scholarly journals Peptidyl transferase center decompaction and structural constraints during early protein elongation on the ribosome

2021 ◽  
Vol 11 (1) ◽  
Author(s):  
Bin Jia ◽  
Tianlong Wang ◽  
Jean Lehmann
Keyword(s):  
Peptide Bond ◽  
Nucleophilic Attack ◽  
Structural Constraints ◽  
Peptide Bond Formation ◽  
Peptidyl Transferase ◽  
Peptidyl Transferase Center ◽  
Early Protein ◽  
Physico Chemical ◽  
Exit Tunnel ◽  
A Site

AbstractPeptide bond formation on the ribosome requires that aminoacyl-tRNAs and peptidyl-tRNAs are properly positioned on the A site and the P site of the peptidyl transferase center (PTC) so that nucleophilic attack can occur. Here we analyse some constraints associated with the induced-fit mechanism of the PTC, that promotes this positioning through a compaction around the aminoacyl ester orchestrated by U2506. The physical basis of PTC decompaction, that allows the elongated peptidyl-tRNA to free itself from that state and move to the P site of the PTC, is still unclear. From thermodynamics considerations and an analysis of published ribosome structures, the present work highlights the rational of this mechanism, in which the free-energy released by the new peptide bond is used to kick U2506 away from the reaction center. Furthermore, we show the evidence that decompaction is impaired when the nascent peptide is not yet anchored inside the exit tunnel, which may contribute to explain why the first rounds of elongation are inefficient, an issue that has attracted much interest for about two decades. Results in this field are examined in the light of the present analysis and a physico-chemical correlation in the genetic code, which suggest that elementary constraints associated with the size of the side-chain of the amino acids penalize early elongation events.

Symmetry at the active site of the ribosome: structural and functional implications

2005 ◽  
Vol 386 (9) ◽  
pp. 833-844 ◽  
Author(s):  
Ilana Agmon ◽  
Anat Bashan ◽  
Raz Zarivach ◽  
Ada Yonath
Keyword(s):  
Ribosomal Rna ◽  
Peptide Bond ◽  
Peptide Bond Formation ◽  
Entire Region ◽  
Peptidyl Transferase ◽  
Ribosomal Subunits ◽  
Peptidyl Transferase Center ◽  
Functional Implications ◽  
Exit Tunnel ◽  
Tunnel Entrance

Abstract The sizable symmetrical region, comprising 180 ribosomal RNA nucleotides, which has been identified in and around the peptidyl transferase center (PTC) in crystal structures of eubacterial and archaeal large ribosomal subunits, indicates its universality, confirms that the ribosome is a ribozyme and evokes the suggestion that the PTC evolved by gene fusion. The symmetrical region can act as a center that coordinates amino acid polymerization by transferring intra-ribosomal signals between remote functional locations, as it connects, directly or through its extensions, the PTC, the three tRNA sites, the tunnel entrance, and the regions hosting elongation factors. Significant deviations from the overall symmetry stabilize the entire region and can be correlated with the shaping and guiding of the motion of the tRNA 3′-end from the A- into the P-site. The linkage between the elaborate PTC architecture and the spatial arrangements of the tRNA 3′-ends revealed the rotatory mechanism that integrates peptide bond formation, translocation within the PTC and nascent protein entrance into the exit tunnel. The positional catalysis exerted by the ribosome places the reactants in stereochemistry close to the intermediate state and facilitates the catalytic contribution of the P-site tRNA 2′-hydroxyl.

scholarly journals Disome-seq reveals widespread ribosome collisions that promote cotranslational protein folding

2021 ◽  
Vol 22 (1) ◽  
Author(s):  
Taolan Zhao ◽  
Yan-Ming Chen ◽  
Yu Li ◽  
Jia Wang ◽  
Siyu Chen ◽  
...  
Keyword(s):  
Protein Quality ◽  
Peptide Bond ◽  
Peptide Bond Formation ◽  
Translation Elongation ◽  
Cryo Electron Microscopy ◽  
Cotranslational Folding ◽  
A Cell ◽  
Exit Tunnel ◽  
Hidden Layer ◽  
A Site

