about
What RNA World? Why a Peptide/RNA Partnership Merits Renewed Experimental AttentionCommentary: History of the ribosome and the origin of translationComputing the origin and evolution of the ribosome from its structure - Uncovering processes of macromolecular accretion benefiting synthetic biologyHistory of the ribosome and the origin of translationAncestral Insertions and Expansions of rRNA do not Support an Origin of the Ribosome in Its Peptidyl Transferase CenterRibosomal accretion, apriorism and the phylogenetic method: a response to Petrov and WilliamsMajor centers of motion in the large ribosomal RNAsHow amino acids and peptides shaped the RNA worldThe case for an early biological origin of DNAFrozen in Time: The History of Proteins.Absence of knots in known RNA structures.Universal and domain-specific sequences in 23S-28S ribosomal RNA identified by computational phylogeneticsStructure of Ribosomal Silencing Factor Bound to Mycobacterium tuberculosis RibosomeDrivers of Bacterial Maintenance and Minimal Energy Requirements.The ribosome challenge to the RNA world.Surveying the sequence diversity of model prebiotic peptides by mass spectrometry.Dynamic basis of fidelity and speed in translation: Coordinated multistep mechanisms of elongation and termination.The elusive quest for RNA knots.Peptidyl Transferase Center and the Emergence of the Translation System.Generation of ribosome imprinted polymers for sensitive detection of translational responses.The Central Symbiosis of Molecular Biology: Molecules in MutualismThe presence of highly disruptive 16S rRNA mutations in clinical samples indicates a wider role for mutations of the mitochondrial ribosome in human disease.Interdependence, Reflexivity, Fidelity, Impedance Matching, and the Evolution of Genetic Coding.Tuning the ribosome: The influence of rRNA modification on eukaryotic ribosome biogenesis and function.Sequence complementarity at the ribosomal Peptidyl Transferase Centre implies self-replicating origin.Ancestral Interactions of Ribosomal RNA and Ribosomal Proteins.Could a Proto-Ribosome Emerge Spontaneously in the Prebiotic World?Coding of Class I and II Aminoacyl-tRNA Synthetases.The ancient heart of the ribosomal large subunit: a response to Caetano-Anolles.Visualization of conformational variability in the domains of long single-stranded RNA molecules.Variant ribosomal RNA alleles are conserved and exhibit tissue-specific expression.Revising the structural diversity of ribosomal proteins across the three domains of life.Dissecting ribosomal particles throughout the kingdoms of life using advanced hybrid mass spectrometry methods.Small genomes and the difficulty to define minimal translation and metabolic machineriesStructure and function of archaeal histones
P2860
Q26995567-8903FF01-8726-4CE2-BF49-8023C5FA7B7AQ28583162-C843614D-C6E3-4490-97C9-778F7BAD5787Q28601049-69F98354-30B7-4292-944B-FD96B37188E6Q28603688-7ED2140D-947D-4789-A582-710D859A42F3Q28608244-15505A3E-F2AB-40BA-883E-275E67F0626CQ28646272-E1399EBA-608D-4EF8-8552-C6B476F81F43Q28647899-E9EB19D4-A351-492A-9E98-29821E5C1393Q28649982-EF2FDE41-5438-4BD9-982D-80FCD240CEFEQ28650996-9E981BB8-1B58-4844-9AAB-D661636CC22AQ30846747-DFA11EE2-DF82-4F87-901C-7FC9D1BA1654Q35129105-91F399B1-455D-4F68-8362-D303773F17CEQ36072294-B8E86291-C8E7-4F43-8EF7-3D0E6597407AQ36478960-C1FC1920-E74B-493E-8F76-92F620FBFDC1Q37614589-4F57835C-1F88-42E4-9D66-ADACE99922EDQ38367623-51AD438E-07A5-4A42-8FB5-A77352EF11B6Q38605162-B74232C8-BAE3-49D5-A649-1C197C2AA6A1Q39290123-C65B05D3-C9F5-4604-B5A9-D677FB002AF2Q40089845-7BA25590-806E-4CAC-8392-22C6F49C2972Q40994850-C65B1499-80AC-46D3-A881-50207892DB16Q41141228-3794B01C-DF3C-4F2A-8B4C-7A65CCCD14CEQ41581024-91882138-FAFD-4C87-8080-F1F8A00CB835Q41779514-5EE953BA-18D4-4C5D-8230-1C7193AEEB47Q46757795-407BB5F1-3C80-49BF-9FE4-0C46305C5A30Q46904858-B2F4A743-4B23-49E1-9FAD-E04419E7ECD4Q47199299-C43F1580-4B86-4CE3-B616-6FC85F3E3020Q47214444-76B5F8B8-DDC1-426F-B265-13D42AFBBBE8Q47250308-CC090D51-614C-43DA-8BB3-2B20B28331ACQ47325408-D9AE82D1-C0A9-40CB-A9DC-0229A6BB6AF2Q47421482-BE6CDEB7-BA10-4509-B4E1-555F357D856CQ47433822-3D15C90B-5AFF-4E35-904A-3A6F5A8B3698Q50420902-F223C3D1-AB80-4EF3-91C7-533248B6D211Q52359075-0EC4F907-86FB-4D31-B23F-6285F6C6BBD6Q55359327-263C2A42-37EC-42AE-9567-CD50F85F1C69Q57898552-698C5AFA-6334-4DEB-9969-A32B81BB74ADQ58286649-1E255B6F-3F67-44C7-A07E-C90EE1E87443
P2860
description
2014 nî lūn-bûn
@nan
2014 թուականի Յունիսին հրատարակուած գիտական յօդուած
@hyw
2014 թվականի հունիսին հրատարակված գիտական հոդված
@hy
2014年の論文
@ja
2014年論文
@yue
2014年論文
@zh-hant
2014年論文
@zh-hk
2014年論文
@zh-mo
2014年論文
@zh-tw
2014年论文
@wuu
name
Evolution of the ribosome at atomic resolution
@ast
Evolution of the ribosome at atomic resolution
@en
Evolution of the ribosome at atomic resolution
@nl
type
label
Evolution of the ribosome at atomic resolution
@ast
Evolution of the ribosome at atomic resolution
@en
Evolution of the ribosome at atomic resolution
@nl
prefLabel
Evolution of the ribosome at atomic resolution
@ast
Evolution of the ribosome at atomic resolution
@en
Evolution of the ribosome at atomic resolution
@nl
P2093
P2860
P356
P1476
Evolution of the ribosome at atomic resolution
@en
P2093
Anton S Petrov
Ashlyn M Norris
Chiaolong Hsiao
Chris C Waterbury
George E Fox
Loren Dean Williams
Nicholas A Kovacs
Nicholas V Hud
Roger M Wartell
Stephen C Harvey
P2860
P304
10251-10256
P356
10.1073/PNAS.1407205111
P407
P577
2014-06-30T00:00:00Z