A mutational analysis of the two motifs common to adenine methyltransferases.

All methyltransferases that use S-adenosyl methionine as the methyl group donor contain a sequence similar to (D/E/S)XFXGXG which has been postulated to form part of the cofactor binding site. In N6-adenine DNA methyltransferases there is a second motif, (D/N)PP(Y/F), which has been proposed to play a role similar to the catalytically essential PC motif conserved in all C5-cytosine DNA methyltransferases. We have made a series of amino acid changes in these two motifs in the EcoKI N6-adenine DNA methyltransferase. The mutant enzymes have been purified to homogeneity and characterized by physical biochemical methods. The first G is the most conserved residue in motif I. Changing this G to D completely abolished S-adenosyl methionine binding, but left enzyme structure and DNA target recognition unaltered, thus documenting the S-adenosyl methionine binding function of motif I in N6-adenine methyltransferases. Substitution of the N with D, or F with either G or C, in motif II abolished enzyme activity, but left S-adenosyl methionine and DNA binding unaltered. Changes of F to Y or W resulted in partial enzyme activity, implying that an aromatic residue is important for methylation. The substitution of W for F greatly enhanced UV-induced cross-linking between the enzyme and S-adenosyl methionine, suggesting that the aromatic residue is close in space to the methyl-group donor.     

The adenosine dimethyltransferase KsgA recognizes a specific conformational state of the 30S ribosomal subunit

The methyltransferase KsgA modifies two adjacent adenosines in 16S rRNA by adding two methyl groups to the N(6) position of each nucleotide. Unlike nearly all other rRNA modifications, these modifications and the responsible enzyme are highly conserved phylogenetically, suggesting that the modification system has an important role in ribosome biogenesis. It has been known for some time that KsgA recognizes a complex pre-30S substrate in vitro, but there is disagreement in the literature as to what that substrate can be. That disagreement is resolved in this report; KsgA is unable to methylate 30S subunits in the translationally active conformation, but rather can modify 30S when in an experimentally well established translationally inactive conformation. Recent 30S crystal structures provide some basis for explaining why it is impossible for KsgA to methylate 30S in the translationally active conformation. Previous work identified one set of ribosomal proteins important for efficient methylation by KsgA and another set refractory methylation. With the exception of S21 the recent crystal structures of 30S also instructs that the proteins important for KsgA activity all exert their influence indirectly. Unfortunately, S21, which is inhibitory to KsgA activity, has not had its position determined by X-ray crystallography. A reevaluation of published biophysical data on the location also suggests that the refractory nature of S21 is also indirect. Therefore, it appears that KsgA solely senses the conformation 16S rRNA when carrying out its enzymatic activity.     

Identification of the binding site for the extrahelical target base in N6-adenine DNA methyltransferases by photo-cross-linking with duplex oligodeoxyribonucleotides containing 5-iodouracil at the target position.

DNA methyltransferases flip their target bases out of the DNA double helix for catalysis. Base flipping of C5-cytosine DNA methyltransferases was directly observed in the protein-DNA cocrystal structures of M.HhaI and M.HaeIII. Indirect structural evidence for base flipping of N6-adenine and N4-cytosine DNA methyltransferases was obtained by modeling DNA into the three-dimensional structures of M.TaqI and M.PvuII in complex with the cofactor. In addition, biochemical evidence of base flipping was reported for different N6-adenine DNA methyltransferases. As no protein-DNA cocrystal structure for the related N6-adenine and N4-cytosine DNA methyltransferases is available, we used light-induced photochemical cross-linking to identify the binding site of the extrahelical target bases. The N6-adenine DNA methyltransferases M.TaqI and M.CviBIII, which both methylate adenine within the double-stranded 5'-TCGA-3' DNA sequence, were photo-cross-linked to duplex oligodeoxyribonucleotides containing 5-iodouracil at the target position in 50-60% and almost quantitative yield, respectively. Proteolytic fragmentation of the M. CviBIII-DNA complex followed by Edman degradation and electrospray ionization mass spectrometry indicates photo-cross-linking to tyrosine 122. In addition, the mutant methyltransferases M. TaqI/Y108A and M.TaqI/F196A were photo-cross-linked with 6-fold and 2-fold reduced efficiency, respectively, which suggests that tyrosine 108 is the primary site of modification in M.TaqI. Our results indicate a close proximity between the extrahelical target base and tyrosine 122 in M.CviBIII or tyrosine 108 in M.TaqI. As both residues belong to the conserved motif IV ((N/D/S)(P/I)P(Y/F/W)) found in all N6-adenine and N4-cytosine DNA as well as in N6-adenine RNA methyltransferases, a similar spatial relationship between the target bases and the aromatic amino acid residue within motif IV is expected for all these methyltransferases.     

