Yanzhi Du1, Yuan Xia, Xiaoling Pan, Zi Chen, Aihua Wang, Kankan Wang, Junmin Li, Ji Zhang. 1. 1 Key Laboratory of Stem Cell Biology, Institute of Health Sciences, Shanghai Institutes for Biological Sciences (SIBS), Chinese Academy of Sciences (CAS), Shanghai Jiao Tong University School of Medicine (SJTU-SM) , Shanghai, China .
Abstract
AIMS: We have recently shown that fenretinide preferentially targets CD34(+) cells of acute myeloid leukemia (AML), and here, we test whether this agent exerts the effect on CD34(+) cells of chronic myeloid leukemia (CML), which are refractory to imatinib. RESULTS: As tested by colony-forming cell assays using clinical specimens, both number and size of total colonies derived from CD34(+) CML cells were significantly reduced by fenretinide, and by combining fenretinide with imatinib. In particular, colonies derived from erythroid progenitors and more primitive pluripotent/multipotent progenitors were highly sensitive to fenretinide/fenretinide plus imatinib. Accordantly, fenretinide appeared to induce apoptosis in CD34(+) CML cells, particularly with regard to the cells in the subpopulation of CD34(+)CD38(-). Through cell quiescent assays, including Ki-67 negativity test, we added evidence that nonproliferative CD34(+) CML cells were largely eliminated by fenretinide. Transcriptome and molecular data further showed that mechanisms underlying the apoptosis in CD34(+) CML cells were highly complex, involving multiple events of oxidative stress responses. INNOVATION AND CONCLUSION: As compared with CD34(+) AML cells, the apoptotic effects of fenretinide on CD34(+) CML cells were more prominent whereas less varied among the samples of different patients, and also various stress-responsive events appeared to be more robust in fenretinide-treated CD34(+) CML cells. Thus, the combination of fenretinide with imatinib may represent a more sophisticated strategy for CML treatment, in which imatinib mainly targets leukemic blast cells through the intrinsic pathway of apopotosis, whereas fenretinide primarily targets CML stem/progenitor cells through the oxidative/endoplasmic reticulum stress-mediated pathway.
AIMS: We have recently shown that fenretinide preferentially targets CD34(+) cells of acute myeloid leukemia (AML), and here, we test whether this agent exerts the effect on CD34(+) cells of chronic myeloid leukemia (CML), which are refractory to imatinib. RESULTS: As tested by colony-forming cell assays using clinical specimens, both number and size of total colonies derived from CD34(+) CML cells were significantly reduced by fenretinide, and by combining fenretinide with imatinib. In particular, colonies derived from erythroid progenitors and more primitive pluripotent/multipotent progenitors were highly sensitive to fenretinide/fenretinide plus imatinib. Accordantly, fenretinide appeared to induce apoptosis in CD34(+) CML cells, particularly with regard to the cells in the subpopulation of CD34(+)CD38(-). Through cell quiescent assays, including Ki-67 negativity test, we added evidence that nonproliferative CD34(+) CML cells were largely eliminated by fenretinide. Transcriptome and molecular data further showed that mechanisms underlying the apoptosis in CD34(+) CML cells were highly complex, involving multiple events of oxidative stress responses. INNOVATION AND CONCLUSION: As compared with CD34(+) AML cells, the apoptotic effects of fenretinide on CD34(+) CML cells were more prominent whereas less varied among the samples of different patients, and also various stress-responsive events appeared to be more robust in fenretinide-treated CD34(+) CML cells. Thus, the combination of fenretinide with imatinib may represent a more sophisticated strategy for CML treatment, in which imatinib mainly targets leukemic blast cells through the intrinsic pathway of apopotosis, whereas fenretinide primarily targets CML stem/progenitor cells through the oxidative/endoplasmic reticulum stress-mediated pathway.
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