Conspectus
Protein
aggregation is a biological phenomenon in which aberrantly
processed or mutant proteins misfold and assemble into a variety of
insoluble aggregates. Decades of studies have delineated the structure,
interaction, and activity of proteins in either their natively folded
structures or insoluble aggregates such as amyloid fibrils. However,
a variety of intermediate species exist between these two extreme
states in the protein folding landscape. Herein, we collectively term
these intermediate species as misfolded protein oligomers, including
soluble oligomers and preamyloid oligomers that are formed by unfolded
or misfolded proteins. While extensive tools have been developed to
study folded proteins or amyloid fibrils, research to understand the
properties and activities of misfolded protein oligomers has been
limited by the lack of methods to detect and interrogate these species
in live cells.
In this Account, we describe our efforts in the
development of
chemical methods that allow for the characterization of the multistep
protein aggregation process, in particular the misfolded protein oligomers,
in living cells. As the start of this journey, we attempted to develop
a fluorogenic method wherein the misfolded oligomers could turn on
the fluorescence of chemical probes that are conjugated to the protein-of-interest
(POI). To this end, we produced a series of destabilized HaloTag variants,
formulating the primary component of the AgHalo sensor, which misfolds
and aggregates when cells are subjected to stress. When AgHalo is
covalently conjugated with a solvatochromic fluorophore, misfolding
of the AgHalo conjugate would activate fluorescence, resulting in
the observation of misfolded oligomers. Following this work, we extended
the scope of detection from AgHalo to any protein-of-interest via
the AggTag method, wherein the POIs are genetically fused to self-labeling
protein tags (HaloTag or SNAP-tag). Focusing on the molecular rotor-based
fluorophores, we applied the modulated fluorescent protein (FP) chromophore
core as a prototype for the AggTag probes, to enable the fluorogenic
detection of misfolded soluble oligomers of multiple proteins in live
cells. Next, we further developed the AggTag method to distinguish
insoluble aggregates from misfolded oligomers, using two classes of
probes that activate different fluorescence emission toward these
two conformations. To enable this goal, we applied physical organic
chemistry and computational chemistry to discover a new category of
triode-like fluorophores, wherein the π orbitals of either an
electron density regulator or the donor–acceptor linkages are
used to control the rotational
barriers of fluorophores in the excited states. This mechanism allows
us to rationally design molecular rotor-based fluorophores that have
desired responses to viscosity, thus extending the application of
the AggTag method.
In summary, our work allows the direct monitoring
of the misfolded
protein oligomers and differentiation of insoluble aggregates from
other conformatio...
