Project description:Leukemia stem cells (LSC) in chronic myelogenous leukemia (CML) resist elimination with tyrosine kinase inhibitors (TKI) and persist as a source of disease recurrence. LSC populations are heterogeneous, but the most primitive, drug-resistant subsets are not well characterized. Previous studies indicate that variable cell-surface expression of the c-Kit receptor identifies heterogeneous hematopoietic stem cells (HSC) populations. We found that c-Kit expression is reduced on CML LSC compared to normal HSC. Long-term engraftment and leukemia generation capacity was restricted to low c-Kit expressing (c-KitLow) LSC, which showed increased quiescence and inflammatory gene signatures expression. The c-Kit ligand, stem cell factor (SCF), expanded normal HSC but drove maturation of CML LSC. The proportion of c-Kitlow LT-HSC was increased with TKI treatment. Supplementary SCF treatment enhanced elimination of committed but not primitive CML LT-HSC in TKI-treated mice. Low c-Kit expression identifies primitive, treatment-resistant LSC subpopulations with distinct regulatory characteristics, that are critical therapeutic targets.

Project description:Imatinib and other BCR-ABL1 inhibitors are effective therapies for chronic myelogenous leukemia (CML), but these inhibitors target additional kinases including KIT, raising the question of whether off-target effects contribute to clinical efficacy. On the basis of its involvement in CML pathogenesis, we hypothesized that KIT may govern responses of CML cells to imatinib. To test this, we assessed the growth of primary CML progenitor cells under conditions of sole BCR-ABL1, sole KIT, and dual BCR-ABL1/KIT inhibition. Sole BCR-ABL1 inhibition suppressed mature CML progenitor cells, but these effects were largely abolished by stem cell factor (SCF) and maximal suppression required dual BCR-ABL1/KIT inhibition. In contrast, KIT inhibition did not add to the effects of BCR-ABL1 inhibition in primitive progenitors, represented by CD34(+)38(-) cells. Long-term culture-initiating cell assays on murine stroma revealed profound depletion of primitive CML cells by sole BCR-ABL1 inhibition despite the presence of SCF, suggesting that primitive CML cells are unable to use SCF as a survival factor upon BCR-ABL1 inhibition. In CD34(+)38(+) cells, SCF strongly induced pAKT(S473) in a phosphoinositide 3-kinase (PI3K)-dependent manner, which was further enhanced by inhibition of BCR-ABL1 and associated with increased colony survival. In contrast, pAKT(S473) levels remained low in CD34(+)38(-) cells cultured under the same conditions. Consistent with reduced response to SCF, KIT surface expression was significantly lower on CD34(+)38(-) compared with CD34(+)38(+) CML cells, suggesting a possible mechanism for the differential effects of SCF on mature and primitive CML progenitor cells.

Project description:A deeper understanding of the biology of therapy resistant cells is important for the development of optimal therapeutic strategies to attain complete cure of leukemia. Here we compared chromatin accessibility of CML patient cells treated with Imatinib vs untreated cells and column enriched deep-quiescent LI (leukemia initiator) cells. ICG-001 treatment of LIs suggested increased differentiation of LIs.

Project description:Purpose: We previously demonstrated that immunophenotypically CD34-CD38- TKI resistant LSC/LIC population was clearly heterogeneous. The goal of this study is to explore more about the drug-resistant LSC/LICs Methods: CML patient cells were treated for 7 days with imatinib and live cells were subjected to scRNA-sequencing Results: scRNA-seq reveals heterogeneity in the therapy resistant cells. Distinct expression profiles, yet with an interrelated continuumsuggest the existence of a depply-quiescent persister population within resistant cells. Conclusions: In this study using single cell transcriptomics and single cell metabolomics analyses we identify and characterize a deeply-quiescent/persister CML LSC/LIC population subset of CML patient cells which is highly dependent on FAO for their metabolomic requierements

