Complementary addressed alkylation of Escherichia coli 16S rRNA with 2',3'-O-[4-N-methyl-N-(2-chloroethyl)aminobenzylidene]m derivatives of oligodeoxyribonucleotides. IV. Determination of binding sites of 16S rRNA with benzylidene derivatives of d(pACCTTGTT)rA, d(pTTACGACT)rU, d(TTTGCTCCCC)rA

By site-directed alkylation of 16S rRNA with benzylidene derivatives of d(pACCTTGTT)rA (II), d(pTTACGACT)rU (III), d(pTTTGCTCCCC)rA (IV) (reagents (II)--(IV] followed by the RNase H treatment a number of 16S rRNA fragments have been obtained. Hybridisation of these fragments with restriction fragments of plasmid pKK 3535, containing operon rrnB of E. coli rRNAs, led to the identification of all reagents' binding sites in 16S rRNA. Good correlation is found between estimated stability of non-perfect 16S rRNA.oligodeoxyribonucleotide duplexes and the level of modification of this site with alkylating derivative of the same oligodeoxyribonucleotide. With high concentration of the reagents (II)--(IV) ((2-5) x 10(-5) M) the site-directed alkylation proceeds not only at the desired site but also at other sites corresponding to non-perfect duplexes between 16S rRNA and the reagents. It should be noted that the modification mainly occurs in the non-perfect duplexes, carrying mismatched bases at the termini. Influence of the secondary structure of 16S rRNA on the site-directed modification is discussed.     

The use of RNAse H for digestion of alkylated 16S rRNA at the binding sites of addressed reagents--oligodeoxyribonucleotide derivatives

It is demonstrated that 16S rRNA, complementary-addressed labelled with 2',3'-O-[4-N-methyl-N-(2-chloroethyl)-amino]benzylidene derivatives of oligonucleotides d(pACCTTGTT)rA and d(pTTTGCTCCCC)rA, can be cleaved by RNase H within the adducts, resulted from the modification. Comparative study of the 16S rRNA cleavage with RNase H within the above--mentioned covalent adducts, on the one hand, and within heteroduplexes with the same oligodeoxyribonucleotides, on the other, showed that(i) the complementary-addressed modification proceeds both in perfect and non-per ect complexes; (ii) 16S rRNA is cleaved by RNase H within both perfect and non-perfect complexes resulted from the alkylation, non-perfect complexes being considerably stabilized by the covalent bond between the reagent and the RNA; (iii) non-perfect complexes of 16S rRNA with the free oligodeoxyribonucleotides are unstable even at the high oligonucleotide concentration, so that no cleavage of 16S rRNA in such duplexes is observed. The approach based on cleavage of RNA within covalent adducts resulted from the complementary-addressed RNA modification may be used for fragmentation of RNA molecule in the addressed reagent's binding site.     

rRNA cleavage as an index of ppp(A2''p)nA activity in interferon-treated encephalomyocarditis virus-infected cells.

In cell-free systems, 2-5A [ppp(A2'p)nA, n = 2 to greater than or equal to 4] activates a latent endoribonuclease, the 2-5A-dependent RNase, which cleaves rRNA in intact ribosomes into discrete and characteristic products (D. H. Wreschner et al., Nucleic Acids Res. 9:1571-1581, 1981). Here we present Northern blots which have identified the 18S or 28S origins of the cleaved products from rRNA. In addition, identical 3' termini were observed for fragments of 18S rRNA from a HeLa cell-free system incubated with 2-5A and from interferon-treated, encephalomyocarditis virus-infected HeLa cells. The previous assumption of identity of such fragments was based only on comigration on electrophoresis in agarose gels. We conclude that appropriate patterns of cleavage found in RNA isolated from intact cells are an indicator of prior 2-5A-dependent RNase activity. The assay of rRNA cleavage is relatively convenient and unambiguous. Accordingly, in the search for situations in which the 2-5A system may be active, it provides a useful alternative to the direct assay of 2-5A.     

