Methylation at nucleotide G745 or G748 in 23S rRNA distinguishes Gram-negative from Gram-positive bacteria

Bacteria tune the function of their ribosomes by methylating specific rRNA nucleotides. Nucleotide G745 in Escherichia coli 23S rRNA is methylated by the methyltransferase enzyme RrmA, whereas in Streptomyces fradiae, the neighbouring nucleotide G748 is methylated by the enzyme TlrB. Both nucleotides line the peptide exit channel of the ribosome at the binding site of macrolide, lincosamide and streptogramin B antibiotics. Resistance to the macrolide tylosin, which is produced by S. fradiae, is conferred by methylation of G748. RrmA and TlrB are homologues (29% identical), and a database search against all presently available sequences revealed a further two dozen homologues from a wide variety of Bacteria. No homologues were found among the Archaea or Eukarya. The bacterial sequences adhere to the species phylogeny and segregate into two groups, in which the Gram-negative sequences align with RrmA and the Gram-positives with TlrB. Consistently, in more than 20 species tested, the distribution of methylation in the Gram-negative rRNAs (methylated at G745) and the Gram-positives (methylated at G748) perfectly matches the bacterial phylogeny. Cloning and expression of representative methyltransferase genes showed that this specificity of methylation is determined solely by the methyltransferase enzyme and is independent of the origin of the rRNA substrate. This is the first case in which the position of an RNA methylation defines a sharp division between the Gram-negative and Gram-positive bacteria. Given the specificities and distribution of these methyltransferases, we propose a change in the nomenclature of RrmA to RlmAI (rRNA large subunit methyltransferase) and of TlrB to RlmAII.     

Recognition elements in rRNA for the tylosin resistance methyltransferase RlmA(II)

The methyltransferase RlmA(II) (formerly TlrB) is found in many Gram-positive bacteria, and methylates the N-1 position of nucleotide G748 within the loop of hairpin 35 in 23S rRNA. Methylation of the rRNA by RlmA(II) confers resistance to tylosin and other mycinosylated 16-membered ring macrolide antibiotics. We have previously solved the solution structure of hairpin 35 in the conformation that is recognized by the RlmA(II) methyltransferase from Streptococcus pneumoniae. It was shown that while essential recognition elements are located in hairpin 35, the interactions between RlmA(II) and hairpin 35 are insufficient on their own to support the methylation reaction. Here we use biochemical techniques in conjunction with heteronuclear/homonuclear nuclear magnetic resonance spectroscopy to define the RNA structures that are required for efficient methylation by RlmA(II). Progressive truncation of the rRNA substrate indicated that multiple contacts occur between RlmA(II) and nucleotides in stem-loops 33, 34 and 35. RlmA(II) appears to recognize its rRNA target through specific surface shape complementarity at the junction formed by these three helices. This means of recognition is highly similar to that of the orthologous Gram-negative methyltransferase, RlmA(I) (formerly RrmA), which also interacts with hairpin 35, but methylates at the adjacent nucleotide G745.     

RlmCD-mediated U747 methylation promotes efficient G748 methylation by methyltransferase RlmAII in 23S rRNA in Streptococcus pneumoniae; interplay between two rRNA methylations responsible for telithromycin susceptibility

Adenine at position 752 in a loop of helix 35 from positions 745 to 752 in domain II of 23S rRNA is involved in binding to the ribosome of telithromycin (TEL), a member of ketolides. Methylation of guanine at position 748 by the intrinsic methyltransferase RlmA^II enhances binding of telithromycin (TEL) to A752 in Streptococcus pneumoniae. We have found that another intrinsic methylation of the adjacent uridine at position 747 enhances G748 methylation by RlmA^II, rendering TEL susceptibility. U747 and another nucleotide, U1939, were methylated by the dual-specific methyltransferase RlmCD encoded by SP_1029 in S. pneumoniae. Inactivation of RlmCD reduced N1-methylated level of G748 by RlmA^II in vivo, leading to TEL resistance when the nucleotide A2058, located in domain V of 23S rRNA, was dimethylated by the dimethyltransferase Erm(B). In vitro methylation of rRNA showed that RlmA^II activity was significantly enhanced by RlmCD-mediated pre-methylation of 23S rRNA. These results suggest that RlmCD-mediated U747 methylation promotes efficient G748 methylation by RlmA^II, thereby facilitating TEL binding to the ribosome.     

