scholarly journals Effects of protein size, thermodynamic stability, and net charge on cotranslational folding on the ribosome

2018 ◽  
Author(s):  
José Arcadio Farías-Rico ◽  
Frida Ruud Selin ◽  
Ioanna Myronidi ◽  
Marie Frühauf ◽  
Gunnar von Heijne
Keyword(s):  
Protein Folding ◽  
Thermodynamic Stability ◽  
Protein Size ◽  
Ribosomal Protein S6 ◽  
Complex Process ◽  
Cotranslational Folding ◽  
Nascent Chain ◽  
Comprehensive Picture ◽  
Pulse Proteolysis ◽  
Net Charges

AbstractDuring the last five decades, studies of protein folding in dilute buffer solutions have produced a rich picture of this complex process. In the cell, however, proteins can start to fold while still attached to the ribosome (cotranslational folding) and it is not yet clear how the ribosome affects the folding of protein domains of different sizes, thermodynamic stabilities, and net charges. Here, by using arrest peptides as force sensors and on-ribosome pulse proteolysis, we provide a comprehensive picture of how the distance from the peptidyl transferase center in the ribosome at which proteins fold correlates with protein size. Moreover, an analysis of a large collection of mutants of theE. coliribosomal protein S6 shows that the force exerted on the nascent chain by protein folding varies linearly with the thermodynamic stability of the folded state, and that the ribosome environment disfavors folding of domains of high net-negative charge.

scholarly journals Effects of protein size, thermodynamic stability, and net charge on cotranslational folding on the ribosome

2018 ◽  
Vol 115 (40) ◽  
pp. E9280-E9287 ◽  
Author(s):  
José Arcadio Farías-Rico ◽  
Frida Ruud Selin ◽  
Ioanna Myronidi ◽  
Marie Frühauf ◽  
Gunnar von Heijne
Keyword(s):  
Protein Folding ◽  
Thermodynamic Stability ◽  
Protein Size ◽  
Ribosomal Protein S6 ◽  
Complex Process ◽  
Cotranslational Folding ◽  
Nascent Chain ◽  
Comprehensive Picture ◽  
Pulse Proteolysis ◽  
Net Charges

During the last five decades, studies of protein folding in dilute buffer solutions have produced a rich picture of this complex process. In the cell, however, proteins can start to fold while still attached to the ribosome (cotranslational folding) and it is not yet clear how the ribosome affects the folding of protein domains of different sizes, thermodynamic stabilities, and net charges. Here, by using arrest peptides as force sensors and on-ribosome pulse proteolysis, we provide a comprehensive picture of how the distance from the peptidyl transferase center in the ribosome at which proteins fold correlates with protein size. Moreover, an analysis of a large collection of mutants of theEscherichia coliribosomal protein S6 shows that the force exerted on the nascent chain by protein folding varies linearly with the thermodynamic stability of the folded state, and that the ribosome environment disfavors folding of domains of high net-negative charge.

scholarly journals Translation and folding of single proteins in real time

2017 ◽  
Vol 114 (22) ◽  
pp. E4399-E4407 ◽  
Author(s):  
Florian Wruck ◽  
Alexandros Katranidis ◽  
Knud H. Nierhaus ◽  
Georg Büldt ◽  
Martin Hegner
Keyword(s):  
Protein Folding ◽  
Amino Acid ◽  
Amino Acid Sequence ◽  
Real Time ◽  
Electrostatic Interactions ◽  
Tertiary Structure ◽  
Chain Elongation ◽  
Ribosomal Tunnel ◽  
Cotranslational Folding ◽  
Nascent Chain

