scholarly journals Unfolding the chaperone story

2017 ◽  
Vol 28 (22) ◽  
pp. 2919-2923 ◽  
Author(s):  
F. Ulrich Hartl
Keyword(s):  
Protein Folding ◽  
Molecular Chaperones ◽  
Current Concept ◽  
Cellular Process ◽  
Protein Chain ◽  
Native State ◽  
Folding Process ◽  
Spontaneous Process ◽  
Short Essay

Protein folding in the cell was originally assumed to be a spontaneous process, based on Anfinsen’s discovery that purified proteins can fold on their own after removal from denaturant. Consequently cell biologists showed little interest in the protein folding process. This changed only in the mid and late 1980s, when the chaperone story began to unfold. As a result, we now know that in vivo, protein folding requires assistance by a complex machinery of molecular chaperones. To ensure efficient folding, members of different chaperone classes receive the nascent protein chain emerging from the ribosome and guide it along an ordered pathway toward the native state. I was fortunate to contribute to these developments early on. In this short essay, I will describe some of the critical steps leading to the current concept of protein folding as a highly organized cellular process.

Cotranslational folding of proteins

1995 ◽  
Vol 73 (11-12) ◽  
pp. 1217-1220 ◽  
Author(s):  
Vyacheslav A. Kolb ◽  
Eugeny V. Makeyev ◽  
Aigar Kommer ◽  
Alexander S. Spirin
Keyword(s):  
Protein Folding ◽  
Biological Activity ◽  
Molecular Chaperones ◽  
Mature Protein ◽  
Native Structure ◽  
Folding Process ◽  
Cotranslational Folding

Many unfolded polypeptides are capable of refolding into their native structure upon the removal of the denaturant. However, the folding of the mature protein during renaturation does not accurately reflect the folding process of nascent proteins in the interior of the cell. This view resulted from the discovery of molecular chaperones known to modulate protein folding. Recent publications discussing the possible role and mechanisms of chaperone action suggest that folding in vivo may be a posttranslational process. Here we discuss data that indicate the final native structure and biological activity can be attainted by nascent protein on the ribosome, thus supporting the cotranslational folding hypothesis.Key words: nacent peptide, globin, luciferase, folding.

Principles of chaperone-mediated protein folding

1995 ◽  
Vol 348 (1323) ◽  
pp. 107-112 ◽  
Keyword(s):  
Protein Folding ◽  
Heat Shock ◽  
Heat Shock Proteins ◽  
Molecular Chaperones ◽  
Cellular Protein ◽  
Chaperone Proteins ◽  
Shock Proteins ◽  
Polypeptide Chains

The recent discovery of molecular chaperones and their functions has changed dramatically our view of the processes underlying the folding of proteins in vivo . Rather than folding spontaneously, most newly synthesized polypeptide chains seem to acquire their native conformations in a reaction mediated by chaperone proteins. Different classes of molecular chaperones, such as the members of the Hsp70 and Hsp60 families of heat-shock proteins, cooperate in a coordinated pathway of cellular protein folding.

scholarly journals Evolving cellular automata schemes for protein folding modeling using the Rosetta atomic representation

2022 ◽  
Author(s):  
Daniel Varela ◽  
José Santos
Keyword(s):  
Protein Folding ◽  
Cellular Automata ◽  
Cellular Automaton ◽  
Structure Refinement ◽  
Coarse Grained ◽  
Connectionist Model ◽  
Protein Chain ◽  
Folding Process ◽  
Folded Structure ◽  
Protein Components

AbstractProtein folding is the dynamic process by which a protein folds into its final native structure. This is different to the traditional problem of the prediction of the final protein structure, since it requires a modeling of how protein components interact over time to obtain the final folded structure. In this study we test whether a model of the folding process can be obtained exclusively through machine learning. To this end, protein folding is considered as an emergent process and the cellular automata tool is used to model the folding process. A neural cellular automaton is defined, using a connectionist model that acts as a cellular automaton through the protein chain to define the dynamic folding. Differential evolution is used to automatically obtain the optimized neural cellular automata that provide protein folding. We tested the methods with the Rosetta coarse-grained atomic model of protein representation, using different proteins to analyze the modeling of folding and the structure refinement that the modeling can provide, showing the potential advantages that such methods offer, but also difficulties that arise.

scholarly journals GroEL/ES buffers entropic traps in folding pathway during evolution of a model substrate

