The hypoxia-inducible factor (HIF)-1␣ and HIF-2␣ are closely related, key transcriptional regulators of the hypoxic response, countering a low oxygen situation with the up-regulation of target genes associated with numerous processes, including vascularization and glycolysis. This involves a dual mechanism of control through both stabilization and transactivation, regulated via prolyl and asparaginyl hydroxylation. Despite high similarity with respect to protein sequence and activation pathway, a growing number of physiological and mechanistic differences between HIF-1␣ and HIF-2␣ are being reported. To further characterize this nonredundancy, the stabilization of endogenous proteins and regulation of the transactivation domains were compared in a graded oxygen environment across a series of cell lines. Although generally similar results were found, interesting and specific differences between the HIF-␣ proteins were observed within certain cell lines, such as rat adrenal PC12s, emphasizing the cell-specific nature of HIF-␣ regulation. We characterize a conserved amino acid substitution between HIF-1␣ and HIF-2␣ that contributes to the intrinsically higher FIH-1-mediated asparaginyl hydroxylation of HIF-1␣ and, hence, lower HIF-1␣ activity. In addition, our data demonstrate that the different cell lines can be classified into two distinct groups: those in which stabilization and transactivation proceed in conjunction (HeLa, 293T, and COS-1) and those cells in which HIF-␣ is stabilized prior to transactivation (PC12, HepG2, and CACO2). Interestingly, the initial stabilization of HIF-␣ prior to transactivation up-regulation predicted from in vitro derived hydroxylation data is only true for a subset of cells.In a state of hypoxia, where the demand for oxygen exceeds supply, physiological responses are mounted, including increasing the capacity for blood to carry oxygen to tissues and facilitating the production of ATP by anaerobic glycolysis. The hypoxia-inducible factors (HIFs) 4 are key transcriptional regulators of this genomic response to hypoxia in essentially all mammalian cells. HIF is composed of an oxygen-regulated HIF-␣ subunit (HIF-1␣ or HIF-2␣) and the ubiquitous aryl hydrocarbon receptor nuclear translocator (or HIF-1) partner protein. HIF-␣ protein turnover in normoxia is very rapid due to the inhibitory action of the HIF-␣ prolyl hydroxylases (PHDs). These oxygen-dependent enzymes hydroxylate two conserved prolyl residues within a central oxygen-dependent degradation domain of the HIF-␣ proteins, promoting binding of the Von Hippel-Lindau protein, ubiquitylation, and proteasomal degradation (1-3). Any HIF-␣ escaping this normoxic degradation is also subject to hydroxylation of a conserved asparagine within the C-terminal transactivation domain (CAD) that represses activity via abrogation of CBP/p300 recruitment (4, 5). Under hypoxic conditions, the activity of the prolyl and asparaginyl hydroxylases is inhibited, and the HIF-␣ proteins are stabilized and transcriptionally activated, leading to po...
