Propensity to form amyloid fibrils is encoded as excitations in the free energy landscape of monomeric proteins

TL;DR

This study reveals that the propensity for proteins to form amyloid fibrils is encoded in the native fluctuations of monomers, with mechanical force and environmental factors influencing the population of aggregation-prone states, which can be linked to fibril formation.

Contribution

The paper demonstrates how native protein fluctuations encode amyloid-prone states and introduces a quantitative framework relating these states to fibril formation tendencies.

Findings

Mechanical force increases aggregation-prone state populations.

Native fluctuation spectrum encodes amyloid propensity.

Fibril formation time scale correlates with $N^*$ state population.

Abstract

Protein aggregation, linked to many of diseases, is initiated when monomers access rogue conformations that are poised to form amyloid fibrils. We show, using simulations of src SH3 domain, that mechanical force enhances the population of the aggregation prone ($N^*$) states, which are rarely populated under force free native conditions, but are encoded in the spectrum of native fluctuations. The folding phase diagrams of SH3 as a function of denaturant concentration ($[C]$), mechanical force ($f$), and temperature exhibit an apparent two-state behavior, without revealing the presence of the elusive $N^*$ states. Interestingly, the phase boundaries separating the folded and unfolded states at all [C] and $f$ fall on a master curve, which can can be quantitatively described using an analogy to superconductors in a magnetic field. The free energy profiles as a function of the molecular extension ($R$), which are accessible in pulling experiments, ($R$), reveal the presence of a native-like $N^*$ with a disordered solvent-exposed amino terminal $\beta$-strand. The structure of the $N^*$ state is identical to that found in Fyn SH3 by NMR dispersion experiments. We show that the time scale for fibril formation can be estimated from the population of the $N^*$ state, determined by the free energy gap separating the native structure and the $N^*$ state, a finding that can be used to assess fibril forming tendencies of proteins. The structures of the $N^*$ state are used to show that oligomer formation and likely route to fibrils occur by a domain-swap mechanism in SH3 domain.