Your search keyword '"Ban, N."' showing total 20 results

1. The molecular mechanism of cotranslational membrane protein recognition and targeting by SecA.

Author

Wang S, Jomaa A, Jaskolowski M, Yang CI, Ban N, and Shan SO

Subjects

Binding Sites, Cryoelectron Microscopy, Escherichia coli K12 chemistry, Escherichia coli Proteins chemistry, Models, Molecular, Protein Biosynthesis, Protein Domains, Protein Structure, Secondary, Ribosomal Proteins chemistry, SEC Translocation Channels chemistry, SEC Translocation Channels metabolism, SecA Proteins chemistry, Escherichia coli K12 metabolism, Escherichia coli Proteins metabolism, Ribosomal Proteins metabolism, SecA Proteins metabolism

Abstract

Cotranslational protein targeting is a conserved process for membrane protein biogenesis. In Escherichia coli, the essential ATPase SecA was found to cotranslationally target a subset of nascent membrane proteins to the SecYEG translocase at the plasma membrane. The molecular mechanism of this pathway remains unclear. Here we use biochemical and cryoelectron microscopy analyses to show that the amino-terminal amphipathic helix of SecA and the ribosomal protein uL23 form a composite binding site for the transmembrane domain (TMD) on the nascent protein. This binding mode further enables recognition of charged residues flanking the nascent TMD and thus explains the specificity of SecA recognition. Finally, we show that membrane-embedded SecYEG promotes handover of the translating ribosome from SecA to the translocase via a concerted mechanism. Our work provides a molecular description of the SecA-mediated cotranslational targeting pathway and demonstrates an unprecedented role of the ribosome in shielding nascent TMDs.

Published

2019

2. 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

3. 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

4. Characterization of variants of the pore-forming toxin ClyA from Escherichia coli controlled by a redox switch.

Author

Roderer D, Benke S, Müller M, Fäh-Rechsteiner H, Ban N, Schuler B, and Glockshuber R

Subjects

Amino Acid Substitution, Animals, Crystallography, X-Ray, Cystine chemistry, Erythrocytes drug effects, Erythrocytes physiology, Escherichia coli, Escherichia coli Proteins genetics, Escherichia coli Proteins pharmacology, Fluorescence Resonance Energy Transfer, Hemolysin Proteins genetics, Hemolysin Proteins pharmacology, Hemolysis, Hemolytic Agents pharmacology, Horses, Kinetics, Models, Molecular, Oxidation-Reduction, Protein Multimerization, Protein Structure, Secondary, Protein Structure, Tertiary, Escherichia coli Proteins chemistry, Hemolysin Proteins chemistry, Hemolytic Agents chemistry

Abstract

The α-pore-forming toxin Cytolysin A (ClyA) is responsible for the hemolytic phenotype of several Escherichia coli and Salmonella enterica strains. ClyA is a soluble, 34 kDa monomer that assembles into a dodecameric pore complex in the presence of membranes or detergent. The comparison of the X-ray structures of monomeric ClyA and the ClyA protomer in the pore complex revealed one of the largest conformational transitions observed so far in proteins, involving the structural rearrangement of more than half of all residues, which is consistent with the finding that conversion from the monomer to the assembly competent protomer is rate-limiting for pore assembly. Here, we introduced artificial disulfide bonds at two distinct sites into the ClyA monomer that both prevent a specific structural rearrangement required for protomer formation. Using electron microscopy and hemolytic activity assays, we show that the engineered disulfides indeed trap these ClyA variants in an assembly incompetent state. Assembly of the variants into functional pore complexes can be completely recovered by disulfide reduction. The assembly kinetics of the ClyA variants recorded with circular dichroism and fluorescence spectroscopy revealed the same mechanism of protomer formation that was observed for wild-type ClyA, proceeding via an intermediate with decreased secondary structure content.

