Your search keyword '"N. Ban"' showing total 43 results

1. NAC guides a ribosomal multienzyme complex for nascent protein processing.

Author

Lentzsch AM, Yudin D, Gamerdinger M, Chandrasekar S, Rabl L, Scaiola A, Deuerling E, Ban N, and Shan SO

Subjects

Animals, Humans, Acetylation, Catalytic Domain, Methionyl Aminopeptidases chemistry, Methionyl Aminopeptidases metabolism, Models, Molecular, N-Terminal Acetyltransferase A chemistry, N-Terminal Acetyltransferase A metabolism, Caenorhabditis elegans, Multienzyme Complexes metabolism, Multienzyme Complexes chemistry, Protein Processing, Post-Translational, Ribosomes chemistry, Ribosomes enzymology, Ribosomes metabolism, Methionine chemistry, Methionine metabolism, Molecular Chaperones chemistry, Molecular Chaperones metabolism

Abstract

Approximately 40% of the mammalian proteome undergoes N-terminal methionine excision and acetylation, mediated sequentially by methionine aminopeptidase (MetAP) and N-acetyltransferase A (NatA), respectively 1 . Both modifications are strictly cotranslational and essential in higher eukaryotic organisms 1 . The interaction, activity and regulation of these enzymes on translating ribosomes are poorly understood. Here we perform biochemical, structural and in vivo studies to demonstrate that the nascent polypeptide-associated complex 2,3 (NAC) orchestrates the action of these enzymes. NAC assembles a multienzyme complex with MetAP1 and NatA early during translation and pre-positions the active sites of both enzymes for timely sequential processing of the nascent protein. NAC further releases the inhibitory interactions from the NatA regulatory protein huntingtin yeast two-hybrid protein K 4,5 (HYPK) to activate NatA on the ribosome, enforcing cotranslational N-terminal acetylation. Our results provide a mechanistic model for the cotranslational processing of proteins in eukaryotic cells., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

2. Structural basis of ribosomal frameshifting during translation of the SARS-CoV-2 RNA genome.

Author

Bhatt PR, Scaiola A, Loughran G, Leibundgut M, Kratzel A, Meurs R, Dreos R, O'Connor KM, McMillan A, Bode JW, Thiel V, Gatfield D, Atkins JF, and Ban N

Subjects

Animals, Antiviral Agents pharmacology, Codon, Terminator, Coronavirus RNA-Dependent RNA Polymerase biosynthesis, Coronavirus RNA-Dependent RNA Polymerase chemistry, Coronavirus RNA-Dependent RNA Polymerase genetics, Cryoelectron Microscopy, Fluoroquinolones pharmacology, Genome, Viral, Humans, Image Processing, Computer-Assisted, Models, Molecular, Nucleic Acid Conformation, Open Reading Frames, Protein Folding, RNA, Messenger chemistry, RNA, Messenger genetics, RNA, Messenger metabolism, RNA, Ribosomal, 18S chemistry, RNA, Ribosomal, 18S genetics, RNA, Ribosomal, 18S metabolism, RNA, Viral chemistry, RNA, Viral metabolism, Ribosomal Proteins metabolism, Ribosomes metabolism, SARS-CoV-2 drug effects, SARS-CoV-2 physiology, Viral Proteins chemistry, Viral Proteins genetics, Virus Replication drug effects, Frameshifting, Ribosomal drug effects, RNA, Viral genetics, Ribosomes ultrastructure, SARS-CoV-2 genetics, Viral Proteins biosynthesis

Abstract

Programmed ribosomal frameshifting is a key event during translation of the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) RNA genome that allows synthesis of the viral RNA-dependent RNA polymerase and downstream proteins. Here, we present the cryo-electron microscopy structure of a translating mammalian ribosome primed for frameshifting on the viral RNA. The viral RNA adopts a pseudoknot structure that lodges at the entry to the ribosomal messenger RNA (mRNA) channel to generate tension in the mRNA and promote frameshifting, whereas the nascent viral polyprotein forms distinct interactions with the ribosomal tunnel. Biochemical experiments validate the structural observations and reveal mechanistic and regulatory features that influence frameshifting efficiency. Finally, we compare compounds previously shown to reduce frameshifting with respect to their ability to inhibit SARS-CoV-2 replication, establishing coronavirus frameshifting as a target for antiviral intervention., (Copyright © 2021 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2021

3. Gene- and Species-Specific Hox mRNA Translation by Ribosome Expansion Segments.

Author

Leppek K, Fujii K, Quade N, Susanto TT, Boehringer D, Lenarčič T, Xue S, Genuth NR, Ban N, and Barna M

Subjects

5' Untranslated Regions genetics, Gene Expression Regulation genetics, Genes, Homeobox genetics, Homeodomain Proteins ultrastructure, Nucleic Acid Conformation, RNA, Messenger genetics, RNA, Ribosomal genetics, Ribosomes ultrastructure, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae ultrastructure, Species Specificity, Homeodomain Proteins genetics, Protein Biosynthesis genetics, RNA, Ribosomal ultrastructure, Ribosomes genetics

Abstract

Ribosomes have been suggested to directly control gene regulation, but regulatory roles for ribosomal RNA (rRNA) remain largely unexplored. Expansion segments (ESs) consist of multitudes of tentacle-like rRNA structures extending from the core ribosome in eukaryotes. ESs are remarkably variable in sequence and size across eukaryotic evolution with largely unknown functions. In characterizing ribosome binding to a regulatory element within a Homeobox (Hox) 5' UTR, we identify a modular stem-loop within this element that binds to a single ES, ES9S. Engineering chimeric, "humanized" yeast ribosomes for ES9S reveals that an evolutionary change in the sequence of ES9S endows species-specific binding of Hoxa9 mRNA to the ribosome. Genome editing to site-specifically disrupt the Hoxa9-ES9S interaction demonstrates the functional importance for such selective mRNA-rRNA binding in translation control. Together, these studies unravel unexpected gene regulation directly mediated by rRNA and how ribosome evolution drives translation of critical developmental regulators., Competing Interests: Declaration of Interest K.L. and M.B. are inventors on patents and submitted provisional patent applications related to the Hoxa9 P4 stem-loop and RNA therapeutics and their various uses., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2020

4. Early Scanning of Nascent Polypeptides inside the Ribosomal Tunnel by NAC.

Author

Gamerdinger M, Kobayashi K, Wallisch A, Kreft SG, Sailer C, Schlömer R, Sachs N, Jomaa A, Stengel F, Ban N, and Deuerling E

Subjects

Animals, Caenorhabditis elegans genetics, Caenorhabditis elegans Proteins genetics, Endoplasmic Reticulum genetics, Humans, Ribosomes genetics, SEC Translocation Channels genetics, Saccharomyces cerevisiae, Caenorhabditis elegans metabolism, Caenorhabditis elegans Proteins biosynthesis, Endoplasmic Reticulum metabolism, Protein Biosynthesis, Ribosomes metabolism, SEC Translocation Channels metabolism

Abstract

Cotranslational processing of newly synthesized proteins is fundamental for correct protein maturation. Protein biogenesis factors are thought to bind nascent polypeptides not before they exit the ribosomal tunnel. Here, we identify a nascent chain recognition mechanism deep inside the ribosomal tunnel by an essential eukaryotic cytosolic chaperone. The nascent polypeptide-associated complex (NAC) inserts the N-terminal tail of its β subunit (N-βNAC) into the ribosomal tunnel to sense substrates directly upon synthesis close to the peptidyl-transferase center. N-βNAC escorts the growing polypeptide to the cytosol and relocates to an alternate binding site on the ribosomal surface. Using C. elegans as an in vivo model, we demonstrate that the tunnel-probing activity of NAC is essential for organismal viability and critical to regulate endoplasmic reticulum (ER) protein transport by controlling ribosome-Sec61 translocon interactions. Thus, eukaryotic protein maturation relies on the early sampling of nascent chains inside the ribosomal tunnel., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

5. Extensions, Extra Factors, and Extreme Complexity: Ribosomal Structures Provide Insights into Eukaryotic Translation.

Author

Weisser M and Ban N

Subjects

Animals, Gene Editing, Genome, Archaeal, Genome, Bacterial, Models, Molecular, Phenotype, Protein Conformation, RNA Splicing, RNA, Long Noncoding genetics, Transcription, Genetic, CRISPR-Cas Systems, Eukaryotic Cells physiology, Protein Biosynthesis, Ribosomes physiology

Abstract

Although the basic aspects of protein synthesis are preserved in all kingdoms of life, there are many important structural and functional differences between bacterial and the more complex eukaryotic ribosomes. High-resolution cryo-electron microscopy (cryo-EM) and X-ray crystallography structures of eukaryotic ribosomes have revealed the complex architectures of eukaryotic ribosomes and species-specific variations in protein and ribosomal RNA (rRNA) extensions. They also enabled structural studies of a range of eukaryotic ribosomal complexes involved in translation initiation, elongation, and termination, revealing unique mechanistic features of the eukaryotic translation process, especially with respect to the identification and recognition of translation start and stop codons on messenger RNAs (mRNAs). Most recently, structural biology has provided insights into the eukaryotic ribosomal biogenesis pathway by visualizing several of its complex intermediates. This review highlights the past decade's structural work on eukaryotic ribosomes and its implications on our understanding of eukaryotic translation., (Copyright © 2019 Cold Spring Harbor Laboratory Press; all rights reserved.)

