P064 Investigating the genotoxic effect of reduced glutathione, n-acetylcysteine, human umbilical cord-derived mesenchymal stem cell exosomes and let-7 miRNA mimics in human lymphocytes and EpiIntestinal cells

Abstract

Abstract Background The current treatments for IBD frequently do not provide sufficient control over the disease, warranting the investigation of alternative therapeutic options with minimal risk of side effects. In IBD, the overgeneration and insufficient removal of reactive oxygen species (ROS) leads to oxidative stress. Reduced glutathione (GSH) and n-acetylcysteine (NAC) are antioxidants which may possess therapeutic potential in IBD, by modulating endogenous mechanisms that decrease ROS production or increase antioxidant enzymes. Additonally, exosomes from human umbilical cord blood derived mesenchymal stem cells (hucMSCs-exo) may be used to treat IBD. These are a subset of extracellular nanosized membrane vesicles which participate in intercellular communication by delivering their contents, such as functional miRNAs to recipient cells, thereby influencing the physiological and pathological processes in various diseases. The therapeutic potential of exosomes can be enhanced through the overexpression of the let-7 family of miRNAs. Methods The EpiIntestinal tissue model is a physiologically relevant predictor of drug-induced GI toxicity. EpiIntestinal cells and lymphocytes from 3 IBD patients were transfected with 50 μL miRNA mimics and inhibitors, and treated with 50μL hucMSC-exo, and 50 μL 1mM GSH and NAC. Next, in comparison to negative controls, single-stranded DNA damage was assessed in peripheral blood mononuclear cells (PBMCs) from IBD patients using the fast microplate DNA damage assay, and double-stranded DNA damage was assessed in EpiIntestinal cells using the alkaline Comet assay. In addition, the viability of healthy and IBD lymphocytes was assessed following treatment with selected concentrations of hucMSC-exo, GSH and NAC. Results Double-stranded DNA damage was significantly reduced in EpiIntestinal cells compared to the negative control following treatment with hucMSC-exo, GSH, NAC, and miRNA mimics for let-7a-5p, -7b-5p, -7c-3p, -7d-3p and -7d-5p. In addition, single-stranded DNA damage was reduced in IBD PBMCs compared to the negative control following treatment with hucMSC-exo, and let-7b-5p and -7c-3p mimics, but was increased following treatment with inhibitors for let-7b-5p, -7c-5p and two novel miRNAs. Additionally, GSH, NAC and hucMSC-exo increased cell viability in treated versus untreated lymphocytes from healthy individuals and IBD patients. Conclusion Selected concentrations of HucMSC-exo, GSH, NAC and/or let-7 miRNA mimics reduced DNA damage and increased cell viability in treated versus untreated cells which may reduce the risk of colorectal cancer in IBD patients. Acknowledgements Our gratitude goes to the MatTek Team for generously granting us a SMI-100-FT EpiIntestinal kit in support of this research.