Fungal Symbiosis Protects Plants Against Drought and Disease
By developing a symbiotic relationship with fungi, plants not only become more tolerant to diseases but can also help contribute to more sustainable agricultural practices. This is the conclusion of a new study from the University of Gothenburg.
Most crops can form symbiosis with fungi to gain key nutrients. The fungi in turn gain carbohydrates generated through the plant’s photosynthesis.
This type of symbiosis is called arbuscular mycorrhizas and is of key importance to sustainable agriculture since it helps crops utilise better the phosphate in fertilisers.
‘This symbiosis is very important since the leakage of phosphate from farm fields contributes to harmful eutrophication of rivers, lakes and seas,’ says Cornelia Spetea Wiklund, professor at the Department of Biological and Environmental Sciences, University of Gothenburg.
The Symbiosis Protects against Drought and Diseases
The fungal symbiosis also makes the plants more tolerant to certain diseases and environmental factors such as drought.
In order to learn how to better utilise the symbiosis in agriculture, the researchers have explored what causes the increased hardiness of plants. One mechanism involved seems to be that the fungi increase the plant’s levels of several hormones in both its roots and shoots.
‘Studies of the legume Medicago truncatula show that the synthesis and signalling of two important plant hormones increase in plants that form this symbiosis,’ says Lisa Adolfsson, researcher at the Department of Biological and Environmental Sciences, University of Gothenburg.
One of the hormones (ABA) makes the plant more drought tolerant, since it reduces the evaporation of water through the stomata of the leaves. The other hormone (jasmonate) helps increase the production of secondary substances that protect the plant against stress and diseases.
The Symbiosis Has Hormonal Effects in Plants
By measuring the levels of various substances in the shoots of the legume, which lives in symbiosis with fungi, and combining the results with large-scale genetic studies, the researchers have found that the levels of secondary substances (flavonoids and terpenoids) rise in the shoots as a result of the increased hormonal levels.
‘This is an interesting finding that may explain the increased tolerance to various stressors and diseases,’ says Spetea Wiklund.
So, the results show that symbiotic fungi influence the hormonal levels of crops.
‘The legume Medicago truncatula is used as a model for other legumes. Consequently, the findings are applicable on commercially important crops such as soybeans,’ says Adolffson.
This article has been republished from materials provided by University of Gothenburg. Note: material may have been edited for length and content. For further information, please contact the cited source.
Lisa Adolfsson, Hugues Nziengui, Ilka N Abreu, Jan Šimura, Azeez Beebo, Andrei Herdean, Jila Aboalizadeh, Jitka Široká, Thomas Moritz, Ondřej Novák, Karin Ljung, Benoît Schoefs, Cornelia Spetea. Enhanced Secondary- and Hormone Metabolism in Leaves of Arbuscular Mycorrhizal Medicago truncatula. Plant Physiology, 2017; 175 (1): 392 DOI: 10.1104/pp.16.01509.
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