Adenosine dimethylation of 16S ribosomal RNA: effect of the methylgroups on local conformational stability as deduced from electrophoretic mobility of RNA fragments in denaturing polyacrylamide gels

A quantitative model predicts how m6A reshapes the kinetic landscape of nucleic acid hybridization and conformational transitions

N6-methyladenosine (m6A) is a post-transcriptional modification that controls gene expression by recruiting proteins to RNA sites. The modification also slows biochemical processes through mechanisms that are not understood. Using temperature-dependent (20°C-65°C) NMR relaxation dispersion, we show that m6A pairs with uridine with the methylamino group in the anti conformation to form a Watson-Crick base pair that transiently exchanges on the millisecond timescale with a singly hydrogen-bonded low-populated (1%) mismatch-like conformation in which the methylamino group is syn. This ability to rapidly interchange between Watson-Crick or mismatch-like forms, combined with different syn:anti isomer preferences when paired (~1:100) versus unpaired (~10:1), explains how m6A robustly slows duplex annealing without affecting melting at elevated temperatures via two pathways in which isomerization occurs before or after duplex annealing. Our model quantitatively predicts how m6A reshapes the kinetic landscape of nucleic acid hybridization and conformational transitions, and provides an explanation for why the modification robustly slows diverse cellular processes.

Alterations in the maturation and structure of ribosomal precursor RNA in Novikoff hepatoma cells induced by 5-fluorocytidine

The effects of 5-fluorocytidine on ribosomal RNA maturation and structure in Novikoff hepatoma cells were investigated. Like other nucleic acid base analogues that are incorporated into RNA, this compound inhibits maturation of the 45S ribosomal RNA precursor. The 45S RNA precursor produced in the presence of 5-fluorocytidine has an abnormal electrophoretic mobility compared with that of the control precursor under nondenaturing conditions, but the two have identical mobilities under denaturing conditions. Under the conditions of these experiments, 5-fluorocytidine inhibited cellular protein synthesis only slightly, whereas equimolar concentrations of 5-azacytidine resulted in nearly 75% inhibition of this process. Despite this difference in the effects of the two analogues as well as the greater chemical lability of the 5-azacytidine, their effects on ribosomal RNA maturation are identical.

Specificity of mismatch repair following transformation of Saccharomyces cerevisiae with heteroduplex plasmid DNA

A method is described for genetic detection of mismatch repair products following transformation of Saccharomyces cerevisiae. The method is based on the detection of beta-galactosidase activity in clonal derivatives of cells transformed with heteroduplex plasmid DNA. Heteroduplex plasmid substrates were constructed by insertion of an oligonucleotide heteroduplex into the coding sequence of the Escherichia coli lacZ gene. The plasmid and oligonucleotides were designed so that one strand of the construct would code for a functional beta-galactosidase and the other strand would contain an in-frame nonsense codon. The frequencies of transformed clones containing only Lac+ cells, only Lac- cells, or a mixture of the two Lac phenotypes provided information on the efficiency of the repair reaction. With this method, plasmids carrying single-base substitution mismatches, a single-base frameshift mismatch (T/delta), or a 3-base-pair substitution mismatch (TGA/GAA) were tested. A/C, G/T, G/A, G/G, and T/delta mismatches were repaired with significantly greater efficiencies than C/C, A/A, T/T, and TGA/GAA. T/C was repaired with an intermediate efficiency. The frequencies of products obtained with G/G, G/A, and T/delta mismatches suggested modest inequality of repair in the two possible directions. Strains carrying the repair-deficient pms1-1 mutation were also tested. The efficiencies of repair of A/C, G/T, G/G, and A/A mismatches were reduced in pms1-1 cells compared with wild-type cells. In addition, a change in repair inequality was detected when transformation of the two strains with an A/C mismatch was compared.

Preparation and sequencing of the cloacin fragment of Streptomyces aureofaciens 16S RNA

A fast method for isolation of a 3'-terminal fragment of Streptomyces aureofaciens 16S RNA was developed. The procedure involves reaction of 70S ribosomes with cloacin DF13 and subsequent fractionation of the reaction mixture by polyacrylamide gel electrophoresis. The cloacin fragment was eluted from the gel and used directly for 3'-end labeling with cytidine-3',5'-[5'-32P]bisphosphate. The labeled RNA fragment was sequenced by the enzymatic method. It consists of 50 nucleotides and has the sequence 5'-GUCGUAACAAGGUAACCGUACCGGA-AGGUGCGGUUGGAUCACCUCCUUUCOH. The differences from the E. coli and Bacillus sequences and their possible influence on the rate and specificity of polypeptide synthesis are discussed.

