Sana Romdhane, Sarah Huet, Aymé Spor, David Bru, Marie-Christine Breuil, Laurent Philippot
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We found significant differences in both bacterial community diversity, composition and co-occurrence networks after soil colonization that were related to physical distancing. We show that reducing distances between cells resulted in a loss of bacterial diversity, with at least 41% of the dominant OTUs being significantly affected by physical distancing. Our results suggest that physical distancing may differentially modulate competitiveness between neighboring species depending on the taxa present in the community. The mixing of communities that assembled at high and low cell densities did not reveal any “home field advantage” during coalescence. This confirms that the observed differences in competitiveness were due to biotic rather than abiotic filtering. 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引用次数: 0
摘要
微生物群落对生态系统的功能具有极其重要的意义,然而我们对这些群落在环境中聚集的生态过程却知之甚少。在这里,我们采用了一种前所未有的实验方法,即在土壤定殖过程中操纵相邻细胞之间的物理距离,以确定细菌相互作用在土壤群落组装中的作用。我们假设,通过实验操纵细菌细胞之间的物理距离会改变相互作用的强度,从而导致微生物群落组成的差异,相邻细胞之间的距离越远,越有利于差的竞争者。我们发现,在土壤定殖后,细菌群落的多样性、组成和共生网络都出现了与物理距离相关的显著差异。我们发现,减少细胞间的距离会导致细菌多样性的丧失,至少有 41% 的优势 OTU 受到物理距离的显著影响。我们的研究结果表明,物理距离可能会根据群落中存在的类群而对相邻物种之间的竞争性产生不同的调节作用。在高细胞密度和低细胞密度下聚集的群落混合后,在凝聚过程中没有发现任何 "主场优势"。这证实了所观察到的竞争力差异是由于生物而非生物过滤造成的。我们的研究表明,细菌的竞争力在很大程度上取决于细胞密度和群落成员组成,因此突出了微生物相互作用在土壤群落形成过程中的基本作用。
Manipulating the physical distance between cells during soil colonization reveals the importance of biotic interactions in microbial community assembly
Microbial communities are of tremendous importance for ecosystem functioning and yet we know little about the ecological processes driving the assembly of these communities in the environment. Here, we used an unprecedented experimental approach based on the manipulation of physical distance between neighboring cells during soil colonization to determine the role of bacterial interactions in soil community assembly. We hypothesized that experimentally manipulating the physical distance between bacterial cells will modify the interaction strengths leading to differences in microbial community composition, with increasing distance between neighbors favoring poor competitors. We found significant differences in both bacterial community diversity, composition and co-occurrence networks after soil colonization that were related to physical distancing. We show that reducing distances between cells resulted in a loss of bacterial diversity, with at least 41% of the dominant OTUs being significantly affected by physical distancing. Our results suggest that physical distancing may differentially modulate competitiveness between neighboring species depending on the taxa present in the community. The mixing of communities that assembled at high and low cell densities did not reveal any “home field advantage” during coalescence. This confirms that the observed differences in competitiveness were due to biotic rather than abiotic filtering. Our study demonstrates that the competitiveness of bacteria strongly depends on cell density and community membership, therefore highlighting the fundamental role of microbial interactions in the assembly of soil communities.
期刊介绍:
Microorganisms, omnipresent across Earth's diverse environments, play a crucial role in adapting to external changes, influencing Earth's systems and cycles, and contributing significantly to agricultural practices. Through applied microbiology, they offer solutions to various everyday needs. Environmental Microbiome recognizes the universal presence and significance of microorganisms, inviting submissions that explore the diverse facets of environmental and applied microbiological research.