Your search keyword '"Iwata-Reuyl D"' showing total 46 results

1. Mutant E97Q crystal structure of Bacillus subtilis QueF with a disulfide Cys 55-99

Author

Mohammad, A., primary, Kiani, M.K., additional, Iwata-Reuyl, D., additional, Stec, B., additional, and Swairjo, M., additional

Published

2017

2. Exploiting preQ(1) riboswitches to regulate ribosomal frameshifting

Author

Yu, C.H., Luo, J.H., Iwata-Reuyl, D., and Olsthoorn, R.R.C.L.

Published

2013

3. Structure of the E. coli Threonylcarbamoyl-AMP Synthase TSAC

Author

Harris, K.A., primary, Bobay, B.G., additional, Sarachan, K.L., additional, Sims, A.F., additional, Bilbille, Y., additional, Deutsch, C., additional, Iwata-Reuyl, D., additional, and Agris, P.F., additional

Published

2015

4. Hypermodification of tRNA in Thermophilic archaea. Cloning, overexpression, and characterization of tRNA-guanine transglycosylase from Methanococcus jannaschii.

Author

Bai, Y, Fox, D T, Lacy, J A, Van Lanen, S G, and Iwata-Reuyl, D

Abstract

tRNA is structurally unique among nucleic acids in harboring an astonishing diversity of modified nucleosides. Two structural variants of the hypermodified nucleoside 7-deazaguanosine have been identified in tRNA: queuosine, which is found at the wobble position of the anticodon in bacterial and eukaryotic tRNA, and archaeosine, which is found at position 15 of the D-loop in archaeal tRNA. From homology searching of the Methanococcus jannaschii genome, a gene coding for an enzyme in the biosynthesis of archaeosine (tgt) was identified and cloned. The tgt gene was overexpressed in an Escherichia coli expression system, and the recombinant tRNA-guanine transglycosylase enzyme was purified and characterized. The enzyme catalyzes a transglycosylation reaction in which guanine is eliminated from position 15 of the tRNA and an archaeosine precursor (preQ(0)) is inserted. The enzyme is able to utilize both guanine and the 7-deazaguanine base preQ(0) as substrates, but not other 7-deazaguanine bases, and is able to modify tRNA from all three phylogenetic domains. The enzyme shows optimal activity at high temperature and acidic pH, consistent with the optimal growth conditions of M. jannaschii. The nature of the temperature dependence is consistent with a requirement for some degree of tRNA tertiary structure in order for recognition by the enzyme to occur.

Published

2000

5. Mechanistic Studies of the tRNA-Modifying Enzyme QueA:  A Chemical Imperative for the Use of AdoMet as a “Ribosyl” Donor

Author

Kinzie, S. D., Thern, B., and Iwata-Reuyl, D.

Abstract

The enzyme S-adenosylmethionine:tRNA ribosyltransferase-isomerase (QueA) catalyzes the penultimate step in the biosynthesis of the tRNA nucleoside queuosine, a unique ribosyl transfer from the cofactor S-adenosylmethionine (AdoMet) to a modified-tRNA precursor. The use of AdoMet in this way is fundamentally new to the chemistry of this important biological cofactor. We report here the first mechanistic studies of this remarkable enzyme, and we propose a chemical mechanism for the reaction consistent with our experimental observations.

Published

2000

6. 7-Deazaguanines in DNA: functional and structural elucidation of a DNA modification system.

Author

Gedara SH, Wood E, Gustafson A, Liang C, Hung SH, Savage J, Phan P, Luthra A, de Crécy-Lagard V, Dedon P, Swairjo MA, and Iwata-Reuyl D

Subjects

Guanine metabolism, RNA, Transfer metabolism, Pentosyltransferases metabolism, Nucleoside Q, DNA genetics

Abstract

The modified nucleosides 2'-deoxy-7-cyano- and 2'-deoxy-7-amido-7-deazaguanosine (dPreQ0 and dADG, respectively) recently discovered in DNA are the products of the bacterial queuosine tRNA modification pathway and the dpd gene cluster, the latter of which encodes proteins that comprise the elaborate Dpd restriction-modification system present in diverse bacteria. Recent genetic studies implicated the dpdA, dpdB and dpdC genes as encoding proteins necessary for DNA modification, with dpdD-dpdK contributing to the restriction phenotype. Here we report the in vitro reconstitution of the Dpd modification machinery from Salmonella enterica serovar Montevideo, the elucidation of the roles of each protein and the X-ray crystal structure of DpdA supported by small-angle X-ray scattering analysis of DpdA and DpdB, the former bound to DNA. While the homology of DpdA with the tRNA-dependent tRNA-guanine transglycosylase enzymes (TGT) in the queuosine pathway suggested a similar transglycosylase activity responsible for the exchange of a guanine base in the DNA for 7-cyano-7-deazaguanine (preQ0), we demonstrate an unexpected ATPase activity in DpdB necessary for insertion of preQ0 into DNA, and identify several catalytically essential active site residues in DpdA involved in the transglycosylation reaction. Further, we identify a modification site for DpdA activity and demonstrate that DpdC functions independently of DpdA/B in converting preQ0-modified DNA to ADG-modified DNA., (© The Author(s) 2023. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2023

7. Structural basis of Qng1-mediated salvage of the micronutrient queuine from queuosine-5'-monophosphate as the biological substrate.

Author

Hung SH, Elliott GI, Ramkumar TR, Burtnyak L, McGrenaghan CJ, Alkuzweny S, Quaiyum S, Iwata-Reuyl D, Pan X, Green BD, Kelly VP, de Crécy-Lagard V, and Swairjo MA

Subjects

Humans, Guanine metabolism, Micronutrients, Proteins, RNA, Transfer metabolism, Nucleoside Q metabolism, Glycoside Hydrolases chemistry, Chloroflexi enzymology

Abstract

Eukaryotic life benefits from-and ofttimes critically relies upon-the de novo biosynthesis and supply of vitamins and micronutrients from bacteria. The micronutrient queuosine (Q), derived from diet and/or the gut microbiome, is used as a source of the nucleobase queuine, which once incorporated into the anticodon of tRNA contributes to translational efficiency and accuracy. Here, we report high-resolution, substrate-bound crystal structures of the Sphaerobacter thermophilus queuine salvage protein Qng1 (formerly DUF2419) and of its human ortholog QNG1 (C9orf64), which together with biochemical and genetic evidence demonstrate its function as the hydrolase releasing queuine from queuosine-5'-monophosphate as the biological substrate. We also show that QNG1 is highly expressed in the liver, with implications for Q salvage and recycling. The essential role of this family of hydrolases in supplying queuine in eukaryotes places it at the nexus of numerous (patho)physiological processes associated with queuine deficiency, including altered metabolism, proliferation, differentiation and cancer progression., (© The Author(s) 2023. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2023

8. The DUF328 family member YaaA is a DNA-binding protein with a novel fold.

Author

Prahlad J, Yuan Y, Lin J, Chang CW, Iwata-Reuyl D, Liu Y, de Crécy-Lagard V, and Wilson MA

Subjects

Crystallography, X-Ray, DNA Repair, DNA, Bacterial chemistry, DNA, Bacterial genetics, DNA, Bacterial metabolism, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Escherichia coli genetics, Escherichia coli metabolism, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism, Oxidative Stress, Protein Domains, DNA-Binding Proteins chemistry, Escherichia coli chemistry, Escherichia coli Proteins chemistry, Protein Folding

Abstract

DUF328 family proteins are present in many prokaryotes; however, their molecular activities are unknown. The Escherichia coli DUF328 protein YaaA is a member of the OxyR regulon and is protective against oxidative stress. Because uncharacterized proteins involved in prokaryotic oxidative stress response are rare, we sought to learn more about the DUF328 family. Using comparative genomics, we found a robust association between the DUF328 family and genes involved in DNA recombination and the oxidative stress response. In some proteins, DUF328 domains are fused to other domains involved in DNA binding, recombination, and repair. Cofitness analysis indicates that DUF328 family genes associate with recombination-mediated DNA repair pathways, particularly the RecFOR pathway. Purified recombinant YaaA binds to dsDNA, duplex DNA containing bubbles of unpaired nucleotides, and Holliday junction constructs in vitro with dissociation equilibrium constants of 200-300 nm YaaA binds DNA with positive cooperativity, forming multiple shifted species in electrophoretic mobility shift assays. The 1.65-Å resolution X-ray crystal structure of YaaA reveals that the protein possesses a new fold that we name the cantaloupe fold. YaaA has a positively charged cleft and a helix-hairpin-helix DNA-binding motif found in other DNA repair enzymes. Our results demonstrate that YaaA is a new type of DNA-binding protein associated with the oxidative stress response and that this molecular function is likely conserved in other DUF328 family members., Competing Interests: Conflict of interest—The authors declare that they have no conflicts of interest with the contents of this article., (© 2020 Prahlad et al.)

Published

2020

9. Specificity in the biosynthesis of the universal tRNA nucleoside N 6 -threonylcarbamoyl adenosine (t 6 A)-TsaD is the gatekeeper.

Author

Swinehart W, Deutsch C, Sarachan KL, Luthra A, Bacusmo JM, de Crécy-Lagard V, Swairjo MA, Agris PF, and Iwata-Reuyl D

Subjects

Adenosine genetics, Adenosine Monophosphate genetics, Adenosine Triphosphate genetics, Amino Acids genetics, Catalytic Domain genetics, Escherichia coli genetics, Protein Conformation, Substrate Specificity genetics, Thermotoga maritima genetics, Threonine genetics, Adenosine analogs & derivatives, Biosynthetic Pathways genetics, Nucleosides genetics, RNA, Transfer genetics

Abstract

N 6 -threonylcarbamoyl adenosine (t 6 A) is a nucleoside modification found in all kingdoms of life at position 37 of tRNAs decoding ANN codons, which functions in part to restrict translation initiation to AUG and suppress frameshifting at tandem ANN codons. In Bacteria the proteins TsaB, TsaC (or C2), TsaD, and TsaE, comprise the biosynthetic apparatus responsible for t 6 A formation. TsaC(C2) and TsaD harbor the relevant active sites, with TsaC(C2) catalyzing the formation of the intermediate threonylcarbamoyladenosine monophosphate (TC-AMP) from ATP, threonine, and CO 2 , and TsaD catalyzing the transfer of the threonylcarbamoyl moiety from TC-AMP to A 37 of substrate tRNAs. Several related modified nucleosides, including hydroxynorvalylcarbamoyl adenosine (hn 6 A), have been identified in select organisms, but nothing is known about their biosynthesis. To better understand the mechanism and structural constraints on t 6 A formation, and to determine if related modified nucleosides are formed via parallel biosynthetic pathways or the t 6 A pathway, we carried out biochemical and biophysical investigations of the t 6 A systems from E. coli and T. maritima to address these questions. Using kinetic assays of TsaC(C2), tRNA modification assays, and NMR, our data demonstrate that TsaC(C2) exhibit relaxed substrate specificity, producing a variety of TC-AMP analogs that can differ in both the identity of the amino acid and nucleotide component, whereas TsaD displays more stringent specificity, but efficiently produces hn 6 A in E. coli and T. maritima tRNA. Thus, in organisms that contain modifications such as hn 6 A in their tRNA, we conclude that their origin is due to formation via the t 6 A pathway., (© 2020 Swinehart et al.; Published by Cold Spring Harbor Laboratory Press for the RNA Society.)

