Francesca De Filippis, Vincenzo Valentino, Min Yap, Raul Cabrera-Rubio, Coral Barcenilla, Niccolò Carlino, José F Cobo-Díaz, Narciso Martín Quijada, Inés Calvete-Torre, Patricia Ruas-Madiedo, Carlos Sabater, Giuseppina Sequino, Edoardo Pasolli, Martin Wagner, Abelardo Margolles, Nicola Segata, Avelino Álvarez-Ordóñez, Paul D Cotter, Danilo Ercolini
{"title":"乳业微生物组图谱揭示了具有益生菌和生物保护活性的新物种和新基因。","authors":"Francesca De Filippis, Vincenzo Valentino, Min Yap, Raul Cabrera-Rubio, Coral Barcenilla, Niccolò Carlino, José F Cobo-Díaz, Narciso Martín Quijada, Inés Calvete-Torre, Patricia Ruas-Madiedo, Carlos Sabater, Giuseppina Sequino, Edoardo Pasolli, Martin Wagner, Abelardo Margolles, Nicola Segata, Avelino Álvarez-Ordóñez, Paul D Cotter, Danilo Ercolini","doi":"10.1038/s41522-024-00541-5","DOIUrl":null,"url":null,"abstract":"<p><p>The resident microbiome in food industries may impact on food quality and safety. In particular, microbes residing on surfaces in dairy industries may actively participate in cheese fermentation and ripening and contribute to the typical flavor and texture. In this work, we carried out an extensive microbiome mapping in 73 cheese-making industries producing different types of cheeses (fresh, medium and long ripened) and located in 4 European countries. We sequenced and analyzed metagenomes from cheese samples, raw materials and environmental swabs collected from both food contact and non-food contact surfaces, as well as operators' hands and aprons. Dairy plants were shown to harbor a very complex microbiome, characterized by high prevalence of genes potentially involved in flavor development, probiotic activities, and resistance to gastro-intestinal transit, suggesting that these microbes may potentially be transferred to the human gut microbiome. More than 6100 high-quality Metagenome Assembled Genomes (MAGs) were reconstructed, including MAGs from several Lactic Acid Bacteria species and putative new species. Although microbial pathogens were not prevalent, we found several MAGs harboring genes related to antibiotic resistance, highlighting that dairy industry surfaces represent a potential hotspot for antimicrobial resistance (AR) spreading along the food chain. Finally, we identified facility-specific strains that can represent clear microbial signatures of different cheesemaking facilities, suggesting an interesting potential of microbiome tracking for the traceability of cheese origin.</p>","PeriodicalId":19370,"journal":{"name":"npj Biofilms and Microbiomes","volume":"10 1","pages":"67"},"PeriodicalIF":7.8000,"publicationDate":"2024-08-02","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC11297241/pdf/","citationCount":"0","resultStr":"{\"title\":\"Microbiome mapping in dairy industry reveals new species and genes for probiotic and bioprotective activities.\",\"authors\":\"Francesca De Filippis, Vincenzo Valentino, Min Yap, Raul Cabrera-Rubio, Coral Barcenilla, Niccolò Carlino, José F Cobo-Díaz, Narciso Martín Quijada, Inés Calvete-Torre, Patricia Ruas-Madiedo, Carlos Sabater, Giuseppina Sequino, Edoardo Pasolli, Martin Wagner, Abelardo Margolles, Nicola Segata, Avelino Álvarez-Ordóñez, Paul D Cotter, Danilo Ercolini\",\"doi\":\"10.1038/s41522-024-00541-5\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>The resident microbiome in food industries may impact on food quality and safety. In particular, microbes residing on surfaces in dairy industries may actively participate in cheese fermentation and ripening and contribute to the typical flavor and texture. In this work, we carried out an extensive microbiome mapping in 73 cheese-making industries producing different types of cheeses (fresh, medium and long ripened) and located in 4 European countries. We sequenced and analyzed metagenomes from cheese samples, raw materials and environmental swabs collected from both food contact and non-food contact surfaces, as well as operators' hands and aprons. Dairy plants were shown to harbor a very complex microbiome, characterized by high prevalence of genes potentially involved in flavor development, probiotic activities, and resistance to gastro-intestinal transit, suggesting that these microbes may potentially be transferred to the human gut microbiome. More than 6100 high-quality Metagenome Assembled Genomes (MAGs) were reconstructed, including MAGs from several Lactic Acid Bacteria species and putative new species. Although microbial pathogens were not prevalent, we found several MAGs harboring genes related to antibiotic resistance, highlighting that dairy industry surfaces represent a potential hotspot for antimicrobial resistance (AR) spreading along the food chain. 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Microbiome mapping in dairy industry reveals new species and genes for probiotic and bioprotective activities.
The resident microbiome in food industries may impact on food quality and safety. In particular, microbes residing on surfaces in dairy industries may actively participate in cheese fermentation and ripening and contribute to the typical flavor and texture. In this work, we carried out an extensive microbiome mapping in 73 cheese-making industries producing different types of cheeses (fresh, medium and long ripened) and located in 4 European countries. We sequenced and analyzed metagenomes from cheese samples, raw materials and environmental swabs collected from both food contact and non-food contact surfaces, as well as operators' hands and aprons. Dairy plants were shown to harbor a very complex microbiome, characterized by high prevalence of genes potentially involved in flavor development, probiotic activities, and resistance to gastro-intestinal transit, suggesting that these microbes may potentially be transferred to the human gut microbiome. More than 6100 high-quality Metagenome Assembled Genomes (MAGs) were reconstructed, including MAGs from several Lactic Acid Bacteria species and putative new species. Although microbial pathogens were not prevalent, we found several MAGs harboring genes related to antibiotic resistance, highlighting that dairy industry surfaces represent a potential hotspot for antimicrobial resistance (AR) spreading along the food chain. Finally, we identified facility-specific strains that can represent clear microbial signatures of different cheesemaking facilities, suggesting an interesting potential of microbiome tracking for the traceability of cheese origin.
期刊介绍:
npj Biofilms and Microbiomes is a comprehensive platform that promotes research on biofilms and microbiomes across various scientific disciplines. The journal facilitates cross-disciplinary discussions to enhance our understanding of the biology, ecology, and communal functions of biofilms, populations, and communities. It also focuses on applications in the medical, environmental, and engineering domains. The scope of the journal encompasses all aspects of the field, ranging from cell-cell communication and single cell interactions to the microbiomes of humans, animals, plants, and natural and built environments. The journal also welcomes research on the virome, phageome, mycome, and fungome. It publishes both applied science and theoretical work. As an open access and interdisciplinary journal, its primary goal is to publish significant scientific advancements in microbial biofilms and microbiomes. The journal enables discussions that span multiple disciplines and contributes to our understanding of the social behavior of microbial biofilm populations and communities, and their impact on life, human health, and the environment.