RÉSUMÉ
Neutrophil extracellular traps (NETs) were first reported as a microbicidal strategy for activated neutrophils. Through an immunologic response against several stimuli, neutrophils release their DNA together with proteins from granules, nucleus, and cytoplasm (e.g., elastase and myeloperoxidase). To date, NETs have been implicated in tissue damage during intense inflammatory processes, mainly when their release is dependent on oxygen radical generation. Flavonoids are antioxidant and anti-inflammatory agents; of these, quercetin is commonly found in our daily diet. Therefore, quercetin could exert some protective activity against tissue damage induced by NETs. In our in vitro assays, quercetin reduced NETs, myeloperoxidase (MPO), and elastase release from neutrophils stimulated with phorbol 12-myristate 13-acetate (PMA). The activity of these enzymes also decreased in the presence of quercetin. Quercetin also reduced the cytotoxic effect of NETs on alveolar cells (A549 cell line). Further, in silico assays indicated favorable interactions between quercetin and NET proteins (MPO and elastase). Overall, our results demonstrate that quercetin decreases deleterious cellular effects of NETs by reducing their release from activated neutrophils, and diminishing the enzymatic activity of MPO and elastase, possibly through direct interaction.
As armadilhas extracelulares de neutrófilos (NETs) foram relatadas pela primeira vez como uma estratégia microbicida para neutrófilos ativados. Por meio de uma resposta imunológica contra vários estímulos, os neutrófilos liberam seu DNA ligado a proteínas de grânulos, núcleo e citoplasma (por exemplo, elastase e mieloperoxidase). Até o momento, os NETs têm sido implicadas em danos aos tecidos durante processos inflamatórios intensos, principalmente quando sua liberação depende da geração de radicais de oxigênio. Os flavonóides são agentes antioxidantes e anti-inflamatórios, e destes, a quercetina é comumente encontrada em nossa dieta diária. Portanto, a quercetina pode exercer alguma atividade protetora contra o dano tecidual induzido por NETs. Em nossos ensaios in vitro, a quercetina reduziu a liberação das NETs, mieloperoxidase (MPO) e elastase a partir de neutrófilos estimulados com forbol 12-miristato 13-acetato (PMA). A atividade dessas enzimas também foi diminuída na presença de quercetina. A quercetina também reduziu o efeito citotóxico dos NETs sobre células alveolares (linha celular A549). Além disso, os ensaios in silico indicaram interações favoráveis entre a quercetina e as proteínas da NET (MPO e elastase). No geral, nossos resultados demonstram que a quercetina diminui os efeitos deletérios das NETs, reduzindo sua liberação à partir de neutrófilos ativados e diminuindo a atividade enzimática de MPO e elastase, possivelmente por meio de interação direta.
Sujet(s)
Quercétine , Flavonoïdes , Pièges extracellulaires , Immunité , Anti-inflammatoires , Granulocytes neutrophiles , AntioxydantsRÉSUMÉ
The human respiratory syncytial virus (hRSV) is the most common cause of severe lower respiratory tract diseases in young children worldwide, leading to a high number of hospitalizations and significant expenditures for health systems. Neutrophils are massively recruited to the lung tissue of patients with acute respiratory diseases. At the infection site, they release neutrophil extracellular traps (NETs) that can capture and/or inactivate different types of microorganisms, including viruses. Evidence has shown that the accumulation of NETs results in direct cytotoxic effects on endothelial and epithelial cells. Neutrophils stimulated by the hRSV-F protein generate NETs that are able to capture hRSV particles, thus reducing their transmission. However, the massive production of NETs obstructs the airways and increases disease severity. Therefore, further knowledge about the effects of NETs during hRSV infections is essential for the development of new specific and effective treatments. This study evaluated the effects of NETs on the previous or posterior contact with hRSV-infected Hep-2 cells. Hep-2 cells were infected with different hRSV multiplicity of infection (MOI 0.5 or 1.0), either before or after incubation with NETs (0.516 μg/mL). Infected and untreated cells showed decreased cellular viability and intense staining with trypan blue, which was accompanied by the formation of many large syncytia. Previous contact between NETs and cells did not result in a protective effect. Cells in monolayers showed a reduced number and area of syncytia, but cell death was similar in infected and non-treated cells. The addition of NETs to infected tissues maintained a similar virus-induced cell death rate and an increased syncytial area, indicating cytotoxic and deleterious damages. Our results corroborate previously reported findings that NETs contribute to the immunopathology developed by patients infected with hRSV.(AU)
