2021
Structural analyses of an RNA stability element interacting with poly(A)
Torabi SF, Chen YL, Zhang K, Wang J, DeGregorio SJ, Vaidya AT, Su Z, Pabit SA, Chiu W, Pollack L, Steitz JA. Structural analyses of an RNA stability element interacting with poly(A). Proceedings Of The National Academy Of Sciences Of The United States Of America 2021, 118: e2026656118. PMID: 33785601, PMCID: PMC8040590, DOI: 10.1073/pnas.2026656118.Peer-Reviewed Original ResearchConceptsRNA stability elementCis-acting RNA elementsGlobal conformational changesRich internal loopCryo-electron microscopyRice transposable elementsDiverse genomesDouble-helical regionsSmall-angle X-ray scatteringEne motifTransposable elementsGlobal structural changesRNA interactionsRNA stabilityBioinformatics studiesRNA elementsStability elementShort helixConformational changesDecay pathwaysInternal loopBiochemical structureTriplex structureBindingMotif
2018
Crystallographic evidence for two‐metal‐ion catalysis in human pol η
Wang J, Smithline ZB. Crystallographic evidence for two‐metal‐ion catalysis in human pol η. Protein Science 2018, 28: 439-447. PMID: 30368948, PMCID: PMC6319759, DOI: 10.1002/pro.3541.Peer-Reviewed Original ResearchConceptsMetal ionsProduct pyrophosphateChemical reactionsTwo-metal-ion catalysisTwo-metal-ion catalytic mechanismThird metal ionPhosphoryl transfer reactionsTransfer reactionsCrystallographic dataCatalytic mechanismCrystal structureCrystallographic evidenceHuman Pol ηMeal ionsIonsHuman polymerase ηCatalysisReactionComplexesSubPyrophosphateBindingProductsDNA polymeraseCrystals
2014
The mechanism of Torsin ATPase activation
Brown RS, Zhao C, Chase AR, Wang J, Schlieker C. The mechanism of Torsin ATPase activation. Proceedings Of The National Academy Of Sciences Of The United States Of America 2014, 111: e4822-e4831. PMID: 25352667, PMCID: PMC4234599, DOI: 10.1073/pnas.1415271111.Peer-Reviewed Original Research
2011
Structural Basis of Cooperative Ligand Binding by the Glycine Riboswitch
Butler EB, Xiong Y, Wang J, Strobel SA. Structural Basis of Cooperative Ligand Binding by the Glycine Riboswitch. Cell Chemical Biology 2011, 18: 293-298. PMID: 21439473, PMCID: PMC3076126, DOI: 10.1016/j.chembiol.2011.01.013.Peer-Reviewed Original ResearchConceptsGlycine riboswitchStructural basisGene expressionÅ crystal structureTandem riboswitchesCooperative ligand bindingRiboswitchLigand bindingTandem pairMinor contactsBinding sitesAmino acid ligandsCooperative recognitionExpressionExtensive networkOperonFusobacterium nucleatumAptamerCrystal structureGlycine binding siteBindingLigandsInteractionAcid ligands
2009
Structure of apo-CAP reveals that large conformational changes are necessary for DNA binding
Sharma H, Yu S, Kong J, Wang J, Steitz TA. Structure of apo-CAP reveals that large conformational changes are necessary for DNA binding. Proceedings Of The National Academy Of Sciences Of The United States Of America 2009, 106: 16604-16609. PMID: 19805344, PMCID: PMC2745332, DOI: 10.1073/pnas.0908380106.Peer-Reviewed Original ResearchConceptsColi catabolite gene activator proteinEscherichia coli catabolite gene activator proteinCatabolite gene activator proteinC-helixConformational changesGene activator proteinDNA binding domainsDNA recognition helixEarlier biochemical dataLarge conformational changesSpecific DNA sequencesBinding of cAMPRecognition helixActivator proteinDNA sequencesDNA bindingBinding domainsActive DNAWT structureInactive formInactive structureBiochemical dataDifferent conformationsBindingConformation
2004
The structure of a ribosomal protein S8/spc operon mRNA complex
Merianos HJ, Wang J, Moore PB. The structure of a ribosomal protein S8/spc operon mRNA complex. RNA 2004, 10: 954-964. PMID: 15146079, PMCID: PMC1370587, DOI: 10.1261/rna.7030704.Peer-Reviewed Original ResearchMeSH KeywordsBase SequenceBinding SitesCrystallography, X-RayEscherichia coliEscherichia coli ProteinsGenes, BacterialLigandsMacromolecular SubstancesModels, MolecularNucleic Acid ConformationOperonProtein BiosynthesisRibosomal ProteinsRNA, BacterialRNA, MessengerSpecies SpecificityStatic ElectricityConceptsSpc operon mRNAOperon mRNARibosomal protein cistronsSmall ribosomal subunitRibosomal initiation complexResolution crystal structureProtein synthesis resultsSpc operonAutogenous regulationTranslational repressionInitiation complexOwn mRNARibosomal subunitS8 bindingSequence differencesCistronInternal sequencesMRNAGenesConformational similarityBindingComplexesRetroregulationRRNAsOperon
2000
Sulfolobus shibatae CCA-adding enzyme forms a tetramer upon binding two tRNA molecules: a scrunching-shuttling model of CCA specificity1 1Edited by T. Richmond
Li F, Wang J, Steitz T. Sulfolobus shibatae CCA-adding enzyme forms a tetramer upon binding two tRNA molecules: a scrunching-shuttling model of CCA specificity1 1Edited by T. Richmond. Journal Of Molecular Biology 2000, 304: 483-492. PMID: 11090289, DOI: 10.1006/jmbi.2000.4189.Peer-Reviewed Original ResearchConceptsActive siteMulti-angle laser lightSmall-angle X-ray scatteringSize exclusion chromatographyX-ray scatteringFurther dimerizationExclusion chromatographyMoleculesDimeric enzymeC basesOligomerization stateTetramerTransfer RNA moleculesLaser lightTRNA moleculesRNA moleculesMonomersPrimer strandChromatographyEnzymeDimersHigh specificityBindingCCA-adding enzymeDimerization