Dehler Carola E, Secombes Christopher J, Martin Samuel A M
Institute of Biological and Environmental Sciences, University of Aberdeen, Tillydrone Avenue, Aberdeen AB24 2TZ, UK.
Aquaculture. 2017 Jan 20;467:149-157. doi: 10.1016/j.aquaculture.2016.07.017.
Gut microbes are key players in host immune system priming, protection and development, as well as providing nutrients to the host that would be otherwise unavailable. Due to this importance, studies investigating the link between host and microbe are being initiated in farmed fish. The establishment, maintenance and subsequent changes of the intestinal microbiota are central to define fish physiology and nutrition in the future. In fish, unlike mammals, acquiring intestinal microbes is believed to occur around the time of first feeding mainly from the water surrounding them and their microbial composition over time is shaped therefore by their habitat. Here we compare the distal intestine microbiota of Atlantic salmon parr reared in a recirculating laboratory aquarium with that of age matched parr maintained in cage culture in an open freshwater loch environment of a commercial fish farm to establish the microbial profiles in the gut at the freshwater stage and investigate if there is a stable subset of bacteria present regardless of habitat type. We used deep sequencing across two variable regions of the 16S rRNA gene, with a mean read depth of 180,144 ± 12,096 raw sequences per sample. All individual fish used in this study had a minimum of 30,000 quality controlled reads, corresponding to an average of 342 ± 19 Operational Taxonomic Units (OTUs) per sample, which predominantly mapped to the phyla , , and . The results indicate that species richness is comparable between both treatment groups, however, significant differences were found in the compositions of the gut microbiota between the rearing groups. Furthermore, a core microbiota of 19 OTUs was identified, shared by all samples regardless of treatment group, mainly consisting of members of the phyla , and . Core microbiotas of the individual rearing groups were determined (aquarium fish: 19 + 4 (total 23) OTUs, loch fish: 19 + 13 (total 32) OTUs), indicating that microbe acquisition or loss is occurring differently in the two habitats, but also that selective forces are acting within the host, offering niches to specific bacterial taxa. The new information gathered in this study by the Illumina MiSeq approach will be useful to understand and define the gut microbiota of healthy Atlantic salmon in freshwater and expand on previous studies using DGGE, TGGE and T-RFPL. Monitoring deviations from these profiles, especially the core microbes which are present regardless of habitat type, might be used in the future as early indicator for intestinal health issues caused by sub optimal feed or infectious diseases in the farm setting.
The Microbiome is central to gut health, local immune function and nutrient up take. We have used deep sequencing approach to show differences in rearing conditions of Atlantic salmon. This work is of interest to aquaculture nutritionists.
肠道微生物是宿主免疫系统启动、保护和发育的关键参与者,同时还为宿主提供原本无法获取的营养物质。鉴于其重要性,针对养殖鱼类中宿主与微生物之间联系的研究正在展开。肠道微生物群的建立、维持及后续变化对于界定未来鱼类的生理机能和营养状况至关重要。与哺乳动物不同,鱼类被认为在初次摄食前后主要从周围水体中获取肠道微生物,因此其微生物组成会随时间受到栖息地的影响。在此,我们将在循环水实验室水族箱中饲养的大西洋鲑幼鱼的远端肠道微生物群与在商业渔场开放淡水湖环境中网箱养殖的同龄幼鱼的微生物群进行比较,以确定淡水阶段肠道中的微生物概况,并研究无论栖息地类型如何,是否存在稳定的细菌亚群。我们对16S rRNA基因的两个可变区域进行了深度测序,每个样本的原始序列平均读取深度为180,144 ± 12,096。本研究中使用的所有个体鱼至少有30,000条经过质量控制的读数,相当于每个样本平均有342 ± 19个操作分类单元(OTU),这些OTU主要映射到 、 和 门。结果表明,两个处理组的物种丰富度相当,然而,饲养组之间肠道微生物群的组成存在显著差异。此外,鉴定出了一个由19个OTU组成的核心微生物群,所有样本(无论处理组如何)均有该核心微生物群,主要由 、 和 门的成员组成。确定了各个饲养组的核心微生物群(水族箱鱼:19 + 4(共23个)OTU,湖鱼:19 + 13(共32个)OTU),这表明在两种栖息地中微生物的获取或丧失情况不同,但也表明宿主内部存在选择压力,为特定细菌类群提供了生态位。本研究通过Illumina MiSeq方法收集的新信息将有助于理解和界定健康大西洋鲑在淡水中的肠道微生物群,并扩展以往使用变性梯度凝胶电泳(DGGE)、温度梯度凝胶电泳(TGGE)和末端限制性片段长度多态性分析(T-RFPL)的研究。监测与这些概况的偏差,尤其是无论栖息地类型如何都存在的核心微生物,未来可能用作养殖环境中因饲料不佳或传染病导致的肠道健康问题的早期指标。
微生物群对于肠道健康、局部免疫功能和营养吸收至关重要。我们使用深度测序方法展示了大西洋鲑养殖条件的差异。这项工作对水产养殖营养学家具有重要意义。
