Loss of conformational entropy in protein folding calculated using realistic ensembles and its implications for NMR-based calculations

Baxa, Michael C.; Haddadian, Esmael J.; Jumper, John; Freed, Karl F.; Sosnick, Tobin R.

doi:10.1073/pnas.1407768111

Cited by 108 publications

(116 citation statements)

References 59 publications

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“…The experimentally observed entropy loss upon folding often is near zero: ΔS exp ∼ 0 ∼ ΔS solvent + ΔS conf , implying that the gain in solvent entropy gain is largely counterbalanced by the loss of conformational entropy, ΔS solvent ∼ −ΔS conf (50,52). Indeed, our estimation of ΔS conf ∼ 1.4 kcal·mol −1 ·res −1 / (300 K) (36,37), is similar to the above estimate of hydrophobic stabilization. However, sfAFP buries only 40% of the hydrophobic surface area of a typical protein.…”

Section: Significancesupporting

confidence: 81%

“…Explicit solvent molecular dynamics (MD) simulations were analyzed to calculate the conformational entropy of sfAFP in its native state for comparison with the model protein ubiquitin (Ub). Entropy is calculated according to S = -R Σ i P i lnP i , where P i is the population in 10°× 10°pixels in the Ramachandran map (36,37). We find that residues in sfAFP's PP2 helices and in Ub's β-sheets exhibit comparable backbone entropy (Fig.…”

Section: Significancementioning

confidence: 90%

“…Our prior studies (36,37) found that the backbone entropy of glycine in the unfolded state exceeds other residues by 0.3 kcal·mol −1 ·res −1 /(300 K). However, other residue types additionally lose side-chain entropy upon folding.…”

Section: Significancementioning

confidence: 93%

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Perplexing cooperative folding and stability of a low-sequence complexity, polyproline 2 protein lacking a hydrophobic core

Gates

Baxa

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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The burial of hydrophobic side chains in a protein core generally is thought to be the major ingredient for stable, cooperative folding. Here, we show that, for the snow flea antifreeze protein (sfAFP), stability and cooperativity can occur without a hydrophobic core, and without α-helices or β-sheets. sfAFP has low sequence complexity with 46% glycine and an interior filled only with backbone H-bonds between six polyproline 2 (PP2) helices. However, the protein folds in a kinetically two-state manner and is moderately stable at room temperature. We believe that a major part of the stability arises from the unusual match between residue-level PP2 dihedral angle bias in the unfolded state and PP2 helical structure in the native state. Additional stabilizing factors that compensate for the dearth of hydrophobic burial include shorter and stronger H-bonds, and increased entropy in the folded state. These results extend our understanding of the origins of cooperativity and stability in protein folding, including the balance between solvent and polypeptide chain entropies.protein folding | cooperativity | kinetics | PP2 | hydrogen bonding T he basis of protein-folding stability and cooperativity remains a topic of great interest (1, 2). Most studies have focused on proteins with hydrophobic cores containing α-helices and β-sheets. Here, we study the folding of snow flea antifreeze protein (sfAFP), a globular protein that lacks these features. The 81-residue protein has a novel fold that is distinct from other proteins (3-6), containing only polyproline 2 (PP2) helices and turns with a core filled with H-bonds and no hydrophobic groups (Fig. 1).The H-bond network between the PP2 helices (6), PP2 1-6 , requires close packing, which would be precluded by the presence of a C β atom. Thus, the PP2 helices are defined by glycine (Gly) repeats (GXX or GGX, where X is any other amino acid), which enable the hydrogen-bond network. As a consequence, the sfAFP molecule has a low-complexity glycine-rich sequence [37/81 Gly residues, or 46%; typical is 6, or 7% (7)]. The sfAFP core is well packed with essentially no interior void volumes, even when probed using a 0.5-Å radius sphere (8). sfAFP also contains two disulfide bonds, C1-C28 and C13-C43.Notably, no side chains are buried in sfAFP's core (2). All 12 hydrophobic side chains (V 4 , K 2 , and P 6 ) are surface exposed. Upon folding, sfAFP buries about 20 Å 2 ·res −1 of hydrophobic surface area compared with an average of 50 Å 2 ·res −1 for a set of 34 proteins of similar size (Fig. 2A). The difference equates to a decrease in stability of ∼1 or 1.4 kcal·mol −1 ·res −1 , assuming a surface tension coefficient of γ ∼ 34 or 47 cal·mol −1 ·Å −2 based on classical (9) or Flory-Huggins theory (10), respectively. Even the lower bound of 1 kcal·mol −1 ·res −1 represents a significant stability loss, and it is not obvious which energetic terms could compensate for the reduction in hydrophobic burial.Because hydrophobic burial is generally regarded as the basis of protein stability a...

