Project description:Pediatric cancers are increasingly linked to transformation events before birth, yet how ontogeny influences oncogenesis remains poorly understood. Using a humanized model of NUP98-NSD1-driven pediatric acute myeloid leukemia, particularly aggressive when accompanied by WT1 mutations, we investigated how the developmental stage of hematopoietic stem cells impacts leukemic transformation, disease progression and therapy response. Fetal-derived hematopoietic stem cells readily transform into leukemia, with WT1 mutations enhancing stemness and alter lineage hierarchy, while stem cells from later developmental stages progressively withstand transformation. Single-cell analyses revealed that fetal-origin versus postnatal leukemic stem cells exhibit greater quiescence and metabolic reliance on oxidative phosphorylation. Notably, therapeutic responses markedly differed between fetal- and postnatal-origin leukemias, even when driven by the same oncogenic mutations. In patients, onco-fetal transcriptional programs were associated with worse outcomes. We identified tailored combination therapies that specifically diminished aggressive fetal-origin leukemia, underscoring the need to consider ontogeny in treatment of pediatric cancers.

Project description:Pediatric cancers are increasingly linked to transformation events before birth, yet how ontogeny influences oncogenesis remains poorly understood. Using a humanized model of NUP98-NSD1-driven pediatric acute myeloid leukemia, particularly aggressive when accompanied by WT1 mutations, we investigated how the developmental stage of hematopoietic stem cells impacts leukemic transformation, disease progression and therapy response. Fetal-derived hematopoietic stem cells readily transform into leukemia, with WT1 mutations enhancing stemness and alter lineage hierarchy, while stem cells from later developmental stages progressively withstand transformation. Single-cell analyses revealed that fetal-origin versus postnatal leukemic stem cells exhibit greater quiescence and metabolic reliance on oxidative phosphorylation. Notably, therapeutic responses markedly differed between fetal- and postnatal-origin leukemias, even when driven by the same oncogenic mutations. In patients, onco-fetal transcriptional programs were associated with worse outcomes. We identified tailored combination therapies that specifically diminished aggressive fetal-origin leukemia, underscoring the need to consider ontogeny in treatment of pediatric cancers.

Project description:Pediatric cancers are increasingly linked to transformation events before birth, yet how ontogeny influences oncogenesis remains poorly understood. Using a humanized model of NUP98-NSD1-driven pediatric acute myeloid leukemia, particularly aggressive when accompanied by WT1 mutations, we investigated how the developmental stage of hematopoietic stem cells impacts leukemic transformation, disease progression and therapy response. Fetal-derived hematopoietic stem cells readily transform into leukemia, with WT1 mutations enhancing stemness and alter lineage hierarchy, while stem cells from later developmental stages progressively withstand transformation. Single-cell analyses revealed that fetal-origin versus postnatal leukemic stem cells exhibit greater quiescence and metabolic reliance on oxidative phosphorylation. Notably, therapeutic responses markedly differed between fetal- and postnatal-origin leukemias, even when driven by the same oncogenic mutations. In patients, onco-fetal transcriptional programs were associated with worse outcomes. We identified tailored combination therapies that specifically diminished aggressive fetal-origin leukemia, underscoring the need to consider ontogeny in treatment of pediatric cancers.

Project description:Genetic studies have identified recurrent somatic mutations in Acute Myeloid Leukemia (AML) patients, including in WT1 (Wilms’ tumor gene 1). The molecular mechanisms by which WT1 mutations contribute to leukemogenesis have not yet been fully elucidated. We investigated the role of Wt1 gene dosage in steady state and pathologic hematopoiesis. Wt1 heterozygous loss enhanced stem cell self-renewal in an age-dependent manner, with increased stem cell function over time and age-dependent leukemic transformation. Wt1-haploinsufficient leukemias were characterized by progressive genetic and epigenetic alterations, including in known leukemia disease alleles, demonstrating a requirement for additional events to promote hematopoietic transformation. Consistent with this observation, we found that Wt1 haploinsufficiency cooperates with Flt3-ITD mutation to induce fully penetrant AML. Our studies provide insight into mechanisms of Wt1-loss in leukemogenesis and into the evolutionary events required to induce transformation of Wt1-haploinsufficient stem/progenitor cells.

Project description:Children with Down syndrome have a 150-fold increased risk of developing myeloid leukemia. As Down syndrome leukemogenesis initiates during fetal development, we sought to characterize the cellular mechanisms of preleukemic initiation and leukemic progression using CRISPR/Cas9-mediated gene editing in human disomic and trisomic fetal liver hematopoietic cells and xenotransplantation. Compared to disomic fetal liver, trisomy 21 initiated atypical fetal hematopoiesis, in part through up-regulation of chromosome 21 miRNAs. GATA1 mutations caused transient preleukemia only when introduced into trisomy 21 long-term hematopoietic stem cells. By contrast, progression to leukemia was independent of trisomy 21 and originated in a wide spectrum of stem and progenitor cells through additional mutations in cohesin genes such as STAG2. CD117+ cells mediated the propagation and progression of the preleukemic and leukemic disease. Treatment with small molecule CD117/KIT inhibitors efficiently targeted preleukemic stem cells and blocked progression to leukemia; thereby laying the groundwork for early prevention strategies in Down syndrome newborns.

