Universal protein misfolding intermediates can bypass the proteostasis network and remain soluble and less functional

Nissley, Daniel A.; Jiang, Yang; Trovato, Fabio; Sitarik, Ian; Narayan, Karthik; To, Philip; Xia, Yingzi; Fried, Stephen D.; O’Brien, Edward P.

doi:10.1038/s41467-022-30548-5

Cited by 35 publications

(71 citation statements)

References 76 publications

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“…A common assumption made in biological experiments is that soluble protein is typically well-folded and active. However, several studies have pointed out that this is an oversimplification (Danielsson et al, 2015; Ebbinghaus et al, 2010; Nissley et al, 2022; Waztor et al, 2020), as appears to be the case for TagRFP675 when not enough chaperone capacity is available to aid its folding.…”

Section: Discussionmentioning

confidence: 99%

G-quadruplexes rescuing protein folding

Son

Cabral

Litberg

et al. 2022

Preprint

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Maintaining the health of the proteome is a critical cellular task. Recently, we found G-quadruplex (G4) nucleic acids are especially potent at preventing protein aggregation in vitro and could at least indirectly improve the protein folding environment of E. coli. However, the roles of G4s in protein folding were not yet explored. Here, through in vitro protein folding experiments, we discover that G4s can accelerate protein folding by rescuing kinetically trapped intermediates to both native and near-native folded states. Time-course folding experiments in E. coli further demonstrate that these G4s primarily improve protein folding quality in E. coli as opposed to preventing protein aggregation. The ability for a short nucleic acid to rescue protein folding opens up the possibility of nucleic acids and ATP-independent chaperones to play considerable roles in dictating the ultimate folding fate of proteins.

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Section: Discussionmentioning

confidence: 99%

G-quadruplexes rescuing protein folding

Son

Cabral

Litberg

et al. 2022

Preprint

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“…This possible mechanism would involve kinetic trapping in a stable structure ( 34 ). Using molecular dynamics simulations, it was proposed that, if unfolded, then half of the cytosolic Escherichia coli proteins could exhibit subpopulations of misfolded conformations, which would be kinetically trapped, but without propensity to aggregate ( 35 ). These conformations are rarely encountered in vivo for freshly expressed proteins, where the cotranslational folding restricts the folding kinetics ( 36 ).…”

Section: Discussionmentioning

confidence: 99%

Mechanical regulation of talin through binding and history-dependent unfolding

et al. 2022

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Talin is a force-sensing multidomain protein and a major player in cellular mechanotransduction. Here, we use single-molecule magnetic tweezers to investigate the mechanical response of the R8 rod domain of talin. We find that under various force cycles, the R8 domain of talin can display a memory-dependent behavior: At the same low force (<10 pN), the same protein molecule shows vastly different unfolding kinetics. This history-dependent behavior indicates the evolution of a unique force-induced native state. We measure through mechanical unfolding that talin R8 domain binds one of its ligands, DLC1, with much higher affinity than previously reported. This strong interaction can explain the antitumor response of DLC1 by regulating inside-out activation of integrins. Together, our results paint a complex picture for the mechanical unfolding of talin in the physiological range and a new mechanism of function of DLC1 to regulate inside-out activation of integrins.

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“…Only a small number of mechanisms intrinsic to a protein's primary structure are known to cause monomeric protein misfolding (Table 1). Recently, high-throughput, coarse-grained simulations of protein synthesis and folding of the E. coli proteome have suggested there exists an additional widespread mechanism of misfolding [1][2][3] . Proteins can populate off-pathway misfolded states that involve a change in entanglement 1 .…”

Section: Introductionmentioning

confidence: 99%

“…The misfolded states observed in the aforementioned simulations involved either the gain of a non-native entanglement (i.e., the formation of an entanglement that is not present in the native ensemble, Table S1) or the loss of a native entanglement (i.e., an entanglement present in the native state fails to form, Table S1) [1][2][3] . This newly predicted class of misfolding offers an explanation for the decades old observations that non-functional protein molecules can persist for long-time scales in the presence of chaperones and not rapidly aggregate nor be degraded [7][8][9] .…”

Section: Introductionmentioning

confidence: 99%

“…Several mechanisms intrinsic to a protein's primary structure are known to cause monomeric protein misfolding (Table 1). Recently, high-throughput, coarse-grained simulations of protein synthesis and folding of the E. coli proteome have suggested there exists an additional widespread mechanism of misfolding [1][2][3] : proteins can populate off-pathway misfolded states that involve a change in non-covalent lasso entanglements 1,2 . This type of entanglement is defined by the presence of two structural components: a loop formed by a protein backbone segment closed by a non-covalent native contact, and another protein segment that is threaded through and around this loop [4][5][6] in some cases multiple times (Figs.…”

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confidence: 99%

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A Newly Identified Class of Protein Misfolding in All-atom Folding Simulations Consistent with Limited Proteolysis Mass Spectrometry

Sitarik

Jiang

et al. 2022

Preprint

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A small number of mechanisms intrinsic to a protein’s primary structure are known to cause monomeric protein misfolding. Coarse-grained simulations predict a new mechanism of misfolding exists involving off-pathway, non-covalent lasso entanglements, which are separate and distinct from protein knots. These misfolded states can be long-lived kinetic traps, and in some cases are structurally similar to the native state according to the coarse-grained simulations. Here, we examine whether such misfolded states occur in long-time-scale, physics-based all-atom simulations of protein folding. We find they do indeed form, estimate they can persist for weeks, and some have characteristics similar to the native state. These results indicate monomeric proteins can exhibit subpopulations of misfolded, self-entangled states that can explain long-time-scale changes in protein structure and function in vivo.One-Sentence SummaryEntangled misfolded states form in physics-based all-atom simulations of protein folding and have characteristics similar to the native state.

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Universal protein misfolding intermediates can bypass the proteostasis network and remain soluble and less functional

Cited by 35 publications

References 76 publications

G-quadruplexes rescuing protein folding

G-quadruplexes rescuing protein folding

Mechanical regulation of talin through binding and history-dependent unfolding

A Newly Identified Class of Protein Misfolding in All-atom Folding Simulations Consistent with Limited Proteolysis Mass Spectrometry

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