Interaction of the tylosin-resistance methyltransferase RlmA II at its rRNA target differs from the orthologue RlmA I

RlmA^II methylates the N1-position of nucleotide G748 in hairpin 35 of 23 S rRNA. The resultant methyl group extends into the peptide channel of the 50 S ribosomal subunit and confers resistance to tylosin and other mycinosylated macrolide antibiotics. Methylation at G748 occurs in several groups of Gram-positive bacteria, including the tylosin-producer Streptomyces fradiae and the pathogen Streptococcus pneumoniae. Recombinant S. pneumoniae RlmA^II was purified and shown to retain its activity and specificity in vitro when tested on unmethylated 23 S rRNA substrates. RlmA^II makes multiple footprint contacts with nucleotides in stem-loops 33, 34 and 35, and does not interact elsewhere in the rRNA. Binding of RlmA^II to the rRNA is dependent on the cofactor S-adenosylmethionine (or S-adenosylhomocysteine). RlmA^II interacts with the same rRNA region as the orthologous enzyme RlmA^I that methylates at nucleotide G745. Differences in nucleotide contacts within hairpin 35 indicate how the two methyltransferases recognize their distinct targets.     

Core sequence in the RNA motif recognized by the ErmE methyltransferase revealed by relaxing the fidelity of the enzyme for its target.

Under physiological conditions, the ErmE methyltransferase specifically modifies a single adenosine within ribosomal RNA (rRNA), and thereby confers resistance to multiple antibiotics. The adenosine (A2058 in Escherichia coli 23S rRNA) lies within a highly conserved structure, and is methylated efficiently, and with equally high fidelity, in rRNAs from phylogenetically diverse bacteria. However, the fidelity of ErmE is reduced when magnesium is removed, and over twenty new sites of ErmE methylation appear in E. coli 16S and 23S rRNAs. These sites show widely different degrees of reactivity to ErmE. The canonical A2058 site is largely unaffected by magnesium depletion and remains the most reactive site in the rRNA. This suggests that methylation at the new sites results from changes in the RNA substrate rather than the methyltransferase. Chemical probing confirms that the rRNA structure opens upon magnesium depletion, exposing potential new interaction sites to the enzyme. The new ErmE sites show homology with the canonical A2058 site, and have the consensus sequence aNNNcgGAHAg (ErmE methylation occurs exclusively at adenosines (underlined); these are preceded by a guanosine, equivalent to G2057; there is a high preference for the adenosine equivalent to A2060; H is any nucleotide except G; N is any nucleotide; and there are slight preferences for the nucleotides shown in lower case). This consensus is believed to represent the core of the motif that Erm methyltransferases recognize at their canonical A2058 site. The data also reveal constraints on the higher order structure of the motif that affect methyltransferase recognition.     

Methylation of 23S rRNA nucleotide G745 is a secondary function of the RlmAI methyltransferase

Several groups of Gram-negative bacteria possess an RlmA(I) methyltransferase that methylates 23S rRNA nucleotide G745 at the N1 position. Inactivation of rlmA(I) in Acinetobacter calcoaceticus and Escherichia coli reduces growth rates by at least 30%, supposedly due to ribosome malfunction. Wild-type phenotypes are restored by introduction of plasmid-encoded rlmA(I), but not by the orthologous Gram-positive gene rlmA(II) that methylates the neighboring nucleotide G748. Nucleotide G745 interacts with A752 in a manner that does not involve the guanine N1 position. When a cytosine is substituted at A752, a Watson-Crick G745-C752 pair is formed occluding the guanine N1 and greatly reducing RlmA(I) methylation. Methylation is completely abolished by substitution of the G745 base. Intriguingly, the absence of methylation in E. coli rRNA mutant strains causes no reduction in growth rate. Furthermore, the slow-growing rlmA(I) knockout strains of Acinetobacter and E. coli revert to the wild-type growth phenotype after serial passages on agar plates. All the cells tested were pseudorevertants, and none of them had recovered G745 methylation. Analyses of the pseudorevertants failed to reveal second-site mutations in the ribosomal components close to nucleotide G745. The results indicate that cell growth is not dependent on G745 methylation, and that the RlmA(I) methyltransferase therefore has another (as yet unidentified) primary function.     

The conformation of 23S rRNA nucleotide A2058 determines its recognition by the ErmE methyltransferase.

