The
development of bifunction al molecules, which can
enable targeted
RNA degradation, targeted protein acetylation, or targeted protein
degradation, remains a time-consuming process that requires tedious
optimization. We propose a split-and-mix nanoplatform that serves
as a self-adjustable platform capable of facile screening, programmable
ligand ratios, self-optimized biomolecule spatial recognition, and
multifunctional applications. Herein, we demonstrate the potential
of our proposed nanoplatform by showcasing proteolysis-targeting chimeras
(PROTACs), namely, split-and-mix PROTAC (SM-PROTAC). We highlight
the scope of our platform through the targeted disruption of intracellular
therapeutic targets involving ERα, CDK4/6, AR, MEK1/2, BRD2/4,
BCR-ABL, etc. These studies confirm the effectiveness and universality
of the SM-PROTAC platform for proximity-induced applications. This
platform is programmable, with significant potential applications
to biomolecule regulation, including the fields of epigenetics, gene
editing, and biomolecule modification regulation.
Blocking
the interaction of MTDH/SND1 complex is an attractive
strategy for cancer therapeutics. In this work, we designed and obtained
a novel class of potent stabilized peptide inhibitors derived from
MTDH sequence to disrupt MTDH/SND1 interaction. Through structure-based
optimization and biological evaluation, stabilized peptides were obtained
with tight binding affinity, improved cell penetration, and antitumor
effects in the triple-negative breast cancer (TNBC) cells without
nonspecific toxicity. To date, our study was the first report to demonstrate
that stabilized peptides truncated from MTDH could serve as promising
candidates to disrupt the MTDH/SND1 interaction for potential breast
cancer treatment.
The ligand-directed (LD) chemistry provides powerful tools for site-specific modification of proteins. We utilized a peptide with an appended methionine (Met) as a ligand; then, the Met thioether was modified into sulfonium which enabled a proximity induced group transfer onto protein cysteine in the vicinity upon peptide−target binding. The sulfonium warhead could be easily constructed with unprotected peptides, and the transferable group scope was conducted on model protein PDZ and its ligand peptides. In addition, a living cell labeling was successfully achieved.
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