scholarly article | Q13442814 |
P50 | author | Sophie Sacquin-Mora | Q43240683 |
P2093 | author name string | Sophie Sacquin-Mora | |
P2860 | cites work | Non-functional conserved residues in globins and their possible role as a folding nucleus | Q78128162 |
Identifying protein folding cores from the evolution of flexible regions during unfolding | Q78605584 | ||
Folding of S6 structures with divergent amino acid composition: pathway flexibility within partly overlapping foldons | Q79286179 | ||
Different folding pathways taken by highly homologous proteins, goat alpha-lactalbumin and canine milk lysozyme | Q82539836 | ||
The nucleation mechanism of protein folding: a survey of computer simulation studies | Q84741155 | ||
The Protein Data Bank | Q24515306 | ||
Coupling between catalytic site and collective dynamics: a requirement for mechanochemical activity of enzymes | Q24549622 | ||
From snapshot to movie: phi analysis of protein folding transition states taken one step further | Q24657640 | ||
Folding pathway of the b1 domain of protein G explored by multiscale modeling | Q24683714 | ||
The nature of protein folding pathways | Q26998903 | ||
Conformational strain in the hydrophobic core and its implications for protein folding and design | Q27638976 | ||
Solution structures and backbone dynamics of the ribosomal protein S6 and its permutant P54-55 | Q27658327 | ||
Crystal structural analysis of mutations in the hydrophobic cores of barnase | Q27731488 | ||
Alpha-lactalbumin possesses a distinct zinc binding site | Q27731996 | ||
VMD: visual molecular dynamics | Q27860554 | ||
Protein folding and misfolding | Q28235199 | ||
Mechanical processes in biochemistry | Q28266209 | ||
How does a protein fold? | Q28299554 | ||
Nucleation mechanisms in protein folding | Q28303614 | ||
The folding of an enzyme. IV. Structure of an intermediate in the refolding of barnase analysed by a protein engineering procedure | Q28306230 | ||
COBALT: constraint-based alignment tool for multiple protein sequences | Q30014837 | ||
Nucleation and the transition state of the SH3 domain | Q30160240 | ||
Hydrophobic core packing in the SH3 domain folding transition state | Q30167681 | ||
Dynamics of large proteins through hierarchical levels of coarse-grained structures. | Q30330023 | ||
Protein folding and misfolding: mechanism and principles. | Q30368801 | ||
Molecular collapse: the rate-limiting step in two-state cytochrome c folding | Q30427366 | ||
How evolution makes proteins fold quickly | Q30430276 | ||
Structural dynamics flexibility informs function and evolution at a proteome scale | Q30431577 | ||
Experimental evidence for a frustrated energy landscape in a three-helix-bundle protein family | Q30493974 | ||
The folding of a family of three-helix bundle proteins: spectrin R15 has a robust folding nucleus, unlike its homologous neighbours. | Q30576249 | ||
The folding nucleus of a fibronectin type III domain is composed of core residues of the immunoglobulin-like fold | Q31853100 | ||
Determination of a transition state at atomic resolution from protein engineering data | Q33185120 | ||
The role of dynamics in enzyme activity | Q33185384 | ||
Equilibrium and kinetics of the folding and unfolding of canine milk lysozyme | Q33281043 | ||
The hydrogen exchange core and protein folding. | Q33714720 | ||
Mutational analysis of acylphosphatase suggests the importance of topology and contact order in protein folding. | Q33878446 | ||
Anisotropy of fluctuation dynamics of proteins with an elastic network model | Q33931550 | ||
Three key residues form a critical contact network in a protein folding transition state | Q33935381 | ||
Mapping the folding pathway of an immunoglobulin domain: structural detail from Phi value analysis and movement of the transition state | Q33948562 | ||
Constructing, verifying, and dissecting the folding transition state of chymotrypsin inhibitor 2 with all-atom simulations | Q33949034 | ||
Protein folding intermediates and pathways studied by hydrogen exchange | Q34001354 | ||
Gating of the active site of triose phosphate isomerase: Brownian dynamics simulations of flexible peptide loops in the enzyme | Q34091949 | ||
Protein folding theory: from lattice to all-atom models | Q34243263 | ||
Different subdomains are most protected from hydrogen exchange in the molten globule and native states of human alpha-lactalbumin | Q34288348 | ||
Take home lessons from studies of related proteins | Q34319454 | ||
Contact order, transition state placement and the refolding rates of single domain proteins. | Q34464266 | ||
Relating protein motion to catalysis | Q34535170 | ||
Identification of the minimal protein-folding nucleus through loop-entropy perturbations | Q34572934 | ||
Malleability of folding intermediates in the homeodomain superfamily | Q34805030 | ||
Contribution to the prediction of the fold code: application to immunoglobulin and flavodoxin cases | Q35615111 | ||
Multiscale Simulations Give Insight into the Hydrogen In and Out Pathways of [NiFe]-Hydrogenases from Aquifex aeolicus and Desulfovibrio fructosovorans | Q61836303 | ||
Frontier Residues Lining Globin Internal Cavities Present Specific Mechanical Properties | Q61836352 | ||
Locating the active sites of enzymes using mechanical properties | Q61836416 | ||
Acid and thermal denaturation of barnase investigated by molecular dynamics simulations | Q71751634 | ||
