Abstract
Effects of chronic heavy metal stress on hepatocellular pathophysiology remains ill-understood. Human livers are a long-term accumulative site for many toxic heavy metals (e.g., cadmium and arsenic) whose effects are unknown. In the current study, we studied effects of chronic, low-dose exposures of cadmium (CLEC) modulated by normoglycemic (5.6 mM) and hyperglycemic (15 mM) exposures, focusing on hepatocellular mitochondrial function. HepG2 and HUH7 cell lines were exposed to CLEC and glucose for 24 weeks, mimicking a chronic heavy metal exposure paradigm seen in normal and type II diabetic individuals. We observe that CLEC exposures significantly affect the long-term health of mitochondria, including decreased mitochondrial mass, increased superoxide production, and loss of mitochondrial membrane potential (MMP) in a CLEC and glucose-dependent manner. Furthermore, the Seahorse MitoStress assay revealed CLEC induced significant chronic oxidative stress. In particular, CLEC cells showed altered levels of basal and non-mitochondrial respiration, causing dysregulation in mitochondrial oxygen consumption rates (OCRs). Lastly, we identified significant impacts of CLEC and glucose exposures on the mitochondrial dynamics (fission/fusion) of the CLEC cells, which showed enhanced mitochondrial fragmentation and turnover rates. We also identified novel cell compensatory mechanisms that may mask the true extent of chronic Cd exposure induced damage in liver cells. CLEC and glucose work additively to damage hepatocellular mitochondrial function. New approach methodologies (NAMs), such as the current vitro toxicology study, establish the insidious effects of chronic heavy metal pollutant exposures on human hepatocellular function.