Partial methylation of two adjacent adenosines in ribosomes from Euglena gracilis chloroplasts suggests evolutionary loss of an intermediate stage in the methyl-transfer reaction

Bacterial, cytoplasmic and organellar ribosomes from a wide phylogenetic spectrum of organisms have a characteristic m6(2)Am6(2)A structure near the 3' end of the RNA of the small ribosomal subunit (SSU). We have studied one of the few exceptions to this extremely conserved post-transcriptionally modified sequence, i.e. dimethylation of only one of the two A's in chloroplasts from Euglena gracilis. It was established that only the A closest to the 5' end is dimethylated, the other one being unmodified. The methylation reaction was studied in vitro using ribosomes from a kasugamycin resistant mutant (ksgA) of Escherichia coli and purified methyl-transferase. Using limited amounts of the methyl donor S-adenosylmethionine (SAM) a partial level of methylation (50% of control) was attained. It is shown that in this case the 3' proximal A is dimethylated while the other is not. This suggests that dimethylation takes place in two successive stages. Apparently in E. gracilis chloroplasts the first stage of methylation does not occur.

Phylogeny of the conserved 3' terminal structure of the RNA of small ribosomal subunits

The strongest conserved part of the RNA of small ribosomal subunits is probably located near the 3' end. This paper reviews the primary and secondary structures of some 40 sequenced 3' termini and tries to classify these structures according to common features and differences. The regions under consideration contain at the 5' side an almost universal, supposedly single-stranded stretch of nucleotides with the sequence--AAGUCGUAACAAGGU--. This is followed by a stem-loop structure. The stem always contains 9 basepairs (including U-G pairs) and no mismatches or bulged nucleotides. The loop of the hairpin is either (m2)GGm62Am62A (bacteria, chloroplasts and mitochondria) or UGm62Am62A (cytoplasm). The hairpin is, in most cases, followed at the 3' side by--GGAUCA--. Next to it bacteria and chloroplasts contain the so-called "Shine and Dalgarno" sequence --CCUCC--. The stem region of the hairpin contains a conserved A-U U-G junction. The two basepairs between this junction and the loop are either of type 1 (G-C G-C) or type 2 (C-G C-G). Classification according to type links certain bacteria with mitochondria of yeast and plants and others with chloroplasts and with animal mitochondria.

Translational attenuation: the regulation of bacterial resistance to the macrolide-lincosamide-streptogramin B antibiotics

The regulation of ermC is described in detail as an example of regulation on the level of translation. ermC specifies a ribosomal RNA methylase which confers resistance to the macrolide-lincosamide-streptogramin B group of antibiotics. Synthesis of the ermC gene product is induced by erythromycin, a macrolide antibiotic. Stimulation of methylase synthesis is mediated by binding of erythromycin to an unmethylated ribosome. The translational attenuation model, supported by sequencing data and by mutational analysis, proposes that binding of erythromycin causes stalling of a ribosome during translation of a "leader peptide", resulting in isomerization of the ermC transcript from an inactive to an active conformer. The ermC system is analogous to the transcriptional attenuation systems described for certain biosynthetic operons. ermC is unique in that interaction with a small molecule inducer mediates regulation on the translational level. However, it is but one example of nontranscriptional -level control of protein synthesis. Other systems are discussed in which control is also exerted through alterations of RNA conformation and an attempt is made to understand ermC in this more general context. Finally, other positive examples of translational attenuation are presented.

High-resolution proton magnetic resonance studies of the 3'-terminal colicin fragment of 16 S ribosomal RNA from Escherichia coli. Assignment of iminoproton resonances by nuclear Overhauser effect experiments and the influence of adenine dimethylation on the hairpin conformation

