Predicting foodborne pathogens and probiotics taxa within poultry-related microbiomes using a machine learning approach.

IF 4.9 Q1 MICROBIOLOGY
Moses B Ayoola, Nisha Pillai, Bindu Nanduri, Michael J Rothrock, Mahalingam Ramkumar
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引用次数: 0

Abstract

Background: Microbiomes that can serve as an indicator of gut, intestinal, and general health of humans and animals are largely influenced by food consumed and contaminant bioagents. Microbiome studies usually focus on estimating the alpha (within sample) and beta (similarity/dissimilarity among samples) diversities. This study took a combinatorial approach and applied machine learning to microbiome data to predict the presence of disease-causing pathogens and their association with known/potential probiotic taxa. Probiotics are beneficial living microorganisms capable of improving the host organism's digestive system, immune function and ultimately overall health. Here, 16 S rRNA gene high-throughput Illumina sequencing of temporal pre-harvest (feces, soil) samples of 42 pastured poultry flocks (poultry in this entire work solely refers to chickens) from southeastern U.S. farms was used to generate the relative abundance of operational taxonomic units (OTUs) as machine learning input. Unique genera from the OTUs were used as predictors of the prevalence of foodborne pathogens (Salmonella, Campylobacter and Listeria) at different stages of poultry growth (START (2-4 weeks old), MID (5-7 weeks old), END (8-11 weeks old)), association with farm management practices and physicochemical properties.

Result: While we did not see any significant associations between known probiotics and Salmonella or Listeria, we observed significant negative correlations between known probiotics (Bacillus and Clostridium) and Campylobacter at the mid-time point of sample collection. Our data indicates a negative correlation between potential probiotics and Campylobacter at both early and end-time points of sample collection. Furthermore, our model prediction shows that changes in farm operations such as how often the houses are moved on the pasture, age at which chickens are introduced to the pasture, diet composition and presence of other animals on the farm could favorably increase the abundance and activity of probiotics that could reduce Campylobacter prevalence.

Conclusion: Integration of microbiome data with farm management practices using machine learning provided insights on how to reduce Campylobacter prevalence and transmission along the farm-to-fork continuum. Altering management practices to support proliferation of beneficial probiotics to reduce pathogen prevalence identified here could constitute a complementary method to the existing but ineffective interventions such as vaccination and bacteriophage cocktails usage. Study findings also corroborate the presence of bacterial genera such as Caloramator, DA101, Parabacteroides and Faecalibacterium as potential probiotics.

使用机器学习方法预测家禽相关微生物组中的食源性病原体和益生菌分类群。
背景:微生物组可以作为人类和动物的肠道、肠道和一般健康的指标,在很大程度上受到所消耗的食物和污染生物制剂的影响。微生物组学研究通常侧重于估算样品内(alpha)和样品间(beta)的多样性。本研究采用组合方法,并将机器学习应用于微生物组数据,以预测致病病原体的存在及其与已知/潜在益生菌分类群的关联。益生菌是有益的活微生物,能够改善宿主的消化系统,免疫功能和最终的整体健康。在这里,使用来自美国东南部农场的42只放牧家禽(本研究中的家禽仅指鸡)的收获前(粪便、土壤)样品的16s rRNA基因高通量Illumina测序来生成相对丰度的操作分类单位(OTUs)作为机器学习输入。来自OTUs的独特属被用作预测家禽生长不同阶段(START(2-4周龄),MID(5-7周龄),END(8-11周龄))食源性病原体(沙门氏菌,弯曲杆菌和李斯特菌)患病率,以及与农场管理措施和理化性质相关的预测指标。结果:虽然我们没有发现已知的益生菌与沙门氏菌或李斯特菌之间有任何显著的关联,但我们发现在样本收集的中期,已知的益生菌(芽孢杆菌和梭状芽孢杆菌)与弯曲杆菌之间存在显著的负相关。我们的数据表明,在样品收集的早期和结束时间点,潜在的益生菌和弯曲杆菌之间呈负相关。此外,我们的模型预测表明,农场操作的变化,如在牧场上移动房屋的频率、将鸡引入牧场的年龄、饲料组成和农场上其他动物的存在,都有利于增加益生菌的丰度和活性,从而减少弯曲杆菌的流行。结论:利用机器学习将微生物组数据与农场管理实践相结合,为如何减少弯曲杆菌在农场到餐桌的流行和传播提供了见解。改变管理实践以支持有益益生菌的增殖,以减少本文所确定的病原体的流行,可以作为现有但无效的干预措施(如接种疫苗和使用噬菌体鸡尾酒)的补充方法。研究结果还证实了细菌属的存在,如卡乐马菌、DA101、拟杆菌和Faecalibacterium是潜在的益生菌。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.20
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0.00%
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审稿时长
13 weeks
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