase of calf thymus

It has been shown that DNA primase activity is tightly associated with 10S DNA polymerase alpha from calf thymus and that the ribonucleotide-dependent DNA synthesis is more sensitive to araCTP than DNA-primed DNA synthesis (Yoshida, S., et al. (1983) Biochim. Biophys. Acta 741, 348-357). Here we measured DNA primase activity using poly(dT) template or M13 bacteriophage single-stranded DNA template and primer RNA synthesis was coupled to the reaction by Escherichia coli DNA polymerase I Klenow fragment. By this method, the primer RNA synthesis can be measured independently of the associating DNA polymerase alpha. Using poly(dT) template, it was found that arabinosyladenine 5'-triphosphate (araATP) strongly inhibited DNA primase in competition with rATP. The apparent Ki for araATP was 21 microM and the ratio of Ki/Km (for rATP) was as low as 0.015. With poly(dI, dT) or M13 DNA, it was shown that araCTP also inhibited DNA primase in the similar manner. Product analysis using [alpha-32P]rATP showed that araATP inhibited the elongation of primer RNA. However, it is not likely that arabinosylnucleotides act as chain-terminators, since incubation of primer RNA with araATP did not abolish its priming activity. From these results, it is suggested that arabinosylnucleotide inhibits the initiation as well as elongation of Okazaki fragments in mammalian cells.     

RNA mediated formation of a phosphorothioate diester bond

Previous results showed that multimeric, tandemly sequence-repeated forms of satellite tobacco ringspot virus RNA of the encapsidated polarity (STobRV (+)RNA) autolytically process at a specific phosphodiester bond, the junction. Substituting a phosphorothioate diester bond for the STobRV (+)RNA junction drastically slowed autolytic processing. Here we show that for the complementary STobRV (-)RNA, in contrast, replacing sets of phosphodiester bonds with phosphorothioate diester bonds, even at the junction, did not greatly slow autolytic processing or spontaneous ligation, the usual reactions of the unmodified RNA. In the ligation reaction STobRV (-)RNA directed the formation of an ApG phosphorothioate diester bond.     

5'-C-methylnucleoside triphosphates in the reaction of RNA synthesis catalyzed by Escherichia coli RNA-polymerase

It was shown that RNA-polymerase is able to discriminate diastereoisomers of 5'-methyl-substituted analogs of ribonucleoside triphosphates (rNTP). Under conditions of soil substrate reactions when the analog is added to the presynthesized ternary complexes, D-allo- and L-talo-stereoisomers incorporate into RNA 100 and 1000 times, respectively, less effectively, then the natural rNTP. The effectivities of incorporation of other 2'- and 3'-substituted analogs of rNTP were measured under the same conditions and compared with that for 5'-Me-rNTP. It was shown also that RNA-polymerase does not support long-chain RNA synthesis from 5'-Me-rNTP in the absence of natural rNTP. No more then two analog residues can be attached to the 3'-end of the presynthesized RNA under such conditions. Addition of one natural rNTP to this reaction mixture results in the synthesis of long alternating RNA containing D-allo-stereoisomer and natural rNTP residues. In the case of L-talo-stereoisomer RNA elongation is not inhibited, if the distance between the analog residues in the RNA chain is not shorter then five nucleotide residues. The rate of pyrophosphorolysis from the RNA of the analogs studied was the same as for the natural rNTP residues.     

Alternative tertiary structure attenuates self-cleavage of the ribozyme in the satellite RNA of barley yellow dwarf virus.

A self-cleaving satellite RNA associated with barley yellow dwarf virus (sBYDV) contains a sequence predicted to form a secondary structure similar to catalytic RNA molecules (ribozymes) of the 'hammerhead' class (Miller et al., 1991, Virology 183, 711-720). However, this RNA differs from other naturally occurring hammerheads both in its very slow cleavage rate, and in some aspects of its structure. One striking structural difference is that an additional helix is predicted that may be part of an unusual pseudoknot containing three stacked helices. Nucleotide substitutions that prevent formation of the additional helix and favor the hammerhead increased the self-cleavage rate up to 400-fold. Compensatory substitutions, predicted to restore the additional helix, reduced the self-cleavage rate by an extent proportional to the calculated stability of the helix. Partial digestion of the RNA with structure-sensitive nucleases supported the existence of the proposed alternative structure in the wildtype sequence, and formation of the hammerhead in the rapidly-cleaving mutants. This tertiary interaction may serve as a molecular switch that controls the rate of self-cleavage and possibly other functions of the satellite RNA.     

