Department of Life Sciences, University of Modena and Reggio Emilia, Via Campi 213/D, 41125, Modena, Italy.
Department of Biology, Indiana University, Jordan Hall 221, 1001 E. 3rd St., Bloomington, IN, 47405, USA.
Microb Ecol. 2018 Aug;76(2):467-481. doi: 10.1007/s00248-017-1134-4. Epub 2018 Jan 15.
Symbiotic associations of metazoans with bacteria strongly influence animal biology since bacteria are ubiquitous and virtually no animal is completely free from them. Tardigrades are micrometazoans famous for their ability to undergo ametabolic states (cryptobiosis) but very little information is available on potential microbial associations. We characterized the microbiomes of six limnoterrestrial tardigrade species belonging to several phylogenetic lines in tandem with the microbiomes of their respective substrates. The experimental design enabled us to determine the effects of both the environment and the host genetic background on the tardigrade microbiome; we were able to define the microbial community of the same species sampled from different environments, and the communities of different species from the same environment. Our 16S rRNA gene amplicon approach indicated that the tardigrade microbiome is species-specific and well differentiated from the environment. Tardigrade species showed a much lower microbial diversity compared to their substrates, with only one significant exception. Forty-nine common OTUs (operational taxonomic units) were classified into six bacterial phyla, while four common OTUs were unclassified and probably represent novel bacterial taxa. Specifically, the tardigrade microbiome appears dominated by Proteobacteria and Bacteroidetes. Some OTUs were shared between different species from geographically distant samples, suggesting the associated bacteria may be widespread. Putative endosymbionts of tardigrades from the order Rickettsiales were identified. Our results indicated that like all other animals, tardigrades have their own microbiota that is different among species, and its assembly is determined by host genotype and environmental influences.
后生动物与细菌的共生关系强烈影响着动物生物学,因为细菌无处不在,几乎没有动物完全不受其影响。缓步动物是微小的后生动物,以能够经历非代谢状态(隐生)而闻名,但关于潜在的微生物共生关系的信息却很少。我们与各自的基质一起,对属于几个系统发育线的六种陆生缓步动物物种的微生物组进行了特征描述。该实验设计使我们能够确定环境和宿主遗传背景对缓步动物微生物组的影响;我们能够定义从不同环境中采样的相同物种的微生物群落,以及从同一环境中采样的不同物种的群落。我们的 16S rRNA 基因扩增子方法表明,缓步动物微生物组是物种特异性的,与环境有很好的区分。与它们的基质相比,缓步动物物种的微生物多样性要低得多,只有一个显著的例外。49 个常见的 OTUs(操作分类单元)被分类为六个细菌门,而四个常见的 OTUs 未分类,可能代表新的细菌分类群。具体而言,缓步动物微生物组似乎由 Proteobacteria 和 Bacteroidetes 主导。一些 OTUs 在来自地理上遥远样本的不同物种之间共享,表明相关细菌可能很普遍。鉴定出了缓步动物纲的 Rickettsiales 目内缓步动物的假定内共生体。我们的结果表明,与所有其他动物一样,缓步动物有自己的微生物群,在物种之间存在差异,其组装由宿主基因型和环境影响决定。
