Insights into the Catalytic Mechanism of 16S rRNA Methyltransferase RsmE (mU1498) from Crystal and Solution Structures

RsmE is the founding member of a new RNA methyltransferase (MTase) family responsible for methylation of U1498 in 16S ribosomal RNA in Escherichia coli. It is well conserved across bacteria and plants and may play an important role in ribosomal intersubunit communication. The crystal structure in monomer showed that it consists of two distinct but structurally related domains: the PUA (pseudouridine synthases and archaeosine‐specific transglycosylases)-like RNA recognition and binding domain and the conserved MTase domain with a deep trefoil knot. Analysis of small-angle X-ray scattering data revealed that RsmE forms a flexible dimeric conformation that may be essential for substrate binding. The S‐adenosyl‐l‐methionine (AdoMet)-binding characteristic determined by isothermal titration calorimetry suggested that there is only one AdoMet molecule bound in the subunit of the homodimer. In vitro methylation assay of the mutants based on the RsmE-AdoMet-uridylic acid complex model showed key residues involved in substrate binding and catalysis. Comprehensive comparisons of RsmE with closely related MTases, combined with the biochemical experiments, indicated that the MTase domain of one subunit in dimeric RsmE is responsible for binding of one AdoMet molecule and catalytic process while the PUA-like domain in the other subunit is mainly responsible for recognition of one substrate molecule (the ribosomal RNA fragment and ribosomal protein complex). The methylation process is required by collaboration of both subunits, and dimerization is functionally critical for catalysis. In general, our study provides new information on the structure-function relationship of RsmE and thereby suggests a novel catalytic mechanism.     

Crystal structure of RlmM, the 2��O-ribose methyltransferase for C2498 of Escherichia coli 23S rRNA

RlmM (YgdE) catalyzes the S-adenosyl methionine (AdoMet)-dependent 2′O methylation of C2498 in 23S ribosomal RNA (rRNA) of Escherichia coli. Previous experiments have shown that RlmM is active on 23S rRNA from an RlmM knockout strain but not on mature 50S subunits from the same strain. Here, we demonstrate RlmM methyltransferase (MTase) activity on in vitro transcribed 23S rRNA and its domain V. We have solved crystal structures of E. coli RlmM at 1.9 Å resolution and of an RlmM–AdoMet complex at 2.6 Å resolution. RlmM consists of an N-terminal THUMP domain and a C-terminal catalytic Rossmann-like fold MTase domain in a novel arrangement. The catalytic domain of RlmM is closely related to YiiB, TlyA and fibrillarins, with the second K of the catalytic tetrad KDKE shifted by two residues at the C-terminal end of a beta strand compared with most 2′O MTases. The AdoMet-binding site is open and shallow, suggesting that RNA substrate binding may be required to form a conformation needed for catalysis. A continuous surface of conserved positive charge indicates that RlmM uses one side of the two domains and the inter-domain linker to recognize its RNA substrate.     

Structural insights into the function of 23S rRNA methyltransferase RlmG (m²G1835) from Escherichia coli

RlmG is a specific AdoMet-dependent methyltransferase (MTase) responsible for N2-methylation of G1835 in 23S rRNA of Escherichia coli. Methylation of m2G1835 specifically enhances association of ribosomal subunits and provides a significant advantage for bacteria in osmotic and oxidative stress. Here, the crystal structure of RlmG in complex with AdoMet and its structure in solution were determined. The structure of RlmG is similar to that of the MTase RsmC, consisting of two homologous domains: the N-terminal domain (NTD) in the recognition and binding of the substrate, and the C-terminal domain (CTD) in AdoMet-binding and the catalytic process. However, there are distinct positively charged protuberances and a distribution of conserved residues contributing to the charged surface patch, especially in the NTD of RlmG for direct binding of protein-free rRNA. The RNA-binding properties of the NTD and CTD characterized by both gel electrophoresis mobility shift assays and isothermal titration calorimetry showed that NTD could bind RNA independently and RNA binding was achieved by the NTD, accomplished by a coordinating role of the CTD. The model of the RlmG-AdoMet-RNA complex suggested that RlmG may unfold its substrate RNA in the positively charged cleft between the NTD and CTD, and then G1835 disengages from its Watson-Crick pairing with C1905 and flips out to insert into the active site. Our structure and biochemical studies provide novel insights into the catalytic mechanism of G1835 methylation.     