The self-cleaving domain from the genomic RNA of hepatitis delta virus: sequence requirements and the effects of denaturant.

The sequence requirements for self-cleavage of hepatitis delta virus genomic RNA were examined using precursor RNAs which were labeled at either the 5' or 3' ends and progressively deleted from the unlabeled end. In the presence of 50% formamide, which enhances self-cleavage in 2 mM MgCl2 at 37 degrees C, 84 nucleotides (nt) 3' of the break site were required. In the absence of formamide the minimum was reduced to 82 nt. Under both sets of conditions, precursors with 1 nt 5' to the break site cleaved. These results allowed two condition-dependent minimal domains for self-cleavage to be defined. However, in the absence of formamide, sequences flanking the minimal domain inhibited cleavage, possibly through involvement in the formation of non-cleaving structures. These data are consistent with the idea that cleavage in vivo could be regulated by alternative RNA structures.     

Mutagenesis analysis of the self-cleavage domain of hepatitis delta virus antigenomic RNA.

To determine the sequence requirements and structural features of the self-cleavage domain of hepatitis delta virus (HDV) antigenomic RNA, we constructed a series of mutants and measured the rate constant of the cleavage reaction for each. The self-cleavage activity of HDV RNA of antigenomic sense was found to reside in a region of less than 90 nucleotides in length. The catalytic domain contained a long complementary sequence which could be deleted to half of its original size. Moreover, this region could be replaced by other sequences as long as they could fold into a stem-and-loop structure. The catalytic domain also required a 6-basepair helix adjacent to the cleaving point for activity. The structural features of these two base-pairing regions are quite similar to those of the HDV genomic self-cleavage domain. The cleavage site as well as the the hinge region (the sequence between the two stems) requires specific sequences for activity.     

The stem hairpin loop structure of p2Sp1 RNA is required for RNA-cleaving activity

We studied the hairpin-loop structure of an RNA fragment (GUUUCGUACAAAC) (R13) with the sequence corresponding to the self-cleavage domain in the precursor of an RNA molecule from bacteriophage T4-infected Escherichia coli cells (p2Sp1 RNA). In order to determine the influence of the hairpin-loop structure on these sequence-specific cleavage reactions, we have synthesized oligoribonucleotides containing hairpin-loop, double-helical stem-loop, and single-stranded RNA structures. The cleavage was affected by the hairpin-loop structure. Furthermore, the helix-stem, which retains the thermodynamically extrastable stem hairpin-loop structures, is also important for the cleavage activity. However, the thermodynamically extrastable helix-stem structure reduced the cleavage activity of the adjacent UA and CA sequences at the helix-stem site. For the cleavage reactions of the RNA cleavage products, the R6 (ACAAAC), R7 (GUUUCGU), and R9 (GUUUCGUAC) mers from the parent RNA, R13 (GUUUCGUACAAAC), a very slight amount of cleavage product (2%) from the RNA 9 was observed, but no reaction occurred for the R6 and R7. We also describe the influences of the sequences (UA and CA) on the cleavage activity.     

The loss of dinucleotides CpG from DNA. IV. Methylation and divergence of genes and pseudogenes of small nuclear RNA

The frequency of neighboring base pairs in nucleotide sequences of over 80 genes and pseudogenes of low molecular weight RNAs U1-U8, 4.5S and 7S in different eukaryotes was determined. The probable frequency of CpG----TpG + CpA substitutions, caused as a result of the deamination of 5-methylcytosine residues in DNA, was determined. It was found that the genes of small RNAs do not reveal a single level of CpG methylation for all the species studied. In most cases CpG in the genes of U1, 4.5S and 7S RNA are methylated, whereas in the genes of U2-U6-RNA these sites must have never been subjected to methylation. Nearly all the investigated pseudogenes of different small RNAs are strongly methylated due to a considerable lack of CpG. It was established that CpG----TpG + CpA transitions may amount to as much third of all the mutations accumulated in the genes of the same RNAs in different species. Such transitions in pseudogenes may account for 40% of all the nucleotide substitutions. This disproportionately high level of mutations in CpG dinucleotides (3-5-fold higher than in other DNA dupletes) must be the direct result of the methylation of these sites. Consequently, CpG methylation causes a dramatic acceleration of the divergence rate of DNA sequences. It has been concluded that protection of most vital genes against methylation is one of the essential conditions for sustaining the high level of stability of the macromolecular structure and for the reliability of macromolecular functioning in a cell.