Insulin-degrading
enzyme (IDE) hydrolyzes monomeric polypeptides,
including amyloid-β (Aβ) and HIV-1 p6. It also acts as
a nonproteolytic chaperone to prevent Aβ polymerization. Here
we compare interactions of Aβ and non-amyloidogenic p6 with
IDE. Although both exhibited similar proteolysis rates, the binding
kinetics to an inactive IDE characterized using relaxation-based NMR
were remarkably different. IDE and Aβ formed a sparsely populated
complex with a lifetime of milliseconds in which a short hydrophobic
cleavage segment of Aβ was anchored to IDE. Strikingly, a second
and more stable complex was significantly populated with a subsecond
lifetime owing to multiple intermolecular contacts between Aβ
and IDE. By selectively sequestering Aβ in this nonproductive
complex, IDE likely increases the critical concentration required
for fibrillization. In contrast, IDE and p6 formed a transient, submillisecond
complex involving a single anchoring p6 motif. Modulation of intermolecular
interactions, thus, allows IDE to differentiate between non-amyloidogenic
and amyloidogenic substrates.
Monoubiquitination
of proteins governs diverse physiological processes,
and its dysregulation is implicated in multiple pathologies. The difficulty
of preparing sufficient material often complicates the biophysical
studies of monoubiquitinated recombinant proteins. Here we describe
a robust avidity-based method that overcomes this problem. As a proof-of-concept,
we produced milligram quantities of two monoubiquitinated targets,
Parkinson’s protein α-synuclein and ESCRT-protein ALIX,
using NEDD4-family E3 ligases. Monoubiquitination hotspots were identified
by quantitative chemical proteomics. Using FRAP and dye-binding assays,
we uncovered strikingly opposite effects of monoubiquitination on
the phase separation and fibrillization properties of these two amyloidogenic
proteins, reflecting differences in their intermolecular interactions,
thereby providing unique insights into the impact of monoubiquitination
on protein aggregation.
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