HuR-dependent SOD2 protein synthesis is an early adaptation to anchorage independence

Abstract

During metastasis, cancer cells must adapt to survive a loss of anchorage and evade anoikis. An important pro-survival adaptation is the ability of metastatic tumor cells to increase their antioxidant capacity and restore cellular redox balance. Although much is known about the transcriptional regulation of antioxidant enzymes in response to stress, how cells rapidly adapt to alter antioxidant enzyme levels is less well understood. Using ovarian cancer cells as a model, we demonstrate that an increase in protein expression of the mitochondrial superoxide dismutase SOD2 is a very early event initiated in response to cellular detachment. SOD2 protein synthesis is rapidly induced within 0.5-2 hours of matrix detachment, and polyribosome profiling demonstrates an increase in the number of ribosomes bound to SOD2 mRNA, indicating an increase in SOD2 translation in response to anchorage-independence. Mechanistically, we find that anchorage-independence specifically induces cytosolic accumulation of the RNA binding protein HuR/ELAVL1 and leads to increased HuR binding to SOD2 mRNA. Using HuR siRNA-mediated knock-down, we show that the presence of HuR is necessary for the increase in SOD2 mRNA association with the heavy polyribosome fraction and SOD2 protein synthesis observed in anchorage-independence. Cellular detachment activates the stress-response protein kinase p38 MAPK, which is necessary for HuR-SOD2 mRNA binding and optimal increases in SOD2 protein expression. These findings illustrate a novel post-transcriptional regulatory mechanisms of SOD2, enabling cells to rapidly increase their mitochondrial antioxidant capacity as an acute response to anchorage-independence.