ABSTRACT
Solid tumors require an efficient decision-making mechanism to progress through a gradient of hypoxia. Here, we show that an oxygen-sensory p53 tetramer-octamer switch makes cell decision for survival or death in variable hypoxia. Trapping homo-oligomers from biosynthesis cycle, we found a metastable p53 tetramer in cells. Under the operation of switch, tetramer segregates the p53 character of a tumor suppressor and promoter. The p53 switch generates a pattern of its on-off state in time that is specific to the strength of hypoxia. A bidirectional tetramer-octamer conversion in on state decides the restoration of basal state by forward and programs apoptosis upon the reverse shift via p53-MDM2 loop. However, reversible dimertetramer transitions in off state trigger chaperoning of HIF-1 complex by tetramer in forward and oncogenic gain-of-function by prion-like dimers in reverse direction. Temporal on-off patterns calibrate stabilized p53 pool by defining the abundance of dimer, tetramer and octamer that ultimately decides diverse cellular outcomes in hypoxia. Through multi-chromophore FRET, we further show that chaperoning of HIF-1 may modulate angiogenesis through a possible flip-flop of the p53T-HIF-1 complex upon DNA. Our results demonstrate how p53 can sense oxygen and act upon its homo-oligomerization states to control cell fate in hypoxic tumors.