Sequence-specific cleavage of small-subunit (SSU) rRNA with oligonucleotides and RNase H: a rapid and simple approach to SSU rRNA-based quantitative detection of microorganisms

A rapid and simple approach to the small-subunit (SSU) rRNA-based quantitative detection of a specific group of microorganisms in complex ecosystems has been developed. The method employs sequence-specific cleavage of rRNA molecules with oligonucleotides and RNase H. Defined mixtures of SSU rRNAs were mixed with an oligonucleotide (referred to as a "scissor probe") that was specifically designed to hybridize with a particular site of targeted rRNA and were subsequently digested with RNase H to proceed to sequence-dependent rRNA scission at the hybridization site. Under appropriate reaction conditions, the targeted rRNAs were correctly cut into two fragments, whereas nontargeted rRNAs remained intact under the same conditions. The specificity of the cleavage could be properly adjusted by controlling the hybridization stringency between the rRNA and the oligonucleotides, i.e., by controlling either the temperature of the reaction or the formamide concentration in the hybridization-digestion buffer used for the reaction. This enabled the reliable discrimination of completely matched rRNA sequences from single-base mismatched sequences. For the detection of targeted rRNAs, the resulting RNA fragment patterns were analyzed by gel electrophoresis with nucleotide-staining fluorescent dyes in order to separate cleaved and intact rRNA molecules. The relative abundance of the targeted SSU rRNA fragments in the total SSU rRNA could easily be calculated without the use of an external standard by determining the signal intensity of individual SSU rRNA bands in the electropherogram. This approach provides a fast and easy means of identification, detection, and quantification of a particular group of microbes in clinical and environmental specimens based on rRNA.     

Sequence-Specific Cleavage of Small-Subunit (SSU) rRNA with Oligonucleotides and RNase H: a Rapid and Simple Approach to SSU rRNA-Based Quantitative Detection of Microorganisms

A rapid and simple approach to the small-subunit (SSU) rRNA-based quantitative detection of a specific group of microorganisms in complex ecosystems has been developed. The method employs sequence-specific cleavage of rRNA molecules with oligonucleotides and RNase H. Defined mixtures of SSU rRNAs were mixed with an oligonucleotide (referred to as a “scissor probe”) that was specifically designed to hybridize with a particular site of targeted rRNA and were subsequently digested with RNase H to proceed to sequence-dependent rRNA scission at the hybridization site. Under appropriate reaction conditions, the targeted rRNAs were correctly cut into two fragments, whereas nontargeted rRNAs remained intact under the same conditions. The specificity of the cleavage could be properly adjusted by controlling the hybridization stringency between the rRNA and the oligonucleotides, i.e., by controlling either the temperature of the reaction or the formamide concentration in the hybridization-digestion buffer used for the reaction. This enabled the reliable discrimination of completely matched rRNA sequences from single-base mismatched sequences. For the detection of targeted rRNAs, the resulting RNA fragment patterns were analyzed by gel electrophoresis with nucleotide-staining fluorescent dyes in order to separate cleaved and intact rRNA molecules. The relative abundance of the targeted SSU rRNA fragments in the total SSU rRNA could easily be calculated without the use of an external standard by determining the signal intensity of individual SSU rRNA bands in the electropherogram. This approach provides a fast and easy means of identification, detection, and quantification of a particular group of microbes in clinical and environmental specimens based on rRNA.     

RNA-RNA and RNA-protein interactions in 30 S ribosomal subunits. Association of 16 S rRNA fragments in the presence of ribosomal proteins.

The E. coli 16 S rRNA with single-site breaks centered at position 777 or 785 was obtained by RNase H site-specific cleavage of rRNA. Spontaneous dissociation of the cleaved 16 S rRNA into fragments occurred under 'native' conditions. The reassociation of the 16 S rRNA fragments was possible only in the presence of ribosomal proteins. The combination of S4 and S16(S17) ribosomal proteins interacting mainly with the 5'-end domain of 16 S rRNA was sufficient for reassociation of the fragments. The 30 S subunits with fragmented RNA at ca. 777 region retained some poly(U)-directed protein synthetic activity.     

Nuclear RNase MRP is required for correct processing of pre-5.8S rRNA in Saccharomyces cerevisiae.