Published

2020

10. Archaeosine Modification of Archaeal tRNA: Role in Structural Stabilization.

Author

Turner B, Burkhart BW, Weidenbach K, Ross R, Limbach PA, Schmitz RA, de Crécy-Lagard V, Stedman KM, Santangelo TJ, and Iwata-Reuyl D

Subjects

Guanosine metabolism, Methanosarcina chemistry, Methanosarcina genetics, RNA Stability, RNA, Archaeal chemistry, RNA, Archaeal metabolism, RNA, Transfer chemistry, RNA, Transfer metabolism, Thermococcus chemistry, Thermococcus genetics, Guanosine analogs & derivatives, Methanosarcina metabolism, RNA, Archaeal genetics, RNA, Transfer genetics, Thermococcus metabolism

Abstract

Archaeosine (G + ) is a structurally complex modified nucleoside found quasi-universally in the tRNA of Archaea and located at position 15 in the dihydrouridine loop, a site not modified in any tRNA outside the Archaea G + is characterized by an unusual 7-deazaguanosine core structure with a formamidine group at the 7-position. The location of G + at position 15, coupled with its novel molecular structure, led to a hypothesis that G + stabilizes tRNA tertiary structure through several distinct mechanisms. To test whether G + contributes to tRNA stability and define the biological role of G + , we investigated the consequences of introducing targeted mutations that disrupt the biosynthesis of G + into the genome of the hyperthermophilic archaeon Thermococcus kodakarensis and the mesophilic archaeon Methanosarcina mazei , resulting in modification of the tRNA with the G + precursor 7-cyano-7-deazaguansine (preQ 0 ) (deletion of arcS ) or no modification at position 15 (deletion of tgtA ). Assays of tRNA stability from in vitro -prepared and enzymatically modified tRNA transcripts, as well as tRNA isolated from the T. kodakarensis mutant strains, demonstrate that G + at position 15 imparts stability to tRNAs that varies depending on the overall modification state of the tRNA and the concentration of magnesium chloride and that when absent results in profound deficiencies in the thermophily of T. kodakarensis IMPORTANCE Archaeosine is ubiquitous in archaeal tRNA, where it is located at position 15. Based on its molecular structure, it was proposed to stabilize tRNA, and we show that loss of archaeosine in Thermococcus kodakarensis results in a strong temperature-sensitive phenotype, while there is no detectable phenotype when it is lost in Methanosarcina mazei Measurements of tRNA stability show that archaeosine stabilizes the tRNA structure but that this effect is much greater when it is present in otherwise unmodified tRNA transcripts than in the context of fully modified tRNA, suggesting that it may be especially important during the early stages of tRNA processing and maturation in thermophiles. Our results demonstrate how small changes in the stability of structural RNAs can be manifested in significant biological-fitness changes., (Copyright © 2020 American Society for Microbiology.)

Published

2020

11. Conformational communication mediates the reset step in t6A biosynthesis.

Author

Luthra A, Paranagama N, Swinehart W, Bayooz S, Phan P, Quach V, Schiffer JM, Stec B, Iwata-Reuyl D, and Swairjo MA

Subjects

Adenosine biosynthesis, Adenosine Triphosphatases genetics, Amino Acid Motifs, Bacterial Proteins genetics, Models, Molecular, Mutagenesis, Protein Conformation, RNA, Transfer chemistry, Thermotoga maritima, Adenosine analogs & derivatives, Bacterial Proteins chemistry, RNA, Transfer metabolism

Abstract

The universally conserved N6-threonylcarbamoyladenosine (t6A) modification of tRNA is essential for translational fidelity. In bacteria, t6A biosynthesis starts with the TsaC/TsaC2-catalyzed synthesis of the intermediate threonylcarbamoyl adenylate (TC-AMP), followed by transfer of the threonylcarbamoyl (TC) moiety to adenine-37 of tRNA by the TC-transfer complex comprised of TsaB, TsaD and TsaE subunits and possessing an ATPase activity required for multi-turnover of the t6A cycle. We report a 2.5-Å crystal structure of the T. maritima TC-transfer complex (TmTsaB2D2E2) bound to Mg2+-ATP in the ATPase site, and substrate analog carboxy-AMP in the TC-transfer site. Site directed mutagenesis results show that residues in the conserved Switch I and Switch II motifs of TsaE mediate the ATP hydrolysis-driven reactivation/reset step of the t6A cycle. Further, SAXS analysis of the TmTsaB2D2-tRNA complex in solution reveals bound tRNA lodged in the TsaE binding cavity, confirming our previous biochemical data. Based on the crystal structure and molecular docking of TC-AMP and adenine-37 in the TC-transfer site, we propose a model for the mechanism of TC transfer by this universal biosynthetic system., (© The Author(s) 2019. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2019

12. Identification of the minimal bacterial 2'-deoxy-7-amido-7-deazaguanine synthesis machinery.

Author

Yuan Y, Hutinet G, Valera JG, Hu J, Hillebrand R, Gustafson A, Iwata-Reuyl D, Dedon PC, and de Crécy-Lagard V

Subjects

Multigene Family, Biosynthetic Pathways genetics, DNA, Bacterial metabolism, Deoxyguanosine analogs & derivatives, Deoxyguanosine biosynthesis, Salmonella enterica genetics, Salmonella enterica metabolism

Abstract

The 7-deazapurine derivatives, 2'-deoxy-7-cyano-7-deazaguanosine (dPreQ 0 ) and 2'-deoxy-7-amido-7-deazaguanosine (dADG) are recently discovered DNA modifications encoded by the dpd cluster found in a diverse set of bacteria. Here we identify the genes required for the formation of dPreQ 0 and dADG in DNA and propose a biosynthetic pathway. The preQ 0 base is a precursor that in Salmonella Montevideo, is synthesized as an intermediate in the pathway of the tRNA modification queuosine. Of the 11 genes (dpdA - dpdK) found in the S. Montevideo dpd cluster, dpdA and dpdB are necessary and sufficient to synthesize dPreQ 0 , while dpdC is additionally required for dADG synthesis. Among the rest of the dpd genes, dpdE, dpdG, dpdI, dpdK, dpdD and possibly dpdJ appear to be involved in a restriction-like phenotype. Indirect competition for preQ 0 base led to a model for dADG synthesis in which DpdA inserts preQ 0 into DNA with the help of DpdB, and then DpdC hydrolyzes dPreQ 0 to dADG. The role of DpdB is not entirely clear as it is dispensable in other dpd clusters. Our discovery of a minimal gene set for introducing 7-deazapurine derivatives in DNA provides new tools for biotechnology applications and demonstrates the interplay between the DNA and RNA modification machineries., (© 2018 John Wiley & Sons Ltd.)

Published

2018

13. Structure and mechanism of a bacterial t6A biosynthesis system.

Author

Luthra A, Swinehart W, Bayooz S, Phan P, Stec B, Iwata-Reuyl D, and Swairjo MA

Subjects

Adenosine biosynthesis, Adenosine chemistry, Adenosine genetics, Adenosine Triphosphatases deficiency, Adenosine Triphosphatases genetics, Adenosine Triphosphate chemistry, Adenosine Triphosphate metabolism, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Binding Sites, Cloning, Molecular, Codon, Crystallography, X-Ray, Escherichia coli genetics, Escherichia coli metabolism, Gene Expression, Genetic Vectors chemistry, Genetic Vectors metabolism, Isoenzymes chemistry, Isoenzymes genetics, Isoenzymes metabolism, Kinetics, Ligases chemistry, Ligases metabolism, Models, Molecular, Nucleic Acid Conformation, Protein Binding, Protein Conformation, alpha-Helical, Protein Conformation, beta-Strand, Protein Interaction Domains and Motifs, RNA, Transfer chemistry, RNA, Transfer metabolism, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Substrate Specificity, Thermotoga maritima genetics, Adenosine analogs & derivatives, Bacterial Proteins genetics, Ligases genetics, Protein Biosynthesis, RNA, Transfer genetics, Thermotoga maritima enzymology

Abstract

The universal N(6)-threonylcarbamoyladenosine (t6A) modification at position 37 of ANN-decoding tRNAs is central to translational fidelity. In bacteria, t6A biosynthesis is catalyzed by the proteins TsaB, TsaC/TsaC2, TsaD and TsaE. Despite intense research, the molecular mechanisms underlying t6A biosynthesis are poorly understood. Here, we report biochemical and biophysical studies of the t6A biosynthesis system from Thermotoga maritima. Small angle X-ray scattering analysis reveals a symmetric 2:2 stoichiometric complex of TsaB and TsaD (TsaB2D2), as well as 2:2:2 complex (TsaB2D2E2), in which TsaB acts as a dimerization module, similar to the role of Pcc1 in the archaeal system. The TsaB2D2 complex is the minimal platform for the binding of one tRNA molecule, which can then accommodate a single TsaE subunit. Kinetic data demonstrate that TsaB2D2 alone, and a TsaB2D2E1 complex with TsaE mutants deficient in adenosine triphosphatase (ATPase) activity, can catalyze only a single cycle of t6A synthesis, while gel shift experiments provide evidence that the role of TsaE-catalyzed ATP hydrolysis occurs after the release of product tRNA. Based on these results, we propose a model for t6A biosynthesis in bacteria.

Published

2018

14. The t 6 A modification acts as a positive determinant for the anticodon nuclease PrrC, and is distinctively nonessential in Streptococcus mutans.

Author

Bacusmo JM, Orsini SS, Hu J, DeMott M, Thiaville PC, Elfarash A, Paulines MJ, Rojas-Benítez D, Meineke B, Deutsch C, Iwata-Reuyl D, Limbach PA, Dedon PC, Rice KC, Shuman S, and Crécy-Lagard V

Subjects

Adenosine deficiency, Adenosine genetics, Anticodon chemistry, Anticodon metabolism, Bacterial Proteins metabolism, Bacterial Toxins biosynthesis, Bacterial Toxins genetics, Endoribonucleases metabolism, Escherichia coli genetics, Escherichia coli metabolism, Nucleic Acid Conformation, Protein Biosynthesis, RNA, Transfer, Lys metabolism, Streptococcus mutans metabolism, Adenosine analogs & derivatives, Bacterial Proteins genetics, Endoribonucleases genetics, RNA Processing, Post-Transcriptional, RNA, Transfer, Lys genetics, Streptococcus mutans genetics

Abstract

Endoribonuclease toxins (ribotoxins) are produced by bacteria and fungi to respond to stress, eliminate non-self competitor species, or interdict virus infection. PrrC is a bacterial ribotoxin that targets and cleaves tRNA Lys UUU in the anticodon loop. In vitro studies suggested that the post-transcriptional modification threonylcarbamoyl adenosine (t 6 A) is required for PrrC activity but this prediction had never been validated in vivo. Here, by using t 6 A-deficient yeast derivatives, it is shown that t 6 A is a positive determinant for PrrC proteins from various bacterial species. Streptococcus mutans is one of the few bacteria where the t 6 A synthesis gene tsaE (brpB) is dispensable and its genome encodes a PrrC toxin. We had previously shown using an HPLC-based assay that the S. mutans tsaE mutant was devoid of t 6 A. However, we describe here a novel and a more sensitive hybridization-based t 6 A detection method (compared to HPLC) that showed t 6 A was still present in the S. mutans ΔtsaE, albeit at greatly reduced levels (93% reduced compared with WT). Moreover, mutants in 2 other S. mutans t 6 A synthesis genes (tsaB and tsaC) were shown to be totally devoid of the modification thus confirming its dispensability in this organism. Furthermore, analysis of t 6 A modification ratios and of t 6 A synthesis genes mRNA levels in S. mutans suggest they may be regulated by growth phase.

