posted on 2021-09-08, 11:37authored byXiaohan Liu, Yanhua Li, Kaiye Wang, Yuanyuan Chen, Mingwan Shi, Xia Zhang, Wei Pan, Na Li, Bo Tang
Blocking
energy metabolism of cancer cells and simultaneously stimulating
the immune system to perform immune attack are significant for cancer
treatment. However, how to potently deliver different drugs with these
functions remains a challenge. Herein, we synthesized a nanoprodrug
formed by a F127-coated drug dimer to inhibit glycolysis of cancer
cells and alleviate the immunosuppressive microenvironment. The dimer
was delicately constructed to connect lonidamine (LND) and NLG919
by a disulfide bond which can be cleaved by excess GSH to release
two drugs. LND can decrease the expression of hexokinase II and destroy
mitochondria to restrain glycolysis for energy supply. NLG919 can
reduce the accumulation of kynurenine and the number of regulatory
T cells, thus alleviating the immunosuppressive microenvironment.
Notably, the consumption of GSH by disulfide bond increased the intracellular
oxidative stress and triggered immunogenic cell death of cancer cells.
This strategy can offer more possibilities to explore dimeric prodrugs
for synergistic cancer therapy.