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IAA acts as signaling molecule in the diatom-bacteria interactions, which needs exchange of nutrients, like organosulfur, ammonia, and tryptophan 1. This hormone signaling mode might be prevalent during plant-microbe interactions. Some phytohormones were originally isolated from fungi, and finally proved to be plant hormone 2 , For instance, GAs were firstly isolated from a rice pathogen Gibberella fujikuroi , latter found to stimulate rice root growth, and finally identified as natural regulators of plant growth and development The GA biosynthetic pathways are different in fungi, bacteria and plants, which may have evolved independently 51 , SLs were first found to induce hyphal branching of arbuscular mycorrhizal fungus Gigaspora margarita , and latter proved to be a new plant hormone inhibiting shoot branching 6 , ABA was also synthesized by some plant pathogenic fungi, including Botrytis cinerea , Cercospora rosicola , Fusarium oxysporum , and Rhizoctonia solani etc Besides the central ABA biosynthetic pathway, genes encoding polysaccharide hydrolases, sugar transporters, and precursor acetyl-CoA also contribute to the ABA biosynthesis in fungi In summary of these transcriptome and metabolite analyses, we proposed an interaction model between plant and endophytic fungi mediated by ABA Fig.
The plant hormone ABA might be sensed by some receptor in endophytic fungi. The central cellular machines for gene transcription, protein synthesis and degradation were changed. Then it may affect the nucleotide metabolism, which might exchange nutrients and energy with plant cell. By the main precursor acetyl-CoA, the biosynthesis of secondary metabolites was also altered.
Production of mycotoxins, which have insect-resistance and anti-pathogen activity, might contribute to adaption of host plant cell against environmental stresses. These interactions are mediated by hormone signaling, nutrients exchange, and secondary metabolites. The ranges of responses to ABA in Aspergillus are quite interesting, and especially the effects on transcription, translation, glycolysis, and cell proliferation might indicate an effect on an mTOR signaling pathway 54 , The molecular mechanism involving ABA receptor and the signal transduction pathway during host-microbe interactions still needs further investigations.
Proposed cross-talk between plant and endophytic fungus A. The plant ABA might be sensed by endophytic fungus, which may change the gene transcription, protein biosynthesis and degradation. Then, primary metabolism may changed, which could exchange nutrients with host cell.
Fungal secondary metabolites may also be changed for their environmental adaption. The cross-talk between plant and associated bacteria might be developed during long term of co-evolution 1. It would be interesting to compare their genetic and transcriptomic differences, and reveal the underlying molecular hormone signaling mechanism. The plant hormone ABA affects not only fungal growth and development, but also primary and secondary metabolisms of endophytic fungus A.
ABA not just acts as hormone in plants, but also as signaling molecule in fungi Moreover, ABA may also regulate the immune modulation and glucose homeostasis in mammals, which might have some medical applications 59 , The phytohormone ABA may act as plant pathogen effector and mammal immune regulator, which are mediated by microbes As an ancient molecule, ABA might function as interspecies communication signal in the natural ecosystems JQ was originally isolated from the fresh leaves of mangrove plant 18 , ABA was dissolved in ethanol as stock solution and added by 0.
Samples from three flasks were mixed and vacuum-filtered. The metabolites extraction and HPLC analysis were following previous procedures Isolation and identification of natural products from A.
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