Principles of protein folding — A perspective from simple exact models

Dill, Ken A.; Bromberg, Sarina; Yue, Kaizhi; Fiebig, Klaus M.; Yee, David P.; Thomas, Paul D.; Chan, Hue Sun

doi:10.1002/pro.5560040401

Cited by 1,379 publications

(489 citation statements)

References 355 publications

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“…From a thermodynamic perspective, the sequestration of the hydrophobic side chains from the solvent facilitates the formation of folding intermediates and therefore hydrophobic collapse occurs spontaneously and results in the formation of the molten globule state (Dill et al, 1995;Kauzmann, 1959). The second view about protein folding, also regarded as "framework model" postulates that the folding process is a directed process where the local interactions lead to the transient formation of the secondary structural elements.…”

Section: Ii1 Proteinsmentioning

confidence: 99%

“…There is a gradual build-up/layering of new structures over the previous ones which help in stabilization of folding intermediates. During this process, the water molecules are excluded from the hydrophobic core which minimizes the free energy and leads to the collapse of the partially folded polypeptide chain to its native state (Daggett and Fersht, 2003;Dill et al, 1995).…”

Section: Ii1 Proteinsmentioning

confidence: 99%

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Firefly luciferase mutants as sensors of proteome stress

et al. 2011

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Section: Ii1 Proteinsmentioning

confidence: 99%

Section: Ii1 Proteinsmentioning

confidence: 99%

Firefly luciferase mutants as sensors of proteome stress

et al. 2011

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“…[30][31][32][33][34] In a separate example, even the use of high resolution experimental techniques such as coupling of H/D exchange with 2D NMR only allows detection of intermediate states with almost native-like five-strand b-sheet conformation during the earliest stage of Ubiquitin folding. 35,36 Computer simulations of protein models at different resolutions, from simple lattice models (and off-lattice) [37][38][39] to continuum solvent models 38,40,41 to all-atom explicit solvent models, 42,43 have been used to supplement existing experimental techniques in understanding aspects of protein folding. 44,45 In principle, molecular dynamics (MD) simulations with an atomistic description of the protein and solvent molecules should provide the most realistic description of the protein folding landscapes.…”

Section: Introductionmentioning

confidence: 99%

β‐strand interactions at the domain interface critical for the stability of human lens γD‐crystallin

2009

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Human age-onset cataracts are believed to be caused by the aggregation of partially unfolded or covalently damaged lens crystallin proteins; however, the exact molecular mechanism remains largely unknown. We have used microseconds of molecular dynamics simulations with explicit solvent to investigate the unfolding process of human lens cD-crystallin protein and its isolated domains. A partially unfolded folding intermediate of cD-crystallin is detected in simulations with its C-terminal domain (C-td) folded and N-terminal domain (N-td) unstructured, in excellent agreement with biochemical experiments. Our simulations strongly indicate that the stability and the folding mechanism of the N-td are regulated by the interdomain interactions, consistent with experimental observations. A hydrophobic folding core was identified within the C-td that is comprised of a and b strands from the Greek key motif 4, the one near the domain interface. Detailed analyses reveal a surprising non-native surface salt-bridge between Glu135 and Arg142 located at the end of the ab folded hairpin turn playing a critical role in stabilizing the folding core. On the other hand, an in silico single E135A substitution that disrupts this non-native Glu135-Arg142 salt-bridge causes significant destabilization to the folding core of the isolated C-td, which, in turn, induces unfolding of the N-td interface. These findings indicate that certain highly conserved charged residues, that is, Glu135 and Arg142, of cD-crystallin are crucial for stabilizing its hydrophobic domain interface in native conformation, and disruption of charges on the cD-crystallin surface might lead to unfolding and subsequent aggregation.

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“…[1][2][3][4] This observation has lead to a strategy for the design of de novo proteins based on the choice of amino acid sequences whose pattern of polar and nonpolar amino acids insures that hydrophobic residues will be buried on folding into the target structure. [3][4][5][6][7][8][9][10][11][12] Other considerations, such as secondary structure propensity, geometric packing, shape complementarity, salt-bridge specificity, and negative design can also play a role in further narrowing (optimizing) the sequences considered in the design process.…”

Section: Introductionmentioning

confidence: 99%

“…To address questions (2) and (3) we designed a number of a sequence ''mutations'': (i) three different mutations for the F21 sequence, which show a partial role of additional polar residues in stabilizing the four-helix fold as well as the possibility to further optimize F21 by inserting nonpolar residues in ad hoc positions and (ii) one mutation for the F14 sequence, which leads to an equilibrium structure population dominated by stable four-helix bundles.…”

Section: Introductionmentioning

confidence: 99%

Relative stability of de novo four–helix bundle proteins: Insights from coarse grained molecular simulations

2011

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We use a recently developed coarse-grained computational model to investigate the relative stability of two different sets of de novo designed four-helix bundle proteins. Our simulations suggest a possible explanation for the experimentally observed increase in stability of the four-helix bundles with increasing sequence length. In details, we show that both short subsequences composed only by polar residues and additional nonpolar residues inserted, via different point mutations in ad hoc positions, seem to play a significant role in stabilizing the fourhelix bundle conformation in the longer sequences. Finally, we propose an additional mutation that rescues a short amino acid sequence that would otherwise adopt a compact misfolded state. Our work suggests that simple computational models can be used as a complementary tool in the design process of de novo proteins.

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Principles of protein folding — A perspective from simple exact models

Cited by 1,379 publications

References 355 publications

Firefly luciferase mutants as sensors of proteome stress

Firefly luciferase mutants as sensors of proteome stress

β‐strand interactions at the domain interface critical for the stability of human lens γD‐crystallin

Relative stability of de novo four–helix bundle proteins: Insights from coarse grained molecular simulations

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