Abstract Background The folding of proteins is challenging in the highly crowded and sticky environment of a cell. Regulation of translation elongation may play a crucial role in ensuring the correct folding of proteins. Much of our knowledge regarding translation elongation comes from the sequencing of mRNA fragments protected by single ribosomes by ribo-seq. However, larger protected mRNA fragments have been observed, suggesting the existence of an alternative and previously hidden layer of regulation. Results In this study, we performed disome-seq to sequence mRNA fragments protected by two stacked ribosomes, a product of translational pauses during which the 5′-elongating ribosome collides with the 3′-paused one. We detected widespread ribosome collisions that are related to slow ribosome release when stop codons are at the A-site, slow peptide bond formation from proline, glycine, asparagine, and cysteine when they are at the P-site, and slow leaving of polylysine from the exit tunnel of ribosomes. The structure of disomes obtained by cryo-electron microscopy suggests a different conformation from the substrate of the ribosome-associated protein quality control pathway. Collisions occurred more frequently in the gap regions between α-helices, where a translational pause can prevent the folding interference from the downstream peptides. Paused or collided ribosomes are associated with specific chaperones, which can aid in the cotranslational folding of the nascent peptides. Conclusions Therefore, cells use regulated ribosome collisions to ensure protein homeostasis.

On Ribosome Conservation and Evolution

2006 ◽  
Vol 52 (3-4) ◽  
pp. 359-374 ◽  
Author(s):  
Ilana Agmon ◽  
Anat Bashan ◽  
Ada Yonath
Keyword(s):  
Bond Formation ◽  
Peptide Bond ◽  
Binding Modes ◽  
Peptide Bond Formation ◽  
Peptidyl Transferase ◽  
Peptide Bonds ◽  
Peptidyl Transferase Center ◽  
Enzymatic Function ◽  
Rotatory Motion ◽  
Rna Fold

The ribosome is a ribozyme whose active site, the peptidyl transferase center (PTC), is situated within a highly conserved universal symmetrical region that connects all ribosomal functional centers involved in amino acid polymerization. The linkage between this elaborate architecture and A-site tRNA position revealed that the A-> P-site passage of the tRNA terminus in the peptidyl transferase center is performed by a rotatory motion, synchronized with the overall tRNA/mRNA sideways movement. Guided by the PTC, the rotatory motion leads to stereochemistry suitable for peptide bond formation, as well as for substrate-mediated catalysis, consistent with quantum mechanical calculations elucidating the transition state mechanism for peptide bond formation and indicating that the peptide bond is being formed during the rotatory motion. Analysis of substrate binding modes to inactive and active ribosomes illuminated the significant PTC mobility and supported the hypothesis that the ancient ribosome produced single peptide bonds and non-coded chains, utilizing free amino acids. Genetic control of the reaction evolved after poly-peptides capable of enzymatic function were created, and an ancient stable RNA fold was converted into tRNA molecules. As the symmetry relates only the backbone fold and nucleotide orientations, but not nucleotide sequence, it emphasizes the superiority of functional requirement over sequence conservation, and indicates that the PTC has evolved by gene fusion, presumably by taking advantage of similar RNA fold structures.

scholarly journals Abstract P-29: Cryoem Study of the Inhibition of Bacterial Ribosomes by Madumycin II

2021 ◽  
Vol 11 (Suppl_1) ◽  
pp. S24-S25
Author(s):  
Alena Yakusheva ◽  
Olga Shulenina ◽  
Evgeny Pichkur ◽  
Alena Paleskava ◽  
Alexander Myasnikov ◽  
...  
Keyword(s):  
Amino Acid ◽  
High Resolution ◽  
Bond Formation ◽  
Protein Translation ◽  
Peptide Bond ◽  
Peptide Bond Formation ◽  
Peptidyl Transferase ◽  
Peptidyl Transferase Center ◽  
70S Ribosome ◽  
Madumycin Ii

