| scholarly article | Q13442814 |
| P50 | author | Ivan B Lomakin | Q64539061 |
| P2093 | author name string | Thomas A Steitz | |
| Ivan B Lomakin | |||
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| N- and C-terminal residues of eIF1A have opposing effects on the fidelity of start codon selection | Q35691356 | ||
| Genetic identification of yeast 18S rRNA residues required for efficient recruitment of initiator tRNA(Met) and AUG selection | Q36843520 | ||
| Position of eukaryotic translation initiation factor eIF1A on the 40S ribosomal subunit mapped by directed hydroxyl radical probing. | Q37318477 | ||
| Structure-function insights into prokaryotic and eukaryotic translation initiation. | Q37506795 | ||
| How do eucaryotic ribosomes select initiation regions in messenger RNA? | Q37870587 | ||
| Position of the CrPV IRES on the 40S subunit and factor dependence of IRES/80S ribosome assembly | Q40105027 | ||
| Eukaryotic start and stop translation sites. | Q40504517 | ||
| Kinetic and thermodynamic analysis of the role of start codon/anticodon base pairing during eukaryotic translation initiation | Q42003947 | ||
| The fidelity of translation initiation: reciprocal activities of eIF1, IF3 and YciH. | Q42043465 | ||
| Pi release from eIF2, not GTP hydrolysis, is the step controlled by start-site selection during eukaryotic translation initiation | Q46772123 | ||
| Reconstitution of yeast translation initiation. | Q46968946 | ||
| Communication between eukaryotic translation initiation factors 1 and 1A on the yeast small ribosomal subunit | Q47761220 | ||
| Bulk-solvent correction in large macromolecular structures | Q57980824 | ||
| P433 | issue | 7462 | |
| P407 | language of work or name | English | Q1860 |
| P304 | page(s) | 307-11 | |
| P577 | publication date | 2013-08-15 | |
| P1433 | published in | Nature | Q180445 |
| P1476 | title | The initiation of mammalian protein synthesis and mRNA scanning mechanism | |
| P478 | volume | 500 |
| Q42109595 | A bacterial homolog YciH of eukaryotic translation initiation factor eIF1 regulates stress-related gene expression and is unlikely to be involved in translation initiation fidelity. |
| Q46103865 | A helicase-independent activity of eIF4A in promoting mRNA recruitment to the human ribosome |
| Q24701801 | An RNA trapping mechanism in Alphavirus mRNA promotes ribosome stalling and translation initiation |
| Q83226429 | An mRNA-binding channel in the ES6S region of the translation 48S-PIC promotes RNA unwinding and scanning |
| Q93026270 | Androgen upregulates the palmitoylation of eIF3L in human prostate LNCaP cells |
| Q48129458 | Catch me if you can: trapping scanning ribosomes in their footsteps |
| Q36461919 | Chemical footprinting reveals conformational changes of 18S and 28S rRNAs at different steps of translation termination on the human ribosome |
| Q58765724 | Comparative sequence and structure analysis of eIF1A and eIF1AD |
| Q35948019 | Conformational Differences between Open and Closed States of the Eukaryotic Translation Initiation Complex |
| Q35131072 | Conformational changes in the P site and mRNA entry channel evoked by AUG recognition in yeast translation preinitiation complexes |
| Q37631233 | Conserved residues in yeast initiator tRNA calibrate initiation accuracy by regulating preinitiation complex stability at the start codon |
| Q92730638 | Control of Translation at the Initiation Phase During Glucose Starvation in Yeast |
| Q109116643 | Coronavirus Nsp1: Immune Response Suppression and Protein Expression Inhibition |
| Q89583429 | Cryo-EM study of an archaeal 30S initiation complex gives insights into evolution of translation initiation |
| Q30828138 | Cryo-EM study of start codon selection during archaeal translation initiation |
| Q50875299 | Crystal Structure of the C-terminal Domain of Human eIF2D and Its Implications on Eukaryotic Translation Initiation. |
