mTORC1 is essential for leukemia propagation but not stem cell self-renewal
Takayuki Hoshii, … , Ken-ichi Yamamura, Atsushi Hirao
Takayuki Hoshii, … , Ken-ichi Yamamura, Atsushi Hirao
Published May 24, 2012
Citation Information: J Clin Invest. 2012;122(6):2114-2129. https://doi.org/10.1172/JCI62279.
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Research Article

mTORC1 is essential for leukemia propagation but not stem cell self-renewal

Abstract

Although dysregulation of mTOR complex 1 (mTORC1) promotes leukemogenesis, how mTORC1 affects established leukemia is unclear. We investigated the role of mTORC1 in mouse hematopoiesis using a mouse model of conditional deletion of Raptor, an essential component of mTORC1. Raptor deficiency impaired granulocyte and B cell development but did not alter survival or proliferation of hematopoietic progenitor cells. In a mouse model of acute myeloid leukemia (AML), Raptor deficiency significantly suppressed leukemia progression by causing apoptosis of differentiated, but not undifferentiated, leukemia cells. mTORC1 did not control cell cycle or cell growth in undifferentiated AML cells in vivo. Transplantation of Raptor-deficient undifferentiated AML cells in a limiting dilution revealed that mTORC1 is essential for leukemia initiation. Strikingly, a subset of AML cells with undifferentiated phenotypes survived long-term in the absence of mTORC1 activity. We further demonstrated that the reactivation of mTORC1 in those cells restored their leukemia-initiating capacity. Thus, AML cells lacking mTORC1 activity can self-renew as AML stem cells. Our findings provide mechanistic insight into how residual tumor cells circumvent anticancer therapies and drive tumor recurrence.

Authors

Takayuki Hoshii, Yuko Tadokoro, Kazuhito Naka, Takako Ooshio, Teruyuki Muraguchi, Naoyuki Sugiyama, Tomoyoshi Soga, Kimi Araki, Ken-ichi Yamamura, Atsushi Hirao

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Figure 5

Undifferentiated AML cells are resistant to loss of mTORC1 activity.

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Undifferentiated AML cells are resistant to loss of mTORC1 activity. The...
The Raptorfl/flCreER AML mice were analyzed 14 days after control or TAM treatment. (A and B) Number of BM-MNCs in BM (A: TAM–, n = 6; TAM+, n = 5) and of platelets (PLT) in PB (B: TAM–, n = 6; TAM+, n = 9). Data are mean number ± SD of the indicated hematopoietic cell type. Horizontal dotted lines are mean values of the indicated hematopoietic parameters in normal adult mice (8 weeks old, n = 5). (C and D) Flow cytometric analyses of AML cells in BM. Representative data are shown for GFP/c-Kit expression in BM-MNCs (C) and for c-Kit/Gr-1 expression in GFP+-gated BM-MNCs (D). Values are the mean percentage ± SD for the indicated subpopulations (C, n = 10; D, n = 3). (E) Absolute numbers of K+G and KG+ cells in the hind legs of the Raptorfl/flCreER AML mice (TAM– or TAM+). Data shown are the values for individual mice (n = 10 per group). Horizontal lines are mean values. (F) Morphological analysis of AML cells. GFP+ cells from the BM of AML mice were stained with May-Grünwald/Giemsa. Data are the mean percentage ± SD of AML cells containing segmented nuclei (n = 5). Right panels show representative images of GFP+ cells. Scale bars: 10 μm. Arrowheads indicate AML cells with segmented nuclei (differentiated AML cells). (G) Cell cycle. BrdU was injected i.p. into AML mice 2 hours prior to sacrifice. AML cells were harvested, stained with an anti-BrdU Ab, and analyzed by flow cytometry. Data are the mean percentage ± SD of BrdU+ cells in the indicated AML cell subpopulations (n = 5). (H) Apoptosis. Data shown are the mean percentage ± SD of Annexin V+7AAD cells in the indicated AML cell subpopulations (n = 5). *P < 0.05, **P < 0.01 (Student’s t test).