O vírus sincicial respiratório humano (hRSV) é a causa mais comum de doenças graves do trato respiratório inferior em crianças pequenas em todo o mundo, resultando em grande número de hospitalizações e gastos significativos para os sistemas de saúde. Neutrófilos são recrutados em massa para o tecido pulmonar de pacientes com doenças respiratórias agudas. No local da infecção, eles liberam armadilhas extracelulares de neutrófilos (NETs) que podem capturar e/ou inativar diferentes tipos de microrganismos, incluindo vírus. Evidências demonstraram que o acúmulo de NETs resulta em efeitos citotóxicos diretos nas células endoteliais e epiteliais. Os neutrófilos estimulados pela proteína F do vírus sincicial respiratório (hRSV-F) geram NETs que são capazes de capturar partículas virais, reduzindo assim sua transmissão. No entanto, a produção maciça de NETs obstrui as vias aéreas e aumenta a gravidade da doença. Assim, um maior conhecimento sobre os efeitos das NETs durante as infecções por hRSV é essencial para o desenvolvimento de novos tratamentos específicos e eficazes. Este estudo avaliou os efeitos das NETs no contato prévio ou posterior à infecção de células Hep-2 com hRSV. As células Hep-2 foram infectadas com diferentes quantidades de hRSV (multiplicidade de infecção ou MOI 0,5 ou 1,0), antes ou após a incubação com NETs (0,516 μg/mL). Células infectadas e não tratadas mostraram redução da viabilidade celular e intensa coloração com azul de tripano, que foi acompanhada pela formação de sincícios numerosos e grandes. O contato prévio entre as NETs e as células não resultou em efeito protetor. As células em monocamadas mostraram um número e área de sincícios reduzidos, mas a morte celular foi semelhante àquela apresentada por células infectadas e não tratadas. A adição de NETs aos tecidos infectados manteve taxa de morte celular e formação de sincícios [...].(AU)
Sujet(s)
Humains , Virus respiratoire syncytial humain/génétique , Infections à virus respiratoire syncytial , Granulocytes neutrophilesRÉSUMÉ
Abstract The human respiratory syncytial virus (hRSV) is the most common cause of severe lower respiratory tract diseases in young children worldwide, leading to a high number of hospitalizations and significant expenditures for health systems. Neutrophils are massively recruited to the lung tissue of patients with acute respiratory diseases. At the infection site, they release neutrophil extracellular traps (NETs) that can capture and/or inactivate different types of microorganisms, including viruses. Evidence has shown that the accumulation of NETs results in direct cytotoxic effects on endothelial and epithelial cells. Neutrophils stimulated by the hRSV-F protein generate NETs that are able to capture hRSV particles, thus reducing their transmission. However, the massive production of NETs obstructs the airways and increases disease severity. Therefore, further knowledge about the effects of NETs during hRSV infections is essential for the development of new specific and effective treatments. This study evaluated the effects of NETs on the previous or posterior contact with hRSV-infected Hep-2 cells. Hep-2 cells were infected with different hRSV multiplicity of infection (MOI 0.5 or 1.0), either before or after incubation with NETs (0.5-16 μg/mL). Infected and untreated cells showed decreased cellular viability and intense staining with trypan blue, which was accompanied by the formation of many large syncytia. Previous contact between NETs and cells did not result in a protective effect. Cells in monolayers showed a reduced number and area of syncytia, but cell death was similar in infected and non-treated cells. The addition of NETs to infected tissues maintained a similar virus-induced cell death rate and an increased syncytial area, indicating cytotoxic and deleterious damages. Our results corroborate previously reported findings that NETs contribute to the immunopathology developed by patients infected with hRSV.