Background: The efficiency of widely used antibiotics is limited by continuous improvement of resistance mechanisms. Thus, the research of poorly studied drugs that have not received practical use until now becomes relevant again. Protein translation is one of the major targets for antibiotics. Madumycin II (MADU) is an antibiotic of the streptogramin A class that binds to the peptidyl transferase center of the initiated bacterial 70S ribosome inhibiting the first cycle of peptide bond formation (I.A. Osterman et al. Nucleic Acids Res., 2017). The ability of MADU to interfere with translating ribosome is an open question that we address by investigation of high-resolution cryo-EM structures of MADU bound 70S ribosome complexes from Escherichia coli. Methods: Purified initiated and translating ribosome complexes preincubated with MADU were applied onto freshly glow discharged carbon-coated grids (Quantifoil R 1.2/1.3) and flash-frozen in the liquid ethane pre-cooled by liquid nitrogen in the Vitrobot Mark IV. Frozen grids were transferred into an in-house Titan Krios microscope. Data were collected using EPU software. Movie stacks were preprocessed in Warp software. For image processing, we have used several software packages: Relion 3.1, CryoSPARC, and CisTEM. The model was built in Coot. Results: We have obtained high-resolution cryo-EM structures of two ribosomal complexes with MADU before and after the first cycle of peptide bond formation with an average resolution of 2.3 Å. Preliminary analysis of the structures shows no major differences in the MADU binding mode to the ribosomal complexes under study suggesting that the quantity of amino acid residues attached to the P-site tRNA does not impact MADU bonding. Moreover, in both cases, we observed similar destabilization of the CCA-ends of A- and P-site tRNAs underlining the comparable influence of MADU on the ribosomal complexes. Conclusion: Our results suggest that although MADU binding site is located in the peptidyl transferase center, the presence of the second amino acid residue on the P-site tRNA does not preclude antibiotic binding. We assume that further elongation of the polypeptide chain would not have any impact either. High conformational lability of the CCA-ends of tRNA at the A and P sites upon binding of MADU obviously plays an important role in the inhibition mechanism of the bacterial ribosome. The further structural and biochemical analysis will be necessary to shed more light on the detailed mechanism of MADU action.

scholarly journals A functional connection between translation elongation and protein folding at the ribosome exit tunnel in Saccharomyces cerevisiae

2020 ◽  
Author(s):  
Olga Rodríguez-Galán ◽  
Juan J García-Gómez ◽  
Iván V Rosado ◽  
Wu Wei ◽  
Alfonso Méndez-Godoy ◽  
...  
Keyword(s):  
Ribosomal Proteins ◽  
Ribosome Biogenesis ◽  
De Novo ◽  
Peptide Bond Formation ◽  
Peptidyl Transferase ◽  
Translation Rate ◽  
Functional Connection ◽  
Translation Elongation ◽  
Peptidyl Transferase Center ◽  
Exit Tunnel

Abstract Proteostasis needs to be tightly controlled to meet the cellular demand for correctly de novo folded proteins and to avoid protein aggregation. While a coupling between translation rate and co-translational folding, likely involving an interplay between the ribosome and its associated chaperones, clearly appears to exist, the underlying mechanisms and the contribution of ribosomal proteins remain to be explored. The ribosomal protein uL3 contains a long internal loop whose tip region is in close proximity to the ribosomal peptidyl transferase center. Intriguingly, the rpl3[W255C] allele, in which the residue making the closest contact to this catalytic site is mutated, affects diverse aspects of ribosome biogenesis and function. Here, we have uncovered, by performing a synthetic lethal screen with this allele, an unexpected link between translation and the folding of nascent proteins by the ribosome-associated Ssb-RAC chaperone system. Our results reveal that uL3 and Ssb-RAC cooperate to prevent 80S ribosomes from piling up within the 5′ region of mRNAs early on during translation elongation. Together, our study provides compelling in vivo evidence for a functional connection between peptide bond formation at the peptidyl transferase center and chaperone-assisted de novo folding of nascent polypeptides at the solvent-side of the peptide exit tunnel.

scholarly journals Madumycin II inhibits peptide bond formation by forcing the peptidyl transferase center into an inactive state

