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1. Fine roots and mycorrhizal fungi accelerate leaf litter decomposition in a northern hardwood forest regardless of dominant tree mycorrhizal associations

   https://doi.org/10.1111/nph.17155  

   Lang, Ashley K.; Jevon, Fiona V.; Vietorisz, Corinne R.; Ayres, Matthew P.; Hatala Matthes, Jaclyn (December 2020, New Phytologist)

   null (Ed.)

   ●Fine roots and mycorrhizal fungi may either stimulate leaf litter decomposition by providing free‐living decomposers with root‐derived carbon, or may slow decomposition through nutrient competition between mycorrhizal and saprotrophic fungi. ●We reduced the presence of fine roots and their associated mycorrhizal fungi in a northern hardwood forest in New Hampshire, USA by soil trenching. Plots spanned a mycorrhizal gradient from 96% arbuscular mycorrhizal (AM) associations to 100% ectomycorrhizal (ECM)‐associated tree basal area. We incubated four species of leaf litter within these plots in areas with reduced access to roots and mycorrhizal fungi and in adjacent areas with intact roots and mycorrhizal fungi. ●Over a period of 608 d, we found that litter decayed more rapidly in the presence of fine roots and mycorrhizal hyphae regardless of the dominant tree mycorrhizal association. Root and mycorrhizal exclusion reduced the activity of acid phosphatase on decomposing litter. ●Our results indicate that both AM‐ and ECM‐associated fine roots stimulate litter decomposition in this system. These findings suggest that the effect of fine roots and mycorrhizal fungi on litter decay in a particular ecosystem likely depends on whether interactions between mycorrhizal roots and saprotrophic fungi are antagonistic or facilitative. 

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2. Interactions between root hairs and the soil microbial community affect the growth of maize seedlings

   https://doi.org/10.1111/pce.14755  

   Quattrone, Amanda; Lopez‐Guerrero, Martha; Yadav, Pooja; Meier, Michael A; Russo, Sabrina E; Weber, Karrie A (February 2024, Plant, Cell & Environment)

   Abstract Root hairs are considered important for rhizosphere formation, which affects root system functioning. Through interactions with soil microorganisms mediated by root exudation, root hairs may affect the phenotypes and growth of young plants. We tested this hypothesis by integrating results from two experiments: (1) a factorial greenhouse seedling experiment withZea mays B73‐wtand its root‐hairless mutant,B73‐rth3, grown in live and autoclaved soil, quantifying 15 phenotypic traits, seven growth rates, and soil microbiomes and (2) a semi‐hydroponic system quantifying root exudation of maize genotypes. Possibly as compensation for lacking root hairs,B73‐rth3seedlings allocated more biomass to roots and grew slower thanB73‐wtseedlings in live soil, whereasB73‐wtseedlings grew slowest in autoclaved soil, suggesting root hairs can be costly and their benefits were realized with more complete soil microbial assemblages. There were substantial differences in root exudation between genotypes and in rhizosphere versus non‐rhizosphere microbiomes. The microbial taxa enriched in the presence of root hairs generally enhanced growth compared to taxa enriched in their absence. Our findings suggest the root hairs' adaptive value extends to plant‐microbe interactions mediated by root exudates, affecting plant phenotypes, and ultimately, growth. 

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3. A Case History of Highwater Shore Erosion and Bank Stabilization via Tree Roots

   Lingwall, Bret N. (October 2021, 10th International Conference on Soil Erosion and Scour)

   Extreme highwater pool elevations in Pactola Reservoir, South Dakota in 2015 and 2019 resulted in massive shoreline erosion along the southern banks. This shoreline erosion occurred despite the geologic material being highly fractured rock with fracture dip angles approximately parallel to that of the subject hillside. The shale and siltstone in the upper 30 meters of the geology had weathered into silt and clay, leaving a matrix of 70% to 90% rock and 10% to 30% fine-grained soil. When highwater occurred, the silty portion of the shore materials eroded, while the remaining small amounts of highly plastic clay were insufficient to bind the weak and thinly bedded rock together, and rock slipped along the 15 to 30-degree fracture dip angle into the water. The shore erosion was arrested by a line of pine trees, and the erosion patterns show the effectiveness of tree roots to resist erosion in highly fractured rock. The erosion case history is presented with descriptions of several individual root systems that were effective in shore stabilization, as well as descriptions of several individual tree root systems that were ineffective in shore stabilization and the trees perished in the highwater evens and toppled. 

