Abstract
Intestinal epithelial cells form a selectively permeable barrier to protect colon tissues from luminal microbiota and antigens and to mediate nutrient, fluid, and waste flux in the intestinal tract. Dysregulation of the epithelial cell barrier coincides with profound shifts in metabolic energy, especially in the colon, which exists in an energetically depleting state of physiological hypoxia. However, studies that systematically examine energy flux and adenylate metabolism during intestinal epithelial barrier development and restoration after disruption are lacking. Here, to delineate barrier-related energy flux, we developed an HPLC-based profiling method to track changes in energy flux and adenylate metabolites during barrier development and restoration. Cultured epithelia exhibited pooling of phosphocreatine and maintained ATP during barrier development. EDTA-induced epithelial barrier disruption revealed that hypoxanthine levels correlated with barrier resistance. Further studies uncovered that hypoxanthine supplementation improves barrier function and wound healing and that hypoxanthine appears to do so by increasing intracellular ATP, which improved cytoskeletal G- to F-actin polymerization. Hypoxanthine supplementation increased the adenylate energy charge in the murine colon, indicating potential to regulate adenylate energy charge-mediated metabolism in intestinal epithelial cells. Moreover, experiments in a murine colitis model disclosed that hypoxanthine loss during active inflammation correlates with markers of disease severity. In summary, our results indicate that hypoxanthine modulates energy metabolism in intestinal epithelial cells and is critical for intestinal barrier function.
Highlights
The primary functions of intestinal epithelial cells (IECs)2 are to form a selectively permeable barrier to protect the tissue
We previously identified a family of genes involved in creatine metabolism that are coordinately regulated by the transcription factor hypoxiainducible factor (HIF) [9]
Subcellular localization of creatine kinase (CK) isoforms revealed coupling to the apical junctional complex (AJC), with CK inhibition attenuating junctional assembly and barrier funcresistance; TAE, total available energy; Allo, allopurinol; PNP, purine nucleoside phosphorylase; 2-DOG, 2-deoxy-D-glucose; AEC, adenylate energy charge; DSS, dextran sulfate sodium; HBSS, Hanks’ balanced salt solution
Summary
Despite these observations, studies that systematically examine energy flux and adenylate metabolism during intestinal epithelial barrier development and restoration after disruption are lacking. To delineate barrier-related adenylate energy flux, we developed an HPLC-based profiling method to characterize changes in high-energy phosphates and associated adenylate metabolites. We identified an ability in IECs to maintain ATP and pool phosphocreatine during barrier development that associated with the accumulation of downstream adenylate metabolites. Extensions of these studies with models of barrier stress identified a capacity for hypoxanthine (Hpx) to promote epithelial cellular function through improving cellular energetics and cytoskeletal capability. The work contained identifies Hpx as a central metabolite in IEC function
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