Published

2019

6. Conformational Switching of the Nuclear Exosome during Ribosome Biogenesis.

Author

Kummer E and Ban N

Subjects

Humans, Models, Biological, Organelle Biogenesis, RNA, Ribosomal metabolism, Cell Nucleus metabolism, Exosomes metabolism, Ribosomes metabolism

Published

2018

7. Structure of a prehandover mammalian ribosomal SRP·SRP receptor targeting complex.

Author

Kobayashi K, Jomaa A, Lee JH, Chandrasekar S, Boehringer D, Shan SO, and Ban N

Subjects

Animals, Cryoelectron Microscopy, GTP Phosphohydrolases chemistry, Guanosine Triphosphate chemistry, Hydrolysis, Protein Conformation, Protein Multimerization, RNA chemistry, Receptors, Cytoplasmic and Nuclear ultrastructure, Receptors, Peptide ultrastructure, Ribosomes ultrastructure, Protein Sorting Signals, Receptors, Cytoplasmic and Nuclear chemistry, Receptors, Peptide chemistry, Ribosomes chemistry

Abstract

Signal recognition particle (SRP) targets proteins to the endoplasmic reticulum (ER). SRP recognizes the ribosome synthesizing a signal sequence and delivers it to the SRP receptor (SR) on the ER membrane followed by the transfer of the signal sequence to the translocon. Here, we present the cryo-electron microscopy structure of the mammalian translating ribosome in complex with SRP and SR in a conformation preceding signal sequence handover. The structure visualizes all eukaryotic-specific SRP and SR proteins and reveals their roles in stabilizing this conformation by forming a large protein assembly at the distal site of SRP RNA. We provide biochemical evidence that the guanosine triphosphate hydrolysis of SRP·SR is delayed at this stage, possibly to provide a time window for signal sequence handover to the translocon., (Copyright © 2018 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2018

8. Structure of the quaternary complex between SRP, SR, and translocon bound to the translating ribosome.

Author

Jomaa A, Fu YH, Boehringer D, Leibundgut M, Shan SO, and Ban N

Subjects

Cryoelectron Microscopy, GTP Phosphohydrolases metabolism, Hydrophobic and Hydrophilic Interactions, Molecular Docking Simulation, Mutation, Protein Binding, Protein Biosynthesis, Protein Sorting Signals genetics, Protein Structure, Quaternary, Protein Transport, Escherichia coli metabolism, Escherichia coli Proteins metabolism, Receptors, Cytoplasmic and Nuclear metabolism, Receptors, Peptide metabolism, Ribosomes metabolism, Signal Recognition Particle metabolism

Abstract

During co-translational protein targeting, the signal recognition particle (SRP) binds to the translating ribosome displaying the signal sequence to deliver it to the SRP receptor (SR) on the membrane, where the signal peptide is transferred to the translocon. Using electron cryo-microscopy, we have determined the structure of a quaternary complex of the translating Escherichia coli ribosome, the SRP-SR in the 'activated' state and the translocon. Our structure, supported by biochemical experiments, reveals that the SRP RNA adopts a kinked and untwisted conformation to allow repositioning of the 'activated' SRP-SR complex on the ribosome. In addition, we observe the translocon positioned through interactions with the SR in the vicinity of the ribosome exit tunnel where the signal sequence is extending beyond its hydrophobic binding groove of the SRP M domain towards the translocon. Our study provides new insights into the mechanism of signal sequence transfer from the SRP to the translocon.

Published

2017

9. Eukaryotic aspects of translation initiation brought into focus.

Author

Aylett CH and Ban N

Subjects

Codon, Initiator metabolism, Eukaryotic Cells metabolism, Eukaryotic Initiation Factors, Eukaryota metabolism, Protein Biosynthesis, Ribosomes metabolism

Abstract

In all organisms, mRNA-directed protein synthesis is catalysed by ribosomes. Although the basic aspects of translation are preserved in all kingdoms of life, important differences are found in the process of translation initiation, which is rate-limiting and the most important step for translation regulation. While great strides had been taken towards a complete structural understanding of the initiation of translation in eubacteria, our understanding of the eukaryotic process, which includes numerous eukaryotic-specific initiation factors, was until recently limited owing to a lack of structural information. In this review, we discuss recent results in the field that provide an increasingly complete molecular description of the eukaryotic initiation process. The structural snapshots obtained using a range of methods now provide insights into the architecture of the initiation complex, start-codon recognition by the initiator tRNA and the process of subunit joining. Future advances will require both higher-resolution insights into previously characterized complexes and mapping of initiation factors that control translation on an additional level by interacting only peripherally or transiently with ribosomal subunits.This article is part of the themed issue 'Perspectives on the ribosome'., (© 2017 The Author(s).)

Published

2017

10. The complete structure of the chloroplast 70S ribosome in complex with translation factor pY.

Author

Bieri P, Leibundgut M, Saurer M, Boehringer D, and Ban N

Subjects

Cryoelectron Microscopy, Models, Molecular, RNA, Ribosomal chemistry, RNA, Ribosomal ultrastructure, Ribosomal Proteins chemistry, Ribosomal Proteins ultrastructure, Chloroplasts, Ribosomes chemistry, Ribosomes ultrastructure, Spinacia oleracea

Abstract

Chloroplasts are cellular organelles of plants and algae that are responsible for energy conversion and carbon fixation by the photosynthetic reaction. As a consequence of their endosymbiotic origin, they still contain their own genome and the machinery for protein biosynthesis. Here, we present the atomic structure of the chloroplast 70S ribosome prepared from spinach leaves and resolved by cryo-EM at 3.4 Å resolution. The complete structure reveals the features of the 4.5S rRNA, which probably evolved by the fragmentation of the 23S rRNA, and all five plastid-specific ribosomal proteins. These proteins, required for proper assembly and function of the chloroplast translation machinery, bind and stabilize rRNA including regions that only exist in the chloroplast ribosome. Furthermore, the structure reveals plastid-specific extensions of ribosomal proteins that extensively remodel the mRNA entry and exit site on the small subunit as well as the polypeptide tunnel exit and the putative binding site of the signal recognition particle on the large subunit. The translation factor pY, involved in light- and temperature-dependent control of protein synthesis, is bound to the mRNA channel of the small subunit and interacts with 16S rRNA nucleotides at the A-site and P-site, where it protects the decoding centre and inhibits translation by preventing tRNA binding. The small subunit is locked by pY in a non-rotated state, in which the intersubunit bridges to the large subunit are stabilized., (© 2016 The Authors. Published under the terms of the CC BY NC ND 4.0 license.)

Published

2017

11. Structures of the E. coli translating ribosome with SRP and its receptor and with the translocon.

Author

Jomaa A, Boehringer D, Leibundgut M, and Ban N

Subjects

Codon metabolism, Cryoelectron Microscopy, Escherichia coli chemistry, Escherichia coli metabolism, Escherichia coli Proteins metabolism, Models, Molecular, Protein Binding, Protein Biosynthesis, Protein Transport, RNA, Messenger genetics, RNA, Messenger metabolism, Receptors, Cytoplasmic and Nuclear genetics, Receptors, Cytoplasmic and Nuclear metabolism, Receptors, Peptide genetics, Receptors, Peptide metabolism, Ribosomes genetics, Ribosomes metabolism, Signal Recognition Particle genetics, Signal Recognition Particle metabolism, Transcription Factors genetics, Transcription Factors metabolism, Codon genetics, Escherichia coli genetics, Escherichia coli Proteins genetics, Receptors, Cytoplasmic and Nuclear chemistry, Receptors, Peptide chemistry, Ribosomes chemistry, Signal Recognition Particle chemistry

Abstract

Co-translational protein targeting to membranes is a universally conserved process. Central steps include cargo recognition by the signal recognition particle and handover to the Sec translocon. Here we present snapshots of key co-translational-targeting complexes solved by cryo-electron microscopy at near-atomic resolution, establishing the molecular contacts between the Escherichia coli translating ribosome, the signal recognition particle and the translocon. Our results reveal the conformational changes that regulate the latching of the signal sequence, the release of the heterodimeric domains of the signal recognition particle and its receptor, and the handover of the signal sequence to the translocon. We also observe that the signal recognition particle and the translocon insert-specific structural elements into the ribosomal tunnel to remodel it, possibly to sense nascent chains. Our work provides structural evidence for a conformational state of the signal recognition particle and its receptor primed for translocon binding to the ribosome-nascent chain complex.

