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Review

Unraveling Arbuscular Mycorrhiza-Induced Changes in Plant Primary and Secondary Metabolome

by
Sukhmanpreet Kaur
and
Vidya Suseela
*
Department of Plant and Environmental Sciences, Clemson University, Clemson, SC 29634, USA
*
Author to whom correspondence should be addressed.
Metabolites 2020, 10(8), 335; https://doi.org/10.3390/metabo10080335
Submission received: 18 June 2020 / Revised: 2 August 2020 / Accepted: 12 August 2020 / Published: 18 August 2020
(This article belongs to the Special Issue Ecometabolomics)
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Abstract

:
Arbuscular mycorrhizal fungi (AMF) is among the most ubiquitous plant mutualists that enhance plant growth and yield by facilitating the uptake of phosphorus and water. The countless interactions that occur in the rhizosphere between plants and its AMF symbionts are mediated through the plant and fungal metabolites that ensure partner recognition, colonization, and establishment of the symbiotic association. The colonization and establishment of AMF reprogram the metabolic pathways of plants, resulting in changes in the primary and secondary metabolites, which is the focus of this review. During initial colonization, plant–AMF interaction is facilitated through the regulation of signaling and carotenoid pathways. After the establishment, the AMF symbiotic association influences the primary metabolism of the plant, thus facilitating the sharing of photosynthates with the AMF. The carbon supply to AMF leads to the transport of a significant amount of sugars to the roots, and also alters the tricarboxylic acid cycle. Apart from the nutrient exchange, the AMF imparts abiotic stress tolerance in host plants by increasing the abundance of several primary metabolites. Although AMF initially suppresses the defense response of the host, it later primes the host for better defense against biotic and abiotic stresses by reprogramming the biosynthesis of secondary metabolites. Additionally, the influence of AMF on signaling pathways translates to enhanced phytochemical content through the upregulation of the phenylpropanoid pathway, which improves the quality of the plant products. These phytometabolome changes induced by plant–AMF interaction depends on the identity of both plant and AMF species, which could contribute to the differential outcome of this symbiotic association. A better understanding of the phytochemical landscape shaped by plant–AMF interactions would enable us to harness this symbiotic association to enhance plant performance, particularly under non-optimal growing conditions.

1. Introduction

Plant–microbe interactions are ubiquitous and are indispensable for the health of both plants and soil. In belowground ecosystems, much of these interactions occur in the rhizosphere, which is inhabited by 10–100-fold more microbiome than the bulk soil due to the carbon (C) input from the plant [1]. Plant–microbe interactions often result in a positive outcome when plants associate with beneficial microorganisms such as mycorrhizal fungi, rhizobia, endophytes, and plant growth-promoting bacteria. The beneficial microbes enhance plant health through the acquisition of nutrients [2] and/or by enhancing the tolerance to abiotic [3] and biotic stresses [4] in return for the photosynthates [5]. A myriad of metabolites often mediates these interactions between plants and beneficial microbes as they facilitate partner recognition, colonization success, and hence the benefits gained by both partners. The microbial genome is affected by plant metabolites, and conversely, the plant genome is influenced by microbial metabolites; thus, the plant–microbe association induces changes in the transcriptome, proteome, and finally, the metabolome of the plant and microbes [6]. In this review, we focus on the changes in the primary and secondary metabolites in plants as influenced by the symbiotic association with arbuscular mycorrhizal fungi (AMF). We chose AMF, as it is among the most ubiquitous plant mutualists that enhance plant growth and yield mainly through the uptake of phosphorus (P). Phosphorus is sparingly available in soil due to complexation with iron and aluminum in acid soils and calcium in calcareous soils [7]. To increase the availability of P, plants have developed specific strategies that include the modification of root morphology, increase the rooting volume [8], the exudation of organic anions that releases P from metal complexes [9] and enzyme phosphatases that recycles the organic forms of P [10]. Another effective P acquisition strategy is the symbiotic association with AMF that allows the plants to forage a greater soil volume [11].
AMF are root obligate biotrophs belonging to the Glomeromycota phylum of fungi [11], forming symbiotic association with 70–80% of plants [12]. The symbiosis between plants and AMF is the most ancient plant-mutualistic association that has evolved over 400 million years ago [13,14]. The benefits of this mutualistic association to plants are multiple and varied, with the most important being the transfer of nutrients, mainly P [15,16], some extent of nitrogen (N), and other micronutrients such as copper and zinc due to their extensive hyphal network [17,18,19]. Higher procurement of nutrients by AMF is credited to their thin fungal hyphae that explore a larger volume of soil and could reach areas where the roots cannot access [20]. In addition to increasing the rooting volume, AMF can acquire P from less bioavailable P-minerals through chelation, acidification, and enzyme activity [21,22]. AMF symbiosis also increases tolerance to drought and salt stress and pests and diseases [23,24,25,26,27,28,29]. Apart from the acquisition of mineral nutrition, AMF also provides additional benefits by increasing the quality of the plant products [30,31] and contributes significantly to the accrual of soil organic matter through better soil aggregation and hyphal input [32]. Being the most widespread symbiotic association in nature, there is a high potential to utilize AMF symbiosis in agriculture, particularly in low input farming and sustainable agriculture [33]. Such an approach would reduce the need for P fertilizers, thus saving farming cost, and would further limit environmental pollution caused by the export of excess P to water bodies [34].
Unlike legume-rhizobia associations that exhibit high host specificity, the plant–AMF associations are less structured. The same plant can associate with different species of AMF and the same AMF species can associate with multiple plant species, i.e., they lack specificity in association. However, not all plant–AMF associations are mutually beneficial, and the productivity of the host plant (i.e., the outcome of the association) is highly specific to the identity of the AMF symbiont. For example, the AMF species Glomus macrocarpum caused a detrimental effect on tobacco plants [35]. However, other plant species such as Sorghum bicolor increased biomass and nutrient uptake when associated with G. macrocarpum [36]. Similarly, different AMF species stimulated different growth responses in Sorghum bicolor [37]. This differential response in the outcome of the plant–AMF association could be due to differences in both plant and AMF genotypes and environmental conditions [35]. The fungal characteristics that may contribute to the specificity in the outcome include differences in the functional traits [38], physiology [11], genetic variability [39], and molecular features such as signaling molecules and fungal effectors [40]. In addition, the AMF species can vary in their P uptake efficiencies [41], which may also contribute to the specificity in the outcome since the plant P uptake pathway is suppressed in the plant–AMF association [42]. Growth depressions in plants when associated with AMF may also arise due to the less control of the plant over the carbon allocation to AMF as plant may consider AMF colonization as a signal for providing carbon even in the absence of P benefits from the AMF [43]. Rhizosphere microbiome can also contribute to differences in the outcome of plant–AMF symbiosis as other soil microbes have a synergistic or antagonistic effect on root colonization by AMF [44,45].
The differential ability of plant species and AMF species to modulate plant metabolites could also contribute to the specificity in the outcome of plant–AMF association. Various metabolites influence the plant–AMF symbiotic association, starting from the pre-symbiotic stage to the formation and establishment of a functional symbiotic association. During the pre-symbiotic stage, the plants and the beneficial microbial partners exchange several chemical signals that result in the initiation of the symbiotic association. Under P-deficient conditions, several plant metabolites are exuded in the rhizosphere to ensure germination and growth of the AMF, whose concentration diminishes with increasing plant benefits from AMF colonization [46]. For example, the strigolactones are important signaling compounds from plants that affect the germination of the AMF spores and leads to the initiation of the plant–AMF symbiosis [47,48]. Apart from strigolactones, plant secondary metabolites such as flavonoids also act as chemical signals during the pre-symbiotic stage. Flavonoids are important for hyphal growth and their effect varies with their chemical composition [49]. Along with the plant metabolites, the AMF also produces certain chemical signals collectively termed as “myc-factors” [11] that initiate AMF colonization in plants. The lipochitooligosaccharides (LCOs) released by AMF act as signals that induce the symbiotic-specific response in host plants, which in turn helps in the development of the symbiosis [50]. The plant–AMF signaling has been elegantly elucidated by others [51,52] and is not the focus of this review. Here, we attempt to elucidate the changes in the primary and secondary metabolites in plants that define plant–AMF associations.
Apart from the chemicals produced exogenously to recognize partners and to establish a functional symbiosis, this mutualistic association also result in the reprogramming of the primary and secondary metabolic pathways of plants (Figure 1; [25,53,54]). The change in the plant metabolic pathways could be potentially mediated by the AMF, plants, environment, and their interactions. The change in plant metabolome due to the symbiotic association with AMF can vary with different plant species or colonization with different AMF species.

2. Primary Metabolites

In the plant–AMF association, plants transfer nearly 4–20% of the photosynthetically fixed carbon to the AMF [25] in the form of sugars [55] and lipids [56]. The carbon drain from the plant by AMF leads to a higher photosynthetic activity [57] as well as creates a carbon sink in the roots [55]. Thus, the carbon metabolism is often elevated in plants inoculated with AMF compared to the non-inoculated control plants. Moreover, these variations are often specific to AMF strains and plant species [58]. AMF-mediated changes in the root metabolites can also affect the metabolites of aboveground organs either due to signaling or transportation [59,60]. Previous studies have revealed that plants associated with AMF differ considerably from non-inoculated plants in the primary metabolites such as sugars, organic acids, and amino acids [61,62,63,64].

2.1. Sugars

Sugar forms an important regulator in the plant–AMF symbiotic association [56,65] as it is among the main sources of carbon supply from the plants to the AMF. Hexoses such as glucose and fructose are easily assimilated by the AMF structures in the roots [66]. A higher concentration of hexoses was observed in the roots at the beginning of the AMF colonization (26–29 days after germination). However, at harvest (40 days after germination), the non-mycorrhizal roots exhibited higher sugars compared to mycorrhizal roots [67]. Maize plants had a higher concentration of sugars in the leaves when associated with AMF [68]. As the plant–AMF interactions are highly functional under low nutrient availability [11], higher sugar content is observed in mycorrhizal plants under P deficiency (Table 1). For example, cebil seedlings in association with an AMF species mixture showed a higher accumulation of soluble carbohydrates and proteins under P-deficient conditions. However, this response was not observed in the seedlings supplied with high P, where there was less colonization by AMF, indicating the potential of AMF to reprogram sugar metabolism [69]. The hexoses assimilated by AMF can be further transformed into trehalose and glycogen in the intra-radical mycelium of AMF [55]. Trehalose is considered as a fungal-specific sugar due to its presence only in the mycorrhizal plants [70]. The concentration of trehalose increased with mycorrhizal colonization [71], and its accumulation in mycorrhizal plants can protect the plants against abiotic stresses [72].