Protein biosynthesis is inherently coupled to cotranslational protein folding. Folding of the nascent chain already occurs during synthesis and is mediated by spatial constraints imposed by the ribosomal exit tunnel as well as self-interactions. The polypeptide’s vectorial emergence from the ribosomal tunnel establishes the possible folding pathways leading to its native tertiary structure. How cotranslational protein folding and the rate of synthesis are linked to a protein’s amino acid sequence is still not well defined. Here, we follow synthesis by individual ribosomes using dual-trap optical tweezers and observe simultaneous folding of the nascent polypeptide chain in real time. We show that observed stalling during translation correlates with slowed peptide bond formation at successive proline sequence positions and electrostatic interactions between positively charged amino acids and the ribosomal tunnel. We also determine possible cotranslational folding sites initiated by hydrophobic collapse for an unstructured and two globular proteins while directly measuring initial cotranslational folding forces. Our study elucidates the intricate relationship among a protein’s amino acid sequence, its cotranslational nascent-chain elongation rate, and folding.

scholarly journals Gradual Compaction of the Nascent Peptide During Cotranslational Folding on the Ribosome

2020 ◽  
Author(s):  
Marija Liutkute ◽  
Manisankar Maiti ◽  
Ekaterina Samatova ◽  
Jörg Enderlein ◽  
Marina V. Rodnina
Keyword(s):  
Profile Analysis ◽  
Dynamic Properties ◽  
Correlation Spectroscopy ◽  
Fluorescence Correlation ◽  
Cotranslational Folding ◽  
Nascent Peptide ◽  
Nascent Chain ◽  
Force Profile ◽  
Exit Tunnel ◽  
Domain Stabilization

ABSTRACTNascent polypeptides begin to fold in the constrained space of the ribosomal peptide exit tunnel. Here we use force profile analysis (FPA) and photo-induced energy-transfer fluorescence correlation spectroscopy (PET-FCS) to show how a small α-helical domain, the N-terminal domain of HemK, folds cotranslationally. Compaction starts vectorially as soon as the first α-helical segments are synthesized. As nascent chain grows, emerging helical segments dock onto each other and continue to rearrange at the vicinity of the ribosome. Inside or in the proximity of the ribosome, the nascent peptide undergoes structural fluctuations on the μs time scale. The fluctuations slow down as the domain moves away from the ribosome. Folding mutations have little effect on folding within the exit tunnel, but abolish the final domain stabilization. The results show the power of FPA and PET-FCS in solving the trajectory of cotranslational protein folding and in characterizing the dynamic properties of folding intermediates.

scholarly journals Cotranslational folding allows misfolding-prone proteins to circumvent deep kinetic traps

2020 ◽  
Vol 117 (3) ◽  
pp. 1485-1495 ◽  
Author(s):  
Amir Bitran ◽  
William M. Jacobs ◽  
Xiadi Zhai ◽  
Eugene Shakhnovich
Keyword(s):  
Self Assembly ◽  
Molecular Mechanisms ◽  
Folding Kinetics ◽  
Rare Codons ◽  
Cotranslational Folding ◽  
Nascent Chain ◽  
Kinetic Traps ◽  
Optimal Window

Many large proteins suffer from slow or inefficient folding in vitro. It has long been known that this problem can be alleviated in vivo if proteins start folding cotranslationally. However, the molecular mechanisms underlying this improvement have not been well established. To address this question, we use an all-atom simulation-based algorithm to compute the folding properties of various large protein domains as a function of nascent chain length. We find that for certain proteins, there exists a narrow window of lengths that confers both thermodynamic stability and fast folding kinetics. Beyond these lengths, folding is drastically slowed by nonnative interactions involving C-terminal residues. Thus, cotranslational folding is predicted to be beneficial because it allows proteins to take advantage of this optimal window of lengths and thus avoid kinetic traps. Interestingly, many of these proteins’ sequences contain conserved rare codons that may slow down synthesis at this optimal window, suggesting that synthesis rates may be evolutionarily tuned to optimize folding. Using kinetic modeling, we show that under certain conditions, such a slowdown indeed improves cotranslational folding efficiency by giving these nascent chains more time to fold. In contrast, other proteins are predicted not to benefit from cotranslational folding due to a lack of significant nonnative interactions, and indeed these proteins’ sequences lack conserved C-terminal rare codons. Together, these results shed light on the factors that promote proper protein folding in the cell and how biomolecular self-assembly may be optimized evolutionarily.