Structural insights into methyltransferase KsgA function in 30S ribosomal subunit biogenesis

The assembly of the ribosomal subunits is facilitated by ribosome biogenesis factors. The universally conserved methyltransferase KsgA modifies two adjacent adenosine residues in the 3'-terminal helix 45 of the 16 S ribosomal RNA (rRNA). KsgA recognizes its substrate adenosine residues only in the context of a near mature 30S subunit and is required for the efficient processing of the rRNA termini during ribosome biogenesis. Here, we present the cryo-EM structure of KsgA bound to a nonmethylated 30S ribosomal subunit. The structure reveals that KsgA binds to the 30S platform with the catalytic N-terminal domain interacting with substrate adenosine residues in helix 45 and the C-terminal domain making extensive contacts to helix 27 and helix 24. KsgA excludes the penultimate rRNA helix 44 from adopting its position in the mature 30S subunit, blocking the formation of the decoding site and subunit joining. We suggest that the activation of methyltransferase activity and subsequent dissociation of KsgA control conformational changes in helix 44 required for final rRNA processing and translation initiation.     

Structures along the catalytic pathway of PrmC/HemK,an N5-glutamine AdoMet-dependent methyltransferase

Posttranslational methylation of release factors on the glutamine residue of a conserved GGQ motif is required for efficient termination of protein synthesis. This methylation is performed by an N(5)-glutamine methyltransferase called PrmC/HemK, whose crystal structure we report here at 2.2 A resolution. The electron density at the active site appears to contain a mixture of the substrates, S-adenosyl-L-methionine (AdoMet) and glutamine, and the products, S-adenosyl-L-homocysteine (AdoHcy) and N(5)-methylglutamine. The C-terminal domain of PrmC adopts the canonical AdoMet-dependent methyltransferase fold and shares structural similarity with the nucleotide N-methyltransferases in the active site, including use of a conserved (D/N)PPY motif to select and position the glutamine substrate. Residues of the PrmC (197)NPPY(200) motif form hydrogen bonds that position the planar Gln side chain such that the lone-pair electrons on the nitrogen nucleophile are oriented toward the methyl group of AdoMet. In the product complex, the methyl group remains pointing toward the sulfur, consistent with either an sp(3)-hybridized, positively charged Gln nitrogen, or a neutral sp(2)-hybridized nitrogen in a strained conformation. Due to steric overlap within the active site, proton loss and formation of the neutral planar methylamide product are likely to occur during or after product release. These structures, therefore, represent intermediates along the catalytic pathway of PrmC and show how the (D/N)PPY motif can be used to select a wide variety substrates.     

Methyldeficient mammalian 4S RNA: evidence for L-ethionine-induced inhibition of N6-dimethyladenosine synthesis in rat liver tRNA

The nucleotide composition of 4s RNA from livers of rats fed with a diet containing 0.3% D-ethionine was found to be identical with that from untreated animals. In contrast, one single modified nucleotide was absent in 4s RNA from livers of rats fed with a 0.3% L-ethionine diet. The minor nucleo=tide was also absent in liver 4s RNA from rats fed with a 0.3% L-ethionine diet followed by ten days of normal food. It was identified after dephosphorylation by ultraviolet absorption spectra, cochromatography with authentic material and mass spectra as N(6)-dimethyladenosine. It is concluded that S-adenosylethionine, the primary product of L-ethionine in the liver, causes strong and selective inhibition of the specific RNA-methylase responsible for adenosine to N(6)-dimethyl=adenosine methylation in rat liver 4s RNA. Compared to the strong inhibition of N(6)-dimethyladenosine formation described here, L-ethionine-dependent ethylation of liver 4s RNA is far less efficient. The quantitation of l-methyladenosine, ribothymidine and 3'-terminal adenosine in this 4s RNA as well as its aminoacid acceptor activity is typical for tRNA; hence it may be concluded that N(6)-dimethyladenosine is a component of rat liver tRNA. This may demonstrate the first evidence for the existence of specifically methyl-deficient mammalian tRNA. A possible correlation between the activity of L-ethionine as a liver carcinogen and its ability to induce the formation of methyl-deficient tRNA by selectively inhibiting the synthesis of N(6)-dimethyladenosine on the tRNA level in the same organ is discussed.     