The "colicin" fragments comprising the 49 3'-terminal nucleotides of 16 S ribosomal RNA have been isolated from wild-type Escherichia coli and from a kasugamycin-resistant mutant that lacks methylation of two geminal adenine residues. Proton nuclear magnetic resonance (n.m.r.) spectra (500 MHz) were recorded at various temperatures. The low-field resonances arising from the hydrogen-bonded iminoprotons of paired bases were assigned using the nuclear Overhauser effect (n.o.e.). Crucial to the interpretation of the spectra are the resonances that originate from the two hydrogen-bonded iminoprotons of a U X G basepair. Combined with temperature-jump relaxation kinetics experiments the n.o.e.s lead to the conclusion that a conserved A X U/U X G junction in the hairpin is a thermolabile dislocation in the helix. The n.m.r. spectra of the wild-type and mutant fragment are only different with respect to the iminoproton resonances of the two base-pairs adjoining the hairpin loop. The spectra recorded at various temperatures tend to indicate that dimethylation of the adenosines labilizes these base-pairs, but no definitive conclusions are drawn. The results confirm our previous views that dimethylation of the adenosine residues affects the conformation of the hairpin loop.

The conformation of a conserved stem-loop structure in ribosomal RNA

The RNA of small ribosomal subunits contains a conserved stem-loop structure near the 3' end. Characteristics for the hairpins are: (a) a nine-basepairs stem: (b) a conserved A-UU-G junction in the stem: (c) a conserved sequence Gm6(2)AM6(2)A sequence in the loop (except yeast mitochondria and mutants from bacteria). We are using UV-optics, micro-calorimetry and 500 MHz-NMR to investigate fragments of about 50 nucleotides cleaved from the 3' ends of small ribosomal subunit RNA's by bacteriocins. Our preliminary conclusions are: (1) Dimethylation of the adenines in the loop destabilizes the hairpin because of an increased stacking; (2) melting of the hairpin starts at the ends as well as in the middle at the A-UU-G junction; (3) basepair substitutions have an unexpectedly large effect on thermal stability.

Kasugamycin resistant mutants of Bacillus stearothermophilus lacking the enzyme for the methylation of two adjacent adenosines in 16S ribosomal RNA

Several mutants of B. stearothermophilus have been isolated that are resistant to the antibiotic kasugamycin. One of these is shown to lack dimethylation of two adjacent adenosines in the 16S ribosomal RNA. All mutants that were analyzed biochemically lack the enzyme that is able to methylate this site. Ribosomal sensitivity and resistance to kasugamycin in B. stearothermophilus is therefore, like in E. coli, closely connected with dimethylation of the adenosines.

Structural investigation of Phe-tRNAPhe from E.coli bound to the ribosomal A-site

Kethoxal modification of guanosines within Phe-tRNAPhe from E. coli was studied for tRNA in the free state and specifically bound to the ribosomal A-site. Complex formation with the ribosome results in a protection from chemical modification of two distant sites in the tRNA molecule. The guanosines affected are G-18 and G-19, located in the D-loop, and G-34 in the anticodon loop. Modification of Phe-tRNAPhe in the absence of ribosomes leads to a destabilisation of the tRNA structure. Our data are consistent with the conclusion that modification of G-34 at the anticodon loop triggers a conformational instability in distant parts of the tRNA molecule.

Calorimetric measurements of the destabilisation of a ribosomal RNA hairpin by dimethylation of two adjacent adenosines

Fragments of 16S ribosomal RNA from E. coli and B. stearothermophilus, respectively comprising the 49 and 52 3' terminal nucleotides have been studied thermodynamically using high sensitivity differential scanning calorimetry. The fragments were isolated after cleavage of 16S rRNA in the ribosome by the bacteriocin cloacin DF13. Comparison of the thermal properties of the E. coli fragments with those derived from a kasugamycin resistant mutant, which specifically lacks dimethylation of two adjacent adenosines was employed to study the effect of the methylgroups on the thermal stability. Both E. coli species exhibit similar complex melting patterns with several transitions. Overall molar transition enthalpies are equal and do not depend significantly on buffer conditions (120 kcal/mol at 15 mM Na+ to 136 kcal/mol at 215 mM Na+). However, the transition with the highest Tm, corresponding to unfolding of a nine basepair central helix is lowered by the dimethylation of the adenines in the four-membered loop. This decrease amounts to 4 degrees C at 15 mM Na+ and 2 degrees C at 215 mM Na+. The corresponding nine basepair long hairpin in the Bacillus fragment melts at a temperature of 70 degrees C at 15 mM Na+. This Tmax is much higher than expected on the basis of the sequence in the hairpin.

