Cuproptosis mechanism in cancer!

As a copper-dependent regulated form of cell death, cuproptosis is critically important for developing targeted cancer therapies and overcoming drug resistance.

A multidimensional framework deciphers the physiological regulation of copper homeostasis, including hepatocentric organ-level regulation, organelle-specific cellular storage and transport, and iron– copper–zinc ion crosstalk.

Cuproptosis is mainly regulated by core cuproptosis proteins, mitochondrial respiratory function, and cellular copper homeostasis.

By depleting glutathione (GSH), alleviating hypoxia, modulating immunity, and enabling multimodal synergy, innovative copper-based nanomaterials enhance copper ion delivery and cytotoxicity, resulting in potent antitumor effects. sciencenewshighlights ScienceMission https://sciencemission.com/Cuproptosis-in-cancer

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Cuproptosis is a mitochondria-and copper-dependent regulated form of cell death that has attracted growing interest as a therapeutic strategy in oncology. Its core mechanism involves the aggregation of lipoylated proteins in the tricarboxylic acid cycle to trigger proteotoxic stress and the destabilization of iron–sulfur cluster proteins, leading to mitochondrial dysfunction. These two effects synergize to initiate this regulated form of cell death. Recent studies have expanded this framework, revealing multilayered regulation through the core proteins of cuproptosis, mitochondrial respiratory function, and cellular copper homeostasis. Translational efforts have led to the development of copper-based therapeutics, including ionophores and nanomaterials. The utilization of smart-responsive nanomaterials also offers improved precision in tumor delivery and resistance circumvention.

LA JOLLA, CA— A cancer drug target already being investigated in clinical trials turns out to be doing something even more consequential than researchers realized. Scientists at Scripps Research have discovered that the enzyme Pol theta (Polθ) drives a DNA repair mechanism directly at broken replication forks—one of the most frequent forms of DNA damage in cancer cells. The findings, published in Molecular Cell on March 16, 2026, help explain how tumors survive relentless replication stress and clarify why Pol theta inhibitors may be an effective strategy to selectively target cancer.

“We’ve uncovered a whole new dimension of how cancer cells cope with DNA damage at replication forks,” says Xiaohua Wu, professor at Scripps Research and senior author of the study.

Every time a cell divides, it must make an exact copy of its entire genome, a process carried out by molecular machinery that unzips the DNA double helix and reads each strand to build a new one. The point where this unzipping and copying actively happens is called a replication fork. But when this replication machinery encounters damage, forks can stall or collapse, leaving behind dangerous one-ended DNA breaks that are particularly difficult to repair and, if left unresolved, can kill the cell. This is particularly true in cancer cells, where replication stress is constant.