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Ashok Kumar Jayavelu, Jennifer N. Moloney, Frank-D. Böhmer, Thomas G

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Presentation on theme: "Ashok Kumar Jayavelu, Jennifer N. Moloney, Frank-D. Böhmer, Thomas G"— Presentation transcript:

1 NOX-driven ROS formation in cell transformation of FLT3-ITD-positive AML 
Ashok Kumar Jayavelu, Jennifer N. Moloney, Frank-D. Böhmer, Thomas G. Cotter  Experimental Hematology  Volume 44, Issue 12, Pages (December 2016) DOI: /j.exphem Copyright © 2016 ISEH - International Society for Experimental Hematology Terms and Conditions

2 Figure 1 Reactive oxygen species, their origins, and cellular systems involved in ROS metabolism. Major ROS sources are the mitochondria and NADPH oxidases, and several oxidases/peroxidases also contribute to ROS formation. Superoxide anions, hydrogen peroxide, lipid peroxides, hypochloride, and the hydroxyl radical can oxidize and thereby modify cellular macromolecules. This can serve essential signaling functions (“green” range), but also cause deleterious effects (“red” range) designated oxidative stress, potentially leading to cell death. Several enzyme systems can modify the formed ROS and have antioxidant activity for preventing damage and reverting macromolecule oxidations (right). NADPH and GSH are required for efficient antioxidant responses. The KEAP–NRF2 system is a master regulator of genes for antioxidant response. Experimental Hematology  , DOI: ( /j.exphem ) Copyright © 2016 ISEH - International Society for Experimental Hematology Terms and Conditions

3 Figure 2 Role of ROS formation in leukemic cell transformation by the oncoprotein FLT3-ITD. FLT3-ITD causes elevated ROS levels in cells of AML. This involves activation of STAT5, which can directly bind to the promoter of NADPH oxidase 4 (NOX4), leading to elevated transcription. Increased NOX4 levels cause elevated formation of ROS, which oxidize the catalytic cysteine of density-enhanced phosphatase-1 (DEP-1; a transmembrane protein–tyrosine phosphatase, also designated PTPRJ or CD148). In contrast to its activity in normal cells, the oxidized and thereby (reversibly) inactivated DEP-1 can no longer dephosphorylate FLT3-ITD, enabling elevated signal transduction and promoting cell transformation. Experimental Hematology  , DOI: ( /j.exphem ) Copyright © 2016 ISEH - International Society for Experimental Hematology Terms and Conditions

4 Figure 3 Oncoprotein-driven ROS formation in myeloid cells causes DNA damage. FLT3-ITD, but also ligand-activated FLT3 or the BCR-ABL oncoprotein, can drive oxidative DNA damage through a signaling chain involving AKT activation, elevated expression of p22phox, and activation of p22phox-interacting NADPH oxidases. DNA damage, involving DNA oxidation and generation of double-strand breaks, contributes to genetic instability and the accumulation of mutations associated with aggressive phenotypes, drug resistance, and relapse. Experimental Hematology  , DOI: ( /j.exphem ) Copyright © 2016 ISEH - International Society for Experimental Hematology Terms and Conditions

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