Published

2016

12. Archaeal aminoacyl-tRNA synthetases interact with the ribosome to recycle tRNAs.

Author

Godinic-Mikulcic V, Jaric J, Greber BJ, Franke V, Hodnik V, Anderluh G, Ban N, and Weygand-Durasevic I

Subjects

Arginine-tRNA Ligase metabolism, Genome, Archaeal, Methanobacteriaceae genetics, Ribosomal Proteins metabolism, Serine-tRNA Ligase metabolism, Amino Acyl-tRNA Synthetases metabolism, Archaea enzymology, Protein Biosynthesis, RNA, Transfer metabolism, Ribosomes enzymology

Abstract

Aminoacyl-tRNA synthetases (aaRS) are essential enzymes catalyzing the formation of aminoacyl-tRNAs, the immediate precursors for encoded peptides in ribosomal protein synthesis. Previous studies have suggested a link between tRNA aminoacylation and high-molecular-weight cellular complexes such as the cytoskeleton or ribosomes. However, the structural basis of these interactions and potential mechanistic implications are not well understood. To biochemically characterize these interactions we have used a system of two interacting archaeal aaRSs: an atypical methanogenic-type seryl-tRNA synthetase and an archaeal ArgRS. More specifically, we have shown by thermophoresis and surface plasmon resonance that these two aaRSs bind to the large ribosomal subunit with micromolar affinities. We have identified the L7/L12 stalk and the proteins located near the stalk base as the main sites for aaRS binding. Finally, we have performed a bioinformatics analysis of synonymous codons in the Methanothermobacter thermautotrophicus genome that supports a mechanism in which the deacylated tRNAs may be recharged by aaRSs bound to the ribosome and reused at the next occurrence of a codon encoding the same amino acid. These results suggest a mechanism of tRNA recycling in which aaRSs associate with the L7/L12 stalk region to recapture the tRNAs released from the preceding ribosome in polysomes.

Published

2014

13. Structural insights into eukaryotic ribosomes and the initiation of translation.

Author

Voigts-Hoffmann F, Klinge S, and Ban N

Subjects

Animals, Eukaryotic Initiation Factors metabolism, Humans, Ribosome Subunits chemistry, Ribosome Subunits metabolism, Eukaryota metabolism, Peptide Chain Initiation, Translational, Ribosomes chemistry, Ribosomes metabolism

Abstract

The initiation of protein biosynthesis entails the ordered assembly of elongation-competent ribosomes, with an initiator tRNA basepaired to an appropriate mRNA start codon. In eukaryotes, this process is more complex than in prokaryotes and involves numerous protein factors that mediate tRNA delivery, mRNA binding, start codon selection and subunit joining. The recent 40S:eIF1, 80S and eIF2:tRNA:GDPNP ternary complex structures provide an initial structural framework toward a molecular understanding of the eukaryotic translation initiation process. Updated homology models of larger initiation complexes provide first insights into the likely arrangements of these higher-order complexes, but also reveal the limits of our current understanding of the eukaryotic translation initiation process., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published

2012

14. Cryo-EM structures of Arx1 and maturation factors Rei1 and Jjj1 bound to the 60S ribosomal subunit.

Author

Greber BJ, Boehringer D, Montellese C, and Ban N

Subjects

Binding Sites, Models, Molecular, Protein Conformation, Cryoelectron Microscopy methods, HSP40 Heat-Shock Proteins chemistry, Ribosomes, Saccharomyces cerevisiae Proteins chemistry

Abstract

Eukaryotic ribosome biogenesis requires many protein factors that facilitate the assembly, nuclear export and final maturation of 40S and 60S particles. We have biochemically characterized ribosomal complexes of the yeast 60S-biogenesis factor Arx1 and late-maturation factors Rei1 and Jjj1 and determined their cryo-EM structures. Arx1 was visualized bound to the 60S subunit together with Rei1, at 8.1-Å resolution, to reveal the molecular details of Arx1 binding whereby Arx1 arrests the eukaryotic-specific rRNA expansion segment 27 near the polypeptide tunnel exit. Rei1 and Jjj1, which have been implicated in Arx1 recycling, bind in the vicinity of Arx1 and form a network of interactions. We suggest that, in addition to the role of Arx1 during pre-60S nuclear export, the binding of Arx1 conformationally locks the pre-60S subunit and inhibits the premature association of nascent chain-processing factors to the polypeptide tunnel exit.

Published

2012

15. Cryo-EM structure of the archaeal 50S ribosomal subunit in complex with initiation factor 6 and implications for ribosome evolution.

Author

Greber BJ, Boehringer D, Godinic-Mikulcic V, Crnkovic A, Ibba M, Weygand-Durasevic I, and Ban N

Subjects

Archaeal Proteins ultrastructure, Binding Sites, Methanobacteriaceae genetics, Prokaryotic Initiation Factors ultrastructure, Protein Biosynthesis, Ribosome Subunits, Large, Archaeal chemistry, Ribosomes metabolism, Archaeal Proteins chemistry, Cryoelectron Microscopy methods, Methanobacteriaceae metabolism, Prokaryotic Initiation Factors chemistry, Ribosome Subunits, Large, Archaeal ultrastructure, Ribosomes genetics

Abstract

Translation of mRNA into proteins by the ribosome is universally conserved in all cellular life. The composition and complexity of the translation machinery differ markedly between the three domains of life. Organisms from the domain Archaea show an intermediate level of complexity, sharing several additional components of the translation machinery with eukaryotes that are absent in bacteria. One of these translation factors is initiation factor 6 (IF6), which associates with the large ribosomal subunit. We have reconstructed the 50S ribosomal subunit from the archaeon Methanothermobacter thermautotrophicus in complex with archaeal IF6 at 6.6 Å resolution using cryo-electron microscopy (EM). The structure provides detailed architectural insights into the 50S ribosomal subunit from a methanogenic archaeon through identification of the rRNA expansion segments and ribosomal proteins that are shared between this archaeal ribosome and eukaryotic ribosomes but are mostly absent in bacteria and in some archaeal lineages. Furthermore, the structure reveals that, in spite of highly divergent evolutionary trajectories of the ribosomal particle and the acquisition of novel functions of IF6 in eukaryotes, the molecular binding of IF6 on the ribosome is conserved between eukaryotes and archaea. The structure also provides a snapshot of the reductive evolution of the archaeal ribosome and offers new insights into the evolution of the translation system in archaea., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published

2012

16. Atomic structures of the eukaryotic ribosome.

Author

Klinge S, Voigts-Hoffmann F, Leibundgut M, and Ban N

Subjects

Crystallography, X-Ray, Eukaryotic Cells metabolism, Models, Molecular, RNA, Ribosomal metabolism, Ribonucleoproteins chemistry, Ribonucleoproteins metabolism, Ribosomal Proteins metabolism, Ribosomes metabolism, Protein Biosynthesis, RNA, Ribosomal chemistry, Ribosomal Proteins chemistry, Ribosomes chemistry

Abstract

Eukaryotic ribosomes are significantly larger and more complex than their prokaryotic counterparts. This parallels the increased complexity of the associated cellular machinery responsible for translation initiation, ribosome assembly, and the regulation of protein synthesis in eukaryotic cells. The recently determined crystal structures of the small (40S) and large (60S) ribosomal subunits and the 80S ribosome now provide an atomic description of this essential molecular machine and reveal its eukaryote-specific features. In this review, we discuss the common structural principles underlying the evolution of both ribosomal subunits. The recently obtained structural information provides a framework for further genetic, biochemical and structural studies of eukaryotic ribosomes. At the same time, it facilitates a direct comparison between prokaryotic and eukaryotic ribosomal features., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published

2012

17. Cryo-EM structure of the E. coli translating ribosome in complex with SRP and its receptor.

Author

Estrozi LF, Boehringer D, Shan SO, Ban N, and Schaffitzel C

Subjects

Bacterial Proteins metabolism, Cryoelectron Microscopy, Escherichia coli Proteins metabolism, Models, Molecular, Protein Biosynthesis, Protein Structure, Tertiary, Receptors, Cytoplasmic and Nuclear metabolism, Ribosomes chemistry, Signal Recognition Particle metabolism, Bacterial Proteins chemistry, Escherichia coli genetics, Escherichia coli Proteins chemistry, Receptors, Cytoplasmic and Nuclear chemistry, Receptors, Peptide chemistry, Ribosomes ultrastructure, Signal Recognition Particle chemistry

Abstract

We report the 'early' conformation of the Escherichia coli signal recognition particle (SRP) and its receptor FtsY bound to the translating ribosome, as determined by cryo-EM. FtsY binds to the tetraloop of the SRP RNA, whereas the NG domains of the SRP protein and FtsY interact weakly in this conformation. Our results suggest that optimal positioning of the SRP RNA tetraloop and the Ffh NG domain leads to FtsY recruitment.

