BACKGROUND INFORMATION: In eukaryotic cells, autophagy is considered a lysosomal catabolic process which participates in the degradation of intracellular components in a vacuolar structure termed autolysosome. This pathway plays a significant role in the erythropoiesis process, contributing to the clearance of some organelles (such as mitochondria) that are not necessary in the mature red blood cells. Nevertheless, the role of autophagy in erythrocyte maturation has not been fully established. RESULTS: Here, we have demonstrated that hemin (a physiological erythroid maturation stimulator) is able to induce the expression of critical autophagic genes (i.e., Map1a1b (LC3), Beclin-1 gen, Atg5) in an erythroleukemia cell type. We have also shown that hemin increased the size of autophagic vacuoles which were labelled with LC3 and the degradative lysosomal marker dye quenched-bovine serum albumin. In addition, we have determined by Western blot a rise in the lipidated form of the autophagic protein LC3 (i.e., LC3-II) upon hemin treatment. Moreover, we provide evidence that hemin induces mitochondrial membrane depolarisation and that mitochondria sequestration by autophagy requires the active form of the NIX protein. CONCLUSIONS: We have found that the physiological erythroid maturation stimulator hemin is able to induce mitophagy in K562 cells, and that the autophagy adaptor NIX is necessary for mitophagy progression. K562 cells have been used as a relevant model to determine the possible therapeutic role of new differentiating compounds. SIGNIFICANCE: It has been proposed that autophagy induction is a feasible new therapeutic key in fighting cancer. Our results suggest that hemin is favoring erythroid maturation by inducing an autophagic response in K562 cells, being a possible therapeutic candidate that may help in the chronic myelogenous leukemia (CML) treatment.
BACKGROUND INFORMATION: In eukaryotic cells, autophagy is considered a lysosomal catabolic process which participates in the degradation of intracellular components in a vacuolar structure termed autolysosome. This pathway plays a significant role in the erythropoiesis process, contributing to the clearance of some organelles (such as mitochondria) that are not necessary in the mature red blood cells. Nevertheless, the role of autophagy in erythrocyte maturation has not been fully established. RESULTS: Here, we have demonstrated that hemin (a physiological erythroid maturation stimulator) is able to induce the expression of critical autophagic genes (i.e., Map1a1b (LC3), Beclin-1 gen, Atg5) in an erythroleukemia cell type. We have also shown that hemin increased the size of autophagic vacuoles which were labelled with LC3 and the degradative lysosomal marker dye quenched-bovine serum albumin. In addition, we have determined by Western blot a rise in the lipidated form of the autophagic protein LC3 (i.e., LC3-II) upon hemin treatment. Moreover, we provide evidence that hemin induces mitochondrial membrane depolarisation and that mitochondria sequestration by autophagy requires the active form of the NIX protein. CONCLUSIONS: We have found that the physiological erythroid maturation stimulator hemin is able to induce mitophagy in K562 cells, and that the autophagy adaptor NIX is necessary for mitophagy progression. K562 cells have been used as a relevant model to determine the possible therapeutic role of new differentiating compounds. SIGNIFICANCE: It has been proposed that autophagy induction is a feasible new therapeutic key in fighting cancer. Our results suggest that hemin is favoring erythroid maturation by inducing an autophagic response in K562 cells, being a possible therapeutic candidate that may help in the chronic myelogenous leukemia (CML) treatment.
Authors: Lorenzo Galluzzi; Eric H Baehrecke; Andrea Ballabio; Patricia Boya; José Manuel Bravo-San Pedro; Francesco Cecconi; Augustine M Choi; Charleen T Chu; Patrice Codogno; Maria Isabel Colombo; Ana Maria Cuervo; Jayanta Debnath; Vojo Deretic; Ivan Dikic; Eeva-Liisa Eskelinen; Gian Maria Fimia; Simone Fulda; David A Gewirtz; Douglas R Green; Malene Hansen; J Wade Harper; Marja Jäättelä; Terje Johansen; Gabor Juhasz; Alec C Kimmelman; Claudine Kraft; Nicholas T Ktistakis; Sharad Kumar; Beth Levine; Carlos Lopez-Otin; Frank Madeo; Sascha Martens; Jennifer Martinez; Alicia Melendez; Noboru Mizushima; Christian Münz; Leon O Murphy; Josef M Penninger; Mauro Piacentini; Fulvio Reggiori; David C Rubinsztein; Kevin M Ryan; Laura Santambrogio; Luca Scorrano; Anna Katharina Simon; Hans-Uwe Simon; Anne Simonsen; Nektarios Tavernarakis; Sharon A Tooze; Tamotsu Yoshimori; Junying Yuan; Zhenyu Yue; Qing Zhong; Guido Kroemer Journal: EMBO J Date: 2017-06-08 Impact factor: 11.598
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Authors: Ruben Adrian Grosso; Paula Virginia Subirada Caldarone; María Cecilia Sánchez; Gustavo Alberto Chiabrando; María Isabel Colombo; Claudio Marcelo Fader Journal: Biosci Rep Date: 2019-01-03 Impact factor: 3.840
Authors: Vanessa Araujo Gomes Santaterra; Maiara Marx Luz Fiusa; Bidossessi Wilfried Hounkpe; Francine Chenou; Wouitchekpo Vincent Tonasse; Loredana Nilkenes Gomes da Costa; Diego Garcia-Weber; Igor de Farias Domingos; Franciele de Lima; Ivanio Teixeira Borba-Junior; Aderson da Silva Araújo; Antonio Roberto Lucena-Araújo; Marcos André Cavalcante Bezerra; Magnun Nueldo Nunes Dos Santos; Fernando Ferreira Costa; Jaime Millán; Erich Vinicius De Paula Journal: Front Immunol Date: 2020-12-14 Impact factor: 7.561