Abstract
Hepatocyte polyploidization promotes liver homeostasis by enhancing resistance to cellular stress. Caspase-2, a proapoptotic protease, restricts polyploidization by deleting polyploid and aneuploid cells. While caspase-2 protects against diet-induced hepatic injury, it also acts as a tumor suppressor by controlling genomic instability and oxidative stress. To investigate these roles, we assessed hepatic ploidy dynamics, liver damage, and age-associated tumorigenesis in caspase-2-deficient and catalytically inactive mutant mice. We found that caspase-2 loss promotes early-onset hepatocyte hyperpolyploidy, accompanied by progressive liver inflammation, fibrosis, oxidative liver damage, ferroptosis, and higher incidence of spontaneous hepatocellular carcinoma in aged animals. Proteomic profiling revealed a pathogenic polyploidy-associated signature associated with caspase-2 deficiency and increased predisposition to liver disease and malignancy. These findings establish caspase-2 enzymatic activity as a critical regulator of hepatic genome stability and preventing age-related liver cancer that strongly argue against therapeutic caspase-2 inhibition as a strategy for managing liver injury or cancer risk.