Several
point mutations can modulate protein structure and dynamics,
leading to different natures. Especially in the case of amyloidogenic
proteins closely related to neurodegenerative diseases, structural
changes originating from point mutations can affect fibrillation kinetics.
Herein, we rationally designed mutant candidates to inhibit the fibrillation
process of amyloid-β with its point mutants through multistep in silico analyses. Our results showed that the designed
mutants induced kinetic self-assembly suppression and reduced the
toxicity of the aggregate. A multidisciplinary biophysical approach
with small-angle X-ray scattering, ion mobility-mass spectrometry,
mass spectrometry, and additional in silico experiments
was performed to reveal the structural basis associated with the inhibition
of fibril formation. The structure-based design of the mutants with
suppressed self-assembly performed in this study could provide a different
perspective for modulating amyloid aggregation based on the structural
understanding of the intrinsically disordered proteins.
TEMPO ((2,2,6,6-tetramethylpiperidine-1-yl)oxyl)-assisted
free-radical-initiated
peptide sequencing mass spectrometry (FRIPS MS) is applied to the
top-down tandem mass spectrometry of guanidinated ubiquitin (UB(Gu))
ions, i.e., p-TEMPO–Bn–Sc–guanidinated
ubiquitin (UBT(Gu)), to shed a light on gas-phase ubiquitin conformations.
Thermal activation of UBT(Gu) ions produced protein backbone fragments
of radical character, i.e., a-/x- and c-/z-type fragments. It is
in contrast to the collision-induced dissociation (CID) results for
UB(Gu), which dominantly showed the specific charge-remote CID fragments
of b-/y-type at the C-terminal side
of glutamic acid (E) and aspartic acid (D). The transfer of a radical
“through space” was mainly observed for the +5 and +6
UBT(Gu) ions. This provides the information about folding/unfolding
and structural proximity between the positions of the incipient benzyl
radical site and fragmented sites. The analysis of FRIPS MS results
for the +5 charge state ubiquitin ions shows that the +5 charge state
ubiquitin ions bear a conformational resemblance to the native ubiquitin
(X-ray crystallography structure), particularly in the central sequence
region, whereas some deviations were observed in the unstable second
structure region (β2) close to the N-terminus. The
ion mobility spectrometry results also corroborate the FRIPS MS results
in terms of their conformations (or structures). The experimental
results obtained in this study clearly demonstrate a potential of
the TEMPO-assisted FRIPS MS as one of the methods for the elucidation
of the overall gas-phase protein structures.
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