28 research outputs found

    Chronic Myeloid Leukemia: causes of treatment failure with imatinib

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    Imatinib is currently the treatment of choice of CML, but despite of the excellent results, it is not able to completely eradicate the disease and resistance may occur. The most studied mechanism is the presence of ABL kinase mutations that interfere with imatinib binding and action, gene amplification and clonal evolution. However, there are other mechanisms involved and less studied such as drug absorption and influx and efflux of imatinib. Besides the true causes of resistance, compliance is always a concern and also drug interaction should be checked. An understanding of these mechanisms will certainly contribute to develop new strategies for the treatment of resistant cases.O mesilato de imatinibe (MI) é atualmente o tratamento de escolha da Leucemoa Mielóide Crônica (LMC), mas, apesar dos excelentes resultados, não é capaz de erradicar completamente a doença, podendo ocorrer resistência ao tratamento. O mecanismo mais conhecido de resistência é o desenvolvimento de mutações do BCR-ABL, que impedem a ação ligação adequada do imatinibe à quinase, além de amplificação gênica e evolução clonal. No entanto, há uma série de outros mecanismos envolvidos e ainda pouco estudados, como alterações na absorção, efluxo e influxo de droga para o interior das células. Devem-se também considerar outros fatores, como aderência ao tratamento e uso de medicamentos concomitantes que podem interferir com imatinibe, diminuindo sua ação. O entendimento desses mecanismos poderá contribuir no desenvolvimento de novas estratégias para o tratamento dos casos resistentes.222

    Reduced SLIT2 is Associated with Increased Cell Proliferation and Arsenic Trioxide Resistance in Acute Promyelocytic Leukemia

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    Simple Summary In solid tumors, the altered expression of embryonic genes such as the SLIT-ROBO family has been associated with poor prognosis, while little is known about their role in acute myeloid leukemia (AML). Previous studies reported frequent hypermethylation of SLIT2 mediated by the methyltransferase enzyme EZH2 and more recently the PML protein, which are commonly found to be aberrantly expressed in AML. Here, we aim to assess retrospectively the clinical relevance of the SLIT2 gene in acute promyelocytic leukemia, a homogenous subtype of AML. We demonstrated that reduced SLIT2 expression was associated with high leukocyte counts and reduced overall survival in different APL cohorts. STLI2 treatment decreased APL growth, while SLIT2 knockdown accelerated cell cycle progression and proliferation. Finally, reduced expression of SLIT2 in murine APL blasts resulted in fatal leukemia associated with increased leukocyte counts in vivo. These findings demonstrate that SLIT2 can be considered as a prognostic marker in APL, and a potential candidate for clinical studies of a more heterogeneous disease, such as AML. The SLIT-ROBO axis plays an important role in normal stem-cell biology, with possible repercussions on cancer stem cell emergence. Although the Promyelocytic Leukemia (PML) protein can regulate SLIT2 expression in the central nervous system, little is known about SLIT2 in acute promyelocytic leukemia. Hence, we aimed to investigate the levels of SLIT2 in acute promyelocytic leukemia (APL) and assess its biological activity in vitro and in vivo. Our analysis indicated that blasts with SLIT2(high) transcript levels were associated with cell cycle arrest, while SLIT2(low) APL blasts displayed a more stem-cell like phenotype. In a retrospective analysis using a cohort of patients treated with all-trans retinoic acid (ATRA) and anthracyclines, high SLIT2 expression was correlated with reduced leukocyte count (p = 0.024), and independently associated with improved overall survival (hazard ratio: 0.94; 95% confidence interval: 0.92-0.97; p <0.001). Functionally, SLIT2-knockdown in primary APL blasts and cell lines led to increased cell proliferation and resistance to arsenic trioxide induced apoptosis. Finally, in vivo transplant of Slit2-silenced primary APL blasts promoted increased leukocyte count (p = 0.001) and decreased overall survival (p = 0.002) compared with the control. In summary, our data highlight the tumor suppressive function of SLIT2 in APL and its deteriorating effects on disease progression when downregulated

    Reduced SLIT2 is associated with increased cell proliferation and arsenic trioxide resistance in acute promyelocytic Leukemia

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    The SLIT-ROBO axis plays an important role in normal stem-cell biology, with possible repercussions on cancer stem cell emergence. Although the Promyelocytic Leukemia (PML) protein can regulate SLIT2 expression in the central nervous system, little is known about SLIT2 in acute promyelocytic leukemia. Hence, we aimed to investigate the levels of SLIT2 in acute promyelocytic leukemia (APL) and assess its biological activity in vitro and in vivo. Our analysis indicated that blasts with SLIT2high transcript levels were associated with cell cycle arrest, while SLIT2low APL blasts displayed a more stem-cell like phenotype. In a retrospective analysis using a cohort of patients treated with all-trans retinoic acid (ATRA) and anthracyclines, high SLIT2 expression was correlated with reduced leukocyte count (p = 0.024), and independently associated with improved overall survival (hazard ratio: 0.94; 95% confidence interval: 0.92–0.97; p < 0.001). Functionally, SLIT2-knockdown in primary APL blasts and cell lines led to increased cell proliferation and resistance to arsenic trioxide induced apoptosis. Finally, in vivo transplant of Slit2-silenced primary APL blasts promoted increased leukocyte count (p = 0.001) and decreased overall survival (p = 0.002) compared with the control. In summary, our data highlight the tumor suppressive function of SLIT2 in APL and its deteriorating effects on disease progression when downregulated

    Leucemia Mielóide Crônica: causas de falha do tratamento com mesilato de imatinibe Chronic Myeloid Leukemia: causes of treatment failure with imatinib

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    O mesilato de imatinibe (MI) é atualmente o tratamento de escolha da Leucemoa Mielóide Crônica (LMC), mas, apesar dos excelentes resultados, não é capaz de erradicar completamente a doença, podendo ocorrer resistência ao tratamento. O mecanismo mais conhecido de resistência é o desenvolvimento de mutações do BCR-ABL, que impedem a ação ligação adequada do imatinibe à quinase, além de amplificação gênica e evolução clonal. No entanto, há uma série de outros mecanismos envolvidos e ainda pouco estudados, como alterações na absorção, efluxo e influxo de droga para o interior das células. Devem-se também considerar outros fatores, como aderência ao tratamento e uso de medicamentos concomitantes que podem interferir com imatinibe, diminuindo sua ação. O entendimento desses mecanismos poderá contribuir no desenvolvimento de novas estratégias para o tratamento dos casos resistentes.<br>Imatinib is currently the treatment of choice of CML, but despite of the excellent results, it is not able to completely eradicate the disease and resistance may occur. The most studied mechanism is the presence of ABL kinase mutations that interfere with imatinib binding and action, gene amplification and clonal evolution. However, there are other mechanisms involved and less studied such as drug absorption and influx and efflux of imatinib. Besides the true causes of resistance, compliance is always a concern and also drug interaction should be checked. An understanding of these mechanisms will certainly contribute to develop new strategies for the treatment of resistant cases
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