Regulation of energy metabolism is a novel function of p53 in tumor suppression. Parkin (PARK2), a Parkinson disease-associated gene, is a potential tumor suppressor whose expression is frequently diminished in tumors. Here Parkin was identified as a p53 target gene that is an important mediator of p53's function in regulating energy metabolism. The human and mouse Parkin genes contain functional p53 responsive elements, and p53 increases the transcription of Parkin in both humans and mice. Parkin contributes to the function of p53 in glucose metabolism; Parkin deficiency activates glycolysis and reduces mitochondrial respiration, leading to the Warburg effect. Restoration of Parkin expression reverses the Warburg effect in cells. Thus, Parkin deficiency is a novel mechanism for the Warburg effect in tumors. Parkin also contributes to the function of p53 in antioxidant defense. Furthermore, Parkin deficiency sensitizes mice to γ-irradiation-induced tumorigenesis, which provides further direct evidence to support a role of Parkin in tumor suppression. Our results suggest that as a novel component in the p53 pathway, Parkin contributes to the functions of p53 in regulating energy metabolism, especially the Warburg effect, and antioxidant defense, and thus the function of p53 in tumor suppression.
Metabolic alterations are a hallmark of tumor cells (1, 2). Whereas normal cells use mitochondrial respiration to provide energy, the majority of tumor cells preferentially use aerobic glycolysis, a switch known as the Warburg effect (3). Because glycolysis produces ATP much less efficiently than mitochondrial respiration, tumor cells compensate by having a much higher rate of glucose uptake and utilization than normal cells (1, 2). Recent studies have strongly suggested that the Warburg effect is a key contributor to malignant progression (1, 2), and reversing the Warburg effect inhibits the tumorigenicity of cancer cells (4, 5). However, the underlying mechanisms for the Warburg effect are not well-understood (1, 2).p53 plays a central role in tumor prevention. As a transcription factor, in response to stress, p53 transcribes its target genes to start various cellular responses, including cell-cycle arrest, apoptosis, and/or senescence, to prevent tumor formation (6, 7). Recent studies have revealed that regulating energy metabolism and the Warburg effect is a novel function of p53 in tumor suppression (2, 8). p53 induces TIGAR (TP53-induced glycolysis and apoptosis regulator) to reduce glycolysis (9), and induces SCO2 (10) and GLS2 (11, 12) to promote mitochondrial respiration. Loss of p53 results in decreased mitochondrial respiration and enhanced glycolysis, leading to the Warburg effect. Furthermore, regulating antioxidant defense has recently been revealed as another novel function for p53 (8, 13). p53 induces several antioxidant genes, including Sestrins (14), TIGAR (9), ALDH4 (15), and GLS2 (11, 12), to reduce the levels of reactive oxygen species (ROS) and DNA damage in cells, which contributes greatly to the ro...
