Mechanisms of T cell Leukemogenesis

Although the survival rates have improved for children with T cell acute lymphoblastic leukemia (T-ALL), 25% of children relapse and most of these will eventually succumb to disease. Treatment of adults with T-ALL has been less successful, with long-term survival rates of only 10-30%. Moreover, modern dose-intensive chemotherapy is associated with side effects in survivors including organ damage/failure, neurocognitive deficits due to intrathecal prophylaxis and risk of developing secondary malignancies. The severity of these long-term side effects and rates of relapse urge the development of targeted therapies for this disease. We have modeled T-ALL in the mouse by expressing the TAL1 and LMO2 oncogenes in developing thymocytes. Similar to what is observed in cortical T-ALL patients, these mice develop spontaneous mutations in NOTCH1 and exhibit INK4A/ARF and/or PTEN loss (Figure 1). We were one of the first to demonstrate that mouse T-ALL is driven by rare leukemia-initiating cells (L-IC) and to show that the thymic progenitor DN3/4 population is enriched in its ability to initiate disease; whereas the CD4, CD8 double-positive leukemic cells were not (Figure 2).

Figure 1. Leukemia-initiating cells (L-IC) are a rare population of leukemic cells that are defined by their ability to initiate disease in mice.

DN3 is enriched in L-IC activity Several studies suggest that relapse may result from a failure to eliminate leukemia-initiating cells (L-ICs). We have demonstrated that NOTCH1 inhibition reduces and in some cases eliminates mouse L-IC activity. Our work is innovative because it focuses on characterizing the recently identified DN3-enriched L-IC in our mouse T-ALL model and on determining the pathways that drive L-IC activity. We study L-IC biology in our mouse T-ALL model where hematopoietic development is well characterized and where micro environmental or niche influences on L-IC survival can be addressed. The current focus of the lab is to purify the mouse L-IC and to identify the pathways that mediate L-IC survival and self-renewal.

Figure 2. Leukemic DN3 progenitors are enriched in leukemic-initiating potential.

NOTCH/c-MYC pathway mediates L-IC activity NOTCH1 mutations develop spontaneously in our TAL1 and TAL1/LMO2 mouse T-ALL models and treatment with gamma-secretase inhibitors (GSI) prevents NOTCH1 activation and extends the survival of leukemic mice, demonstrating that GSIs have anti-leukemia activity in vivo (Cullion K, et. al. 2009). We have shown that NOTCH1 inhibition can also reduce/eliminate the L-IC population and prevent disease initiation (Tatarek J, et. al. 2011). NOTCH1 directly induces MYC expression (Sharma V, et. al. 2006) and MYC silencing or inhibition reduces mouse L-IC frequency (Figure 3; Roderick J, et. al. 2014). Collectively, these studies demonstrate that the NOTCH1-MYC axis is critical for L-IC activity in vivo.

Figure 3. Log-plot of L-IC frequency shows that NOTCH and MYC inhibition target the L-IC in Tal/Lmo2 T-ALL.

References:

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