2.2. Organic Acids

In addition to sugars, AMF also impacts the tricarboxylic acid (TCA) cycle [64]. The TCA cycle and its intermediaries involving citric acid, malic acid, fumaric acid and succinic acid are important for cellular respiration and adenosine triphosphate (ATP) synthesis [73]. This energy synthesis helps the plant in its development as well as tolerating adverse stress conditions [74]. For example, during the later stages of mycorrhizal development, higher accumulation of organic acids was observed in the leaves of pea [75]. However, a decrease in organic acids of the TCA cycle was recorded in dicots along with species-specific changes in other metabolites in the above-ground organs of plants as AMF affects the plants’ central catabolism due to carbon utilization. In contrast, an increase in organic acids in the monocot (Poa annua) was observed (Table 1; [76]). Some of the substrates of the TCA cycle such as aconitic acid and fumaric acid diminished in mycorrhizal roots of Medicago truncatula, implying a mycorrhiza induced stimulation of mitochondrial and plastidial metabolism [70]. Moreover, plants release organic acids into the soil to solubilize the insoluble form of P [77,78]. For example, a higher concentration of citric acid was observed in the soil solution of Allium Cepa colonized with Gigaspora margarita compared to the control plants [79]. AMF species can also vary their ability to release organic acids into the soil [80]. Fungal extra-radical hyphae release organic acids into the soil which helps in breaking the complex forms of minerals and therefore could increase their absorption in the plants [81].

2.3. Amino Acids

Amino acids, the building blocks of proteins, and enzymes, also act as signaling molecules and regulates environmental stress in plants [82]. The amino acids can be directly taken by the AMF from the soil [62] and they can also be synthesized by AMF spores using N from the soil [83]. The amino acid uptake from the soil was higher in the arbuscular mycorrhizal plants compared to the non-mycorrhizal plants [62]. Previous studies have reported increased, decreased or no variation of amino acid content in plants due to AMF colonization (Table 1; [84,85]). AMF colonization decreased the content of phenylalanine, the precursor of phenylpropanoids. Amino acids such as tryptophan, tyrosine, phenylalanine, alanine, and leucine decreased, while the abundance of amino acid-derived secondary metabolites increased in the mycorrhizal roots of tomato [64]. Concomitantly, amino acids such as aspartic, asparagine, glutamic, and pyroglutamic acids that are less related to the production of secondary compounds increased in AM roots [70]. Amino acids such as glutamic acid, histidine, and cysteine accumulated in tomato plants associated with AMF [86]. Furthermore, there was no variation in the amino acid content of mycorrhizal and non-mycorrhizal roots of tobacco plants [87].
Similar to the roots, amino acids were higher in the leaves of different plant species inoculated with AMF [75,88] compared to the non-inoculated plants. However, a reduction in the amino acids was observed in willow leaves [89] and Lotus japonicus associated with AMF [84]. Apart from roots and leaves, the amino acid content in fruits also increased with mycorrhization. For example, in tomato plants inoculation with Glomus mosseae increased several amino acids in fruits, of which glutamine and asparagine concentrations were the most responsive [90]. Aromatic amino acids are important in grapes as they are essential for the aroma of wines and these amino acids increased in grapes when colonized by AMF species compared to the non-inoculated plants [91]. Amino acids showed variable accumulation in different studies which could be a function of the plant species or fungal genotype as well as the environmental conditions (Table 1).

2.4. Effect of AMF on Primary Metabolites under Biotic/Abiotic Stresses

Plants subjected to abiotic stress increased the content of sugars particularly in association with AMF. Under water-stressed conditions, both sugars and lipids were upregulated in AMF plants, which was consistent with the biomass increase in the plants [92]. Similarly, under drought conditions, maize inoculated with AMF had less reduction in sugar content compared to the non-inoculated plants [93]. Although a higher abundance of reducing sugars was observed in the leaves of mycorrhizal maize plants without salinity stress, comparatively higher reducing sugars were observed in mycorrhizal plants compared to non-mycorrhizal plants at different salinity levels [68]. Increased soluble sugars by mycorrhizae rendered resistance against salt stress in maize plants [61]. Several studies have found a similar accumulation of sugars in plants colonized by AMF under different abiotic stress conditions such as drought, salinity, cold stress, heavy metals, and nutrient deficiencies [81,94,95,96,97,98,99,100,101,102,103]. The accumulation of sugars could vary with AMF species. For example, trifoliate orange seedlings under drought conditions accumulated higher concentrations of sucrose, glucose, and fructose in the leaves of the plants inoculated with Paraglomus occultum compared to Funneliformis mosseae [29]. Moreover, under stress conditions, there could be a differential accumulation of sugars in roots and leaves (Table 1). For example, under temperature stress, soluble sugars accumulated in roots of AMF plants but the soluble sugar content in leaves did not vary between AMF and non-inoculated plants [104].
An increase in organic acids was observed in Puccinellia tenuiflora inoculated with AMF, as part of the mechanism of toleration against alkali stress [105]. Similarly, monocots such as Poa annua [76] and maize associated with AMF had higher organic acid content under salt stress [68]. A higher concentration of malic acid was observed in the root exudates of Citrullus lanatus (watermelon) colonized with Glomus mosseae. However, other organic acids increased with Fusarium oxysporum f. sp. niveum infection [106].
Under drought conditions, trifoliate orange plants inoculated with AMF plants had a lower accumulation of proline than the non-AMF plants indicating that AMF plants experienced less stress under drought [29]. In soybean, under drought stress, the roots of AMF plants accumulated 14% more proline, whereas the shoots accumulated 39% less proline compared to the non-inoculated plants [107]. Interestingly, another study with maize showed a reduction in amino acids in the leaves of mycorrhizal plants under different salinity levels [68]. Furthermore, under alkaline stress conditions, amino acids such as glutamine that scavenge reactive oxygen species (ROS) also increased in the AMF-inoculated seedlings of Puccinellia tenuiflora [105]. More importantly, in cocoa plants, AMF inoculation reduced the susceptibility to Phytophthora megakarya along with higher soluble content of amino acids in leaves [108].
Overall, the sugars, organic acids, and amino acids are differentially regulated in various plant species by different AMF species (Table 1). They are mostly elevated or decreased, to the best benefit of the plant and also to reduce the costs of the resource under biotic and abiotic stresses. Moreover, AMF also showed the capacity to upregulate or downregulate plant metabolism based on plant growth conditions. The changes in primary metabolites due to AMF provide protection from environmental stress and improves the quality of the plant products. Most of these benefits to plants may also depend on the AMF demand on plant carbon, which would also vary with different AMF species thus affecting the specificity of the outcome of plant–AMF interaction.
Table
Table 1. Summary of primary metabolites modulated by AMF in different studies.
Table 1. Summary of primary metabolites modulated by AMF in different studies.
Primary MetabolitesPlant PartsAMF SpeciesPlant SpeciesEnviromental ConditionIncrease/DecreaseReference
Sugars
FructoseRootsGlomus versiformePoncirus trifoliataWell-wateredIncrease[109]
GlucoseRootsGlomus versiformePoncirus trifoliataDroughtIncrease[109]
KestoseLeaves, flowersGlomus mossaeLotus japonicus-Increase[84]
Soluble sugarsRoot + shootGlomus mossaeMaizeSalt stressIncrease[61]
Soluble sugarsLeavesGlomus mossaeMaizeSalt stressIncrease[68]
SucroseRoots + leavesGlomus versiformePoncirus trifoliataDroughtIncrease[109]
Total sugarsRootGlomus intraradicesMaizeDroughtIncrease[93]
Total sugarsLeavesGlomus intraradicesMaizeDroughtIncrease in drought sensitive and decrease in drought resistant variety[93]
TrehaloseRootsGlomus intraradicesMedicago truncatula-Increase[70]
Sugar alcohols
Myo-inositolLeaves, flowersGlomus mossaeLotus japonicus-Increase[84]
PinitolRootsFunneliformis mossaeTriticum durumWater stressDecrease[92]
XilitolRoots* AMF mix and natural AMF inoculumTriticum durumN stress, P richIncrease[110]
XylitolLeaves, flowersGlomus mossaeLotus japonicus-Increase[84]
Organic acids
2-methyl-malic acidLeaves, flowersGlomus mossaeLotus japonicus-Decrease[84]
Acetic acidLeavesGlomus mossaeMaizeSalt stressIncrease[68]
Citric acidLeaves, flowersGlomus mossaeLotus japonicus-Decrease[84]
Citric acidLeavesRhizophagus irregularis** Monocot and dicots-Decrease in dicots and increase in monocot[76]
Formic acidLeavesGlomus mossaeMaizeSalt stressDecrease at highest salt concentration[68]
Fumaric acidLeavesGlomus mossaeMaizeSalt stressIncrease[68]
Fumaric acidLeavesRhizophagus irregularis** Monocot and dicots-Decrease in dicots and increase in monocot[76]
Isocitric acidLeavesRhizophagus irregularis** Monocot and dicots-Partly Decrease in dicots and increase in monocot[76]
Malic acidLeaves, flowersGlomus mossaeLotus japonicus-Decrease[84]
Malic acidLeavesGlomus mossaeMaizeSalt stressIncrease[68]
Malic acidLeavesRhizophagus irregularis** Monocot and dicots-Decrease in dicots and increase in monocot[76]
Oxalic acidLeavesGlomus mossaeMaizeSalt stressIncrease[68]
Succinic acidLeaves, flowersGlomus mossaeLotus japonicus-Decrease[84]
Succinic acidLeavesGlomus mossaeMaizeSalt stressDecrease at highest salt concentration[68]
Succinic acidLeavesRhizophagus irregularis** Monocot and dicots-Partly decrease in dicots and increase in monocot[76]
Amino acids
4-amino-butanoic acidLeaves, flowersGlomus mossaeLotus japonicus-Decrease[84]
AlanineLeavesRhizophagus irregularis** Monocot and dicots-Increase (mainly in dicots)[76]
AlanineRoot* AMF mix and natural AMF inoculumTriticum durumN stress, P richDecrease [110]
AsparagineLeaves, flowersGlomus mossaeLotus japonicus-Decrease[84]
AsparagineRoots* AMF mix and natural AMF inoculumTriticum durumN stress, P richDecrease in AMF mix[110]
AsparagineRootsGlomus intraradicesMedicago truncatula-Increase[70]
Aspartic acidLeaves, flowersGlomus mossaeLotus japonicus-Decrease[84]
Aspartic acidLeavesRhizophagus irregularis** Monocot and dicots-Increase (mainly in dicots)[76]
Aspartic acidRootsFunneliformis mossae and Rhizophagus irregularis
(different treatments)		Solanum lycopersicumMinimum PDecrease[64]
Aspartic acidRootsGlomus intraradicesMedicago truncatula-Increase[70]
Glutamic acidLeaves, flowersGlomus mossaeLotus japonicus-Decrease[84]
Glutamic acidLeavesRhizophagus irregularis** Monocot and dicots-Increase (mainly in dicots)[76]
Glutamic acidRootsFunneliformis mossae and Rhizophagus irregularis
(different treatments)		Solanum lycopersicumMinimum PIncrease[64]
Glutamic acidRootsGlomus intraradicesMedicago truncatula-Increase[70]
GlutamineRoots* AMF mix and natural AMF inoculumTriticum durumN stress, P richDecrease in AMF mix[110]
GlycineLeaves, flowersGlomus mossaeLotus japonicus-Decrease[84]
HomoserineLeavesRhizophagus irregularis** Monocot and dicots-Increase (mainly in dicots)[76]
IsoleucineLeavesRhizophagus irregularis** Monocot and dicots-Increase (mainly in dicots)[76]
Leucine/IsoleucineRootsFunneliformis mossae and Rhizophagus irregularis
(different treatments)		Solanum lycopersicumMinimum PDecrease[64]
OrnithineLeavesRhizophagus irregularis** Monocot and dicots-Increase (mainly in dicots)[76]
PhenylalanineLeavesRhizophagus irregularis** Monocot and dicots-Increase (mainly in dicots)[76]
PhenylalanineRoots* AMF mix and natural AMF inoculumTriticum durumN stress, P richDecrease in AMF mix[110]
PhenylalanineRootsFunneliformis mossae and Rhizophagus irregularis (different treatments)Solanum lycopersicumMinimum PDecrease[64]
SerineLeavesRhizophagus irregularis** Monocot and dicots-Increase (mainly in dicots)[76]
ThreonineLeavesRhizophagus irregularis** Monocot and dicots-Increase (mainly in dicots)[76]
TryptophanRootsFunneliformis mossae and Rhizophagus irregularis
(different treatments)		Solanum lycopersicumMinimum PDecrease[64]
TyrosineRootsFunneliformis mossae and Rhizophagus irregularis
(different treatments)		Solanum lycopersicumMinimum PDecrease[64]
Fatty acids
Fatty acids and their estersRoots* AMF mix and natural AMF inoculumTriticum durumN stress, P richDecrease in AMF mix[110]
Octadecanoic acidLeaves, flowersGlomus mossaeLotus japonicus-Decrease[84]
Oleic acidRootsGlomus intraradicesMedicago truncatula-Increase[70]
Palmitic acidRootsGlomus intraradicesMedicago truncatula-Increase[70]
Palmitvaccenic acidRootsGlomus intraradicesMedicago truncatula-Increase[70]
Vaccenic acidRootsGlomus intraradicesMedicago truncatula-Increase[70]
ProteinsLeavesGigaspora albida+ Acaulospora longulaAnadenanthera colubrinaMinimal PIncrease[69]
Carbohydrates
3-propylphosphoenolpyruvateRootsFunneliformis mossaeTriticum durumWater stressIncrease[92]
CarbohydratesLeavesGigaspora albida+ Acaulospora longulaAnadenanthera colubrinaMinimal phosphorusPIncrease[69]
Glucose-1,6-bisphosphateRootsFunneliformis mossaeTriticum durumWater stressIncrease[92]
Mannosylfructose-phosphateRootsFunneliformis mossaeTriticum durumWater stressIncrease[92]
* AMF mix = Scutellospora calospora, Acuolospora laevis, Glomus aggregatum, Rhizophagus irregulare, Funneliformis mossae, Glomus fasciculatum, Glomus deserticola, and Gigaspora margarita. ** Monocot and dicots = Plantago lanceolata, Plantago major, Veronica chamaedrys, Medicago truncatula (Dicots) and Poa annua (Monocot).