Published

2011

18. Homologs of aminoacyl-tRNA synthetases acylate carrier proteins and provide a link between ribosomal and nonribosomal peptide synthesis.

Author

Mocibob M, Ivic N, Bilokapic S, Maier T, Luic M, Ban N, and Weygand-Durasevic I

Subjects

Acylation, Agrobacterium tumefaciens genetics, Agrobacterium tumefaciens metabolism, Alanine metabolism, Amino Acid Sequence, Amino Acyl-tRNA Synthetases chemistry, Amino Acyl-tRNA Synthetases genetics, Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism, Biocatalysis, Bradyrhizobium genetics, Bradyrhizobium metabolism, Carrier Proteins genetics, Catalytic Domain, Crystallography, X-Ray, Kinetics, Models, Biological, Models, Molecular, Molecular Sequence Data, Protein Structure, Tertiary, Sequence Homology, Amino Acid, Serine-tRNA Ligase chemistry, Serine-tRNA Ligase genetics, Serine-tRNA Ligase metabolism, Transfer RNA Aminoacylation, Amino Acyl-tRNA Synthetases metabolism, Carrier Proteins metabolism, Peptide Biosynthesis, Nucleic Acid-Independent, Ribosomes metabolism

Abstract

Aminoacyl-tRNA synthetases (aaRSs) are ancient and evolutionary conserved enzymes catalyzing the formation of aminoacyl-tRNAs, that are used as substrates for ribosomal protein biosynthesis. In addition to full length aaRS genes, genomes of many organisms are sprinkled with truncated genes encoding single-domain aaRS-like proteins, which often have relinquished their canonical role in genetic code translation. We have identified the genes for putative seryl-tRNA synthetase homologs widespread in bacterial genomes and characterized three of them biochemically and structurally. The proteins encoded are homologous to the catalytic domain of highly diverged, atypical seryl-tRNA synthetases (aSerRSs) found only in methanogenic archaea and are deprived of the tRNA-binding domain. Remarkably, in comparison to SerRSs, aSerRS homologs display different and relaxed amino acid specificity. aSerRS homologs lack canonical tRNA aminoacylating activity and instead transfer activated amino acid to phosphopantetheine prosthetic group of putative carrier proteins, whose genes were identified in the genomic surroundings of aSerRS homologs. Detailed kinetic analysis confirmed that aSerRS homologs aminoacylate these carrier proteins efficiently and specifically. Accordingly, aSerRS homologs were renamed amino acid:[carrier protein] ligases (AMP forming). The enzymatic activity of aSerRS homologs is reminiscent of adenylation domains in nonribosomal peptide synthesis, and thus they represent an intriguing link between programmable ribosomal protein biosynthesis and template-independent nonribosomal peptide synthesis.

Published

2010

19. The ribosome as a platform for co-translational processing, folding and targeting of newly synthesized proteins.

Author

Kramer G, Boehringer D, Ban N, and Bukau B

Subjects

Models, Molecular, Molecular Chaperones chemistry, Molecular Chaperones metabolism, Peptides chemistry, Protein Binding, Protein Conformation, Protein Folding, Protein Structure, Secondary, Ribosomal Proteins chemistry, Peptides metabolism, Protein Biosynthesis, Ribosomal Proteins metabolism, Ribosomes metabolism

Abstract

The early events in the life of newly synthesized proteins in the cellular environment are remarkably complex. Concurrently with their synthesis by the ribosome, nascent polypeptides are subjected to enzymatic processing, chaperone-assisted folding or targeting to translocation pores at membranes. The ribosome itself has a key role in these different tasks and governs the interplay between the various factors involved. Indeed, the ribosome serves as a platform for the spatially and temporally regulated association of enzymes, targeting factors and chaperones that act upon the nascent polypeptides emerging from the exit tunnel. Furthermore, the ribosome provides opportunities to coordinate the protein-synthesis activity of its peptidyl transferase center with the protein targeting and folding processes. Here we review the early co-translational events involving the ribosome that guide cytosolic proteins to their native state.

Published

2009

20. YidC and Oxa1 form dimeric insertion pores on the translating ribosome.

Author

Kohler R, Boehringer D, Greber B, Bingel-Erlenmeyer R, Collinson I, Schaffitzel C, and Ban N

Subjects

Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism, Cysteine chemistry, Cysteine metabolism, Dimerization, Electron Transport Complex IV genetics, Escherichia coli Proteins genetics, Membrane Transport Proteins genetics, Mitochondrial Proteins genetics, Models, Molecular, Nuclear Proteins genetics, Oxidation-Reduction, Protein Binding, Protein Biosynthesis, Ribosomes genetics, SEC Translocation Channels, Electron Transport Complex IV chemistry, Electron Transport Complex IV metabolism, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Membrane Transport Proteins chemistry, Membrane Transport Proteins metabolism, Mitochondrial Proteins chemistry, Mitochondrial Proteins metabolism, Multiprotein Complexes metabolism, Nuclear Proteins chemistry, Nuclear Proteins metabolism, Protein Structure, Quaternary, Ribosomes metabolism

Abstract

The YidC/Oxa1/Alb3 family of membrane proteins facilitates the insertion and assembly of membrane proteins in bacteria, mitochondria, and chloroplasts. Here we present the structures of both Escherichia coli YidC and Saccharomyces cerevisiae Oxa1 bound to E. coli ribosome nascent chain complexes determined by cryo-electron microscopy. Dimers of YidC and Oxa1 are localized above the exit of the ribosomal tunnel. Crosslinking experiments show that the ribosome specifically stabilizes the dimeric state. Functionally important and conserved transmembrane helices of YidC and Oxa1 were localized at the dimer interface by cysteine crosslinking. Both Oxa1 and YidC dimers contact the ribosome at ribosomal protein L23 and conserved rRNA helices 59 and 24, similarly to what was observed for the nonhomologous SecYEG translocon. We suggest that dimers of the YidC and Oxa1 proteins form insertion pores and share a common overall architecture with the SecY monomer.

Published

2009

21. Molecular mechanism and structure of Trigger Factor bound to the translating ribosome.

Author

Merz F, Boehringer D, Schaffitzel C, Preissler S, Hoffmann A, Maier T, Rutkowska A, Lozza J, Ban N, Bukau B, and Deuerling E

Subjects

Amino Acid Sequence, Cross-Linking Reagents chemistry, Cryoelectron Microscopy, Peptides chemistry, Protein Conformation, Protein Folding, Protein Structure, Tertiary, Escherichia coli Proteins chemistry, Molecular Chaperones chemistry, Peptidylprolyl Isomerase chemistry, Protein Biosynthesis, Ribosomes chemistry

Abstract

Ribosome-associated chaperone Trigger Factor (TF) initiates folding of newly synthesized proteins in bacteria. Here, we pinpoint by site-specific crosslinking the sequence of molecular interactions of Escherichia coli TF and nascent chains during translation. Furthermore, we provide the first full-length structure of TF associated with ribosome-nascent chain complexes by using cryo-electron microscopy. In its active state, TF arches over the ribosomal exit tunnel accepting nascent chains in a protective void. The growing nascent chain initially follows a predefined path through the entire interior of TF in an unfolded conformation, and even after folding into a domain it remains accommodated inside the protective cavity of ribosome-bound TF. The adaptability to accept nascent chains of different length and folding states may explain how TF is able to assist co-translational folding of all kinds of nascent polypeptides during ongoing synthesis. Moreover, we suggest a model of how TF's chaperoning function can be coordinated with the co-translational processing and membrane targeting of nascent polypeptides by other ribosome-associated factors.