The crystal structure of M. leprae ML2640c defines a large family of putative S-adenosylmethionine-dependent methyltransferases in mycobacteria

Mycobacterium leprae protein ML2640c belongs to a large family of conserved hypothetical proteins predominantly found in mycobacteria, some of them predicted as putative S-adenosylmethionine (AdoMet)-dependent methyltransferases (MTase). As part of a Structural Genomics initiative on conserved hypothetical proteins in pathogenic mycobacteria, we have determined the structure of ML2640c in two distinct crystal forms. As expected, ML2640c has a typical MTase core domain and binds the methyl donor substrate AdoMet in a manner consistent with other known members of this structural family. The putative acceptor substrate-binding site of ML2640c is a large internal cavity, mostly lined by aromatic and aliphatic side-chain residues, suggesting that a lipid-like molecule might be targeted for catalysis. A flap segment (residues 222-256), which isolates the binding site from the bulk solvent and is highly mobile in the crystal structures, could serve as a gateway to allow substrate entry and product release. The multiple sequence alignment of ML2640c-like proteins revealed that the central alpha/beta core and the AdoMet-binding site are very well conserved within the family. However, the amino acid positions defining the binding site for the acceptor substrate display a higher variability, suggestive of distinct acceptor substrate specificities. The ML2640c crystal structures offer the first structural glimpses at this important family of mycobacterial proteins and lend strong support to their functional assignment as AdoMet-dependent methyltransferases.     

The structure of the RlmB 23S rRNA methyltransferase reveals a new methyltransferase fold with a unique knot

In Escherichia coli, RlmB catalyzes the methylation of guanosine 2251, a modification conserved in the peptidyltransferase domain of 23S rRNA. The crystal structure of this 2'O-methyltransferase has been determined at 2.5 A resolution. RlmB consists of an N-terminal domain connected by a flexible extended linker to a catalytic C-terminal domain and forms a dimer in solution. The C-terminal domain displays a divergent methyltransferase fold with a unique knotted region, and lacks the classic AdoMet binding site features. The N-terminal domain is similar to ribosomal proteins L7 and L30, suggesting a role in 23S rRNA recognition. The conserved residues in this novel family of 2'O-methyltransferases cluster in the knotted region, suggesting the location of the catalytic and AdoMet binding sites.     

Structural and functional analysis of methylation and 5'-RNA sequence requirements of short capped RNAs by the methyltransferase domain of dengue virus NS5

The N-terminal 33 kDa domain of non-structural protein 5 (NS5) of dengue virus (DV), named NS5MTase(DV), is involved in two of four steps required for the formation of the viral mRNA cap (7Me)GpppA(2'OMe), the guanine-N7 and the adenosine-2'O methylation. Its S-adenosyl-l-methionine (AdoMet) dependent 2'O-methyltransferase (MTase) activity has been shown on capped (7Me+/-)GpppAC(n) RNAs. Here we report structural and binding studies using cap analogues and capped RNAs. We have solved five crystal structures at 1.8 A to 2.8 A resolution of NS5MTase(DV) in complex with cap analogues and the co-product of methylation S-adenosyl-l-homocysteine (AdoHcy). The cap analogues can adopt several conformations. The guanosine moiety of all cap analogues occupies a GTP-binding site identified earlier, indicating that GTP and cap share the same binding site. Accordingly, we show that binding of (7Me)GpppAC(4) and (7Me)GpppAC(5) RNAs is inhibited in the presence of GTP, (7Me)GTP and (7Me)GpppA but not by ATP. This particular position of the cap is in accordance with the 2'O-methylation step. A model was generated of a ternary 2'O-methylation complex of NS5MTase(DV), (7Me)GpppA and AdoMet. RNA-binding increased when (7Me+/-)GpppAGC(n-1) starting with the consensus sequence GpppAG, was used instead of (7Me+/-)GpppAC(n). In the NS5MTase(DV)-GpppA complex the cap analogue adopts a folded, stacked conformation uniquely possible when adenine is the first transcribed nucleotide at the 5' end of nascent RNA, as it is the case in all flaviviruses. This conformation cannot be a functional intermediate of methylation, since both the guanine-N7 and adenosine-2'O positions are too far away from AdoMet. We hypothesize that this conformation mimics the reaction product of a yet-to-be-demonstrated guanylyltransferase activity. A putative Flavivirus RNA capping pathway is proposed combining the different steps where the NS5MTase domain is involved.     