| Q41341367 | Crystal Structure of the Human Ribosome in Complex with DENR-MCT-1. |
| Q91641936 | Crystal structure of the C-terminal domain of DENR |
| Q90744821 | Crystal structure of the DENR-MCT-1 complex revealed zinc-binding site essential for heterodimer formation |
| Q55434885 | DENR-MCTS1 heterodimerization and tRNA recruitment are required for translation reinitiation. |
| Q36914646 | DHX29 reduces leaky scanning through an upstream AUG codon regardless of its nucleotide context |
| Q36426432 | Doubly Spin-Labeled RNA as an EPR Reporter for Studying Multicomponent Supramolecular Assemblies |
| Q104439844 | Dynamic competition between SARS-CoV-2 NSP1 and mRNA on the human ribosome inhibits translation initiation |
| Q107111791 | Dynamic competition between SARS-CoV-2 NSP1 and mRNA on the human ribosome inhibits translation initiation |
| Q34534686 | Dynamics of ribosome scanning and recycling revealed by translation complex profiling. |
| Q37491704 | Enhanced eIF1 binding to the 40S ribosome impedes conformational rearrangements of the preinitiation complex and elevates initiation accuracy. |
| Q26771380 | Eukaryote-specific extensions in ribosomal proteins of the small subunit: Structure and function |
| Q38764186 | Eukaryotic aspects of translation initiation brought into focus |
| Q34115417 | Eukaryotic translation initiation factor eIF5 promotes the accuracy of start codon recognition by regulating Pi release and conformational transitions of the preinitiation complex |
| Q36972906 | Heterogeneity of the translational machinery: Variations on a common theme. |
| Q34509637 | Human eukaryotic initiation factor 2 (eIF2)-GTP-Met-tRNAi ternary complex and eIF3 stabilize the 43 S preinitiation complex |
| Q59351754 | Interaction of rRNA with mRNA and tRNA in Translating Mammalian Ribosome: Functional Implications in Health and Disease |
| Q38399151 | Interaction of tRNA with eukaryotic ribosome |
| Q37662017 | Interface between 40S exit channel protein uS7/Rps5 and eIF2α modulates start codon recognition in vivo |
| Q47857695 | Maternal Dead-end 1 promotes translation of nanos1 by binding the eIF3 complex. |
| Q35636275 | Mechanism of cytoplasmic mRNA translation |
| Q35961180 | Metabolite profiling stratifies pancreatic ductal adenocarcinomas into subtypes with distinct sensitivities to metabolic inhibitors |
| Q37739606 | Molecular Landscape of the Ribosome Pre-initiation Complex during mRNA Scanning: Structural Role for eIF3c and Its Control by eIF5. |
| Q39028088 | More than just scanning: the importance of cap-independent mRNA translation initiation for cellular stress response and cancer. |
| Q102059631 | Nonstructural Protein 1 of SARS-CoV-2 Is a Potent Pathogenicity Factor Redirecting Host Protein Synthesis Machinery toward Viral RNA |
| Q34634172 | Novel RNA-binding protein P311 binds eukaryotic translation initiation factor 3 subunit b (eIF3b) to promote translation of transforming growth factor β1-3 (TGF-β1-3). |
| Q36046835 | Principles of start codon recognition in eukaryotic translation initiation |
| Q35234645 | Quantitative analysis of mammalian translation initiation sites by FACS-seq |
| Q28258346 | Quantitative studies of mRNA recruitment to the eukaryotic ribosome |
| Q30856398 | Re-analysis of cryoEM data on HCV IRES bound to 40S subunit of human ribosome integrated with recent structural information suggests new contact regions between ribosomal proteins and HCV RNA |
| Q42291024 | Recognition but no repair of abasic site in single-stranded DNA by human ribosomal uS3 protein residing within intact 40S subunit |
| Q59125509 | Role of aIF1 in Pyrococcus abyssi translation initiation |
| Q93340499 | Role of the uS9/yS16 C-terminal tail in translation initiation and elongation in Saccharomyces cerevisiae |
| Q41750015 | Rps3/uS3 promotes mRNA binding at the 40S ribosome entry channel and stabilizes preinitiation complexes at start codons |