Structure of the N6-adenine DNA methyltransferase M.TaqI in complex with DNA and a cofactor analog

The 2.0 A crystal structure of the N6-adenine DNA methyltransferase M.TaqI in complex with specific DNA and a nonreactive cofactor analog reveals a previously unrecognized stabilization of the extrahelical target base. To catalyze the transfer of the methyl group from the cofactor S-adenosyl-l-methionine to the 6-amino group of adenine within the double-stranded DNA sequence 5'-TCGA-3', the target nucleoside is rotated out of the DNA helix. Stabilization of the extrahelical conformation is achieved by DNA compression perpendicular to the DNA helix axis at the target base pair position and relocation of the partner base thymine in an interstrand pi-stacked position, where it would sterically overlap with an innerhelical target adenine. The extrahelical target adenine is specifically recognized in the active site, and the 6-amino group of adenine donates two hydrogen bonds to Asn 105 and Pro 106, which both belong to the conserved catalytic motif IV of N6-adenine DNA methyltransferases. These hydrogen bonds appear to increase the partial negative charge of the N6 atom of adenine and activate it for direct nucleophilic attack on the methyl group of the cofactor.     

Structural basis of successive adenosine modifications by the conserved ribosomal methyltransferase KsgA

Biogenesis of ribosomal subunits involves enzymatic modifications of rRNA that fine-tune functionally important regions. The universally conserved prokaryotic dimethyltransferase KsgA sequentially modifies two universally conserved adenosine residues in helix 45 of the small ribosomal subunit rRNA, which is in proximity of the decoding site. Here we present the cryo-EM structure of Escherichia coli KsgA bound to an E. coli 30S at a resolution of 3.1 Å. The high-resolution structure reveals how KsgA recognizes immature rRNA and binds helix 45 in a conformation where one of the substrate nucleotides is flipped-out into the active site. We suggest that successive processing of two adjacent nucleotides involves base-flipping of the rRNA, which allows modification of the second substrate nucleotide without dissociation of the enzyme. Since KsgA is homologous to the essential eukaryotic methyltransferase Dim1 involved in 40S maturation, these results have also implications for understanding eukaryotic ribosome maturation.     

RNA methyltransferases utilize two cysteine residues in the formation of 5-methylcytosine

Proteins that have sequence homology with known RNA m(5)C methyltransferases contain two conserved cysteines, each of which lies within a sequence that bears similarity to a methyltransferase active site. Other enzymes that transfer a methyl group to carbon 5 of a pyrimidine nucleotide, such as the bacterial DNA m(5)C methyltransferases, utilize their single conserved cysteine residue to form a covalent Michael adduct with carbon 6 of the pyrimidine ring during catalysis. We present a model for the utilization of two cysteines in catalysis by RNA m(5)C methyltransferases. It is proposed that one thiol acts in a classical fashion by forming a covalent link to carbon 6 of the pyrimidine base, while the other cysteine assists breakdown of the covalent adduct. Therefore, alteration of the assisting cysteine is anticipated to stabilize the covalent enzyme-RNA intermediate. The model was conceived as a possible explanation for the effects of mutations that change the conserved cysteines in Nop2p, an apparent RNA m(5)C methyltransferase that is essential for ribosome assembly and yeast viability. Evidence for the predicted accumulation of protein-RNA complexes following mutation of the assisting cysteine has been obtained with Nop2p and a known tRNA m(5)C methyltransferase called Ncl1p (Trm4).     