The ErmE methyltransferase confers resistance to MLS antibiotics by specifically dimethylating adenine 2058 (A2058, Escherichia coli numbering) in bacterial 23S rRNA. To define nucleotides in the rRNA that are part of the motif recognized by ErmE, we investigated both in vivo and in vitro the effects of mutations around position A2058 on methylation. Mutagenizing A2058 (to G or U) completely abolishes methylation of 23S rRNA by ErmE. No methylation occurred at other sites in the rRNA, demonstrating the fidelity of ErmE for A2058. Breaking the neighboring G2057-C2611 Watson-Crick base pair by introducing either an A2057 or a U2611 mutation, greatly reduces the rate of methylation at A2058. Methylation remains impaired after these mutations have been combined to create a new A2057-U2611 Watson-Crick base interaction. The conformation of this region in 23S rRNA was probed with chemical reagents and it was shown that the A2057 and U2611 mutations alone and in combination alter the reactivity of A2058 and adjacent bases. However, mutagenizing position G-->A2032 in an adjacent loop, which has been implicated to interact with A2058, alters neither the ErmE methylation at A2058 nor the accessibility of this region to the chemical reagents. The data indicate that a less-exposed conformation at A2058 leads to reduction in methylation by ErmE. Nucleotide G2057 and its interaction with C2611 maintain the conformation at A2058, and are thus important in forming the structural motif that is recognized by the ErmE methyltransferase.     

Structure of 23S rRNA hairpin 35 and its interaction with the tylosin-resistance methyltransferase RlmAII

The bacterial rRNA methyltransferase RlmAII (formerly TlrB) contributes to resistance against tylosin-like 16-membered ring macrolide antibiotics. RlmAII was originally discovered in the tylosin-producer Streptomyces fradiae, and members of this subclass of methyltransferases have subsequently been found in other Gram-positive bacteria, including Streptococcus pneumoniae. In all cases, RlmAII methylates 23S rRNA at nucleotide G748, which is situated in a stem-loop (hairpin 35) at the macrolide binding site of the ribosome. The conformation of hairpin 35 recognized by RlmAII is shown here by NMR spectroscopy to resemble the anticodon loop of tRNA. The loop folds independently of the rest of the 23S rRNA, and is stabilized by a non-canonical G-A pair and a U-turn motif, rendering G748 accessible. Binding of S.pneumoniae RlmAII induces changes in NMR signals at specific nucleotides that are involved in the methyltransferase-RNA interaction. The conformation of hairpin 35 that interacts with RlmAII is radically different from the structure this hairpin adopts within the 50S subunit. This indicates that the hairpin undergoes major structural rearrangement upon interaction with ribosomal proteins during 50S assembly.     

The tylosin resistance gene tlrB of Streptomyces fradiae encodes a methyltransferase that targets G748 in 23S rRNA

tlrB is one of four resistance genes encoded in the operon for biosynthesis of the macrolide tylosin in antibiotic-producing strains of Streptomyces fradiae. Introduction of tlrB into Streptomyces lividans similarly confers tylosin resistance. Biochemical analysis of the rRNA from the two Streptomyces species indicates that in vivo TlrB modifies nucleotide G748 within helix 35 of 23S rRNA. Purified recombinant TlrB retains its activity and specificity in vitro and modifies G748 in 23S rRNA as well as in a 74 nucleotide RNA containing helix 35 and surrounding structures. Modification is dependent on the presence of the methyl group donor, S-adenosyl methionine. Analysis of the 74-mer RNA substrate by biochemical and mass spectrometric methods shows that TlrB adds a single methyl group to the base of G748. Homologues of TlrB in other bacteria have been revealed through database searches, indicating that TlrB is the first member to be described in a new subclass of rRNA methyltransferases that are implicated in macrolide drug resistance.     

