RESUMO
Nicotinamide riboside (NR), a NAD+ precursor, has received attention due to several health benefits it has induced in experimental models. Studies in cultured cells, animals, and humans consistently show increased NAD+ availability after NR supplementation, which is considered the only mode of NR action that leads to health benefits. In the present study, we show that a persistently low NR concentration (1 µM) in the growth medium of BEAS-2B human cells, grown in a monolayer, induces energy stress, which precedes a cellular NAD+ increase after 192 h. NR concentrations greater than 1 µM under the specified conditions were cytotoxic in the 2D cell culture model, while all concentrations tested in the 3D cell culture model (BEAS-2B cell spheroids exposed to 1, 5, 10, and 50 µM NR) induced apoptosis. Shotgun proteomics revealed that NR modulated the abundance of proteins, agreeing with the observed effects on cellular energy metabolism and cell growth or survival. Energy stress may activate pathways that lead to health benefits such as cancer prevention. Accordingly, the premalignant 1198 cell line was more sensitive to NR cytotoxicity than the phenotypically normal parent BEAS-2B cell line. The role of a mild energy stress induced by low concentrations of NR in its beneficial effects deserves further investigation. On the other hand, strategies to increase the bioavailability of NR require attention to toxic effects that may arise.
RESUMO
A reprogramação metabólica de células do câncer é apontada como uma característica essencial para o desenvolvimento da doença (cancer hallmark). Estudos mostram que mutações na enzima fumarato hidratase levam ao aumento da concentração intra e extracelular de fumarato, o que ocorre paralelamente à indução da transformação maligna. Neste trabalho, a fim de entender se o excesso de fumarato extracelular pode propiciar a transformação de células normais, foram quantificados alguns endpoints relacionados aos efeitos do fumarato e à transformação maligna, além de alterações metabólicas em células imortalizadas de epitélio brônquico humano normal (BEAS-2B) expostas ao fumarato. Uma vez que fumarato nas concentrações de 0,1 a 10 mM ao longo de 144 h não foi citotóxico, foram selecionadas as concentrações de 1 mM, 5 mM e 10 mM para as incubações. Fumarato induziu a formação de colônias em soft-agar após o período de sete dias (168 h) de exposição, o que indica a indução de transformação celular. Fumarato é um oncometabólito que inibe enzimas que dependem de α-cetoglutarato como co-substrato, dentre as quais as enzimas ten eleven translocation (TET) que catalisam a formação de 5-hidroximetilcitosina (5-hmC) a partir de 5-metilcitosina (5-mC), o primeiro passo da sequência de reações que levam à desmetilação do DNA. Os níveis totais de 5-hmC estavam diminuídos no DNA das células expostas. Colônias retiradas do soft-agar (controle, 1, 5 e 10 mM de fumarato) foram cultivadas e, após 90 dias em cultura, as células foram submetidas ao ensaio de invasão e migração em câmara de Boyden (transwell), tendo sido observada maior capacidade de migração/invasão das células anteriormente expostas ao fumarato. Foi observada indução de estresse redox nas células expostas ao fumarato. A partir da quantificação de metabólitos intracelulares por HPLC-ESI-MS/MS e HPLC-ESI-Q-TOF, verificamos que as células BEAS-2B absorveram o fumarato adicionado ao meio de cultura, o qual foi convertido intracelularmente a malato, aspartato, argininosuccinato, citrato, succinato e glutamato. O oncometabólito 2-L-hidroxiglutarato foi detectado em níveis aumentados nas células expostas a fumarato, assim como adenosina, enquanto que NAD+ e NADP+ apareceram diminuídos. As alterações metabólicas na presença de fumarato contribuíram para a manutenção do balanço energético das células, ou mesmo para um saldo positivo de energia. A exposição das células a [13C4]fumarato permitiu a análise do fluxo inicial do fumarato absorvido pelas células. A partir dessa análise verificamos que o fumarato absorvido entra no ciclo de Krebs, gerando malato, que é em grande parte desviado para reações externas ao ciclo, como a geração de aspartato e argininosuccinato. Citrato proveniente das reações de [13C4]fumarato no ciclo de Krebs foi detectado em níveis inferiores aos endógenos. O uso de [13C4]fumarato permitiu a visualização da geração de [13C4]succinato, que tem como possível fonte a atividade reversa da succinato desidrogenase. Verificamos também a geração de [13C3]glutamato. Supõe-se que as alterações metabólicas induzidas pelo fumarato absorvido pelas células BEAS-2B contribuam para a modulação da expressão de genes e da atividade de proteínas que favorecem o processo tumorigênico
The metabolic reprogramming of cancer cells is identified as an essential feature for the development of the disease (a cancer hallmark). Studies show that mutations in the enzyme fumarate hydratase lead to increased intra- and extracellular fumarate concentration, which occurs in parallel with the induction of malignant transformation. In this work, in order to understand if excess extracellular fumarate can lead to the transformation of normal cells, some endpoints related to the effects of fumarate and malignant transformation were quantified, as well as metabolic alterations in the immortalized normal human bronchial epithelial cell line BEAS-2B exposed to fumarate. Since fumarate at concentrations from 0.1 to 10 mM over 144 h was not cytotoxic, the concentrations of 1 mM, 5 mM and 10 mM were selected for incubations. Fumarate induced colony formation in soft agar after the seven day (168 h) exposure period, which indicates the induction of cell transformation. Fumarate is an oncometabolite that inhibits α-ketoglutarate-dependent enzymes, among which are ten eleven translocation (TET) enzymes that catalyze the formation of 5-hydroxymethylcytosine (5-hmC) from 5-methylcytosine (5-mC), the first step in the sequence of reactions leading to DNA demethylation. Total 5-hmC levels were decreased in the DNA of exposed cells. Colonies removed from the soft-agar (control, 1, 5 and 10 mM fumarate) were cultured and after 90 days in culture the cells were subjected to the Boyden chamber (transwell) invasion and migration assay, and a greater capacity for migration/invasion of cells previously exposed to fumarate was observed. Redox stress induction was observed in cells exposed to fumarate. From the quantification of intracellular metabolites by HPLC-ESI-MS/MS and HPLC-ESI-Q-TOF, we found that BEAS-2B cells absorbed the fumarate added to the culture medium, which was intracellularly converted to malate, aspartate, argininosuccinate, citrate, succinate and glutamate. The oncometabolite 2-L-hydroxyglutarate was detected at increased levels in cells exposed to fumarate, as well as adenosine, while NAD+ and NADP+ appeared decreased. Metabolic changes in the presence of fumarate contributed to the maintenance of the energy balance of the cells, or even to a positive energy balance. Exposure of cells to [13C4]fumarate allowed the analysis of the initial flow of the fumarate absorbed by the cells. From this analysis we found that the absorbed fumarate entered the Krebs cycle, generating malate, which was largely diverted to reactions outside the cycle, such as the generation of aspartate and argininosuccinate. Citrate from the reactions of [13C4]fumarate in the Krebs cycle was detected at levels lower than endogenous. The use of [13C4]fumarate allowed the detection of [13C4]succinate, which has as its possible source the reverse activity of succinate dehydrogenase. We also observed the generation of [13C3]glutamate. The metabolic changes induced by the absorbed fumarate are supposed to contribute to the modulation of gene expression and protein activity that favor the tumorigenic process