Investigation of the molecular origins of protein-arginine methyltransferase I (PRMT1) product specificity reveals a role for two conserved methionine residues

Protein-arginine methyltransferases aid in the regulation of many biological processes by methylating specific arginyl groups within targeted proteins. The varied nature of the response to methylation is due in part to the diverse product specificity displayed by the protein-arginine methyltransferases. In addition to site location within a protein, biological response is also determined by the degree (mono-/dimethylation) and type of arginine dimethylation (asymmetric/symmetric). Here, we have identified two strictly conserved methionine residues in the PRMT1 active site that are not only important for activity but also control substrate specificity. Mutation of Met-155 or Met-48 results in a loss in activity and a change in distribution of mono- and dimethylated products. The altered substrate specificity of M155A and M48L mutants is also evidenced by automethylation. Investigation into the mechanistic basis of altered substrate recognition led us to consider each methyl transfer step separately. Single turnover experiments reveal that the rate of transfer of the second methyl group is much slower than transfer of the first methyl group in M48L, especially for arginine residues located in the center of the peptide substrate where turnover of the monomethylated species is negligible. Thus, altered product specificity in M48L originates from the differential effect of the mutation on the two rates. Characterization of the two active-site methionines provides the first insight into how the PRMT1 active site is engineered to control product specificity.     

Evidence for a catalytic Mg2+ ion and effect of phosphate on the activity of Escherichia coli phosphofructokinase-2: regulatory properties of a ribokinase family member

Phosphofructokinase-2 (Pfk-2) from Escherichia coli belongs to the ribokinase family of sugar kinases. One of the signatures observed in amino acid sequences from the ribokinase familiy members is the NXXE motif, which locates at the active site in the ribokinase fold. It has been suggested that the effect of Mg2+ and phosphate ions on enzymatic activity, observed in several adenosine kinases and ribokinases, would be a widespread feature in the ribokinase family, with the conserved amino acid residues in the NXXE motif playing a role in the binding of these ions at the active site [Maj, M. C., et al. (2002) Biochemistry 41, 4059-4069]. In this work we study the effect of Mg2+ and phosphate ions on Pfk-2 activity and the involvement of residue E190 from the NXXE motif in this behavior. The kinetic data are in agreement with the requirement of a Mg2+ ion, besides the one present in the metal-nucleotide complex, for catalysis in the wild-type enzyme. Since the response to free Mg2+ concentration is greatly affected in the E190Q mutant, we conclude that this residue is required for the proper binding of the catalytic Mg2+ ion at the active site. The E190Q mutant presents a 50-fold decrease in the kcat value and a 15-fold increment in the apparent Km for MgATP(2-). Inorganic phosphate, typically considered an activator of adenosine kinases, ribokinases, and phosphofructokinases (nonhomologous to Pfk-2) acted as an inhibitor of wild-type and E190Q mutant Pfk-2. We suggest that phosphate can bind to the allosteric site of Pfk-2, producing an inhibition pattern qualitatively similar to MgATP(2-), which can be reversed to some extent by increasing the concentration of fructose-6-P. Given that the E190Q mutant presents alterations in the inhibition by MgATP(2-) and phosphate, we conclude that the E190 residue has a role not only in catalysis but also in allosteric regulation.     

A simple method of the preparation of 2′-O-Methyladenosine Methylation of adenosine with methyl iodide in anhydrous alkaline medium

A simple and effective method of the methylation on the 2′-O position of adenosine is described. Adenosine is treated with CH₃I in an anhydrous alkaline medium at 0°C for 4 h. The major products of this reaction are monomethylated adenosine at either the 2′-O or 3′-O position (total of 64%) and the side products are dimethylated adenosine (2′,3′-O-dimethyladenosi, 21%, and N⁶-2′-O-dimethyladenosine, 11%). The ratio of 2′-O- and 3′-O-methyladenosine has been found to be 8 to 1. Therefore, this reaction preferentially favors the synthesis of 2′-O-methyladenosine. The monomethylated adenosine is isolated from reaction mixture by a silica gel column chromatography. Then the pure 2′-O-methyladenosine can be separated by crystallization in ethanol from the mixture of 2′-O and 3′-O-methylated isomers. The overall yield of 2′-O-methyladenosine is 42%.     

