To improve the treatment strategies of T-cell acute lymphoblastic leukemia/lymphoma (T-ALL), further efforts are needed to identify therapeutic targets. Dysregulated expression of HOX-type transcription factors occurs in 30–40% of cases of T-ALL. TLX1/HOX11 is the prototypical HOX-type transcription factor. TLX1 may be an attractive therapeutic target because mice that are deficient in TLX1 are healthy. To test this possibility, we developed a conditional doxycycline-regulated mouse model of TLX1-initiated T-ALL. TLX1 induced T-ALL after ∼5–7 months with penetrance of 15–60%. Similar to human TLX1-type T-ALLs, the TLX1-induced tumors were arrested at the cortical stage of T-cell development and acquired activating NOTCH1 mutations. Inhibition of NOTCH signaling abrogated growth of cell lines derived from the TLX1-induced tumors. NOTCH inhibition also transiently delayed leukemia progression in vivo. Suppression of TLX1 expression slowed the growth of TLX1 tumor cell lines. Suppression of TLX1 in vivo also transiently delayed leukemia progression. We have shown that TLX1 functions as a T-cell oncogene that is active during both the induction and the maintenance phases of leukemia. However, the effect of suppressing NOTCH or TLX1 was transient. The tumors eventually “escaped” from inhibition. These data imply that the biological pathways and gene sets impacted by TLX1 and NOTCH have largely lost their importance in the fully established tumor. They have been supplanted by stronger oncogenic pathways. Although TLX1 or NOTCH inhibitors may not be effective as single agents, they may still contribute to combination therapy for TLX1-driven acute leukemia.
1026 Despite numerous advances in the past few decades, treatment of acute lymphoblastic leukemia/lymphoma (ALL) remains a common and considerable challenge. Further efforts to define the molecular lesions that drive ALL are needed to improve clinical management. The Hox subfamily of T-cell ALL (T-ALL) represents 30–40% of pediatric and adult cases. TLX1/HOX11 is the prototypical member of the Hox group. To generate a resource for developing targeted therapies for Hox T-ALLs, we developed a doxycycline-regulated mouse model of Tlx1-initiated T-ALL. Dysregulated thymic expression of Tlx1 induces T-ALL after ∼5-7 months with penetrance of 15–60%. The lymphoblasts are arrested at the early CD4+/CD8+/CD24hi stage of T-cell development, similar to human T-ALLs of the TLX1 subtype. Spontaneous activation of the Notch1 oncogene occurred in the tumors. In about two-thirds of samples, Notch was activated through acquired mutations in the heterodimerization and PEST domains that resemble the Notch1 mutations found in human patients. Inhibition of Notch signaling with g-secretase inhibitors completely abrogated cell line growth and induced apoptosis. Notch inhibition also transiently delayed leukemia progression by ∼17 days in vivo. In contrast, suppression of Tlx1 expression had more moderate inhibitory effects on cell line growth in vitro. However, suppression of Tlx1 expression in transgenic mice transiently delayed leukemia progression by ∼11 days. Tlx1 suppression had the strongest inhibitory effects on expression of CCR7 and lymph node size. These effects were fully reversed with ectopic expression of Tlx1. These data show that Tlx1 can convert normal thymocytes into leukemia cells, but the leukemia cells are not fully dependent on continued Tlx1 expression. The leukemia cells recruit secondary factors and pathways such as Notch and c-Myc to sustain growth and survival. Our study highlights a strong resiliency of T-ALL cells to both Tlx1 and Notch inhibition. Our study has important implications for targeting these pathways for the treatment of T-ALL. Disclosures: No relevant conflicts of interest to declare.
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