| Q33983619 | Rps5-Rps16 communication is essential for efficient translation initiation in yeast S. cerevisiae |
| Q100387950 | SARS-CoV-2 Nsp1 suppresses host but not viral translation through a bipartite mechanism |
| Q64119701 | Start Codon Recognition in Eukaryotic and Archaeal Translation Initiation: A Common Structural Core |
| Q38988322 | Stress-induced start codon fidelity regulates arsenite-inducible regulatory particle-associated protein (AIRAP) translation |
| Q38459563 | Structural Insights into tRNA Dynamics on the Ribosome |
| Q34440678 | Structural changes enable start codon recognition by the eukaryotic translation initiation complex |
| Q27681329 | Structural integrity of the PCI domain of eIF3a/TIF32 is required for mRNA recruitment to the 43S pre-initiation complexes |
| Q47384205 | Structural rearrangements in mRNA upon its binding to human 80S ribosomes revealed by EPR spectroscopy. |
| Q49832547 | Structure of a eukaryotic cytoplasmic pre-40S ribosomal subunit. |
| Q98944748 | Structure of a human 48S translational initiation complex |
| Q27697933 | Structure of a yeast 40S-eIF1-eIF1A-eIF3-eIF3j initiation complex |
| Q27694629 | Structure of the mammalian 80S initiation complex with initiation factor 5B on HCV-IRES RNA |
| Q33778295 | Systematic genomic and translational efficiency studies of uveal melanoma |
| Q51410878 | The Jigsaw Puzzle of mRNA Translation Initiation in Eukaryotes: A Decade of Structures Unraveling the Mechanics of the Process. |
| Q38954583 | The integrated stress response. |
| Q37565821 | The interaction between eukaryotic initiation factor 1A and eIF5 retains eIF1 within scanning preinitiation complexes |
| Q38961838 | The molecular choreography of protein synthesis: translational control, regulation, and pathways |
| Q36844633 | The ribosomal protein Asc1/RACK1 is required for efficient translation of short mRNAs |
| Q35884199 | The β-hairpin of 40S exit channel protein Rps5/uS7 promotes efficient and accurate translation initiation in vivo. |
| Q61804594 | Thomas A. Steitz (1940-2018) |
| Q64942886 | Toward a Kinetic Understanding of Eukaryotic Translation. |
| Q59327146 | Translating the Game: Ribosomes as Active Players |
| Q52593667 | Translation and Translational Control in Dinoflagellates. |
| Q36295149 | Translation complex profile sequencing to study the in vivo dynamics of mRNA-ribosome interactions during translation initiation, elongation and termination |
| Q50055353 | Translation initiation of alphavirus mRNA reveals new insights into the topology of the 48S initiation complex. |
| Q60048439 | Translational initiation factor eIF5 replaces eIF1 on the 40S ribosomal subunit to promote start-codon recognition |
| Q50420902 | Variant ribosomal RNA alleles are conserved and exhibit tissue-specific expression |
| Q49294166 | Variants of the 5'-terminal region of p53 mRNA influence the ribosomal scanning and translation efficiency. |
| Q42142778 | When Proteins Start to Make Sense: Fine-tuning Aminoglycosides for PTC Suppression Therapy |
| Q26827587 | Why is start codon selection so precise in eukaryotes? |
| Q61458334 | Z-DNA and Z-RNA in human disease |
| Q46608158 | Zooming in on eukaryotic translation initiation |
| Q52318693 | eIF1 Loop 2 interactions with Met-tRNAi control the accuracy of start codon selection by the scanning preinitiation complex. |
| Q47252148 | eIF1A residues implicated in cancer stabilize translation preinitiation complexes and favor suboptimal initiation sites in yeast. |
| Q37228876 | eIF1A/eIF5B interaction network and its functions in translation initiation complex assembly and remodeling |
| Q34510080 | eIF5 and eIF5B together stimulate 48S initiation complex formation during ribosomal scanning |
| Q40385115 | microRNAs stimulate translation initiation mediated by HCV-like IRESes |
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