<p>Engineered probiotics are considered effective and safe therapeutic strategies for the treatment of various diseases. <i>Escherichia coli</i> Nissle 1917 (EcN) has been widely used as a chassis strain because of its safety and well-established genetic manipulation system. However, the limited intestinal colonization ability of EcN limits its potential as a chassis for the construction of synthetic probiotics. Here, an engineered EcN strain (EcN-CPM) with enhanced gastric acid and bile salt tolerance and improved intestinal adhesion was constructed. Oral administration of EcN-CPM to mice with colitis alleviated disease severity and reshaped the disordered gut microbiome by decreasing the abundance of <i>Escherichia-Shigella</i> while increasing the abundance of <i>norank_f_Muribaculaceae</i>. Mechanistically, the EcN-CPM supernatant directly promoted the proliferation of <i>norank_f_Muribaculaceae</i>, a short-chain fatty acid (SCFA)-producing genus. Targeted metabolomics revealed that EcN-CPM restored the DSS-induced depletion of SCFAs, which were negatively correlated with the abundance of <i>Escherichia-Shigella</i> and positively correlated with the abundance of <i>norank_f_Muribaculaceae</i>. Consistent with these findings, EcN-CPM treatment upregulated the expression of Treg-associated markers (<i>Foxp3</i>, <i>Ctla4</i>, and <i>Cd25</i>) and downregulated the expression of Th17-related genes (<i>IL-17A</i> and <i>Roryt</i>) in colonic tissues, restoring the IL-17A/Foxp3 ratio to homeostasis. Untargeted metabolomics further demonstrated that EcN-CPM uniquely restored the levels of seven anti-inflammatory metabolites depleted by DSS treatment. Collectively, these findings demonstrate that EcN-CPM alleviates intestinal inflammation by remodeling the gut microbiota to increase the production of SCFAs and anti-inflammatory metabolites, thereby driving a shift in Th17- and Treg-associated transcriptional signatures. This study establishes a platform for precision-designed synthetic probiotics with enhanced probiotic properties.</p>

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Construction of an engineered Escherichia coli strain with enhanced intestinal colonization and anti-inflammatory efficacy in colitis

  • Peijun Yu,
  • Wenjing Zhou,
  • Chunyang Li,
  • Qiang Sun,
  • Yunpeng Yang

摘要

Engineered probiotics are considered effective and safe therapeutic strategies for the treatment of various diseases. Escherichia coli Nissle 1917 (EcN) has been widely used as a chassis strain because of its safety and well-established genetic manipulation system. However, the limited intestinal colonization ability of EcN limits its potential as a chassis for the construction of synthetic probiotics. Here, an engineered EcN strain (EcN-CPM) with enhanced gastric acid and bile salt tolerance and improved intestinal adhesion was constructed. Oral administration of EcN-CPM to mice with colitis alleviated disease severity and reshaped the disordered gut microbiome by decreasing the abundance of Escherichia-Shigella while increasing the abundance of norank_f_Muribaculaceae. Mechanistically, the EcN-CPM supernatant directly promoted the proliferation of norank_f_Muribaculaceae, a short-chain fatty acid (SCFA)-producing genus. Targeted metabolomics revealed that EcN-CPM restored the DSS-induced depletion of SCFAs, which were negatively correlated with the abundance of Escherichia-Shigella and positively correlated with the abundance of norank_f_Muribaculaceae. Consistent with these findings, EcN-CPM treatment upregulated the expression of Treg-associated markers (Foxp3, Ctla4, and Cd25) and downregulated the expression of Th17-related genes (IL-17A and Roryt) in colonic tissues, restoring the IL-17A/Foxp3 ratio to homeostasis. Untargeted metabolomics further demonstrated that EcN-CPM uniquely restored the levels of seven anti-inflammatory metabolites depleted by DSS treatment. Collectively, these findings demonstrate that EcN-CPM alleviates intestinal inflammation by remodeling the gut microbiota to increase the production of SCFAs and anti-inflammatory metabolites, thereby driving a shift in Th17- and Treg-associated transcriptional signatures. This study establishes a platform for precision-designed synthetic probiotics with enhanced probiotic properties.