Published

2018

15. QueF-Like, a Non-Homologous Archaeosine Synthase from the Crenarchaeota.

Author

Bon Ramos A, Bao L, Turner B, de Crécy-Lagard V, and Iwata-Reuyl D

Subjects

Biocatalysis, Guanosine metabolism, Ligases genetics, Guanosine analogs & derivatives, Ligases metabolism, Pyrobaculum enzymology

Abstract

Archaeosine (G⁺) is a structurally complex modified nucleoside ubiquitous to the Archaea, where it is found in the D-loop of virtually all archaeal transfer RNA (tRNA). Its unique structure, which includes a formamidine group that carries a formal positive charge, and location in the tRNA, led to the proposal that it serves a key role in stabilizing tRNA structure. Although G⁺ is limited to the Archaea, it is structurally related to the bacterial modified nucleoside queuosine, and the two share homologous enzymes for the early steps of their biosynthesis. In the Euryarchaeota, the last step of the archaeosine biosynthetic pathway involves the amidation of a nitrile group on an archaeosine precursor to give formamidine, a reaction catalyzed by the enzyme Archaeosine Synthase (ArcS). Most Crenarchaeota lack ArcS, but possess two proteins that inversely distribute with ArcS and each other, and are implicated in G⁺ biosynthesis. Here, we describe biochemical studies of one of these, the protein QueF-like (QueF-L) from Pyrobaculum calidifontis, that demonstrate the catalytic activity of QueF-L, establish where in the pathway QueF-L acts, and identify the source of ammonia in the reaction.

Published

2017

16. Protection of the Queuosine Biosynthesis Enzyme QueF from Irreversible Oxidation by a Conserved Intramolecular Disulfide.

Author

Mohammad A, Bon Ramos A, Lee BW, Cohen SW, Kiani MK, Iwata-Reuyl D, Stec B, and Swairjo MA

Subjects

Bacterial Proteins chemistry, Biocatalysis, Biosynthetic Pathways, Conserved Sequence, Crystallography, X-Ray, Cysteine metabolism, Mutant Proteins chemistry, Mutant Proteins metabolism, Oxidation-Reduction, Phylogeny, Time Factors, Bacillus subtilis enzymology, Bacterial Proteins metabolism, Disulfides metabolism, Nucleoside Q biosynthesis

Abstract

QueF enzymes catalyze the nicotinamide adenine dinucleotide phosphate (NADPH)-dependent reduction of the nitrile group of 7-cyano-7-deazaguanine (preQ₀) to 7-aminomethyl-7-deazaguanine (preQ₁) in the biosynthetic pathway to the tRNA modified nucleoside queuosine. The QueF-catalyzed reaction includes formation of a covalent thioimide intermediate with a conserved active site cysteine that is prone to oxidation in vivo. Here, we report the crystal structure of a mutant of Bacillus subtilis QueF, which reveals an unanticipated intramolecular disulfide formed between the catalytic Cys55 and a conserved Cys99 located near the active site. This structure is more symmetric than the substrate-bound structure and exhibits major rearrangement of the loops responsible for substrate binding. Mutation of Cys99 to Ala/Ser does not compromise enzyme activity, indicating that the disulfide does not play a catalytic role. Peroxide-induced inactivation of the wild-type enzyme is reversible with thioredoxin, while such inactivation of the Cys99Ala/Ser mutants is irreversible, consistent with protection of Cys55 from irreversible oxidation by disulfide formation with Cys99. Conservation of the cysteine pair, and the reported in vivo interaction of QueF with the thioredoxin-like hydroperoxide reductase AhpC in Escherichia coli suggest that regulation by the thioredoxin disulfide-thiol exchange system may constitute a general mechanism for protection of QueF from oxidative stress in vivo.

Published

2017

17. Mechanism and catalytic strategy of the prokaryotic-specific GTP cyclohydrolase-IB.

Author

Paranagama N, Bonnett SA, Alvarez J, Luthra A, Stec B, Gustafson A, Iwata-Reuyl D, and Swairjo MA

Subjects

Bacterial Proteins antagonists & inhibitors, Bacterial Proteins genetics, Bacterial Proteins metabolism, Catalytic Domain, Cloning, Molecular, Crystallography, X-Ray, Enzyme Inhibitors chemistry, Escherichia coli genetics, Escherichia coli metabolism, GTP Cyclohydrolase antagonists & inhibitors, GTP Cyclohydrolase genetics, GTP Cyclohydrolase metabolism, Gene Expression, Guanosine Triphosphate chemistry, Kinetics, Models, Molecular, Mutation, Neisseria gonorrhoeae enzymology, Protein Binding, Protein Conformation, alpha-Helical, Protein Conformation, beta-Strand, Protein Interaction Domains and Motifs, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, S-Nitrosothiols chemistry, Substrate Specificity, Bacterial Proteins chemistry, GTP Cyclohydrolase chemistry, Guanosine Triphosphate analogs & derivatives, Neisseria gonorrhoeae chemistry, Tromethamine chemistry

Abstract

Guanosine 5'-triphosphate (GTP) cyclohydrolase-I (GCYH-I) catalyzes the first step in folic acid biosynthesis in bacteria and plants, biopterin biosynthesis in mammals, and the biosynthesis of 7-deazaguanosine-modified tRNA nucleosides in bacteria and archaea. The type IB GCYH (GCYH-IB) is a prokaryotic-specific enzyme found in many pathogens. GCYH-IB is structurally distinct from the canonical type IA GCYH involved in biopterin biosynthesis in humans and animals, and thus is of interest as a potential antibacterial drug target. We report kinetic and inhibition data of Neisseria gonorrhoeae GCYH-IB and two high-resolution crystal structures of the enzyme; one in complex with the reaction intermediate analog and competitive inhibitor 8-oxoguanosine 5'-triphosphate (8-oxo-GTP), and one with a tris(hydroxymethyl)aminomethane molecule bound in the active site and mimicking another reaction intermediate. Comparison with the type IA enzyme bound to 8-oxo-GTP (guanosine 5'-triphosphate) reveals an inverted mode of binding of the inhibitor ribosyl moiety and, together with site-directed mutagenesis data, shows that the two enzymes utilize different strategies for catalysis. Notably, the inhibitor interacts with a conserved active-site Cys149, and this residue is S-nitrosylated in the structures. This is the first structural characterization of a biologically S-nitrosylated bacterial protein. Mutagenesis and biochemical analyses demonstrate that Cys149 is essential for the cyclohydrolase reaction, and S-nitrosylation maintains enzyme activity, suggesting a potential role of the S -nitrosothiol in catalysis., (© 2017 The Author(s); published by Portland Press Limited on behalf of the Biochemical Society.)

Published

2017

18. Crystal structure of the archaeosine synthase QueF-like-Insights into amidino transfer and tRNA recognition by the tunnel fold.

Author

Mei X, Alvarez J, Bon Ramos A, Samanta U, Iwata-Reuyl D, and Swairjo MA

Subjects

Amidinotransferases genetics, Amidinotransferases metabolism, Amino Acid Sequence, Archaeal Proteins genetics, Archaeal Proteins metabolism, Catalytic Domain, Cloning, Molecular, Crystallography, X-Ray, Escherichia coli genetics, Escherichia coli metabolism, Gene Expression, Guanosine chemistry, Guanosine metabolism, Molecular Docking Simulation, Protein Binding, Protein Conformation, alpha-Helical, Protein Conformation, beta-Strand, Protein Interaction Domains and Motifs, Protein Multimerization, Protein Subunits chemistry, Protein Subunits genetics, Protein Subunits metabolism, Pyrimidinones metabolism, Pyrobaculum genetics, Pyrroles metabolism, RNA, Archaeal chemistry, RNA, Archaeal genetics, RNA, Archaeal metabolism, RNA, Transfer chemistry, RNA, Transfer genetics, RNA, Transfer metabolism, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Sequence Alignment, Sequence Homology, Amino Acid, Substrate Specificity, Amidinotransferases chemistry, Archaeal Proteins chemistry, Guanosine analogs & derivatives, Pyrimidinones chemistry, Pyrobaculum enzymology, Pyrroles chemistry, RNA Processing, Post-Transcriptional

Abstract

The tunneling-fold (T-fold) structural superfamily has emerged as a versatile protein scaffold of diverse catalytic activities. This is especially evident in the pathways to the 7-deazaguanosine modified nucleosides of tRNA queuosine and archaeosine. Four members of the T-fold superfamily have been confirmed in these pathways and here we report the crystal structure of a fifth enzyme; the recently discovered amidinotransferase QueF-Like (QueF-L), responsible for the final step in the biosynthesis of archaeosine in the D-loop of tRNA in a subset of Crenarchaeota. QueF-L catalyzes the conversion of the nitrile group of the 7-cyano-7-deazaguanine (preQ 0 ) base of preQ 0 -modified tRNA to a formamidino group. The structure, determined in the presence of preQ 0 , reveals a symmetric T-fold homodecamer of two head-to-head facing pentameric subunits, with 10 active sites at the inter-monomer interfaces. Bound preQ 0 forms a stable covalent thioimide bond with a conserved active site cysteine similar to the intermediate previously observed in the nitrile reductase QueF. Despite distinct catalytic functions, phylogenetic distributions, and only 19% sequence identity, the two enzymes share a common preQ 0 binding pocket, and likely a common mechanism of thioimide formation. However, due to tight twisting of its decamer, QueF-L lacks the NADPH binding site present in QueF. A large positively charged molecular surface and a docking model suggest simultaneous binding of multiple tRNA molecules and structure-specific recognition of the D-loop by a surface groove. The structure sheds light on the mechanism of nitrile amidation, and the evolution of diverse chemistries in a common fold. Proteins 2016; 85:103-116. © 2016 Wiley Periodicals, Inc., (© 2016 Wiley Periodicals, Inc.)

Published

2017

19. Essentiality of threonylcarbamoyladenosine (t(6)A), a universal tRNA modification, in bacteria.

Author

Thiaville PC, El Yacoubi B, Köhrer C, Thiaville JJ, Deutsch C, Iwata-Reuyl D, Bacusmo JM, Armengaud J, Bessho Y, Wetzel C, Cao X, Limbach PA, RajBhandary UL, and de Crécy-Lagard V

Subjects

Adenosine genetics, Adenosine metabolism, Amino Acid Sequence, Amino Acyl-tRNA Synthetases genetics, Amino Acyl-tRNA Synthetases metabolism, Aminoacylation genetics, Conserved Sequence, Deinococcus metabolism, Escherichia coli metabolism, Molecular Sequence Data, Prokaryotic Cells, Proteomics, RNA, Bacterial genetics, RNA, Bacterial metabolism, Saccharomyces cerevisiae genetics, Adenosine analogs & derivatives, Deinococcus genetics, Escherichia coli genetics, RNA, Transfer genetics, RNA, Transfer metabolism

Abstract

Threonylcarbamoyladenosine (t(6)A) is a modified nucleoside universally conserved in tRNAs in all three kingdoms of life. The recently discovered genes for t(6)A synthesis, including tsaC and tsaD, are essential in model prokaryotes but not essential in yeast. These genes had been identified as antibacterial targets even before their functions were known. However, the molecular basis for this prokaryotic-specific essentiality has remained a mystery. Here, we show that t(6)A is a strong positive determinant for aminoacylation of tRNA by bacterial-type but not by eukaryotic-type isoleucyl-tRNA synthetases and might also be a determinant for the essential enzyme tRNA(Ile)-lysidine synthetase. We confirm that t(6)A is essential in Escherichia coli and a survey of genome-wide essentiality studies shows that genes for t(6)A synthesis are essential in most prokaryotes. This essentiality phenotype is not universal in Bacteria as t(6)A is dispensable in Deinococcus radiodurans, Thermus thermophilus, Synechocystis PCC6803 and Streptococcus mutans. Proteomic analysis of t(6)A(-) D. radiodurans strains revealed an induction of the proteotoxic stress response and identified genes whose translation is most affected by the absence of t(6)A in tRNAs. Thus, although t(6)A is universally conserved in tRNAs, its role in translation might vary greatly between organisms., (© 2015 John Wiley & Sons Ltd.)

