Redox imbalance induces remodeling of glucose metabolism in Rhipicephalus microplus embryonic cell line
dc.contributor.author | Noce, Bárbara Pitta Della | pt_BR |
dc.contributor.author | Silva, Renato Martins da | pt_BR |
dc.contributor.author | Uhl, Marcelle Vianna de Carvalho | pt_BR |
dc.contributor.author | Konnai, Satoru | pt_BR |
dc.contributor.author | Ohashi, Kazuhiko | pt_BR |
dc.contributor.author | Calixto, Christiano | pt_BR |
dc.contributor.author | Sampaio, Angélica Fernandes Arcanjo | pt_BR |
dc.contributor.author | Abreu, Leonardo Araujo de | pt_BR |
dc.contributor.author | Carvalho, Stephanie Serafim de | pt_BR |
dc.contributor.author | Vaz Junior, Itabajara da Silva | pt_BR |
dc.contributor.author | Logullo, Carlos | pt_BR |
dc.date.accessioned | 2022-04-13T04:50:35Z | pt_BR |
dc.date.issued | 2022 | pt_BR |
dc.identifier.issn | 0021-9258 | pt_BR |
dc.identifier.uri | http://hdl.handle.net/10183/237082 | pt_BR |
dc.description.abstract | Carbohydrate metabolism not only functions in supplying cellular energy but also has an important role in maintaining physiological homeostasis and in preventing oxidative damage caused by reactive oxygen species. Previously, we showed that arthropod embryonic cell lines have high tolerance to H²O² exposure. Here, we describe that Rhipicephalus microplus tick embryonic cell line (BME26) employs an adaptive glucose metabolism mechanism that confers tolerance to hydrogen peroxide at concentrations too high for other organisms. This adaptive mechanism sustained by glucose metabolism remodeling promotes cell survival and redox balance in BME26 cell line after millimolar H²O² exposure. The present work shows that this tick cell line could tolerate high H²O² concentrations by initiating a carbohydrate-related adaptive response. We demonstrate that gluconeogenesis was induced as a compensation strategy that involved, among other molecules, the metabolic enzymes NADP-ICDH, G6PDH, and PEPCK. We also found that this phenomenon was coupled to glycogen accumulation and glucose uptake, supporting the pentose phosphate pathway to sustain NADPH production and leading to cell survival and proliferation. Our findings suggest that the described response is not atypical, being also observed in cancer cells, which highlights the importance of this model to all proliferative cells. We propose that these results will be useful in generating basic biological information to support the development of new strategies for disease treatment and parasite control. | en |
dc.format.mimetype | application/pdf | pt_BR |
dc.language.iso | eng | pt_BR |
dc.relation.ispartof | The journal of biological chemistry. New York. Vol. 298, no. 3 (Mar. 2022), 101599, 16 p. | pt_BR |
dc.rights | Open Access | en |
dc.subject | Gluconeogênese | pt_BR |
dc.subject | Metabolism | en |
dc.subject | Glucose | en |
dc.subject | Células embrionárias | pt_BR |
dc.subject | Embryogenesis | en |
dc.subject | Rhipicephalus microplus | pt_BR |
dc.subject | Peróxido de hidrogênio | pt_BR |
dc.subject | Arthropod | en |
dc.subject | ROS | en |
dc.subject | Oxirredução | pt_BR |
dc.subject | Células tumorais | pt_BR |
dc.title | Redox imbalance induces remodeling of glucose metabolism in Rhipicephalus microplus embryonic cell line | pt_BR |
dc.type | Artigo de periódico | pt_BR |
dc.identifier.nrb | 001138029 | pt_BR |
dc.type.origin | Estrangeiro | pt_BR |
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