Project description:Solid tumors are characterized by significantly lower oxygen (O2) levels. Despite this fact, routine preclinical cancer studies are performed under ambient O2 conditions. We have developed an experimental approach that allows us to collect, process and evaluate cancer and non-cancer cells under physioxia (3-5% O2), in such a way that there is very minimal exposure to air. In addition to evaluating mouse mammary tumor cell lines with respect to kinome changes due to ambient and physioxic O2 tensions, we applied single cell-RNA sequencing to determine transcriptomic changes that occur in primary human breast epithelial cells that were collected, processed and cultured in ambient air and physioxia. We demonstrate that ambient and physioxic O2 tensions induce unique transcriptomic changes in primary human breast epithelial cells that are concurrent with our observations in the tumor cells.

Project description:Solid tumors are characterized by significantly lower oxygen (O2) levels. Despite this fact, routine preclinical cancer studies are performed under ambient O2 conditions. We have developed an experimental approach that allows us to collect, process and evaluate cancer and non-cancer cells under physioxia (3-5% O2), in such a way that there is very minimal exposure to air. We have shown in previous studies that ambient and physioxic O2 differentially impact relevant cell surface markers and sensitivity to therapy. In this study, our goal was to further explore oxygen-dependent signaling pathway alterations and to determine how these pathways influence response to targeted therapies. Using cells derived from transgenic mouse mammary tumors and healthy primary human breast epithelial cells, we show the impact of ambient air and physioxia on the kinome, with subsequent pathway alterations that mediate the effectiveness of single and combination therapies. Our data emphasize the importance of O2 considerations in preclinical cancer research and drug development.

Project description:Preclinical studies of primary cancer cells are always done after tumors are removed from patients or animals at ambient atmospheric oxygen (O2, ~21%). However, O2 concentrations in organs are in the ~3-10% range, with most tumors in an hypoxic or 1-2% O2 environment in vivo. Although effects of O2 tension on tumor cell characteristics in vitro have been studied, these studies are done only after tumors are first collected and processed in ambient air. Similarly, sensitivity of primary cancer cells to anti-cancer agents is routinely examined at ambient O2. Here, using both mouse models and human cancers, we demonstrate that tumors collected, processed and propagated at physiologic (physioxia) O2 compared to ambient air display very distinct differences in key signaling networks including Lgr5/Wnt, Yap, and Nrf2/Keap1, nuclear reactive oxygen species levels, alternative splicing, and sensitivity to several targeted therapies including PIK3CAalpha-specific and EGFR inhibitors. Significance: Extra-physiologic oxygen shock/stress (EPHOSS), as noted in cells collected/processed under ambient air, has been demonstrated to have significant impact on numbers and engrafting ability of hematopoietic stem cells. We report deleterious effects of EPHOSS on cancer cell behavior and EPHOSS-mediated effects on cancer cells give misleading information on signaling pathway activation that could severely impact the relevance of these findings. Cancer cells under EPHOSS show higher proliferation rate compared to cells under physioxia and thus are sensitive to anti-proliferative agents. Thus, drugs that show effectiveness on cancer cells collected in ambient air and subjected to EPHOSS may not be effective or as relevant in vivo, results that could partially explain the limited clinical translation of laboratory findings. Evaluating cell signaling and effects of drugs on cancer cells under physiologic O2 prior to in vivo studies could substantially reduce cost and aid in drug discovery relevant to the actual physioxia/pathological status of the tumor cells in vivo.

Project description:Endothelial cells, and many other types of cells too, physiologically reside in low O2 environments (~ 2-13% O2 or 15-60 mmHg pO2; [PCN]) relevantly to atmospheric O2 (~ 21% or 160 mmHg pO2 at sea level) in vivo. Such PCN is critical for endothelial functions. The majority of our current knowledge regarding the cellular and signaling mechanisms governing endothelial functions, however, is built on endothelial models established under atmospheric O2 (~21% O2). Herein, we comapred the transcriptional profiles between HUVE and HUAE cells cultured and expanded under PCN (3% oxygen) and standard culture normoxia (21% O2).

Project description:Comparison of hypoxia (4 % O2) cultured human embryonic stem cells (hESCs) to normoxia (21 % O2) cultured

Project description:Plants were grown in liquid media at ambient air composition [0.03% CO2, 78.97% N2, 21% O2] for 12 days. On 13th day one set (“perturbed set”) of samples (20 samples) were exposed to air with elevated CO2 composition [1% CO2, 78% N2, 21% O2] and the other set (“control set”) of samples (20 samples) were continued to grow at air of ambient composition. Two samples (shake flasks containing plants) were harvested at 1, 3, 6, 9, 12, 18, 24 and 30 hours from each of the two sets after the start of the treatment. From each of the “control” and “perturbed” set 4 samples were harvested to serve as pre-treatment controls.

Project description:Endothelial cells, and many other types of cells too, physiologically reside in low O2 environments (~ 2-13% O2 or 15-60 mmHg pO2; [PCN]) relevantly to atmospheric O2 (~ 21% or 160 mmHg pO2 at sea level) in vivo. Such PCN is critical for endothelial functions. The majority of our current knowledge regarding the cellular and signaling mechanisms governing endothelial functions, however, is built on endothelial models established under atmospheric O2 (~21% O2). Herein, we comapred the transcriptional profiles between HUVE and HUAE cells cultured and expanded under PCN (3% oxygen) and standard culture normoxia (21% O2). We established human umbilical vein (HUVE) and artery (HUAE) endothelial cell cultures under PCN (3% O2; 20-25 days) and SCN (21% O2), and examined the global gene expression using Affymetrix U133 plus 2.0 microarray chips.

Project description:Ambient O2 pressure induces NF-kB1/RelA related inflammatory response in human lung epithelial cells in vitro

Project description:Ambient O2 pressure induces NF-kB1/RelA related inflammatory response in human lung epithelial cells in vitro

Project description:To delineate the role of hypoxia in esophageal epithelial biology, we carried out gene array experiments using a non-transformed immortalized diploid human esophageal cell line, EPC2-hTERT (Mol Cancer Res. 2003;1:729-38). Unlike cancer cell lines, EPC2-hTERT has no genetic alterations at early passages that may affect the cellular response to hypoxia. Experiment Overall Design: EPC2-hTERT cells were exposed to moderate (1% O2) hypoxia in experiment 1 (Exp1) or severe (0.2% O2) hypoxia in experiment 2 (Exp2). Normoxia (21% O2) served as a control in both experiments.