3. Secondary Metabolites

Secondary metabolites play a critical role in plant defense against biotic and abiotic stresses [111]. Similar to primary metabolites, AMF also influences different secondary metabolites. In the plant–AMF symbiosis, the secondary metabolites mediate interactions between the two partners starting from the phase of recognition to colonization and further the establishment of AMF within the root tissues. Secondary metabolites are released by both plants and AMF in the pre-symbiotic stage of association, which act as signaling molecules in plant–AMF symbiotic interaction [112]. The host plant and AMF then engage in a coordinated molecular dialog that would suppress the defense response of the host plant [113] and later prime the host for better tolerance against biotic and abiotic stresses [114]. The AMF-induced plant protection against biotic and abiotic stresses is mediated through the production of several secondary metabolites (Table 2). The ability to modulate and suppress the plant defense system may vary with both plant and AMF genotypes and their interaction with the environment. Inoculation with AMF can improve plant health by enhancing the whole plant defense system known as the systemic acquired resistance (SAR). Furthermore, AMF can prime the plant to react faster to pathogen attack through induced systemic resistance ISR [115]. AMF also provides protection against many insect-pests where the AMF-induced plant protection was found to be more effective against phloem feeders or specialist chewing insects compared to generalist herbivores [4]. Other than their function in the plant defense system, some of the secondary metabolites enhanced by AMF in agricultural products [116] and medicinal plants [117] increase the quality of the products. Several secondary metabolite pathways are activated by AMF, such as the carotenoid, phenylpropanoid, and antioxidant pathways [118,119]. Compounds produced in these pathways are indicators of different functions in the plant–AMF symbiosis such as signaling, stress tolerance, nutrient uptake, and resistance against biotic and abiotic stresses (Figure 1).

3.1. Carotenoid Pathway

Carotenoids belong to the subfamily of terpenoids with 40 carbon atoms and 8 isoprene molecules in their structures [135]. The carotenoid pathway plays an important role in many plant processes such as photosynthesis, photoprotection, hormones synthesis, and release and signaling [136]. Some of the compounds derived from the carotenoid pathway are key regulators of AM symbiosis. Strigolactones, the important signaling molecules that initiate AMF symbiosis, are plant hormones that are synthesized in the carotenoid pathway [137]. Under low inorganic P availability, plants release strigolactones into the soil [138], which are perceived by the AMF as signaling molecules. The strigolactones trigger multiple responses in AMF such as germination of spores, hyphal elongation, and the formation of hyphopodia [47]. After colonization, the AMF in turn affects the carotenoid pathway by inducing the production of other apocarotenoids such as mycorradicin and cyclohexenone derivatives, which are important for establishing and maintaining AMF symbiosis [70,139]. For example, an accumulation of cyclohexenone derivatives was observed in barley with an increase in the mycorrhizal establishment [121]. Among the cyclohexonone derivatives, the most abundant are the mono-, di- and branched triglycosides of blumenols [125]. Blumenols which are produced in the roots were found to be further transported to the aboveground organs of the plants and are considered as shoot biomarkers for AMF colonization [59]. The content of blumenols could thus vary with plant organs where its content in the roots may not mirror that in the shoots as observed in ragwort [118]. The accumulation of these cyclohexenone derivatives was observed in different plant species with different AMF species, but their quantity varied across AMF species [123].
Moreover, the apocarotenoids are observed to be highly abundant in AMF roots of most of the plant species. These apocarotenoids may involve in the synthesis of signaling molecules, autoregulation of fungal colonization, and protection of plants against pathogens and ROS [140]. The carotenoid biosynthesis is activated in almost all the mycorrhizal plants and thus it can be assumed as a general characteristic of mycorrhizal plants [141]. Additionally, blumenin, a sesquiterpenoid cyclohexenone glycoside, accumulated in the roots of graminaceous plants with mycorrhizae but was not observed when the same plants were exposed to abiotic stress or pathogen or endophyte. Thus, the terpenoids metabolism can be specific to the AMF association with the plant [126]. Moreover, the release of volatile sesquiterpenes upon herbivore attack reduced in the mycorrhizal inoculated Plantago lanceolata plants compared to the non-inoculated plants, reflecting indirect upregulation of the defense system in the plant [142]. These findings suggest that carotenoid pathway has different applicability in AMF symbiosis such as signaling compounds during the pre-symbiotic stage; as markers of AMF colonization in both root and shoot after colonization; and as important compounds mediating the indirect priming of the defense system.

