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.

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.

Project description:The forkhead box (FOX) family of transcriptional regulators is characterized by a distinct forkhead DNA-binding domain11. FOXF1 gene is highly conserved across species and implicated in embryonic digestive tract morphogenesis. In an in-vitro established model, normal esophageal squamous cells, EPC2, were transfected with FOXF1 to determine pathways regulated by FOXF1 during the squamous to columnar change in cells.

Project description:Transformed human esophageal keratinocyte cell line EPC2-T (EPC2-hTERT-EGFR-cyclin D1-p53R175H) cells were stimulated with or without 2.5 ng/ml recombinant human TGF-beta1 for 10 days. The above cells were subjected to treatment for 10 days with or without 0.5 µg/ml doxycycline (DOX) to activate tetracycline-inducible (tet-on) ICN1, an active form of Notch1.

Project description:We report RNA- and ChIP-sequencing profiling of the esophageal epithelial cell line EPC2 in response to IL-13 and Vitamin D either alone or in the combined treatment

Project description:We used RNA sequencing to identify differentially expressed genes during esophageal epithelial differentiation and in the presence of interleukin 13 using an air-liquid interface culture system. RNA sequencing was performed on a human esophageal epithelial cell line (EPC2-hTERT) grown submerged (day 8) or at the air-liquid interface (ALI) (day 14, untreated or treated with interleukin 13 [100 ng/mL])

Project description:In this study we performed H3K4me3 and STAT6 ChIP seq analyses on hTERT immortalized human esophageal keratinocytes (hTERT-EPC2) under air-liquid interface conditions following IL-13 (100ng/ml) 30 minutes and 4 hours stimulation

Project description:Comparison of CD44-high/CD24-low (CD44H) and CD44-low/CD24-high (CD44L) cell fractions in transformed human esophageal cell line EPC2-T CD44H cells display enhanced malignant potential (e.g. tumorigenicity, colony formation) compared to CD44L cells.

Project description:The general assumption is that when bacteria run out of nutrients they become dormant or form spores. Here we show, using a new technique, that under deep starvation conditions non-sporulating Bacillus subtilis cells do not become dormant but continue to grow. B. subtilis can form (endo)spores and this has been regarded as the principal mechanism through which it survives long periods of nutrient depletion. However, in this study we demonstrate that non-sporulating B. subtilis cells can survive deep starvation conditions for many months. During this period, cells adopt an almost coccoid shape and become tolerant to antibiotics and oxidative stress. Interestingly, these cells appeared to be metabolically active, and transcriptome analyses indicated that their gene-expression profile differs substantially from both stationary phase cells, and exponentially growing cells. Surprisingly, using an inhibitor for cell division, we discovered that these coccoid-like B. subtilis cells are not dormant but actually grow and divide, albeit with a doubling time of ~4 days. It emerged that secreted proteases, allowing acquisition of nutrients from lysed brethren, are essential for this growth mode. In fact, nutrient levels comparable to 10,000 times diluted LB (Lysogeny broth) appeared to be sufficient to sustain this growth. The very slow growth provides an alternative strategy for B. subtilis to survive nutrient depletion and environmental stresses. We propose to call this the oligotrophic growth state. This state might be common among bacterial species to survive deep starvation conditions.

Project description:Cancer cells exhibit dramatic differences in gene expression at the single-cell level which can predict whether they become resistant to treatment. Treatment perpetuates this heterogeneity, resulting in a diversity of cell states among resistant clones. However, it remains unclear whether these differences lead to distinct responses when another treatment is applied or the same treatment is continued. In this study, we combined single-cell RNA-sequencing with barcoding to track resistant clones through prolonged and sequential treatments. We found that cells within the same clone have similar gene expression states after multiple rounds of treatment. Moreover, we demonstrated that individual clones have distinct and differing fates, including growth, survival, or death, when subjected to a second treatment or when the first treatment is continued. By identifying gene expression states that predict clone survival, this work provides a foundation for selecting optimal therapies that target the most aggressive resistant clones within a tumor.