RNase MRP is a site-specific ribonucleoprotein endoribonuclease that cleaves RNA from the mitochondrial origin of replication in a manner consistent with a role in priming leading-strand DNA synthesis. Despite the fact that the only known RNA substrate for this enzyme is complementary to mitochondrial DNA, the majority of the RNase MRP activity in a cell is found in the nucleus. The recent characterization of this activity in Saccharomyces cerevisiae and subsequent cloning of the gene coding for the RNA subunit of the yeast enzyme have enabled a genetic approach to the identification of a nuclear role for this ribonuclease. Since the gene for the RNA component of RNase MRP, NME1, is essential in yeast cells and RNase MRP in mammalian cells appears to be localized to nucleoli within the nucleus, we utilized both regulated expression and temperature-conditional mutations of NME1 to assay for a possible effect on rRNA processing. Depletion of the RNA component of the enzyme was accomplished by using the glucose-repressed GAL1 promoter. Shortly after the shift to glucose, the RNA component of the enzyme was found to be depleted severely, and rRNA processing was found to be normal at all sites except the B1 processing site. The B1 site, at the 5' end of the mature 5.8S rRNA, is actually composed of two cleavage sites 7 nucleotides apart. This cleavage normally generates two species of 5.8S rRNA at a ratio of 10:1 (small to large) in most eukaryotes. After RNase MRP depletion, yeast cells were found to have almost exclusively the larger species of 5.8S rRNA. In addition, an aberrant 309-nucleotide precursor that stretched from the A2 to E processing sites of rRNA accumulated in these cells. Temperature-conditional mutations in the RNase MRP RNA gene gave an identical phenotype.Translation in yeast cells depleted of the smaller 5.8S rRNA was found to remain robust, suggesting a possible function for two 5.8S rRNAs in the regulated translation of select messages. These results are consistent with RNase MRP playing a role in a late step of rRNA processing. The data also indicate a requirement for having the smaller form of 5.8S rRNA, and they argue for processing at the B1 position being composed of two separate cleavage events catalyzed by two different activities.     

Processing pathway of Escherichia coli 16S precursor rRNA.

Immediate precursors of 16S rRNA are processed by endonucleolytic cleavage at both 5' and 3' mature termini, with the concomitant release of precursor fragments which are further metabolized by both exo- and endonucleases. In wild-type cells rapid cleavages by RNase III in precursor-specific sequences precede the subsequent formation of the mature ends; mature termini can, however, be formed directly from pre-16S rRNA with no intermediate species. The direct maturation is most evident in a strain deficient in RNase III, and the results in whole cells are consistent with results from maturation reactions in vitro. Thus, maturation does not require cleavages within the double-stranded stems that enclose mature rRNA sequences in the pre-16S rRNA.     

Hybridization specificity, enzymatic activity and biological (Ha-ras) activity of oligonucleotides containing 2,4-dideoxy-beta-D-erythro-hexopyranosyl nucleosides.

Antisense oligonucleotides with a 2,4-dideoxyhexopyranosyl nucleoside incorporated at the 3'-end and at a mutation site of the Ha-ras oncogene mRNA were synthesized. Melting temperature studies revealed that an A*-G mismatch is more stable than an A*-T mismatch with these hexopyranosyl nucleosides incorporated at the mutation site. The oligonucleotides are stable against enzymatic degradation. RNase H mediated cleavage studies revealed selective cleavage of mutated Ha-ras mRNA. The oligonucleotide containing two pyranose nucleosides at the penultimate position activates RNase H more strongly than natural oligonucleotides. No correlation, however, was found between DNA - DNA or RNA - DNA melting temperatures and RNase H mediated cleavage capacity. Although the A*-G mismatch gives more stable hybridization than the A*-T base pairing, only the oligonucleotides containing an A*-T base pair are recognized by RNase H. This modification is situated 3 base pairs upstream to the cleavage site. Finally, the double pyranose modified oligonucleotide was able to reduce the growth of T24 cells (bladder carcinoma) while the unmodified antisense oligonucleotide was not.     

Processing of the yeast pre-rRNA at sites A(2) and A(3) is linked.

Cleavage of the yeast pre-rRNA at site A(2) in internal transcribed spacer 1 (ITS1) requires multiple snoRNP species, whereas cleavage at site A(3),located 72 nt 3' in ITS1, requires Rnase MRP. Analyses of mutations in the pre- rRNA have revealed an unexpected link between processing at A(2) and A(3). Small substitution mutations in the 3' flanking sequence at A(2) inhibit processing at site A(3), whereas a small deletion at A(3) has been shown to delay processing at site A(2). Moreover, the combination of mutations in cis at both A(2) and A(3) leads to the synthesis of pre-rRNA species with 5' ends within the mature 18S rRNA sequence, at sites between + 482 and + 496. The simultaneous interference with an snoRNP processing complex at site A(2) and an Rnase MPRP complex at site A(3) may activate a pre-rRNA breakdown pathway. The same aberantpre-rRNA species are observed in strains with mutations in the RNA component of Rnase MRP, consistent with interactions between the processing complexes. Furthermore, genetic depletion of the snoRNA, snR30, has been shown to affect the coupling between cleavage by Rnase MRP and subsequent exonuclease digestion.We conclude that an sno-RNP-dependent processing complex that is required for A(2) cleavage and that recognizes the 3' flanking sequence at A(2), interacts with the RNase MRP complex bound to the pre-rRNA around site A(3).     