Published

2015

20. NMR-based Structural Analysis of Threonylcarbamoyl-AMP Synthase and Its Substrate Interactions.

Author

Harris KA, Bobay BG, Sarachan KL, Sims AF, Bilbille Y, Deutsch C, Iwata-Reuyl D, and Agris PF

Subjects

Ligases metabolism, Models, Molecular, Nuclear Magnetic Resonance, Biomolecular, Protein Conformation, Substrate Specificity, Threonine metabolism, Adenosine Monophosphate metabolism, Ligases chemistry

Abstract

The hypermodified nucleoside N(6)-threonylcarbamoyladenosine (t(6)A37) is present in many distinct tRNA species and has been found in organisms in all domains of life. This post-transcriptional modification enhances translation fidelity by stabilizing the anticodon/codon interaction in the ribosomal decoding site. The biosynthetic pathway of t(6)A37 is complex and not well understood. In bacteria, the following four proteins have been discovered to be both required and sufficient for t(6)A37 modification: TsaC, TsaD, TsaB, and TsaE. Of these, TsaC and TsaD are members of universally conserved protein families. Although TsaC has been shown to catalyze the formation of L-threonylcarbamoyl-AMP, a key intermediate in the biosynthesis of t(6)A37, the details of the enzymatic mechanism remain unsolved. Therefore, the solution structure of Escherichia coli TsaC was characterized by NMR to further study the interactions with ATP and L-threonine, both substrates of TsaC in the biosynthesis of L-threonylcarbamoyl-AMP. Several conserved amino acids were identified that create a hydrophobic binding pocket for the adenine of ATP. Additionally, two residues were found to interact with L-threonine. Both binding sites are located in a deep cavity at the center of the protein. Models derived from the NMR data and molecular modeling reveal several sites with considerable conformational flexibility in TsaC that may be important for L-threonine recognition, ATP activation, and/or protein/protein interactions. These observations further the understanding of the enzymatic reaction catalyzed by TsaC, a threonylcarbamoyl-AMP synthase, and provide structure-based insight into the mechanism of t(6)A37 biosynthesis., (© 2015 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2015

21. Promiscuous and adaptable enzymes fill "holes" in the tetrahydrofolate pathway in Chlamydia species.

Author

Adams NE, Thiaville JJ, Proestos J, Juárez-Vázquez AL, McCoy AJ, Barona-Gómez F, Iwata-Reuyl D, de Crécy-Lagard V, and Maurelli AT

Subjects

Chlamydia genetics, Signal Transduction genetics, Signal Transduction physiology, Bacterial Proteins metabolism, Chlamydia enzymology, Chlamydia metabolism, Tetrahydrofolates metabolism

Abstract

Folates are tripartite molecules comprising pterin, para-aminobenzoate (PABA), and glutamate moieties, which are essential cofactors involved in DNA and amino acid synthesis. The obligately intracellular Chlamydia species have lost several biosynthetic pathways for essential nutrients which they can obtain from their host but have retained the capacity to synthesize folate. In most bacteria, synthesis of the pterin moiety of folate requires the FolEQBK enzymes, while synthesis of the PABA moiety is carried out by the PabABC enzymes. Bioinformatic analyses reveal that while members of Chlamydia are missing the genes for FolE (GTP cyclohydrolase) and FolQ, which catalyze the initial steps in de novo synthesis of the pterin moiety, they have genes for the rest of the pterin pathway. We screened a chlamydial genomic library in deletion mutants of Escherichia coli to identify the "missing genes" and identified a novel enzyme, TrpFCtL2, which has broad substrate specificity. TrpFCtL2, in combination with GTP cyclohydrolase II (RibA), the first enzyme of riboflavin synthesis, provides a bypass of the first two canonical steps in folate synthesis catalyzed by FolE and FolQ. Notably, TrpFCtL2 retains the phosphoribosyl anthranilate isomerase activity of the original annotation. Additionally, we independently confirmed the recent discovery of a novel enzyme, CT610, which uses an unknown precursor to synthesize PABA and complements E. coli mutants with deletions of pabA, pabB, or pabC. Thus, Chlamydia species have evolved a variant folate synthesis pathway that employs a patchwork of promiscuous and adaptable enzymes recruited from other biosynthetic pathways. Importance: Collectively, the involvement of TrpFCtL2 and CT610 in the tetrahydrofolate pathway completes our understanding of folate biosynthesis in Chlamydia. Moreover, the novel roles for TrpFCtL2 and CT610 in the tetrahydrofolate pathway are sophisticated examples of how enzyme evolution plays a vital role in the adaptation of obligately intracellular organisms to host-specific niches. Enzymes like TrpFCtL2 which possess an enzyme fold common to many other enzymes are highly versatile and possess the capacity to evolve to catalyze related reactions in two different metabolic pathways. The continued identification of unique enzymes such as these in bacterial pathogens is important for development of antimicrobial compounds, as drugs that inhibit such enzymes would likely not have any targets in the host or the host's normal microbial flora., (Copyright © 2014 Adams et al.)

Published

2014

22. Diversity of the biosynthesis pathway for threonylcarbamoyladenosine (t(6)A), a universal modification of tRNA.

Author

Thiaville PC, Iwata-Reuyl D, and de Crécy-Lagard V

Subjects

Adenosine biosynthesis, Anticodon chemistry, Anticodon metabolism, Archaeal Proteins genetics, Codon chemistry, Codon metabolism, Escherichia coli genetics, Escherichia coli metabolism, Escherichia coli Proteins chemistry, Haloferax volcanii genetics, Haloferax volcanii metabolism, Humans, Nucleic Acid Conformation, RNA, Transfer chemistry, RNA-Binding Proteins chemistry, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Telomerase genetics, Adenosine analogs & derivatives, Archaeal Proteins metabolism, Escherichia coli Proteins metabolism, RNA Processing, Post-Transcriptional, RNA, Transfer metabolism, RNA-Binding Proteins metabolism, Saccharomyces cerevisiae Proteins metabolism, Telomerase metabolism

Abstract

The tRNA modification field has a rich literature covering biochemical analysis going back more than 40 years, but many of the corresponding genes were only identified in the last decade. In recent years, comparative genomic-driven analysis has allowed for the identification of the genes and subsequent characterization of the enzymes responsible for N6-threonylcarbamoyladenosine (t(6)A). This universal modification, located in the anticodon stem-loop at position 37 adjacent to the anticodon of tRNAs, is found in nearly all tRNAs that decode ANN codons. The t(6)A biosynthesis enzymes and synthesis pathways have now been identified, revealing both a core set of enzymes and kingdom-specific variations. This review focuses on the elucidation of the pathway, diversity of the synthesis genes, and proposes a new nomenclature for t(6)A synthesis enzymes.

Published

2014

23. Exploiting preQ(1) riboswitches to regulate ribosomal frameshifting.

Author

Yu CH, Luo J, Iwata-Reuyl D, and Olsthoorn RC

Subjects

Aptamers, Nucleotide, Base Sequence, Nucleic Acid Conformation, Frameshifting, Ribosomal, Riboswitch

Abstract

Knowing the molecular details of the interaction between riboswitch aptamers and their corresponding metabolites is important to understand gene expression. Here we report on a novel in vitro assay to study preQ(1) riboswitch aptamers upon binding of 7-aminomethyl-7-deazaguanine (preQ(1)). The assay is based on the ability of the preQ(1) aptamer to fold, upon ligand binding, into a pseudoknotted structure that is capable of stimulating -1 ribosomal frameshifting (-1 FS). Aptamers from three different species were found to induce between 7% and 20% of -1 FS in response to increasing preQ(1) levels, whereas preQ(1) analogues were 100-1000-fold less efficient. In depth mutational analysis of the Fusobacterium nucleatum aptamer recapitulates most of the structural details previously identified for preQ(1) aptamers from other bacteria by crystallography and/or NMR spectroscopy. In addition to providing insight into the role of individual nucleotides of the preQ(1) riboswitch aptamer in ligand binding, the presented system provides a valuable tool to screen small molecules against bacterial riboswitches in a eukaryotic background.

Published

2013

24. Structural basis of biological nitrile reduction.

Author

Chikwana VM, Stec B, Lee BW, de Crécy-Lagard V, Iwata-Reuyl D, and Swairjo MA

Subjects

Amino Acid Substitution, Bacillus subtilis genetics, Bacterial Proteins genetics, Bacterial Proteins metabolism, Mutation, Missense, Nitriles metabolism, Oxidation-Reduction, Oxidoreductases genetics, Oxidoreductases metabolism, Bacillus subtilis enzymology, Bacterial Proteins chemistry, Nitriles chemistry, Oxidoreductases chemistry

Abstract

The enzyme QueF catalyzes the reduction of the nitrile group of 7-cyano-7-deazaguanine (preQ(0)) to 7-aminomethyl-7-deazaguanine (preQ(1)), the only nitrile reduction reaction known in biology. We describe here two crystal structures of Bacillus subtilis QueF, one of the wild-type enzyme in complex with the substrate preQ(0), trapped as a covalent thioimide, a putative intermediate in the reaction, and the second of the C55A mutant in complex with the substrate preQ(0) bound noncovalently. The QueF enzyme forms an asymmetric tunnel-fold homodecamer of two head-to-head facing pentameric subunits, harboring 10 active sites at the intersubunit interfaces. In both structures, a preQ(0) molecule is bound at eight sites, and in the wild-type enzyme, it forms a thioimide covalent linkage to the catalytic residue Cys-55. Both structural and transient kinetic data show that preQ(0) binding, not thioimide formation, induces a large conformational change in and closure of the active site. Based on these data, we propose a mechanism for the activation of the Cys-55 nucleophile and subsequent hydride transfer.

Published

2012

25. Biosynthesis of threonylcarbamoyl adenosine (t6A), a universal tRNA nucleoside.

Author

Deutsch C, El Yacoubi B, de Crécy-Lagard V, and Iwata-Reuyl D

Subjects

Anticodon, Base Sequence, Catalysis, Codon, Computational Biology methods, Escherichia coli metabolism, Escherichia coli Proteins metabolism, Mass Spectrometry methods, Molecular Sequence Data, Nucleic Acid Conformation, Protein Binding, RNA, Transfer metabolism, RNA-Binding Proteins metabolism, Recombinant Proteins chemistry, Adenosine chemistry, Escherichia coli physiology, Gene Expression Regulation, Bacterial, RNA, Transfer chemistry

Abstract

The anticodon stem-loop (ASL) of transfer RNAs (tRNAs) drives decoding by interacting directly with the mRNA through codon/anticodon pairing. Chemically complex nucleoside modifications found in the ASL at positions 34 or 37 are known to be required for accurate decoding. Although over 100 distinct modifications have been structurally characterized in tRNAs, only a few are universally conserved, among them threonylcarbamoyl adenosine (t(6)A), found at position 37 in the anticodon loop of a subset of tRNA. Structural studies predict an important role for t(6)A in translational fidelity, and in vivo work supports this prediction. Although pioneering work in the 1970s identified the fundamental substrates for t(6)A biosynthesis, the enzymes responsible for its biosynthesis have remained an enigma. We report here the discovery that in bacteria four proteins (YgjD, YrdC, YjeE, and YeaZ) are both necessary and sufficient for t(6)A biosynthesis in vitro. Notably, YrdC and YgjD are members of universally conserved families that were ranked among the top 10 proteins of unknown function in need of functional characterization, while YeaZ and YjeE are specific to bacteria. This latter observation, coupled with the essentiality of all four proteins in bacteria, establishes this pathway as a compelling new target for antimicrobial development.

