ABSTRACT
SUMMARY: Gastrin plays a vital role in the development and progression of gastric cancer (GC). Its expression is up-regulated in GC tissues and several GC cell lines. Yet, the underlying mechanism remains to be investigated. Here, we aim to investigate the role and mechanism of gastrin in GC proliferation. Gastrin-overexpressing GC cell model was constructed using SGC7901 cells. Then the differentially expressed proteins were identified by iTRAQ analysis. Next, we use flow cytometry and immunofluorescence to study the effect of gastrin on the mitochondrial potential and mitochondria-derived ROS production. Finally, we studied the underlying mechanism of gastrin regulating mitochondrial function using Co-IP, mass spectrometry and immunofluorescence. Overexpression of gastrin promoted GC cell proliferation in vitro and in vivo. A total of 173 proteins were expressed differently between the controls and gastrin- overexpression cells and most of these proteins were involved in tumorigenesis and cell proliferation. Among them, Cox17, Cox5B and ATP5J that were all localized to the mitochondrial respiratory chain were down-regulated in gastrin-overexpression cells. Furthermore, gastrin overexpression led to mitochondrial potential decrease and mitochondria-derived ROS increase. Additionally, gastrin-induced ROS generation resulted in the inhibition of cell apoptosis via activating NF-kB, inhibiting Bax expression and promoting Bcl-2 expression. Finally, we found gastrin interacted with mitochondrial membrane protein Annexin A2 using Co-IP and mass spectrometry. Overexpr ession of gastrin inhibits GC cell apoptosis by inducing mitochondrial dysfunction through interacting with mitochondrial protein Annexin A2, then up-regulating ROS production to activate NF-kB and further leading to Bax/Bcl-2 ratio decrease.
La gastrina juega un papel vital en el desarrollo y progresión del cáncer gástrico (CG). Su expresión está regulada al alza en tejidos de CG y en varias líneas celulares de CG. Sin embargo, el mecanismo subyacente aun no se ha investigado. El objetivo de este estudio fue investigar el papel y el mecanismo de la gastrina en la proliferación de CG. El modelo de células CG que sobre expresan gastrina se construyó usando células SGC7901. Luego, las proteínas expresadas diferencialmente se identificaron mediante análisis iTRAQ. A continuación, utilizamos la citometría de flujo y la inmunofluorescencia para estudiar el efecto de la gastrina en el potencial mitocondrial y la producción de ROS derivada de las mitocondrias. Finalmente, estudiamos el mecanismo subyacente de la gastrina que regula la función mitocondrial utilizando Co-IP, espectrometría de masas e inmunofluorescencia. La sobreexpresión de gastrina promovió la proliferación de células CG in vitro e in vivo. Un total de 173 proteínas se expresaron de manera diferente entre los controles y las células con sobreexpresión de gastrina y la mayoría de estas proteínas estaban implicadas en la tumorigenesis y la proliferación celular. Entre estas, Cox17, Cox5B y ATP5J, todas localizadas en la cadena respiratoria mitocondrial, estaban reguladas a la baja en las células con sobreexpresión de gastrina. Además, la sobreexpresión de gastrina provocó una disminución del potencial mitocondrial y un aumento de las ROS derivadas de las mitocondrias. Por otra parte, la generación de ROS inducida por gastrina resultó en la inhibición de la apoptosis celular mediante la activación de NF-kB, inhibiendo la expresión de Bax y promoviendo la expresión de Bcl-2. Finalmente, encontramos que la gastrina interactuaba con la proteína de membrana mitocondrial Anexina A2 usando Co-IP y espectrometría de masas. La sobreexpresión de gastrina inhibe la apoptosis de las células CG al inducir la disfunción mitocondrial a través de la interacción con la proteína mitocondrial Anexina A2, luego regula el aumento de la producción de ROS para activar NF-kB y conduce aún más a la disminución de la relación Bax/Bcl-2.
Subject(s)
Animals , Mice , Stomach Neoplasms/metabolism , Stomach Neoplasms/pathology , Gastrins/metabolism , Annexin A2/metabolism , Mitochondria/pathology , Mass Spectrometry , NF-kappa B , Fluorescent Antibody Technique , Reactive Oxygen Species , Apoptosis , Cell Line, Tumor , Immunoprecipitation , Cell Proliferation , Carcinogenesis , Flow CytometryABSTRACT
O Aspergillus fumigatus é o principal agente etiológico da aspergilose invasiva, uma infecção fúngica oportunista que acomete, principalmente, pacientes de Unidades Hematológicas, como aqueles com neutropenia profunda e prolongada. Após a filamentação este fungo angioinvasivo é capaz de ativar e causar danos em células endoteliais de veia umbilical humana (HUVEC) que passam a expressar um fenótipo pró-trombótico. A ativação destas células, dependente de contato célulacélula, é mediada por TNF-α e caracterizada pela expressão de moléculas próinflamatórias, como citocinas, quimiocinas e moléculas de adesão. Recentemente, nosso grupo comparou a ativação endotelial de HUVECs desafiadas com cepas selvagens e uma cepa mutante para o gene UGM1. Nestes experimentos a cepa mutante Δugm1, que apresenta um fenótipo de maior produção de galactosaminogalactana (GAG) na parede celular, mostrou um fenótipo hiperadesivo e uma capacidade maior de ativar células endoteliais. Entretanto, os receptores e as vias de sinalização envolvidos nesta ativação permanecem desconhecidos. Assim, o objetivo deste trabalho foi verificar as proteínas envolvidas nestes processos através do estudo das proteínas diferencialmente expressas nas HUVECs após a interação com A. fumigatus, usando a técnica proteômica 2D-DIGE. Brevemente, as HUVECs foram infectadas com tubos germinativos da cepa selvagem (AF293) e da cepa Δugm1 de A. fumigatus. Em seguida, as proteínas foram marcadas com diferentes fluorocromos e separadas por eletroforese bidimensional. A análise quantitativa foi realizada utilizando o software DeCyder...
Aspergillus fumigatus is the main etiological agent of invasive aspergillosis, the main opportunistic fungal infection of Hematologial Unitys patients, especially those with long-term neutropenia. Upon filamentation, this angioinvasive fungus can activate and damage the human umbilical vein endothelial cells (HUVEC), which in response switch to a pro-thrombotic phenotype. HUVEC activation is mediated by TNF-α once cell-cell contact occurs. This activation is characterized by the expression of pro-inflammatory molecules such cytokines, chemokines and adhesion molecules. Recently, our group performed the comparison of HUVEC activation upon interaction with a wild type and the UGM1 mutant strains of A. fumigatus. The Δugm1 strain, which presents an increased production of the cell wall galactosaminogalactan, showed a hyper adherent phenotype and an increased capability to cause endothelial cell stimulation and activation, when compared with the wild type strain. The receptors involved in the pathogen-host interaction or the signaling pathways after endothelial activation by A. fumigatus remain unknown. Thus, the aim of this study was to investigate the differentially expressed proteins in HUVECs upon interaction with A. fumigatus, using the 2D-DIGE proteomic approach. Briefly, HUVECs were challenged with germlings of A. fumigatus wild type Af293 and Δugm1 strains and then submitted to protein extraction. The total HUVEC protein extracts were labeled with different CyDyes and fractionated by 2D electrophoresis. Quantitative analysis to determine the differences in protein abundance amongst interacted cells vs. control endothelial cells was performed using the software DeCyder. Five differentially expressed proteins were identified by MS/MS including galectin-1 and annexin A2, both overexpressed after the interaction. These two proteins are described elsewhere to be associated with host-pathogen interaction...