Single-cell RNA sequencing dissects the immunosuppressive signatures in Helicobacter pylori-infected human gastric ecosystem
Wei Hu, Ze Min Chen, Ying Wang, Chao Yang, Zehua Wu, You Li, Zhi Yong Zhai, Zhao Yu Huang, Ping Zhou, Si Lin Huang, Xia Xi Li, Gen Hua Yang, Chong Bao, Xiao Cui, Gui Li Xia, Mei Ping Ou Yang, Lin Zhang, William Ka Kei Wu, Long Fei Li, Li Tan, Yu Xuan Zhang, Wei Gong
Abstract
Helicobacter pylori (H. pylori) manipulates the host immune system to establish a persistent colonization, posing a serious threat to human health, but the mechanisms remain poorly understood. Here we integrate single-cell RNA sequencing and TCR profiling for analyzing 187,192 cells from 11 H. pylori-negative and 12 H. pylori-positive individuals to describe the human gastric ecosystem reprogrammed by H. pylori infection, as manifested by impaired antigen presentation and phagocytosis function. We further delineate a monocyte-to-C1QC+ macrophage differentiation trajectory driven by H. pylori infection, while T cell responses exhibit broad functional impairment and hyporesponsiveness with restricted clonal expansion capacity. We also identify an HLA-DRs- and CTLA4-expressing T cell population residing in H. pylori-inhabited stomach that potentially contribute to immune evasion. Together, our findings provide single-cell resolution information into the immunosuppressive microenvironment shaped by H. pylori infection, offering critical insights for developing novel therapeutic approaches to eliminate this globally prevalent pathogen. Helicobacter pylori (H. pylori) establishes chronic infection in human, but the underlying mechanistic insights are lacking. Here the authors use single cell RNA and TCR sequencing to profile peripheral blood and mucosal cells from infected patients to report alterations in macrophage differentiation and T cell gene signature that may contribute to persisting H. pylori infection.