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4. Topographical shifts in fine root lifespan in a mixed, mesic temperate forest

   https://doi.org/10.1371/journal.pone.0254672  

   Primka, Edward J.; Adams, Thomas S.; Buck, Alexandra; Eissenstat, David M. (July 2021, PLOS ONE)

   Zang, RunGuo (Ed.)

   Root lifespan, often is estimated in landscape- and ecosystem-level carbon models using linear approximations. In water manipulation experiments, fine root lifespan can vary with soil water content. Soil water content is generally structured by complex topography, which is largely unaccounted for in landscape- and ecosystem-scale carbon models. Topography governs the range of soil water content experienced by roots which may impact their lifespan. We hypothesized that root lifespan varied nonlinearly across a temperate, mesic, forested catchment due to differences in soil water content associated with topographic position. We expected regions of the landscape that were too wet or too dry would have soils that were not optimal for roots and thus result in shorter root lifespans. Specifically, we hypothesized that root lifespan would be longest in areas that consistently had soil water content in the middle of the soil water content spectrum, while in soils at either very low or very high soil water content, root lifespan would be relatively short. We tested this hypothesis by collecting and analyzing two years of minirhizotron and soil moisture data in plots widely distributed in the Shale Hills catchment of the Susquehanna-Shale Hills Critical Zone Observatory in Pennsylvania. We found that fine root lifespans were longer in traditionally wetter topographic regions, but detected no short term (biweekly) effect of soil moisture on root lifespan. Additionally, depth in soil, soil series, slope face orientation, and season of birth strongly affected root lifespans across the catchment. In contrast, lifespan was unaffected by root diameter or mycorrhizal association. Failure to account for these variables could result in erroneous estimates of fine root lifespan and, consequentially, carbon flux in temperate forested regions. 

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5. Termite Presence and Feeding on Loblolly Pine Wood Differs Among Four Root-Infecting Bluestain (ophiostomatoid) Fungal Species

   https://doi.org/10.1093/ee/nvab052  

   Clay, Natalie A; Siegert, Courtney; Tang, Juliet D; Little, Nathan S; Eckhardt, Lori G; Riggins, John J (June 2021, Environmental Entomology)

   Hajek, Ann (Ed.)

   Abstract Bark beetles and root weevils can impact forests through tree death on landscape scales. Recently, subterranean termites have been linked to these beetles via the presence of bluestain fungi (Ascomycota: Ophiostomataceae), which are vectored to trees by beetles. However, only a small subset of bluestain species have been examined. Here, we tested whether termite-bluestain association patterns in the field reflect termite feeding preference in laboratory choice trials. We documented the presence of four bluestain fungi (Leptographium procerum (W.B. Kendr.), L. terebrantis (Barras & Perry), Grosmannia huntii (Rob.-Jeffr.), and G. alacris (T.A. Duong, Z.W. de Beer & M.J. Wingf.) in the roots of 2,350 loblolly pine trees in the southeastern United States and whether termites were present or absent on these roots and paired this with laboratory choice feeding trials. Termites were found 2.5-fold on tree roots with at least one bluestain fungus present than tree roots without bluestain fungi. Although termites in this study and others were associated with L. procerum, L. terebrantis, and marginally G. huntii, termites only showed preferential feeding on wood inoculated with G. huntii in laboratory trials. This suggests that increased termite presence on wood with bluestain fungi may be driven by factors other than increased wood palatability. Termites could thus disproportionately affect wood turnover rates for specific pools (e.g., bark beetle and root weevil attacked trees) and in some cases (e.g., G. huntii) accelerate wood decomposition. This study supports the growing evidence that the association between subterranean termites and bluestain fungi is spatially and taxonomically widespread. 

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