Project description:Hematopoietic stem cells (HSCs) with certain somatic mutations, most commonly in the DNA methyltransferase DNMT3A, gain a clonal growth advantage leading to the development of clonal hematopoiesis (CH). The distinct functional differences that allow DNMT3A-mutant HSCs to gain a fitness advantage and outcompete wild-type HSC in the context of aging are not fully elucidated. We recently discovered that HSC aging is initiated by decline in local production of insulin-like growth factor 1 (IGF1). Here, we used a mouse model of DNMT3A-mutant CH (Dnmt3aR878H/+) to investigate the extent to which decline in IGF1 alters the selective advantage of Dnmt3aR878H/+ HSCs. Upon transplant into IGF1-deficient recipient mice, Dnmt3aR878H/+ HSCs gained enhanced selective advantage over wild-type HSCs and maintained lineage balanced blood production. As IGF1/mTOR signaling is well understood to regulate energy metabolism, we investigated underlying metabolic differences between Dnmt3aR878H/+ and wild-type HSCs. Dnmt3aR878H/+ HSPCs had similar glycolytic capacity as wild-type HSCs but enhanced mitochondrial reserve capacity and mitochondrial activation potential. To evaluate whether mitochondrial function is a targetable dependency of Dnmt3aR878H/+ HSCs, we administered the mitochondrial-targeted molecule MitoQ resulting in the depletion of their mitochondrial reserve capacity. We find that MitoQ reduces the competitive advantage of Dnmt3aR878H/+ hematopoiesis. To identify the mechanism(s) by which MitoQ alters Dnmt3aR878H/+ phenotypic expansion we evaluated transcriptional changes after MitoQ treatment and find altered response to Igf1/mTOR signaling compared to wild-type HSC. The altered response to Igf1/mTOR signaling in part mediates the Dnmt3aR878H/+ hematopoietic selective advantage. Taken together, our work supports that mitochondrial metabolic regulation is a key mechanism by which DNMT3A-mutant HSCs gain a selective advantage. Targeting this mechanism may maintain polyclonal hematopoiesis during aging and reduce the risk of CH-associated disease.

Project description:Driver somatic mutations in adult acute myeloid leukemia (AML) are often preceded by a benign or premalignant state termed clonal hematopoiesis (CH) for which the greatest risk factor is aging. To risk-stratify aged individuals and develop therapies to prevent AML, we need to understand the variables that promote transformation from CH to AML. Using our orthogonally inducible Dnmt3aR878H;Npm1cA-mutant model of progression from CH to myeloid malignancy, we find that in young mice, Dnmt3a mutation buffers against myeloid differentiation, proliferation, acquisition of cooperating mutations and transformation induced by stress, inflammation, and the oncogenic Npm1 mutation. However, when Dnmt3a;Npm1-mutant hematopoietic stem cells (HSCs) are transplanted into naturally aged recipient mice, they gain myeloid-biased differentiation capacity and have an accelerated transformation to AML. These results support the hypothesis that alterations in the aged microenvironment drive risk of AML in individuals with CH and help to explain why this Dnmt3a mutation is exceedingly rare in pediatric leukemias.

Project description:Somatic mutations of ASXL1 are frequently detected in age-related clonal hematopoiesis (CH). However, how ASXL1 mutations drive CH remains elusive. Using knockin (KI) mice expressing a C-terminally truncated form of ASXL1-mutant (ASXL1-MT), we examined the influence of ASXL1-MT on physiological aging in hematopoietic stem cells (HSCs). HSCs expressing ASXL1-MT display competitive disadvantage after transplantation. Nevertheless, in genetic mosaic mouse model, they acquire clonal advantage during aging, recapitulating CH in humans. Mechanistically, ASXL1-MT cooperates with BAP1 to deubiquitinate and activate AKT. Overactive Akt/mTOR signaling induced by ASXL1-MT results in aberrant proliferation and dysfunction of HSCs associated with age-related accumulation of DNA damage. Treatment with an mTOR inhibitor rapamycin ameliorates aberrant expansion of the HSC compartment as well as dysregulated hematopoiesis in aged ASXL1-MT KI mice. Our findings suggest that ASXL1-MT provokes dysfunction of HSCs, whereas it confers clonal advantage on HSCs over time, leading to the development of CH.

