Abstract
Clonal hematopoiesis (CH) increases with age and is associated with severe outcome in the course of infections or tumor development. Understanding the environmental conditions that favor mutant clones and the CH-immune system response to such environments is key to designing therapeutic strategies to stall the expansion of mutant clones and the development of CH-associated pathologies. Using human cells, we unravel a cell-specific and opposite impact of TET2 mutations on hematopoietic stem and progenitor cells (HSPC) compared to their myeloid progeny. Multi-omic analyses reveal that TET2-mutant HSPCs exhibit intrinsic epigenetic silencing of AP-1 transcription factors and a blunted transcriptional adaptation to systemic inflammation. Conversely, monocyte-macrophage trajectory derived from TET2Mut HSCs contributes to exacerbated inflammation. Together, these findings reconcile how TET2-mutant CH can simultaneously promote increased stemness within the HSPC compartment and heightened inflammation through its myeloid progeny, providing mechanistic insight into how TET2-CH expands under inflammatory stress.