Characterization of the Staphylococcus aureus rRNA Methyltransferase Encoded by orfX,the Gene Containing the Staphylococcal Chromosome Cassette mec (SCCmec) Insertion Site

The gene orfX is conserved among all staphylococci, and its complete sequence is maintained upon insertion of the staphylococcal chromosome cassette mec (SCCmec) genomic island, containing the gene encoding resistance to β-lactam antibiotics (mecA), into its C terminus. The function of OrfX has not been determined. We show that OrfX was constitutively produced during growth, that orfX could be inactivated without altering bacterial growth, and that insertion of SCCmec did not alter gene expression. We solved the crystal structure of OrfX at 1.7 Å and found that it belongs to the S-adenosyl-l-methionine (AdoMet)-dependent α/β-knot superfamily of SPOUT methyltransferases (MTases), with a high structural homology to YbeA, the gene product of the Escherichia coli 70 S ribosomal MTase RlmH. MTase activity was confirmed by demonstrating the OrfX-dependent methylation of the Staphylococcus aureus 70 S ribosome. When OrfX was crystallized in the presence of its AdoMet substrate, we found that each monomer of the homodimeric structure bound AdoMet in its active site. Solution studies using isothermal titration calorimetry confirmed that each monomer bound AdoMet but with different binding affinities (K_d = 52 ± 0.4 and 606 ± 2 μm). In addition, the structure shows that the AdoMet-binding pocket, formed by a deep trefoil knot, contains a bound phosphate molecule, which is the likely nucleotide methylation site. This study represents the first characterization of a staphylococcal ribosomal MTase and provides the first crystal structure of a member of the α/β-knot superfamily of SPOUT MTases in the RlmH or COG1576 family with bound AdoMet.     

Initiation factor 3-induced structural changes in the 30 S ribosomal subunit and in complexes containing tRNA(f)(Met) and mRNA

Initiation factor 3 (IF3) acts to switch the decoding preference of the small ribosomal subunit from elongator to initiator tRNA. The effects of IF3 on the 30 S ribosomal subunit and on the 30 S.mRNA. tRNA(f)(Met) complex were determined by UV-induced RNA crosslinking. Three intramolecular crosslinks in the 16 S rRNA (of the 14 that were monitored by gel electrophoresis) are affected by IF3. These are the crosslinks between C1402 and C1501 within the decoding region, between C967xC1400 joining the end loop of a helix of 16 S rRNA domain III and the decoding region, and between U793 and G1517 joining the 790 end loop of 16 S rRNA domain II and the end loop of the terminal helix. These changes occur even in the 30 S.IF3 complex, indicating they are not mediated through tRNA(f)(Met) or mRNA. UV-induced crosslinks occur between 16 S rRNA position C1400 and tRNA(f)(Met) position U34, in tRNA(f)(Met) the nucleotide adjacent to the 5' anticodon nucleotide, and between 16 S rRNA position C1397 and the mRNA at positions +9 and +10 (where A of the initiator AUG codon is +1). The presence of IF3 reduces both of these crosslinks by twofold and fourfold, respectively. The binding site for IF3 involves the 790 region, some other parts of the 16 S rRNA domain II and the terminal stem/loop region. These are located in the front bottom part of the platform structure in the 30 S subunit, a short distance from the decoding region. The changes that occur in the decoding region, even in the absence of mRNA and tRNA, may be induced by IF3 from a short distance or could be caused by the second IF3 structural domain.     

