The influence of oligonucleotide-effector on the selectivity of sequence specific modification of 16 S rRNA

The influence of duplex stabilizing oligonucleotide-effector (oligonucleotide, carrying N-(2-hydroxyethyl)phenazinium residues on both ends), on selectivity of site-directed modification of E. coli 16 S rRNA (1542 nucleotides in length) under the conditions of its secondary structure stability was studied. The constant of cooperative binding of the reagent and the oligonucleotide-effector with 16 S rRNA was determined. The accuracy of modification was shown to double in the presence of 50 microM effector at 5 microM concentration of the reagent.     

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.     

Complementary addressed alkylation of 16s rRNA from Escherichia coli by 2',3'-0-[4-N-(2-chloroethyl)-N-methylamino]benzylidene derivatives of oligodeoxyribonucleotides. III. Segments of 16s rRNA interacting with the benzylidene derivative of d(pACCTTGTT)rA

16S rRNA chain was cleaved by RNase H within covalent adduct with a 2',3'-0-[4-N-(2-chloroethyl)-N-methylamino]benzylidene derivative of d(pACCTTGTT)rA. It was shown that no less than 50% of cleavage occurs at the 1498-1506 site. The selectivity of alkylation and correspondingly the cleavage by RNase H, at this site practically does not increase when RNA was alkylated to a low extent, and also when a small excess of the reagent in respect to rRNA was used.     

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.     

Complementary addressed alkylation of Escherichia coli 16S rRNA with 2',3'-O-[4-2-chloroethyl)-N-methylamino]benzylidene derivatives of deoxyribooligonucleotides. II. The nature of rapid interaction at 0 degrees C

Fast non-covalent interactions of 16S rRNA Escherichia coli with 14C labeled 2',3'-O-[4-N-(2-chloroethyl)-N-methylamino]benzylidene derivatives of deoxyribooligonucleotides d(pACCTTGTT)rA, d[pTTACGATC)rU, d(pTTTGCTCCCC)rA (less than[14C]CHRCl-reagents) observed at 0 degrees C were investigated. It was shown, that 16S rRNA and [14C]CHRCl-reagents at 0 degrees C form stable complexes which can not be disrupted under mild acidic conditions (pH 4, 40 degrees C) and under denaturing conditions (7 M urea, 50 degrees C), but are completely disrupted in the course of centrifugation in sucrose density gradient in the presence of SDS. Formation of such complexes of 16S rRNA with greater than[14C]CHRCl-reagents at 0 degrees C was observed due to the presence in the reagent preparation of a number of unidentified products, formed in the course of the synthesis of benzylidene derivatives, and having a hydrophobicity larger, than those for greater than CHRCl-derivatives of deoxyribooligonucleotide. Preparation of [14C]CHRCl-reagents, subjected for purification by reverse-phase chromatography, were unable to form such a complex with 16S rRNA at 0 degrees C. Studies on the complementary addressed modification at 0 degrees C (or incubation at 0 degrees C) with the use of the oligonucleotide benzylidene derivatives not purified from hydrophobic contaminations may lead to alkylation within these complexes during subsequent treatments and in such a way give incorrect information about the level of alkylation within the complex under investigation.     

Study of the structural-energy aspects of complementary-addressed modifications of nucleic acid with reactive 4-]N-methyl-N-(2-chloroethyl)-amino]benzyl-3'- or 5'-phosphamide oligonucleotide derivatives by a molecular mechanics method

Calculations of probabilities of the complementary addressed modification of target NA by 3'- or 5'-reactive derivatives of oligonucleotides carrying a 4-[N-(2-chloroethyl)-N-methyl]aminobenzyl group attached to the 3'- or 5'-terminal phosphates through a phosphoroamide linkage have been made. It is shown that the structural basis of the high efficiency and positional specificity depending on the NA target base sequence is the extent of structural correspondence of the energetically optimal conformation of the active group in the complex to the mutual arrangement of the active group and nucleophilic site needed for the chemical reaction. The 3'-derivative has the highest dependence of efficiency and positional specificity of the alkylation on the target NA base sequence. The maximal positional specificity of the alkylation is found for the modification of the cytidine at the first position from the terminal complementary base pair at the 5'-end of the target NA. For the 5'-derivative, the alkylating ability was determined to depend on the insertion of additional methylene bridges into the standard phosphoroamide linker: two methylene groups provide for the maximal increase of the modification ability of the nucleophilic site of the target NA in the double-stranded part of the complex. The efficiency of alkylation of the target NA in a three component complex with oligonucleotide-effector also complementary to the target NA have been studied. It was found that formation of the three-component complex lead to an additional stabilization of the conformation needed for the reaction of the active group, in comparison with two-component complex, by means of the intercalation of the phenyl group of the reagent in the gap between the oligonucleotide derivative and the oligonucleotide effector.     

