HIF-1 is a transcription factor that regulates genes involved in oxygen homeostasis. In normoxia, degradation of the HIF-1 alpha subunit is enabled by two prolyl hydroxylations at residues P402 and P564, while inactivation occurs through asparaginyl hydroxylation at residue N803 within its C-transactivation domain (C-TAD). For therapeutic angiogenesis purposes, HIF-1 alpha stabilization was previously achieved by either deleting its oxygen-dependent degradation domains, or introducing two proline point mutations at residues P402 and P564. We assessed the hypothesis that constitutive activation of HIF-1 alpha in addition to its stabilization would result in greater HIF-1 alpha transcriptional activity and angiogenic effects than mere stabilization of the molecule. For this, we constructed a Triple mutant HIF-1 alpha (TM), bearing mutations P402A and P564G N803A. Transient co-transfections with hypoxia-responsive element-luciferase construct revealed 2 to 2.5-fold increase in transcriptional activity of TM compared with P402A P564G double mutant and wild-type HIF-1 alpha. In-vitro angiogenesis assay using transfected human umbilical vein endothelial cells (HUVEC) showed that TM stimulated tube formation to a greater extent than both P402A P564G mutant and wild-type HIF-1 alpha. Accordingly, ELISA revealed that VEGF levels within the transfected HUVEC were about 10-fold greater with the TM.
Conclusions: Constitutive activation of the HIF-1 alpha C-TAD, and not merely stabilization of the HIF-1 alpha molecule, is essential for optimal HIF-mediated transcriptional and angiogenic effects. This finding could have important implications for therapeutic angiogenesis using HIF-1 alpha.