Project description:Driver somatic mutations in adult acute myeloid leukemia (AML) may be preceded by a benign state termed clonal hematopoiesis (CH). To develop therapeutic strategies to prevent leukemia development from CH, it is important to understand the mechanisms by which CH-driving and AML-driving mutations cooperate. Here, we utilize mice with inducible mutant alleles common in CH (DNMT3AR882; mouse Dnmt3aR878H/+) and AML (NPM1c; mouse Npm1cA/+). We find that Dnmt3aR878H/+ hematopoietic stem cells (HSCs), but not multipotent progenitor cell (MPP) subsets, have reduced expression of cytokine and pro-inflammatory transcriptional signatures and a functional competitive advantage over their wild-type counterparts. These Dnmt3aR878H/+ HSCs are transformed by activation of Npm1cA/+, generating myeloid malignancies in which few additional cooperating somatic mutation events were detected. At a molecular level, Npm1cA/+ acutely increased accessibility of a distinct set of promoters in cooperation with Dnmt3aR878H/+ than it did as a single mutation. These promoters were enriched for pro-inflammatory response signatures, p53 pathway, DNA repair and targets of transcription factors implicated in AML, including Hmgb1 and Pax4. These results suggest cooperativity between pre-existing Dnmt3a mutation and Npm1 mutation at the chromatin level, where specific loci altered in accessibility by the Npm1 mutation are dependent on Dnmt3a mutation status. These findings have implications for biological understanding and therapeutic intervention of the transformation from CH to AML.

Project description:In the aging hematopoietic system, blood cell production becomes dominated by a limited number of hematopoietic stem cell (HSC) clones. While somatic mutations in the de novo DNA methyltransferase 3A (DNMT3A) frequently drive clone dominance, the aging milieu also likely contributes to selection of variant HSCs. The detrimental impact of clonal hematopoiesis on organismal health is thought to be mediated by differentiated progeny of variant HSCs through mechanisms as yet poorly understood. Here, we examined the interaction between high fat diet (HFD) as an inflammatory stressor and a hematopoietic system haploinsufficient for DNMT3A. Strikingly, HFD accelerated weight gain in mice harboring bone marrow with reduced DNMT3A. Moreover, distal tissues of such mice including pancreas, adipose, and spleen, harbored high levels of mutant macrophages that impacted tissue function. Aberrant DNA methylation and pro-inflammatory transcriptional activation in mutant-derived myeloid cells correlated with increased IL-6 and TNFa signaling. Together, these findings identify synergism between HFD and DNMT3A haploinsufficiency that, through increased inflammatory myeloid cell functions, can contribute to deterioration in organismal health.

Project description:Accumulation of fatty bone marrow (FBM) is one of the key age related changes possibly influencing the blood system. While a link between obesity and cancer evolution has been reported it remains unknown whether FBM can modify the evolution of the early stages of leukemia and clonal hematopoiesis (CH). To address this question, we established different FBM mouse models in immunodeficient mice in whom we can study both mouse and human cells. We focused our studies on two FBM models: 1) after sublethal irradiation; 2) after castration; and in both we used an adipogenesis inhibitor as a control (PPARγ inhibitor). We transplanted both human and mice hematopoietic stem cells (HSCs) carrying DNMT3A mutations into immunodeficient mice with FBM. A significant increase in self-renewal was found when DNMT3AMut-HSCs were exposed to FBM. To better understand the mechanisms of the FBM-CH interaction, we performed single cell RNA-sequencing on HSPCs after FBM exposure in vivo. A 6-10 fold increase in DNMT3AMut-HSCs was observed under FBM conditions in comparison to normal bone marrow. Mutated HSCs from mice exposed to FBM exhibited an activated inflammatory signaling (IL-6 and IFNγ). Cytokine analysis of BM fluid and BM derived adipocytes grown in vitro demonstrated increased IL-6 levels under FBM conditions. Anti-IL-6 neutralizing antibodies significantly reduced the selective advantage of mice derived DNMT3AMut-HSCs exposed to FBM. Overall, paracrine FBM inflammatory signals promote DNMT3A-driven clonal hematopoiesis, which can be inhibited by blocking the IL-6 receptor.

