2009
DOI: 10.1073/pnas.0811147106
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Dodging the crisis of folding proteins with knots

Abstract: Proteins with nontrivial topology, containing knots and slipknots, have the ability to fold to their native states without any additional external forces invoked. A mechanism is suggested for folding of these proteins, such as YibK and YbeA, that involves an intermediate configuration with a slipknot. It elucidates the role of topological barriers and backtracking during the folding event. It also illustrates that native contacts are sufficient to guarantee folding in Ϸ1-2% of the simulations, and how slipknot… Show more

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Cited by 168 publications
(236 citation statements)
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“…Most of the nonspecific knotted configurations were of types i and iii; however, one iv case was also found. This is consistent with theoretical evidence that folding nucleation by nonspecific knots is entropically unlikely in proteins (11,13). This process should have a barrier with a large entropic contribution because there is little energetic stabilization until the native environment forms around the knot.…”
Section: Resultssupporting
confidence: 78%
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“…Most of the nonspecific knotted configurations were of types i and iii; however, one iv case was also found. This is consistent with theoretical evidence that folding nucleation by nonspecific knots is entropically unlikely in proteins (11,13). This process should have a barrier with a large entropic contribution because there is little energetic stabilization until the native environment forms around the knot.…”
Section: Resultssupporting
confidence: 78%
“…1). We characterize the knot position by monitoring its depth (11), distance along the sequence K N , K C to the knot, respectively, from the N terminal and C terminal. In the case of a slipknot we additionally monitor depth of a slipknot loop (12), which is located between K N and K C .…”
Section: Resultsmentioning
confidence: 99%
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“…In general, knots in proteins are orders of magnitude less frequent than would be expected for random polymers with similar length, compactness, and flexibility (3). In principle, the polypeptide chains folding into knotted native protein structures encounter more kinetic difficulties than unknotted proteins (4)(5)(6)(7)(8)(9)(10)(11)(12). Therefore, it is believed that knotted protein structures were, in part, eliminated during evolution because proteins that fold slowly and/or nonreproducibly should be evolutionarily disadvantageous for the hosting organisms.…”
mentioning
confidence: 99%