Published

2012

26. Diversity of archaeosine synthesis in crenarchaeota.

Author

Phillips G, Swairjo MA, Gaston KW, Bailly M, Limbach PA, Iwata-Reuyl D, and de Crécy-Lagard V

Subjects

Amino Acid Sequence, Archaeal Proteins chemistry, Archaeal Proteins genetics, Crenarchaeota chemistry, Crenarchaeota genetics, Crenarchaeota metabolism, Genomics, Guanosine chemistry, Guanosine metabolism, Molecular Sequence Data, Phylogeny, Sequence Alignment, Substrate Specificity, Archaeal Proteins metabolism, Crenarchaeota enzymology, Guanosine analogs & derivatives

Abstract

Archaeosine (G(+)) is found at position 15 of many archaeal tRNAs. In Euryarchaeota, the G(+) precursor, 7-cyano-7-deazaguanine (preQ(0)), is inserted into tRNA by tRNA-guanine transglycosylase (arcTGT) before conversion into G(+) by ARChaeosine Synthase (ArcS). However, many Crenarchaeota known to harbor G(+) lack ArcS homologues. Using comparative genomics approaches, two families that could functionally replace ArcS in these organisms were identified: (1) GAT-QueC, a two-domain family with an N-terminal glutamine amidotransferase class-II domain fused to a domain homologous to QueC, the enzyme that produces preQ(0) and (2) QueF-like, a family homologous to the bacterial enzyme catalyzing the reduction of preQ(0) to 7-aminomethyl-7-deazaguanine. Here we show that these two protein families are able to catalyze the formation of G(+) in a heterologous system. Structure and sequence comparisons of crenarchaeal and euryarchaeal arcTGTs suggest the crenarchaeal enzymes have broader substrate specificity. These results led to a new model for the synthesis and salvage of G(+) in Crenarchaeota.

Published

2012

27. Functional promiscuity of the COG0720 family.

Author

Phillips G, Grochowski LL, Bonnett S, Xu H, Bailly M, Blaby-Haas C, El Yacoubi B, Iwata-Reuyl D, White RH, and de Crécy-Lagard V

Subjects

Amino Acid Motifs, Archaeal Proteins genetics, Biopterins genetics, Genetic Complementation Test, Guanosine analogs & derivatives, Guanosine metabolism, Kinetics, Models, Molecular, Molecular Sequence Data, Neopterin genetics, Neopterin metabolism, Nucleoside Q metabolism, Phosphorus-Oxygen Lyases genetics, Phylogeny, Protein Structure, Tertiary genetics, Recombinant Proteins genetics, Recombinant Proteins metabolism, Sequence Homology, Amino Acid, Substrate Specificity, Sulfolobus genetics, Tetrahydrofolates metabolism, Archaeal Proteins metabolism, Biopterins metabolism, Guanosine Triphosphate metabolism, Neopterin analogs & derivatives, Phosphorus-Oxygen Lyases metabolism, Sulfolobus enzymology

Abstract

The biosynthesis of GTP derived metabolites such as tetrahydrofolate (THF), biopterin (BH(4)), and the modified tRNA nucleosides queuosine (Q) and archaeosine (G(+)) relies on several enzymes of the Tunnel-fold superfamily. A subset of these proteins includes the 6-pyruvoyltetrahydropterin (PTPS-II), PTPS-III, and PTPS-I homologues, all members of the COG0720 family that have been previously shown to transform 7,8-dihydroneopterin triphosphate (H(2)NTP) into different products. PTPS-II catalyzes the formation of 6-pyruvoyltetrahydropterin in the BH(4) pathway, PTPS-III catalyzes the formation of 6-hydroxylmethyl-7,8-dihydropterin in the THF pathway, and PTPS-I catalyzes the formation of 6-carboxy-5,6,7,8-tetrahydropterin in the Q pathway. Genes of these three enzyme families are often misannotated as they are difficult to differentiate by sequence similarity alone. Using a combination of physical clustering, signature motif, phylogenetic codistribution analyses, in vivo complementation studies, and in vitro enzymatic assays, a complete reannotation of the COG0720 family was performed in prokaryotes. Notably, this work identified and experimentally validated dual function PTPS-I/III enzymes involved in both THF and Q biosynthesis. Both in vivo and in vitro analyses showed that the PTPS-I family could tolerate a translation of the active site cysteine and was inherently promiscuous, catalyzing different reactions on the same substrate or the same reaction on different substrates. Finally, the analysis and experimental validation of several archaeal COG0720 members confirmed the role of PTPS-I in archaeosine biosynthesis and resulted in the identification of PTPS-III enzymes with variant signature sequences in Sulfolobus species. This study reveals an expanded versatility of the COG0720 family members and illustrates that for certain protein families extensive comparative genomic analysis beyond homology is required to correctly predict function.

Published

2012

28. Queuosine deficiency in eukaryotes compromises tyrosine production through increased tetrahydrobiopterin oxidation.

Author

Rakovich T, Boland C, Bernstein I, Chikwana VM, Iwata-Reuyl D, and Kelly VP

Subjects

Animals, Hep G2 Cells, Humans, Mice, Oxidation-Reduction, Pentosyltransferases genetics, Pentosyltransferases metabolism, Phenylalanine genetics, Phenylalanine metabolism, Phenylalanine Hydroxylase genetics, Phenylalanine Hydroxylase metabolism, Phenylketonurias genetics, Phenylketonurias metabolism, RNA, Transfer genetics, RNA, Transfer metabolism, Tetrahydrofolate Dehydrogenase genetics, Tetrahydrofolate Dehydrogenase metabolism, Nucleoside Q genetics, Nucleoside Q metabolism, Pterins metabolism, Tyrosine biosynthesis, Tyrosine genetics

Abstract

Queuosine is a modified pyrrolopyrimidine nucleoside found in the anticodon loop of transfer RNA acceptors for the amino acids tyrosine, asparagine, aspartic acid, and histidine. Because it is exclusively synthesized by bacteria, higher eukaryotes must salvage queuosine or its nucleobase queuine from food and the gut microflora. Previously, animals made deficient in queuine died within 18 days of withdrawing tyrosine, a nonessential amino acid, from the diet (Marks, T., and Farkas, W. R. (1997) Biochem. Biophys. Res. Commun. 230, 233-237). Here, we show that human HepG2 cells deficient in queuine and mice made deficient in queuosine-modified transfer RNA, by disruption of the tRNA guanine transglycosylase enzyme, are compromised in their ability to produce tyrosine from phenylalanine. This has similarities to the disease phenylketonuria, which arises from mutation in the enzyme phenylalanine hydroxylase or from a decrease in the supply of its cofactor tetrahydrobiopterin (BH4). Immunoblot and kinetic analysis of liver from tRNA guanine transglycosylase-deficient animals indicates normal expression and activity of phenylalanine hydroxylase. By contrast, BH4 levels are significantly decreased in the plasma, and both plasma and urine show a clear elevation in dihydrobiopterin, an oxidation product of BH4, despite normal activity of the salvage enzyme dihydrofolate reductase. Our data suggest that queuosine modification limits BH4 oxidation in vivo and thereby potentially impacts on numerous physiological processes in eukaryotes.

Published

2011

29. A role for the universal Kae1/Qri7/YgjD (COG0533) family in tRNA modification.

Author

El Yacoubi B, Hatin I, Deutsch C, Kahveci T, Rousset JP, Iwata-Reuyl D, Murzin AG, and de Crécy-Lagard V

Subjects

Adenosine metabolism, Genetic Complementation Test, Metalloendopeptidases genetics, Mitochondrial Proteins genetics, Multiprotein Complexes, RNA, Transfer genetics, RNA, Transfer metabolism, Saccharomyces cerevisiae growth & development, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Adenosine analogs & derivatives, Metalloendopeptidases metabolism, Mitochondrial Proteins metabolism, RNA, Transfer chemistry, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins metabolism

Abstract

The YgjD/Kae1 family (COG0533) has been on the top-10 list of universally conserved proteins of unknown function for over 5 years. It has been linked to DNA maintenance in bacteria and mitochondria and transcription regulation and telomere homeostasis in eukaryotes, but its actual function has never been found. Based on a comparative genomic and structural analysis, we predicted this family was involved in the biosynthesis of N(6)-threonylcarbamoyl adenosine, a universal modification found at position 37 of tRNAs decoding ANN codons. This was confirmed as a yeast mutant lacking Kae1 is devoid of t(6)A. t(6)A(-) strains were also used to reveal that t(6)A has a critical role in initiation codon restriction to AUG and in restricting frameshifting at tandem ANN codons. We also showed that YaeZ, a YgjD paralog, is required for YgjD function in vivo in bacteria. This work lays the foundation for understanding the pleiotropic role of this universal protein family.

Published

2011

30. Discovery and characterization of an amidinotransferase involved in the modification of archaeal tRNA.

Author

Phillips G, Chikwana VM, Maxwell A, El-Yacoubi B, Swairjo MA, Iwata-Reuyl D, and de Crécy-Lagard V

Subjects

Amidinotransferases chemistry, Amidinotransferases genetics, Amidinotransferases isolation & purification, Archaeal Proteins chemistry, Archaeal Proteins genetics, Archaeal Proteins isolation & purification, Guanosine analogs & derivatives, Guanosine genetics, Guanosine metabolism, Haloferax volcanii genetics, Pentosyltransferases genetics, Pentosyltransferases metabolism, RNA, Archaeal chemistry, RNA, Archaeal genetics, RNA, Transfer chemistry, RNA, Transfer genetics, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins isolation & purification, Recombinant Proteins metabolism, Structural Homology, Protein, Amidinotransferases metabolism, Archaeal Proteins metabolism, Haloferax volcanii enzymology, RNA, Archaeal metabolism, RNA, Transfer metabolism

Abstract

The presence of the 7-deazaguanosine derivative archaeosine (G(+)) at position 15 in tRNA is one of the diagnostic molecular characteristics of the Archaea. The biosynthesis of this modified nucleoside is especially complex, involving the initial production of 7-cyano-7-deazaguanine (preQ(0)), an advanced precursor that is produced in a tRNA-independent portion of the biosynthesis, followed by its insertion into the tRNA by the enzyme tRNA-guanine transglycosylase (arcTGT), which replaces the target guanine base yielding preQ(0)-tRNA. The enzymes responsible for the biosynthesis of preQ(0) were recently identified, but the enzyme(s) catalyzing the conversion of preQ(0)-tRNA to G(+)-tRNA have remained elusive. Using a comparative genomics approach, we identified a protein family implicated in the late stages of archaeosine biosynthesis. Notably, this family is a paralog of arcTGT and is generally annotated as TgtA2. Structure-based alignments comparing arcTGT and TgtA2 reveal that TgtA2 lacks key arcTGT catalytic residues and contains an additional module. We constructed a Haloferax volcanii DeltatgtA2 derivative and demonstrated that tRNA from this strain lacks G(+) and instead accumulates preQ(0). We also cloned the corresponding gene from Methanocaldococcus jannaschii (mj1022) and characterized the purified recombinant enzyme. Recombinant MjTgtA2 was shown to convert preQ(0)-tRNA to G(+)-tRNA using several nitrogen sources and to do so in an ATP-independent process. This is the only example of the conversion of a nitrile to a formamidine known in biology and represents a new class of amidinotransferase chemistry.

