Characterization of the cofactor-binding site in the SPOUT-fold methyltransferases by computational docking of S-adenosylmethionine to three crystal structures

BACKGROUND: There are several evolutionarily unrelated and structurally dissimilar superfamilies of S-adenosylmethionine (AdoMet)-dependent methyltransferases (MTases). A new superfamily (SPOUT) has been recently characterized on a sequence level and three structures of its members (1gz0, 1ipa, and 1k3r) have been solved. However, none of these structures include the cofactor or the substrate. Due to the strong evolutionary divergence and the paucity of experimental information, no confident predictions of protein-ligand and protein-substrate interactions could be made, which hampered the study of sequence-structure-function relationships in the SPOUT superfamily. RESULTS: We used the computational docking program AutoDock to identify the AdoMet-binding site on the surface of three MTase structures. We analyzed the sequence divergence in two distinct lineages of the SPOUT superfamily in the context of surface features and preferred cofactor binding mode to propose specific function for the conserved residues. CONCLUSION: Our docking analysis has confidently predicted the common AdoMet-binding site in three remotely related proteins structures. In the vicinity of the cofactor-binding site, subfamily-conserved grooves were identified on the protein surface, suggesting location of the target-binding/catalytic site. Functionally important residues were inferred and a general reaction mechanism, involving conformational change of a glycine-rich loop, was proposed

Structural and functional insights into tRNA binding and adenosine N1-methylation by an archaeal Trm10 homologue

Purine nucleosides on position 9 of eukaryal and archaeal tRNAs are frequently modified in vivo by the post-transcriptional addition of a methyl group on their N1 atom. The methyltransferase Trm10 is responsible for this modification in both these domains of life. While certain Trm10 orthologues specifically methylate either guanosine or adenosine at position 9 of tRNA, others have a dual specificity. Until now structural information about this enzyme family was only available for the catalytic SPOUT domain of Trm10 proteins that show specificity toward guanosine. Here, we present the first crystal structure of a full length Trm10 orthologue specific for adenosine, revealing next to the catalytic SPOUT domain also N- and C-terminal domains. This structure hence provides crucial insights in the tRNA binding mechanism of this unique monomeric family of SPOUT methyltransferases. Moreover, structural comparison of this adenosine-specific Trm10 orthologue with guanosine-specific Trm10 orthologues suggests that the N1 methylation of adenosine relies on additional catalytic residues.SCOPUS: ar.jinfo:eu-repo/semantics/publishe

Investigations into Streptomyces azureus Thiostrepton-resistance rRNA Methyltransferase and its Cognate Antibiotic