The last rRNA methyltransferase of E. coli revealed: The yhiR gene encodes adenine-N6 methyltransferase specific for modification of A2030 of 23S ribosomal RNA

The ribosomal RNA (rRNA) of Escherichia coli contains 24 methylated residues. A set of 22 methyltransferases responsible for modification of 23 residues has been described previously. Herein we report the identification of the yhiR gene as encoding the enzyme that modifies the 23S rRNA nucleotide A2030, the last methylated rRNA nucleotide whose modification enzyme was not known. YhiR prefers protein-free 23S rRNA to ribonucleoprotein particles containing only part of the 50S subunit proteins and does not methylate the assembled 50S subunit. We suggest renaming the yhiR gene to rlmJ according to the rRNA methyltransferase nomenclature. The phenotype of yhiR knockout gene is very mild under various growth conditions and at the stationary phase, except for a small growth advantage at anaerobic conditions. Only minor changes in the total E. coli proteome could be observed in a cell devoid of the 23S rRNA nucleotide A2030 methylation.     

YebU is a m5C methyltransferase specific for 16 S rRNA nucleotide 1407

The rRNAs in Escherichia coli contain methylations at 24 nucleotides, which collectively are important for ribosome function. Three of these methylations are m5C modifications located at nucleotides C967 and C1407 in 16S rRNA and at nucleotide C1962 in 23S rRNA. Bacterial rRNA modifications generally require specific enzymes, and only one m5C rRNA methyltransferase, RsmB (formerly Fmu) that methylates nucleotide C967, has previously been identified. BLAST searches of the E.coli genome revealed a single gene, yebU, with sufficient similarity to rsmB to encode a putative m5C RNA methyltransferase. This suggested that the yebU gene product modifies C1407 and/or C1962. Here, we analysed the E.coli rRNAs by matrix assisted laser desorption/ionization mass spectrometry and show that inactivation of the yebU gene leads to loss of methylation at C1407 in 16 S rRNA, but does not interfere with methylation at C1962 in 23 S rRNA. Purified recombinant YebU protein retains its specificity for C1407 in vitro, and methylates 30 S subunits (but not naked 16 S rRNA or 70 S ribosomes) isolated from yebU knockout strains. Nucleotide C1407 is located at a functionally active region of the 30 S subunit interface close to the P site, and YebU-directed methylation of this nucleotide seems to be conserved in bacteria. The yebU knockout strains display slower growth and reduced fitness in competition with wild-type cells. We suggest that a more appropriate designation for yebU would be the rRNA small subunit methyltransferase gene rsmF, and that the nomenclature system be extended to include the rRNA methyltransferases that still await identification.     

Erythromycin resistance mutations in ribosomal proteins L22 and L4 perturb the higher order structure of 23 S ribosomal RNA.

We have used chemical modification to examine the conformation of 23 S rRNA in Escherichia coli ribosomes bearing erythromycin resistance mutations in ribosomal proteins L22 and L4. Changes in reactivity to chemical probes were observed at several nucleotide positions scattered throughout 23 S rRNA. The L4 mutation affects the reactivity of G799 and U1255 in domain II and that of A2572 in domain V. The L22 mutation influences modification in domain II at positions m5U747, G748, and A1268, as well as at A1614 in domain III and G2351 in domain V. The reactivity of A789 is weakly enhanced by both the L22 and L4 mutations. None of these nucleotide positions has previously been associated with macrolide antibiotic resistance. Interestingly, neither of the ribosomal protein mutations produces any detectable effects at or within the vicinity of A2058 in domain V, the site most frequently shown to confer macrolide resistance when altered by methylation or mutation. Thus, while L22 and L4 bind primarily to domain I of 23 S rRNA, erythromycin resistance mutations in these ribosomal proteins perturb the conformation of residues in domains II, III and V and affect the action of antibiotics known to interact with nucleotide residues in the peptidyl transferase center of domain V. These results support the hypothesis that ribosomal proteins interact with rRNA at multiple sites to establish its functionally active three-dimensional structure, and suggest that these antibiotic resistance mutations act by perturbing the conformation of rRNA.     

Characterization of the 23 S ribosomal RNA m5U1939 methyltransferase from Escherichia coli.

An Escherichia coli open reading frame, ygcA, was identified as a putative 23 S ribosomal RNA 5-methyluridine methyltransferase (Gustafsson, C., Reid, R., Greene, P. J., and Santi, D. V. (1996) Nucleic Acids Res. 24, 3756-3762). We have cloned, expressed, and purified the 50-kDa protein encoded by ygcA. The purified enzyme catalyzed the AdoMet-dependent methylation of 23 S rRNA but did not act upon 16 S rRNA or tRNA. A high performance liquid chromatography-based nucleoside analysis identified the reaction product as 5-methyluridine. The enzyme specifically methylated U1939 as determined by a nuclease protection assay and by methylation assays using site-specific mutants of 23 S rRNA. A 40-nucleotide 23 S rRNA fragment (nucleotide 1930--1969) also served as an efficient substrate for the enzyme. The apparent K(m) values for the 40-mer RNA oligonucleotide and AdoMet were 3 and 26 microm, respectively, and the apparent k(cat) was 0.06 s(-1). The enzyme contains two equivalents of iron/monomer and has a sequence motif similar to a motif found in iron-sulfur proteins. We propose to name this gene rumA and accordingly name the protein product as RumA for RNA uridine methyltransferase.     

