posted on 2021-09-13, 19:10authored byJunli Wang, Yifei Guo, Xin Geng, Jingyu Hu, Minmin Yan, Yuanqiang Sun, Ke Zhang, Lingbo Qu, Zhaohui Li
Lipid
droplets (LDs) play indispensable roles in numerous physiological
processes; hence, the visualization of the dynamic behavior of LDs
in living cells is of great importance in physiological and pathological
research. In this article, the quantitative structure–activity
relationship (QSAR) theory was employed as an effective design strategy
for the development of organelle-targeting carbon dots (CDs). The
lipid–water partition coefficient (Log P)
of the QSAR was adopted as a key parameter to predict the cellular
uptake and subcellular localization of CDs in live cells. By carefully
adjusting the molecular structure and lipophilicity of the precursors, p-phenylenediamine-derivatized nucleolus-targeting hydrophilic
CDs were converted to lipophilic CDs [4-piperidinoaniline (PA) CDs]
with inherent LD-targeting performance. The PA CDs were able to indicate
the dynamic behavior of LDs and visualize the changes of bisphenol
A-induced nonalcoholic fatty liver disease-like changes in a cellular
model. The QSAR strategy of CDs demonstrated here is expected to be
increasingly exploited as a powerful design tool for developing various
organelle-targeting CDs.