Published

2008

22. A peptide deformylase-ribosome complex reveals mechanism of nascent chain processing.

Author

Bingel-Erlenmeyer R, Kohler R, Kramer G, Sandikci A, Antolić S, Maier T, Schaffitzel C, Wiedmann B, Bukau B, and Ban N

Subjects

Amidohydrolases deficiency, Amidohydrolases genetics, Amino Acid Sequence, Arabinose metabolism, Binding Sites, Crystallography, X-Ray, Escherichia coli genetics, Escherichia coli growth & development, Escherichia coli metabolism, Genetic Complementation Test, Models, Biological, Models, Molecular, Molecular Sequence Data, N-Formylmethionine metabolism, Peptidylprolyl Isomerase metabolism, Protein Binding, Protein Structure, Secondary, RNA, Transfer, Met genetics, RNA, Transfer, Met metabolism, Ribosome Subunits chemistry, Ribosome Subunits metabolism, Amidohydrolases chemistry, Amidohydrolases metabolism, Escherichia coli enzymology, Protein Biosynthesis, Protein Processing, Post-Translational, Ribosomes chemistry, Ribosomes metabolism

Abstract

Messenger-RNA-directed protein synthesis is accomplished by the ribosome. In eubacteria, this complex process is initiated by a specialized transfer RNA charged with formylmethionine (tRNA(fMet)). The amino-terminal formylated methionine of all bacterial nascent polypeptides blocks the reactive amino group to prevent unfavourable side-reactions and to enhance the efficiency of translation initiation. The first enzymatic factor that processes nascent chains is peptide deformylase (PDF); it removes this formyl group as polypeptides emerge from the ribosomal tunnel and before the newly synthesized proteins can adopt their native fold, which may bury the N terminus. Next, the N-terminal methionine is excised by methionine aminopeptidase. Bacterial PDFs are metalloproteases sharing a conserved N-terminal catalytic domain. All Gram-negative bacteria, including Escherichia coli, possess class-1 PDFs characterized by a carboxy-terminal alpha-helical extension. Studies focusing on PDF as a target for antibacterial drugs have not revealed the mechanism of its co-translational mode of action despite indications in early work that it co-purifies with ribosomes. Here we provide biochemical evidence that E. coli PDF interacts directly with the ribosome via its C-terminal extension. Crystallographic analysis of the complex between the ribosome-interacting helix of PDF and the ribosome at 3.7 A resolution reveals that the enzyme orients its active site towards the ribosomal tunnel exit for efficient co-translational processing of emerging nascent chains. Furthermore, we have found that the interaction of PDF with the ribosome enhances cell viability. These results provide the structural basis for understanding the coupling between protein synthesis and enzymatic processing of nascent chains, and offer insights into the interplay of PDF with the ribosome-associated chaperone trigger factor.

Published

2008

23. Dynamics of trigger factor interaction with translating ribosomes.

Author

Rutkowska A, Mayer MP, Hoffmann A, Merz F, Zachmann-Brand B, Schaffitzel C, Ban N, Deuerling E, and Bukau B

Subjects

Kinetics, Escherichia coli Proteins metabolism, Peptidylprolyl Isomerase metabolism, Ribosomes metabolism

Abstract

In all organisms ribosome-associated chaperones assist early steps of protein folding. To elucidate the mechanism of their action, we determined the kinetics of individual steps of the ribosome binding/release cycle of bacterial trigger factor (TF), using fluorescently labeled chaperone and ribosome-nascent chain complexes. Both the association and dissociation rates of TF-ribosome complexes are modulated by nascent chains, whereby their length, sequence, and folding status are influencing parameters. However, the effect of the folding status is modest, indicating that TF can bind small globular domains and accommodate them within its substrate binding cavity. In general, the presence of a nascent chain causes an up to 9-fold increase in the rate of TF association, which provides a kinetic explanation for the observed ability of TF to efficiently compete with other cytosolic chaperones for binding to nascent chains. Furthermore, a subset of longer nascent polypeptides promotes the stabilization of TF-ribosome complexes, which increases the half-life of these complexes from 15 to 50 s. Nascent chains thus regulate their folding environment generated by ribosome-associated chaperones.

Published

2008

24. Trapping the ribosome to control gene expression.

Author

Boehringer D and Ban N

Subjects

5' Untranslated Regions, Binding Sites, Cryoelectron Microscopy, Escherichia coli metabolism, Escherichia coli Proteins chemistry, Escherichia coli Proteins genetics, Models, Molecular, Mutation, Nucleic Acid Conformation, Protein Binding, Protein Conformation, RNA, Bacterial chemistry, RNA, Transfer metabolism, Regulatory Sequences, Ribonucleic Acid, Ribosomal Proteins chemistry, Ribosomal Proteins genetics, Ribosomes chemistry, Ribosomes ultrastructure, Time Factors, Escherichia coli genetics, Escherichia coli Proteins metabolism, Gene Expression Regulation, Bacterial, Peptide Chain Initiation, Translational, RNA, Bacterial metabolism, RNA, Messenger metabolism, Ribosomal Proteins metabolism, Ribosomes metabolism

Abstract

Protein synthesis is often regulated by structured mRNAs that interact with ribosomes. In this issue of Cell, Marzi et al. (2007) provide insights into the autoregulation of protein S15 by visualizing the folded repressor mRNA on the ribosome stalled in the preinitiation state. These results have implications for our understanding of the mechanism of translation initiation in general.

Published

2007

25. Generation of ribosome nascent chain complexes for structural and functional studies.

Author

Schaffitzel C and Ban N

Subjects

Cryoelectron Microscopy, Crystallization, Protein Biosynthesis, Ribosomes ultrastructure, Sucrose chemistry, Analytic Sample Preparation Methods, Escherichia coli Proteins chemistry, Peptides chemistry, Ribosomes chemistry, Transcription Factors chemistry

Abstract

Biochemical and structural studies of co-translational folding, targeting and translocation depend on an efficient methodology to prepare ribosome nascent chain complexes (RNCs). Here we present our approach for the generation of homogenous and stable RNCs involving in vitro translation and affinity purification. Fusing the SecM arrest sequence, which tightly interacts with the ribosomal tunnel, to the nascent polypeptide chain significantly enhanced the stability of the RNCs. We have been able to increase the yield of the affinity purification step by engineering a tag with higher affinity. The RNCs generated with this approach have been successfully used to obtain 3D cryo-electron microscopic reconstructions of complexes with the signal recognition particle and the translocon. The established procedure is highly efficient and if scaled up could yield milligram amounts of RNCs sufficient for crystallization experiments.

Published

2007

26. Structure of the E. coli signal recognition particle bound to a translating ribosome.

Author

Schaffitzel C, Oswald M, Berger I, Ishikawa T, Abrahams JP, Koerten HK, Koning RI, and Ban N

Subjects

Base Sequence, Binding Sites, Membrane Proteins biosynthesis, Membrane Proteins genetics, Molecular Sequence Data, RNA chemistry, RNA, Ribosomal chemistry, Escherichia coli genetics, Models, Molecular, Protein Biosynthesis, Ribosomes chemistry, Signal Recognition Particle chemistry

Abstract

The prokaryotic signal recognition particle (SRP) targets membrane proteins into the inner membrane. It binds translating ribosomes and screens the emerging nascent chain for a hydrophobic signal sequence, such as the transmembrane helix of inner membrane proteins. If such a sequence emerges, the SRP binds tightly, allowing the SRP receptor to lock on. This assembly delivers the ribosome-nascent chain complex to the protein translocation machinery in the membrane. Using cryo-electron microscopy and single-particle reconstruction, we obtained a 16 A structure of the Escherichia coli SRP in complex with a translating E. coli ribosome containing a nascent chain with a transmembrane helix anchor. We also obtained structural information on the SRP bound to an empty E. coli ribosome. The latter might share characteristics with a scanning SRP complex, whereas the former represents the next step: the targeting complex ready for receptor binding. High-resolution structures of the bacterial ribosome and of the bacterial SRP components are available, and their fitting explains our electron microscopic density. The structures reveal the regions that are involved in complex formation, provide insight into the conformation of the SRP on the ribosome and indicate the conformational changes that accompany high-affinity SRP binding to ribosome nascent chain complexes upon recognition of the signal sequence.