3.2. Phenylpropanoid Pathway

Phenylpropanoids form the largest group of compounds among secondary metabolites. They are biosynthesized from aromatic amino acid phenylalanine. They are further divided into five main groups including flavonoids, monolignols, phenolic acids, stilbenes, and coumarins [143]. They play a significant role in signaling, which is important for both plant development and defense [144]. The phenylpropanoid pathway undergoes significant reprogramming due to the AMF association. The AMF induces a change in both the abundance and composition of different plant secondary metabolites to ensure its colonization and establishment in plants.
Flavonoids are an important group of compounds in the phenylpropanoid pathway. Flavonoids provide color, aroma, and taste to plants; inhibit the production of ROS due to biotic or abiotic stresses; and regulate the plant-symbiotic associations [145]. In plant–AMF interactions, the flavonoids play an essential role in initiating and restricting the AMF colonization. The flavonoid biosynthesis was upregulated in the mycorrhizal plant leaves [60]. Different flavonoids can have varying effects on the colonization of different AMF species [146]. The flavonoids, namely formononetin and ononin, have an essential role in the autoregulation of symbiotic association by limiting AMF colonization in the plant after it reaches a threshold [147]. Similarly, at the later stages of fungal colonization, the upregulation of some isoflavonoids such as daidzein, ononin, and malonylonin was observed in the mycorrhizal roots of Medicago truncatula [70]. A comparative study conducted between successfully colonized roots of Medicago truncatula, Medicago sativa and myc- roots (incompletely colonized roots) of Medicago sativa suggested that 4′, 7-dihydroxyflavone flavonoid increased in mycorrhizal roots. However, it did not increase in myc- roots, suggesting its important role in the growth of internal AMF structure [148]. Similarly, medicarpin levels were elevated during initial colonization, and subsequently reduced to negligible levels at the full development stage of the AMF. Interestingly, the decrease in medicarpin was not observed in myc- roots indicating that the decrease in medicarpin is critical for the establishment and regulation of AMF colonization in Medicago [148]. More importantly, increased levels of some flavonoids in mycorrhizal roots such as formononetin malonyl glucoside (FGM), medicarpin malonyl glycoside (MGM), diadzein and coumestrol emphasizes on the improved ability of mycorrhizal plants to resist stresses [148]. Along with the above, flavonoids such as quercetin, which is known to have an important role as a phytochemical in grapes, are stimulated in mycorrhizal plants, and this increase was highly dependent on the grape varieties [129]. Although increasing soil P affected the accumulation of primary metabolites, the elevated P conditions did not affect the accumulation of flavonoids, tannins, and phenolics [69]. Similarly, in the leaves of Medicago truncatula, the abundance of flavonoids and anthocyanins increased in AMF plants even in the absence of any P uptake benefits to the plant [134]. These results suggest that secondary metabolites in the phenylpropanoid pathway are often reprogrammed by mycorrhizal colonization irrespective of the benefits provided by AMF including the increased uptake of nutrients.
Apart from flavonoids, other phenolic acids also act as signaling compounds in plant–microbial interactions [149] and as antioxidant compounds that protect the plants against many stress conditions. A higher abundance of phenolic acids also reflects a better quality of the plant products [150]. Increased abundance of phenolic compounds was observed in the leaves and roots of peanut inoculated with AMF [128]. Moreover, different phenolic acids vary in abundance in the same plant. For example, caffeic and chlorogenic acids decreased while ferulic acid increased in abundance in the mycorrhizal roots of tomato [151]. Furthermore, different AMF species increased the tolerance of date palm against bayoud disease by increasing the enzymatic activities of peroxidases and polyphenoloxidases, which further are associated with increasing phenolic compounds in the cell wall [152]. Therefore, a higher abundance of phenolic acids in mycorrhizal plants depicts the priming of the defense system of the plant, which further protects the plant from pathogens. Moreover, other phenolic acid derivatives showed altered concentration in mycorrhizal plants. The accumulation of hydroxycinnamate amides was observed in barley roots [128] and chicory roots along with the higher abundance of the derivatives of caffeic acids in AMF-inoculated plants [127]. Similarly, other compounds in the phenylpropanoid pathway such as coumarins and its hydroxyl forms had higher abundance in leaves of willow when colonized by AMF [89]. These coumarins can act as antimicrobial and antioxidant compounds. A higher abundance of these compounds in the roots could also affect the mycorrhizal colonization because of their antimicrobial properties, which explains the lower abundance of coumarins such as scopoletin and its glucoside scopolin in the roots of tobacco cultivar [87].
Most of the compounds in the phenylpropanoid pathway have antioxidant properties, which will protect the plants against ROS. Not only these antioxidants are beneficial for plants in stress conditions, but also these compounds provide medicinal properties to the plant [153]. AMF has been found to increase the accumulation of these compounds in plants [154]. This increase in the production of antioxidants could be partly contributed by the indirect benefits provided by AMF including nutrient (mainly P) uptake and partly due to the direct interaction with the plant, under a series of environmental conditions [155]. Under less water availability, mycorrhizae increased the antioxidant compounds in lettuce [120]. Interestingly, plants associated with AMF increased the synthesis of antioxidants such as rosmarinic and caffeic acids in sweet basil than the plants supplied with sufficient P. Thus, the increase in antioxidants in mycorrhizal plants cannot be attributed only to the P benefits. AMF also increased the medicinal value of purslane by increasing fatty acids, flavonoids, and antioxidant activity in the leaves of the plant under drought conditions [117]. More importantly, Glomus mosseae and Glomus caledonium increased the abundance of these antioxidant compounds, whereas Glomus intraradices did not elevate the synthesis of these compounds [148]. Furthermore, AMF species varied in enhancing the phenolic content and antioxidant activity in the two cultivars of globe artichoke, where Clardeoglomus claroideum 22W3 and Funneliformis mosseae IMA1 increased the antioxidant activity compared to the control, whereas other isolates of Funneliformis mosseae, Rhizophagus irregularis, and Glomus sp. did not affect the antioxidant activity [149]. Therefore, different AMF species can play a distinct role in increasing the production of these medicinal compounds [133]. This is further evident from one of the studies with mycorrhizal maize plants, where the leaves of the plants inoculated with Acaulospora longula accumulated higher flavonoids content compared to the control and the plants inoculated with Claroideoglomus etunicatum and Dentiscutata heterogama [156,157]. Differences in the accumulation of phenolics and flavonoids in various plant species by different AMF species points to the higher specificity in the outcome of the plant–AMF symbiotic association. However, the mechanisms underlying the higher specificity in the outcome of this association are not well explored.

3.3. Effect of AMF on Secondary Metabolites under Biotic/Abiotic Stresses

AMF provides resistance against many biotic and abiotic stresses [108,158,159,160,161,162,163,164,165,166,167,168]. Phenolic compounds are important secondary metabolites in disease suppression or defense mechanisms against other stress. Mycorrhizae enhance the phenolic content in plants, which could explain its role in protecting the plants against pathogens [128]. These phenolics are synthesized in higher quantity due to the upregulation of signaling pathways involving hydrogen peroxide, salicylic acid, and nitrogen oxide pathways in the colonized roots [169]. Similar upregulation of these pathways was observed in the mycorrhizal inoculated plants against citrus canker [161]. Furthermore, elevated flavonoid content corresponded with increased resistance against the tomato mosaic virus in the mycorrhizal tomato plants [170]. Other important low-molecular-weight antimicrobial compounds, namely phytoalexins, were accumulated in the roots when exposed to the pathogens in the presence of AMF. However, the absence of either AMF or pathogen did not influence the phytoalexins in the plant roots [131]. Under chilling stress, AMF increased the biomass of cucumber plants when exposed to low-temperature conditions than the plants without AMF under optimum and stressed conditions. Consistent with this biomass increase, AMF also raised the concentration of phenols, flavonoids, lignin, and many enzymes involved in the synthesis of secondary metabolites [119]. Despite a positive mycorrhizal growth response (MGR) by AMF under both drought and salinity conditions, only salinity stress seemed to affect the metabolite profile of tomato roots, because plants under water stress are more inclined to change the physiological processes, whereas salt stress can cause variations in antioxidant metabolites. The compounds in the mevalonate pathway, carotenoid pathway, oxylipins pathway, and lignans, which improves the stress tolerance, were accumulated in tomato plants inoculated with AMF compared to the control plants under salinity conditions [86]. Additionally, the phenylpropanoid pathway also upregulated under salt stress in the presence of AMF [171]. Similarly, water stress also affected the plant metabolome of wheat cultivars associated with AMF, as evident from the differential regulation of several metabolites in the secondary metabolite classes, including alkaloids, flavonoids, and terpenoids [92]. Drought results in oxidative stress and the accumulation of ROS, which causes damage to plants. In the presence of AMF, antioxidant compounds such as glutathione and 4-O-oxalyl-L-threonate reacted with ROS and reduced the oxidative stress in plants and hence caused less damage to plants due to drought. In addition, AMF also affected the accumulation of most of the glucosinolates [92] and cyanogenic glycoside [172]. Moreover, AMF modulated the polyamine metabolic pathway in trifoliate orange under drought stress where it increased the accumulation of putrescine and cadaverine, which enhanced drought tolerance by scavenging ROS, maintaining cell pH and ion homeostasis [173]. Interestingly, even under drought conditions, AMF enhanced the antioxidant activity of the medicinal plant, Purslane [117] and Dracocephalum moldavica [174]. Overall, AMF provides resistance against many biotic and abiotic stresses by increasing the abundance of several secondary metabolites (Table 2).

4. Plant Defense and Hormonal Regulation

Plants initially perceive AMF as putative pathogens, which results in the temporary activation of plant defense responses during the initial stages of colonization. The plants can regulate their defense responses through elicitor degradation, stimulating genes involved in regulating symbiotic association and hormonal regulation, including salicylic acid (SA) and jasmonic acid (JA) [175]. During the initial stage of colonization, AMF triggers the production of SA in plants. SA has a strong impact on the initial establishment of AMF, but not on the final root colonization by AMF [176,177]. As the higher content of SA reduces the colonization by AMF, this initial response is suppressed to ensure successful colonization by AMF. Moreover, while the upregulation of SA was observed during the early phase of mycorrhization, the upregulation of JA was observed during the late phase of mycorrhization when the salicylic acid decreases to ensure the establishment of AMF in the plant [25]. The up- and downregulation of these phytohormones explains the activity of AMF against the pathogens controlled by these hormones. Furthermore, AMF primes the plant defense system regulated by jasmonic acid. The upregulation of the jasmonic acid signaling pathway during plant–AMF interaction increases the production of defense compounds [25]. This priming of the defense system can vary with AMF genotypes [53]. The increase in JA enhanced the biosynthesis of secondary metabolites such as flavonoids and terpenoids [134]. A large number of fungal effectors are predicted to be released by mycorrhizal fungi, which could differentially affect the signaling pathways. Similarly, different AMF species are known to release different secreted proteins or fungal effectors, thus could affect the production of signaling hormones [40]. Precise regulation of different plant hormones is a critical factor in the successful establishment and hence the outcome of this symbiotic relationship [178].

5. Analytical Platforms for the Analysis of Plant Metabolome

Plant metabolome is a complex mixture of low-molecular-weight compounds that vary in their diversity and abundance. Nuclear magnetic resonance (NMR) spectroscopy and mass spectrometry (MS) are the most commonly used analytical platforms to analyze the metabolome [179]. Compared to MS, NMR is non-destructive, non-selective, enables structural elucidation and cross-laboratory comparisons and is thus widely used for non-targeted metabolomics. However, the major disadvantage of NMR is its low sensitivity [180,181]. Although the major advantage of MS is its high sensitivity compared to NMR, the different mass analyzers used in these studies, which vary in their resolution, affect the outcome of the analysis (Figure 2; [182]).
MS is coupled with liquid chromatography (LC) or gas chromatography (GC) to separate the compounds in a complex mixture. GC–MS is most effective for volatile compounds and its efficiency can be improved by derivatizing the samples to increase the volatility and stability of compounds. The high polarity compounds can be well detected with LC–MS. Hence, GC–MS and LC–MS together provide a more comprehensive information about plant metabolome [183]. The disadvantages of MS based analysis include the presence of matrix effect, ion suppression that would lead to wide variation in signal intensities and selectivity for specific analytes [181]. Methods used for GC- or LC-based chromatographic separation would affect the ability to identity and quantitate the metabolites. None of the instruments or methods can entirely detect all the compounds in the plant sample and, they can vary in their strengths and limitations. [183]. The results of plant metabolome analysis in various studies may be partly attributed to different methods and instruments employed. Plant metabolome can also vary with plant age, development stage, environmental conditions and fertilizer regimes [58]. Another drawback in plant metabolomics is the lack of robust libraries for the identification of compounds [184].

