Colonization of naïve roots from Populus tremula x alba involves successive waves of fungi and bacteria with different trophic abilities

Abstract

AbstractThrough their roots, trees interact with a highly complex community of microorganisms belonging to various trophic guilds and contributing to tree nutrition, development and protection against stresses. Tree roots select for specific microbial species from the bulk soil communities. The root microbiome formation is a dynamic process but little is known on how the different microorganisms colonize the roots and how the selection occurs. To decipher if the final composition of the root microbiome is the product of several waves of colonization by different guilds of microorganisms, we planted sterile rooted cuttings of Gray Poplar obtained from plantlets propagated in axenic conditions in natural soil taken from a poplar stand. We analyzed the root microbiome at different time points between 2 and 50 days of culture by combining high-throughput Illumina MiSeq sequencing of fungal rDNA ITS and bacterial 16S rRNA amplicons with Confocal Laser Scanning Microscope observations. The microbial colonisation of poplar roots took place in three stages but the dynamic was different between bacteria and fungi. Root bacterial communities were clearly different from the soil after two days of culture. By contrast, if fungi were also already colonizing roots after two days, the initial communities were very close to the one of the soil and were dominated by saprotrophs. Those were slowly replaced by endophytes and ectomycorhizal fungi. The replacement of the most abundant fungal and bacterial community members observed in poplar roots along time suggest potential competition effect between microorganisms and/or a selection by the host.ImportanceThe tree root microbiome is composed of a very diverse set of bacterial and fungal communities. These microorganisms have a profound impact on tree growth, development and protection against different types of stress. They mainly originate from the bulk soil and colonize the root system which provides a unique nutrient rich-environment for a diverse assemblage of microbial communities. In order to better understand how the tree root microbiome is shaped along time, we observed the composition of root-associated microbial communities of naïve plantlets of poplar transferred in natural soil. The composition of the final root microbiome rely on a series of colonization stages characterized by the dominance of different fungal guilds and bacterial community members along time. Our observations suggest an early stabilization of bacterial communities, whereas fungal communities are established following a more gradual pattern.