Ectomycorrhizal Fungi: Difference between revisions
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[[File:Ecto Vs. Endo.png|500px|thumb|right| Endomycorrhiza vs Ectomycorrhiza]] | [[File:Ecto Vs. Endo.png|500px|thumb|right| Endomycorrhiza vs Ectomycorrhiza]] | ||
==Structures== | ==Structures== | ||
[[File:Ecm diagram.jpg|thumb|Diagram of ectomycorrhizal fingal relationship (left). Photo from Nature Education Bonfante.]] | [[File:Ecm diagram.jpg|thumb|Diagram of ectomycorrhizal fingal relationship (left). Photo from Nature Education Bonfante.]] | ||
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===Relationship in action=== | ===Relationship in action=== | ||
Once the fungus has infected the plant roots and the epidermal cells, the mantle can form. Upon initial colonization, increased polypeptide synthesis has been observed. [9] | Once the fungus has infected the plant roots and the epidermal cells, the mantle can form. Upon initial colonization, increased polypeptide synthesis has been observed. [9] An important function of mycorrhizal fungi is its propensity to aid in the uptake of nitrogen, which is used for vital processes within the plant. [10] Partnerships with mycorrhizal fungi allow can assist plants in outcompeting their neighboring plants that do not from relationships with mycorrhizae. | ||
===Process of nutrient transport=== | ===Process of nutrient transport=== | ||
Nutrients are absorbed from the surrounding soil and transported to the plant roots through the use of three components | Nutrients are absorbed from the surrounding soil and transported to the plant roots through the use of three components: soil-fungus interface, fungus-apoplast interface, and apoplast-root interface. Once nutrients have reached the fungus-apoplast interface, the fungus keeps some of the acquired nutrients to maintain its own homeostasis. Up to 86% of the host's nitrogen requirements can be provided by the fungus, while keeping around 15% of the plant's net primary productivity. [11] | ||
Once nutrients have reached the fungus-apoplast interface, the fungus keeps some of the acquired nutrients to maintain its own homeostasis. Up to 86% of the host's nitrogen requirements can be provided by the fungus, while keeping around 15% of the plant's net primary productivity. [11] | |||
==Agriculture and Restoration== | ==Agriculture and Restoration== | ||
Latest revision as of 15:56, 30 March 2022
Ectomycorrhizal fungi (ECM) are a subgroup of mycorrhizae that evolved with the first land plants around 450 million years ago. They form symbiotic relationships with plant roots. Despite ectomycorrhizae forming on about 2% of plant species on earth, they perform some of the most environmentally and economically beneficial interactions. [1] ECM assist plants in nutrient uptake and prevent the uptake of toxic or harmful materials and pathogens.
They differ from the subgroup endomycorrhizae in that they do not penetrate the roots and are mainly found on the outside of the root system. The word Ectomycorrihiza stems from three Greek words: ἐκτός ektos, "outside"; μύκης mykes, "fungus"; and ῥίζα rhiza, "root".
Structures
Mantle
A layer encasing the outside of the root tip in either a loose gathering or tight alignment of hyphae. The presence of the mantle can sometimes hinder root hair growth if the root is secured tightly.
Hartig net
A network of hyphae strands that work around epidermal and cortical root cells, as they make their way through the cortex towards the middle of the root. [4]
Extraradical hyphae
A fine network of hyphae that extend outward from the encased root, filling the role of the suppressed root hairs. By spreading out into the surrounding soil, the hyphae can extract water and nutrients for transport back to the root.
Fruiting bodies
The most recognizable part of an ECM relationship is the fruiting body. These growths are usually easy to spot with the naked eye. The function of the fruiting body is sexual reproduction to spread the fungus to new hosts.
Symbiotic Relationship
In order to attract and form an ECM relationship, plants release metabolites, or small molecules, that encourage hyphae to grow in the direction of the plant root. [7] Flavonoids are one example of a metabolite exuded by plant roots. [8] Once the hyphae approach and penetrate the outer membrane of the root cap, the fungus can begin to infect the plant. In some cases, natural defenses may still resist the invasion by default for up to 21 days. [3]
Relationship in action
Once the fungus has infected the plant roots and the epidermal cells, the mantle can form. Upon initial colonization, increased polypeptide synthesis has been observed. [9] An important function of mycorrhizal fungi is its propensity to aid in the uptake of nitrogen, which is used for vital processes within the plant. [10] Partnerships with mycorrhizal fungi allow can assist plants in outcompeting their neighboring plants that do not from relationships with mycorrhizae.