Published

2014

5. Structural insights into methyltransferase KsgA function in 30S ribosomal subunit biogenesis.

Author

Boehringer D, O'Farrell HC, Rife JP, and Ban N

Subjects

Cryoelectron Microscopy, Escherichia coli genetics, Escherichia coli metabolism, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism, Methyltransferases genetics, Methyltransferases metabolism, Peptide Chain Initiation, Translational physiology, Protein Structure, Tertiary, RNA Processing, Post-Transcriptional physiology, RNA, Bacterial genetics, RNA, Bacterial metabolism, RNA, Ribosomal, 16S genetics, RNA, Ribosomal, 16S metabolism, RNA, Transfer, Ribosome Subunits, Small, Bacterial genetics, Ribosome Subunits, Small, Bacterial metabolism, Escherichia coli chemistry, Escherichia coli Proteins chemistry, Methyltransferases chemistry, RNA, Bacterial chemistry, RNA, Ribosomal, 16S chemistry, Ribosome Subunits, Small, Bacterial chemistry

Abstract

The assembly of the ribosomal subunits is facilitated by ribosome biogenesis factors. The universally conserved methyltransferase KsgA modifies two adjacent adenosine residues in the 3'-terminal helix 45 of the 16 S ribosomal RNA (rRNA). KsgA recognizes its substrate adenosine residues only in the context of a near mature 30S subunit and is required for the efficient processing of the rRNA termini during ribosome biogenesis. Here, we present the cryo-EM structure of KsgA bound to a nonmethylated 30S ribosomal subunit. The structure reveals that KsgA binds to the 30S platform with the catalytic N-terminal domain interacting with substrate adenosine residues in helix 45 and the C-terminal domain making extensive contacts to helix 27 and helix 24. KsgA excludes the penultimate rRNA helix 44 from adopting its position in the mature 30S subunit, blocking the formation of the decoding site and subunit joining. We suggest that the activation of methyltransferase activity and subsequent dissociation of KsgA control conformational changes in helix 44 required for final rRNA processing and translation initiation.

Published

2012

6. The crystal structure of the signal recognition particle in complex with its receptor.

Author

Ataide SF, Schmitz N, Shen K, Ke A, Shan SO, Doudna JA, and Ban N

Subjects

Bacterial Proteins metabolism, Base Sequence, Binding Sites, Crystallization, Crystallography, X-Ray, Enzyme Activation, Escherichia coli chemistry, Escherichia coli metabolism, Escherichia coli Proteins metabolism, GTP Phosphohydrolases chemistry, GTP Phosphohydrolases metabolism, Guanosine Triphosphate analogs & derivatives, Guanosine Triphosphate chemistry, Guanosine Triphosphate metabolism, Hydrogen Bonding, Hydrophobic and Hydrophilic Interactions, Models, Biological, Models, Molecular, Nucleic Acid Conformation, Protein Conformation, Protein Multimerization, Protein Structure, Tertiary, Protein Transport, RNA, Bacterial metabolism, Receptors, Cytoplasmic and Nuclear metabolism, Ribosomal Proteins chemistry, Ribosomal Proteins metabolism, Ribosomes metabolism, Signal Recognition Particle metabolism, Bacterial Proteins chemistry, Escherichia coli Proteins chemistry, RNA, Bacterial chemistry, Receptors, Cytoplasmic and Nuclear chemistry, Signal Recognition Particle chemistry

Abstract

Cotranslational targeting of membrane and secretory proteins is mediated by the universally conserved signal recognition particle (SRP). Together with its receptor (SR), SRP mediates the guanine triphosphate (GTP)-dependent delivery of translating ribosomes bearing signal sequences to translocons on the target membrane. Here, we present the crystal structure of the SRP:SR complex at 3.9 angstrom resolution and biochemical data revealing that the activated SRP:SR guanine triphosphatase (GTPase) complex binds the distal end of the SRP hairpin RNA where GTP hydrolysis is stimulated. Combined with previous findings, these results suggest that the SRP:SR GTPase complex initially assembles at the tetraloop end of the SRP RNA and then relocalizes to the opposite end of the RNA. This rearrangement provides a mechanism for coupling GTP hydrolysis to the handover of cargo to the translocon.