A carbon-13 nuclear magnetic resonance study of the 3'-terminus of 16S ribosomal RNA of Escherichia coli specifically labeled with carbon-13 in the methylgroups of the m6(2)Am6(2)A sequence

30S ribosomes were isolated from a kasugamycin resistant mutant of E. coli that lacks methylgroups on two adjacent adenines in 16S ribosomal RNA. These ribosomes were methylated in vitro with a purified methylating enzyme and 5-S-adenosyl-(13C-methyl)-L-methionine chloride ((13C-methyl)-SAM) as methyldonor. After in situ cleavage of the 16S ribosomal RNA by the bacteriocin cloacin DF13, the 49 nucleotide fragment from the 3'-end of the RNA was isolated. The carbon-13 nuclear magnetic resonance spectra of the fragment at various temperatures were compared with those of 6-N-dimethyladenosine (m6(2)A) and 6-N-dimethyladenylyl-(3' leads to 5')-6-N-dimethyladenosine (m6(2)Am6(2)A). The data show that the two methylated adenines, which are part of a four membered hairpin loop, show a strong tendency to be stacked in analogy to the dinucleotide m6(2)Am6(2).

The structure and function of the regulatory elements of the Escherichia coli uvrB gene

The construction and properties of recombinant plasmids carrying the Escherichia coli uvrB gene, including its transcriptional- and translational regulatory elements, is reported. The DNA sequence of the region, which governs the expression of the uvrB gene, has been determined. Within this sequence two non-overlapping DNA segments match the model sequence for Escherichia coli promoters (1). The '-10 regions' and the '-35 regions' of the proposed uvrB promoters are, respectively, 5'TAAAAT (P1), 5'TATAAT (P2) and 5'TTGGCA (P1), 5'GTGATG (P2). The existence and the position of these promoters has been established by elimination of one promoter (P2), using molecular cloning procedures, by length measurements of in vitro synthesized 'run-off' transcripts and by protection of the uvrB regulatory region for S1 nuclease digestion using in vivo made RNA. Potential sites of interaction within the uvrB regulatory region with regulatory proteins, such as the LexA protein (2) and the UvrC protein (3) are discussed.

Sequence and secondary structure of the colicin fragment of Bacillus stearothermophilus 16S ribosomal RNA

The sequence and the position of post-transcriptionally modified residues of the 3' -terminal end of Bacillus stearothermophilus 16S ribosomal RNA have been determined from the fragment that is cleaved off by bacteriocin treatment. The fragment contains 52 nucleotides, as compared to the 49 nucleotides of the corresponding fragment from E. coli ribosomes, The additional nucleotides are present in the sequence UCU very next to the 3' -terminus as was published earlier (1). The remainder of the sequence is identical to the one of E. coli except at six positions, due to the UV melting properties of the colicin fragment from B. stearothermophilus in comparison to the same fragment of E. coli show that the RNA from the thermophile has a more stable secondary structure.

Destabilization of secondary structure in 16S ribosomal RNA by dimethylation of two adjacent adenosines

Fragments comprising the 49 nucleotides from the 3'-end have been purified from 16S ribosomal RNA of wild-type Escherichia coli and from a kasugamycin-resistant mutant that specifically lacks dimethylation of two adjacent adenines near the 3'-terminus. These fragments, obtained after treatment of ribosomes in vitro with the bacteriocin cloacin DF13, were used to study the effect of the methyl groups on the temperature dependent unfolding of double-stranded regions. Both fragments contain at least 3 independent melting transitions, of which the one with the highest Tm corresponds with the unfolding of a nine-basepair long central hairpin. Dimethylation of the adenines in the loop of this hairpin lowers the melting temperature (Tm) by approximately 2 degrees C at 0.2 M NaCl and by about 5 degrees C at 0.15 M NaCl. It is suggested that m6(2)Am6(2)A is more antagonistic to loop formation that ApA and that the function of the methyl groups is to help to destabilize the 3'-terminal hairpin in 16S rRNA in order to facilitate intermolecular interactions.

16S ribosomal RNA of Escherichia coli contains a N2-methylguanosine at 27 nucleotides from the 3' end

The 49 nucleotides fragment derived from the 3' end of 16S rRNA by cloacin DF13, is not cleaved by ribonuclease T1 at a guanosine residue tha is present at 27 nucleotides from the 3' terminus (position 115 in 16S rRNA). Analysis of the isolated nucleotide indicates that it is a modified G residue. In vivo labeling with (3H)methionine shows that this G is methylated and co-chromatography with markers reveals that it is N2-methylguanosine.