Slowest-first protein translation scheme: Structural asymmetry and co-translational folding

McBride, J. Michael; Tlusty, Tsvi

doi:10.1016/j.bpj.2021.11.024

Cited by 6 publications

(3 citation statements)

References 134 publications

(204 reference statements)

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“…Given the marginal stability of most proteins, mutations may easily destabilize a protein so that its melting temperature falls below room temperature. The process of protein folding is carefully tuned in vivo for folding on the ribosome, and through interactions with chaperones, and mutations that do not change structure may retard folding through other mechanisms [44]. To see whether pLDDT is predictive of whether a protein will fold or not, we studied a set of 147 WW-domain-like sequences, of which 40 were found to fold in vitro .…”

Section: Discussionmentioning

confidence: 99%

AlphaFold2 can predict single-mutation effects

McBride

Polev

Reinharz

et al. 2022

Preprint

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AlphaFold2 (AF2) is a promising tool for structural biology, but is it sufficiently accurate to predict the effect of missense mutations? We find that structural variation between closely related 1-3 mutations) protein pairs is correlated across experimental and AF2-predicted structures ~90,000 pairs. Analysis of ~10,000 predicted structures from three high-throughput studies linking sequence and phenotype (fluorescence, foldability, and catalysis) demonstrates that AF2 can predict the phenotypic effect of missense mutations.

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Section: Discussionmentioning

confidence: 99%

AlphaFold2 can predict single-mutation effects

McBride

Polev

Reinharz

et al. 2022

Preprint

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“…81,[84][85][86][87] For example, CPs have recently demonstrated the importance of co-translational folding, protein evolution, and asymmetry in secondary structure placement. 9 These studies reiterate the importance of studying the effects of CP on protein stability, folding, and function.…”

Section: Discussionmentioning

confidence: 99%

Metal‐binding and circular permutation‐dependent thermodynamic and kinetic stability of azurin

et al. 2022

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Native topology is known to determine the folding kinetics and the energy landscape of proteins. Furthermore, the circular permutation (CP) of proteins alters the order of the secondary structure connectivity while retaining the three-dimensional structure, making it an elegant and powerful approach to altering native topology. Previous studies elucidated the influence of CP in proteins with different folds such as Greek key β-barrel, β-sandwich, β-α-β, and all α-Greek key. CP mainly affects the protein stability and unfolding kinetics, while folding kinetics remains mostly unaltered. However, the effect of CP on metalloproteins is yet to be elaborately studied. The active site of metalloproteins poses an additional complexity in studying protein folding.Here, we investigate a CP variant (cpN42) of azurin-in both metal-free and metalbound (holo) forms. As observed earlier in other proteins, apo-forms of wild-type (WT) and cpN42 fold with similar rates. In contrast, zinc-binding accelerates the folding of WT but decelerates the folding of cpN42. On zinc-binding, the spontaneous folding rate of WT increases by >250 times that of cpN42, which is unprecedented and the highest for any CP to date. On the other hand, zinc-binding reduces the spontaneous unfolding rate of cpN42 by $100 times, making the WT and CP azurins unfold at similar rates. Our study demonstrates metal binding as a novel way to modulate the unfolding and folding rates of CPs compared to their WT counterparts. We hope our study increases the understanding of the effect of CP on the folding mechanism and energy landscape of metalloproteins.

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“…The original sample of proteins had 16,200 in total, which were selected from a nonredundant set of proteins available in the PDB, corresponding exactly to natural sequences without signal peptides. [67] However, only 14,963 made it through the pipeline due to the inability of PDB2PQR to handle structures with too many disordered residues and the lack of hydrophobicity information for non-canonical and modified amino acids. Functional annotations are obtained by matching Gene Ontology terms via UniProt, using the Python package GOATOOLS.…”

Section: Protein Surface Analysismentioning

confidence: 99%

Statistical Survey of Chemical and Geometric Patterns on Protein Surfaces as a Blueprint for Protein-mimicking Nanoparticles

McBride,

Koshevarnikov,

Siek

et al. 2024

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Despite recent breakthroughs in understanding how protein sequence relates to structure and function, considerably less attention has been paid to the general features of protein surfaces beyond those regions involved in binding and catalysis. This paper provides a systematic survey of the universe of protein surfaces and quantifies the sizes, shapes, and curvatures of the positively/negatively charged and hydrophobic/hydrophilic surface patches as well as correlations between such patches. It then compares these statistics with the metrics characterizing nanoparticles functionalized with ligands terminated with positively and negatively charged ligands. These particles are of particular interest because they are also surface-patchy and have been shown to exhibit both antibiotic and anticancer activities – via selective interactions against various cellular structures – prompting loose analogies to proteins. Our analyses support such analogies in several respects (e.g., patterns of charged protrusions and hydrophobic niches similar to those observed in proteins), although there are also significant differences. Looking forward, this work provides a blueprint for the rational design of synthetic nanoobjects with further enhanced mimicry of proteins’ surface properties.

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Slowest-first protein translation scheme: Structural asymmetry and co-translational folding

Cited by 6 publications

References 134 publications

AlphaFold2 can predict single-mutation effects

AlphaFold2 can predict single-mutation effects

Metal‐binding and circular permutation‐dependent thermodynamic and kinetic stability of azurin

Statistical Survey of Chemical and Geometric Patterns on Protein Surfaces as a Blueprint for Protein-mimicking Nanoparticles

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