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Implications of reduced root-soil contact for microbial rhizosphere establishment and early plant growth performance

Anna S. Wendel, Sara L. Bauke, Janadi Chamika Ileperuma, Karolin Funken, Katharina Frindte, Claudia Knief

2025Soil Biology and Biochemistry7 citationsDOIOpen Access PDF

Abstract

Processes at the root-soil interface are essential for plant nutrient and water uptake, but the level of root-soil contact varies depending on root traits and soil properties. Implications of reduced root-soil contact for the rhizosphere, its microbiota and for plant performance remain largely unclear. Here, the consequences of root-soil contact reduction were analyzed in maize microcosm experiments. Either soil porosity was modified by introducing artificial large-sized pores, or the contact area was reduced by a maize mutant ( rth3 ) impaired in root hair development. Microscopic evaluation of roots grown in pores without soil contact revealed strongly reduced prokaryotic surface colonization. Bacterial abundance in the rhizosphere soil of remaining contact areas was also reduced (2.2 × 10 10 vs. 1.0 × 10 9 16S rRNA gene copies per g dry soil), including the abundance of nitrogen cycling bacteria. The absence of root hairs decreased bacterial abundance likewise, though not of nitrogen cycling prokaryotes. 16S rRNA gene-based amplicon sequencing revealed bacterial community-compositional alterations in the rhizosphere (PERMANOVA R 2 = 0.701, p = 0.001) with lower relative abundances of Massilia and Paenibacillus for roots grown in pores. Community shifts in the rhizosphere of rth3 plants showed similar changes. No differences were evident upon root-soil contact reduction in the endosphere bacterial community. Combined manipulations revealed that root hairs improved root-soil contact in pores, whereas lateral roots reduced it, as validated with a maize mutant ( lrt1 ) impaired in lateral root development. Plant growth and biomass allocation in the first three weeks were only weakly affected by root-soil contact reduction. Overall, the level of root-soil contact appears critical for bacterial life in the rhizosphere and rhizoplane, including the establishment of nitrifying bacteria and potential plant-beneficial taxa such as Massilia . Aiming at optimum root-soil contact by soil management and plant breeding strategies has thus the potential to contribute to the establishment of a functional rhizosphere microbiome. • Reduced root-soil in soil pores limits proliferation of bacterial nitrifiers, denitrifiers and potential beneficials ( Massilia, Paenibacillus ) in the rhizosphere • Root-soil contact reduction by lack of root hairs reduces bacterial abundance in the rhizosphere • Reduced root-soil contact does not affect root endophytic colonization • Root hairs support root-soil contact in soil pores, whereas lateral roots cause contact reduction • Three-week old plants show early signs of impaired plant performance upon root-soil contact reduction

Topics & Concepts

RhizospherePlant growthAgronomyEnvironmental scienceRoot (linguistics)BiologyPlant rootBotanyHorticultureBacteriaPhilosophyLinguisticsGeneticsPlant-Microbe Interactions and ImmunityLegume Nitrogen Fixing SymbiosisAgronomic Practices and Intercropping Systems