Project description:Children with Down syndrome have a 150-fold increased risk of developing myeloid leukemia. As Down syndrome leukemogenesis initiates during fetal development, we sought to characterize the cellular mechanisms of preleukemic initiation and leukemic progression using CRISPR/Cas9-mediated gene editing in human disomic and trisomic fetal liver hematopoietic cells and xenotransplantation. Compared to disomic fetal liver, trisomy 21 initiated atypical fetal hematopoiesis, in part through up-regulation of chromosome 21 miRNAs. GATA1 mutations caused transient preleukemia only when introduced into trisomy 21 long-term hematopoietic stem cells. By contrast, progression to leukemia was independent of trisomy 21 and originated in a wide spectrum of stem and progenitor cells through additional mutations in cohesin genes such as STAG2. CD117+ cells mediated the propagation and progression of the preleukemic and leukemic disease. Treatment with small molecule CD117/KIT inhibitors efficiently targeted preleukemic stem cells and blocked progression to leukemia; thereby laying the groundwork for early prevention strategies in Down syndrome newborns.

Project description:The molecular mechanisms involved in disease progression and relapse in T-cell acute lymphoblastic leukemia (T-ALL) are poorly understood. We used single nucleotide polymorphism (SNP) array analysis to analyze paired diagnostic and relapsed T-ALL samples to identify recurrent genetic alterations in T-ALL. This analysis showed a notorious absence of acquired chromosomal changes at relapse. In addition, we identified deletions and associated mutations in the WT1 tumor suppressor gene in 2/9 samples. Subsequent analysis showed WT1 mutations in 28/211 (13.2%) of pediatric and 10/85 (11.7%) of adult T-ALL cases. WT1 mutations present in T-ALL are predominantly heterozygous frameshift mutations resulting in truncation of the C-terminal zinc finger domains of this transcription factor. WT1 mutations are most prominently found in T-ALL cases with aberrant rearrangements of the oncogenic TLX1, TLX3 and HOXA transcription factor oncogenes. Survival analysis demonstrated that WT1 mutations do not confer adverse prognosis in pediatric and adult T-ALL. Overall these results show that overt chromosomal instability does not seem to be a major mutagenic mechanism contributing to disease progression in T-ALL and the presence of WT1 mutations as a recurrent genetic alteration in T-ALL.

Project description:NUP98-NSD1 positive Acute myeloid leukemia (AML) frequently occurs within the pediatric karyotypic normal(CN)-AML cohort. It is often associated with mutations in genes like FLT3, NRAS, WT1 and MYC. Here we have studied the role of NUP98-NSD1 fusion and NRASG12D in leukemia initiation and progression.

Project description:GATA2 deficiency is an autosomal dominant germline disorder of immune dysfunction and bone marrow failure with a high propensity for leukemic transformation in adolescents, present in up to 7% of pediatric myelodysplastic syndrome (MDS) and 15% of advanced MDS cases. While sequencing studies have identified several secondary mutations thought to contribute to malignancy, the mechanisms of disease progression have been difficult to identify due to a lack of disease-specific experimental models. Here, we generated a murine model of one of the most common GATA2 mutations associated with leukemic progression in GATA2 deficiency, Gata2R396Q/+. While mutant mice exhibit mild defects in peripheral blood output throughout life, they display significant hematopoietic abnormalities in the bone marrow (BM), including a reduction in hematopoietic stem cell (HSC) function and intrinsic biases toward specific stem cell subsets that differ from previous models of GATA2 loss. Supporting this observation, single-cell RNA sequencing of BM hematopoietic progenitors revealed a loss of HSC stemness, myeloid-bias, and accelerated ageing phenotype. Importantly, we show that Gata2R396Q/+ exerts effects early in hematopoietic development, as mutant mice generate fewer HSCs in the aorta gonad mesonephros, and fetal liver HSCs have reduced function. This reduced pool of HSCs and aged phenotype could be potential contributors to leukemic transformation in patients, and our model provides a useful tool to study the mechanisms of malignant transformation in GATA2 deficiency.

Project description:Hematopoietic stem cells sustain life-long blood production. While they are the known cellular origin of aging-associated myeloid malignancies, such as acute myeloid leukemia (AML), mechanisms driving their malignant transformation have remained elusive. Epigenetic dysregulation following acquired loss-of-function mutations of DNA methyl-cytosine dioxygenase Ten-Eleven Translocation-2 (TET2) occurs frequently in the elderly leading to cytosine hypermethylation in and around DNA binding sites of master transcription factors, including PU.1. Here we show that Tet2 deficient hematopoietic stem and progenitor cells (HSPC) undergo malignant transformation upon compromised PU.1 gene regulation. Leukemic stem and progenitor cells show hypermethylation at PU.1 binding sites and fail to activate PU.1-depenent myeloid enhancers, and are hallmarked by a defined signature of impaired genes shared with human AML. Our study demonstrates that Tet2 and PU.1 cooperate in suppressing leukemogenesis in HSPC and establishes a methylation sensitive PU.1-dependent gene network as a unifying feature in acute myeloid leukemia.