Project description:Heterogeneity of therapy-resistant CML cells

Project description:Heterogeneity of CML therapy resistant cells

Project description:Hematopoietic stem cells (HSCs) are heterogeneous with respect to their self-renewal, lineage, and reconstitution potentials. Although c-Kit is required for HSC function, gain and loss-of-function c-Kit mutants suggest that even small changes in c-Kit signaling profoundly affect HSC function. Herein, we demonstrate that even the most rigorously defined HSCs can be separated into functionally distinct subsets based on c-Kit activity. Functional and transcriptome studies show HSCs with low levels of surface c-Kit expression (c-Kit(lo)) and signaling exhibit enhanced self-renewal and long-term reconstitution potential compared with c-Kit(hi) HSCs. Furthermore, c-Kit(lo) and c-Kit(hi) HSCs are hierarchically organized, with c-Kit(hi) HSCs arising from c-Kit(lo) HSCs. In addition, whereas c-Kit(hi) HSCs give rise to long-term lymphomyeloid grafts, they exhibit an intrinsic megakaryocytic lineage bias. These functional differences between c-Kit(lo) and c-Kit(hi) HSCs persist even under conditions of stress hematopoiesis induced by 5-fluorouracil. Finally, our studies show that the transition from c-Kit(lo) to c-Kit(hi) HSC is negatively regulated by c-Cbl. Overall, these studies demonstrate that HSCs exhibiting enhanced self-renewal potential can be isolated based on c-Kit expression during both steady state and stress hematopoiesis. Moreover, they provide further evidence that the intrinsic functional heterogeneity previously described for HSCs extends to the megakaryocytic lineage.

Project description:Therapy resistant primitive stem cells in chronic myelogenous leukemia are characterized by low c-Kit expression and altered SCF response

Project description:We report that angiotensin-converting enzyme (ACE), a critical physiologic regulator of blood pressure, angiogenesis, and inflammation, is a novel marker for identifying hemangioblasts differentiating from human embryonic stem cells (hESC). We demonstrate that ACE+CD45-CD34+/- hemangioblasts are common yolk sac (YS)-like progenitors for not only endothelium but also both primitive and definitive human lymphohematopoietic cells. Thrombopoietin and basic fibroblast growth factor are identified as critical factors for the proliferation of human hemangioblasts. The developmental sequence of human embryoid body hematopoiesis is remarkably congruent to the timeline of normal human YS development, which occurs during weeks 2 to 6 of human gestation. Furthermore, ACE and the renin-angiotensin system (RAS) directly regulate hemangioblast expansion and differentiation via signaling through the angiotensin II receptors AGTR1 and AGTR2. ACE enzymatic activity is required for hemangioblast expansion, and differentiation toward either endothelium or multipotent hematopoietic progenitors is dramatically augmented after manipulation of angiotensin II signaling with either AGTR1- or AGTR2-specific inhibitors. The RAS can therefore be exploited to direct the hematopoietic or endothelial fate of hESC-derived hemangioblasts, thus providing novel opportunities for human tissue engineering. Moreover, the initial events of human hematoendotheliogenesis can be delineated in a manner previously impossible because of inaccessibility to early human embryonic tissues.

Project description:Overcoming drug resistance and targeting cancer stem cells remain challenges for curative cancer treatment. To investigate the role of microRNAs (miRNAs) in regulating drug resistance and leukemic stem cell (LSC) fate, we performed global transcriptome profiling in treatment-naive chronic myeloid leukemia (CML) stem/progenitor cells and identified that miR-185 levels anticipate their response to ABL tyrosine kinase inhibitors (TKIs). miR-185 functions as a tumor suppressor: its restored expression impaired survival of drug-resistant cells, sensitized them to TKIs in vitro, and markedly eliminated long-term repopulating LSCs and infiltrating blast cells, conferring a survival advantage in preclinical xenotransplantation models. Integrative analysis with mRNA profiles uncovered PAK6 as a crucial target of miR-185, and pharmacological inhibition of PAK6 perturbed the RAS/MAPK pathway and mitochondrial activity, sensitizing therapy-resistant cells to TKIs. Thus, miR-185 presents as a potential predictive biomarker, and dual targeting of miR-185-mediated PAK6 activity and BCR-ABL1 may provide a valuable strategy for overcoming drug resistance in patients.