Resumo O vírus sincicial respiratório humano (hRSV) é a causa mais comum de doenças graves do trato respiratório inferior em crianças pequenas em todo o mundo, resultando em grande número de hospitalizações e gastos significativos para os sistemas de saúde. Neutrófilos são recrutados em massa para o tecido pulmonar de pacientes com doenças respiratórias agudas. No local da infecção, eles liberam armadilhas extracelulares de neutrófilos (NETs) que podem capturar e/ou inativar diferentes tipos de microrganismos, incluindo vírus. Evidências demonstraram que o acúmulo de NETs resulta em efeitos citotóxicos diretos nas células endoteliais e epiteliais. Os neutrófilos estimulados pela proteína F do vírus sincicial respiratório (hRSV-F) geram NETs que são capazes de capturar partículas virais, reduzindo assim sua transmissão. No entanto, a produção maciça de NETs obstrui as vias aéreas e aumenta a gravidade da doença. Assim, um maior conhecimento sobre os efeitos das NETs durante as infecções por hRSV é essencial para o desenvolvimento de novos tratamentos específicos e eficazes. Este estudo avaliou os efeitos das NETs no contato prévio ou posterior à infecção de células Hep-2 com hRSV. As células Hep-2 foram infectadas com diferentes quantidades de hRSV (multiplicidade de infecção ou MOI 0,5 ou 1,0), antes ou após a incubação com NETs (0,5-16 μg/mL). Células infectadas e não tratadas mostraram redução da viabilidade celular e intensa coloração com azul de tripano, que foi acompanhada pela formação de sincícios numerosos e grandes. O contato prévio entre as NETs e as células não resultou em efeito protetor. As células em monocamadas mostraram um número e área de sincícios reduzidos, mas a morte celular foi semelhante àquela apresentada por células infectadas e não tratadas. A adição de NETs aos tecidos infectados manteve taxa de morte celular e formação de sincícios semelhantes àqueles induzidos pelo vírus em células não tratadas, indicando danos citotóxicos e deletérios. Nossos resultados corroboram achados relatados anteriormente de que as NETs contribuem para a imunopatologia desenvolvida por pacientes infectados com hRSV.
Sujet(s)
Humains , Enfant d'âge préscolaire , Virus respiratoire syncytial humain , Infections à virus respiratoire syncytial , Pièges extracellulaires , Cellules épithéliales , PoumonRÉSUMÉ
The human respiratory syncytial virus (hRSV) is the most common cause of severe lower respiratory tract diseases in young children worldwide, leading to a high number of hospitalizations and significant expenditures for health systems. Neutrophils are massively recruited to the lung tissue of patients with acute respiratory diseases. At the infection site, they release neutrophil extracellular traps (NETs) that can capture and/or inactivate different types of microorganisms, including viruses. Evidence has shown that the accumulation of NETs results in direct cytotoxic effects on endothelial and epithelial cells. Neutrophils stimulated by the hRSV-F protein generate NETs that are able to capture hRSV particles, thus reducing their transmission. However, the massive production of NETs obstructs the airways and increases disease severity. Therefore, further knowledge about the effects of NETs during hRSV infections is essential for the development of new specific and effective treatments. This study evaluated the effects of NETs on the previous or posterior contact with hRSV-infected Hep-2 cells. Hep-2 cells were infected with different hRSV multiplicity of infection (MOI 0.5 or 1.0), either before or after incubation with NETs (0.516 μg/mL). Infected and untreated cells showed decreased cellular viability and intense staining with trypan blue, which was accompanied by the formation of many large syncytia. Previous contact between NETs and cells did not result in a protective effect. Cells in monolayers showed a reduced number and area of syncytia, but cell death was similar in infected and non-treated cells. The addition of NETs to infected tissues maintained a similar virus-induced cell death rate and an increased syncytial area, indicating cytotoxic and deleterious damages. Our results corroborate previously reported findings that NETs contribute to the immunopathology developed by patients infected with hRSV.