Published

2010

31. Zinc-independent folate biosynthesis: genetic, biochemical, and structural investigations reveal new metal dependence for GTP cyclohydrolase IB.

Author

Sankaran B, Bonnett SA, Shah K, Gabriel S, Reddy R, Schimmel P, Rodionov DA, de Crécy-Lagard V, Helmann JD, Iwata-Reuyl D, and Swairjo MA

Subjects

Amino Acid Sequence, Bacillus subtilis genetics, Bacillus subtilis metabolism, Bacterial Proteins genetics, Binding Sites, Chromatography, Gel, Chromatography, High Pressure Liquid, Computational Biology, Crystallography, X-Ray, GTP Cyclohydrolase genetics, Manganese metabolism, Models, Molecular, Molecular Sequence Data, Neisseria gonorrhoeae genetics, Neisseria gonorrhoeae metabolism, Protein Binding, Protein Structure, Secondary, Sequence Homology, Amino Acid, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Folic Acid biosynthesis, GTP Cyclohydrolase chemistry, GTP Cyclohydrolase metabolism, Zinc metabolism

Abstract

GTP cyclohydrolase I (GCYH-I) is an essential Zn(2+)-dependent enzyme that catalyzes the first step of the de novo folate biosynthetic pathway in bacteria and plants, the 7-deazapurine biosynthetic pathway in Bacteria and Archaea, and the biopterin pathway in mammals. We recently reported the discovery of a new prokaryotic-specific GCYH-I (GCYH-IB) that displays no sequence identity to the canonical enzyme and is present in approximately 25% of bacteria, the majority of which lack the canonical GCYH-I (renamed GCYH-IA). Genomic and genetic analyses indicate that in those organisms possessing both enzymes, e.g., Bacillus subtilis, GCYH-IA and -IB are functionally redundant, but differentially expressed. Whereas GCYH-IA is constitutively expressed, GCYH-IB is expressed only under Zn(2+)-limiting conditions. These observations are consistent with the hypothesis that GCYH-IB functions to allow folate biosynthesis during Zn(2+) starvation. Here, we present biochemical and structural data showing that bacterial GCYH-IB, like GCYH-IA, belongs to the tunneling-fold (T-fold) superfamily. However, the GCYH-IA and -IB enzymes exhibit significant differences in global structure and active-site architecture. While GCYH-IA is a unimodular, homodecameric, Zn(2+)-dependent enzyme, GCYH-IB is a bimodular, homotetrameric enzyme activated by a variety of divalent cations. The structure of GCYH-IB and the broad metal dependence exhibited by this enzyme further underscore the mechanistic plasticity that is emerging for the T-fold superfamily. Notably, while humans possess the canonical GCYH-IA enzyme, many clinically important human pathogens possess only the GCYH-IB enzyme, suggesting that this enzyme is a potential new molecular target for antibacterial development.

Published

2009

32. Biosynthesis of 7-deazaguanosine-modified tRNA nucleosides: a new role for GTP cyclohydrolase I.

Author

Phillips G, El Yacoubi B, Lyons B, Alvarez S, Iwata-Reuyl D, and de Crécy-Lagard V

Subjects

Cluster Analysis, Comparative Genomic Hybridization, Computational Biology, Escherichia coli enzymology, Escherichia coli Proteins genetics, GTP Cyclohydrolase genetics, Guanosine biosynthesis, Haloferax volcanii enzymology, Haloferax volcanii genetics, Nucleoside Q biosynthesis, Phylogeny, RNA, Bacterial biosynthesis, Escherichia coli genetics, Escherichia coli Proteins metabolism, GTP Cyclohydrolase metabolism, Guanosine analogs & derivatives, RNA, Transfer biosynthesis

Abstract

Queuosine (Q) and archaeosine (G(+)) are hypermodified ribonucleosides found in tRNA. Q is present in the anticodon region of tRNA(GUN) in Eukarya and Bacteria, while G(+) is found at position 15 in the D-loop of archaeal tRNA. Prokaryotes produce these 7-deazaguanosine derivatives de novo from GTP through the 7-cyano-7-deazaguanine (pre-Q(0)) intermediate, but mammals import the free base, queuine, obtained from the diet or the intestinal flora. By combining the results of comparative genomic analysis with those of genetic studies, we show that the first enzyme of the folate pathway, GTP cyclohydrolase I (GCYH-I), encoded in Escherichia coli by folE, is also the first enzyme of pre-Q(0) biosynthesis in both prokaryotic kingdoms. Indeed, tRNA extracted from an E. coli DeltafolE strain is devoid of Q and the deficiency is complemented by expressing GCYH-I-encoding genes from different bacterial or archaeal origins. In a similar fashion, tRNA extracted from a Haloferax volcanii strain carrying a deletion of the GCYH-I-encoding gene contains only traces of G(+). These results link the production of a tRNA-modified base to primary metabolism and further clarify the biosynthetic pathway for these complex modified nucleosides.

Published

2008

33. An embarrassment of riches: the enzymology of RNA modification.

Author

Iwata-Reuyl D

Subjects

Nucleoside Q biosynthesis, Sulfur metabolism, Thiouridine metabolism, Enzymes metabolism, RNA Processing, Post-Transcriptional, RNA, Transfer metabolism

Abstract

The maturation of transfer RNA (tRNA) involves extensive chemical modification of the constituent nucleosides and results in the introduction of significant chemical diversity to tRNA. Many of the pathways to these modified nucleosides are characterized by chemically complex transformations, some of which are unprecedented in other areas of biology. To illustrate the scope of the field, recent progress in understanding the enzymology leading to the formation of two distinct classes of modified nucleosides, the thiouridines and queuosine, a 7-deazaguanosine, is reviewed. In particular, recent data validating the involvement of several proposed intermediates in the formation of thiouridines are discussed, including two key enzyme intermediates and the activated tRNA intermediate. The discovery and mechanistic characterization of a new enzyme activity in the queuosine pathway is discussed.

Published

2008

34. Mechanistic studies of Bacillus subtilis QueF, the nitrile oxidoreductase involved in queuosine biosynthesis.

Author

Lee BW, Van Lanen SG, and Iwata-Reuyl D

Subjects

Bacterial Proteins chemistry, Bacterial Proteins metabolism, Enzyme Activation drug effects, Hydrogen-Ion Concentration, Kinetics, Models, Biological, Mutant Proteins chemistry, Mutant Proteins metabolism, NADP metabolism, Salts pharmacology, Substrate Specificity, Titrimetry, Bacillus subtilis enzymology, Nitriles metabolism, Nucleoside Q biosynthesis, Oxidoreductases chemistry, Oxidoreductases metabolism

Abstract

The enzyme QueF was recently identified as an enzyme involved in the biosynthesis of queuosine, a 7-deazaguanosine modified nucleoside found in bacterial and eukaryotic tRNA. QueF exhibits sequence homology to the type I GTP cyclohydrolases characterized by FolE, but contrary to the predictions based on sequence analysis the enzyme in fact catalyzes a mechanistically unrelated reaction, the NADPH-dependent reduction of 7-cyano-7-deazaguanine (preQ0) to 7-aminomethyl-7-deazaguanine (preQ1), a late step in the queuosine pathway. The reduction of a nitrile is unprecedented in biology, and we report here characterization and mechanistic studies of the enzyme from Bacillus subtilis. The recombinant enzyme exhibits optimal activity at pH 7.5 and moderate ionic strength, and is not dependent on metal ions for catalytic activity. Steady-state kinetic analysis provided a kcat = 0.66 +/- 0.04 min-1, KM (preQ0) = 0.237 +/- 0.045 microM, and KM (NADPH) = 19.2 +/- 1.1 microM. Based on sequence analysis and homology modeling we predicted previously that Cys55 would be present in the active site and in proximity to the nitrile group of preQ0. Consistent with that prediction we observed that the enzyme was inactivated when preincubated with iodoacetamide, and protected from inactivation when preQ0 was present. Furthermore, titrations of the enzyme with preQ0 in the absence of NADPH were accompanied by the appearance of a new absorption band at 376 nm in the UV-vis spectrum consistent with the formation of an alpha,beta-unsaturated thioimide. Site-directed mutagenesis of Cys55 to Ala or Ser resulted in loss of catalytic activity and no absorption at 376 nm upon addition of preQ0. Based on our data we propose a chemical mechanism for the enzyme-catalyzed reaction, and a chemical rationale for the observation of covalent catalysis.

Published

2007

35. A riboswitch selective for the queuosine precursor preQ1 contains an unusually small aptamer domain.

Author

Roth A, Winkler WC, Regulski EE, Lee BW, Lim J, Jona I, Barrick JE, Ritwik A, Kim JN, Welz R, Iwata-Reuyl D, and Breaker RR

Subjects

5' Untranslated Regions genetics, Aptamers, Nucleotide genetics, Base Pairing genetics, Base Sequence, Conserved Sequence, Dialysis, Gene Expression Regulation, Bacterial, Genes, Bacterial, Molecular Sequence Data, Nucleoside Q chemistry, Phylogeny, Pyrimidinones chemistry, Pyrroles chemistry, RNA, Bacterial chemistry, RNA, Bacterial genetics, Aptamers, Nucleotide chemistry, Bacillus subtilis genetics, Nucleoside Q metabolism, Pyrimidinones metabolism, Pyrroles metabolism, Regulatory Sequences, Ribonucleic Acid

Abstract

A previous bioinformatics-based search for riboswitches yielded several candidate motifs in eubacteria. One of these motifs commonly resides in the 5' untranslated regions of genes involved in the biosynthesis of queuosine (Q), a hypermodified nucleoside occupying the anticodon wobble position of certain transfer RNAs. Here we show that this structured RNA is part of a riboswitch selective for 7-aminomethyl-7-deazaguanine (preQ(1)), an intermediate in queuosine biosynthesis. Compared with other natural metabolite-binding RNAs, the preQ(1) aptamer appears to have a simple structure, consisting of a single stem-loop and a short tail sequence that together are formed from as few as 34 nucleotides. Despite its small size, this aptamer is highly selective for its cognate ligand in vitro and has an affinity for preQ(1) in the low nanomolar range. Relatively compact RNA structures can therefore serve effectively as metabolite receptors to regulate gene expression.

