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Closing in on the last frontier: C allocation in the rhizosphere

Sophie Obersteiner, Tamir Klein

2022Global Change Biology18 citationsDOIOpen Access PDF

Abstract

Increased belowground C allocation of trees, especially enhanced rhizodeposition, might lead to long-term C sequestration in forest soil. Microbes are crucial players in this complex process of forming stable soil organic carbon (SOC). Hence, research must be accelerated to understand the complex rhizosphere processes and their effect on stable SOC formation. This is a commentary on Hikino et al., 2022, https://onlinelibrary.wiley.com/doi/full/10.1111/gcb.16388 In this issue, Hikino et al. (2022) combine a rain exclusion experiment and a 13C labeling experiment performed on mature trees in the field, representing a new achievement in tree eco-physiology research. Furthermore, this experimental approach, applied at a large scale, facilitated the characterization of novel mechanisms in tree eco-physiology, such that belowground allocation of current photoassimilates covers only half of the C used for fine-root growth. Another enlightening example from the same research regards the sustained C allocation to root exudation, despite drought (Brunn et al., 2022). This finding corroborates observations from a more drought-exposed forest (Jakoby et al., 2020). Further, Hikino et al. (2022) show that 90% of C allocated to root exudation came from new photoassimilates after drought release, compared with 65% under control conditions. An increase in belowground C allocation, as Hikino et al. (2022) presented, might potentially increase soil C sequestration, leading to a net removal of atmospheric CO2. Soil organic C (SOC) is primarily formed by (1) aboveground litter, (2) root litter, and (3) net rhizodeposition (organic C that remains after microbial utilization and decomposition in the rhizosphere; Villarino et al., 2021; Figure 1). Mycorrhizal fungi are among the highest contributors of organic C to the soil and might play a significant role in adding exudates and necromass to the net rhizodeposition. SOC can be divided into particulate (POC), and mineral-associated (MAOC) forms, where POC is more vulnerable to microbial decomposition and MAOC displays higher persistence. Rhizodeposition has the highest MAOC formation efficiency and root biomass input has the highest POC formation efficiency (Villarino et al., 2021). This finding is confirmed by a recent study revealing that residues from saprotrophic and mycorrhizal fungi contribute more to MAOC than plant residues (Klink et al., 2022). Despite the “priming effect” of root exudates (increased microbial activity leading to destabilization of already existing C pools), Panchal et al. (2022) suggest that the rhizosphere environment of forests can help to stabilize root exudates due to the accumulation of microbial biomass residues, leading to long-term sequestration. As demonstrated well in Hikino et al. (2022), it is crucial to consider tree C allocation to predict C sequestration in the soil. Abiotic factors such as intensified drought, elevated atmospheric CO2 (eCO2) and warming are already influencing tree C fluxes. Jakoby et al. (2020) found an increase in the exudation rate during seasonal drought in a Mediterranean mixed forest. Similarly, oak trees in a greenhouse study showed an increased root exudation rate under drought treatment (Preece et al., 2018). Under eCO2, enhanced C assimilation of pines increased root exudation (Dror & Klein, 2021). In a long-term soil warming experiment in a hardwood forest, different phases of C losses were found over 26 years due to warming. The study estimated that three-quarters of the total C loss occurred during the first 9 years due to high microbial activity (Melillo et al., 2017). After 6 years of microbial community reorganization (without increased C loss in warmed plots), soil respiration increased again until reaching another plateau. Overall, SOC dynamics are complex due to its sensitivity to warming and dynamic soil microbial communities. After drought release in the combined rain exclusion—13C labeling experiment, fine root growth increased; however, no change in root exudation or ectomycorrhizae was found (Hikino et al., 2022). Because the more vulnerable POC might be formed first (Figure 1), the increase in root biomass might not contribute to a more stable belowground C pool. Even though rhizosphere processes are crucial for stable SOC formation, studies about root exudation and their role in the formation and stabilization of SOC are scarce. There is a severe lack of in situ studies on root exudation, partly because of the technical challenges of root exudation collection in natural ecosystems. In addition, studies on rhizosphere processes under global change scenarios are rare. In this matter, Hikino et al. (2022) lead the way forward. Still, research must be accelerated, considering the unknown effects of global change on C allocation in the rhizosphere. Finally, the soil is not the ultimate last frontier. A large portion of tree roots can be found in the rock layer, where roots access additional mineral and water resources. Hence, future research should consider rhizosphere processes for C sequestration not only in the soil but also in the rock layer, which is even more challenging to access and study in natural environments. The authors thank Yaara Oppenheimer-Shaanan and Stav Livne-Luzon (the Weizmann Tree Lab) on useful comments made on previous versions of this commentary. The authors declare no conflict of interests in preparation of this manuscript. No data were used for this commentary.

Topics & Concepts

RhizosphereSoil carbonFrontierEnvironmental scienceAgroforestryEcologySoil scienceGeographyBiologySoil waterPaleontologyArchaeologyBacteriaSoil Carbon and Nitrogen DynamicsLegume Nitrogen Fixing SymbiosisPlant nutrient uptake and metabolism
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