Pentavalent ions dependency is a conserved property of adenosine kinase from diverse sources: identification of a novel motif implicated in phosphate and magnesium ion binding and substrate inhibition

The catalytic activity of adenosine kinase (AK) from mammalian sources has previously been shown to exhibit a marked dependency upon the presence of pentavalent ions (PVI), such as phosphate (PO4), arsenate, or vanadate. We now show that the activity of AK from diverse sources, including plant, yeast, and protist species, is also markedly enhanced in the presence of PVI. In all cases, PO4 or other PVI exerted their effects primarily by decreasing the Km for adenosine and alleviating the inhibition caused by high concentrations of substrates. These results provide evidence that PVI dependency is a conserved property of AK and perhaps of the PfkB family of carbohydrate kinases which includes AK. On the basis of sequence alignments, we have identified a conserved motif NXXE within the PfkB family. The N and E of this motif make close contacts with Mg2+ and PO4 ions in the crystal structures of AK and bacterial ribokinase (another PfkB member which shows PVI dependency), implicating these residues in their binding. Site-directed mutagenesis of these residues in Chinese hamster AK have resulted in active proteins with greatly altered phosphate stimulation and substrate inhibition characteristics. The N239Q mutation leads to the formation of an active protein whose activity was not stimulated by PO4 or inhibited by high concentrations of adenosine or ATP. The activity of the E242D mutant protein was also not significantly altered in the presence of phosphate. Although PO4 had no effect on the KmAdenosine for this mutant, the KmATP, K(i)Adenosine, and K(i)ATP were significantly decreased. In contrast to these mutations, N239L or E242L mutant proteins showed greatly decreased activity with an altered Mg2+ requirement. These observations support the view that N239 and E242 play an important role in the binding of PO4 and Mg2+ ions required for the catalytic activity of adenosine kinase.     

2��-O Methylation of Internal Adenosine by Flavivirus NS5 Methyltransferase

RNA modification plays an important role in modulating host-pathogen interaction. Flavivirus NS5 protein encodes N-7 and 2′-O methyltransferase activities that are required for the formation of 5′ type I cap (m⁷GpppAm) of viral RNA genome. Here we reported, for the first time, that flavivirus NS5 has a novel internal RNA methylation activity. Recombinant NS5 proteins of West Nile virus and Dengue virus (serotype 4; DENV-4) specifically methylates polyA, but not polyG, polyC, or polyU, indicating that the methylation occurs at adenosine residue. RNAs with internal adenosines substituted with 2′-O-methyladenosines are not active substrates for internal methylation, whereas RNAs with adenosines substituted with N⁶-methyladenosines can be efficiently methylated, suggesting that the internal methylation occurs at the 2′-OH position of adenosine. Mass spectroscopic analysis further demonstrated that the internal methylation product is 2′-O-methyladenosine. Importantly, genomic RNA purified from DENV virion contains 2′-O-methyladenosine. The 2′-O methylation of internal adenosine does not require specific RNA sequence since recombinant methyltransferase of DENV-4 can efficiently methylate RNAs spanning different regions of viral genome, host ribosomal RNAs, and polyA. Structure-based mutagenesis results indicate that K61-D146-K181-E217 tetrad of DENV-4 methyltransferase forms the active site of internal methylation activity; in addition, distinct residues within the methyl donor (S-adenosyl-L-methionine) pocket, GTP pocket, and RNA-binding site are critical for the internal methylation activity. Functional analysis using flavivirus replicon and genome-length RNAs showed that internal methylation attenuated viral RNA translation and replication. Polymerase assay revealed that internal 2′-O-methyladenosine reduces the efficiency of RNA elongation. Collectively, our results demonstrate that flavivirus NS5 performs 2′-O methylation of internal adenosine of viral RNA in vivo and host ribosomal RNAs in vitro.     