Crucial elements that maintain the interactions between the regulatory TnaC peptide and the ribosome exit tunnel responsible for Trp inhibition of ribosome function

Translation of the TnaC nascent peptide inhibits ribosomal activity in the presence of l-tryptophan, inducing expression of the tnaCAB operon in Escherichia coli. Using chemical methylation, this work reveals how interactions between TnaC and the ribosome are affected by mutations in both molecules. The presence of the TnaC-tRNA(Pro) peptidyl-tRNA within the ribosome protects the 23S rRNA nucleotide U2609 against chemical methylation. Such protection was not observed in mutant ribosomes containing changes in 23S rRNA nucleotides of the A748-A752 region. Nucleotides A752 and U2609 establish a base-pair interaction. Most replacements of either A752 or U2609 affected Trp induction of a TnaC-regulated LacZ reporter. However, the single change A752G, or the dual replacements A752G and U2609C, maintained Trp induction. Replacements at the conserved TnaC residues W12 and D16 also abolished the protection of U2609 by TnaC-tRNA(Pro) against chemical methylation. These data indicate that the TnaC nascent peptide in the ribosome exit tunnel interacts with the U2609 nucleotide when the ribosome is Trp responsive. This interaction is affected by mutational changes in exit tunnel nucleotides of 23S rRNA, as well as in conserved TnaC residues, suggesting that they affect the structure of the exit tunnel and/or the nascent peptide configuration in the tunnel.     

The aminoglycoside resistance methyltransferase Sgm impedes RsmF methylation at an adjacent rRNA nucleotide in the ribosomal A site

Ribosome-targeting antibiotics block protein synthesis by binding at functionally important regions of the bacterial rRNA. Resistance is often conferred by addition of a methyl group at the antibiotic binding site within an rRNA region that is already highly modified with several nucleotide methylations. In bacterial rRNA, each methylation requires its own specific methyltransferase enzyme, and this raises the question as to how an extra methyltransferase conferring antibiotic resistance can be accommodated and how it can gain access to its nucleotide target within a short and functionally crowded stretch of the rRNA sequence. Here, we show that the Sgm methyltransferase confers resistance to 4,6-disubstituted deoxystreptamine aminoglycosides by introducing the 16S rRNA modification m⁷G1405 within the ribosomal A site. This region of Escherichia coli 16S rRNA already contains several methylated nucleotides including m⁴Cm1402 and m⁵C1407. Modification at m⁵C1407 by the methyltransferase RsmF is impeded as Sgm gains access to its adjacent G1405 target on the 30S ribosomal subunit. An Sgm mutant (G135A), which is impaired in S-adenosylmethionine binding and confers lower resistance, is less able to interfere with RsmF methylation on the 30S subunit. The two methylations at 16S rRNA nucleotide m⁴Cm1402 are unaffected by both the wild-type and the mutant versions of Sgm. The data indicate that interplay between resistance methyltransferases and the cell''s own indigenous methyltransferases can play an important role in determining resistance levels.     

YgdE is the 2'-O-ribose methyltransferase RlmM specific for nucleotide C2498 in bacterial 23S rRNA