Published

2007

36. Discovery of a new prokaryotic type I GTP cyclohydrolase family.

Author

El Yacoubi B, Bonnett S, Anderson JN, Swairjo MA, Iwata-Reuyl D, and de Crécy-Lagard V

Subjects

Acinetobacter enzymology, Acinetobacter genetics, Amino Acid Sequence, Archaea enzymology, Archaea genetics, Bacillus subtilis enzymology, Bacillus subtilis genetics, Bacteria genetics, Base Sequence, DNA, Bacterial genetics, GTP Cyclohydrolase chemistry, GTP Cyclohydrolase classification, GTP Cyclohydrolase genetics, Genes, Bacterial, Genetic Complementation Test, Humans, Molecular Sequence Data, Neisseria gonorrhoeae enzymology, Neisseria gonorrhoeae genetics, Phylogeny, Sequence Homology, Amino Acid, Species Specificity, Thermotoga maritima enzymology, Thermotoga maritima genetics, Bacteria enzymology, GTP Cyclohydrolase metabolism, Prokaryotic Cells enzymology

Abstract

GTP cyclohydrolase I (GCYH-I) is the first enzyme of the de novo tetrahydrofolate biosynthetic pathway present in bacteria, fungi, and plants, and encoded in Escherichia coli by the folE gene. It is also the first enzyme of the biopterin (BH4) pathway in Homo sapiens, where it is encoded by a homologous folE gene. A homology-based search of GCYH-I orthologs in all sequenced bacteria revealed a group of microbes, including several clinically important pathogens, that encoded all of the enzymes of the tetrahydrofolate biosynthesis pathway but GCYH-I, suggesting that an alternate family was present in these organisms. A prediction based on phylogenetic occurrence and physical clustering identified the COG1469 family as a potential candidate for this missing enzyme family. The GCYH-I activity of COG1469 family proteins from a variety of sources (Thermotoga maritima, Bacillus subtilis, Acinetobacter baylyi, and Neisseria gonorrhoeae) was experimentally verified in vivo and/or in vitro. Although there is no detectable sequence homology with the canonical GCYH-I, protein fold recognition based on sequence profiles, secondary structure, and solvation potential information suggests that, like GCYH-I proteins, COG1469 proteins are members of the tunnel-fold (T-fold) structural superfamily. This new GCYH-I family is found in approximately 20% of sequenced bacteria and is prevalent in Archaea, but the family is to this date absent in Eukarya.

Published

2006

37. The subsystems approach to genome annotation and its use in the project to annotate 1000 genomes.

Author

Overbeek R, Begley T, Butler RM, Choudhuri JV, Chuang HY, Cohoon M, de Crécy-Lagard V, Diaz N, Disz T, Edwards R, Fonstein M, Frank ED, Gerdes S, Glass EM, Goesmann A, Hanson A, Iwata-Reuyl D, Jensen R, Jamshidi N, Krause L, Kubal M, Larsen N, Linke B, McHardy AC, Meyer F, Neuweger H, Olsen G, Olson R, Osterman A, Portnoy V, Pusch GD, Rodionov DA, Rückert C, Steiner J, Stevens R, Thiele I, Vassieva O, Ye Y, Zagnitko O, and Vonstein V

Subjects

Acyl Coenzyme A metabolism, Coenzyme A biosynthesis, Computational Biology, Internet, Leucine metabolism, Ribosomal Proteins classification, Terminology as Topic, Vocabulary, Controlled, Genome, Archaeal, Genome, Bacterial, Genomics methods, Software

Abstract

The release of the 1000th complete microbial genome will occur in the next two to three years. In anticipation of this milestone, the Fellowship for Interpretation of Genomes (FIG) launched the Project to Annotate 1000 Genomes. The project is built around the principle that the key to improved accuracy in high-throughput annotation technology is to have experts annotate single subsystems over the complete collection of genomes, rather than having an annotation expert attempt to annotate all of the genes in a single genome. Using the subsystems approach, all of the genes implementing the subsystem are analyzed by an expert in that subsystem. An annotation environment was created where populated subsystems are curated and projected to new genomes. A portable notion of a populated subsystem was defined, and tools developed for exchanging and curating these objects. Tools were also developed to resolve conflicts between populated subsystems. The SEED is the first annotation environment that supports this model of annotation. Here, we describe the subsystem approach, and offer the first release of our growing library of populated subsystems. The initial release of data includes 180 177 distinct proteins with 2133 distinct functional roles. This data comes from 173 subsystems and 383 different organisms.

Published

2005

38. Crystallization and preliminary X-ray characterization of the nitrile reductase QueF: a queuosine-biosynthesis enzyme.

Author

Swairjo MA, Reddy RR, Lee B, Van Lanen SG, Brown S, de Crécy-Lagard V, Iwata-Reuyl D, and Schimmel P

Subjects

Bacillus subtilis metabolism, Catalysis, Computational Biology, Crystallization, GTP Cyclohydrolase chemistry, Guanine analogs & derivatives, Guanine chemistry, Models, Chemical, Models, Molecular, NADP chemistry, Protein Conformation, Protein Isoforms, Protein Structure, Tertiary, Pyrimidinones chemistry, Pyrroles chemistry, RNA Processing, Post-Transcriptional, RNA, Transfer chemistry, X-Ray Diffraction, Bacillus subtilis enzymology, Crystallography, X-Ray methods, Nucleoside Q chemistry, Oxidoreductases chemistry

Abstract

QueF (MW = 19.4 kDa) is a recently characterized nitrile oxidoreductase which catalyzes the NADPH-dependent reduction of 7-cyano-7-deazaguanine (preQ0) to 7-aminomethyl-7-deazaguanine, a late step in the biosynthesis of the modified tRNA nucleoside queuosine. Initial crystals of homododecameric Bacillus subtilis QueF diffracted poorly to 8.0 A. A three-dimensional model based on homology with the tunnel-fold enzyme GTP cyclohydrolase I suggested catalysis at intersubunit interfaces and a potential role for substrate binding in quaternary structure stabilization. Guided by this insight, a second crystal form was grown that was strictly dependent on the presence of preQ0. This crystal form diffracted to 2.25 A resolution.

Published

2005

39. From cyclohydrolase to oxidoreductase: discovery of nitrile reductase activity in a common fold.

Author

Van Lanen SG, Reader JS, Swairjo MA, de Crécy-Lagard V, Lee B, and Iwata-Reuyl D

Subjects

Acinetobacter enzymology, Acinetobacter genetics, Amino Acid Sequence, Bacillus subtilis genetics, Base Sequence, DNA, Bacterial genetics, Escherichia coli genetics, GTP Cyclohydrolase genetics, Genes, Bacterial, Molecular Sequence Data, Nucleoside Q biosynthesis, Oxidoreductases genetics, Protein Folding, Recombinant Fusion Proteins chemistry, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Sequence Homology, Amino Acid, Bacillus subtilis enzymology, Escherichia coli enzymology, GTP Cyclohydrolase chemistry, GTP Cyclohydrolase metabolism, Oxidoreductases chemistry, Oxidoreductases metabolism

Abstract

The enzyme YkvM from Bacillus subtilis was identified previously along with three other enzymes (YkvJKL) in a bioinformatics search for enzymes involved in the biosynthesis of queuosine, a 7-deazaguanine modified nucleoside found in tRNA(GUN) of Bacteria and Eukarya. Genetic analysis of ykvJKLM mutants in Acinetobacter confirmed that each was essential for queuosine biosynthesis, and the genes were renamed queCDEF. QueF exhibits significant homology to the type I GTP cyclohydrolases characterized by FolE. Given that GTP is the precursor to queuosine and that a cyclohydrolase-like reaction was postulated as the initial step in queuosine biosynthesis, QueF was proposed to be the putative cyclohydrolase-like enzyme responsible for this reaction. We have cloned the queF genes from B. subtilis and Escherichia coli and characterized the recombinant enzymes. Contrary to the predictions based on sequence analysis, we discovered that the enzymes, in fact, catalyze a mechanistically unrelated reaction, the NADPH-dependent reduction of 7-cyano-7-deazaguanineto7-aminomethyl-7-deazaguanine, a late step in the biosynthesis of queuosine. We report here in vitro and in vivo studies that demonstrate this catalytic activity, as well as preliminary biochemical and bioinformatics analysis that provide insight into the structure of this family of enzymes.

Published

2005

40. Kinetic mechanism of the tRNA-modifying enzyme S-adenosylmethionine:tRNA ribosyltransferase-isomerase (QueA).

Author

Van Lanen SG and Iwata-Reuyl D

Subjects

Adenosine chemistry, Adenosine pharmacology, Binding, Competitive, Catalysis, Isomerases, Kinetics, Magnetic Resonance Spectroscopy, Nucleoside Q metabolism, Pentosyltransferases antagonists & inhibitors, Ribose metabolism, S-Adenosylhomocysteine chemistry, S-Adenosylhomocysteine pharmacology, S-Adenosylmethionine pharmacology, Adenosine analogs & derivatives, Escherichia coli enzymology, Pentosyltransferases chemistry, Pentosyltransferases metabolism, RNA, Transfer metabolism, S-Adenosylmethionine chemistry

Abstract

The bacterial enzyme S-adenosylmethionine:tRNA ribosyltransferase-isomerase (QueA) catalyzes the unprecedented transfer and isomerization of the ribosyl moiety of S-adenosylmethionine (AdoMet) to a modified tRNA nucleoside in the biosynthesis of the hypermodified nucleoside queuosine. The complexity of this reaction makes it a compelling problem in fundamental mechanistic enzymology, and as part of our mechanistic studies of the QueA-catalyzed reaction, we report here the elucidation of the steady-state kinetic mechanism. Bi-substrate kinetic analysis gave initial velocity patterns indicating a sequential mechanism, and provided the following kinetic constants: K (M)(tRNA)= 1.9 +/- 0.7 microM and K (M)(AdoMet)= 98 +/- 5.0 microM. Dead-end inhibition studies with the substrate analogues S-adenosylhomocysteine and sinefungin gave competitive inhibition patterns against AdoMet and noncompetitive patterns against preQ(1)-tRNA(Tyr), with K(i) values of 133 +/- 18 and 4.6 +/- 0.5 microM for sinefungin and S-adenosylhomocysteine, respectively. Product inhibition by adenine was noncompetitive against both substrates under conditions with a subsaturating cosubstrate concentration and uncompetitive against preQ(1)-tRNA(Tyr) when AdoMet was saturating. Inhibition by the tRNA product (oQ-tRNA(Tyr)) was competitive and noncompetitive against the substrates preQ(1)-tRNA(Tyr) and AdoMet, respectively. Inhibition by methionine was uncompetitive versus preQ(1)-tRNA(Tyr), but noncompetitive against AdoMet. However, when methionine inhibition was investigated at high AdoMet concentrations, the pattern was uncompetitive. Taken together, the data are consistent with a fully ordered sequential bi-ter kinetic mechanism in which preQ(1)-tRNA(Tyr) binds first followed by AdoMet, with product release in the order adenine, methionine, and oQ-tRNA. The chemical mechanism that we previously proposed for the QueA-catalyzed reaction [Daoud Kinzie, S., Thern, B., and Iwata-Reuyl, D. (2000) Org. Lett. 2, 1307-1310] is consistent with the constraints imposed by the kinetic mechanism determined here, and we suggest that the magnitude of the inhibition constants for the dead-end inhibitors may provide insight into the catalytic strategy employed by the enzyme.

Published

2003

41. Bacterial phytoene synthase: molecular cloning, expression, and characterization of Erwinia herbicola phytoene synthase.

