Anti-alcoholism drug disulfiram for targeting glioma energy metabolism using BBB-penetrating delivery of fixed-dose combination

The interconnection between tumor metabolism and the immune microenvironment governs the progression of glioma. It was revealed that the metabolic enzymes ALDH1L1 and PKM2 were overexpressed in glioma. We discovered that the anti-alcoholism drug disulfiram (DSF) can intervene in the tumor energy metabolism by inhibiting ATP supply via an alternative pathway, of which ALDH1L1 is an essential enzyme in the 10-formyl-tetrahydrofolate-NADH-ATP metabolism axis. We thus proposed a dual-inhibition strategy by using a combination therapy of a PKM2 inhibitor shikonin (SHK) and an ALDH1L1 inhibitor DSF. By simultaneously inhibiting glycolysis and NADH-ATP metabolism, the ATP generation in the tumor cells can be efficiently cut down. A BBB-penetrating hybrid albumin/lactoferrin nanosystem (termed BSA/LF NP) was developed for biomimetic codelivery of DSF/SHK for anti-glioma therapy. Due to the overexpression of SPARC and LRP-1 in both the BBB and glioma cells, the BSA/LF NP could efficiently enter the glioma. More importantly, it can deliver a fixed-dose ratio of DSF and SHK to the glioma, providing a basis for synergistic effect in combination therapy. The BSA/LF NP effectively prolonged the survival of glioma mice by interactive modulation of energy metabolism (via both glycolysis and NADH-ATP pathways) and immune microenvironment. The work provided a promising glioma-targeting strategy for a fixed-dose combination and a potent ATP-depletion treatment.0 2022 Published by Elsevier Ltd.

Automated summary

The interplay between tumor metabolism and the immune microenvironment plays a crucial role in glioma progression. In this study, the researchers discovered that the drugs disulfiram (DSF) and shikonin (SHK) can inhibit the ATP supply pathway and glycolysis in glioma cells, leading to a reduction in ATP generation. By developing a nanoparticle system, they were able to efficiently deliver a fixed-dose combination of DSF and SHK to the glioma cells, resulting in prolonged survival in glioma mice by modulating energy metabolism and the immune microenvironment.