The first structure of an RNA m5C methyltransferase, Fmu, provides insight into catalytic mechanism and specific binding of RNA substrate

The crystal structure of E. coli Fmu, determined at 1.65 A resolution for the apoenzyme and 2.1 A resolution in complex with AdoMet, is the first representative of the 5-methylcytosine RNA methyltransferase family that includes the human nucleolar proliferation-associated protein p120. Fmu contains three subdomains which share structural homology to DNA m(5)C methyltransferases and two RNA binding protein families. In the binary complex, the AdoMet cofactor is positioned within the active site near a novel arrangement of two conserved cysteines that function in cytosine methylation. The site is surrounded by a positively charged cleft large enough to bind its unique target stem loop within 16S rRNA. Docking of this stem loop RNA into the structure followed by molecular mechanics shows that the Fmu structure is consistent with binding to the folded RNA substrate.     

G1401: a keystone nucleotide at the decoding site of Escherichia coli 30S ribosomes.

16S ribosomal RNA contains three highly conserved single-stranded regions. Centrally located in one of these regions is the C1400 residue. Zero-length cross-linking of this residue to the anticodon of ribosome-bound tRNA showed that it was at or near the ribosomal decoding site [Ehresmann, C., Ehresmann, B., Millon, R., Ebel, J-P., Nurse, K., & Ofengand, J. (1984) Biochemistry 23, 429-437]. To assess the functional significance of sequence conservation of rRNA in the vicinity of this functionally important site, a series of site-directed mutations in this region were constructed and the effects of these mutations on the partial reactions of protein synthesis determined. Mutation of C1400 or C1402 to any other base only moderately affected a set of in vitro protein synthesis partial reactions. However, any base change from the normal G1401 residue blocked all of the tested ribosomal functions. This was also true for the deletion of G1401. Deletion of C1400 or C1402 had more complex effects. Whereas subunit association was hardly affected, 30S initiation complex formation was blocked by deletion of C1400 but much less so by deletion of C1402. Alternatively, tRNA binding to the ribosomal A site was more strongly affected by deletion of C1402 than by deletion of C1400. P site binding was inhibited by either deletion. HPLC analysis of the in vitro reconstituted mutant ribosomes showed that none of the functional effects were due to the absence or gross reduction in amount of any ribosomal protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

In silico identification, structure prediction and phylogenetic analysis of the 2'-O-ribose (cap 1) methyltransferase domain in the large structural protein of ssRNA negative-strand viruses

The Escherichia coli RrmJ gene product has recently been shown to be the 23S rRNA:U2552 specific 2'-O-ribose methyltransferase (MTase) (RrmJ). Its structure has been solved and refined to 1.5 A resolution, demonstrating conservation of the three-dimensional fold and key catalytic side chains with the vaccinia virus VP39 protein, which functions as an mRNA 5'm(7)G-cap-N-specific 2'-O-ribose MTase. Using the amino acid sequence of RrmJ as an initial probe in an iterative search of sequence databases, we identified a homologous domain in the sequence of the L protein of non-segmented, negative-sense, single-stranded RNA viruses. The plausibility of the prediction was confirmed by homology modeling and checking whether important residues at substrate/ligand-binding sites were conserved. The predicted structural compatibility and the conservation of the active site between the novel putative MTase domain and genuine 2'-O-ribose MTases, together with the available results of biochemical studies, strongly suggest that this domain is a 5'm(7)G-cap-N-specific 2'-O-ribose MTase (i.e. the cap 1 MTase). Evolutionary relationships between these proteins are also discussed.     

Crystal structure of Bacillus subtilis guanine deaminase: the first domain-swapped structure in the cytidine deaminase superfamily

Guanine deaminase, a key enzyme in the nucleotide metabolism, catalyzes the hydrolytic deamination of guanine into xanthine. The crystal structure of the 156-residue guanine deaminase from Bacillus subtilis has been solved at 1.17-A resolution. Unexpectedly, the C-terminal segment is swapped to form an intersubunit active site and an intertwined dimer with an extensive interface of 3900 A(2) per monomer. The essential zinc ion is ligated by a water molecule together with His(53), Cys(83), and Cys(86). A transition state analog was modeled into the active site cavity based on the tightly bound imidazole and water molecules, allowing identification of the conserved deamination mechanism and specific substrate recognition by Asp(114) and Tyr(156'). The closed conformation also reveals that substrate binding seals the active site entrance, which is controlled by the C-terminal tail. Therefore, the domain swapping has not only facilitated the dimerization but has also ensured specific substrate recognition. Finally, a detailed structural comparison of the cytidine deaminase superfamily illustrates the functional versatility of the divergent active sites found in the guanine, cytosine, and cytidine deaminases and suggests putative specific substrate-interacting residues for other members such as dCMP deaminases.     