Author

Iwata-Reuyl D, Math SK, Desai SB, and Poulter CD

Subjects

Alkyl and Aryl Transferases chemistry, Alkyl and Aryl Transferases isolation & purification, Alkyl and Aryl Transferases metabolism, Base Sequence, Chromatography, Affinity methods, Cloning, Molecular, DNA Primers, Electrophoresis, Polyacrylamide Gel, Escherichia coli genetics, Genes, Bacterial, Geranylgeranyl-Diphosphate Geranylgeranyltransferase, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins isolation & purification, Recombinant Proteins metabolism, Alkyl and Aryl Transferases genetics, Erwinia enzymology

Abstract

Phytoene synthase (PSase) catalyzes the condensation of two molecules of geranylgeranyl diphosphate (GGPP) to give prephytoene diphosphate (PPPP) and the subsequent rearrangement of the cyclopropylcarbinyl intermediate to phytoene. These reactions constitute the first pathway specific step in carotenoid biosynthesis. The crtB gene encoding phytoene synthase was isolated from a plasmid containing the carotenoid gene cluster in Erwinia herbicola and cloned into an Escherichia coli expression system. Upon induction, recombinant phytoene synthase constituted 5-10% of total soluble protein. To facilitate purification of the recombinant enzyme, the structural gene for PSase was modified by site-directed mutagenesis to incorporate a C-terminal Glu-Glu-Phe (EEF) tripepetide to allow purification by immunoaffinity chromatography on an immobilized monoclonal anti-alpha-tubulin antibody YL1/2 column. Purified recombinant PSase-EEF gave a band at 34.5 kDa upon SDS-PAGE. Recombinant PSase-EEF was then purified to >90% homogeneity in two steps by ion-exchange and immunoaffinity chromatography. The enzyme required Mn(2+) for activity, had a pH optimum of 8.2, and was strongly stimulated by detergent. The concentration of GGPP needed for half-maximal activity was approximately 35 microM, and a significant inhibition of activity was seen at GGPP concentrations above 100 microM. The sole product of the reaction was 15,15'-Z-phytoene.

Published

2003

42. tRNA modification by S-adenosylmethionine:tRNA ribosyltransferase-isomerase. Assay development and characterization of the recombinant enzyme.

Author

Van Lanen SG, Kinzie SD, Matthieu S, Link T, Culp J, and Iwata-Reuyl D

Subjects

Catalysis, Genetic Vectors, Glutathione Transferase metabolism, Hydrogen-Ion Concentration, Isomerases, Kinetics, Magnesium pharmacology, Recombinant Proteins metabolism, Pentosyltransferases metabolism, RNA, Transfer metabolism

Abstract

The enzyme S-adenosylmethionine:tRNA ribosyltransferase-isomerase catalyzes the penultimate step in the biosynthesis of the hypermodified tRNA nucleoside queuosine (Q), an unprecedented ribosyl transfer from the cofactor S-adenosylmethionine (AdoMet) to a modified-tRNA precursor to generate epoxyqueuosine (oQ). The complexity of the reaction makes it an especially interesting mechanistic problem, and as a foundation for detailed kinetic and mechanistic studies we have carried out the basic characterization of the enzyme. Importantly, to allow for the direct measurement of oQ formation, we have developed protocols for the preparation of homogeneous substrates; specifically, an overexpression system was constructed for tRNA(Tyr) in an E. coli queA deletion mutant to allow for the isolation of large quantities of substrate tRNA, and [U-ribosyl-(14)C]AdoMet was synthesized. The enzyme shows optimal activity at pH 8.7 in buffers containing various oxyanions, including acetate, carbonate, EDTA, and phosphate. Unexpectedly, the enzyme was inhibited by Mg(2+) and Mn(2+) in millimolar concentrations. The steady-state kinetic parameters were determined to be K(m)(AdoMet) = 101.4 microm, K(m)(tRNA) = 1.5 microm, and k(cat) = 2.5 min(-1). A short minihelix RNA was synthesized and modified with the precursor 7-aminomethyl-7-deazaguanine, and this served as an efficient substrate for the enzyme (K(m)(RNA) = 37.7 microm and k(cat) = 14.7 min(-1)), demonstrating that the anticodon stem-loop is sufficient for recognition and catalysis by QueA.

Published

2003

43. Biosynthesis of the 7-deazaguanosine hypermodified nucleosides of transfer RNA.

Author

Iwata-Reuyl D

Subjects

Catalysis, Nucleoside Q biosynthesis, Nucleoside Q chemistry, Pentosyltransferases chemistry, RNA, Transfer biosynthesis, Guanosine analogs & derivatives, Guanosine biosynthesis, Guanosine chemistry, Nucleosides biosynthesis, Nucleosides chemistry, Pentosyltransferases metabolism, RNA, Transfer chemistry, RNA, Transfer metabolism

Abstract

Transfer RNA (tRNA) is structurally unique among nucleic acids in harboring an astonishing diversity of post-transcriptionally modified nucleoside. Two of the most radically modified nucleosides known to occur in tRNA are queuosine and archaeosine, both of which are characterized by a 7-deazaguanosine core structure. In spite of the phylogenetic segregation observed for these nucleosides (queuosine is present in Eukarya and Bacteria, while archaeosine is present only in Archaea), their structural similarity suggested a common biosynthetic origin, and recent biochemical and genetic studies have provided compelling evidence that a significant portion of their biosynthesis may in fact be identical. This review covers current understanding of the physiology and biosynthesis of these remarkable nucleosides, with particular emphasis on the only two enzymes that have been discovered in the pathways: tRNA-guanine transglycosylase (TGT), which catalyzes the insertion of a modified base into the polynucleotide with the concomitant elimination of the genetically encoded guanine in the biosynthesis of both nucleosides, and S-adenosylmethionine:tRNA ribosyltransferase-isomerase (QueA), which catalyzes the penultimate step in the biosynthesis of queuosine, the construction of the carbocyclic side chain.

Published

2003

44. Mechanistic studies of the tRNA-modifying enzyme QueA: a chemical imperative for the use of AdoMet as a "ribosyl" donor.

Author

Kinzie SD, Thern B, and Iwata-Reuyl D

Subjects

Isomerases, Magnetic Resonance Spectroscopy, Nucleoside Q biosynthesis, RNA, Transfer metabolism, Ribose metabolism, Pentosyltransferases chemistry, Pentosyltransferases metabolism, S-Adenosylmethionine chemistry

Abstract

[formula: see text] The enzyme S-adenosylmethionine:tRNA ribosyltransferase-isomerase (QueA) catalyzes the penultimate step in the biosynthesis of the tRNA nucleoside queuosine, a unique ribosyl transfer from the cofactor S-adenosylmethionine (AdoMet) to a modified-tRNA precursor. The use of AdoMet in this way is fundamentally new to the chemistry of this important biological cofactor. We report here the first mechanistic studies of this remarkable enzyme, and we propose a chemical mechanism for the reaction consistent with our experimental observations.

Published

2000

45. Synthesis and reaction of potential alternate substrates and mechanism-based inhibitors of clavaminate synthase.

Author

Iwata-Reuyl D, Basak A, Silverman LS, Engle CA, and Townsend CA

Subjects

Clavulanic Acids chemical synthesis, Clavulanic Acids chemistry, Cyclization, Hydroxylation, Indicators and Reagents, Molecular Conformation, Prodrugs chemistry, Stereoisomerism, Structure-Activity Relationship, Substrate Specificity, Trimethylsilyl Compounds chemistry, Aza Compounds chemistry, Mixed Function Oxygenases antagonists & inhibitors, Mixed Function Oxygenases chemistry

Abstract

Clavaminate synthase is an FeII/alpha-ketoglutarate-dependent enzyme central to the biosynthesis of the beta-lactamase inhibitor clavulanic acid. In the presence of dioxygen it catalyzes the oxidative cyclization/desaturation of proclavaminic acid to clavaminic acid in a two-step process. Samples of (4'R)- and (4'S)-D,L-[4'-2H]proclavaminic acid have been prepared and used to demonstrate that oxazolidine ring formation occurs with retention of configuration. The stereochemical course of oxygen insertion from substrate that takes place in this oxidative cyclization is the same as that observed from molecular oxygen in several hydroxylation reactions catalyzed by other FeII/alpha-ketoglutarate-dependent enzymes. The ferryl (FeIV = O) species thought to be transiently involved in each of these processes was investigated in the present work with clavaminate synthase and three structural analogues of proclavaminic acid bearing vinyl or ethynyl groups at C-4' or a cyclopropyl at C-4. In the synthesis of the former two derivatives and proclavaminic acid stereoselectively labeled with deuterium at C-4', introduction of the unsaturated substituents in a stereochemically defined manner at C-4' relied upon ready access to (4R)-4-thiophenyl-2-azetidinone. Trimethylsilyl substitution could be easily achieved at C-3 of the optically pure starting material to give the readily separable cis and trans diastereomers. In radical chain reactions in which the thiophenyl was replaced by deuterium or in anionic reactions in which the thiophenyl was eliminated as its sulfone and replaced by addition of carbanions, the steric bulk of the trimethylsilyl group at C-3 governed the approach of incoming reagents to give the trans product. The enzymatic fate, however, of these derivatives was disappointing, yielding neither detectable reaction nor hoped-for inactivation of clavaminate synthase. Finally, as mixed competitive/noncompetitive inhibitors of catalysis, they gave unexceptional inhibition constants in the range 2-10 mM.

Published

1993

46. Elucidation of the order of oxidations and identification of an intermediate in the multistep clavaminate synthase reaction.

Author

Salowe SP, Krol WJ, Iwata-Reuyl D, and Townsend CA

Subjects

Anti-Bacterial Agents biosynthesis, Carbon Radioisotopes, Clavulanic Acids chemical synthesis, Indicators and Reagents, Kinetics, Oxidation-Reduction, Radioisotope Dilution Technique, Stereoisomerism, Streptomyces enzymology, Tritium, Clavulanic Acids biosynthesis, Mixed Function Oxygenases metabolism

Abstract

The enzyme clavaminate synthase (CS) catalyzes the formation of the first bicyclic intermediate in the biosynthetic pathway to the potent beta-lactamase inhibitor clavulanic acid. Our previous work has led to the proposal that the cyclization/desaturation of the substrate proclavaminate proceeds in two oxidative steps, each coupled to a decarboxylation of alpha-ketoglutarate and a reduction of dioxygen to water [Salowe, S. P., Marsh, E. N., & Townsend, C. A. (1990) Biochemistry 29, 6499-6508]. We have now employed kinetic isotope effect studies to determine the order of oxidations for CS purified from Streptomyces clavuligerus. By using (4'RS)-[4'-3H,1-14C]-rac-proclavaminate, a primary T(V/K) = 8.3 +/- 0.2 was measured from [3H]water release data, while an alpha-secondary T(V/K) = 1.06 +/- 0.01 was determined from the changing 3H/14C ratio of the product clavaminate. Values for the primary and alpha-secondary effects of 11.9 +/- 1.7 and 1.12 +/- 0.07, respectively, were obtained from the changing 3H/14C ratio of the residual proclavaminate by using new equations derived for a racemic substrate bearing isotopic label at both primary and alpha-secondary positions. Since only the first step of consecutive irreversible reactions will exhibit a V/K isotope effect, we conclude that C-4' is the initial site of oxidation in proclavaminate. As expected, no significant changes in the 3H/14C ratio of residual substrate were observed with [3-3H,1-14C]-rac-proclavaminate. However, two new tritiated compounds were produced in this incubation, apparently the result of isotope-induced branching brought about by the presence of tritium at the site of the second oxidation. One of these compounds was identified by comparison to authentic material as dihydroclavaminate, a stable intermediate that normally remains enzyme-bound. On the basis of the body of information available and the similarities to alpha-ketoglutarate-dependent dioxygenases, a comprehensive mechanistic scheme for CS is proposed to account for this unusual enzymatic transformation.

Published

1991