The ectomycorrhizal symbiosis: life in the real world

ANDY F.S. TAYLOR , IAN ALEXANDER
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Abstract

Ectomycorrhizas (ECM) are dual organs formed between the terminal feeder roots of many plant species and certain soil fungi. The species richness and taxonomic diversity of ECM symbionts is impressive: ca. 7-10,000 fungal and ca. 8,000 plant species may be capable of forming ECM. The latter are the dominant components of forest and woodland ecosystems over much of the earth's surface. The obligate nature of the symbiosis for ECM fungi has been brought into question by reports that some species produce sporocarps under field conditions in the absence of a host plant. We suggest that there is no unequivocal evidence to support this. The spread of tree roots is often underestimated and small, overlooked hosts such as dwarf Salix spp or sedges may explain the appearance of ECM sporocarps in vegetation apparently devoid of ECM hosts. Compared to plant material, the sporocarps of ECM fungi contain high concentrations of N and P. We show that it would take between 3 and 14 million mycorrhizal tips, or 1800 km of hyphae, to supply the N in one sporocarp of Boletus edulis. The mantle formed by the fungus over the root tip is the likely site of storage for the N and P required for sporocarp production, and we discuss the chemical and structural mechanisms developed on mantles by ECM fungi to defend this resource against fungivory.

外生菌根共生:现实世界中的生活
外生菌根(ECM)是在许多植物的末端取食根和某些土壤真菌之间形成的双重器官。ECM共生体的物种丰富度和分类多样性令人印象深刻:大约7-10,000种真菌和大约8,000种植物可能能够形成ECM。后者是地球表面大部分地区森林和林地生态系统的主要组成部分。据报道,在没有寄主植物的野外条件下,一些物种会产生孢子囊,这使ECM真菌共生的专性受到质疑。我们认为没有明确的证据支持这一点。树根的传播通常被低估,而小的、被忽视的寄主,如矮柳或莎草,可以解释在明显缺乏ECM寄主的植被中出现ECM孢子实的原因。与植物材料相比,ECM真菌的孢子囊中含有高浓度的N和p。我们发现,在Boletus edulis的一个孢子囊中,需要300万到1400万个菌根尖端或1800公里的菌丝来供应N。真菌在根尖上形成的地幔可能是孢子皮生产所需氮和磷的储存场所,我们讨论了ECM真菌在地幔上形成的化学和结构机制,以保护这一资源免受真菌的侵害。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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