6. Conclusions

Plant metabolites are pre-requisites to initiate and maintain the plant–AMF symbiotic association. Briefly, the plant–AMF association begins after recognizing specific metabolites by both plants and AMF. Further, the plant–AMF symbiotic association modifies the plant defense system starting from the signaling and carotenoid pathway, and expanding to the phenylpropanoid pathway. The reprogramming of plant secondary metabolism due to AMF symbiosis enables the plant to better tolerate abiotic and biotic stresses. The increase in abundance of the antioxidant compounds in the plant explains their enhanced resistance against pests and pathogens and the improved quality of plant products. Furthermore, the carbon demands of AMF influence the primary metabolism of the plant that affects the abundance of sugars, amino acids and, organic acids. Many of these primary metabolites also alleviate various abiotic stresses such as drought and salinity. Not only the point of contact of AMF, i.e., roots show the modification of plant metabolome, but the entire plant metabolome exhibit considerable variation with AMF association. Thus, the symbiotic association of plants with AMF modulates the plant metabolome to ensure the colonization of AMF and to obtain carbon benefits from the plants. The benefits of AMF symbiosis to plants may arise from a combination of increased plant biomass and reprogrammed plant primary and secondary metabolome. However, studies have also found alternate results in which AMF association makes the plant vulnerable against pathogens [185] and decreases the biomass of the plants [35]. The outcome of the plant–AMF symbiosis is highly species-specific, where some AMF associations result in a positive outcome, while others exhibit neutral or negative outcomes (parasitism; [35]). The ability of both plant species and AMF species to modulate the primary and secondary metabolites may partly contribute to this differential outcome in plant–AMF symbiosis. Hence, it is important to direct our efforts towards understanding the reprogramming of plant metabolome elicited by different AMF species when colonizing the same plant species or different plant species. The reprogramming of plant metabolome should also be captured at different stages of the symbiotic association and different developmental stages of plants to better understand the outcome of plant–AMF symbiosis. A comprehensive understanding of the AMF-mediated changes in plant metabolome would help in deciphering the mechanisms underlying plant tolerance to biotic and abiotic stresses and improving the product quality of crops.

Author Contributions

Conceptualization, V.S.; writing—original draft preparation, S.K.; writing—review and editing, V.S. All authors have read and agreed to the published version of the manuscript.