Kinetic and catalytic properties of dimeric KpnI DNA methyltransferase

KpnI DNA-(N(6)-adenine)-methyltransferase (KpnI MTase) is a member of a restriction-modification (R-M) system in Klebsiella pneumoniae and recognizes the sequence 5'-GGTACC-3'. It modifies the recognition sequence by transferring the methyl group from S-adenosyl-l-methionine (AdoMet) to the N(6) position of adenine residue. KpnI MTase occurs as a dimer in solution as shown by gel filtration and chemical cross-linking analysis. The nonlinear dependence of methylation activity on enzyme concentration indicates that the functionally active form of the enzyme is also a dimer. Product inhibition studies with KpnI MTase showed that S-adenosyl-l-homocysteine is a competitive inhibitor with respect to AdoMet and noncompetitive inhibitor with respect to DNA. The methylated DNA showed noncompetitive inhibition with respect to both DNA and AdoMet. A reduction in the rate of methylation was observed at high concentrations of duplex DNA. The kinetic analysis where AdoMet binds first followed by DNA, supports an ordered bi bi mechanism. After methyl transfer, methylated DNA dissociates followed by S-adenosyl-l-homocysteine. Isotope-partitioning analysis showed that KpnI MTase-AdoMet complex is catalytically active.     

Functional analysis of amino acid residues at the dimerisation interface of KpnI DNA methyltransferase

KpnI DNA-(N6-adenine) methyltransferase (M.KpnI) recognises the sequence 5'-GGTACC-3' and transfers the methyl group from S-adenosyl-L-methionine (AdoMet) to the N6 position of the adenine residue in each strand. Earlier studies have shown that M.KpnI exists as a dimer in solution, unlike most other MTases. To address the importance of dimerisation for enzyme function, a three-dimensional model of M.KpnI was obtained based on protein fold-recognition analysis, using the crystal structures of M.RsrI and M.MboIIA as templates. Residues I146, I161 and Y167, the side chains of which are present in the putative dimerisation interface in the model, were targeted for site-directed mutagenesis. Methylation and in vitro restriction assays showed that the mutant MTases are catalytically inactive. Mutation at the I146 position resulted in complete disruption of the dimer. The replacement of I146 led to drastically reduced DNA and cofactor binding. Substitution of I161 resulted in weakening of the interaction between monomers, leading to both monomeric and dimeric species. Steady-state fluorescence measurements showed that the wild-type KpnI MTase induces structural distortion in bound DNA, while the mutant MTases do not. The results establish that monomeric MTase is catalytically inactive and that dimerisation is an essential event for M.KpnI to catalyse the methyl transfer reaction.     

Crystal structure of Streptococcus pneumoniae Sp1610, a putative tRNA methyltransferase,in complex with S‐adenosyl‐L‐methionine

Streptococcus pneumoniae Sp1610, a Class‐I fold S‐adenosylmethionine (AdoMet)‐dependent methyltransferase, is a member of the COG2384 family in the Clusters of Orthologous Groups database, which catalyzes the methylation of N¹‐adenosine at position 22 of bacterial tRNA. We determined the crystal structure of Sp1610 in the ligand‐free and the AdoMet‐bound forms at resolutions of 2.0 and 3.0 Å, respectively. The protein is organized into two structural domains: the N‐terminal catalytic domain with a Class I AdoMet‐dependent methyltransferase fold, and the C‐terminal substrate recognition domain with a novel fold of four α‐helices. Observations of the electrostatic potential surface revealed that the concave surface located near the AdoMet binding pocket was predominantly positively charged, and thus this was predicted to be an RNA binding area. Based on the results of sequence alignment and structural analysis, the putative catalytic residues responsible for substrate recognition are also proposed.     