2020 ◽  
Author(s):  
Anwar Sadat ◽  
Satyam Tiwari ◽  
Kanika Verma ◽  
Arjun Ray ◽  
Mudassar Ali ◽  
...  
Keyword(s):  
Protein Folding ◽  
Molecular Chaperones ◽  
Folding Pathway ◽  
Substrate Protein ◽  
Model Protein ◽  
Physical Barriers ◽  
Evolutionary Step ◽  
Entropic Traps

ABSTRACTThe folding landscape of proteins can change during evolution with the accumulation of mutations that may introduce entropic or enthalpic barriers in the protein folding pathway, making it a possible substrate of molecular chaperones in vivo. Can the nature of such physical barriers of folding dictate the feasibility of chaperone-assistance? To address this, we have simulated the evolutionary step to chaperone-dependence keeping GroEL/ES as the target chaperone and GFP as a model protein in an unbiased screen. We find that the mutation conferring GroEL/ES dependence in vivo and in vitro encode an entropic trap in the folding pathway rescued by the chaperonin. Additionally, GroEL/ES can edit the formation of non-native contacts similar to DnaK/J/E machinery. However, this capability is not utilized by the substrates in vivo. As a consequence, GroEL/ES caters to buffer mutations that predominantly cause entropic traps, despite possessing the capacity to edit both enthalpic and entropic traps in the folding pathway of the substrate protein.

scholarly journals Molecular chaperones maximize the native state yield on biological times by driving substrates out of equilibrium

2017 ◽  
Vol 114 (51) ◽  
pp. E10919-E10927 ◽  
Author(s):  
Shaon Chakrabarti ◽  
Changbong Hyeon ◽  
Xiang Ye ◽  
George H. Lorimer ◽  
D. Thirumalai
Keyword(s):  
Molecular Chaperones ◽  
Atp Hydrolysis ◽  
General Relation ◽  
Native State ◽  
Folding Rate ◽  
Biologically Relevant ◽  
Final Yield ◽  
Short Time

Molecular chaperones facilitate the folding of proteins and RNA in vivo. Under physiological conditions, the in vitro folding ofTetrahymenaribozyme by the RNA chaperone CYT-19 behaves paradoxically; increasing the chaperone concentration reduces the yield of native ribozymes. In contrast, the protein chaperone GroEL works as expected; the yield of the native substrate increases with chaperone concentration. The discrepant chaperone-assisted ribozyme folding thus contradicts the expectation that it operates as an efficient annealing machine. To resolve this paradox, we propose a minimal stochastic model based on the Iterative Annealing Mechanism (IAM) that offers a unified description of chaperone-mediated folding of both proteins and RNA. Our theory provides a general relation that quantitatively predicts how the yield of native states depends on chaperone concentration. Although the absolute yield of native states decreases in theTetrahymenaribozyme, the product of the folding rate and the steady-state native yield increases in both cases. By using energy from ATP hydrolysis, both CYT-19 and GroEL drive their substrate concentrations far out of equilibrium, thus maximizing the native yield in a short time. This also holds when the substrate concentration exceeds that of GroEL. Our findings satisfy the expectation that proteins and RNA be folded by chaperones on biologically relevant time scales, even if the final yield is lower than what equilibrium thermodynamics would dictate. The theory predicts that the quantity of chaperones in vivo has evolved to optimize native state production of the folded states of RNA and proteins in a given time.

What does protein refolding in vitro tell us about protein folding in the cell?

1993 ◽  
Vol 339 (1289) ◽  
pp. 287-295 ◽  
Keyword(s):  
Protein Folding ◽  
Molecular Chaperones ◽  
Side Reaction ◽  
Kinetic Mechanism ◽  
Structural Elements ◽  
Native Structure ◽  
Extrinsic Factors ◽  
Structure Of Proteins

The classical in vitro denaturation-renaturation studies by Anson, Anfinsen, Neurath, Pauling and others clearly suggested that the primary structure of proteins determines all higher levels of protein structure. Protein folding in the cell is inaccessible to a detailed analysis of its kinetic mechanism. There are obvious differences: nascent proteins acquire their native structure co- and post-translationally, with half-times in the minutes range, whereas refolding starts from the complete polypeptide chain, with rates varying from seconds to days. In the cell, accessory proteins are involved in regulating the rate of folding and association. Their role can be analysed both in vivo , by mutant studies, or by coexpression together with recombinant model proteins, and in vitro , by folding experiments in the absence and in the presence of 'foldases’ and molecular chaperones, with the following general results: (i) folding is a sequential process involving native-like structural elements and a ‘collapsed state’ as early intermediates; (ii) the major side-reaction is caused by ‘kinetic partitioning’ between correct folding and wrong aggregation; (iii) rate-determining steps may be assisted by protein disulphide isomerase, peptidyl prolyl- cys - trans -isomerase, and molecular chaperones; and (iv) extrinsic factors, not encoded in the amino acid sequence, may be of crucial importance.

