Browsing by Autor "Heriberto Cuevas"

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Bolivian Aymara Natives with Chronic Mountain Sickness Have Autonomous BFU-E Growth
(Elsevier BV, 2015) Ricardo Amaru; Ariel Amaru; Hortensia Miguez; Torres Gina; Josué Mamani; Oscar Vera; Heriberto Cuevas; Josef T. Prchal; Jaroslav F. Prchal
Abstract Background Erythrocytosis / polycythemia is divided into primary and secondary. Primary polycythemia can be either acquired; i.e. polycythemia vera (PV) due to somatic JAK2 mutation, or congenital due to germ-line DNA changes (erythropoietin (EPO) receptor and VHL mutations in Chuvash polycythemia). These mutations are expressed within erythroid progenitors, drive increased erythropoiesis and are detected by hypersensitive or autonomous EPO BFU-E responses. In contrast, secondary erythrocytosis (SE), such as seen with cardiopulmonary pathologies, is driven by the circulating EPO. Chronic mountain sickness (CMS) is characterized by high altitude pathological erythrocytosis and by cognitive and neurological impairments. CMS is found in subjects living in high altitude (2500 meters and higher). In La Paz, Bolivia, (3600m) there is 7% incidence of CMS erythrocytosis. Some human populations (Tibetans, Andean Quechuas and Aymaras, and Ethiopians) are adapted to very high altitudes and their adapted phenotypes and, in some instances, evolutionarily selected haplotypes, have been reported. Whole genome was evaluated in Andeans and two genes, SENP1 and ANP32D were found to be evolutionarily selected and correlated with presence or absence of erythrocytosis. The genes down-regulation in hypoxia had survival benefit in Drosophila ortholog (1).SENP1 desumoylate GATA-1 and other regulatory proteins and is critical for definitive erythropoiesis (2,3). Here we evaluated native Aymara La Paz dwellers with three types of polycythemia: CMS, SE secondary to cardiopulmonary disease, and PV, by clinical studies and by in vitro evaluation of erythroid progenitors, and compared them to non-polycythemic subjects. Patients and Methods Complete blood count was performed by automatic hematologic counter (Micro 60, USA). Serum EPO was measured by Elisa (R&D System, USA) and JAK2V617F mutation analysis by PCR assay. Erythroid progenitors were isolated by density gradient centrifugation and cultured in methylcellulose medium with and without EPO (Stem Cell technologies, Canada) at 370 C and 5 % CO2. BFU-E colonies reading was carried out according to standardized criteria at 7 and 14 days. Results Table. Normal Control(n=10) CMS (n=15) Secondary Erythrocytosis(n=10) PolycythemiaVera (n=5) 1.Gender M/F 10/0 15/0 10/0 3/2 Age (range) 42 (40-47) 48 (29-58) 53 (34-72) 67 (42-74) Hb g/dl (SD) 16.2 (+ 0.9) 20.3 (+ 0.9) 22.8 (+ 1.4) 20.0 (+ 2.5) Ret % (SD) 1.3 (+ 0.1) 2.9 (+ 1.3) 3.6 (+ 1.2) 2.1 (+ 0.3) WBC /ul (SD) 6300 (+ 1600) 7200 (+ 1900) 6600 (+ 1700) 16600 (+ 4800) PLT 103 ul (SD) 273 (+ 80) 229 (+ 58) 193 (+ 54) 604 (+ 177) sEPO mUI/ml (SD) 10.0 (+ 3.9) 10.5 (+ 2.2) 82.9 (+ 30.4) 3.0 (+ 1.2) JAK2 V617F, No. (%) 0 (0) 0 (0) 0 (0) 100 Apoptosis Normal Delayed Normal Delayed BFU-E: EEC 0 (0-0) 10 (2-25) 0 (0-0) 45 (25-70) References: 1. Yu L et al. J Exp Med., 2010, 207:1183. 2. Sharma D et al. Cell Report, 2013, 3:1640. 3. Zhou D et al. Am J Hum Genet. 2013, 93:452. 4. Kapralova K et al. Blood. 2014,123:391 Conclusions a) Endogenous erythroid colony (EEC) are present in Aymaras with CMS, indicating primary polycythemia. b) Endogenous EECs are higher in PV than in CMS. c) CMS subjects have normal serum EPO levels. d) The role of SENP1, and hypoxia-regulated RUNX1 and NF-E2 (4) that promote erythropoiesis, is being interrogated in native erythroid cells. e) It remains to be determined if the autonomous BFU-E growth is specific for Aymara's CMS or present in CMS individuals of other ethnicities. Disclosures No relevant conflicts of interest to declare.