Protection from chemical modification of nucleotides in complexes of M1 RNA, the catalytic subunit of RNase P from E coli, and tRNA precursors.

Certain nucleotides in M1 RNA, the catalytic RNA subunit of RNase P from E coli, are protected from chemical modification when M1 RNA forms complexes with tRNA precursor molecules (ES complexes). Many of these nucleotides are important in the formation of the Michaelis complex. In the presence of tRNA precursor molecules, the pattern of protection from chemical modification of a region in M1 RNA that resembles the E site in 23S rRNA is similar to the pattern of protection of the E site in the presence of deacylated tRNA. In the complex with the RNA enzyme, more nucleotides in the substrate become accessible to modification, an indication that the substrate is in an unfolded conformation under these conditions.     

The ribosomal neighbourhood of the central fold of tRNA: cross-links from position 47 of tRNA located at the A, P or E site.

The naturally occurring nucleotide 3-(3-amino-3-carboxy-propyl)uridine (acp3U) at position 47 of tRNA(Phe) from Escherichia coli was modified with a diazirine derivative and bound to ribosomes in the presence of suitable mRNA analogues under conditions specific for the ribosomal A, P or E sites. After photo-activation at 350 nm the cross-links to ribosomal proteins and RNA were identified by our standard procedures. In the 30S subunit protein S19 (and weakly S9 and S13) was the target of cross-linking from tRNA at the A site, S7, S9 and S13 from the P site and S7 from the E site. Similarly, in the 50S subunit L16 and L27 were cross-linked from the A site, L1, L5, L16, L27 and L33 from the P site and L1 and L33 from the E site. Corresponding cross-links to rRNA were localized by RNase H digestion to the following areas: in 16S rRNA between positions 687 and 727 from the P and E sites, positions 1318 and 1350 (P site) and 1350 and 1387 (E site); in the 23S rRNA between positions 865 and 910 from the A site, 1845 and 1892 (P site), 1892 and 1945 (A site), 2282 and 2358 (P site), 2242 and 2461 (P and E sites), 2461 and 2488 (A site), 2488 and 2539 (all three sites) and 2572 and 2603 (A and P sites). In most (but not all) cases, more precise localizations of the cross-link sites could be made by primer extension analysis.     

Quantitative analysis of rat liver nucleolar and nucleoplasmic ribosomal ribonucleic acids.

rRNA from detergent-purified nuclei was fractionated quantitatively, by two independent methods, into nucleolar and nucleoplasmic RNA fractions. The two RNA fractions were analysed by urea/agar-gel electrophoresis and the amount of pre-rRNA (precursor of rRNA) and rRNA components was determined. The rRNA constitutes 35% of total nuclear RNA, of which two-thirds are in nucleolar RNA and one-third in nucleoplasmic RNA. The identified pre-rRNA components (45 S, 41 S, 39 S, 36 S, 32 S and 21 S) are confined to the nucleolus and constitute about 70% of its rRNA. The remaining 30% are represented by 28 S and 18 S rRNA, in a molar ratio of 1.4. The bulk of rRNA in nucleoplasmic RNA is represented by 28 S and 18 S rRNA in a molar ratio close to 1.0. Part of the mature rRNA species in nucleoplasmic RNA originate from ribosomes attached to the outer nuclear membrane, which resist detergent treatment. The absolute amount of nuclear pre-rRNA and rRNA components was evaluated. The amount of 32 S and 21 S pre-rRNA (2.9 x 10(4) and 2.5 x 10(4) molecules per nucleus respectively) is 2-3-fold higher than that of 45 S, 41 S and 36 S pre-rRNA.     

Do mRNA and rRNA binding sites of E.coli ribosomal protein S15 share common structural determinants?