O vírus sincicial respiratório humano (hRSV) é a causa mais comum de doenças graves do trato respiratório inferior em crianças pequenas em todo o mundo, resultando em grande número de hospitalizações e gastos significativos para os sistemas de saúde. Neutrófilos são recrutados em massa para o tecido pulmonar de pacientes com doenças respiratórias agudas. No local da infecção, eles liberam armadilhas extracelulares de neutrófilos (NETs) que podem capturar e/ou inativar diferentes tipos de microrganismos, incluindo vírus. Evidências demonstraram que o acúmulo de NETs resulta em efeitos citotóxicos diretos nas células endoteliais e epiteliais. Os neutrófilos estimulados pela proteína F do vírus sincicial respiratório (hRSV-F) geram NETs que são capazes de capturar partículas virais, reduzindo assim sua transmissão. No entanto, a produção maciça de NETs obstrui as vias aéreas e aumenta a gravidade da doença. Assim, um maior conhecimento sobre os efeitos das NETs durante as infecções por hRSV é essencial para o desenvolvimento de novos tratamentos específicos e eficazes. Este estudo avaliou os efeitos das NETs no contato prévio ou posterior à infecção de células Hep-2 com hRSV. As células Hep-2 foram infectadas com diferentes quantidades de hRSV (multiplicidade de infecção ou MOI 0,5 ou 1,0), antes ou após a incubação com NETs (0,516 μg/mL). Células infectadas e não tratadas mostraram redução da viabilidade celular e intensa coloração com azul de tripano, que foi acompanhada pela formação de sincícios numerosos e grandes. O contato prévio entre as NETs e as células não resultou em efeito protetor. As células em monocamadas mostraram um número e área de sincícios reduzidos, mas a morte celular foi semelhante àquela apresentada por células infectadas e não tratadas. A adição de NETs aos tecidos infectados manteve taxa de morte celular e formação de sincícios [...].
Sujet(s)
Humains , Infections à virus respiratoire syncytial , Granulocytes neutrophiles , Virus respiratoire syncytial humain/génétiqueRÉSUMÉ
Abstract The human respiratory syncytial virus (hRSV) is the most common cause of severe lower respiratory tract diseases in young children worldwide, leading to a high number of hospitalizations and significant expenditures for health systems. Neutrophils are massively recruited to the lung tissue of patients with acute respiratory diseases. At the infection site, they release neutrophil extracellular traps (NETs) that can capture and/or inactivate different types of microorganisms, including viruses. Evidence has shown that the accumulation of NETs results in direct cytotoxic effects on endothelial and epithelial cells. Neutrophils stimulated by the hRSV-F protein generate NETs that are able to capture hRSV particles, thus reducing their transmission. However, the massive production of NETs obstructs the airways and increases disease severity. Therefore, further knowledge about the effects of NETs during hRSV infections is essential for the development of new specific and effective treatments. This study evaluated the effects of NETs on the previous or posterior contact with hRSV-infected Hep-2 cells. Hep-2 cells were infected with different hRSV multiplicity of infection (MOI 0.5 or 1.0), either before or after incubation with NETs (0.516 g/mL). Infected and untreated cells showed decreased cellular viability and intense staining with trypan blue, which was accompanied by the formation of many large syncytia. Previous contact between NETs and cells did not result in a protective effect. Cells in monolayers showed a reduced number and area of syncytia, but cell death was similar in infected and non-treated cells. The addition of NETs to infected tissues maintained a similar virus-induced cell death rate and an increased syncytial area, indicating cytotoxic and deleterious damages. Our results corroborate previously reported findings that NETs contribute to the immunopathology developed by patients infected with hRSV.
Resumo O vírus sincicial respiratório humano (hRSV) é a causa mais comum de doenças graves do trato respiratório inferior em crianças pequenas em todo o mundo, resultando em grande número de hospitalizações e gastos significativos para os sistemas de saúde. Neutrófilos são recrutados em massa para o tecido pulmonar de pacientes com doenças respiratórias agudas. No local da infecção, eles liberam armadilhas extracelulares de neutrófilos (NETs) que podem capturar e/ou inativar diferentes tipos de microrganismos, incluindo vírus. Evidências demonstraram que o acúmulo de NETs resulta em efeitos citotóxicos diretos nas células endoteliais e epiteliais. Os neutrófilos estimulados pela proteína F do vírus sincicial respiratório (hRSV-F) geram NETs que são capazes de capturar partículas virais, reduzindo assim sua transmissão. No entanto, a produção maciça de NETs obstrui as vias aéreas e aumenta a gravidade da doença. Assim, um maior conhecimento sobre os efeitos das NETs durante as infecções por hRSV é essencial para o desenvolvimento de novos tratamentos específicos e eficazes. Este estudo avaliou os efeitos das NETs no contato prévio ou posterior à infecção de células Hep-2 com hRSV. As células Hep-2 foram infectadas com diferentes quantidades de hRSV (multiplicidade de infecção ou MOI 0,5 ou 1,0), antes ou após a incubação com NETs (0,516 g/mL). Células infectadas e não tratadas mostraram redução da viabilidade celular e intensa coloração com azul de tripano, que foi acompanhada pela formação de sincícios numerosos e grandes. O contato prévio entre as NETs e as células não resultou em efeito protetor. As células em monocamadas mostraram um número e área de sincícios reduzidos, mas a morte celular foi semelhante àquela apresentada por células infectadas e não tratadas. A adição de NETs aos tecidos infectados manteve taxa de morte celular e formação de sincícios semelhantes àqueles induzidos pelo vírus em células não tratadas, indicando danos citotóxicos e deletérios. Nossos resultados corroboram achados relatados anteriormente de que as NETs contribuem para a imunopatologia desenvolvida por pacientes infectados com hRSV.
