Browsing by Subject "Acute myeloid leukemia"
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Item Oncogenic roles of RAS in acute myeloid leukemia cooperated with Mll-AF9.(2008-07) Kim, Won-ilThree main sections are presented in this thesis. First, we investigated which hematopoietic cells express TRE -driven transgenes when combined with Vav-tTA , because mastocytosis was developed in Vav-tTA ; TRE-NRAS G12V transgenic mice without detectable other diseases. We assayed Vav-tTA -driven luciferase expression in hematopoietic cells including bone marrow-derived mast cells (BMMC) and CD34 positive hematopoietic progenitor cells (HPC) as well as myeloid and lymphoid lineages by live mouse imaging and relative light unit measurement before or after treating Vav-tTA ; TRE -luciferase co-transgenic mice with doxycycline (Dox). We found that B cells in the bone marrow and T cells in the thymus expresses Vav-tTA -driven luciferase at much higher levels than in myeloid cells, BMMC and CD34 positive HPC, which showed relatively low levels. Thus, we conclude that Vav-tTA -driven NRAS G12V expression is sufficient for mastocytosis development but not for myeloid leukemia, and lymphoid cells are resistant to NRAS G12V transformation despite high level of expression. Second, experiments were performed to study the oncogenic role of the NRAS oncogene ( NRAS G12V ) in the context of acute myeloid leukemia (AML). We transplanted AML, which was developed in Vav-tTA TRE-NRASG12V ; Mll-AF9 transgenic ( TRM -transgenic) mice, into recipient SCID mice. Conditional repression of NRAS G12V expression greatly reduced peripheral white blood cell (WBC) counts in leukemia recipient mice and induced apoptosis in the transplanted AML cells correlated with reduced Ras/Erk signaling. After marked decrease of AML blast cells, myeloproliferative disease (MPD)-like AML relapsed characterized by cells that did not express NRAS G12V . In comparison with primary AML, the MPD-like AML showed significantly reduced aggressiveness, reduced myelosuppression and a more differentiated phenotype. We conclude that, in AML induced by an Mll-AF9 transgene, NRAS G12V expression contributes to acute leukemia maintenance by suppressing apoptosis and reducing differentiation of leukemia cells. Moreover, NRAS G12V oncogene has a cell non-autonomous role in suppressing erythropoiesis that results in the MPD-like AML showed significantly reduced ability to induce anemia. Third, based on the results finding the relapse of NRAS G12V -independent AML, we tested a hypothesis that chemotherapeutic cytarabine (AraC) treatment in addition to the RAS oncogene suppression would prevent or delay the relapse of AML. After the establishment of full-blown AML. We treated recipient mice with Dox and/or AraC (50 mg/kg/day). Compared with recipient mice treated with either Dox or AraC, we found that co-treatment significantly postponed the relapse of resistant AML and increased the survival days of the TRM -transgenic AML recipient mice. These results suggest that oncogenic RAS-targeting therapy may increase the therapeutic potential against drug-resistant AML when combined with chemotherapeutic AraC treatments. Consequently, we conclude the oncogenic roles of NRAS G12V expression in AML induced in cooperation with Mll-AF9 are; (1) to induce proliferation of AML blast cells, (2) to induce cell non-autonomous myelosuppression, (3) to suppress apoptosis in AML blast cells, and (4) to inhibit differentiation of AML blast cells. In treatment of AML, oncogenic RAS suppression combined current chemotherapy may improve the therapeutic potential and achieve longer remission period.Item A study of chemotherapy resistance in acute myeloid leukemia(2013-10) Rathe, Susan KayAcute myeloid leukemia (AML) is the most deadly of the leukemias. Due to its heterogeneous genetic nature it has been difficult to find effective targeted treatments. Standard induction chemotherapy, which includes cytarabine (Ara-C) as its primary component, will in most cases result in remission, but the remission is short-lived and usually results in the presentation of an Ara-C resistant form of AML at relapse. A thorough understanding of how chemotherapy resistance develops in AML would lead to the establishment of drug profiles describing the molecular conditions under which a drug should be considered or rejected as a treatment option. With the ultimate goal of providing patient specific drug treatment options to restore or preserve chemotherapy sensitivity, the research presented here had five objectives: (1) to develop and/or evaluate mouse models of Ara-C resistance in vitro and in vivo and determine their ability to mimic the Ara-C resistance found in human disease, (2) to discover cellular mechanisms of Ara-C resistance, (3) to find effective drug partners for Ara-C in treating de novo AML, (4) to find drugs for treating chemotherapy refractory AML, and (5) to predict drug response based on the molecular profile (gene expression patterns and specific mutations) for each AML patient. Although these objectives are broad and aggressive, this research has resulted in some significant strides towards meeting them. Using gene expression microarray, transcriptome sequencing, and targeted mutagenesis via TAL endonuclease treatment, it was determined mutations in Dck were the primary factor in the development of Ara-C resistance in an in vitro model of Ara-C resistance. Drug screens were used to determine Ara-C resistant cells became more sensitive to glucocorticoids, and cladribine is an affective partner to Ara-C in treating de novo disease. Also, an in vivo model of Ara-C resistance was developed by passaging AML cells through SCID/beige mice and treating the mice with low doses of Ara-C.