Universality and diversity of the protein folding scenarios: a comprehensive analysis with the aid of a lattice model | Q73174194 | ||
The folding of an immunoglobulin-like Greek key protein is defined by a common-core nucleus and regions constrained by topology | Q73514556 | ||
Protein folding and protein evolution: common folding nucleus in different subfamilies of c-type cytochromes? | Q74587897 | ||
Folding nucleus: specific or multiple? Insights from lattice models and experiments | Q77796149 | ||
Predicting the protein folding nucleus from sequences [correction of a sequence] | Q77936321 | ||
Native contact density and nonnative hydrophobic effects in the folding of bacterial immunity proteins | Q35643122 | ||
Theory of protein folding | Q35753216 | ||
Coarse-grained models for proteins | Q36101080 | ||
Identification of kinetically hot residues in proteins | Q36280778 | ||
Thermal fluctuations of haemoglobin from different species: adaptation to temperature via conformational dynamics | Q36344005 | ||
Stepwise protein folding at near amino acid resolution by hydrogen exchange and mass spectrometry | Q36835434 | ||
Protein mechanics: a route from structure to function | Q36959715 | ||
Predicting protein folding cores by empirical potential functions | Q37193804 | ||
Comparing a simple theoretical model for protein folding with all-atom molecular dynamics simulations | Q37276465 | ||
Native contacts determine protein folding mechanisms in atomistic simulations | Q37276492 | ||
What lessons can be learned from studying the folding of homologous proteins? | Q37767065 | ||
The folding of single domain proteins--have we reached a consensus? | Q37818728 | ||
The role of key residues in structure, function, and stability of cytochrome-c. | Q38101468 | ||
Folding the proteome | Q38114257 | ||
Universally conserved positions in protein folds: reading evolutionary signals about stability, folding kinetics and function | Q38321925 | ||
Non‐native interactions play an effective role in protein folding dynamics | Q41295041 | ||
Confirmation of the hierarchical folding of RNase H: a protein engineering study | Q41687636 | ||
Conservation of folding pathways in evolutionarily distant globin sequences | Q41753216 | ||
Investigating the local flexibility of functional residues in hemoproteins. | Q41927059 | ||
Protein-protein docking with a reduced protein model accounting for side-chain flexibility | Q42102959 | ||
Exploring the cytochrome c folding mechanism: cytochrome c552 from thermus thermophilus folds through an on-pathway intermediate | Q42169209 | ||
Protein folding: adding a nucleus to guide helix docking reduces landscape roughness | Q42428500 | ||
Plasticity within the obligatory folding nucleus of an immunoglobulin-like domain | Q43110554 | ||
Conformational plasticity in folding of the split beta-alpha-beta protein S6: evidence for burst-phase disruption of the native state | Q43960332 | ||
Prediction of the protein folding core: application to the immunoglobulin fold | Q44001033 | ||
Why and how does native topology dictate the folding speed of a protein? | Q44729167 | ||
Structural and dynamic characterization of partially folded states of apomyoglobin and implications for protein folding | Q46559043 | ||
Detection of rare partially folded molecules in equilibrium with the native conformation of RNaseH. | Q46840681 | ||
A specific hydrophobic core in the alpha-lactalbumin molten globule | Q47885497 | ||
Mapping the stability clusters in bovine pancreatic ribonuclease A. | Q47992522 | ||
Evolutionary conservation of the folding nucleus. | Q52064717 | ||
A strategy for detecting the conservation of folding-nucleus residues in protein superfamilies. | Q52237589 | ||
Specific nucleus as the transition state for protein folding: evidence from the lattice model. | Q52372545 | ||
Complete change of the protein folding transition state upon circular permutation. | Q52944479 | ||
Identifying the protein folding nucleus using molecular dynamics. | Q54276099 | ||
Evidence for the sequential folding mechanism in RNase H from an ensemble-based model. | Q54290440 | ||
Analyses of the folding properties of ferredoxin-like fold proteins by means of a coarse-grained Gō model: relationship between the free energy profiles and folding cores. | Q54627051 | ||
The Structure of the Transition State for Folding of Chymotrypsin Inhibitor 2 Analysed by Protein Engineering Methods: Evidence for a Nucleation-condensation Mechanism for Protein Folding | Q57823358 | ||
Structure of the transition state in the folding process of human procarboxypeptidase A2 activation domain | Q57957112 | ||
Outlining Folding Nuclei in Globular Proteins | Q58037857 | ||
Detection and characterization of a folding intermediate in barnase by NMR | Q59009991 | ||
Conserved residues and the mechanism of protein folding | Q59073215 | ||
P433 | issue | 112 | |
P921 | main subject | protein folding | Q847556 |
P577 | publication date | 2015-11-01 | |
P1433 | published in | Journal of the Royal Society Interface | Q2492390 |
P1476 | title | Fold and flexibility: what can proteins' mechanical properties tell us about their folding nucleus? | |
P478 | volume | 12 |
Q93142062 | Interconnecting Flexibility, Structural Communication, and Function in RhoGEF Oncoproteins | cites work | P2860 |
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