Escherichia coli ribosomal protein S15 recognizes two RNA targets: a three-way junction in 16S rRNA and a pseudoknot structure on its own mRNA. Binding to mRNA occurs when S15 is expressed in excess over its rRNA target, resulting in an inhibition of translation start. The sole apparent similarity between the rRNA and mRNA targets is the presence of a G-U/G-C motif that contributes only modestly to rRNA binding but is essential for mRNA. To get more information on the structural determinants used by S15 to bind its mRNA target as compared to its rRNA site, we used site-directed mutagenesis, substitution by nucleotide analogs, footprinting experiments on both RNA and protein, and graphic modeling. The size of the mRNA-binding site could be reduced to 45 nucleotides, without loss of affinity. This short RNA preferentially folds into a pseudoknot, the formation of which depends on magnesium concentration and temperature. The size of the loop L2 that bridges the two stems of the pseudoknot through the minor groove could not be reduced below nine nucleotides. Then we showed that the pseudoknot recognizes the same side of S15 as 16S rRNA, although shielding a smaller surface area. It turned out that the G-U/G-C motif is recognized from the minor groove in both cases, and that the G-C pair is recognized in a very similar manner. However, the wobble G-U pair of the mRNA is not directly contacted by S15, as in rRNA, but is most likely involved in building a precise conformation of the RNA, essential for binding. Otherwise, unique specific features are utilized, such as the three-way junction in the case of 16S rRNA and the looped out A(-46) for the mRNA pseudoknot.     

Covalent cross-linking of tRNAGly1 to the ribosomal P site via the dihydrouridine loop

The dihydrouracil residue at position 20 of Escherichia coli tRNAGly1 has been replaced by the photoaffinity reagent, N-(4-azido-2-nitrophenyl)glycyl hydrazide (AGH). The location of the substituent was confirmed by the susceptibility of the modified tRNA to cleavage with aniline. When N-acetylglycyl-tRNAGly1 derivatized with AGH was bound noncovalently to the P site of E. coli 70 S ribosomes, 5-6% on average was photochemically cross-linked to the ribosomal particles in a reaction requiring poly(G,U), irradiation and the presence of the AGH label in the tRNA. Approximately two-thirds of the covalently attached tRNA was associated with 16 S RNA in the 30 S subunit. This material was judged to be in the P site by the criterion of puromycin reactivity. As partial RNAase digestion of the tRNA-16 S RNA complex produced labeled fragments from both 5' and 3' segments of the rRNA, there appeared to be more than one site of cross-linking in the 30 S subunit. The small amount of N-acetylglycyl-tRNAGly1 associated with the 50 S subunit was also linked mainly to rRNA, but it was not puromycin-reactive.     

Independent binding sites in mouse 5.8S ribosomal ribonucleic acid for 28S ribosomal ribonucleic acid

Limited digestion of mouse 5.8S ribosomal RNA (rRNA) with RNase T2 generates 5'- and 3'-terminal "half-molecules". These fragments are capable of independently and specifically binding to 28S rRNA, so there exist at least two contacts in the 5.8S rRNA for the 28S rRNA. The dissociation constants for the 5.8S/28S, 5' 5.8S fragment/28S, and 3' 5.8S fragment/28S complexes are 9 x 10(-8) M, 6 x 10(-8) M, and 13 x 10(-8) M, respectively. Thus, each of the fragment binding sites contributes about equally to the overall binding energy of the 5.8S/28S rRNA complex, and the binding sites act independently, rather than cooperatively. The dissociation constants suggest that the 5.8S rRNA termini from short, irregular helices with 28S rRNA. Thermal denaturation data on complexes containing 28S rRNA and each of the half-molecules of 5.8S rRNA indicate that the 5'-terminal binding site(s) exist(s) in a single conformation while the 3'-terminal site exhibits two conformational alternatives. The functional significance of the different conformational states is presently indeterminate, but the possibility they may represent alternative forms of a conformational switch operative during ribosome function is discussed.     

