Abstract
Hematopoietic stem cells require tight regulation to rapidly initiate emergency hematopoiesis in response to pathogens, but chronic activation leads to proliferation induced exhaustion. Timely reentry into quiescence after inflammatory stimuli is essential for long term sustained HSC maintenance. We identify IL-10R signaling, an established negative feedback regulator in mature myeloid cells, as critical for returning HSCs to quiescence. IL-10R blockade prolongs HSC cycling and sustains activated transcriptional programs after acute inflammation. With chronic exposure, blockade increases cumulative divisions and accelerates aging hallmarks, including myeloid bias, loss of polarity, and functional defects, under conditions that do not otherwise exhaust HSCs when IL-10R signaling is intact. Jak2 (V617F) mutant HSCs resist the aging acceleration induced by blockade. Consistent with this resistance, IL-10R blocking antibody promotes Jak2 (V617F) clonal expansion and augments the myeloproliferative neoplasm phenotype. Together, these findings identify IL-10R signaling as a key coordinator of post inflammatory return to quiescence and suggest that modulating this axis could preserve HSCs and shape clonal hematopoiesis. SUMMARY: Wadley et al. show that IL-10 receptor signaling restrains inflammation-induced hematopoietic stem cell cycling and exhaustion; its blockade prolongs cycling, accelerates aging-related decline, and selectively favors Jak2 (V617F) mutant HSCs, establishing IL-10 signaling as a critical regulator of inflammatory HSC exhaustion and malignant clonal evolution.