Department of Mycorrhizal Symbioses, Institute of Botany of the Czech Academy of Sciences, Průhonice, Czech Republic.
Laboratory of Fungal Biology, Institute of Microbiology of the Czech Academy of Sciences, Prague, Czech Republic.
Mycorrhiza. 2020 May;30(2-3):299-313. doi: 10.1007/s00572-020-00949-9. Epub 2020 Apr 6.
Arbuscular mycorrhizal (AM) fungi play a positive role in plant water relations, and the AM symbiosis is often cited as beneficial for overcoming drought stress of host plants. Nevertheless, water uptake via mycorrhizal hyphal networks has been little addressed experimentally, especially so through isotope tracing. In a greenhouse study conducted in two-compartment rhizoboxes, Medicago truncatula was planted in the primary compartment (PC), either inoculated with Rhizophagus irregularis or left uninoculated. Plant roots were either allowed to enter the secondary compartment (SC) or were restricted to the PC by root-excluding mesh. Substrate moisture was manipulated in the PC such that the plants were grown either in high moisture (15% of gravimetric water content, GWC) or low moisture (8% GWC). Meanwhile, the SC was maintained at 15% GWC throughout and served as a water source accessible (or not) by roots and/or hyphae. Water in the SC was labeled with deuterium (D) to quantify water uptake by the plants from the SC. Significantly, increased D incorporation into plants indicated higher water uptake by mycorrhizal plants when roots had access to the D source, but this was mainly explained by generally larger mycorrhizal root systems in proximity to the D source. On the other hand, AM fungal hyphae with access to the D source increased D incorporation into plants more than twofold compared to non-mycorrhizal plants. Despite this strong effect, water transport via AM fungal hyphae was low compared to the transpiration demand of the plants.
丛枝菌根(AM)真菌在植物水分关系中发挥积极作用,AM 共生关系常被认为有利于克服宿主植物的干旱胁迫。然而,通过菌根菌丝网络吸收水分在实验中很少被关注,尤其是通过同位素示踪法。在温室中的两室根盒研究中,将紫花苜蓿种植在主室(PC)中,要么接种摩西管柄囊霉,要么不接种。植物根系要么被允许进入副室(SC),要么通过根排斥网限制在 PC 中。在 PC 中控制基质水分,使植物在高水分(15%的重量含水量,GWC)或低水分(8%GWC)下生长。同时,SC 始终保持在 15%的 GWC,并作为根系和/或菌丝可及(或不可及)的水源。SC 中的水用氘(D)标记,以量化植物从 SC 中吸收的水量。重要的是,当根系可以接触到 D 源时,增加的 D 掺入植物中表明丛枝菌根植物吸收了更多的水,但这主要是由于靠近 D 源的丛枝菌根根系通常更大。另一方面,与非丛枝菌根植物相比,可接触到 D 源的 AM 真菌菌丝将 D 掺入植物中的量增加了两倍以上。尽管这种影响很强,但通过 AM 真菌菌丝的水分运输与植物的蒸腾需求相比仍然较低。