Funding

This work was partly supported by funding from the National Science Foundation (DEB 1754679). This is technical contribution No. 6891 of the Clemson University Experiment Station.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Weller, D.M.; Thomashow, L.S. Current Challenges in Introducing Beneficial Microorganisms into the Rhizosphere. In Molecular Ecology of Rhizosphere Microorganisms; Wiley: Hoboken, NJ, USA, 2007; pp. 1–18. [Google Scholar]
  2. Nihorimbere, V.; Ongena, M.; Smargiassi, M.; Thonart, P. Beneficial effect of the rhizosphere microbial community for plant growth and health. Biotechnol. Agron. Soc. Environ. 2011, 15, 327–337. [Google Scholar]
  3. Sorty, A.M.; Bitla, U.M.; Meena, K.K.; Singh, N.P. Role of Microorganisms in Alleviating Abiotic Stresses. In Advances in Plant Microbiome and Sustainable Agriculture; Springer Science and Business Media: Berlin, Germany, 2018; pp. 115–128. [Google Scholar]
  4. Pineda, A.; Zheng, S.-J.; Van Loon, J.J.A.; Pieterse, C.M.; Dicke, M. Helping plants to deal with insects: The role of beneficial soil-borne microbes. Trends Plant Sci. 2010, 15, 507–514. [Google Scholar] [CrossRef] [PubMed]
  5. Denison, R.F.; Bledsoe, C.; Kahn, M.; O’Gara, F.; Simms, E.L.; Thomashow, L.S. Cooperation in the rhizosphere and the “free rider” problem. Ecology 2003, 84, 838–845. [Google Scholar] [CrossRef]
  6. Mhlongo, M.I.; Piater, L.A.; Madala, N.E.; Labuschagne, N.; A Dubery, I. The Chemistry of Plant–Microbe Interactions in the Rhizosphere and the Potential for Metabolomics to Reveal Signaling Related to Defense Priming and Induced Systemic Resistance. Front. Plant Sci. 2018, 9, 112. [Google Scholar] [CrossRef] [Green Version]
  7. Syers, J.K.; Johnston, A.E.; Curtin, D. Efficiency of soil and fertilizer phosphorus use: Reconciling changing concepts of soil phosphorus behaviour with agronomic information. FAO Fertil. Plant Nutr. Bull. 2008, 18, 128. [Google Scholar]
  8. López-Bucio, J.; Cruz-Ramírez, A.; Herrera-Estrella, L.R. The role of nutrient availability in regulating root architecture. Curr. Opin. Plant Boil. 2003, 6, 280–287. [Google Scholar] [CrossRef]
  9. Jones, D.L. Organic acids in the rhizosphere—A critical review. Plant Soil 1998, 205, 25–44. [Google Scholar] [CrossRef]
  10. Gilbert, G.A.; Vance, C.P.; Knight, J.D.; Allan, D. Acid phosphatase activity in phosphorus-deficient white lupin roots. Plant Cell Environ. 1999, 22, 801–810. [Google Scholar] [CrossRef]
  11. Parniske, M. Arbuscular mycorrhiza: The mother of plant root endosymbioses. Nat. Rev. Genet. 2008, 6, 763–775. [Google Scholar] [CrossRef]
  12. Brundrett, M.C.; Tedersoo, L. Evolutionary history of mycorrhizal symbioses and global host plant diversity. New Phytol. 2018, 220, 1108–1115. [Google Scholar] [CrossRef]
  13. Taylor, T.N.; Remy, W.; Haas, H.; Kerp, H. Fossil arbuscular mycorrhizae from the Early Devonian. Mycologia 1995, 87, 560–573. [Google Scholar] [CrossRef] [Green Version]
  14. Strullu-Derrien, C.; Kenrick, P.; Pressel, S.; Duckett, J.G.; Rioult, J.-P.; Strullu, D.-G. Fungal associations inHorneophyton lignerifrom the Rhynie Chert (c. 407 million year old) closely resemble those in extant lower land plants: Novel insights into ancestral plant-fungus symbioses. New Phytol. 2014, 203, 964–979. [Google Scholar] [CrossRef] [PubMed]
  15. Li, X.-L.; George, E.; Marschner, H. Extension of the phosphorus depletion zone in VA-mycorrhizal white clover in a calcareous soil. Plant Soil 1991, 136, 41–48. [Google Scholar] [CrossRef]
  16. Lekberg, Y.; Koide, R.T. Is plant performance limited by abundance of arbuscular mycorrhizal fungi? A meta-analysis of studies published between 1988 and 2003. New Phytol. 2005, 168, 189–204. [Google Scholar] [CrossRef]
  17. Smith, S.; Read, D. Mycorrhizal Symbiosis, 3rd ed.; Academic Press: Cambridge, MA, USA, 2008; p. 175. [Google Scholar]
  18. Smith, F.A.; Smith, F.A. Roles of Arbuscular Mycorrhizas in Plant Nutrition and Growth: New Paradigms from Cellular to Ecosystem Scales. Annu. Rev. Plant Boil. 2011, 62, 227–250. [Google Scholar] [CrossRef] [Green Version]
  19. Hodge, A.; Storer, K. Arbuscular mycorrhiza and nitrogen: Implications for individual plants through to ecosystems. Plant Soil 2014, 386, 1–19. [Google Scholar] [CrossRef]
  20. Bolan, N. A critical review on the role of mycorrhizal fungi in the uptake of phosphorus by plants. Plant Soil 1991, 134, 189–207. [Google Scholar] [CrossRef]
  21. Zhang, Q.; Zhang, Q.; Pan, J.; Jiang, S.; Liu, Y.; Bahadur, A.; Peng, Z.; Yang, Y.; Feng, H. Effect of arbuscular mycorrhizal fungi on soil enzyme activity is coupled with increased plant biomass. Eur. J. Soil Sci. 2019, 71, 84–92. [Google Scholar] [CrossRef]
  22. Harrison, M.J. The Arbuscular Mycorrhizal Symbiosis. In Plant-Microbe Interactions; Springer Science and Business Medi: Berlin, Germany, 1997; pp. 1–34. [Google Scholar]
  23. Colla, G.; Rouphael, Y.; Cardarelli, M.; Tullio, M.; Rivera, C.M.; Rea, E. Alleviation of salt stress by arbuscular mycorrhizal in zucchini plants grown at low and high phosphorus concentration. Boil. Fertil. Soils 2007, 44, 501–509. [Google Scholar] [CrossRef]
  24. Gianinazzi, S.; Gollotte, A.; Binet, M.-N.; Van Tuinen, D.; Redecker, D.; Wipf, D. Agroecology: The key role of arbuscular mycorrhizas in ecosystem services. Mycorrhiza 2010, 20, 519–530. [Google Scholar] [CrossRef]
  25. Jung, S.C.; Martínez-Medina, A.; López-Ráez, J.A.; Pozo, M.J. Mycorrhiza-Induced Resistance and Priming of Plant Defenses. J. Chem. Ecol. 2012, 38, 651–664. [Google Scholar] [CrossRef] [PubMed]
  26. Ruiz-Lozano, J.M.; Porcel, R.; Azcon, C.; Aroca, R.; Azcón, R. Regulation by arbuscular mycorrhizae of the integrated physiological response to salinity in plants: New challenges in physiological and molecular studies. J. Exp. Bot. 2012, 63, 4033–4044. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  27. Selosse, M.-A.; Bessis, A.; Pozo, M.J. Microbial priming of plant and animal immunity: Symbionts as developmental signals. Trends Microbiol. 2014, 22, 607–613. [Google Scholar] [CrossRef] [PubMed]
  28. Jayne, B.; Quigley, M. Influence of arbuscular mycorrhiza on growth and reproductive response of plants under water deficit: A meta-analysis. Mycorrhiza 2013, 24, 109–119. [Google Scholar] [CrossRef] [PubMed]
  29. Wu, H.-H.; Zou, Y.-N.; Rahman, M.M.; Ni, Q.-D.; Wu, Q. Mycorrhizas alter sucrose and proline metabolism in trifoliate orange exposed to drought stress. Sci. Rep. 2017, 7, 42389. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  30. Castellanos-Morales, V.; Villegas, J.; Wendelin, S.; Vierheilig, H.; Eder, R.; Cárdenas-Navarro, R. Root colonisation by the arbuscular mycorrhizal fungus Glomus intraradices alters the quality of strawberry fruits (Fragaria × ananassa Duch.) at different nitrogen levels. J. Sci. Food Agric. 2010, 90, 1774–1782. [Google Scholar] [CrossRef]
  31. Baum, C.; El-Tohamy, W.; Gruda, N.S. Increasing the productivity and product quality of vegetable crops using arbuscular mycorrhizal fungi: A review. Sci. Hortic. 2015, 187, 131–141. [Google Scholar] [CrossRef]
  32. Wilson, G.; Rice, C.W.; Rillig, M.C.; Springer, A.; Hartnett, D.C. Soil aggregation and carbon sequestration are tightly correlated with the abundance of arbuscular mycorrhizal fungi: Results from long-term field experiments. Ecol. Lett. 2009, 12, 452–461. [Google Scholar] [CrossRef]
  33. Rillig, M.C.; Aguilar-Trigueros, C.A.; Camenzind, T.; Cavagnaro, T.R.; Degrune, F.; Hohmann, P.; Lammel, D.R.; Mansour, I.; Roy, J.; Van Der Heijden, M.G.A.; et al. Why farmers should manage the arbuscular mycorrhizal symbiosis. New Phytol. 2019, 222, 1171–1175. [Google Scholar] [CrossRef] [Green Version]
  34. Schindler, D.W.; Hecky, R.E.; Findlay, D.L.; Stainton, M.P.; Parker, B.R.; Paterson, M.J.; Beaty, K.G.; Lyng, M.; Kasian, S.E.M. Eutrophication of lakes cannot be controlled by reducing nitrogen input: Results of a 37-year whole-ecosystem experiment. Proc. Natl. Acad. Sci. USA 2008, 105, 11254–11258. [Google Scholar] [CrossRef] [Green Version]
  35. Johnson, N.C.; Graham, J.H.; Smith, F.A. Functioning of mycorrhizal associations along the mutualism-parasitism continuum. New Phytol. 1997, 135, 575–585. [Google Scholar] [CrossRef]
  36. Raju, P.S.; Clark, R.B.; Ellis, J.R.; Maranville, J.W. Effects of species of VA-mycorrhizal fungi on growth and mineral uptake of sorghum at different temperatures. Plant Soil 1990, 121, 165–170. [Google Scholar] [CrossRef]
  37. Watts-Williams, S.J.; Emmett, B.D.; Levesque-Tremblay, V.; MacLean, A.M.; Sun, X.; Satterlee, J.W.; Fei, Z.; Harrison, M.J. Diverse Sorghum bicolor accessions show marked variation in growth and transcriptional responses to arbuscular mycorrhizal fungi. Plant Cell Environ. 2019, 42, 1758–1774. [Google Scholar] [CrossRef] [PubMed]
  38. Chagnon, P.-L.; Bradley, R.L.; Maherali, H.; Klironomos, J. A trait-based framework to understand life history of mycorrhizal fungi. Trends Plant Sci. 2013, 18, 484–491. [Google Scholar] [CrossRef] [PubMed]
  39. Koch, A.M.; Antunes, P.M.; Maherali, H.; Hart, M.M.; Klironomos, J. Evolutionary asymmetry in the arbuscular mycorrhizal symbiosis: Conservatism in fungal morphology does not predict host plant growth. New Phytol. 2017, 214, 1330–1337. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  40. Lanfranco, L.; Fiorilli, V.; Gutjahr, C. Partner communication and role of nutrients in the arbuscular mycorrhizal symbiosis. New Phytol. 2018, 220, 1031–1046. [Google Scholar] [CrossRef] [PubMed]
  41. Kiers, E.T.; Duhamel, M.; Beesetty, Y.; Mensah, J.A.; Franken, O.; Verbruggen, E.; Fellbaum, C.R.; Kowalchuk, G.A.; Hart, M.M.; Bago, A.; et al. Reciprocal Rewards Stabilize Cooperation in the Mycorrhizal Symbiosis. Science 2011, 333, 880–882. [Google Scholar] [CrossRef] [Green Version]
  42. Smith, F.A.; Grace, E.J.; Smith, F.A. More than a carbon economy: Nutrient trade and ecological sustainability in facultative arbuscular mycorrhizal symbioses. New Phytol. 2009, 182, 347–358. [Google Scholar] [CrossRef]
  43. Smith, F.A.; Smith, S.E. How useful is the mutualism-parasitism continuum of arbuscular mycorrhizal functioning? Plant Soil 2013, 363, 7–18. [Google Scholar] [CrossRef]