The CafA protein required for the 5'-maturation of 16 S rRNA is a 5'-end-dependent ribonuclease that has context-dependent broad sequence specificity

The CafA protein, which was initially described as having a role in either Escherichia coli cell division or chromosomal segregation, has recently been shown to be required for the maturation of the 5'-end of 16 S rRNA. The sequence of CafA is similar to that of the N-terminal ribonucleolytic half of RNase E, an essential E. coli enzyme that has a central role in the processing of rRNA and the decay of mRNA and RNAI, the antisense regulator of ColE1-type plasmids. We show here that a highly purified preparation of CafA is sufficient in vitro for RNA cutting. We detected CafA cleavage of RNAI and a structured region from the 5'-untranslated region of ompA mRNA within segments cleavable by RNaseE, but not CafA cleavage of 9 S RNA at its "a" RNase E site. The latter is consistent with the finding that the generation of 5 S rRNA from its 9 S precursor can be blocked by inactivation of RNase E in cells that are wild type for CafA. Interestingly, however, a decanucleotide corresponding in sequence to the a site of 9 S RNA was cut efficiently indicating that cleavage by CafA is regulated by the context of sites within structured RNAs. Consistent with this notion is our finding that although 23 S rRNA is stable in vivo, a segment from this RNA is cut efficient by CafA at multiple sites in vitro. We also show that, like RNase E cleavage, the efficiency of cleavage by CafA is dependent on the presence of a monophosphate group on the 5'-end of the RNA. This finding raises the possibility that the context dependence of cleavage by CafA may be due at least in part to the separation of a cleavable sequence from the 5'-end of an RNA. Comparison of the sites surrounding points of CafA cleavage suggests that this enzyme has broad sequence specificity. Together with the knowledge that CafA can cut RNAI and ompA mRNA in vitro within segments whose cleavage in vivo initiates the decay of these RNAs, this finding suggests that CafA may contribute at some point during the decay of many RNAs in E. coli.     

RRP5 is required for formation of both 18S and 5.8S rRNA in yeast.

Three of the four eukaryotic ribosomal RNA molecules (18S, 5.8S and 25-28S) are synthesized as a single precursor which is subsequently processed into the mature rRNAs by a complex series of cleavage and modification reactions. In the yeast Saccharomyces cerevisiae, the early pre-rRNA cleavages at sites A0, A1 and A2, required for the synthesis of 18S rRNA, are inhibited in strains lacking RNA or protein components of the U3, U14, snR10 and snR30 small nucleolar ribonucleoproteins (snoRNPs). The subsequent cleavage at site A3, required for formation of the major, short form of 5.8S rRNA, is carried out by another ribonucleoprotein, RNase MRP. A screen for mutations showing synthetic lethality with deletion of the non-essential snoRNA, snR10, identified a novel gene, RRP5, which is essential for viability and encodes a 193 kDa nucleolar protein. Genetic depletion of Rrp5p inhibits the synthesis of 18S rRNA and, unexpectedly, also of the major short form of 5.8S rRNA. Pre-rRNA processing is concomitantly impaired at sites A0, A1, A2 and A3. This distinctive phenotype makes Rrp5p the first cellular component simultaneously required for the snoRNP-dependent cleavage at sites A0, A1 and A2 and the RNase MRP-dependent cleavage at A3 and provides evidence for a close interconnection between these processing events. Putative RRP5 homologues from Caenorhabditis elegans and humans were also identified, suggesting that the critical function of Rrp5p is evolutionarily conserved.     