RÉSUMÉ
Neutrophil extracellular traps (NETs) were first reported as a microbicidal strategy for activated neutrophils. Through an immunologic response against several stimuli, neutrophils release their DNA together with proteins from granules, nucleus, and cytoplasm (e.g., elastase and myeloperoxidase). To date, NETs have been implicated in tissue damage during intense inflammatory processes, mainly when their release is dependent on oxygen radical generation. Flavonoids are antioxidant and anti-inflammatory agents; of these, quercetin is commonly found in our daily diet. Therefore, quercetin could exert some protective activity against tissue damage induced by NETs. In our in vitro assays, quercetin reduced NETs, myeloperoxidase (MPO), and elastase release from neutrophils stimulated with phorbol 12-myristate 13-acetate (PMA). The activity of these enzymes also decreased in the presence of quercetin. Quercetin also reduced the cytotoxic effect of NETs on alveolar cells (A549 cell line). Further, in silico assays indicated favorable interactions between quercetin and NET proteins (MPO and elastase). Overall, our results demonstrate that quercetin decreases deleterious cellular effects of NETs by reducing their release from activated neutrophils, and diminishing the enzymatic activity of MPO and elastase, possibly through direct interaction.
Sujet(s)
Pièges extracellulaires , Cellules A549 , Pièges extracellulaires/métabolisme , Humains , Pancreatic elastase/métabolisme , Myeloperoxidase , Quercétine/pharmacologie , 12-Myristate-13-acétate de phorbol/métabolisme , 12-Myristate-13-acétate de phorbol/pharmacologieRÉSUMÉ
The human respiratory syncytial virus (hRSV) is the most common cause of severe lower respiratory tract diseases in young children worldwide, leading to a high number of hospitalizations and significant expenditures for health systems. Neutrophils are massively recruited to the lung tissue of patients with acute respiratory diseases. At the infection site, they release neutrophil extracellular traps (NETs) that can capture and/or inactivate different types of microorganisms, including viruses. Evidence has shown that the accumulation of NETs results in direct cytotoxic effects on endothelial and epithelial cells. Neutrophils stimulated by the hRSV-F protein generate NETs that are able to capture hRSV particles, thus reducing their transmission. However, the massive production of NETs obstructs the airways and increases disease severity. Therefore, further knowledge about the effects of NETs during hRSV infections is essential for the development of new specific and effective treatments. This study evaluated the effects of NETs on the previous or posterior contact with hRSV-infected Hep-2 cells. Hep-2 cells were infected with different hRSV multiplicity of infection (MOI 0.5 or 1.0), either before or after incubation with NETs (0.5-16 µg/mL). Infected and untreated cells showed decreased cellular viability and intense staining with trypan blue, which was accompanied by the formation of many large syncytia. Previous contact between NETs and cells did not result in a protective effect. Cells in monolayers showed a reduced number and area of syncytia, but cell death was similar in infected and non-treated cells. The addition of NETs to infected tissues maintained a similar virus-induced cell death rate and an increased syncytial area, indicating cytotoxic and deleterious damages. Our results corroborate previously reported findings that NETs contribute to the immunopathology developed by patients infected with hRSV.