TRANSFER RNA QUEUOSINE MODIFICATION ENZYME MANIPULATES TIGHT JUNCTION PROTEINS IN INFLAMMATORY BOWEL DISEASE

Abstract

Abstract Background Transfer RNA (tRNA) queuosine (Q)-modification occur at the wobble anticodon position of four special cellular tRNAs. In eukaryotes, tRNA-Q modification relies on the intestinal microbial product queuine and eukaryotic tRNA-guanine transglycosylase complex contains of Q tRNA ribosyltransferase catalytic subunit 1 (QTRT1). Q-tRNA modification is critical for the fidelity and accuracy to translate RNA to protein. It is known that dysfunction of Q-tRNA associates with cancer proliferation and malignancy. However, mechanisms of how Q and Q-tRNA modifications influence intestinal epithelial biology and chronic inflammation are unknown. Methods We explored the expression of QTRT1 in patients with IBD by investigating human biopsy tissues and re-analyzing gene expression datasets (with both UC and CD patients). To further investigate the QTRT1 role in IBD, the dextran sodium sulfate (DSS) induced colitis mouse model and IL10-deficient mouse model were used to evaluate the molecular mechanism. We further investigated the impact of QTRT1 reduction on intestinal cells by generating QTRT1 knockdown HCT116 and Caco-2 BBE cells using a Double Nickase Plasmid. Results We found that the QTRT1 expression in IHC staining was significantly downregulated in the colon of both Ulcerative Colitis (UC) and Crohn’s Disease (CD) patients compared with normal controls. After extracting and analyzing the datasets, we found the gene expression of QTRT1 was significantly suppressed in colonic mucosa of UC and intestinal mucosa of CD, compared with controls. Moreover, the four tRNA-Q-related tRNA synthetase (asparaginyl-tRNA synthetase, aspartyl-tRNA synthetase, histidyl-tRNA synthetase and tyrosyl-tRNA synthetase) were also decreased in IBD patients. The decreased QTRT1-expression was further confirmed in both DSS-induced colitis mice and IL10-defecient mice. Meanwhile, the significantly downregulated beta-catenin and Claudin-5, and upregulated Caludin-2 were identified in these two colitis models. All these molecular alterations, which are important in cell adhesion and tight junction formation, were further verified in protein expression and mRNA level using QTRT1 reduction HCT116 and Caco-2 BBE cells in vitro. Conclusion Our results demonstrate that the QTRT1 plays a novel role in human IBD by altering intestinal cell adhesion and junctions. Microbiome-dependent Q supply can be altered during disease development or when a limited variety of food-types are ingested. Investigations on the gut microbiome-derived tRNA modification in IBD will uncover novel molecular mechanisms for potential prevention and therapy.