scholarly journals Breaking the Deadlock of Molecular Chaperones

2017 ◽  
Author(s):  
Tania Morán Luengo ◽  
Roman Kityk ◽  
Matthias P. Mayer ◽  
Stefan G. D. Rüdiger
Keyword(s):  
Protein Folding ◽  
Molecular Chaperones ◽  
Binding Pocket ◽  
Folding Pathway ◽  
Hydrophobic Core ◽  
Folding Intermediate ◽  
Native State ◽  
Folding Nucleus ◽  
Hydrophobic Binding ◽  
Highly Hydrophobic

AbstractProtein folding in the cell requires ATP-driven chaperone machines. It is poorly understood, however, how these machines fold proteins. Here we propose that the conserved Hsp70 and Hsp90 chaperones support formation of the folding nucleus by providing a gradient of decreasing hydrophobicity. Early on the folding pathway Hsp70 uses its highly hydrophobic binding pocket to recover a stalled, unproductive folding intermediate. The aggressive nature of Hsp70 action, however, blocks productive folding by grabbing hydrophobic, core-forming segments. This precludes on-pathway nucleation at high, physiological Hsp70 levels. Transfer to the less hydrophobic Hsp90 enables the intermediate to resume forming its folding nucleus. Subsequently, the protein enters a spontaneous folding trajectory towards its native state, independent of the ATPase activities of both Hsp70 and Hsp90. Our findings provide a general mechanistic concept for chaperoned protein folding.

scholarly journals Molecular chaperones maximize the native state yield per unit time by driving substrates out of equilibrium

2017 ◽  
Author(s):  
Shaon Chakrabarti ◽  
Changbong Hyeon ◽  
Xiang Ye ◽  
George H. Lorimer ◽  
D. Thirumalai
Keyword(s):  
Stochastic Model ◽  
Molecular Chaperones ◽  
Self Assembly ◽  
General Relation ◽  
Native State ◽  
Folding Rate ◽  
Absolute Yield ◽  
State Production ◽  
The Absolute

AbstractMolecular chaperones have evolved to facilitate folding of proteins and RNA in vivo where spontaneous self-assembly is sometimes prohibited. Folding of Tetrahymena ribozyme, assisted by the RNA chaperone CYT-19, surprisingly shows that at physiological Mg2+ ion concentrations, increasing the chaperone concentration reduces the yield of native ribozymes. In contrast, the more extensively investigated protein chaperone GroEL works in exactly the opposite manner—the yield of native substrate increases with the increase in chaperone concentration. Thus, the puzzling observation on the assisted-ribozyme folding seems to contradict the expectation that a molecular chaperone acts as an efficient annealing machine. We suggest a resolution to this apparently paradoxical behavior by developing a minimal stochastic model that captures the essence of the Iterative Annealing Mechanism (IAM), providing a unified description of chaperone mediated-folding of proteins and RNA. Our theory provides a general relation involving the kinetic rates of the system, which quantitatively predicts how the yield of native state depends on chaperone concentration. By carefully analyzing a host of experimental data on Tetrahymena (and its mutants) as well as the protein Rubisco and Malate Dehydrogenase, we show that although the absolute yield of native states decreases in the ribozyme, the rate of native state production increases in both the cases. By utilizing energy from ATP hydrolysis, both CYT-19 and GroEL drive their substrate concentrations far out of equilibrium, in an endeavor to maximize the native yield in a short time. Our findings are consistent with the general expectation that proteins or RNA need to be folded by the cellular machinery on biologically relevant timescales, even if the final yield is lower than what equilibrium thermodynamics would dictate. Besides establishing the IAM as the basis for functions of RNA and protein chaperones, our work shows that cellular copy numbers have been adjusted to optimize the rate of native state production of the folded states of RNA and proteins under physiological conditions.Significance statementMolecular chaperones have evolved to assist the folding of proteins and RNA, thus avoiding the deleterious consequences of misfolding. Thus, it is expected that increasing chaperone concentration should lead to an enhancement in native yield. While this has been observed in GroEL-mediated protein folding, experiments on Tetrahymena ribozyme folding assisted by CYT-19, surprisingly show the opposite trend. Here, we reconcile these divergent experimental observations by developing a unified stochastic model of chaperone assisted protein and RNA folding. We show that chaperones drive their substrates out of equilibrium, and in the process maximize the rate of native substrate production rather than the absolute yield or the folding rate. In vivo the number of chaperones is regulated to optimize their functions.

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