2017 ◽  
Vol 45 (12) ◽  
pp. 7507-7514 ◽  
Author(s):  
Ilya A. Osterman ◽  
Nelli F. Khabibullina ◽  
Ekaterina S. Komarova ◽  
Pavel Kasatsky ◽  
Victor G. Kartsev ◽  
...  
Keyword(s):  
Bond Formation ◽  
Peptide Bond ◽  
Peptide Bond Formation ◽  
Peptidyl Transferase ◽  
Peptidyl Transferase Center ◽  
Inactive State ◽  
Madumycin Ii

scholarly journals Essential Mechanisms in the Catalysis of Peptide Bond Formation on the Ribosome

2005 ◽  
Vol 280 (43) ◽  
pp. 36065-36072 ◽  
Author(s):  
Malte Beringer ◽  
Christian Bruell ◽  
Liqun Xiong ◽  
Peter Pfister ◽  
Peter Bieling ◽  
...  
Keyword(s):  
Ph Dependence ◽  
Bond Formation ◽  
Peptide Bond ◽  
Activation Entropy ◽  
Peptide Bond Formation ◽  
Peptidyl Transferase ◽  
Peptidyl Transferase Center ◽  
Chemical Catalysis ◽  
Catalytic Function ◽  
Peptidyl Transfer

Peptide bond formation is the main catalytic function of the ribo-some. The mechanism of catalysis is presumed to be highly conserved in all organisms. We tested the conservation by comparing mechanistic features of the peptidyl transfer reaction on ribosomes from Escherichia coli and the Gram-positive bacterium Mycobacterium smegmatis. In both cases, the major contribution to catalysis was the lowering of the activation entropy. The rate of peptide bond formation was pH independent with the natural substrate, amino-acyl-tRNA, but was slowed down 200-fold with decreasing pH when puromycin was used as a substrate analog. Mutation of the conserved base A2451 of 23 S rRNA to U did not abolish the pH dependence of the reaction with puromycin in M. smegmatis, suggesting that A2451 did not confer the pH dependence. However, the A2451U mutation alters the structure of the peptidyl transferase center and changes the pattern of pH-dependent rearrangements, as probed by chemical modification of 23 S rRNA. A2451 seems to function as a pivot point in ordering the structure of the peptidyl transferase center rather than taking part in chemical catalysis.

scholarly journals Disome-seq reveals widespread ribosome collisions that recruit co-translational chaperones

2019 ◽  
Author(s):  
Taolan Zhao ◽  
Yan-Ming Chen ◽  
Yu Li ◽  
Jia Wang ◽  
Siyu Chen ◽  
...  
Keyword(s):  
Bond Formation ◽  
Peptide Bond ◽  
Protein Homeostasis ◽  
Peptide Bond Formation ◽  
Translation Elongation ◽  
Protein Levels ◽  
Cryo Electron Microscopy ◽  
Exit Tunnel ◽  
Hidden Layer ◽  
A Site

ABSTRACTRegulation of translation elongation plays a crucial role in determining absolute protein levels and ensuring the correct localization and folding of proteins. Much of our knowledge regarding translation elongation comes from the sequencing of mRNA fragments protected by single ribosomes (ribo-seq). However, larger protected mRNA fragments have been observed, suggesting the existence of an alternative and previously hidden layer of regulation. In this study, we performed disome-seq to sequence mRNA fragments protected by two stacked ribosomes — a product of translational pauses during which the 5′-ribosome collides with the 3′-paused one. We detected widespread ribosome collisions that are missed in traditional ribo-seq. These collisions are due to 1) slow ribosome release when stop codons are at the A-site, 2) slow peptide bond formation from proline, glycine, asparagine, and cysteine when they are at the P-site, and 3) slow leaving of polylysine from the exit tunnel of ribosomes. The paused ribosomes can continue translating after collisions, as suggested by the structure of disomes obtained by cryo-electron microscopy (cryo-EM). Collided ribosomes recruit chaperones, which can aid in the co-translational folding of the nascent peptides. Therefore, cells use regulated ribosome collisions to ensure protein homeostasis.

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