Process of nutrient transport
Nutrients are absorbed from the surrounding soil and transported to the plant roots through the use of three components: soil-fungus interface, fungus-apoplast interface, and apoplast-root interface. Once nutrients have reached the fungus-apoplast interface, the fungus keeps some of the acquired nutrients to maintain its own homeostasis. Up to 86% of the host's nitrogen requirements can be provided by the fungus, while keeping around 15% of the plant's net primary productivity. [11]
Agriculture and Restoration
In agricultural and restoration efforts, trees are often planted with ECM from their native ranges. Without their respective symbiotic partners in the soil, some tree species can struggle with the uptake of nutrients needed to survive.
References
[1] Tedersoo, Leho; May, Tom W.; Smith, Matthew E. (2010). "Ectomycorrhizal lifestyle in fungi: global diversity, distribution, and evolution of phylogenetic lineages" (PDF). Mycorrhiza. 20 (4): 217–263. doi:10.1007/s00572-009-0274-x. PMID 20191371.
[2] Dighton, J. "Mycorrhizae." Encyclopedia of Microbiology (2009): 153-162.
[3] Smith, Sally E.; Read, David J. (26 July 2010). Mycorrhizal Symbiosis. Academic Press. ISBN 978-0-08-055934-6.
[4] Carlile, M.J. & Watkinson, S.C. (1994) The Fungi. Academic Press Ltd, London. pp 329 - 340.
[5] Díez, Jesús. "Invasion biology of Australian ectomycorrhizal fungi introduced with eucalypt plantations into the Iberian Peninsula" (PDF). Issues in Bioinvasion Science. 2005: 3–15. doi:10.1007/1-4020-3870-4_2.
[6] Dickie, Ian A.; et al. (2010). "Co‐invasion by Pinus and its mycorrhizal fungi". New Phytologist. 187 (2): 475–484. doi:10.1111/j.1469-8137.2010.03277.x. PMID 20456067.
[7] Egerton-Warburton, L. M.; et al. (2003). "Mycorrhizal fungi". Encyclopedia of Soils in the Environment.
[8] Martin, Francis; et al. (2001). "Developmental cross talking in the ectomycorrhizal symbiosis: signals and communication genes". New Phytologist. 151 (1): 145–154. doi:10.1046/j.1469-8137.2001.00169.x.
[9] Hilbert, Jean-Louis; Costa, Guy; Martin, Francis (1991). "Ectomycorrhizin synthesis and polypeptide changes during the early stage of eucalypt mycorrhiza development" (PDF). Plant Physiology. 97 (3): 977–984. doi:10.1104/pp.97.3.977.
[10] Chalot, Michel; Brun, Annick (1998). "Physiology of organic nitrogen acquisition by ectomycorrhizal fungi and ectomycorrhizas". FEMS Microbiology Reviews. 22 (1): 21–44. doi:10.1111/j.1574-6976.1998.tb00359.x.
[11] Peay, Kabir G.; et al. (2007). "A strong species–area relationship for eukaryotic soil microbes: island size matters for ectomycorrhizal fungi" (PDF). Ecology Letters. 10 (6): 470–480. doi:10.1111/j.1461-0248.2007.01035.x.
[12] Tedersoo, Leho, et al. “Ectomycorrhizal Lifestyle in Fungi: Global Diversity, Distribution, and Evolution of Phylogenetic Lineages.” SpringerLink, Springer-Verlag, 16 Sept. 2009, link.springer.com/article/10.1007/s00572-009-0274-x.
[13] Ruotsalainen, A. L., et al. “Mycorrhizal Colonisation .” SpringerLink, Springer Netherlands, 8 Mar. 2008, link.springer.com/article/10.1007/s10661-007-0152-y.
[14] The Role of Ectomycorrhiza in Boreal Forest Ecosystem, L. Qu, K. Makoto, D. S. Choi, A. M. Quoreshi, T. Koike