Thiostrepton (TS: TS; C72H85N19O18S5) is a thiazoline antibiotic that is effective against Gram-positive bacteria and the malarial parasite, Plasmodium falciparum. Tight binding of TS to the bacterial L11-23S ribosomal RNA (rRNA) complex of the large 50S ribosomal unit inhibits protein biosynthesis. The TS producing organism, Streptomyces azureus, biosynthesizes thiostrepton-resistance methyltransferase (TSR), an enzyme that uses S-adenosyl-L-methionine (AdoMet) as a methyl donor, to modify the TS target site. Methylation of A1067 (Escherichia coli ribosome numbering) by TSR circumvents TS binding. The S. azureus tsr gene was overexpressed in E. coli and the protein purified for biochemical characterization. Although the recombinant protein was produced in a soluble form, its tendency to aggregate made handling a challenge during the initial stages of establishing a purification protocol. Different purification conditions were screened to generate an isolation protocol that yields milligram quantities of protein with little aggregation and sufficient purity for crystallographic studies. Enzymological characterization of TSR was carried out using an assay to monitor AdoMet-dependent ([methyl-3H]-AdoMet) methylation of the rRNA substrate by liquid scintillation counting. During the optimization of assay, it was found that, although this method is frequently employed, it is very time and labour intensive. A scintillation proximity assay was investigated to evaluate whether it could be a method for collecting kinetic data, and was found that further optimization is required. Comparative sequence analysis of TSR has shown it to be a member of the novel Class IV SpoUT family of AdoMet-dependent MTases. Members of this class possess a non-canonical AdoMet binding site containing a deep trefoil knot. Selected SpoUT family proteins were used as templates to develop a TSR homology model for monomeric and dimeric forms. Validation of the homology models was performed with structural validation servers and the model was then used as the basis of ongoing mutagenesis experiments. The X-ray crystal structure of TSR bound with AdoMet (2.45 Å) was elucidated by our collaborators, Drs. Mark Dunstan and Graeme Conn (University of Manchester). This structure confirms TSR MTase’s membership in the SpoUT MTase family with a deep trefoil knot in the catalytic domain. The AdoMet bound in the crystal structure is in an extended conformation not previously observed in SpoUT MTases. RNA docking simulations revealed some features that may be relevant to binding and recognition of TSR to the L11 binding domain of the RNA substrate. Two structure-activity studies were conducted to investigate the TS-rRNA interaction and TS solubility. Computational analyses of TS conformations, molecular orbitals and dynamics provided insight into the possible modes of TS binding to rRNA. Single-site modification of TS was attempted, targeting the dehydroalanine and dehydrobutyrine residues of the antibiotic. These moieties were modified using the polar thiol, 2-mercaptoethanesulfonic acid (2-MESNA). Similar modifications had been previously used to improve solubility and bioavailability of antibiotics. The resulting analogue was structurally characterized (NMR and mass spectrometry) and showed antimicrobial activity against Bacillus subtilis and Staphylococcus aureus

Structural basis for the methylation of A1408 in 16S rRNA by a panaminoglycoside resistance methyltransferase NpmA from a clinical isolate and analysis of the NpmA interactions with the 30S ribosomal subunit

NpmA, a methyltransferase that confers resistance to aminoglycosides was identified in an Escherichia coli clinical isolate. It belongs to the kanamycin–apramycin methyltransferase (Kam) family and specifically methylates the 16S rRNA at the N1 position of A1408. We determined the structures of apo-NpmA and its complexes with S-adenosylmethionine (AdoMet) and S-adenosylhomocysteine (AdoHcy) at 2.4, 2.7 and 1.68 Å, respectively. We generated a number of NpmA variants with alanine substitutions and studied their ability to bind the cofactor, to methylate A1408 in the 30S subunit, and to confer resistance to kanamycin in vivo. Residues D30, W107 and W197 were found to be essential. We have also analyzed the interactions between NpmA and the 30S subunit by footprinting experiments and computational docking. Helices 24, 42 and 44 were found to be the main NpmA-binding site. Both experimental and theoretical analyses suggest that NpmA flips out the target nucleotide A1408 to carry out the methylation. NpmA is plasmid-encoded and can be transferred between pathogenic bacteria; therefore it poses a threat to the successful use of aminoglycosides in clinical practice. The results presented here will assist in the development of specific NpmA inhibitors that could restore the potential of aminoglycoside antibiotics

Deep Knot Structure for Construction of Active Site and Cofactor Binding Site of tRNA Modification Enzyme

AbstractThe tRNA(Gm18) methyltransferase (TrmH) catalyzes the 2′-O methylation of guanosine 18 (Gua18) of tRNA. We solved the crystal structure of Thermus thermophilus TrmH complexed with S-adenosyl-L-methionine at 1.85 Å resolution. The catalytic domain contains a deep trefoil knot, which mutational analyses revealed to be crucial for the formation of the catalytic site and the cofactor binding pocket. The tRNA dihydrouridine(D)-arm can be docked onto the dimeric TrmH, so that the tRNA D-stem is clamped by the N- and C-terminal helices from one subunit while the Gua18 is modified by the other subunit. Arg41 from the other subunit enters the catalytic site and forms a hydrogen bond with a bound sulfate ion, an RNA main chain phosphate analog, thus activating its nucleophilic state. Based on Gua18 modeling onto the active site, we propose that once Gua18 binds, the phosphate group activates Arg41, which then deprotonates the 2′-OH group for methylation

