Litcius/Paper detail

Thermodynamic and Evolutionary Coupling between the Native and Amyloid State of Globular Proteins

Tobias Langenberg, Rodrigo Gallardo, Rob van der Kant, Nikolaos Louros, Emiel Michiels, Ramon Duran‐Romaña, Bert Houben, Rafaela Ferreira Cassio, Hannah Wilkinson, Teresa García, Chris Ulens, Joost Van Durme, Frédéric Rousseau, Joost Schymkowitz

2020Cell Reports53 citationsDOIOpen Access PDF

Abstract

The amyloid-like aggregation propensity present in most globular proteins is generally considered to be a secondary side effect resulting from the requirements of protein stability. Here, we demonstrate, however, that mutations in the globular and amyloid state are thermodynamically correlated rather than simply associated. In addition, we show that the standard genetic code couples this structural correlation into a tight evolutionary relationship. We illustrate the extent of this evolutionary entanglement of amyloid propensity and globular protein stability. Suppressing a 600-Ma-conserved amyloidogenic segment in the p53 core domain fold is structurally feasible but requires 7-bp substitutions to concomitantly introduce two aggregation-suppressing and three stabilizing amino acid mutations. We speculate that, rather than being a corollary of protein evolution, it is equally plausible that positive selection for amyloid structure could have been a driver for the emergence of globular protein structure.

Topics & Concepts

Globular clusterGlobular proteinAmyloid (mycology)Amyloid fibrilCoupling (piping)Native stateChemistryEvolutionary biologyBiophysicsComputational biologyBiologyBiochemistryComputer scienceAmyloid βMedicineMaterials scienceDiseaseInternal medicineStarsMetallurgyComputer visionInorganic chemistryProtein Structure and DynamicsEnzyme Structure and FunctionComputational Drug Discovery Methods