Ribosomal protein L1 recognizes the same specific structural motif in its target sites on the autoregulatory mRNA and 23S rRNA

The RNA-binding ability of ribosomal protein L1 is of profound interest since the protein has a dual function as a ribosomal protein binding rRNA and as a translational repressor binding its mRNA. Here, we report the crystal structure of ribosomal protein L1 in complex with a specific fragment of its mRNA and compare it with the structure of L1 in complex with a specific fragment of 23S rRNA determined earlier. In both complexes, a strongly conserved RNA structural motif is involved in L1 binding through a conserved network of RNA–protein H-bonds inaccessible to the solvent. These interactions should be responsible for specific recognition between the protein and RNA. A large number of additional non-conserved RNA–protein H-bonds stabilizes both complexes. The added contribution of these non-conserved H-bonds makes the ribosomal complex much more stable than the regulatory one.     

Mutational analysis of the conserved bases C1402 and A1500 in the center of the decoding domain of Escherichia coli 16 S rRNA reveals an important tertiary interaction

Interactions within the decoding center of the 30 S ribosomal subunit have been investigated by constructing all 15 possible mutations at nucleotides C1402 and A1500 in helix 44 of 16 S rRNA. As expected, most of the mutations resulted in highly deleterious phenotypes, consistent with the high degree of conservation of this region and its functional importance. A total of seven mutants were viable under conditions where the mutant ribosomes comprised 100 % of the ribosomal pool. A suppressor mutation specific for the C1402U-A1500G mutant was isolated at position 1520 in helix 45 of 16 S rRNA. In addition, lack of dimethylation of A1518/A1519 caused by mutation of the ksgA methylase enhanced the deleterious effect of many of the 1402/1500 mutations. These data suggest that a higher-order interaction between helices 44 and 45 in 16 S rRNA is important for the proper functioning of the ribosome. This is consistent with the recent high-resolution crystal structures of the 30 S subunit, which show a tertiary interaction between the 1402/1500 region of helix 44 and the dimethyl A stem loop.     

Structure of the Thiostrepton Resistance Methyltransferase��S-Adenosyl-l-methionine Complex and Its Interaction with Ribosomal RNA

The x-ray crystal structure of the thiostrepton resistance RNA methyltransferase (Tsr)·S-adenosyl-l-methionine (AdoMet) complex was determined at 2.45-Å resolution. Tsr is definitively confirmed as a Class IV methyltransferase of the SpoU family with an N-terminal “L30-like” putative target recognition domain. The structure and our in vitro analysis of the interaction of Tsr with its target domain from 23 S ribosomal RNA (rRNA) demonstrate that the active biological unit is a Tsr homodimer. In vitro methylation assays show that Tsr activity is optimal against a 29-nucleotide hairpin rRNA though the full 58-nucleotide L11-binding domain and intact 23 S rRNA are also effective substrates. Molecular docking experiments predict that Tsr·rRNA binding is dictated entirely by the sequence and structure of the rRNA hairpin containing the A1067 target nucleotide and is most likely driven primarily by large complementary electrostatic surfaces. One L30-like domain is predicted to bind the target loop and the other is near an internal loop more distant from the target site where a nucleotide change (U1061 to A) also decreases methylation by Tsr. Furthermore, a predicted interaction with this internal loop by Tsr amino acid Phe-88 was confirmed by mutagenesis and RNA binding experiments. We therefore propose that Tsr achieves its absolute target specificity using the N-terminal domains of each monomer in combination to recognize the two distinct structural elements of the target rRNA hairpin such that both Tsr subunits contribute directly to the positioning of the target nucleotide on the enzyme.RNA modifications and the enzymes that catalyze their formation are critical for cellular viability. Certain RNA modifications are extremely well characterized, such as CCA addition and amino acylation of the 3′-ends of tRNA, and the contributions of some nucleotide modifications to the creation of specific functional tRNA structures (1–3). Although the single most common nucleotide modification is pseudouridine, by far the most abundant type of RNA chemical modification is methylation (4). A vast array of unique mono-, di-, and trimethylations of each RNA base and/or ribose sugar 2′-OH is possible, and important new functions for these modifications continue to emerge. In ribosomal RNA (rRNA),² for example, modifications cluster in functionally critical regions where methylation may act as a checkpoint in ribosome subunit assembly (5), influence the process of translation (6), and alter resistance to certain antibiotics (7, 8).RNA methylation is catalyzed by members of two classes (I and IV) of S-adenosyl-l-methionine (AdoMet)-dependent RNA methyltransferase (MTase) enzymes (9). In bacteria, rRNA methylations are incorporated by both “housekeeping” MTases and those that confer resistance to antibiotics. Although members of the former group are often highly conserved, the latter are generally only found in the antibiotic-producing strain as one mechanism of defense against self-intoxication (10). However, several instances of antibiotic resistance MTase genes in non-producer strains, including pathogenic bacteria, have been identified, and it is clear that these genes are mobile resistance determinants, usually obtained by lateral gene transfer.Several classes of antibiotics target the conserved centers on the ribosome, altering or blocking critical steps in translation such as decoding and peptidyl transfer, to exert their bactericidal effect (11). RNA MTases have been identified as clinically significant resistance determinants to a number of these, including the aminoglycoside (Arm MTase) and erythromycin (Erm MTase) antibiotics (12, 13). Another functionally critical ribosome domain, the factor binding site (or “GTPase” center), is also the target for a family of thiazole-containing peptide antibiotics (14), which includes thiostrepton. These antibiotics have been important biochemical tools for studies of ribosome function but are of limited clinical use due to their poor aqueous solubility. Thiostrepton is, however, used in veterinary medicine, and recent studies suggest it may have application in development of novel antimalarial and anticancer strategies (15, 16). The minimal rRNA sequence for interaction of thiostrepton is a highly conserved, independently folded 58-nucleotide rRNA domain that is also bound by ribosomal protein L11. Resistance to thiostrepton can result from mutations in the N-terminal domain of L11 or its entire absence, whereas mutation of the target nucleoside (A1067) confers far greater resistance (17–19). In the thiostrepton producer Streptomyces azureus the thiostrepton resistance MTase (Tsr) catalyzes the 2′-O-methylation of A1067 resulting in specific and total resistance to thiostrepton (20).Here we present the crystal structure of Tsr in complex with AdoMet. The structure definitively places Tsr into the SpoU/TrmD (SPOUT) family of enzymes and provides the basis for modeling the Tsr·rRNA recognition process.     