The rRNAs of Escherichia coli contain four 2'- O- methylated nucleotides. Similar to other bacterial species and in contrast with Archaea and Eukaryota, the E. coli rRNA modifications are catalysed by specific methyltransferases that find their nucleotide targets without being guided by small complementary RNAs. We show here that the ygdE gene encodes the methyltransferase that catalyses 2'- O- methylation at nucleotide C2498 in the peptidyl transferase loop of E. coli 23S rRNA. Analyses of rRNAs using MALDI mass spectrometry showed that inactivation of the ygdE gene leads to loss of methylation at nucleotide C2498. The loss of ygdE function causes a slight reduction in bacterial fitness. Methylation at C2498 was restored by complementing the knock-out strain with a recombinant copy of ygdE . The recombinant YgdE methyltransferase modifies C2498 in naked 23S rRNA, but not in assembled 50S subunits or ribosomes. Nucleotide C2498 is situated within a highly conserved and heavily modified rRNA sequence, and YgdE's activity is influenced by other modification enzymes that target this region. Phylogenetically, YgdE is placed in the cluster of orthologous groups COG2933 together with S -adenosylmethionine-dependent, Rossmann-fold methyltransferases such as the archaeal and eukaryotic RNA-guided fibrillarins. The ygdE gene has been redesignated rlmM for r RNA l arge subunit m ethyltransferase M .     

YccW is the m5C methyltransferase specific for 23S rRNA nucleotide 1962

Methylation at the 5-position of cytosine [m⁵C (5-methylcytidine)] occurs at three RNA nucleotides in Escherichia coli. All these modifications are at highly conserved nucleotides in the rRNAs, and each is catalyzed by its own m⁵C methyltransferase enzyme. Two of the enzymes, RsmB and RsmF, are already known and methylate 16S rRNA at nucleotides C967 and C1407, respectively. Here, we report the identity of the third E. coli m⁵C methyltransferase. Analysis of rRNAs by matrix-assisted laser desorption/ionization mass spectrometry showed that inactivation of the yccW gene leads to loss of m⁵C methylation at nucleotide 1962 in E. coli 23S rRNA. This methylation is restored by complementing the knockout strain with a plasmid-encoded copy of the yccW gene. Purified recombinant YccW protein retains its specificity for C1962 in vitro and methylates naked 23S rRNA isolated from the yccW knockout strain. However, YccW does not methylate assembled 50S subunits, and this is somewhat surprising as the published crystal structures show nucleotide C1962 to be fully accessible at the subunit interface. YccW-directed methylation at nucleotide C1962 is conserved in bacteria, and loss of this methylation in E. coli marginally reduces its growth rate. YccW had previously eluded identification because it displays only limited sequence similarity to the m⁵C methyltransferases RsmB and RsmF and is in fact more similar to known m⁵U (5-methyluridine) RNA methyltransferases. In keeping with the previously proposed nomenclature system for bacterial rRNA methyltransferases, yccW is now designated as the rRNA large subunit methyltransferase gene rlmI.     

Point mutations in the 23 S rRNA genes of four lincomycin resistant Nicotiana plumbaginifolia mutants could provide new selectable markers for chloroplast transformation

Summary Experiments designed to establish stable chloroplast transformation require selectable marker genes encoded by the chloroplast genome. The antibiotic lincomycin is a specific inhibitor of chloroplast ribosomal activity and is known to bind to the large ribosomal subunit. We have investigated a defined region of the chloroplast 23 S rRNA genes from four lincomycin resistant Nicotiana plumbaginifolia mutants and from wild-type N. plumbaginifolia. The mutants LR415, LR421 and LR446 have A to G transitions at positions equivalent to the nucleotides 2058 and 2059 in the Escherichia coli 23 S rRNA. The mutant, LR400, possesses a G to A transition at a position corresponding to nucleotide 2032 of the E. coli 23 S rRNA.     

Ribosomal RNA guanine-(N2)-methyltransferases and their targets

Five nearly universal methylated guanine-(N2) residues are present in bacterial rRNA in the ribosome. To date four out of five ribosomal RNA guanine-(N2)-methyltransferases are described. RsmC(YjjT) methylates G1207 of the 16S rRNA. RlmG(YgjO) and RlmL(YcbY) are responsible for the 23S rRNA m²G1835 and m²G2445 formation, correspondingly. RsmD(YhhF) is necessary for methylation of G966 residue of 16S rRNA. Structure of Escherichia coli RsmD(YhhF) methyltransferase and the structure of the Methanococcus jannaschii RsmC ortholog were determined. All ribosomal guanine-(N2)-methyltransferases have similar AdoMet-binding sites. In relation to the ribosomal substrate recognition, two enzymes that recognize assembled subunits are relatively small single domain proteins and two enzymes that recognize naked rRNA are larger proteins containing separate methyltransferase- and RNA-binding domains. The model for recognition of specific target nucleotide is proposed. The hypothetical role of the m²G residues in rRNA is discussed.