Crystal structures of the tRNA:m2G6 methyltransferase Trm14/TrmN from two domains of life

Methyltransferases (MTases) form a major class of tRNA-modifying enzymes needed for the proper functioning of tRNA. Recently, RNA MTases from the TrmN/Trm14 family that are present in Archaea, Bacteria and Eukaryota have been shown to specifically modify tRNAPhe at guanosine 6 in the tRNA acceptor stem. Here, we report the first X-ray crystal structures of the tRNA m2G6 (N2-methylguanosine) MTase TTCTrmN from Thermus thermophilus and its ortholog PfTrm14 from Pyrococcus furiosus. Structures of PfTrm14 were solved in complex with the methyl donor S-adenosyl-l-methionine (SAM or AdoMet), as well as the reaction product S-adenosyl-homocysteine (SAH or AdoHcy) and the inhibitor sinefungin. TTCTrmN and PfTrm14 consist of an N-terminal THUMP domain fused to a catalytic Rossmann-fold MTase (RFM) domain. These results represent the first crystallographic structure analysis of proteins containing both THUMP and RFM domain, and hence provide further insight in the contribution of the THUMP domain in tRNA recognition and catalysis. Electrostatics and conservation calculations suggest a main tRNA binding surface in a groove between the THUMP domain and the MTase domain. This is further supported by a docking model of TrmN in complex with tRNAPhe of T. thermophilus and via site-directed mutagenesis

DYNAMICS OF SUBSTRATE INTERACTIONS IN tRNA (m1G37) METHYLTRANSFERASE: IMPLICATIONS FOR DRUG DISCOVERY

The bacterial enzyme t-RNA (m1G37) methyltransferase (TrmD) is an ideal anti-microbial drug target since it is found in all eubacteria, serves an essential role during protein synthesis, and shares very little sequence or structural homology with its eukaryotic counterpart, Trm5. TrmD, a homodimeric protein, methylates the G37 nucleotide of tRNA using S-adenosyl-L-methionine (SAM) as the methyl donor and thus enables proper codon-anticodon alignment during translation. The two deeply buried binding sites for SAM seen in X-ray crystallography suggest that significant conformational changes must occur for substrate binding and catalytic turnover. Results from molecular dynamics simulations implicate a flexible loop region and a halo-like loop which may be gating the entrance to the active site. Analysis of simulation trajectories indicates an alternating pattern of active site accessibility between the two SAM binding sites, suggesting a single site mechanism for enzyme activity. Isothermal titration calorimetry (ITC), demonstrates that binding of SAM to TrmD is an exothermic reaction resulting from sequential binding at two sites. A similar mode of binding at higher affinities was observed for the product, S-adenosyl-L-homocysteine (SAH) suggesting that product inhibition may be important in vivo. ITC reveals that tRNA binding is an endothermic reaction in which one tRNA molecule binds to one TrmD dimer. This further supports the hypothesis of a single site mechanism for enzyme function. However, mutational analysis using hybrid mutant proteins suggests that catalytic integrity must be maintained in both active sites for maximum enzymatic efficiency. Mutations impeding flexibility of the halo loop were particularly detrimental to enzyme activity. Noncompetitive inhibition of TrmD was observed in the presence of bis-ANS, an extrinsic fluorescent dye. In silico ligand docking of bis-ANS to TrmD suggests that dye interferes with mobility of the flexible linker above the active site. Because SAM is a ubiquitous cofactor in methyltransferase reactions, analogs of this ligand may not be suitable for drug development. It is therefore important to investigate allosteric modes of inhibition. These experiments have identified key, mobile structural elements in the TrmD enzyme important for activity, and provide a basis for further research in the development of allosteric inhibitors for this enzyme

