ISGylation directly modifies hypoxia-inducible factor-2α and enhances its polysome association.

The hypoxia-inducible factors (HIF)-1α and HIF-2α are central regulators of transcriptional programmes in settings such as development and tumour expansion. HIF-2α moonlights as a cap-dependent translation factor. We provide new insights into how the interferon-stimulated gene 15 (ISG15), a ubiquitin-like modifier, and the HIFs regulate one another in hypoxia and interferon-induced cells. We show that upon ISGylation induction and HIF-α stabilization, both HIFs promote protein ISGylates through transcriptional and/or post-transcriptional pathways. We show the first evidence of HIF-2α modification by ISG15. ISGylation induces system-level alterations to the HIF transcriptional programme and increases the cytoplasmic/nuclear fraction and translation activity of HIF-2α. This work identifies ISG15 as a regulator of hypoxic mRNA translation, which has implications for immune processes and disease progression.

Physioxic human cell culture improves viability, metabolism, and mitochondrial morphology while reducing DNA damage.

Multicellular organisms balance oxygen delivery and toxicity by having oxygen pass through several barriers before cellular delivery. In human cell culture, these physiologic barriers are removed, exposing cells to higher oxygen levels. Human cells cultured in ambient air may appear normal, but this is difficult to assess without a comparison at physiologic oxygen. Here, we examined the effects of culturing human cells throughout the spectrum of oxygen availability on oxidative damage to macromolecules, viability, proliferation, the antioxidant and DNA damage responses, metabolism, and mitochondrial fusion and morphology. We surveyed 4 human cell lines cultured for 3 d at 7 oxygen conditions between 1 and 21% O2. We show that oxygen levels and cellular benefit are not inversely proportional, but the benefit peaks within the physioxic range. Normoxic cells are in a perpetual state of responding to damaged macromolecules and mitochondrial networks relative to physioxic cells, which could compromise an investigation. These data contribute to the concept of an optimal oxygen availability for cell culture in the physioxic range where the oxygen is not too high to reduce oxidative damage, and not too low for efficient oxidative metabolism, but just right: the Goldiloxygen zone.-Timpano, S., Guild, B. D., Specker, E. J., Melanson, G., Medeiros, P. J., Sproul, S. L. J., Uniacke, J. Physioxic human cell culture improves viability, metabolism, and mitochondrial morphology while reducing DNA damage.

The eIF4E2-Directed Hypoxic Cap-Dependent Translation Machinery Reveals Novel Therapeutic Potential for Cancer Treatment.

Hypoxia is an aspect of the tumor microenvironment that is linked to radiation and chemotherapy resistance, metastasis, and poor prognosis. The ability of hypoxic tumor cells to achieve these cancer hallmarks is, in part, due to changes in their gene expression profiles. Cancer cells have a high demand for protein synthesis, and translational control is subsequently deregulated. Various mechanisms of translation initiation are active to improve the translation efficiency of select transcripts to drive cancer progression. This review will focus on a noncanonical cap-dependent translation initiation mechanism that utilizes the eIF4E homolog eIF4E2, a hypoxia-activated cap-binding protein that is implicated in hypoxic cancer cell migration, invasion, and tumor growth in mouse xenografts. A historical perspective about eIF4E2 and its various aliases will be provided followed by an evaluation of potential therapeutic strategies. The recent successes of disabling canonical translation and eIF4E with drugs should highlight the novel therapeutic potential of targeting the homologous eIF4E2 in the treatment of hypoxic solid tumors.

Analysis of Cap-binding Proteins in Human Cells Exposed to Physiological Oxygen Conditions.

Translational control is a focal point of gene regulation, especially during periods of cellular stress. Cap-dependent translation via the eIF4F complex is by far the most common pathway to initiate protein synthesis in eukaryotic cells, but stress-specific variations of this complex are now emerging. Purifying cap-binding proteins with an affinity resin composed of Agarose-linked m7GTP (a 5' mRNA cap analog) is a useful tool to identify factors involved in the regulation of translation initiation. Hypoxia (low oxygen) is a cellular stress encountered during fetal development and tumor progression, and is highly dependent on translation regulation. Furthermore, it was recently reported that human adult organs have a lower oxygen content (physioxia 1-9% oxygen) that is closer to hypoxia than the ambient air where cells are routinely cultured. With the ongoing characterization of a hypoxic eIF4F complex (eIF4FH), there is increasing interest in understanding oxygen-dependent translation initiation through the 5' mRNA cap. We have recently developed a human cell culture method to analyze cap-binding proteins that are regulated by oxygen availability. This protocol emphasizes that cell culture and lysis be performed in a hypoxia workstation to eliminate exposure to oxygen. Cells must be incubated for at least 24 hr for the liquid media to equilibrate with the atmosphere within the workstation. To avoid this limitation, pre-conditioned media (de-oxygenated) can be added to cells if shorter time points are required. Certain cap-binding proteins require interactions with a second base or can hydrolyze the m7GTP, therefore some cap interactors may be missed in the purification process. Agarose-linked to enzymatically resistant cap analogs may be substituted in this protocol. This method allows the user to identify novel oxygen-regulated translation factors involved in cap-dependent translation.