HIF2α acts as an mTORC1 activator through the amino acid carrier SLC7A5.

The mammalian target of rapamycin (mTOR) pathway, which is essential for cell proliferation, is repressed in certain cell types in hypoxia. However, hypoxia-inducible factor 2α (HIF2α) can act as a proliferation-promoting factor in some biological settings. This paradoxical situation led us to study whether HIF2α has a specific effect on mTORC1 regulation.

Acute Vhl gene inactivation induces cardiac HIF-dependent erythropoietin gene expression.

Von Hippel Lindau (Vhl) gene inactivation results in embryonic lethality. The consequences of its inactivation in adult mice, and of the ensuing activation of the hypoxia-inducible factors (HIFs), have been explored mainly in a tissue-specific manner. This mid-gestation lethality can be also circumvented by using a floxed Vhl allele in combination with an ubiquitous tamoxifen-inducible recombinase Cre-ER(T2).

A yeast three-hybrid system that reconstitutes mammalian hypoxia inducible factor regulatory machinery.

Background: Several human pathologies, including neoplasia and ischemic cardiovascular diseases, course with an unbalance between oxygen supply and demand (hypoxia). Cells within hypoxic regions respond with the induction of a specific genetic program, under the control of the Hypoxia Inducible Factor (HIF), that mediates their adaptation to the lack of oxygen. The activity of HIF is mainly regulated by the EGL-nine homolog (EGLN) enzymes that hydroxylate the alpha subunit of this transcription factor in an oxygen-dependent reaction.

Identification of a region on hypoxia-inducible-factor prolyl 4-hydroxylases that determines their specificity for the oxygen degradation domains.

HIFs [hypoxia-inducible (transcription) factors] are essential for the induction of an adaptive gene expression programme under low oxygen partial pressure. The activity of these transcription factors is mainly determined by the stability of the HIFalpha subunit, which is regulated, in an oxygen-dependent manner, by a family of three prolyl 4-hydroxylases [EGLN1-EGLN3 (EGL nine homologues 1-3)]. HIFalpha contains two, N- and C-terminal, independent ODDs (oxygen-dependent degradation domains), namely NODD and CODD, that, upon hydroxylation by the EGLNs, target HIFalpha for proteasomal degradation.

Analysis of HIF-prolyl hydroxylases binding to substrates.

Hypoxia inducible transcription factors (HIF) are mainly regulated by a group of proline hydroxylases (EGLNs) that, in the presence of oxygen, target HIF for degradation. HIFalpha contains two independent oxygen degradation domains (N-ODD and C-ODD) that are substrates for these enzymes. In this work, we employed the yeast two-hybrid assay to study the sequence determinants required for the binding of EGLN1 and 3 to HIF1alpha in a cellular context.