Structural insight into the assembly of iron-sulfur clusters and their function in radical generation

Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Chemistry, 2008.Vita.Includes bibliographical references.This thesis addresses two emerging areas in the study of iron-sulfur cluster biochemistry: bioassembly of iron-sulfur clusters, and their involvement in initiation of radical chemistry. The structure of a cysteine desulfurase involved in cluster bioassembly in the cyanobacterium Synechocystis PCC sp. 6803 was solved by X-ray crystallography and analyzed in terms of its mechanistic implications. We found that the active site cysteine responsible for the direct removal of sulfur from substrate cysteine is located on a short, well-ordered loop, consistent with structures solved of homologous proteins. The length of this loop is thought to restrain the active site cysteine, interfering with its ability to affect catalysis. Our results are consistent with the theory that this cysteine desulfurase requires an accessory protein for fully activity in vivo. Two structures of pyruvate formate-lyase activating enzyme from Escherichia coli, an Sadenosylmethionine radical enzyme, were also solved by X-ray crystallography, providing the first structure of an activase from this family of enzymes. These structures revealed the enzyme's active site and the residues involved in binding and orienting substrate for hydrogen atom abstraction. Comparison of the structures of the substrate-free and substrate-bound forms of the enzyme identified a conformational change associated with substrate binding. Detailed analyses of the structure of pyruvate formatelyase activating enzyme were carried out to provide insight into catalysis. These structures were also analyzed in comparison with other S-adenosylmethionine radical enzyme structures to more clearly understand the structural basis for reactivity in this superfamily.by Jessica L. Vey.Ph.D

Genes and proteins involved in RNA modification: evolutionary genomic context and characterization of YibK and GidB Methyltransferases

Tesis doctoral inédita. Universidad Autónoma de Madrid, Facultad de Ciencias, Departamento de Biología Molecular. Fecha de lectura: 22-06-2010Bibliogr.: p.97-11

Methylation at position 32 of tRNA catalyzed by TrmJ alters oxidative stress response in Pseudomonas aeruginosa

Bacteria respond to environmental stresses using a variety of signaling and gene expression pathways, with translational mechanisms being the least well understood. Here, we identified a tRNA methyltransferase in Pseudomonas aeruginosa PA14, trmJ, which confers resistance to oxidative stress. Analysis of tRNA from a trmJ mutant revealed that TrmJ catalyzes formation of Cm, Um, and, unexpectedly, Am. Defined in vitro analyses revealed that tRNA[superscript Met(CAU)] and tRNA[superscript Trp(CCA)] are substrates for Cm formation, tRNA[superscript Gln(UUG)], tRNA[superscript Pro(UGG)], tRNA[superscript Pro(CGG)] and tRNA[superscript His(GUG)] for Um, and tRNA[superscript Pro(GGG)] for Am. tRNA[superscript Ser(UGA)], previously observed as a TrmJ substrate in Escherichia coli, was not modified by PA14 TrmJ. Position 32 was confirmed as the TrmJ target for Am in tRNA[superscriptPro(GGG)] and Um in tRNA[superscript Gln(UUG)] by mass spectrometric analysis. Crystal structures of the free catalytic N-terminal domain of TrmJ show a 2-fold symmetrical dimer with an active site located at the interface between the monomers and a flexible basic loop positioned to bind tRNA, with conformational changes upon binding of the SAM-analog sinefungin. The loss of TrmJ rendered PA14 sensitive to H2O2 exposure, with reduced expression of oxyR-recG, katB-ankB, and katE. These results reveal that TrmJ is a tRNA:Cm32/Um32/Am32 methyltransferase involved in translational fidelity and the oxidative stress response.National Science Foundation (U.S.) (CHE-1308839)Agilent TechnologiesSingapore-MIT Alliance for Research and Technology (SMART