Published

2006

27. Structure of the E. coli protein-conducting channel bound to a translating ribosome.

Author

Mitra K, Schaffitzel C, Shaikh T, Tama F, Jenni S, Brooks CL 3rd, Ban N, and Frank J

Subjects

Cell Membrane chemistry, Cell Membrane metabolism, Cryoelectron Microscopy, Escherichia coli Proteins biosynthesis, Membrane Proteins chemistry, Membrane Proteins metabolism, Models, Molecular, Multiprotein Complexes chemistry, Multiprotein Complexes metabolism, Pliability, Protein Binding, Protein Structure, Quaternary, Protein Transport, SEC Translocation Channels, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Protein Biosynthesis, Ribosomes metabolism

Abstract

Secreted and membrane proteins are translocated across or into cell membranes through a protein-conducting channel (PCC). Here we present a cryo-electron microscopy reconstruction of the Escherichia coli PCC, SecYEG, complexed with the ribosome and a nascent chain containing a signal anchor. This reconstruction shows a messenger RNA, three transfer RNAs, the nascent chain, and detailed features of both a translocating PCC and a second, non-translocating PCC bound to mRNA hairpins. The translocating PCC forms connections with ribosomal RNA hairpins on two sides and ribosomal proteins at the back, leaving a frontal opening. Normal mode-based flexible fitting of the archaeal SecYEbeta structure into the PCC electron microscopy densities favours a front-to-front arrangement of two SecYEG complexes in the PCC, and supports channel formation by the opening of two linked SecY halves during polypeptide translocation. On the basis of our observation in the translocating PCC of two segregated pores with different degrees of access to bulk lipid, we propose a model for co-translational protein translocation.

Published

2005

28. A cradle for new proteins: trigger factor at the ribosome.

Author

Maier T, Ferbitz L, Deuerling E, and Ban N

Subjects

Binding Sites, Models, Biological, Protein Binding, Protein Conformation, Escherichia coli Proteins chemistry, Models, Chemical, Models, Molecular, Molecular Chaperones chemistry, Peptidylprolyl Isomerase chemistry, Protein Biosynthesis, Ribosomes chemistry

Abstract

Newly synthesized proteins leave the ribosome through a narrow tunnel in the large subunit. During ongoing synthesis, nascent protein chains are particularly sensitive to aggregation and degradation because they emerge from the ribosome in an unfolded state. In bacteria, the first protein to interact with nascent chains and facilitate their folding is the ribosome-associated chaperone trigger factor. Recently, crystal structures of trigger factor and of its ribosome-binding domain in complex with the large ribosomal subunit revealed that the chaperone adopts an extended 'dragon-shaped' fold with a large hydrophobic cradle, which arches over the exit of the ribosomal tunnel and shields newly synthesized proteins. These structural results, together with recent biochemical data on trigger factor and its interplay with other chaperones and factors that interact with the nascent chain, provide a comprehensive view of the role of trigger factor during co-translational protein folding.

Published

2005

29. Target-directed proteolysis at the ribosome.

Author

Henrichs T, Mikhaleva N, Conz C, Deuerling E, Boyd D, Zelazny A, Bibi E, Ban N, and Ehrmann M

Subjects

Adenosine Triphosphatases genetics, Adenosine Triphosphatases metabolism, Bacterial Proteins genetics, Bacterial Proteins metabolism, Binding Sites, Chromosomes, Bacterial genetics, Chromosomes, Bacterial metabolism, Cytoplasm metabolism, Endopeptidases genetics, Escherichia coli genetics, Escherichia coli metabolism, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism, Membrane Transport Proteins genetics, Membrane Transport Proteins metabolism, Models, Biological, Receptors, Cytoplasmic and Nuclear genetics, Receptors, Cytoplasmic and Nuclear metabolism, Recombinant Proteins genetics, Recombinant Proteins metabolism, SEC Translocation Channels, SecA Proteins, Signal Recognition Particle genetics, Signal Recognition Particle metabolism, Endopeptidases metabolism, Ribosomes metabolism

Abstract

Target directed proteolysis allows specific processing of proteins in vivo. This method uses tobacco etch virus (TEV) NIa protease that recognizes a seven-residue consensus sequence. Because of its specificity, proteins engineered to contain a cleavage site are proteolysed, whereas other proteins remain unaffected. Therefore, this approach can be used to study the structure and function of target proteins in their natural environment within living cells. One application is the conditional inactivation of essential proteins, which is based on the concept that a target containing a recognition site can be inactivated by coexpressed TEV protease. We have previously identified one site in the secretion factor SecA that tolerated a TEV protease site insert. Coexpression of TEV protease in the cytoplasm led to incomplete cleavage and a mild secretion defect. To improve the efficiency of proteolysis, TEV protease was attached to the ribosome. We show here that cleaving SecA under these conditions is one way of increasing the efficiency of target directed proteolysis. The implications of recruiting novel biological activities to ribosomes are discussed.

Published

2005

30. The structural basis of macrolide-ribosome binding assessed using mutagenesis of 23S rRNA positions 2058 and 2059.

Author

Pfister P, Jenni S, Poehlsgaard J, Thomas A, Douthwaite S, Ban N, and Böttger EC

Subjects

Binding Sites, Computer Simulation, Drug Resistance, Bacterial, Mutagenesis, RNA, Ribosomal, 23S genetics, Anti-Bacterial Agents metabolism, Macrolides metabolism, Mycobacterium smegmatis drug effects, Mycobacterium smegmatis genetics, RNA, Ribosomal, 23S chemistry, RNA, Ribosomal, 23S metabolism, Ribosomes metabolism

Abstract

Macrolides are a diverse group of antibiotics that inhibit bacterial growth by binding within the peptide tunnel of the 50S ribosomal subunit. There is good agreement about the architecture of the macrolide site from different crystallography studies of bacterial and archaeal 50S subunits. These structures show plainly that 23S rRNA nucleotides A2058 and A2059 are located accessibly on the surface of the tunnel wall where they act as key contact sites for macrolide binding. However, the molecular details of how macrolides fit into this site remain a matter of contention. Here, we have generated an isogenic set of single and dual substitutions at A2058 and A2059 in Mycobacterium smegmatis to investigate the effects of the rRNA mutations on macrolide binding. Resistances conferred to a comprehensive array of 11 macrolide compounds are used to assess models of macrolide binding predicted from the crystal structures. The data indicate that all macrolides and their derivatives bind at the same site in the tunnel with their C5 amino sugar in a similar orientation. Our data are compatible with the lactone rings of 14-membered and 16-membered macrolides adopting different conformations, enabling the latter compounds to avoid a steric clash with 2058G. This difference, together with interactions conveyed via substituents that are specific to certain ketolide and macrolide sub-classes, influences the binding to the large ribosomal subunit. Our genetic data show no support for a derivatized-macrolide binding site that has been proposed to be located further down the tunnel.

Published

2004

31. Trigger factor in complex with the ribosome forms a molecular cradle for nascent proteins.

Author

Ferbitz L, Maier T, Patzelt H, Bukau B, Deuerling E, and Ban N

Subjects

Crystallization, Crystallography, X-Ray, Escherichia coli metabolism, Haloarcula marismortui, Hydrophobic and Hydrophilic Interactions, Models, Genetic, Models, Molecular, Molecular Chaperones chemistry, Molecular Chaperones metabolism, Protein Binding, Protein Conformation, Protein Subunits chemistry, Protein Subunits metabolism, Proteins chemistry, Ribosomes chemistry, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Peptidylprolyl Isomerase chemistry, Peptidylprolyl Isomerase metabolism, Protein Biosynthesis, Protein Folding, Proteins metabolism, Ribosomes metabolism

Abstract

During protein biosynthesis, nascent polypeptide chains that emerge from the ribosomal exit tunnel encounter ribosome-associated chaperones, which assist their folding to the native state. Here we present a 2.7 A crystal structure of Escherichia coli trigger factor, the best-characterized chaperone of this type, together with the structure of its ribosome-binding domain in complex with the Haloarcula marismortui large ribosomal subunit. Trigger factor adopts a unique conformation resembling a crouching dragon with separated domains forming the amino-terminal ribosome-binding 'tail', the peptidyl-prolyl isomerase 'head', the carboxy-terminal 'arms' and connecting regions building up the 'back'. From its attachment point on the ribosome, trigger factor projects the extended domains over the exit of the ribosomal tunnel, creating a protected folding space where nascent polypeptides may be shielded from proteases and aggregation. This study sheds new light on our understanding of co-translational protein folding, and suggests an unexpected mechanism of action for ribosome-associated chaperones.

Published

2004

32. Dial tm for rescue: tmRNA engages ribosomes stalled on defective mRNAs.

Author

Haebel PW, Gutmann S, and Ban N

Subjects

Alanine metabolism, Protein Binding, Protein Conformation, RNA, Bacterial chemistry, RNA, Messenger chemistry, RNA-Binding Proteins chemistry, RNA-Binding Proteins metabolism, Ribosomes chemistry, Structure-Activity Relationship, Protein Biosynthesis genetics, RNA, Bacterial genetics, RNA, Messenger metabolism, Ribosomes metabolism

Abstract

Ribosomes translate genetic information encoded by mRNAs into protein chains with high fidelity. Truncated mRNAs lacking a stop codon will cause the synthesis of incomplete peptide chains and stall translating ribosomes. In bacteria, a ribonucleoprotein complex composed of tmRNA, a molecule that combines the functions of tRNAs and mRNAs, and small protein B (SmpB) rescues stalled ribosomes. The SmpB-tmRNA complex binds to the stalled ribosome, allowing translation to resume at a short internal tmRNA open reading frame that encodes a protein degradation tag. The aberrant protein is released when the ribosome reaches the stop codon at the end of the tmRNA open reading frame and the fused peptide tag targets it for degradation by cellular proteases. The recently determined NMR structures of SmpB, the crystal structure of the SmpB-tmRNA complex and the cryo-EM structure of the SmpB-tmRNA-EF-Tu-ribosome complex have provided first detailed insights into the intricate mechanisms involved in ribosome rescue.