Published

2011

7. 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

8. The structure of a cytolytic alpha-helical toxin pore reveals its assembly mechanism.

Author

Mueller M, Grauschopf U, Maier T, Glockshuber R, and Ban N

Subjects

Cell Membrane chemistry, Crystallography, X-Ray, Protein Structure, Tertiary, Escherichia coli K12 chemistry, Escherichia coli Proteins chemistry, Hemolysin Proteins chemistry, Membrane Proteins chemistry, Models, Molecular, Protein Folding

Abstract

Pore-forming toxins (PFTs) are a class of potent virulence factors that convert from a soluble form to a membrane-integrated pore. They exhibit their toxic effect either by destruction of the membrane permeability barrier or by delivery of toxic components through the pores. Among the group of bacterial PFTs are some of the most dangerous toxins, such as diphtheria and anthrax toxin. Examples of eukaryotic PFTs are perforin and the membrane-attack complex, proteins of the immune system. PFTs can be subdivided into two classes, alpha-PFTs and beta-PFTs, depending on the suspected mode of membrane integration, either by alpha-helical or beta-sheet elements. The only high-resolution structure of a transmembrane PFT pore is available for a beta-PFT--alpha-haemolysin from Staphylococcus aureus. Cytolysin A (ClyA, also known as HlyE), an alpha-PFT, is a cytolytic -helical toxin responsible for the haemolytic phenotype of several Escherichia coli and Salmonella enterica strains. ClyA is cytotoxic towards cultured mammalian cells, induces apoptosis of macrophages and promotes tissue pervasion. Electron microscopic reconstructions demonstrated that the soluble monomer of ClyA must undergo large conformational changes to form the transmembrane pore. Here we report the 3.3 A crystal structure of the 400 kDa dodecameric transmembrane pore formed by ClyA. The tertiary structure of ClyA protomers in the pore is substantially different from that in the soluble monomer. The conversion involves more than half of all residues. It results in large rearrangements, up to 140 A, of parts of the monomer, reorganization of the hydrophobic core, and transitions of -sheets and loop regions to -helices. The large extent of interdependent conformational changes indicates a sequential mechanism for membrane insertion and pore formation.

Published

2009

9. 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

10. Recycling of aborted ribosomal 50S subunit-nascent chain-tRNA complexes by the heat shock protein Hsp15.

Author

Jiang L, Schaffitzel C, Bingel-Erlenmeyer R, Ban N, Korber P, Koning RI, de Geus DC, Plaisier JR, and Abrahams JP

Subjects

Cryoelectron Microscopy, Puromycin chemistry, DNA-Binding Proteins chemistry, Escherichia coli Proteins chemistry, Heat-Shock Proteins chemistry, Models, Molecular, RNA, Bacterial chemistry, RNA, Transfer chemistry, Ribosome Subunits, Large, Bacterial chemistry

Abstract

When heat shock prematurely dissociates a translating bacterial ribosome, its 50S subunit is prevented from reinitiating protein synthesis by tRNA covalently linked to the unfinished protein chain that remains threaded through the exit tunnel. Hsp15, a highly upregulated bacterial heat shock protein, reactivates such dead-end complexes. Here, we show with cryo-electron microscopy reconstructions and functional assays that Hsp15 translocates the tRNA moiety from the A site to the P site of stalled 50S subunits. By stabilizing the tRNA in the P site, Hsp15 indirectly frees up the A site, allowing a release factor to land there and cleave off the tRNA. Such a release factor must be stop codon independent, suggesting a possible role for a poorly characterized class of putative release factors that are upregulated by cellular stress, lack a codon recognition domain and are conserved in eukaryotes.

