Authors: Shuo Qie, Dongming Liang, Chengqian Yin, Weiting Gu, Meng Meng, Chenguang Wang and Nianli Sang

Shuo Qie

Department of Biology; College of Arts and Sciences; Drexel University; Philadelphia, PA USA; Department of Pathology and Laboratory Medicine; Drexel University College of Medicine; Philadelphia, PA USA

Dongming Liang

Department of Biology; College of Arts and Sciences; Drexel University; Philadelphia, PA USA

Chengqian Yin

Department of Biology; College of Arts and Sciences; Drexel University; Philadelphia, PA USA

Weiting Gu

Departments of Cancer Biology; Stem Cell Biology and Regenerative Medicine; Kimmel Cancer Center; Thomas Jefferson University; Philadelphia, PA USA; Department of Obstetrics and Gynecology; Qilu Hospital; Shandong University; Jinan, Shandong, China

Meng Meng

Department of Biology; College of Arts and Sciences; Drexel University; Philadelphia, PA USA

Chenguang Wang

Departments of Cancer Biology; Stem Cell Biology and Regenerative Medicine; Kimmel Cancer Center; Thomas Jefferson University; Philadelphia, PA USA; Department of Obstetrics and Gynecology; Qilu Hospital; Shandong University; Jinan, Shandong, China

Nianli Sang

Corresponding author: nianli.sang@drexel.edu
Department of Biology; College of Arts and Sciences; Drexel University; Philadelphia, PA USA; Department of Pathology and Laboratory Medicine; Drexel University College of Medicine; Philadelphia, PA USA

Abstract:
Glutamine (Gln) and glucose (Glc) represent two important nutrients for proliferating cells, consistent with the observations that oncogenic processes are associated with enhanced glycolysis and glutaminolysis. Gln depletion and Glc depletion have been shown to trigger growth arrest and eventually cell death. Solid tumors often outgrow the blood supply, resulting in ischemia, which is associated with hypoxia and nutrient insufficiency. Whereas oxygen-sensing and adaptive mechanisms to hypoxia have been well-studied, how cells directly sense and respond to Gln and Glc insufficiency remains unclear. Using mRNA profiling techniques, we compared the gene expression profiles of acute Gln-depleted cells, Glc-depleted cells and cells adapted to Gln depletion. Here we report the global changes of the gene expression in those cells cultured under the defined nutrient conditions. Analysis of mRNA profiling data revealed that Gln and Glc depletion triggered dramatic gene expression reprogramming. Either Gln or Glc deletion leads to changes of the expression of cell cycle genes, but these conditions have distinctive effects on transcription regulators and gene expression profiles. Moreover, Gln and Glc depletion triggered distinguishable ER-stress responses. The gene expression patterns support that Gln and Glc have distinctive metabolic roles in supporting cell survival and proliferation, and cells use different mechanisms to sense and respond to Gln and Glc insufficiency. Our mRNA profiling database provides a resource for further investigating the nutrient-sensing mechanisms and potential effects of Glc and Gln abundance on the biological behaviors of cells.

Received: February 9, 2012; Accepted: August 23, 2012; Published Online: August 30, 2012

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