Published

2004

33. The chemistry of protein synthesis and voyage through the ribosomal tunnel.

Author

Jenni S and Ban N

Subjects

Binding Sites, Catalysis, Macromolecular Substances, Peptides chemistry, Protein Binding, Protein Folding, Protein Structure, Tertiary, Protein Subunits, Protein Transport physiology, Ribosomal Proteins chemistry, Ribosomal Proteins metabolism, Models, Molecular, Protein Biosynthesis, Proteins chemistry, RNA, Transfer chemistry, RNA, Transfer metabolism, Ribosomes chemistry, Ribosomes metabolism

Abstract

High-resolution structures of ribosomal subunits and their complexes with substrates and antibiotics have revealed fundamental principles of template-directed protein synthesis. Mechanistic questions regarding ribosome function and catalysis can now be addressed with structure-based experiments. Recent studies have investigated the mechanism of peptide bond formation catalyzed by the large ribosomal subunit, the mode of protein synthesis inhibition by macrolide antibiotics, the interaction of nascent polypeptides with the ribosomal exit tunnel, and the role of ribosomal proteins in the recruitment of accessory factors that assist protein folding and targeting.

Published

2003

34. L23 protein functions as a chaperone docking site on the ribosome.

Author

Kramer G, Rauch T, Rist W, Vorderwülbecke S, Patzelt H, Schulze-Specking A, Ban N, Deuerling E, and Bukau B

Subjects

Amino Acid Motifs, Amino Acid Sequence, Binding Sites, Cross-Linking Reagents, Escherichia coli genetics, Escherichia coli growth & development, Escherichia coli metabolism, Escherichia coli Proteins chemistry, Escherichia coli Proteins genetics, Mass Spectrometry, Molecular Chaperones chemistry, Molecular Sequence Data, Mutation genetics, Peptidylprolyl Isomerase chemistry, Protein Binding, Protein Folding, Protein Structure, Tertiary, Ribosomal Proteins chemistry, Ribosomal Proteins genetics, Escherichia coli Proteins metabolism, Molecular Chaperones metabolism, Peptidylprolyl Isomerase metabolism, Ribosomal Proteins metabolism, Ribosomes metabolism

Abstract

During translation, the first encounter of nascent polypeptides is with the ribosome-associated chaperones that assist the folding process--a principle that seems to be conserved in evolution. In Escherichia coli, the ribosome-bound Trigger Factor chaperones the folding of cytosolic proteins by interacting with nascent polypeptides. Here we identify a ribosome-binding motif in the amino-terminal domain of Trigger Factor. We also show the formation of crosslinked products between Trigger Factor and two adjacent ribosomal proteins, L23 and L29, which are located at the exit of the peptide tunnel in the ribosome. L23 is essential for the growth of E. coli and the association of Trigger Factor with the ribosome, whereas L29 is dispensable in both processes. Mutation of an exposed glutamate in L23 prevents Trigger Factor from interacting with ribosomes and nascent chains, and causes protein aggregation and conditional lethality in cells that lack the protein repair function of the DnaK chaperone. Purified L23 also interacts specifically with Trigger Factor in vitro. We conclude that essential L23 provides a chaperone docking site on ribosomes that directly links protein biosynthesis with chaperone-assisted protein folding.

Published

2002

35. The structures of four macrolide antibiotics bound to the large ribosomal subunit.

Author

Hansen JL, Ippolito JA, Ban N, Nissen P, Moore PB, and Steitz TA

Subjects

Base Sequence, Binding Sites, Crystallography, X-Ray, Drug Resistance genetics, Haloarcula marismortui cytology, Haloarcula marismortui genetics, Macrolides, Models, Molecular, Molecular Structure, Mutation, Nucleic Acid Conformation, Protein Conformation, RNA, Archaeal chemistry, RNA, Archaeal genetics, RNA, Archaeal metabolism, RNA, Ribosomal, 23S genetics, Ribosomes genetics, Static Electricity, Anti-Bacterial Agents chemistry, Anti-Bacterial Agents metabolism, Haloarcula marismortui chemistry, RNA, Ribosomal, 23S chemistry, RNA, Ribosomal, 23S metabolism, Ribosomes chemistry, Ribosomes metabolism

Abstract

Crystal structures of the Haloarcula marismortui large ribosomal subunit complexed with the 16-membered macrolide antibiotics carbomycin A, spiramycin, and tylosin and a 15-membered macrolide, azithromycin, show that they bind in the polypeptide exit tunnel adjacent to the peptidyl transferase center. Their location suggests that they inhibit protein synthesis by blocking the egress of nascent polypeptides. The saccharide branch attached to C5 of the lactone rings extends toward the peptidyl transferase center, and the isobutyrate extension of the carbomycin A disaccharide overlaps the A-site. Unexpectedly, a reversible covalent bond forms between the ethylaldehyde substituent at the C6 position of the 16-membered macrolides and the N6 of A2103 (A2062, E. coli). Mutations in 23S rRNA that result in clinical resistance render the binding site less complementary to macrolides.

Published

2002

36. RNA tertiary interactions in the large ribosomal subunit: the A-minor motif.

Author

Nissen P, Ippolito JA, Ban N, Moore PB, and Steitz TA

Subjects

Adenosine chemistry, Adenosine genetics, Adenosine metabolism, Base Pairing, Binding Sites, Conserved Sequence genetics, Haloarcula marismortui chemistry, Hydrogen Bonding, Models, Molecular, Mutation genetics, Protein Subunits, RNA Stability, RNA, Archaeal genetics, RNA, Ribosomal, 23S chemistry, RNA, Ribosomal, 23S genetics, RNA, Ribosomal, 23S metabolism, RNA, Ribosomal, 5S chemistry, RNA, Ribosomal, 5S genetics, RNA, Ribosomal, 5S metabolism, Ribosomes chemistry, Solvents, Structure-Activity Relationship, Haloarcula marismortui genetics, Nucleic Acid Conformation, RNA, Archaeal chemistry, RNA, Archaeal metabolism, Ribosomes genetics, Ribosomes metabolism

Abstract

Analysis of the 2.4-A resolution crystal structure of the large ribosomal subunit from Haloarcula marismortui reveals the existence of an abundant and ubiquitous structural motif that stabilizes RNA tertiary and quaternary structures. This motif is termed the A-minor motif, because it involves the insertion of the smooth, minor groove edges of adenines into the minor groove of neighboring helices, preferentially at C-G base pairs, where they form hydrogen bonds with one or both of the 2' OHs of those pairs. A-minor motifs stabilize contacts between RNA helices, interactions between loops and helices, and the conformations of junctions and tight turns. The interactions between the 3' terminal adenine of tRNAs bound in either the A site or the P site with 23S rRNA are examples of functionally significant A-minor interactions. The A-minor motif is by far the most abundant tertiary structure interaction in the large ribosomal subunit; 186 adenines in 23S and 5S rRNA participate, 68 of which are conserved. It may prove to be the universally most important long-range interaction in large RNA structures.

