Project description:Antifibrotic effect of metformin in the lung

Project description:This experiment includes treatment of human pulmonary fibroblasts obtained from IPF patients with metformin. Since, we would like to investigate the transcriptome profile of these samples following metformin treatment. There will be two groups consist of four samples each. First group treated with metformin for 72 hours, while the second group treated with vehicle.

Project description:Effect of metformin (50mg/kg,400mg/kg) on gene expression in livers of db/db mice.

Project description:Proteomics was used to explore the effect of metformin on the neural differentiation of gingival mesenchymal stem cells in three-dimensional culture.

Project description:Metformin is first line treatment for type 2 diabetes, however its exact mechanisms remain incompletely understood. Furthermore, the role of glucose transporter in intestine are highlighted to investigate metabolic change. We here report RNA change after metformin treatment in ileum tissue. We are going to focus on change of glucose transporter and relate factor of those changes. In previous study metformin increases expression of GLUT1/GLUT2 in ileum and metformin plays role as complex1 inhibitor so we are going to find target of metformin-induced glucose metabolic increasment

Project description:Here, we report that Metformin shows a striking synergistic effect with Gilteritinib in suppressing cell proliferation and promoting apoptosis and cell cycle arrest in multiple FLT3-ITD AML cell lines, including FLT3 TKI-resistant MOLM13 cells. Mechanistically, the combinational treatment synergistically suppresses Polo-like kinase 1 (PLK1) expression and phosphorylation of FLT3/STAT5/ERK/mTOR in MOLM13-RES cells. Intriguingly, our retrospective clinical analysis has unveiled a significant correlation between Metformin intake and improved survival rates among FLT3-ITD AML patients. Collectively, the cotreatment of Metformin and Gilteritinib shows robustly enhanced therapeutic efficacy in treating FLT3-mutated AML by synergistically suppressing PLK1 expression and phosphorylation of FLT3/STAT5/ERK/mTOR.

Project description:To examine the effect of metformin on lung cancer biology, human lung H226 and H1299 squamous cell carcinoma cell-lines were grown in RPMI-1640 medium with 10% v/v fetal bovine serum and with or without 15 uM metformin hydrochloride for 7-8 days. Medium (with any metformin) was replaced every two days. Paired cultures with and without metformin were grown and maintained in parallel. Three separate paired cultures, all seeded with same stock of frozen cells, were grown.

Project description:Effect of metformin in the mouse ileum gene expression

Project description:Investigate the effect of 1.0 mM Metformin on CD4 T cells from Systemic Lupus Patients and compare to Healthy Control CD4 T cells

Project description:Metformin rejuvenates adult rat oligodendrocyte progenitor cells (OPCs) allowing more efficient differentiation into oligodendrocytes and improved remyelination of CNS axons and therefore is of interest as a possible therapeutic in demyelinating diseases such as multiple sclerosis (MS). We set out to test whether metformin had a similar effect in human stem cell derived-OPCs. We assessed the suitability of human monoculture, organoid and transplantation into immunodeficient mice (chimera model) culture systems in simulating in vivo adult human oligodendrocytes, finding most close resemblance in the chimera model. Metformin increased myelin proteins and/or sheaths in all models even when human cells had fetal signatures. In the chimera model, metformin led to a marked increase in mitochondrial area both in the human transplanted cells and in the mouse axons with associated increase in transcripts related to mitochondrial function and metabolism. Human oligodendrocytes from MS brain donors treated pre-mortem with metformin also expressed similar transcripts suggesting that metformin’s brain effect is not cell-specific, altering metabolism in both oligodendrocytes and axons leading to more myelin production, in part through mitochondrial changes. This bodes well for ongoing clinical trials testing metformin for neuroprotection.