MnlI--The member of H-N-H subtype of Type IIS restriction endonucleases

The Type IIS restriction endonuclease MnlI recognizes the non-palindromic nucleotide sequence 5'-CCTC(N)7/6 downward arrow and cleaves DNA strands as indicated by the arrow. The genes encoding MnlI restriction-modification system were cloned and sequenced. It comprises N6-methyladenine and C5-methylcytosine methyltransferases and the restriction endonuclease. Biochemical studies revealed that MnlI restriction endonuclease cleaves double- and single-stranded DNA, and that it prefers different metal ions for hydrolysis of these substrates. Mg2+ ions were shown to be required for the specific cleavage of double-stranded DNA, whereas Ni2+ and some other transition metal ions were preferred for nonspecific cleavage of single-stranded DNA. The C-terminal part of MnlI restriction endonuclease revealed an intriguing similarity with the H-N-H type nucleolytic domain of bacterial toxins, Colicin E7 and Colicin E9. Alanine replacements in the conserved sequence motif 306Rx3ExHHx14Nx8H greatly reduced specific activity of MnlI, and some mutations even completely inactivated the enzyme. However, none of these mutations had effect on MnlI binding to the specific DNA, and on its oligomerisation state as well. We interpret the presented experimental evidence as a suggestion that the motif 306Rx3ExHHx14Nx8H represents the active site of MnlI. Consequentially, MnlI seems to be the member of Type IIS with the active site of the H-N-H type.     

Characterization of the highly conserved VFMGD motif in a bacterial polyisoprenyl-phosphate N-acetylaminosugar-1-phosphate transferase

Polyisoprenyl-phosphate N-acetylaminosugar-1-phosphate transferases (PNPTs) constitute a family of eukaryotic and prokaryotic membrane proteins that catalyze the transfer of a sugar-1-phosphate to a phosphoisoprenyl lipid carrier. All PNPT members share a highly conserved 213-Valine-Phenylalanine-Methionine-Glycine-Aspartic acid-217 (VFMGD) motif. Previous studies using the MraY protein suggested that the aspartic acid residue in this motif, D267, is a nucleophile for a proposed double-displacement mechanism involving the cleavage of the phosphoanhydride bond of the nucleoside. Here, we demonstrate that the corresponding residue in the E. coli WecA, D217, is not directly involved in catalysis, as its replacement by asparagine results in a more active enzyme. Kinetic data indicate that the D217N replacement leads to more than twofold increase in V(max) without significant change in the K(m) for the nucleoside sugar substrate. Furthermore, no differences in the binding of the reaction intermediate analog tunicamycin were found in D217N as well as in other replacement mutants at the same position. We also found that alanine substitutions in various residues of the VFMGD motif affect to various degrees the enzymatic activity of WecA in vivo and in vitro. Together, our data suggest that the highly conserved VFMGD motif defines a common region in PNPT proteins that contributes to the active site and is likely involved in the release of the reaction product.     

A conserved "hydrophobic staple motif" plays a crucial role in the refolding of human glutathione transferase P1-1

The specific (i, i+5) hydrophobic staple interaction involving a helix residue and a second residue located in the turn preceding the helix is a recurrent motif at the N terminus of alpha-helices. This motif is strictly conserved in the core of all soluble glutathione transferases (GSTs) as well as in other protein structures. Human GSTP1-1 variants mutated in amino acid Ile(149) and Tyr(154) of the hydrophobic staple motif of the alpha6-helix were analyzed. In particular, a double mutant cycle analysis has been performed to evaluate the role of the hydrophobic staple motif in the refolding process. The results show that this local interaction, by restricting the number of conformations of the alpha6-helix relative to the alpha1-helix, favors the formation of essential interdomain interactions and thereby accelerates the folding process. Thus, for the first time it is shown that the hydrophobic staple interaction has a role in the folding process of an intact protein. In P(i) class GSTs, Tyr(154) appears to be of particular structural importance, since it interacts with conserved residues Leu(21), Asp(24), and Gln(25) of the adjacent alpha1-helix which contributes to the active site. Human GSTP1-1 variants L21A and Y154F have also been analyzed in order to distinguish the role of interdomain interactions from that of the hydrophobic staple. The experimental results reported here suggest that the strict conservation of the hydrophobic staple motif reflects an evolutionary pressure for proteins to fold rapidly.