1.Response: An In Vitro Model to Probe the Regulation of Adipocyte Differentiation under Hyperglycemia (Diabetes Metab J 2013;37:176-80).
Kusampudi SHILPA ; Thangaraj DINESH ; Baddireddi Subhadra LAKSHMI
Diabetes & Metabolism Journal 2013;37(4):298-299
No abstract available.
Adipocytes
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Hyperglycemia
2.An In Vitro Model to Probe the Regulation of Adipocyte Differentiation under Hyperglycemia.
Kusampudi SHILPA ; Thangaraj DINESH ; Baddireddi Subhadra LAKSHMI
Diabetes & Metabolism Journal 2013;37(3):176-180
BACKGROUND: The aim of this study was an in vitro investigation of the effect of high glucose concentration on adipogenesis, as prolonged hyperglycemia alters adipocyte differentiation. METHODS: 3T3-L1 preadipocytes differentiated in the presence of varying concentrations of glucose (25, 45, 65, 85, and 105 mM) were assessed for adipogenesis using AdipoRed (Lonza) assay. Cell viability and proliferation were measured using MTT reduction and [3H] thymidine incorporation assay. The extent of glucose uptake and glycogen synthesis were measured using radiolabelled 2-deoxy-D-[1-3H] glucose and [14C]-UDP-glucose. The gene level expression was evaluated using reverse transcription-polymerase chain reaction and protein expression was studied using Western blot analysis. RESULTS: Glucose at 105 mM concentration was observed to inhibit adipogenesis through inhibition of CCAAT-enhancer-binding proteins, sterol regulatory element-binding protein, peroxisome proliferator-activated receptor and adiponectin. High concentration of glucose induced stress by increasing levels of toll-like receptor 4, nuclear factor kappaB and tumor necrosis factor alpha thereby generating activated preadipocytes. These cells entered the state of hyperplasia through inhibition of p27 and proliferation was found to increase through activation of protein kinase B via phosphoinositide 3 kinase dependent pathway. This condition inhibited insulin signaling through decrease in insulin receptor beta. Although the glucose transporter 4 (GLUT4) protein remained unaltered with the glycogen synthesis inhibited, the cells were found to exhibit an increase in glucose uptake via GLUT1. CONCLUSION: Adipogenesis in the presence of 105 mM glucose leads to an uncontrolled proliferation of activated preadipocytes providing an insight towards understanding obesity.
Adipocytes
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Adipogenesis
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Adiponectin
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Blotting, Western
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CCAAT-Enhancer-Binding Proteins
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Cell Survival
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Glucose
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Glucose Transport Proteins, Facilitative
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Glycogen
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Hyperglycemia
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Hyperplasia
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Insulin
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Obesity
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Peroxisomes
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Phosphotransferases
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Proto-Oncogene Proteins c-akt
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Receptor, Insulin
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Thymidine
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Toll-Like Receptor 4
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Tumor Necrosis Factor-alpha
3.Role of STAT3 Phosphorylation in Ethanol-Mediated Proliferation of Breast Cancer Cells.
Poornima Devi NARAYANAN ; Sangeetha Kadapakkam NANDABALAN ; Lakshmi Subhadra BADDIREDDI
Journal of Breast Cancer 2016;19(2):122-132
PURPOSE: In this study, we investigated the molecular mechanism involved in ethanol (EtOH)-mediated proliferation of breast cancer cells. METHODS: EtOH concentration was optimized by studying its effect on cell proliferation in MCF-7 and MDA MB-231 cells. We used flow cytometry and immunoblot analysis to evaluate the increased proliferation caused by the optimized concentrations of EtOH. The mechanism of EtOH-mediated proliferation was determined using reactive oxygen species (ROS) release assay, reverse transcription polymerase chain reaction, and immunoblot studies. Gene silencing followed by quantitative real-time polymerase chain reaction studies and inhibitor studies indicated the involvement of signal transducer and activator of transcription 3 (STAT3) in EtOH-mediated breast cancer proliferation. RESULTS: Exposure to EtOH caused an increase in cell proliferation and an accumulation of cells in S-phase in MCF-7 (347 µM EtOH) and MDA MB-231 (173 µM EtOH) cells. Additionally, increased release of ROS and the expression of pro-inflammatory cytokines, such as interleukin 6 and tumor necrosis factor α, confirmed that the proliferation was induced by the ROS-linked inflammatory response in breast cancer. The proinflammatory response was followed by phosphorylation of STAT3. The importance of STAT3 activation in EtOH-mediated proliferation was confirmed through the silencing of STAT3, followed by an investigation on the expression of cyclins and matrix metalloproteinases. Finally, studies using specific inhibitors indicated that the EtOH-mediated effect on STAT3 activation could be regulated by phosphoinositide-3-kinase and Janus kinase 2. CONCLUSION: The study demonstrates the involvement of STAT3 signaling in EtOH-mediated breast cancer proliferation.
Breast Neoplasms*
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Breast*
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Cell Proliferation
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Cyclins
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Cytokines
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Ethanol
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Flow Cytometry
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Gene Silencing
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Inflammation
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Interleukin-6
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Janus Kinase 2
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Matrix Metalloproteinases
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Phosphorylation*
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Polymerase Chain Reaction
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Reactive Oxygen Species
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Real-Time Polymerase Chain Reaction
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Reverse Transcription
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STAT3 Transcription Factor
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Tumor Necrosis Factor-alpha