Abstract
Transcription factors HIF1 and HIF2 are central regulators of physiological responses to hypoxia and important for normal functioning of tissue stem cells and maintenance of healthy microvasculature. Even modest decreases in HIF activity exert detrimental effects in tissues although it is unclear what factors can directly impair HIF functions. We hypothesized that the presence of functionally important, large intrinsically disordered regions in HIFα subunits of HIF1/2 could make them structurally vulnerable to protein-damaging conditions. We found that common protein-damaging agents such as endogenous/exogenous aldehydes (formaldehyde, acetaldehyde), moderate heat shock and the environmental toxicant cadmium cause inactivation of HIF1 and HIF2 due to structural damage to HIFα subunits. Aldehydes triggered a rapid and selective depletion of HIF1α and HIF2α, which occurred as a result of enhanced binding of Pro-hydroxylated/VHL-ubiquitinated HIFα by 26S proteasomes. In the absence of proteasomal degradation, aldehyde-damaged HIF1 and HIF2 were transactivation defective and HIFα subunits became insoluble/denatured when their VHL-mediated ubiquitination was blocked. Protein damage by heat shock and cadmium resulted in the insolubility of Pro-nonhydroxylated HIFα. Thus, VHL-dependent ubiquitination of damaged HIFα also acts as means to maintain their solubility, permitting capture by proteasomes. The observed control of HIFα stability at the point of proteasome binding may extend to several posttranslational modifications that occur in the conformationally flexible regions of these proteins. Our findings revealed vulnerability of HIF1 and HIF2 to direct inactivation by protein-damaging agents, which helps understand their tissue injury mechanisms and favorable responses of hypoxic tumors to hyperthermia.