2009
The Human SepSecS-tRNASec Complex Reveals the Mechanism of Selenocysteine Formation
Palioura S, Sherrer RL, Steitz TA, Söll D, Simonović M. The Human SepSecS-tRNASec Complex Reveals the Mechanism of Selenocysteine Formation. Science 2009, 325: 321-325. PMID: 19608919, PMCID: PMC2857584, DOI: 10.1126/science.1173755.Peer-Reviewed Original ResearchMeSH KeywordsAmino Acyl-tRNA SynthetasesBase SequenceBiocatalysisCatalytic DomainCrystallography, X-RayHumansHydrogen BondingModels, MolecularMolecular Sequence DataNucleic Acid ConformationPhosphatesPhosphoserineProtein ConformationProtein MultimerizationProtein Structure, SecondaryRNA, Transfer, Amino Acid-SpecificRNA, Transfer, Amino AcylSelenocysteineConceptsTransfer RNASelenocysteine formationSelenocysteinyl-tRNA synthaseCognate transfer RNAEnzyme active siteTRNA bindingActive siteConformational changesEnzyme assaysAmino acidsFree phosphoserinePhosphoserineSepSecSFinal stepSelenocysteineBiosynthesisComplexesRNAMechanismBindsCrystal structureSynthaseBindingFormationAssaysA Cytidine Deaminase Edits C to U in Transfer RNAs in Archaea
Randau L, Stanley BJ, Kohlway A, Mechta S, Xiong Y, Söll D. A Cytidine Deaminase Edits C to U in Transfer RNAs in Archaea. Science 2009, 324: 657-659. PMID: 19407206, PMCID: PMC2857566, DOI: 10.1126/science.1170123.Peer-Reviewed Original ResearchConceptsTransfer RNAArchaeon Methanopyrus kandleriTertiary coreCytidine deaminase domainsTRNA genesTransfer RNAsTHUMP domainProper foldingU editingC deaminationMethanopyrus kandleriTRNA tertiary structureDeaminase domainTertiary structureTRNA tertiary corePosition 8Cytidine deaminaseUnique familyArchaeaRNAsGenesRNAFoldingDomainCrystal structure
2006
A Molecular Tunnel Required for Cooperation of an Asparaginase and a Glu‐tRNAGln Kinase in Gln‐tRNA Formation
Sheppard K, Feng L, Oshikane H, Nakamura Y, Fukai S, Nureki O, Söll D. A Molecular Tunnel Required for Cooperation of an Asparaginase and a Glu‐tRNAGln Kinase in Gln‐tRNA Formation. The FASEB Journal 2006, 20: a503-a503. DOI: 10.1096/fasebj.20.4.a503-a.Peer-Reviewed Original ResearchGlu-tRNAGlnMolecular tunnelMost prokaryotesCo-crystal structurePresence of ATPGln-tRNAGlnSequence similarityEvolutionary linkHeterodimeric enzymeStructural insightsGatDEGatDEnzyme showEnzymatic analysisKinaseAmide donorCrystal structureActive siteATPGlnGluProkaryotesArchaeaTransamidationTight coupling
1996
Aminoacyl-tRNA Synthetases Optimize Both Cognate tRNA Recognition and Discrimination against Noncognate tRNAs †
Sherman J, Söll D. Aminoacyl-tRNA Synthetases Optimize Both Cognate tRNA Recognition and Discrimination against Noncognate tRNAs †. Biochemistry 1996, 35: 601-607. PMID: 8555233, DOI: 10.1021/bi951602b.Peer-Reviewed Original ResearchConceptsTRNA recognitionNoncognate tRNAsEscherichia coli glutaminyl-tRNA synthetaseWild-type GlnRSGlutaminyl-tRNA synthetaseAminoacyl-tRNA synthetasesNucleic acid interactionsGlutamine tRNAFirst base pairMutational analysisSpecific proteinsTRNAGlnRSequence preferenceMutantsBase pairsAcid interactionsDecreased affinityVivoTRNAGlnAffinitySynthetasesProteinSynthetaseCrystal structure
1995
Substrate selection by aminoacyl-tRNA synthetases.
Ibba M, Thomann H, Hong K, Sherman J, Weygand-Durasevic I, Sever S, Stange-Thomann N, Praetorius M, Söll D. Substrate selection by aminoacyl-tRNA synthetases. Nucleic Acids Symposium Series 1995, 40-2. PMID: 8643392.Peer-Reviewed Original Research