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Section: Significancesupporting

confidence: 81%

Section: Significancementioning

confidence: 90%

See 1 more Smart Citation

Perplexing cooperative folding and stability of a low-sequence complexity, polyproline 2 protein lacking a hydrophobic core

Gates

Baxa

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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“…As mentioned already, entropy has been one of the most difficult quantities to calculate directly from trajectories, and a consensus has not been reached on the best approach. To test whether the difference between

Δ Δ G_{solv}^{exp}

and

Δ Δ G_{solv}^{imp}

can be reduced by calculating

Δ S_{normalV}

with a different approach, we repeated our analysis using a relatively simple method described in a recently published paper, which we refer to as the additive joint entropy method. The entropies calculated with this method often differ by up to a factor of two from the ones calculated with the CC‐MLA method (Supporting Information Table S3), and generally led to better agreement between

Δ Δ G_{solv}^{exp}

and

Δ Δ G_{solv}^{imp}

(Supporting Information Fig.…”

Section: Resultsmentioning

confidence: 99%

“…CENCALC was used for the entropies calculated with the CC‐MLA method, while an in‐house implementation was used for the approach by Baxa et al, referred to here as the additive joint entropy method, with a bin size of 10°. These entropy calculations used the same number of frames as the energy calculations.…”

Section: Methodsmentioning

confidence: 99%

Free energies of solvation in the context of protein folding: Implications for implicit and explicit solvent models

Cumberworth¹,

Bui²,

Gsponer³

2015

J Comput Chem

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Implicit solvent models for biomolecular simulations have been developed to use in place of more expensive explicit models; however, these models make many assumptions and approximations that are likely to affect accuracy. Here, the changes in free energies of solvation upon folding ΔΔGsolv of several fast folding proteins are calculated from previously run μs-ms simulations with a number of implicit solvent models and compared to the values needed to be consistent with the explicit solvent model used in the simulations. In the majority of cases, there is a significant and substantial difference between the ΔΔGsolv values calculated from the two approaches that is robust to the details of the calculations. These differences could only be remedied by selecting values for the model parameters-the internal dielectric constant for the polar term and the surface tension coefficient for the nonpolar term-that were system-specific or physically unrealistic. We discuss the potential implications of our findings for both implicit and explicit solvent simulations. © 2015 Wiley Periodicals, Inc.

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Shedding light on the extra thermal stability of thermophilic proteins

Pica

Graziano

2016

Biopolymers

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An entropic stabilization mechanism has recently gained attention and credibility as the physical ground for the extra thermal stability of globular proteins from thermophilic microorganisms. An empirical result, obtained from the analysis of thermodynamic data for a large set of proteins, strengthens the general reliability of the theoretical approach originally devised to rationalize the occurrence of cold denaturation [Graziano, PCCP 2014, 16, 21755-21767]. It is shown that this theoretical approach can readily account for the entropic stabilization mechanism. On decreasing the conformational entropy gain associated with denaturation, the thermal stability of a model globular protein increases markedly.

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Loss of conformational entropy in protein folding calculated using realistic ensembles and its implications for NMR-based calculations

Cited by 108 publications

References 59 publications

Perplexing cooperative folding and stability of a low-sequence complexity, polyproline 2 protein lacking a hydrophobic core

Perplexing cooperative folding and stability of a low-sequence complexity, polyproline 2 protein lacking a hydrophobic core

Free energies of solvation in the context of protein folding: Implications for implicit and explicit solvent models

Shedding light on the extra thermal stability of thermophilic proteins

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