DNA-UMSAgen, EXTRACCIÓN DE DNA GENÓMICO PARA DIAGNÓSTICO MOLECULAR: MÉTODO RÁPIDO Y ECONÓMICO
(2006) Ricardo Amaru; Hortencia Miguez; Rosario Peñaloza; Gina Torres; Julio Silvestre; Heriberto Cuevas
ERITROCITOSIS PATOLÓGICA DE ALTURA: CARACTERIZACIÓN BIOLÓGICA, DIAGNÓSTICO Y TRATAMIENTO
(2013) Ricardo Amaru; Hortencia Miguez; Rosario Peñaloza; Gina Torres; Oscar Vera; Jeaneth Velarde; Nelly Huarachi; Reyna Mamani; Heriberto Cuevas
FILTRO DE AGUA EN LA PREPARACIÓN DE QUIMIOTERAPIA PARA OPTIMIZAR LA BIOSEGURIDAD
(2016) Jeaneth Velarde; Reyna Mamani; Nelly Guarachi; Teddy Quispe; Ricardo Amaru; Heriberto Cuevas
MECANISMO MOLECULAR DE LAS ESTATINAS EN EL TRATAMIENTO DE LA ERITROCITOSIS PATOLÓGICA DE ALTURA
(2013) Ricardo Amaru; Oscar Arturo Vera; Hortencia Miguez; Rosario Peñaloza; Gina Torres; Jeaneth Velarde; Helly Huarachi; Reyna Mamani; Heriberto Cuevas
Successful Treatment of HU-Refractory Polycythemia Vera with Atorvastatin and Low Dose Hydroxyurea. Results from a Pilot Study in Bolivia
(Elsevier BV, 2015) Ricardo Amaru; Ariel Amaru; Hortensia Miguez; Gina Torres; Josué Mamani; María Aguilar; Heriberto Cuevas
Abstract Background Polycythemia Vera (PV) is a clonal myeloproliferative neoplasm, characterized by the JAK2V617F mutation. The main goal of current therapies for PV is to prevent thrombotic events and delay transformation to Myelofibrosis (MF) or Acute Myeloid Leukemia (AML).Treatment for PV to keep an hematocrit (Hct) level <45 %, has been associated with a reduction in cardiovascular deaths and thrombotic events (Marchioli, R et al. NEJM 2013). Currently, low-risk PV patients (<60 years and no previous thrombotic events) are treated with aspirin and phlebotomy while high-risk patients require additional cytoreductive therapy, usually with Hydroxyurea (HU). Resistance to HU is associated with an increased risk of transformation and reduced survival. This is why for HU-refractory patients, second line treatments with interferon alpha, anagrelide or even ruxolitinib are recommended. In Latin America, because of high cost and drugs availability, this last group reflects difficulties to be treated. Because statins have been reported to modulate the erythroid clonogenic activity of normal BM erythroid colonies we performed a pilot study to investigate in vitro and in vivo the biologic and clinical activity of atorvastatin in PV patients Patients and Methods Ten high risk PV patients with a median age of 64.3 years (range 58-73) entered into this study. The diagnosis of PV was done according to the 2008 World Health Organization diagnostic criteria and patients were stratified according to an algorithm proposal provided by Griesshammer et al. (Ann Hematol, 2015). The definition of HU resistance (Barosi, G et al.: BJH 2009) was applicable to five patients (median age 63.9 years) failing to achieve a satisfactory hematologic response upon treatment with more than 2 g of HU, 100 mg of Aspirin and phlebotomies. The assessment of the JAK2V617F mutation was performed as previously described (Guerini et al.: Leukemia 2009). Colony assay, proliferation and apoptosis tests were performed with or without Simvastatin (3.5 uM), as previously described (Amaru, A, Experimental Hematology 2012), on cell lines (UKE1 and K562) and bone marrow mononuclear cells obtained from PV patients and healthy donors. Patients with HU refractory PV (n=5) and high risk PV with hypercholesterolemia (n=5) were eligible to receive Atorvastatin (20 mg/day) added on the top of the ongoing treatment with phlebotomies, Aspirin (100 mg/day) and cytoreductive HU therapy (500 mg/day). All treated patients were high altitude residents (> 3.600 m.a.s.l.) of La Paz (Bolivia) where the normal Hct level of healthy subjects is 48-57% for men and 44-54% for women. This pilot study was approved by the Review Board of the Hospital and the University of San Andres, La Paz. Results In a preliminary set of in vitro proliferation cell assays, simvastatin (3.5 uM), added for 5 days, induced a 33% inhibition of cell proliferation of UKE-1 (JAK2V617F mutated) as compared to 5 % of K562 (BCR/ABL positive). A comparable result was obtained in a 7-day clonogenic cell assay where the colony inhibition was 50 % for UKE-1 and 10 % for K562. On the basis of these results similar experiments were also performed using BM mononuclear cells derived from PV patients and healthy donors. In these experiments performed with the addition of simvastatin, it induced a 41% of inhibition in BFU-E colonies of PV patients and a 25% of inhibition in healthy donors. Furthermore, BFU-E colonies inhibited by simvastatin presented a decrease in hemoglobinization and the size of colonies. HU refractory PV patients and High-risk PV patients with hypercholesterolemia treated with the addition of Atorvastatin, Aspirin, cytoreductive HU and phlebotomies; after a follow-up of 2.6 years (1-7 years), induced a decrease of WBC from 16.500 to 9.270/ul, Hct 61.1 to 52.3% and PLT 457.900,000 to 324.7000/ul. The number of required phlebotomies is reduced in comparison to the required at starting treatment. None of the patients presented thrombotic or cardiopulmonary event. One patient died within two years of starting treatment, due to complications of diabetes mellitus. Conclusions In vitro and in vivo, statins showed some evidence of inhibitory activity of the hematopoiesis of PV patients. These preliminary results might indicate the opportunity to further investigate the potential clinical value of these molecules in the treatment of PV. Disclosures Off Label Use: Atorvastatin was used for its antiproliferative activity on myeloid progenitor cells shown by in vitro experiments.
TERAPIA CELULAR PARA EL TRATAMIENTO DE ÚLCERAS CRÓNICAS
(2016) Ricardo Amaru; Hortencia Miguez; Teddy Quispe; Edwin Quisbert; A. Bruno Miranda; Josué Mamani; Gina Torres; Rosario Peñaloza; Heriberto Cuevas