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Autori principali: Silva, Tatiana, Alves, Célia, Evtyugina, Margarita G, Dias, Ana S, Pereira, Guilherme Martins, de Castro Vasconcellos, Pérola, de Fátima Andrade, Maria, Oliveira, Helena, Duarte, Iola F
Natura: Artículo científico
Lingua:en
Pubblicazione: Environmental toxicology and pharmacology 2025
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Accesso online:https://pubmed.ncbi.nlm.nih.gov/40311788/
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author Silva, Tatiana
Alves, Célia
Evtyugina, Margarita G
Dias, Ana S
Pereira, Guilherme Martins
de Castro Vasconcellos, Pérola
de Fátima Andrade, Maria
Oliveira, Helena
Duarte, Iola F
author_facet Silva, Tatiana
Alves, Célia
Evtyugina, Margarita G
Dias, Ana S
Pereira, Guilherme Martins
de Castro Vasconcellos, Pérola
de Fátima Andrade, Maria
Oliveira, Helena
Duarte, Iola F
Silva, Tatiana
Alves, Célia
Evtyugina, Margarita G
Dias, Ana S
Pereira, Guilherme Martins
de Castro Vasconcellos, Pérola
de Fátima Andrade, Maria
Oliveira, Helena
Duarte, Iola F
collection PubMed - marine biology
contents Cytotoxic and metabolic effects of organic extracts from airborne fine particulate matter (PM) in neuronal cells. Silva, Tatiana Alves, Célia Evtyugina, Margarita G Dias, Ana S Pereira, Guilherme Martins de Castro Vasconcellos, Pérola de Fátima Andrade, Maria Oliveira, Helena Duarte, Iola F Particulate Matter Humans Air Pollutants Neurons Cell Line, Tumor Apoptosis Cell Survival Oxidative Stress Energy Metabolism Airborne fine particulate matter (PM) has been linked to neurological diseases, but its cellular and metabolic effects remain incompletely understood. This study assessed the cytotoxic and metabolic impact of PM samples from São Paulo, Brazil, on SH-SY5Y neuroblastoma cells. Even at low toxicity levels (IC-IC), PM organic extracts induced apoptosis, increased TNF-α secretion, and triggered moderate oxidative responses. Metabolomic analyses revealed a downregulation of energy-producing pathways, including glycolysis and the TCA cycle, along with decreased ATP and phosphocreatine levels. Compensatory adaptations were evident, such as increased proline oxidation, lipid accumulation, and activation of the creatine-phosphocreatine system. One-carbon metabolism was also affected, with changes suggesting suppression of the folate and methionine cycles. Elevated glutathione levels indicated an enhanced antioxidant response. These findings highlight how PM disrupts neuronal energy homeostasis and redox balance, offering new insights into the cellular mechanisms of air pollution-related neurotoxicity.
format Artículo científico
id pubmed_40311788
institution PubMed
language en
publishDate 2025
publisher Environmental toxicology and pharmacology
record_format pubmed
spellingShingle Cytotoxic and metabolic effects of organic extracts from airborne fine particulate matter (PM) in neuronal cells.
Silva, Tatiana
Alves, Célia
Evtyugina, Margarita G
Dias, Ana S
Pereira, Guilherme Martins
de Castro Vasconcellos, Pérola
de Fátima Andrade, Maria
Oliveira, Helena
Duarte, Iola F
Particulate Matter
Humans
Air Pollutants
Neurons
Cell Line, Tumor
Apoptosis
Cell Survival
Oxidative Stress
Energy Metabolism
Cytotoxic and metabolic effects of organic extracts from airborne fine particulate matter (PM) in neuronal cells. Silva, Tatiana Alves, Célia Evtyugina, Margarita G Dias, Ana S Pereira, Guilherme Martins de Castro Vasconcellos, Pérola de Fátima Andrade, Maria Oliveira, Helena Duarte, Iola F Particulate Matter Humans Air Pollutants Neurons Cell Line, Tumor Apoptosis Cell Survival Oxidative Stress Energy Metabolism Airborne fine particulate matter (PM) has been linked to neurological diseases, but its cellular and metabolic effects remain incompletely understood. This study assessed the cytotoxic and metabolic impact of PM samples from São Paulo, Brazil, on SH-SY5Y neuroblastoma cells. Even at low toxicity levels (IC-IC), PM organic extracts induced apoptosis, increased TNF-α secretion, and triggered moderate oxidative responses. Metabolomic analyses revealed a downregulation of energy-producing pathways, including glycolysis and the TCA cycle, along with decreased ATP and phosphocreatine levels. Compensatory adaptations were evident, such as increased proline oxidation, lipid accumulation, and activation of the creatine-phosphocreatine system. One-carbon metabolism was also affected, with changes suggesting suppression of the folate and methionine cycles. Elevated glutathione levels indicated an enhanced antioxidant response. These findings highlight how PM disrupts neuronal energy homeostasis and redox balance, offering new insights into the cellular mechanisms of air pollution-related neurotoxicity.
title Cytotoxic and metabolic effects of organic extracts from airborne fine particulate matter (PM) in neuronal cells.
topic Particulate Matter
Humans
Air Pollutants
Neurons
Cell Line, Tumor
Apoptosis
Cell Survival
Oxidative Stress
Energy Metabolism
url https://pubmed.ncbi.nlm.nih.gov/40311788/