Rhizosphere assembly alters along a chronosequence in the Hallstätter glacier forefield (Dachstein, Austria)

• Published in: FEMS microbiology ecology Vol. 100; no. 2
• Main Authors: Wicaksono, Wisnu Adi, Mora, Maximilian, Bickel, Samuel, Berg, Christian, Kühn, Ingolf, Cernava, Tomislav, Berg, Gabriele
• Format: Journal Article
• Language: English
• Published: England Oxford University Press 24.01.2024
• Subjects: Austria; Bacteria - genetics; Ice Cover - microbiology; Microbiota; Plants; Rhizosphere; Soil; Soil Microbiology; Austria; metagenome; bacteria; glacier forefield; pioneer plants; soil microorganisms; deglaciation; microbiome
• ISSN: 1574-6941; 1574-6941
• DOI: 10.1093/femsec/fiae005

Abstract Rhizosphere microbiome assembly is essential for plant health, but the temporal dimension of this process remains unexplored. We used a chronosequence of 150 years of the retreating Hallstätter glacier (Dachstein, Austria) to disentangle this exemplarily for the rhizosphere of three pioneer alpine plants. Time of deglaciation was an important factor shaping the rhizosphere microbiome. Microbiome functions, i.e. nutrient uptake and stress protection, were carried out by ubiquitous and cosmopolitan bacteria. The rhizosphere succession along the chronosequence was characterized by decreasing microbial richness but increasing specificity of the plant-associated bacterial community. Environmental selection is a critical factor in shaping the ecosystem, particularly in terms of plant-driven recruitment from the available edaphic pool. A higher rhizosphere microbial richness during early succession compared to late succession can be explained by the occurrence of cold-acclimated bacteria recruited from the surrounding soils. These taxa might be sensitive to changing habitat conditions that occurred at the later stages. A stronger influence of the plant host on the rhizosphere microbiome assembly was observed with increased time since deglaciation. Overall, this study indicated that well-adapted, ubiquitous microbes potentially support pioneer plants to colonize new ecosystems, while plant-specific microbes may be associated with the long-term establishment of their hosts. Rhizosphere assembly alters along a chronosequence.