Probing the dissociation pathway of a kinetically labile transthyretin mutant

Abstract

AbstractAggregation of transthyretin (TTR) is associated with devastating TTR amyloid disease. Amyloidosis begins with dissociation of the native tetramer to form a monomeric intermediate that assembles into pathogenic aggregates. This process is accelerated in vitro at low pH, but the dissociation and reassembly of TTR at neutral pH remains poorly understood, due to the low population of intermediates. We use NMR studies with a highly sensitive19F probe that allows deconvolution of relative populations of a destabilized A25T mutant at concentrations as low as 2 µM. The A25T mutation, located at the weak dimer interface, perturbs both the weak and strong dimer interfaces. A tetramer-dimer-monomer (TDM) equilibrium model is proposed to account for concentration- and temperature-dependent population changes. All thermodynamic and kinetic parameters and activation energetics for dissociation of the native A25T tetramer, as well as a destabilized alternative tetramer (T*) with a mispacked F87 side chain, were extracted by van’t Hoff and19F NMR line-shape analysis. The conversion from T to T*, the slowest first-order kinetic step, shows anti-Arrhenius behavior. The19F and methyl chemical shifts of probes close to the strong dimer interface in the dimer and T* species are degenerate, implicating interfacial perturbation as a common structural feature of these intermediate species. Molecular dynamics (MD) simulations further suggest more frequent F87 ring flipping on the nanoscale timescale in the A25T dimer than in the tetramer. Our integrated approach offers quantitative insights into the energy landscape of the dissociation pathway of TTR at neutral pH.