Structural analysis of a putative SAM-dependent methyltransferase,YtqB, from Bacillus subtilis

S-adenosyl-l-methionine (SAM)-dependent methyltransferases (MTases) methylate diverse biological molecules using a SAM cofactor. The ytqB gene of Bacillus subtilis encodes a putative MTase and its biological function has never been characterized. To reveal the structural features and the cofactor binding mode of YtqB, we have determined the crystal structures of YtqB alone and in complex with its cofactor, SAM, at 1.9 Å and 2.2 Å resolutions, respectively. YtqB folds into a β-sheet sandwiched by two α-helical layers, and assembles into a dimeric form. Each YtqB monomer contains one SAM binding site, which shapes SAM into a slightly curved conformation and exposes the reactive methyl group of SAM potentially to a substrate. Our comparative structural analysis of YtqB and its homologues indicates that YtqB is a SAM-dependent class I MTase, and provides insights into the substrate binding site of YtqB.     

Fine-tuning of the ribosomal decoding center by conserved methyl-modifications in the Escherichia coli 16S rRNA

In bacterial 16S rRNAs, methylated nucleosides are clustered within the decoding center, and these nucleoside modifications are thought to modulate translational fidelity. The N⁴, 2′-O-dimethylcytidine (m⁴Cm) at position 1402 of the Escherichia coli 16S rRNA directly interacts with the P-site codon of the mRNA. The biogenesis and function of this modification remain unclear. We have identified two previously uncharacterized genes in E. coli that are required for m⁴Cm formation. mraW (renamed rsmH) and yraL (renamed rsmI) encode methyltransferases responsible for the N⁴ and 2′-O-methylations of C1402, respectively. Recombinant RsmH and RsmI proteins employed the 30S subunit (not the 16S rRNA) as a substrate to reconstitute m⁴Cm1402 in the presence of S-adenosylmethionine (Ado-Met) as the methyl donor, suggesting that m⁴Cm1402 is formed at a late step during 30S assembly in the cell. A luciferase reporter assay indicated that the lack of N⁴ methylation of C1402 increased the efficiency of non-AUG initiation and decreased the rate of UGA read-through. These results suggest that m⁴Cm1402 plays a role in fine-tuning the shape and function of the P-site, thus increasing decoding fidelity.