Molecular
Mechanism Underlying the Action of a Celastrol-Loaded
Layered Double Hydroxide-Coated Magnesium Alloy in Osteosarcoma Inhibition
and Bone Regeneration
Osteosarcoma (OS) is a malignant bone tumor that threatens
human
health. Surgical removal of the tumor and followed by implantation
with a graft is the golden standard for its clinical treatment. However,
avoiding recurrence by enhancing the antitumor properties of the implants
and improving osteogenesis around the implants remain a challenge.
Here, we developed a layered double hydroxide (LDH)-coated magnesium
(Mg) alloy and loaded it with celastrol. The celastrol-loaded Mg alloy
exhibited enhanced corrosion resistance and sustained release of celastrol. In vitro cell culture suggested that the modified Mg alloy
loaded with an appropriate amount of celastrol significantly inhibited
the proliferation and migration of bone tumor cells while having little
influence on normal cells. A mechanistic study revealed that the celastrol-loaded
Mg alloy upregulated reactive oxygen species (ROS) generation in bone
tumor cells, resulting in mitochondrial dysfunction due to reduced
membrane potential, thereby inducing bone tumor cell apoptosis. Furthermore,
it was found that celastrol-induced autophagy in tumor cells inhibited
cell apoptosis in the initial 6 h. After ≥12 h of culture,
inhibition of the PI3K-Akt-mTOR signaling pathway was noted, resulting
in excessive autophagy in tumor cells, finally causing cell apoptosis.
The celatsrol-loaded Mg alloy also exhibited effective antitumor properties
in a subcutaneous tumor model. In vitro tartrate-resistant
acid phosphatase (TRAP) staining and gene expression results revealed
that the modified Mg alloy reduced the viability of osteoclasts, inducing
a potential pathway for the increased bone regeneration around the
modified Mg alloy seen in vivo. Together, the results
of our study show that the celatsrol-loaded Mg alloy might be a promising
implant for treating OS.