2- and 8-azido photoaffinity probes. 1. Enzymatic synthesis, characterization, and biological properties of 2- and 8-azido photoprobes of 2-5A and photolabeling of 2-5A binding proteins

The 2- and 8-azido trimer 5'-triphosphate photoprobes of 2-5A have been enzymatically synthesized from [gamma-32P]2-azidoATP and [alpha-32P]8-azidoATP by 2-5A synthetase from rabbit reticulocyte lysates. Identification and structural determination of the 2- and 8-azido adenylate trimer 5'-triphosphates were accomplished by enzymatic hydrolyses with T2 RNase, snake venom phosphodiesterase, and bacterial alkaline phosphatase. Hydrolysis products were identified by HPLC and PEI-cellulose TLC analyses. The 8-azido photoprobe of 2-5A displaces p3A4[32P]pCp from RNase L with affinity equivalent to p3A3 (IC50 = 2 X 10(-9) M in radiobinding assays). The 8-azido photoprobe also activates RNase L to hydrolyze poly(U) [32P]pCp 50% at 7 X 10(-9) M in core-cellulose assays. The 2- and 8-azido photoprobes and authentic p3A3 activate RNase L to cleave 28S and 18S rRNA to specific cleavage products at 10(-9) M in rRNA cleavage assays. The nucleotide binding site(s) of RNase L and/or other 2-5A binding proteins in extracts of interferon-treated L929 cells were investigated by photoaffinity labeling. Dramatically different photolabeling patterns were observed with the 2- and 8-azido photoprobes. The [gamma-32P]2-azido adenylate trimer 5'-triphosphate photolabels only one polypeptide with a molecular weight of 185,000 as determined by SDS gel electrophoresis, whereas the [alpha-32P]8-azido adenylate trimer 5'-triphosphate covalently photolabels six polypeptides with molecular weights of 46,000, 63,000, 80,000, 89,000, 109,000, and 158,000. Evidence that the photolabeling by 2- and 8-azido 2-5A photoprobes was highly specific for the p3A3 allosteric binding site was obtained as follows.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of antisense DNA against the alpha-sarcin stem-loop structure of the ribosomal 23S rRNA.

Antisense DNAs complementary against various sequences of the alpha-sarcin domain (C2646-G2674) of 23S rRNA from Escherichia coli were hybridized to naked 23S rRNA as well as to 70S ribosomes. Saturation levels of up to 0.4 per 70S ribosome were found, the identical fraction was susceptible to the attack of the RNase alpha-sarcin. The hybridization was specific as demonstrated with RNase H digestion, sequencing the resulting fragments and blockage of the action of alpha-sarcin. The RNase alpha-sarcin seems to approach its cleavage site from the 3' half of the loop of the alpha-sarcin domain. Hybridization is efficiently achieved at 37 degrees C and can extend at least into the 3' strand of the stem of the alpha-sarcin domain. However, the inhibition of alpha-sarcin activity is observed at 30 degrees C but not at 37 degrees C. For a significant inhibition of poly(Phe) synthesis the temperature had to be lowered to 25 degrees C. The results imply that the alpha-sarcin domain changes its conformation during protein synthesis and that the conformational changes may include a melting of the stem of the alpha-sarcin domain.     

Modulation of ppp(A2''p)nA-dependent RNase by a temperature-sensitive mutant of vaccinia virus.

Activation of the ppp(A2'p)nA (2-5A)-dependent RNase was investigated during the abortive infection of BSC40 cells by a temperature-sensitive mutant of vaccinia virus, ts22. At the nonpermissive temperature, ts22 has an abortive late phenotype. At the onset of late-viral-gene expression, viral mRNA is degraded and rRNA is cleaved into discrete fragments in the absence of prior interferon treatment (R. F. Pacha and R. C. Condit, J. Virol. 56:395-403, 1985). Concomitant with rRNA cleavage, an increase in 2-5A occurred late during infection. Discrete 18S- and 28S-rRNA degradation products from BSC40 cells infected with ts22 at the nonpermissive temperature comigrated in denaturing agarose gels with rRNA cleaved fragments produced by the activation of 2-5A-dependent RNase in uninfected cells transfected with exogenous 2-5A. An increase in 2-5A levels and a similar discrete and characteristic degradation of rRNA were observed in BSC40 cells infected with wild-type vaccinia virus in the presence of isatin-beta-thiosemicarbazone. The results show that the ts22 lesion and the action of isatin-beta-thiosemicarbazone may affect the same pathway, leading to the activation of latent 2-5A-dependent RNase and resulting in indiscriminate RNA degradation and inhibition of viral replication.