posted on 2021-03-24, 15:00authored byChangjoon Keum, Jiyoung Hong, Doyeon Kim, Sang-Yup Lee, Hyuncheol Kim
Multidrug
resistance (MDR) of cancer cells reduces chemotherapeutic
efficacy by preventing drug accumulation in the cells through a drug
efflux pump and lysosomal sequestration/exocytosis. Herein, to overcome
such anticancer resistance, lysosome-targeted self-assembly of perylene
diimide (PDI) derivatives is presented as a powerful strategy for
effective and selective anticancer therapy. Stimulated by the lysosomal
low pH, the amphiphilic PDI derivatives functionalized with amino
acids (PDI-AAs) construct fibrous self-assembled structures inside
the lysosomes, causing cancer cell apoptosis by lysosomal rupture.
In contrast, negligible apoptosis was observed from normal cells by
PDI-AA. The agglomerated fibrous assemblies were not removed by lysosomal
exocytosis, thereby displaying a 10.7-fold higher anticancer efficacy
on MDR cancer cells compared to a doxorubicin chemotherapeutic agent.
The MDR-circumventing capability, along with high selectivity toward
cancer cells, supports PDI-AAs as potential candidates for the treatment
of MDR cancer cells by lysosome-targeted self-assembly.