Project description:Accumulation of fatty bone marrow (FBM) is one of the key age related changes possibly influencing the blood system. While a link between obesity and cancer evolution has been reported it remains unknown whether FBM can modify the evolution of the early stages of leukemia and clonal hematopoiesis (CH). To address this question, we established different FBM mouse models in immunodeficient mice in whom we can study both mouse and human cells. We focused our studies on two FBM models: 1) after sublethal irradiation; 2) after castration; and in both we used an adipogenesis inhibitor as a control (PPARγ inhibitor). We transplanted both human and mice hematopoietic stem cells (HSCs) carrying DNMT3A mutations into immunodeficient mice with FBM. A significant increase in self-renewal was found when DNMT3AMut-HSCs were exposed to FBM. To better understand the mechanisms of the FBM-CH interaction, we performed single cell RNA-sequencing on HSPCs after FBM exposure in vivo. A 6-10 fold increase in DNMT3AMut-HSCs was observed under FBM conditions in comparison to normal bone marrow. Mutated HSCs from mice exposed to FBM exhibited an activated inflammatory signaling (IL-6 and IFNγ). Cytokine analysis of BM fluid and BM derived adipocytes grown in vitro demonstrated increased IL-6 levels under FBM conditions. Anti-IL-6 neutralizing antibodies significantly reduced the selective advantage of mice derived DNMT3AMut-HSCs exposed to FBM. Overall, paracrine FBM inflammatory signals promote DNMT3A-driven clonal hematopoiesis, which can be inhibited by blocking the IL-6 receptor.

Project description:Accumulation of fatty bone marrow (FBM) is one of the key age related changes possibly influencing the blood system. While a link between obesity and cancer evolution has been reported it remains unknown whether FBM can modify the evolution of the early stages of leukemia and clonal hematopoiesis (CH). To address this question, we established different FBM mouse models in immunodeficient mice in whom we can study both mouse and human cells. We focused our studies on two FBM models: 1) after sublethal irradiation; 2) after castration; and in both we used an adipogenesis inhibitor as a control (PPARγ inhibitor). We transplanted both human and mice hematopoietic stem cells (HSCs) carrying DNMT3A mutations into immunodeficient mice with FBM. A significant increase in self-renewal was found when DNMT3AMut-HSCs were exposed to FBM. To better understand the mechanisms of the FBM-CH interaction, we performed single cell RNA-sequencing on HSPCs after FBM exposure in vivo. A 6-10 fold increase in DNMT3AMut-HSCs was observed under FBM conditions in comparison to normal bone marrow. Mutated HSCs from mice exposed to FBM exhibited an activated inflammatory signaling (IL-6 and IFNγ). Cytokine analysis of BM fluid and BM derived adipocytes grown in vitro demonstrated increased IL-6 levels under FBM conditions. Anti-IL-6 neutralizing antibodies significantly reduced the selective advantage of mice derived DNMT3AMut-HSCs exposed to FBM. Overall, paracrine FBM inflammatory signals promote DNMT3A-driven clonal hematopoiesis, which can be inhibited by blocking the IL-6 receptor.

Project description:Clonal hematopoiesis (CH) results from enhanced fitness of a mutant hematopoietic stem and progenitor cell (HSPC), but how such clones expand is unclear. Here, we developed a technique that combines mosaic mutagenesis with color labeling of HSPCs to study how acquired mutations affect clonal fitness in a native environment. Mutations in CH-associated genes, like asxl1, promoted clonal dominance. Single-cell transcriptional analysis revealed that mutations stimulated expression of proinflammatory genes in mature myeloid cells and anti-inflammatory genes in progenitor cells of the mutant clone. Biallelic loss of one such immunomodulator, nr4a1, abrogated the ability of asxl1-mutant clones to establish clonal dominance. These results support a model where clonal fitness of mutant clones is driven by enhanced resistance to inflammatory signals from their mutant mature cell progeny.

Project description:Clonal hematopoiesis (CH) results from enhanced fitness of a mutant hematopoietic stem and progenitor cell (HSPC), but how such clones expand is unclear. Here, we developed a technique that combines mosaic mutagenesis with color labeling of HSPCs to study how acquired mutations affect clonal fitness in a native environment. Mutations in CH-associated genes, like asxl1, promoted clonal dominance. Single-cell transcriptional analysis revealed that mutations stimulated expression of proinflammatory genes in mature myeloid cells and anti-inflammatory genes in progenitor cells of the mutant clone. Biallelic loss of one such immunomodulator, nr4a1, abrogated the ability of asxl1-mutant clones to establish clonal dominance. These results support a model where clonal fitness of mutant clones is driven by enhanced resistance to inflammatory signals from their mutant mature cell progeny.