Abstract
The mucus layer in the intestine affects several aspects of intestinal biology, encompassing physical, chemical protection, immunomodulation and growth, thus contributing to homeostasis. Mice with genetic inactivation of the Muc2 gene, encoding the MUC2 mucin, the major protein component of mucus, exhibit altered intestinal homeostasis, which is strictly dependent on the habitat, likely due to differing complements of intestinal microbes. Our previous work established that Muc2 deficiency was linked to low chronic inflammation resulting in tumor development in the small, large intestine including the rectum. Here, we report that inactivation of Muc2 alters metabolic pathways in the normal appearing mucosa of Muc2−/− mice. Comparative analysis of gene expression profiling of isolated intestinal epithelial cells (IECs) and the entire intestinal mucosa, encompassing IECs, immune and stromal cells underscored that more than 50% of the changes were common to both sets of data, suggesting that most alterations were IEC-specific. IEC-specific expression data highlighted perturbation of lipid absorption, processing and catabolism linked to altered Pparα signaling in IECs. Concomitantly, alterations of glucose metabolism induced expression of genes linked to de novo lipogenesis, a characteristic of tumor cells. Importantly, gene expression alterations characterizing Muc2−/− IECs are similar to those observed when analyzing the gene expression signature of IECs along the crypt-villus axis in WT B6 mice, suggesting that Muc2−/− IECs display a crypt-like gene expression signature. Thus, our data strongly suggest that decreased lipid metabolism, and alterations in glucose utilization characterize the crypt proliferative compartment, and may represent a molecular signature of pre-neoplastic lesions.
Highlights
A unique set of rules has evolved to control the potential constant stimulation of the intestinal immune system that could arise from the intestinal microbiota
These changes are all likely linked to the function of Muc2 as the major component of the mucus barrier, which, when compromised, can alter the intestinal microbiota and the interactions of these bacteria with the mucosa
Alterations of microbiota-epithelial cell interactions are indicated by the data here showing that there is increased number of ROS producing phagocytes in the stroma surrounding intestinal crypts, and upregulation of ROS producing enzymes expressed by intestinal epithelial cells (IECs) contributing to altered homeostasis
Summary
A unique set of rules has evolved to control the potential constant stimulation of the intestinal immune system that could arise from the intestinal microbiota. A key component modulating the conversation between the mucosa and the vast population of bacteria that inhabit the large intestine is the thick mucus layer that provides a physical separation between the epithelial cell monolayer and the luminal contents. This mucus layer provides a chemical and biochemical barrier that supports the structure of the mucus gel, as well as the ability of the gel to concentrate biological factors secreted by mucosal epithelial cells (reviewed in [1]). Compromising the integrity of the mucus barrier has profound effects on the functioning and homeostasis of the intestinal mucosa
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