scholarly journals Chaperoning ribosome assembly

2010 ◽  
Vol 189 (1) ◽  
pp. 11-12 ◽  
Author(s):  
Katrin Karbstein
Keyword(s):  
Protein Folding ◽  
Ribosome Assembly ◽  
Cell Biol ◽  
Nascent Chain ◽  
Cellular Compartments

Chaperones help proteins fold in all cellular compartments, and many associate directly with ribosomes, capturing nascent chains to assist their folding and prevent aggregation. In this issue, new data from Koplin et al. (2010. J. Cell Biol. doi: 10.1083/jcb.200910074) and Albanèse et al. (2010. J. Cell Biol. doi: 10.1083/jcb.201001054) suggest that in addition to promoting protein folding, the chaperones ribosome-associated complex (RAC), nascent chain–associated complex (NAC), and Jjj1 also help in the assembly of ribosomes.

scholarly journals A ribosome-anchored chaperone network that facilitates eukaryotic ribosome biogenesis

2010 ◽  
Vol 189 (1) ◽  
pp. 69-81 ◽  
Author(s):  
Véronique Albanèse ◽  
Stefanie Reissmann ◽  
Judith Frydman
Keyword(s):  
Protein Folding ◽  
Ribosome Biogenesis ◽  
De Novo ◽  
Protein Biosynthesis ◽  
Critical Role ◽  
Cellular Protein ◽  
Complex Process ◽  
J Proteins ◽  
Oligomeric Complex ◽  
Chaperone Network

Molecular chaperones assist cellular protein folding as well as oligomeric complex assembly. In eukaryotic cells, several chaperones termed chaperones linked to protein synthesis (CLIPS) are transcriptionally and physically linked to ribosomes and are implicated in protein biosynthesis. In this study, we show that a CLIPS network comprising two ribosome-anchored J-proteins, Jjj1 and Zuo1, function together with their partner Hsp70 proteins to mediate the biogenesis of ribosomes themselves. Jjj1 and Zuo1 have overlapping but distinct functions in this complex process involving the coordinated assembly and remodeling of dozens of proteins on the ribosomal RNA (rRNA). Both Jjj1 and Zuo1 associate with nuclear 60S ribosomal biogenesis intermediates and play an important role in nuclear rRNA processing, leading to mature 25S rRNA. In addition, Zuo1, acting together with its Hsp70 partner, SSB (stress 70 B), also participates in maturation of the 35S rRNA. Our results demonstrate that, in addition to their known cytoplasmic roles in de novo protein folding, some ribosome-anchored CLIPS chaperones play a critical role in nuclear steps of ribosome biogenesis.

scholarly journals The ribosome and its role in protein folding: looking through a magnifying glass

2017 ◽  
Vol 73 (6) ◽  
pp. 509-521 ◽  
Author(s):  
Abid Javed ◽  
John Christodoulou ◽  
Lisa D. Cabrita ◽  
Elena V. Orlova
Keyword(s):  
Protein Folding ◽  
Structural Biology ◽  
Polypeptide Chain ◽  
Structure And Function ◽  
Cellular Activity ◽  
Cryo Electron Microscopy ◽  
Nascent Chain ◽  
Exit Tunnel ◽  
Dynamics Simulations ◽  
And Function

Protein folding, a process that underpins cellular activity, begins co-translationally on the ribosome. During translation, a newly synthesized polypeptide chain enters the ribosomal exit tunnel and actively interacts with the ribosome elements – the r-proteins and rRNA that line the tunnel – prior to emerging into the cellular milieu. While understanding of the structure and function of the ribosome has advanced significantly, little is known about the process of folding of the emerging nascent chain (NC). Advances in cryo-electron microscopy are enabling visualization of NCs within the exit tunnel, allowing early glimpses of the interplay between the NC and the ribosome. Once it has emerged from the exit tunnel into the cytosol, the NC (still attached to its parent ribosome) can acquire a range of conformations, which can be characterized by NMR spectroscopy. Using experimental restraints within molecular-dynamics simulations, the ensemble of NC structures can be described. In order to delineate the process of co-translational protein folding, a hybrid structural biology approach is foreseeable, potentially offering a complete atomic description of protein folding as it occurs on the ribosome.

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