Recognition of 16S rRNA by ribosomal protein S4 from Bacillus stearothermophilus

Protein S4 is essential for bacterial small ribosomal subunit assembly and recognizes the 5' domain (approximately 500 nt) of small subunit rRNA. This study characterizes the thermodynamics of forming the S4-5' domain rRNA complex from a thermophile, Bacillus stearothermophilus, and points out unexpected differences from the homologous Escherichia coli complex. Upon incubation of the protein and RNA at temperatures between 35 and 50 degrees C under ribosome reconstitution conditions [350 mM KCl, 8 mM MgCl2, and 30 mM Tris (pH 7.5)], a complex with an association constant of > or = 10(9) M(-1) was observed, more than an order of magnitude tighter than previously found for the homologous E. coli complex under similar conditions. This high-affinity complex was shown to be stoichiometric, in equilibrium, and formed at rates on the order of magnitude expected for diffusion-controlled reactions ( approximately 10(7) M(-1) x s(-1)), though at low temperatures the complex became kinetically trapped. Heterologous binding experiments with E. coli S4 and 5' domain RNA suggest that it is the B. stearothermophilus S4, not the rRNA, that is activated by higher temperatures; the E. coli S4 is able to bind 5' domain rRNA equally well at 0 and 37 degrees C. Tight complex formation requires a low Mg ion concentration (1-2 mM) and is very sensitive to KCl concentration [- partial differential[log(K)]/partial differential(log[KCl]) = 9.3]. The protein has an unusually strong nonspecific binding affinity of 3-5 x 10(6) M(-1), detected as a binding of one or two additional proteins to the target 5' domain RNA or two to three proteins binding a noncognate 23S rRNA fragment of the approximately same size. This binding is not as sensitive to monovalent ion concentration [- partial differential[log(K)]/partial differential(log[KCl]) = 6.3] as specific binding and does not require Mg ion. These findings are consistent with S4 stabilizing a compact form of the rRNA 5' domain.     

Comparison of the conformation of RNA from phage MS2 and 16S rRNA. Interaction with dyes specific for the secondary structure of native RNA and RNA subjected to hydrolysis by nuclease S1

The interaction of ethidium bromide (EtBr) with double-stranded (ds), and acridine orange (AO) with single-stranded (ss) fragments of 16S rRNA Escherichia coli in a wide range of ionic strength, at various pH, Zn2+ ion concentrations and partial hydrolysis by nuclease S1 was investigated. It was shown that about 90% of the RNA molecule is accessible to both dyes, when the ionic strength is near of 0.01 (pH 7). Approximately half of the RNA becomes inaccessible to dyes, when the ionic strength was increased up to 0.08-0.24 (pH 4.7-7), independent on the presence of Zn2+ ions (10(-3) M). About a half of the ds-, and a quarter of the ss-segments of the RNA, deduced from the secondary structure model were protected from the interaction with EtBr and AO. The hydrolysis of about a half of ss-segments upon addition of the Zn2+ (10(-3) M) ions did not affect the RNA tertiary structure. The experimental data obtained confirm the idea of the existence of some "nucleus" (or "nuclei") within the 16S rRNA molecule. The "nucleus" seems to be inaccessible to the dyes and is very stable to heat denaturation. It was supposed that this structure is organized by means of interaction of some of the parallelly oriented ds-segments, as it was suggested earlier for the phage MS2 RNA structure.     

A chemical interference study on the interaction of ribosomal protein L11 from Escherichia coli with RNA molecules containing its binding site from 23S rRNA.

The interaction between ribosomal protein L11 from Escherichia coli and in vitro synthesized RNA containing its binding site from 23S rRNA was characterized by identifying nucleotides that interfered with complex formation when chemically modified by diethylpyrocarbonate or hydrazine. Chemically modified RNA was incubated with L11 under conditions appropriate for specific binding of L11 and the resulting protein-RNA complex was separated from unbound RNA on Mg(2+)-containing polyacrylamide gels. The ability to isolate L11 complexes on such gels was affected by the extent of modification by either reagent. Protein-bound and free RNAs were recovered and treated with aniline to identify their content of modified bases. Exclusion of RNA containing chemically altered bases from L11-associated material occurred for 29 modified nucleotides, located throughout the region corresponding to residues 1055-1105 in 23S rRNA. Ten bases within this region did not reproducibly inhibit binding when modified. Multiple bands of RNA were consistently observed on the nondenaturing gels, suggesting that significant intermolecular RNA-RNA interactions had occurred.