  44. Ndoye, F.; Kane, A.; Bakhoum, N.; Sanon, A.; Fall, D.; Diouf, D.; Sylla, S.N.; Bâ, A.M.; Sy, M.O.; Noba, K. Response of Acacia senegal (L.) Willd. to inoculation with arbuscular mycorrhizal fungi isolates in sterilized and unsterilized soils in Senegal. Agrofor. Syst. 2013, 87, 941–952. [Google Scholar] [CrossRef]
  45. Hoeksema, J.D.; Chaudhary, V.B.; Gehring, C.A.; Johnson, N.C.; Karst, J.; Koide, R.T.; Pringle, A.; Zabinski, C.; Bever, J.D.; Moore, J.C.; et al. A meta-analysis of context-dependency in plant response to inoculation with mycorrhizal fungi. Ecol. Lett. 2010, 13, 394–407. [Google Scholar] [CrossRef] [PubMed]
  46. Graham, J.H.; Leonard, R.T.; Menge, J.A. Membrane-Mediated Decrease in Root Exudation Responsible for Phorphorus Inhibition of Vesicular-Arbuscular Mycorrhiza Formation. Plant Physiol. 1981, 68, 548–552. [Google Scholar] [CrossRef] [PubMed]
  47. Akiyama, K.; Matsuzaki, K.-I.; Hayashi, H. Plant sesquiterpenes induce hyphal branching in arbuscular mycorrhizal fungi. Nature 2005, 435, 824–827. [Google Scholar] [CrossRef] [PubMed]
  48. Besserer, A.; Puech-Pagès, V.; Kiefer, P.; Gomez-Roldan, V.; Jauneau, A.; Roy, S.; Portais, J.-C.; Roux, C.; Bécard, G.; Sejalon-Delmas, N. Strigolactones stimulate arbuscular mycorrhizal fungi by activating mitochondria. PLoS Boil. 2006, 4, e226. [Google Scholar] [CrossRef]
  49. Steinkellner, S.; Lendzemo, V.; Langer, I.; Schweiger, P.; Khaosaad, T.; Toussaint, J.-P.; Vierheilig, H. Flavonoids and Strigolactones in Root Exudates as Signals in Symbiotic and Pathogenic Plant-Fungus Interactions. Molecules 2007, 12, 1290–1306. [Google Scholar] [CrossRef] [Green Version]
  50. Maillet, F.; Poinsot, V.; André, O.; Puech-Pagès, V.; Haouy, A.; Gueunier, M.; Cromer, L.; Giraudet, D.; Formey, D.; Niebel, A.; et al. Fungal lipochitooligosaccharide symbiotic signals in arbuscular mycorrhiza. Nature 2011, 469, 58–63. [Google Scholar] [CrossRef]
  51. Vierheilig, H.; Piché, Y. Signalling in Arbuscular Mycorrhiza: Facts and Hypotheses. In Advances in Experimental Medicine and Biology; Springer Science and Business Media: Berlin, Germany, 2002; Volume 505, pp. 23–39. [Google Scholar]
  52. Oldroyd, G.E.D. Speak, friend, and enter: Signalling systems that promote beneficial symbiotic associations in plants. Nat. Rev. Genet. 2013, 11, 252–263. [Google Scholar] [CrossRef]
  53. Pozo, M.J.; Verhage, A.; García-Andrade, J.; Garcia, J.M.; Azcón-Aguilar, C. Priming Plant Defence Against Pathogens by Arbuscular Mycorrhizal Fungi. In Mycorrhizas—Functional Processes and Ecological Impact; Springer Science and Business Media: Berlin, Germany, 2008; pp. 123–135. [Google Scholar]
  54. Song, Y.; Ye, M.; Li, C.Y.; Wang, R.L.; Wei, X.C.; Luo, S.M.; Zeng, R. Priming of Anti-Herbivore Defense in Tomato by Arbuscular Mycorrhizal Fungus and Involvement of the Jasmonate Pathway. J. Chem. Ecol. 2013, 39, 1036–1044. [Google Scholar] [CrossRef]
  55. Bago, B.; Pfeffer, P.E.; Shachar-Hill, Y. Carbon Metabolism and Transport in Arbuscular Mycorrhizas. Plant Physiol. 2000, 124, 949–958. [Google Scholar] [CrossRef] [Green Version]
  56. Keymer, A.; Pimprikar, P.; Wewer, V.; Huber, C.; Brands, M.; Bucerius, S.L.; Delaux, P.-M.; Klingl, V.; Von Röpenack-Lahaye, E.; Wang, T.L.; et al. Lipid transfer from plants to arbuscular mycorrhiza fungi. eLife 2017, 6. [Google Scholar] [CrossRef]
  57. Kaschuk, G.; Kuyper, T.W.; Leffelaar, P.; Hungria, M.; Giller, K.E. Are the rates of photosynthesis stimulated by the carbon sink strength of rhizobial and arbuscular mycorrhizal symbioses? Soil Boil. Biochem. 2009, 41, 1233–1244. [Google Scholar] [CrossRef]
  58. Korenblum, E.; Aharoni, A. Phytobiome metabolism: Beneficial soil microbes steer crop plants’ secondary metabolism. Pest Manag. Sci. 2019, 75, 2378–2384. [Google Scholar] [CrossRef] [PubMed]
  59. Wang, M.; Schäfer, M.; Li, D.; Halitschke, R.; Dong, C.; McGale, E.; Paetz, C.; Song, Y.; Li, S.; Dong, J.; et al. Blumenols as shoot markers of root symbiosis with arbuscular mycorrhizal fungi. eLife 2018, 7, e37093. [Google Scholar] [CrossRef] [PubMed]
  60. Schweiger, R.; Müller, C. Leaf metabolome in arbuscular mycorrhizal symbiosis. Curr. Opin. Plant Boil. 2015, 26, 120–126. [Google Scholar] [CrossRef] [PubMed]
  61. Zhang, F.; Feng, G.; Li, X.; Tian, C.; Tang, C.; Rengel, Z. Improved tolerance of maize plants to salt stress by arbuscular mycorrhiza is related to higher accumulation of soluble sugars in roots. Mycorrhiza 2002, 12, 185–190. [Google Scholar] [CrossRef]
  62. Whiteside, M.D.; Garcia, M.O.; Treseder, K.K. Amino Acid Uptake in Arbuscular Mycorrhizal Plants. PLoS ONE 2012, 7, e47643. [Google Scholar] [CrossRef] [Green Version]
  63. Luginbuehl, L.H.; Menard, G.N.; Kurup, S.; Van Erp, H.; Radhakrishnan, G.V.; Breakspear, A.; Oldroyd, G.E.D.; Eastmond, P.J. Fatty acids in arbuscular mycorrhizal fungi are synthesized by the host plant. Science 2017, 356, 1175–1178. [Google Scholar] [CrossRef] [Green Version]
  64. Rivero, J.; Gamir, J.; Aroca, R.; Pozo, M.J.; Flors, V. Metabolic transition in mycorrhizal tomato roots. Front. Microbiol. 2015, 6, 598. [Google Scholar] [CrossRef]
  65. Shachar-Hill, Y.; Pfeffer, P.E.; Douds, D.; Osman, S.F.; Doner, L.W.; Ratcliffe, G. Partitioning of Intermediary Carbon Metabolism in Vesicular-Arbuscular Mycorrhizal Leek. Plant Physiol. 1995, 108, 7–15. [Google Scholar] [CrossRef] [Green Version]
  66. Pfeffer, P.E.; Douds, D.D.; Bécard, G.; Shachar-Hill, Y. Carbon Uptake and the Metabolism and Transport of Lipids in an Arbuscular Mycorrhiza. Plant Physiol. 1999, 120, 587–598. [Google Scholar] [CrossRef] [Green Version]
  67. Schubert, A.; Allara, P.; Morte, A. Cleavage of sucrose in roots of soybean (Glycine max) colonized by an arbuscular mycorrhizal fungus. New Phytol. 2004, 161, 495–501. [Google Scholar] [CrossRef]
  68. Sheng, M.; Tang, M.; Zhang, F.; Huang, Y. Influence of arbuscular mycorrhiza on organic solutes in maize leaves under salt stress. Mycorrhiza 2010, 21, 423–430. [Google Scholar] [CrossRef] [PubMed]
  69. Pedone-Bonfim, M.V.; A Lins, M.; Coelho, I.R.; Santana, A.S.; Da Silva, F.S.B.; Maia, L.C. Mycorrhizal technology and phosphorus in the production of primary and secondary metabolites in cebil (Anadenanthera colubrina (Vell.) Brenan) seedlings. J. Sci. Food Agric. 2012, 93, 1479–1484. [Google Scholar] [CrossRef] [PubMed]
  70. Schliemann, W.; Ammer, C.; Strack, D. Metabolite profiling of mycorrhizal roots of Medicago truncatula. Phytochemistry 2008, 69, 112–146. [Google Scholar] [CrossRef] [PubMed]
  71. Schubert, A.; Wyss, P.; Wiemken, A. Occurrence of trehalose in vesicular-arbuscular mycorrhizal fungi and in mycorrhizal roots. J. Plant Physiol. 1992, 140, 41–45. [Google Scholar] [CrossRef]
  72. Ocon, A.; Hampp, R.; Requena, N. Trehalose turnover during abiotic stress in arbuscular mycorrhizal fungi. New Phytol. 2007, 174, 879–891. [Google Scholar] [CrossRef]
  73. Fernie, A.R.; Carrari, F.; Sweetlove, L.J. Respiratory metabolism: Glycolysis, the TCA cycle and mitochondrial electron transport. Curr. Opin. Plant Boil. 2004, 7, 254–261. [Google Scholar] [CrossRef]
  74. Li, M.; Guo, R.; Jiao, Y.; Jin, X.; Zhang, H.; Shi, L.-X. Comparison of Salt Tolerance in Soja Based on Metabolomics of Seedling Roots. Front. Plant Sci. 2017, 8, 1101. [Google Scholar] [CrossRef]
  75. Shtark, O.Y.; Puzanskiy, R.K.; Avdeeva, G.S.; Yurkov, A.P.; Smolikova, G.; Yemelyanov, V.V.; Kliukova, M.S.; Shavarda, A.L.; Kirpichnikova, A.A.; Zhernakov, A.I.; et al. Metabolic alterations in pea leaves during arbuscular mycorrhiza development. Peer J. 2019, 7, e7495. [Google Scholar] [CrossRef] [Green Version]
  76. Schweiger, R.; Baier, M.C.; Persicke, M.; Müller, C. High specificity in plant leaf metabolic responses to arbuscular mycorrhiza. Nat. Commun. 2014, 5, 3886. [Google Scholar] [CrossRef] [Green Version]
  77. Zhang, F.; Ma, J.; Cao, Y.P. Phosphorus deficiency enhances root exudation of low-molecular weight organic acids and utilization of sparingly soluble inorganic phosphates by radish (Raghanus satiuvs L.) and rape (Brassica napus L.) plants. Plant Soil 1997, 196, 261–264. [Google Scholar] [CrossRef]
  78. Jones, D.L.; Hodge, A.; Kuzyakov, Y. Plant and mycorrhizal regulation of rhizodeposition. New Phytol. 2004, 163, 459–480. [Google Scholar] [CrossRef]
  79. Tawaraya, K.; Naito, M.; Wagatsuma, T. Solubilization of Insoluble Inorganic Phosphate by Hyphal Exudates of Arbuscular Mycorrhizal Fungi. J. Plant Nutr. 2006, 29, 657–665. [Google Scholar] [CrossRef]
  80. Klugh, K.R.; Cumming, J.R. Variations in organic acid exudation and aluminum resistance among arbuscular mycorrhizal species colonizing Liriodendron tulipifera. Tree Physiol. 2007, 27, 1103–1112. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  81. Giasson, P.; Karam, A.; Jaouich, A. Arbuscular Mycorrhizae and Alleviation of Soil Stresses on Plant Growth. In Mycorrhizae: Sustainable Agriculture and Forestry; Springer Science and Business Media: Berlin, Germany, 2008; pp. 99–134. [Google Scholar]
  82. Hildebrandt, T.; Nunes-Nesi, A.; Araujo, W.; Braun, H.-P. Amino Acid Catabolism in Plants. Mol. Plant 2015, 8, 1563–1579. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  83. Gachomo, E.; Allen, J.W.; Pfeffer, P.E.; Govindarajulu, M.; Douds, D.D.; Jin, H.; Nagahashi, G.; Lammers, P.J.; Shachar-Hill, Y.; Bücking, H. Germinating spores ofGlomus intraradicescan use internal and exogenous nitrogen sources forde novobiosynthesis of amino acids. New Phytol. 2009, 184, 399–411. [Google Scholar] [CrossRef] [PubMed]
  84. Fester, T.; Fetzer, I.; Buchert, S.; Lucas, R.; Rillig, M.C.; Härtig, C. Towards a systemic metabolic signature of the arbuscular mycorrhizal interaction. Oecologia 2011, 167, 913–924. [Google Scholar] [CrossRef] [PubMed]
  85. De Souza, L.A.; Camargos, L.S.; Schiavinato, M.A.; De Andrade, S.A.L. Mycorrhization alters foliar soluble amino acid composition and influences tolerance to Pb in Calopogonium mucunoides. Theor. Exp. Plant Physiol. 2014, 26, 211–216. [Google Scholar] [CrossRef]
  86. Rivero, J.; Álvarez, D.; Flors, V.; Azcón-Aguilar, C.; Pozo, M.J. Root metabolic plasticity underlies functional diversity in mycorrhiza-enhanced stress tolerance in tomato. New Phytol. 2018, 220, 1322–1336. [Google Scholar] [CrossRef] [Green Version]