Published

2001

37. Progress toward an understanding of the structure and enzymatic mechanism of the large ribosomal subunit.

Author

Hansen JL, Schmeing TM, Klein DJ, Ippolito JA, Ban N, Nissen P, Freeborn B, Moore PB, and Steitz TA

Subjects

Crystallography, X-Ray, Haloarcula marismortui enzymology, Haloarcula marismortui genetics, Models, Molecular, Nucleic Acid Conformation, Protein Conformation, RNA, Ribosomal, 23S chemistry, RNA, Ribosomal, 23S genetics, Ribosomal Proteins chemistry, Thermus thermophilus enzymology, Thermus thermophilus genetics, Ribosomes chemistry, Ribosomes metabolism

Published

2001

38. The complete atomic structure of the large ribosomal subunit at 2.4 A resolution.

Author

Ban N, Nissen P, Hansen J, Moore PB, and Steitz TA

Subjects

Archaeal Proteins chemistry, Archaeal Proteins metabolism, Base Sequence, Binding Sites, Conserved Sequence, Crystallography, X-Ray, Haloarcula marismortui ultrastructure, Models, Molecular, Molecular Sequence Data, Nucleic Acid Conformation, Protein Conformation, Protein Folding, RNA, Archaeal chemistry, RNA, Archaeal metabolism, RNA, Ribosomal, 23S metabolism, RNA, Ribosomal, 5S metabolism, Ribosomal Proteins metabolism, Ribosomes ultrastructure, Haloarcula marismortui chemistry, RNA, Ribosomal, 23S chemistry, RNA, Ribosomal, 5S chemistry, Ribosomal Proteins chemistry, Ribosomes chemistry

Abstract

The large ribosomal subunit catalyzes peptide bond formation and binds initiation, termination, and elongation factors. We have determined the crystal structure of the large ribosomal subunit from Haloarcula marismortui at 2.4 angstrom resolution, and it includes 2833 of the subunit's 3045 nucleotides and 27 of its 31 proteins. The domains of its RNAs all have irregular shapes and fit together in the ribosome like the pieces of a three-dimensional jigsaw puzzle to form a large, monolithic structure. Proteins are abundant everywhere on its surface except in the active site where peptide bond formation occurs and where it contacts the small subunit. Most of the proteins stabilize the structure by interacting with several RNA domains, often using idiosyncratically folded extensions that reach into the subunit's interior.

Published

2000

39. The structural basis of ribosome activity in peptide bond synthesis.

Author

Nissen P, Hansen J, Ban N, Moore PB, and Steitz TA

Subjects

Archaeal Proteins chemistry, Archaeal Proteins metabolism, Base Pairing, Base Sequence, Binding Sites, Catalysis, Crystallization, Evolution, Molecular, Haloarcula marismortui chemistry, Haloarcula marismortui metabolism, Haloarcula marismortui ultrastructure, Hydrogen Bonding, Hydrogen-Ion Concentration, Models, Molecular, Molecular Sequence Data, Nucleic Acid Conformation, Oligonucleotides metabolism, Peptides metabolism, Peptidyl Transferases antagonists & inhibitors, Peptidyl Transferases chemistry, Phosphates chemistry, Phosphates metabolism, Protein Conformation, Puromycin metabolism, RNA, Archaeal chemistry, RNA, Archaeal metabolism, RNA, Transfer metabolism, RNA, Transfer, Amino Acyl metabolism, Ribosomal Proteins chemistry, Ribosomal Proteins metabolism, Ribosomes chemistry, Peptide Biosynthesis, Peptidyl Transferases metabolism, RNA, Catalytic chemistry, RNA, Catalytic metabolism, RNA, Ribosomal, 23S chemistry, RNA, Ribosomal, 23S metabolism, Ribosomes metabolism

Abstract

Using the atomic structures of the large ribosomal subunit from Haloarcula marismortui and its complexes with two substrate analogs, we establish that the ribosome is a ribozyme and address the catalytic properties of its all-RNA active site. Both substrate analogs are contacted exclusively by conserved ribosomal RNA (rRNA) residues from domain V of 23S rRNA; there are no protein side-chain atoms closer than about 18 angstroms to the peptide bond being synthesized. The mechanism of peptide bond synthesis appears to resemble the reverse of the acylation step in serine proteases, with the base of A2486 (A2451 in Escherichia coli) playing the same general base role as histidine-57 in chymotrypsin. The unusual pK(a) (where K(a) is the acid dissociation constant) required for A2486 to perform this function may derive in part from its hydrogen bonding to G2482 (G2447 in E. coli), which also interacts with a buried phosphate that could stabilize unusual tautomers of these two bases. The polypeptide exit tunnel is largely formed by RNA but has significant contributions from proteins L4, L22, and L39e, and its exit is encircled by proteins L19, L22, L23, L24, L29, and L31e.

Published

2000

40. Haloarcula marismortui 50S subunit-complementarity of electron microscopy and X-Ray crystallographic information.

Author

Penczek P, Ban N, Grassucci RA, Agrawal RK, and Frank J

Subjects

Archaeal Proteins chemistry, Archaeal Proteins ultrastructure, Cryoelectron Microscopy, Crystallography, X-Ray, Haloarcula marismortui ultrastructure, Models, Molecular, Haloarcula marismortui chemistry, Ribosomes chemistry

Abstract

The large 50S subunit of the Haloarcula marismortui 70S ribosome was solved to 19 A using cryo-electron microscopy and single particle reconstruction techniques and to 9 A using X-ray crystallography. In the latter case, phases were determined by multiple isomorphous replacement and anomalous scattering from three heavy atom derivatives. The availability of X-ray and electron microscopy (EM) data has made it possible to compare the results of the two experimental methods. In the flexible regions of the 50S subunit, small differences in the mass distribution were detected. These differences can be attributed to the influence of packing in the crystal cell. The rotationally averaged power spectra of X-ray and EM were compared in an overlapping spatial frequency range from 60 to 13 A. The resulting ratio of X-ray to EM power ranges from 1 to 15, reflecting a progressively larger underestimation of the Fourier amplitudes by the electron microscope., (Copyright 1999 Academic Press.)

Published

1999

41. Placement of protein and RNA structures into a 5 A-resolution map of the 50S ribosomal subunit.

Author

Ban N, Nissen P, Hansen J, Capel M, Moore PB, and Steitz TA

Subjects

Archaeal Proteins chemistry, Crystallography, X-Ray, Haloarcula marismortui chemistry, Haloarcula marismortui ultrastructure, Nucleic Acid Conformation, Protein Conformation, RNA, Archaeal chemistry, Ribosomes ultrastructure, RNA, Ribosomal chemistry, Ribosomal Proteins chemistry, Ribosomes chemistry

Abstract

We have calculated at 5.0 A resolution an electron-density map of the large 50S ribosomal subunit from the bacterium Haloarcula marismortui by using phases derived from four heavy-atom derivatives, intercrystal density averaging and density-modification procedures. More than 300 base pairs of A-form RNA duplex have been fitted into this map, as have regions of non-A-form duplex, single-stranded segments and tetraloops. The long rods of RNA crisscrossing the subunit arise from the stacking of short, separate double helices, not all of which are A-form, and in many places proteins crosslink two or more of these rods. The polypeptide exit channel was marked by tungsten cluster compounds bound in one heavy-atom-derivatized crystal. We have determined the structure of the translation-factor-binding centre by fitting the crystal structures of the ribosomal proteins L6, L11 and L14, the sarcin-ricin loop RNA, and the RNA sequence that binds L11 into the electron density. We can position either elongation factor G or elongation factor Tu complexed with an aminoacylated transfer RNA and GTP onto the factor-binding centre in a manner that is consistent with results from biochemical and electron microscopy studies.

Published

1999

42. A 9 A resolution X-ray crystallographic map of the large ribosomal subunit.

Author

Ban N, Freeborn B, Nissen P, Penczek P, Grassucci RA, Sweet R, Frank J, Moore PB, and Steitz TA

Subjects

Microscopy, Electron methods, RNA, Archaeal chemistry, RNA, Ribosomal, 5S chemistry, Ribosomal Proteins chemistry, Crystallography, X-Ray methods, Haloarcula marismortui chemistry, Image Processing, Computer-Assisted methods, Ribosomes chemistry

Abstract

The 50S subunit of the ribosome catalyzes the peptidyl-transferase reaction of protein synthesis. We have generated X-ray crystallographic electron density maps of the large ribosomal subunit from Haloarcula marismortui at various resolutions up to 9 A using data from crystals that diffract to 3 A. Positioning a 20 A resolution EM image of these particles in the crystal lattice produced phases accurate enough to locate the bound heavy atoms in three derivatives using difference Fourier maps, thus demonstrating the correctness of the EM model and its placement in the unit cell. At 20 A resolution, the X-ray map is similar to the EM map; however, at 9 A it reveals long, continuous, but branched features whose shape, diameter, and right-handed twist are consistent with segments of double-helical RNA that crisscross the subunit.

Published

1998

43. Progress toward an understanding of the structure and enzymatic mechanism of the large ribosomal subunit

Author

Thomas A. Steitz, Joseph A. Ippolito, T.M. Schmeing, Jeffrey Hansen, N. Ban, Daniel J. Klein, B. Freeborn, Peter B. Moore, and Poul Nissen

Subjects

chemistry.chemical_classification, Models, Molecular, Ribosomal Proteins, Haloarcula marismortui, Mechanism (biology), Protein Conformation, Thermus thermophilus, RNA, Ribosomal RNA, Crystallography, X-Ray, Biochemistry, RNA, Ribosomal, 23S, Enzyme, Protein structure, chemistry, Large ribosomal subunit, Genetics, Nucleic Acid Conformation, Molecular Biology, Ribosomes

Published

2003