Simultaneously Delivery of Functional Gallium Ions and Hydrogen Sulfide to Endow Potentiated Treatment Efficacy in Chemo- and PARPi-resistant Ovarian Cancer

Overview

Journal J Nanobiotechnology

Publisher Biomed Central

Date 2025 Feb 1

PMID 39893477

Authors

Sangsang Tang

Yangyang Li

Yifeng Fang

Mengyan Tu

Shenglong Wu

Yixuan Cen

Junfen Xu

Affiliations

Soon will be listed here.

Abstract

Limited therapeutic options are available for patients with platinum-resistant ovarian cancer (OC). Herein, we developed gallium sulfide-embedded bovine serum albumin nanoformulations (GaS-BSA NMs) with a size of ~ 11 nm via a self-assembly approach. As the nanoformulations degraded in an acidic cancer microenvironment, Ga and HS gas were simultaneously released to exert their combined anticancer effects. In A2780-CIS and SKOV3-CIS platinum-resistant OC cells, Ga and HS released from GaS-BSA NMs synergistically enhanced DNA damage, which arrested the cell cycle at S and G2/M phases and suppressed cell proliferation. Meanwhile, GaS-BSA NMs significantly inhibited NF-κB signaling and Bcl2 protein expression, leading to cell apoptosis. Furthermore, GaS-BSA NMs increased cellular lipid peroxidation and triggered ferroptosis. RNA-seq analysis further clarified the comprehensive antitumor mechanisms of GaS-BSA NMs. More importantly, the therapeutic efficacy of GaS-BSA NMs and their ability to enhance the sensitivity to carboplatin and fluzoparib with negligible toxicity were further confirmed in a platinum-resistant OC animal model. Altogether, our results demonstrated a potentially safe and practical strategy by using GaS-BSA NMs to combat drug resistance in platinum-resistant OC.

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