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牡蛎育苗场中细菌群落动态对益生菌处理的响应

Bacterial Community Dynamics in an Oyster Hatchery in Response to Probiotic Treatment.

作者信息

Stevick Rebecca J, Sohn Saebom, Modak Tejashree H, Nelson David R, Rowley David C, Tammi Karin, Smolowitz Roxanna, Markey Lundgren Kathryn, Post Anton F, Gómez-Chiarri Marta

机构信息

Graduate School of Oceanography, The University of Rhode Island, Narragansett, RI, United States.

Department of Fisheries, Animal and Veterinary Sciences, The University of Rhode Island, Kingston, RI, United States.

出版信息

Front Microbiol. 2019 May 15;10:1060. doi: 10.3389/fmicb.2019.01060. eCollection 2019.

DOI:10.3389/fmicb.2019.01060
PMID:31156583
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6530434/
Abstract

Larval oysters in hatcheries are susceptible to diseases caused by bacterial pathogens, including spp. Previous studies have shown that daily addition of the probiotic RI06-95 to water in rearing tanks increases larval survival when challenged with the pathogen . We propose that the presence of probiotics causes shifts in bacterial community structure in rearing tanks, leading to a net decrease in the relative abundance of potential pathogens. During three trials spanning the 2012-2015 hatchery seasons, larvae, tank biofilm, and rearing water samples were collected from control and probiotic-treated tanks in an oyster hatchery over a 12-day period after spawning. Samples were analyzed by 16S rRNA sequencing of the V4 or V6 regions followed by taxonomic classification, in order to determine bacterial community structures. There were significant differences in bacterial composition over time and between sample types, but no major effect of probiotics on the structure and diversity of bacterial communities (phylum level, Bray-Curtis = 2, 95% confidence). Probiotic treatment, however, led to a higher relative percent abundance of and spp. in water and oyster larvae. In the water, an increase in spp. diversity in the absence of a net increase in relative read abundance suggests a likely decrease in the abundance of specific pathogenic spp., and therefore lower chances of a disease outbreak. Co-occurrence network analysis also suggests that probiotic treatment had a systemic effect on targeted members of the bacterial community, leading to a net decrease in potentially pathogenic species.

摘要

孵化场中的牡蛎幼虫易受包括 属细菌病原体引起的疾病影响。先前的研究表明,在育苗池中每天向水中添加益生菌RI06 - 95可提高幼虫在受到病原体攻击时的存活率。我们认为,益生菌的存在会导致育苗池中细菌群落结构发生变化,从而使潜在病原体的相对丰度净下降。在2012 - 2015年孵化场季节的三次试验中,在产卵后的12天内,从牡蛎孵化场的对照池和经益生菌处理的池中采集幼虫、池生物膜和养殖水样。通过对V4或V6区域进行16S rRNA测序,然后进行分类学分类来分析样本,以确定细菌群落结构。随着时间的推移以及样本类型之间,细菌组成存在显著差异,但益生菌对细菌群落的结构和多样性没有主要影响(门水平,Bray - Curtis = 2,95%置信度)。然而,益生菌处理导致水中和牡蛎幼虫中 属和 属的相对丰度百分比更高。在水中, 属多样性增加而相对读数丰度没有净增加,这表明特定致病 属的丰度可能下降,因此疾病爆发的可能性降低。共现网络分析还表明,益生菌处理对细菌群落的目标成员有系统性影响,导致潜在致病物种净减少。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d97f/6530434/d906fea38385/fmicb-10-01060-g007.jpg
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