Department of Ecology and Evolutionary Biology, University of Colorado at Boulder, Boulder, CO, USA.
Department of Biology, Duke University, Durham, NC, USA.
Mol Ecol. 2018 Apr;27(8):1992-2006. doi: 10.1111/mec.14507. Epub 2018 Mar 23.
Amphibians undergo significant developmental changes during their life cycle, as they typically move from a primarily aquatic environment to a more terrestrial one. Amphibian skin is a mucosal tissue that assembles communities of symbiotic microbiota. However, it is currently not well understood as to where amphibians acquire their skin symbionts, and whether the sources of microbial symbionts change throughout development. In this study, we utilized data collected from four wild boreal toad populations (Anaxyrus boreas); specifically, we sampled the skin bacterial communities during toad development, including eggs, tadpoles, subadults and adults as well as environmental sources of bacteria (water, aquatic sediment and soil). Using 16S rRNA marker gene profiling coupled with SourceTracker, we show that while primary environmental sources remained constant throughout the life cycle, secondary sources of boreal toad symbionts significantly changed with development. We found that toad skin communities changed predictably across development and that two developmental disturbance events (egg hatching and metamorphosis) dictated major changes. Toad skin communities assembled to alternative stable states following each of these developmental disturbances. Using the predicted average rRNA operon copy number of the communities at each life stage, we showed how the skin bacterial communities undergo a successional pattern whereby "fast-growing" (copiotroph) generalist bacteria dominate first before "slow-growing" (oligotroph) specialized bacteria take over. Our study highlights how host-associated bacterial community assembly is tightly coupled to host development and that host-associated communities demonstrate successional patterns akin to those observed in free-living bacteria as well as macrofaunal communities.
两栖动物在其生命周期中经历显著的发育变化,因为它们通常从主要的水生环境转移到更陆地的环境。两栖动物的皮肤是一种黏膜组织,它集合了共生微生物群落。然而,目前还不清楚两栖动物从何处获得皮肤共生体,以及微生物共生体的来源是否在整个发育过程中发生变化。在这项研究中,我们利用从四个野生北方箱蛙种群(Anaxyrus boreas)收集的数据;具体来说,我们在北方箱蛙发育过程中采样了皮肤细菌群落,包括卵、蝌蚪、亚成体和成年个体以及细菌的环境来源(水、水生沉积物和土壤)。我们使用 16S rRNA 标记基因分析结合 SourceTracker 技术,结果表明,尽管主要的环境来源在整个生命周期中保持不变,但北方箱蛙共生体的次要来源随着发育而显著变化。我们发现,随着发育的进行,青蛙皮肤群落发生了可预测的变化,并且两个发育干扰事件(卵孵化和变态)决定了主要的变化。在这些发育干扰之后,青蛙皮肤群落朝着替代的稳定状态组装。通过预测每个生命阶段的群落的平均 rRNA 操纵子拷贝数,我们展示了皮肤细菌群落如何经历一个演替模式,即“快速生长”(copiotroph)的泛生物种细菌首先占主导地位,然后是“缓慢生长”(oligotroph)的特化细菌接管。我们的研究强调了宿主相关细菌群落组装与宿主发育的紧密联系,并且宿主相关群落表现出类似于自由生活细菌以及大型动物群落中观察到的演替模式。
