Systematic mapping of free energy landscapes of a growing filamin domain during biosynthesis

Cotranslational folding (CTF) is a fundamental molecular process that ensures efficient protein biosynthesis and minimizes the formation of misfolded states. However, the complexity of this process makes it extremely challenging to obtain structural characterizations of CTF pathways. Here, we correlate observations of translationally arrested nascent chains with those of a systematic C-terminal truncation strategy. We create a detailed description of chain length-dependent free energy landscapes associated with folding of the FLN5 filamin domain, in isolation and on the ribosome, and thus, quantify a substantial destabilization of the native structure on the ribosome. We identify and characterize two folding intermediates formed in isolation, including a partially folded intermediate associated with the isomerization of a conserved cis proline residue. The slow folding associated with this process raises the prospect that neighboring unfolded domains might accumulate and misfold during biosynthesis. We develop a simple model to quantify the risk of misfolding in this situation and show that catalysis of folding by peptidyl-prolyl isomerases is sufficient to eliminate this hazard.

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Systematic mapping of the free energy landscapes of a growing immunoglobulin domain identifies a kinetic intermediate associated with co-translational proline isomerization

10.1101/189050 ◽

2017 ◽

Author(s):

Christopher A. Waudby ◽

Maria-Evangelia Karyadi ◽

Tomasz Wlodarski ◽

Anaïs M. E. Cassaignau ◽

Sammy Chan ◽

...

Keyword(s):

Free Energy ◽

Protein Biosynthesis ◽

Energy Landscapes ◽

Folding Kinetics ◽

Proline Isomerization ◽

Partially Folded Intermediate ◽

Free Energy Landscapes ◽

Immunoglobulin Domain ◽

Peptidyl Prolyl Isomerases ◽

Structural Characterizations

AbstractCo-translational folding is a fundamental molecular process that ensures efficient protein biosynthesis and minimizes the wasteful or hazardous formation of misfolded states. However, the complexity of this process makes it extremely challenging to obtain structural characterizations of co-translational folding pathways. Here we contrast observations in translationally-arrested nascent chains with those of a systematic C-terminal truncation strategy. We create a detailed description of chain length-dependent free energy landscapes associated with folding of the FLN5 filamin domain, in isolation and on the ribosome. By using this approach we identify and characterize two folding intermediates, including a partially folded intermediate associated with the isomerization of a conserved proline residue, which, together with measurements of folding kinetics, raises the prospect that neighboring unfolded domains might accumulate during biosynthesis. We develop a simple model to quantify the risk of misfolding in this situation, and show that catalysis of folding by peptidyl-prolyl isomerases is essential to eliminate this hazard.

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Towards complete descriptions of the free–energy landscapes of proteins

Philosophical Transactions of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rsta.2004.1501 ◽

2004 ◽

Vol 363 (1827) ◽

pp. 433-452 ◽

Cited By ~ 55

Author(s):

Michele Vendruscolo ◽

Christopher M. Dobson

Keyword(s):

Free Energy ◽

Resonance Spectroscopy ◽

Energy Landscapes ◽

Native Structure ◽

Wide Range ◽

Protein Molecules ◽

Different Types ◽

Free Energy Landscapes ◽

Dynamics Simulations ◽

Do So

In recent years increasingly detailed information about the structures and dynamics of protein molecules has been obtained by innovative applications of experimental techniques, in particular nuclear magnetic resonance spectroscopy and protein engineering, and theoretical methods, notably molecular dynamics simulations. In this article we discuss how such approaches can be combined by incorporating a wide range of different types of experimental data as restraints in computer simulations to provide unprecedented detail about the ensembles of structures that describe proteins in a wide variety of states from the native structure to highly unfolded species. Knowledge of these ensembles is beginning to enable the complete free–energy landscapes of individual proteins to be defined at atomic resolution. This strategy has provided new insights into the mechanism by which proteins are able to fold into their native states, or by which they fail to do so and give rise to harmful aggregates that are associated with a wide range of debilitating human diseases.

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FOLDING FREE ENERGY LANDSCAPE OF THE DECAPEPTIDE CHIGNOLIN

Modern Physics Letters B ◽

10.1142/s0217984908017606 ◽

2008 ◽

Vol 22 (31) ◽

pp. 3087-3098 ◽

Cited By ~ 5

Author(s):

XIANGHUA DOU ◽

JIHUA WANG

Keyword(s):

Free Energy ◽

Force Field ◽

Force Fields ◽

Energy Landscapes ◽

Native Structure ◽

Good Template ◽

Free Energy Landscapes ◽

Folded Structures ◽

Dynamics Simulations ◽

Folding Free Energy

Chignolin is an artificially designed ten-residue (GYDPETGTWG) folded peptide, which is the smallest protein and provides a good template for protein folding. In this work, we completed four explicit water molecular dynamics simulations of Chignolin folding using GROMOS and OPLS-AA force fields from extended initial states without any experiment informations. The four-folding free energy landscapes of the peptide has been drawn. The folded state of Chignolin has been successfully predicated based on the free energy landscapes. The four independent simulations gave similar results. (i) The four free energy landscapes have common characters. They are fairly smooth, barrierless, funnel-like and downhill without intermediate state, which consists with the experiment. (ii) The different extended initial structures converge at similar folded structures with the lowest free energy under GROMOS and OPLS-AA force fields. In the GROMOS force field, the backbone RMSD of the folded structures from the NMR native structure of Chignolin is only 0.114 nm, which is a stable structure in this force field. In the OPLS-AA force field, the similar results have been obtained. In addition, the smallest RMSD structure is in better agreement with the NMR native structure but unlikely stable in the force field.

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