Institute of Behaviour, Animal Health and Comparative Medicine, Graham Kerr Building, University of Glasgowgrid.8756.c, Glasgow, Scotland.
School of Engineering, University of Glasgowgrid.8756.c, Glasgow, Scotland.
Microbiol Spectr. 2022 Jun 29;10(3):e0195321. doi: 10.1128/spectrum.01953-21. Epub 2022 May 9.
Alpha mannose-oligosaccharide (MOS) prebiotics are widely deployed in animal agriculture as immunomodulators as well as to enhance growth and gut health. Their mode of action is thought to be mediated through their impact on host microbial communities and their associated metabolism. Bio-Mos is a commercially available prebiotic currently used in the agri-feed industry, but studies show contrasting results of its effect on fish performance and feed efficiency. Thus, detailed studies are needed to investigate the effect of MOS supplements on the fish microbiome to enhance our understanding of the link between MOS and gut health. To assess Bio-Mos for potential use as a prebiotic growth promoter in salmonid aquaculture, we have modified an established Atlantic salmon gut model, SalmoSim, to evaluate its impact on the host microbial communities. The microbial communities obtained from ceca compartments from four adult farmed salmon were inoculated in biological triplicate reactors in SalmoSim. Prebiotic treatment was supplemented for 20 days, followed by a 6-day washout period. Inclusion of Bio-Mos in the media resulted in a significant increase in formate ( = 0.001), propionate ( = 0.037) and 3-methyl butanoic acid ( = 0.024) levels, correlated with increased abundances of several, principally, anaerobic microbial genera (). DNA metabarcoding with the 16S rDNA marker confirmed a significant shift in microbial community composition in response to Bio-Mos supplementation with observed increase in lactic acid producing . In conjunction with previous studies linking enhanced volatile fatty acid production alongside MOS supplementation to host growth and performance, our data suggest that Bio-Mos may be of value in salmonid production. Furthermore, our data highlights the potential role of gut models to complement trials of microbiome modulators. In this paper we report the results of the impact of a prebiotic (alpha-MOS supplementation) on microbial communities, using an simulator of the gut microbial environment of the Atlantic salmon. Our data suggest that Bio-Mos may be of value in salmonid production as it enhances volatile fatty acid production by the microbiota from salmon pyloric ceca and correlates with a significant shift in microbial community composition with observed increase in lactic acid producing . In conjunction with previous studies linking enhanced volatile fatty acid production alongside MOS supplementation to host growth and performance, our data suggest that Bio-Mos may be of value in salmonid production. Furthermore, our data highlights the potential role of gut models to augment trials of microbiome modulators.
阿尔法甘露寡糖 (MOS) 益生元作为免疫调节剂以及促进生长和肠道健康,被广泛应用于动物农业。其作用模式被认为是通过对宿主微生物群落及其相关代谢的影响来介导的。Bio-Mos 是一种商业上可利用的益生元,目前用于农业饲料行业,但研究表明其对鱼类生长性能和饲料效率的影响结果存在差异。因此,需要进行详细的研究来调查 MOS 补充剂对鱼类微生物组的影响,以增强我们对 MOS 与肠道健康之间联系的理解。为了评估 Bio-Mos 在鲑鱼养殖中作为促生长益生元的潜在用途,我们对已建立的大西洋鲑鱼肠道模型 SalmoSim 进行了修改,以评估其对宿主微生物群落的影响。从四个成年养殖鲑鱼的盲肠隔间获得的微生物群落被接种到 SalmoSim 中的三个生物重复反应器中。预生物处理补充 20 天,然后进行 6 天的洗脱期。在培养基中添加 Bio-Mos 导致甲酸盐(=0.001)、丙酸盐(=0.037)和 3-甲基丁酸(=0.024)水平显著增加,与几种主要的厌氧微生物属的丰度增加相关()。16S rDNA 标记的 DNA 宏条形码证实,微生物群落组成因 Bio-Mos 补充而发生显著变化,伴随着 MOS 补充与宿主生长和性能相关的挥发性脂肪酸产量增加,观察到产乳酸的增加。结合先前的研究,将增强挥发性脂肪酸产生与 MOS 补充与宿主生长和性能相关联,我们的数据表明 Bio-Mos 可能对鲑鱼生产有价值。此外,我们的数据突出了肠道模型在补充微生物组调节剂试验中的潜在作用。在本文中,我们报告了一种益生元(α-MOS 补充)对微生物群落影响的结果,使用了大西洋鲑鱼胃微生物环境的模拟器。我们的数据表明,Bio-Mos 可能对鲑鱼生产有价值,因为它增强了来自鲑鱼幽门盲肠的微生物群的挥发性脂肪酸产生,并与微生物群落组成的显著变化相关,观察到产乳酸的增加。结合先前的研究,将增强挥发性脂肪酸产生与 MOS 补充与宿主生长和性能相关联,我们的数据表明 Bio-Mos 可能对鲑鱼生产有价值。此外,我们的数据突出了肠道模型在补充微生物组调节剂试验中的潜在作用。