Published

2009

11. Multiple conformational switches in a GTPase complex control co-translational protein targeting.

Author

Zhang X, Schaffitzel C, Ban N, and Shan SO

Subjects

Bacterial Proteins metabolism, Cell Membrane metabolism, Escherichia coli Proteins metabolism, GTP Phosphohydrolases metabolism, Multiprotein Complexes, Protein Binding, Protein Conformation, Receptors, Cytoplasmic and Nuclear metabolism, Ribosomes metabolism, Signal Recognition Particle metabolism, Signal Recognition Particle physiology, Bacterial Proteins physiology, Escherichia coli Proteins physiology, GTP Phosphohydrolases physiology, Protein Transport, Receptors, Cytoplasmic and Nuclear chemistry, Receptors, Cytoplasmic and Nuclear physiology, Receptors, Peptide chemistry, Signal Recognition Particle chemistry

Abstract

The "GTPase switch" paradigm, in which a GTPase switches between an active, GTP-bound state and an inactive, GDP-bound state through the recruitment of nucleotide exchange factors (GEFs) or GTPase activating proteins (GAPs), has been used to interpret the regulatory mechanism of many GTPases. A notable exception to this paradigm is provided by two GTPases in the signal recognition particle (SRP) and the SRP receptor (SR) that control the co-translational targeting of proteins to cellular membranes. Instead of the classical "GTPase switch," both the SRP and SR undergo a series of discrete conformational rearrangements during their interaction with one another, culminating in their reciprocal GTPase activation. Here, we show that this series of rearrangements during SRP-SR binding and activation provide important control points to drive and regulate protein targeting. Using real-time fluorescence, we showed that the cargo for SRP--ribosomes translating nascent polypeptides with signal sequences--accelerates SRP.SR complex assembly over 100-fold, thereby driving rapid delivery of cargo to the membrane. A series of subsequent rearrangements in the SRP x SR GTPase complex provide important driving forces to unload the cargo during late stages of protein targeting. Further, the cargo delays GTPase activation in the SRP.SR complex by 8-12 fold, creating an important time window that could further improve the efficiency and fidelity of protein targeting. Thus, the SRP and SR GTPases, without recruiting external regulatory factors, constitute a self-sufficient system that provides exquisite spatial and temporal control of a complex cellular process.

Published

2009

12. 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

13. 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

14. 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

15. 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

16. Elongation arrest by SecM via a cascade of ribosomal RNA rearrangements.

Author

Mitra K, Schaffitzel C, Fabiola F, Chapman MS, Ban N, and Frank J

Subjects

Cryoelectron Microscopy, Escherichia coli genetics, Escherichia coli metabolism, Escherichia coli Proteins genetics, Macromolecular Substances, Models, Molecular, Nucleic Acid Conformation, Peptide Chain Elongation, Translational, Protein Conformation, RNA, Bacterial chemistry, RNA, Bacterial genetics, RNA, Ribosomal chemistry, RNA, Ribosomal genetics, RNA, Ribosomal, 23S chemistry, RNA, Ribosomal, 23S genetics, RNA, Ribosomal, 23S metabolism, Ribosomes metabolism, Transcription Factors genetics, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, RNA, Bacterial metabolism, RNA, Ribosomal metabolism, Transcription Factors chemistry, Transcription Factors metabolism

Abstract

In E. coli, the SecM nascent polypeptide causes elongation arrest, while interacting with 23S RNA bases A2058 and A749-753 in the exit tunnel of the large ribosomal subunit. We compared atomic models fitted by real-space refinement into cryo-electron microscopy reconstructions of a pretranslocational and SecM-stalled E. coli ribosome complex. A cascade of RNA rearrangements propagates from the exit tunnel throughout the large subunit, affecting intersubunit bridges and tRNA positions, which in turn reorient small subunit RNA elements. Elongation arrest could result from the inhibition of mRNA.(tRNAs) translocation, E site tRNA egress, and perhaps translation factor activation at the GTPase-associated center. Our study suggests that the specific secondary and tertiary arrangement of ribosomal RNA provides the basis for internal signal transduction within the ribosome. Thus, the ribosome may itself have the ability to regulate its progression through translation by modulating its structure and consequently its receptivity to activation by cofactors.

Published

2006

17. 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

18. 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

19. 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

20. 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