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The long-term maintenance of hematopoietic stem cells (HSCs) relies on the regulation of endoplasmic reticulum (ER) stress at a low level, but the underlying mechanism remains poorly understood. Here, we demonstrate that suppression of ER stress improves the functions of HSCs and protects HSCs against ionizing radiation (IR)-induced injury. We identify epithelial membrane protein 1 (EMP1) as a key regulator that mitigates ER stress in HSCs. Emp1 deficiency leads to the accumulation of protein aggregates and elevated ER stress, ultimately resulting in impaired HSC maintenance and self-renewal. Mechanistically, EMP1 is located within the ER and interacts with ceramide synthase 2 (CERS2) to limit the production of a class of sphingolipids, dihydroceramides (dhCers). DhCers accumulate in Emp1-deficient HSCs and induce protein aggregation. Furthermore, Emp1 deficiency renders HSCs more susceptible to IR, while overexpression of Emp1 or inhibition of CERS2 protects HSCs against IR-induced injury. These findings highlight the critical role played by the EMP1-CERS2-dhCers axis in constraining ER stress and preserving HSC potential. A new study shows EMP1 protects hematopoietic stem cells by suppressing sphingolipid metabolism and ER stress. EMP1 interacts with CERS2 to limit dihydroceramide production, which causes protein aggregation when elevated.

GATA2 germline mutations lead to a syndrome characterized by immunodeficiency, vascular disorders and myeloid malignancies. To elucidate how these mutations affect hematopoietic homeostasis, we created a knock-in mouse model expressing the recurrent Gata2 R396Q missense mutation. Employing molecular and functional approaches, we investigated the mutation’s impact on hematopoiesis, revealing significant alterations in the hematopoietic stem and progenitor (HSPC) compartment in young age. These include increased LT-HSC numbers, reduced self-renewal potential, and impaired response to acute inflammatory stimuli. The mature HSPC compartment was primarily affected at the CMP sub-population level. In the mutant LT-HSC population, we identified an aberrant subpopulation strongly expressing CD150, resembling aging, but occurring prematurely. This population showed hyporesponsiveness, accumulated over time, and exhibited allele-specific expression (ASE) favoring the mutated Gata2 allele, also observed in GATA2 mutated patients. Our findings reveal the detrimental impact of a Gata2 recurrent missense mutation on the HSC compartment contributing to its functional decline. Defects in the CMP mature compartment, along with the inflammatory molecular signature, explain the loss of heterogeneity in HPC compartment observed in patients. Finally, our study provides a valuable model that recapitulates the ASE-related pathology observed in GATA2 deficiency, shedding light on the mechanisms contributing to the disease’s natural progression.

The development of hematopoietic cell lineages is a highly complex process governed by a delicate interplay of various transcription factors. The expression of these factors is influenced, in part, by epigenetic signatures that define each stage of cell differentiation. In particular, the formation of B lymphocytes depends on the sequential silencing of stemness genes and the balanced expression of interdependent transcription factors, along with DNA rearrangement. We have investigated the impact of Dido3 deficiency, a protein involved in chromatin status readout, on B cell differentiation within the hematopoietic compartment of mice. Our findings revealed significant impairments in the successive stages of B cell development. The absence of Dido3 resulted in remarkable alterations in the expression of essential transcription factors and differentiation markers, which are crucial for orchestrating the differentiation process. Additionally, the somatic recombination process, responsible for generation of antigen receptor diversity, was also adversely affected. These observations highlight the vital role of epigenetic regulation, particularly the involvement of Dido3, in ensuring proper B cell differentiation. This study reveals new mechanisms underlying disruptive alterations, deepening our understanding of hematopoiesis and may potentially lead to insights that aid in the development of therapeutic interventions for disorders involving aberrant B cell development.Supplementary InformationThe online version contains supplementary material available at 10.1186/s13578-025-01394-x.