Bone Marrow Stromal Cells Modulate Mouse ENT1 Activity and Protect Leukemia Cells from Cytarabine Induced Apoptosis

BACKGROUND: Despite a high response rate to chemotherapy, the majority of patients with acute myeloid leukemia (AML) are destined to relapse due to residual disease in the bone marrow (BM). The tumor microenvironment is increasingly being recognized as a critical factor in mediating cancer cell survival and drug resistance. In this study, we propose to identify mechanisms involved in the chemoprotection conferred by the BM stroma to leukemia cells. METHODS: Using a leukemia mouse model and a human leukemia cell line, we studied the interaction of leukemia cells with the BM microenvironment. We evaluated in vivo and in vitro leukemia cell chemoprotection to different cytotoxic agents mediated by the BM stroma. Leukemia cell apoptosis was assessed by flow cytometry and western blotting. The activity of the equilibrative nucleoside transporter 1 (ENT1), responsible for cytarabine cell incorporation, was investigated by measuring transport and intracellular accumulation of (3)H-adenosine. RESULTS: Leukemia cell mobilization from the bone marrow into peripheral blood in vivo using a CXCR4 inhibitor induced chemo-sensitization of leukemia cells to cytarabine, which translated into a prolonged survival advantage in our mouse leukemia model. In vitro, the BM stromal cells secreted a soluble factor that mediated significant chemoprotection to leukemia cells from cytarabine induced apoptosis. Furthermore, the BM stromal cell supernatant induced a 50% reduction of the ENT1 activity in leukemia cells, reducing the incorporation of cytarabine. No protection was observed when radiation or other cytotoxic agents such as etoposide, cisplatin and 5-fluorouracil were used. CONCLUSION: The BM stroma secretes a soluble factor that significantly protects leukemia cells from cytarabine-induced apoptosis and blocks ENT1 activity. Strategies that modify the chemo-protective effects mediated by the BM microenvironment may enhance the benefit of conventional chemotherapy for patients with AML

STS and the city:politics and practices of hope

Many recent studies on network technologies and cities share an alarmist view of the impact of technological or regulatory change in utility sectors on the social and spatial fabric of cities, pointing to growing discrimination and inequalities, alienation, enhanced social exclusion and urban "splintering" on a universal scale. A science and technology study (STS) perspective on these matters is helpful in moving beyond this "universal alarmism" by emphasizing the ambivalence inherent to all technologies, the significant potential of contestation of, and resistance, to technology-supported forms of discrimination, and the deeply contingent nature of the process of appropriation of new technologies and, as a consequence, of the social "effects" of technologies. Adopting this perspective would mean actively searching for and exploring these context-dependent and often conflictive appropriation processes. For it is in these spaces that we might begin to identify urban technological politics that break free from an intellectually and politically disabling technological pessimism

Cardiotoxicity of anticancer therapies. Towards the implementation of cardio-oncology units Cardiotoxicidad inducida por tratamientos oncológicos. Fundamentos para la implementación de equipos de Cardio-Oncología

© 2018, Sociedad Medica de Santiago. All rights reserved. Recently, we have witnessed major improvements in cancer treatment. Early diagnosis and development of new therapies have reduced cancer-related mortality. However, these new therapies, along with greater patient survival, are associated with an increase in untoward effects, particularly in the cardiovascular system. Although cardiotoxicity induced by oncologic treatments affects predominantly the myocardium, it can also involve other structures of the cardiovascular system, becoming one of the main causes of morbidity and mortality in those who survive cancer. The main objective of cardio-oncology is to achieve the maximum benefits of oncologic treatments while minimizing their deleterious cardiovascular effects. It harbors the stratification of patients at risk of cardiotoxicity, the implementation of diagnostic tools (imaging techniques and biomarkers) for early diagnosis, preventive strategies and early treatment options fo

Cardiotoxicity of anticancer therapies. Towards the implementation of cardio-oncology units

Recently, we have witnessed major improvements in cancer treatment. Early diagnosis and development of new therapies have reduced cancer-related mortality. However, these new therapies, along with greater patient survival, are associated with an increase in untoward effects, particularly in the cardiovascular system. Although cardiotoxicity induced by oncologic treatments affects predominantly the myocardium, it can also involve other structures of the cardiovascular system, becoming one of the main causes of morbidity and mortality in those who survive cancer. The main objective of cardio-oncology is to achieve the maximum benefits of oncologic treatments while minimizing their deleterious cardiovascular effects. It harbors the stratification of patients at risk of cardiotoxicity, the implementation of diagnostic tools (imaging techniques and biomarkers) for early diagnosis, preventive strategies and early treatment options for the complications. Herein, we discuss the basic knowledge for the implementation of cardio-oncology units and their role in the management of cancer patients, the diagnostic tools available to detect cardiotoxicity and the present therapeutic options