Bisphenol A exposure affects specific gut taxa and drives microbiota dynamics in childhood obesity
Metadatos
Mostrar el registro completo del ítemAutor
López Moreno, Ana; Cerk, Klara; Rodrigo Conde Salazar, Lourdes T.; Suárez García, Antonio Francisco; Aguilera Gómez, Margarita; Ruiz Rodríguez, AliciaEditorial
American Society for Microbiology
Materia
Xenobiotics BPA Obesity
Fecha
2024-03-01Referencia bibliográfica
Lopez-Moreno A, Cerk K, Rodrigo L, Suarez A, Aguilera M, Ruiz-Rodriguez A.2024.Bisphenol A exposure affects specific gut taxa and drives microbiota dynamics in childhood obesity. mSystems9:e00957-23.https://doi.org/10.1128/msystems.00957-23
Patrocinador
European Food Safety Authority (EFSA) (EUFORA/GP/EFSA/ENCO/2021/01); UGR | Vicerrectorado de Investigación y Transferencia, Universidad de Granada (Office of Vice-Rector for Research and Knowledge Transfer, University of Granada) (MARIA ZAMBRANO Next Generation EU); Consejería de Universidad, Investigación e Innovación, Junta de Andalucía (Ministry of Knowledge, Research and University, Andalusia) (Proyectos-Excelencia: P21-00341 DiETOXμBio)Resumen
Cumulative xenobiotic exposure has an environmental and human health impact which is currently assessed under the One Health approach. Bisphenol A (BPA) exposure and its potential link with childhood obesity that has parallelly increased during the last decades deserve special attention. It stands during prenatal or early life and could trigger comorbidities and non-communicable diseases along life. Accumulation in the nature of synthetic chemicals supports the “environmental obesogen” hypothesis, such as BPA. This estrogen-mimicking xenobiotic has shown endocrine disruptive and obesogenic effects accompanied by gut microbiota misbalance that is not yet well elucidated. This study aimed to investigate specific microbiota taxa isolated and selected by direct BPA exposure and reveal its role on the overall children microbiota community and dynamics, driving toward specific obesity dysbiosis. A total of 333 BPA-resistant isolated species obtained through culturing after several exposure conditions were evaluated for their role and interplay with the global microbial community. The selected BPA-cultured taxa biomarkers showed a significant impact on alpha diversity. Specifically, Clostridium and Romboutsia were positively associated promoting the richness of microbiota communities, while Intestinibacter, Escherichia-Shigella, Bifidobacterium, and Lactobacillus were negatively associated. Microbial community dynamics and networks analyses showed differences according to the study groups. The normal-weight children group exhibited a more enriched, structured, and connected taxa network compared to overweight and obese groups, which could represent a more resilient community to xenobiotic substances. In this sense, subnetwork analysis generated with the BPA-cultured genera showed a correlation between taxa connectivity and more diverse potential enzymatic BPA degradation capacities.