The activation of mostly quiescent haematopoietic stem cells (HSCs) is a prerequisite for life-long production of blood cells
. This process requires major molecular adaptations to allow HSCs to meet ...the regulatory and metabolic requirements for cell division
. The mechanisms that govern cellular reprograming upon stem-cell activation, and the subsequent return of stem cells to quiescence, have not been fully characterized. Here we show that chaperone-mediated autophagy (CMA)
, a selective form of lysosomal protein degradation, is involved in sustaining HSC function in adult mice. CMA is required for protein quality control in stem cells and for the upregulation of fatty acid metabolism upon HSC activation. We find that CMA activity in HSCs decreases with age and show that genetic or pharmacological activation of CMA can restore the functionality of old mouse and human HSCs. Together, our findings provide mechanistic insights into a role for CMA in sustaining quality control, appropriate energetics and overall long-term HSC function. Our work suggests that CMA may be a promising therapeutic target for enhancing HSC function in conditions such as ageing or stem-cell transplantation.
Mechanisms governing the maintenance of blood-producing hematopoietic stem and multipotent progenitor cells (HSPCs) are incompletely understood, particularly those regulating fate, ensuring long-term ...maintenance, and preventing aging-associated stem cell dysfunction. We uncovered a role for transitory free cytoplasmic iron as a rheostat for adult stem cell fate control. We found that HSPCs harbor comparatively small amounts of free iron and show the activation of a conserved molecular response to limited iron—particularly during mitosis. To study the functional and molecular consequences of iron restriction, we developed models allowing for transient iron bioavailability limitation and combined single-molecule RNA quantification, metabolomics, and single-cell transcriptomic analyses with functional studies. Our data reveal that the activation of the limited iron response triggers coordinated metabolic and epigenetic events, establishing stemness-conferring gene regulation. Notably, we find that aging-associated cytoplasmic iron loading reversibly attenuates iron-dependent cell fate control, explicating intervention strategies for dysfunctional aged stem cells.
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•Quiescent HSCs strongly restrict their pool of cytoplasmic labile iron•Regenerating HSCs activate iron homeostasis pathways•Iron homeostasis is functionalized for stem cell fate determination and relies on Tip60•Reversible modest iron loading drives the functional decline of aging HSCs
The preservation of adult stem cell identity following cell division is essential for sustained tissue maintenance and repair. Will, Kao, and colleagues identify iron as a crucial regulator allowing hematopoietic stem cells to orchestrate metabolic and gene regulatory control during regenerative fate determination.
Bone marrow resident and rarely dividing hematopoietic stem cells (HSC) harbor an extensive self-renewal capacity to sustain life-long blood formation, albeit their function declines during ageing. ...Various molecular mechanisms confer stem cell identity, ensure long-term maintenance and are known to be deregulated in aged stem cells. How these programs are coordinated, particularly during cell division, and what triggers their ageing-associated dysfunction has been unknown.
We have previously uncovered that iron chelator exposure increases the number of functional HSC ex vivo and in vivo (Kao et al., Science Transl Med 2018). While ensuring a sufficient amount of redox active, readily available iron which is required in numerous electron transfer reactions governing fundamental cellular processes, cells tightly regulate the size of the intracellular labile iron pool (LIP) to limit adverse ROS generation. Perturbations in the ability to limit intracellular iron is detrimental for cells and known to compromise HSC maintenance and function via altered redox signaling and increased macromolecule oxidation and damage. The HSC stimulatory effects of iron chelator (IC) treatment and the well characterized central roles of redox active intracellular iron in sustaining basic cell function prompted us to examine a potential regulatory role of the LIP in controlling somatic stem cell function.
In this study, we quantified LIP in young and aged HSC and monitored iron homoeostasis pathway activation, hallmarked by the stabilization of transferrin receptor (Tfrc) mRNA, in stem cells for which we developed a single molecule RNA fluorescence in situ hybridization (smRNA FISH) assay enabling the quantification of Tfrc dynamics with unparalleled resolution and sensitivity. We have further used experimental LIP modulation in primary hematopoietic stem cell models to characterize the consequences of iron homeostasis pathway activation in young and aged stem cells; and employed integrated comparative quantitative transcriptomics (single cell RNA-seq) and proteomics along with genetic and pharmacological rescue models to identify the consequences and mechanisms of LIP size alterations. Our findings demonstrate that HSC, containing the lowest amount of cytoplasmic chelatable iron hematopoietic cells, activate a limited iron response during mitosis. Engagement of this iron homeostasis pathway elicits mobilization and β-oxidation of arachidonic acid and enhances stem cell-defining transcriptional programs governed by histone acetyl transferase Tip60/KAT5. We further find an age-associated expansion of the labile iron pool, along with loss of Tip60/KAT5-dependent gene regulation to contribute to the functional decline of ageing HSC, which can be mitigated by iron chelation.
Together, our work reveals cytoplasmic redox active iron as a novel rheostat in adult stem cells; it demonstrates a role for the intracellular labile iron pool in coordinating a cascade of molecular events which reinforces HSC identity during cell division and to drive stem cell ageing when perturbed. As loss of iron homeostasis is commonly observed in the elderly, we anticipate these findings to trigger further studies into understanding and therapeutic mitigation of labile iron pool-dependent hematopoietic stem cell dysfunction in a wide range of degenerative and malignant hematologic pathologies.
D'Alessandro: Omix Thecnologies: Other: Co-founder; Rubius Therapeutics: Consultancy; Forma Therapeutics: Membership on an entity's Board of Directors or advisory committees.
Cytosine hypermethylation in and around DNA-binding sites of master transcription factors, including PU.1, occurs in aging hematopoietic stem cells following acquired loss-of-function mutations of ...DNA methyl-cytosine dioxygenase ten-eleven translocation-2 (TET2), albeit functional relevance has been unclear. We show that Tet2-deficient mouse hematopoietic stem and progenitor cells undergo malignant transformation upon compromised gene regulation through heterozygous deletion of an upstream regulatory region (UREΔ/WT) of the PU.1 gene. Although compatible with multilineage blood formation at young age, Tet2-deficient PU.1 UREΔ/WT mice develop highly penetrant, transplantable acute myeloid leukemia (AML) during aging. Leukemic stem and progenitor cells show hypermethylation at putative PU.1-binding sites, fail to activate myeloid enhancers, and are hallmarked by a signature of genes with impaired expression shared with human AML. Our study demonstrates that Tet2 and PU.1 jointly suppress leukemogenesis and uncovers a methylation-sensitive PU.1-dependent gene network as a unifying molecular vulnerability associated with AML.
We identify moderately impaired PU.1 mRNA expression as a biological modality predisposing Tet2-deficient hematopoietic stem and progenitor cells to malignant transformation. Our study furthermore uncovers a methylation-sensitive PU.1 gene network as a common feature of myeloid leukemia potentially allowing for the identification of patients at risk for malignant transformation. See related commentary by Schleicher and Pietras, p. 378. This article is highlighted in the In This Issue feature, p. 369.