  87. Maier, W.; Schmidt, J.; Nimtz, M.; Wray, V.; Strack, D. Secondary products in mycorrhizal roots of tobacco and tomato. Phytochemistry 2000, 54, 473–479. [Google Scholar] [CrossRef]
  88. Shao, Y.-D.; Zhang, D.-J.; Hu, X.-C.; Wu, Q.; Jiang, C.-J.; Gao, X.-B.; Kuča, K. Arbuscular Mycorrhiza Improves Leaf Food Quality of Tea Plants. Not. Bot. Horti Agrobot. Cluj-Napoca 2019, 47, 47. [Google Scholar] [CrossRef] [Green Version]
  89. Aliferis, K.A.; Chamoun, R.; Jabaji, S.H. Metabolic responses of willow (Salix purpurea L.) leaves to mycorrhization as revealed by mass spectrometry and 1H NMR spectroscopy metabolite profiling. Front. Plant Sci. 2015, 6, 1–15. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  90. Di Fossalunga, A.S.; Zouari, I.; Chalot, M.; Bonfante, P. The arbuscular mycorrhizal status has an impact on the transcriptome profile and amino acid composition of tomato fruit. BMC Plant Boil. 2012, 12, 44. [Google Scholar] [CrossRef] [Green Version]
  91. Torres, N.; Hilbert, G.; Antolín, M.C.; Goicoechea, N. Amino acids and flavonoids profiling in tempranillo berries can be modulated by the arbuscular mycorrhizal fungi. Plants 2019, 8, 400. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  92. Bernardo, L.; Carletti, P.; Badeck, F.; Rizza, F.; Morcia, C.; Ghizzoni, R.; Rouphael, Y.; Colla, G.; Terzi, V.; Lucini, L. Metabolomic responses triggered by arbuscular mycorrhiza enhance tolerance to water stress in wheat cultivars. Plant Physiol. Biochem. 2019, 137, 203–212. [Google Scholar] [CrossRef] [PubMed]
  93. Subramanian, K.S.; Charest, C.; Dwyer, L.M.; Hamilton, R.I. Effects of arbuscular mycorrhizae on leaf water potential, sugar content, and P content during drought and recovery of maize. Can. J. Bot. 1997, 75, 1582–1591. [Google Scholar] [CrossRef]
  94. Wang, F.; Sun, Y.; Shi, Z.Y. Arbuscular Mycorrhiza Enhances Biomass Production and Salt Tolerance of Sweet Sorghum. Microorganisms 2019, 7, 289. [Google Scholar] [CrossRef] [Green Version]
  95. Tisarum, R.; Theerawitaya, C.; Samphumphuang, T.; Phisalaphong, M.; Singh, H.P.; Cha-Um, S. Promoting water deficit tolerance and anthocyanin fortification in pigmented rice cultivar (Oryza sativa L. subsp. indica) using arbuscular mycorrhizal fungi inoculation. Physiol. Mol. Boil. Plants 2019, 25, 821–835. [Google Scholar] [CrossRef]
  96. Zhang, Z.; Zhang, J.; Xu, G.; Zhou, L.; Li, Y. Arbuscular mycorrhizal fungi improve the growth and drought tolerance of Zenia insignis seedlings under drought stress. New For. 2018, 50, 593–604. [Google Scholar] [CrossRef]
  97. Golubkina, N.A.; Zamana, S.; Seredin, T.M.; Poluboyarinov, P.A.; Sokolov, S.; Baranova, H.; Krivenkov, L.; Pietrantonio, L.; Caruso, G. Effect of Selenium Biofortification and Beneficial Microorganism Inoculation on Yield, Quality and Antioxidant Properties of Shallot Bulbs. Plants 2019, 8, 102. [Google Scholar] [CrossRef] [Green Version]
  98. Ramadan, M.E.-S. Mycorrhizal inoculation and phosphorus fertilizers to improve onion productivity in saline soil. Acta Sci. Pol. Hortorum Cultus 2019, 18, 57–66. [Google Scholar] [CrossRef]
  99. Chu, X.; Fu, J.; Sun, Y.; Xu, Y.; Miao, Y.; Xu, Y.; Hu, T. Effect of arbuscular mycorrhizal fungi inoculation on cold stress-induced oxidative damage in leaves of Elymus nutans Griseb. S. Afr. J. Bot. 2016, 104, 21–29. [Google Scholar] [CrossRef]
  100. Hashem, A.; Abd_Allah, E.F.; Alqarawi, A.A.; Wirth, S.; Egamberdieva, D. Arbuscular mycorrhizal fungi alleviate salt stress in lupine (Lupinus termis Forsik) through modulation of antioxidant defense systems and physiological traits. Legum. Res. Int. J. 2016, 39, 198–207. [Google Scholar] [CrossRef] [Green Version]
  101. Sanmartín, C.; Garmendia, I.; Romano, B.; Díaz, M.; Palop, J.A.; Goicoechea, N. Mycorrhizal inoculation affected growth, mineral composition, proteins and sugars in lettuces biofortified with organic or inorganic selenocompounds. Sci. Hortic. 2014, 180, 40–51. [Google Scholar] [CrossRef]
  102. Goicoechea, N.; Baslam, M.; Erice, G.; Irigoyen, J.J. Increased photosynthetic acclimation in alfalfa associated with arbuscular mycorrhizal fungi (AMF) and cultivated in greenhouse under elevated COJ. Plant Physiol. 2014, 171, 1774–1781. [Google Scholar] [CrossRef] [PubMed]
  103. Ding, X.; Zhang, S.; Wang, R.; Li, S.; Liao, X. AM fungi and rhizobium regulate nodule growth, phosphorous (P) uptake, and soluble sugar concentration of soybeans experiencing P deficiency. J. Plant Nutr. 2016, 39, 1915–1925. [Google Scholar] [CrossRef]
  104. Zhu, X.; Song, F.; Xu, H. Influence of arbuscular mycorrhiza on lipid peroxidation and antioxidant enzyme activity of maize plants under temperature stress. Mycorrhiza 2009, 20, 325–332. [Google Scholar] [CrossRef]
  105. Yang, C.; Zhao, W.; Wang, Y.; Zhang, L.; Huang, S.; Lin, J. Metabolomics Analysis Reveals the Alkali Tolerance Mechanism in Puccinellia tenuiflora Plants Inoculated with Arbuscular Mycorrhizal Fungi. Microorganisms 2020, 8, 327. [Google Scholar] [CrossRef] [Green Version]
  106. Ren, L.; Zhang, N.; Wu, P.; Huo, H.; Xu, G.; Wu, G. Arbuscular mycorrhizal colonization alleviates Fusarium wilt in watermelon and modulates the composition of root exudates. Plant Growth Regul. 2015, 77, 77–85. [Google Scholar] [CrossRef]
  107. Porcel, R.; Ruiz-Lozano, J.M. Arbuscular mycorrhizal influence on leaf water potential, solute accumulation, and oxidative stress in soybean plants subjected to drought stress. J. Exp. Bot. 2004, 55, 1743–1750. [Google Scholar] [CrossRef] [Green Version]
  108. Tchameni, S.N.; Nwaga, D.; Wakam, L.N.; Ngonkeu, E.L.M.; Fokom, R.; Kuaté, J.; Etoa, F.-X. Growth Enhancement, Amino Acid Synthesis and Reduction in Susceptibility Towards Phytophthora megakarya by Arbuscular Mycorrhizal Fungi Inoculation in Cocoa Plants. J. Phytopathol. 2012, 160, 220–228. [Google Scholar] [CrossRef]
  109. Wu, Q.; Xia, R.-X.; Zou, Y.-N.; Wang, G.-Y. Osmotic solute responses of mycorrhizal citrus (Poncirus trifoliata) seedlings to drought stress. Acta Physiol. Plant. 2007, 29, 543–549. [Google Scholar] [CrossRef]
  110. Saia, S.; Ruisi, P.; Fileccia, V.; Di Miceli, G.; Amato, G.; Martinelli, F. Metabolomics Suggests That Soil Inoculation with Arbuscular Mycorrhizal Fungi Decreased Free Amino Acid Content in Roots of Durum Wheat Grown under N-Limited, P-Rich Field Conditions. PLoS ONE 2015, 10, e0129591. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  111. Mazid, M.; Khan, T.A.; Mohammad, F. Role of secondary metabolites in defense mechanisms of plants. Biol. Med. 2011, 3, 232–249. [Google Scholar]
  112. Zhi-lin, Y.; Chuan-Chao, D.; Lian-Qing, C. Regulation and accumulation of secondary metabolites in plant-fungus symbiotic system. Afr. J. Biotechnol. 2007, 6, 1266–1271. [Google Scholar]
  113. Zamioudis, C.; Pieterse, C.M. Modulation of Host Immunity by Beneficial Microbes. Mol. Plant-Microbe Interact. 2012, 25, 139–150. [Google Scholar] [CrossRef] [Green Version]
  114. Conrath, U.; Beckers, G.J.M.; Flors, V.; García-Agustín, P.; Jakab, G.; Mauch, F.; Newman, M.-A.; Pieterse, C.M.; Poinssot, B.; Pozo, M.J.; et al. Priming: Getting Ready for Battle. Mol. Plant-Microbe Interact. 2006, 19, 1062–1071. [Google Scholar] [CrossRef] [Green Version]
  115. Chen, M.; Arato, M.; Borghi, L.; Nouri, E.; Reinhardt, D. Beneficial services of arbuscular mycorrhizal fungi –From ecology to application. Front. Plant Sci. 2018, 9, 1270. [Google Scholar] [CrossRef]
  116. Baslam, M.; Garmendia, I.; Goicoechea, N. Arbuscular Mycorrhizal Fungi (AMF) Improved Growth and Nutritional Quality of Greenhouse-Grown Lettuce. J. Agric. Food Chem. 2011, 59, 5504–5515. [Google Scholar] [CrossRef]
  117. Hosseinzadeh, M.H.; Ghalavand, A.; Mashhadi-Akbar-Boojar, M.; Modarres-Sanavy, S.A.M.; Mokhtassi-Bidgoli, A. Increased Medicinal Contents of Purslane by Nitrogen and Arbuscular Mycorrhiza under Drought Stress. Commun. Soil Sci. Plant Anal. 2019, 51, 118–135. [Google Scholar] [CrossRef]
  118. Hill, E.M.; Robinson, L.A.; Abdul-Sada, A.; Vanbergen, A.J.; Hodge, A.; Hartley, S.E. Arbuscular Mycorrhizal Fungi and Plant Chemical Defence: Effects of Colonisation on Aboveground and Belowground Metabolomes. J. Chem. Ecol. 2018, 44, 198–208. [Google Scholar] [CrossRef] [Green Version]
  119. Chen, S.; Jin, W.; Liu, A.; Zhang, S.; Liu, D.; Wang, F.; Lin, X.; He, C. Arbuscular mycorrhizal fungi (AMF) increase growth and secondary metabolism in cucumber subjected to low temperature stress. Sci. Hortic. 2013, 160, 222–229. [Google Scholar] [CrossRef]
  120. Baslam, M.; Goicoechea, N. Water deficit improved the capacity of arbuscular mycorrhizal fungi (AMF) for inducing the accumulation of antioxidant compounds in lettuce leaves. Mycorrhiza 2011, 22, 347–359. [Google Scholar] [CrossRef] [PubMed]
  121. Peipp, H.; Maier, W.; Schmidt, J.; Wray, V.; Strack, D. Arbuscular mycorrhizal fungus-induced changes in the accumulation of secondary compounds in barley roots. Phytochemistry 1997, 44, 581–587. [Google Scholar] [CrossRef]
  122. Fester, T.; Maier, W.; Strack, D. Accumulation of secondary compounds in barley and wheat roots in response to inoculation with an arbuscular mycorrhizal fungus and co-inoculation with rhizosphere bacteria. Mycorrhiza 1999, 8, 241–246. [Google Scholar] [CrossRef]
  123. Vierheilig, H.; Gagnon, H.; Strack, D.; Maier, W. Accumulation of cyclohexenone derivatives in barley, wheat and maize roots in response to inoculation with different arbuscular mycorrhizal fungi. Mycorrhiza 2000, 9, 291–293. [Google Scholar] [CrossRef]
  124. Schliemann, W.; Kolbe, B.; Schmidt, J.; Nimtz, M.; Wray, V. Accumulation of apocarotenoids in mycorrhizal roots of leek (Allium porrum). Phytochemistry 2008, 69, 1680–1688. [Google Scholar] [CrossRef]
  125. Schliemann, W.; Schmidt, J.; Nimtz, M.; Wray, V.; Fester, T.; Strack, D. Accumulation of apocarotenoids in mycorrhizal roots of Ornithogalum umbellatum. Phytochemistry 2006, 67, 1196–1205. [Google Scholar] [CrossRef]
  126. Maier, W.; Hammer, K.; Dammann, U.; Schulz, B.; Strack, D. Accumulation of sesquiterpenoid cyclohexenone derivatives induced by an arbuscular mycorrhizal fungus in members of the Poaceae. Planta 1997, 202, 36–42. [Google Scholar] [CrossRef]
  127. Rozpądek, P.; Wężowicz, K.; Stojakowska, A.; Malarz, J.; Surówka, E.; Sobczyk, Ł.; Anielska, T.; Ważny, R.; Miszalski, Z.; Turnau, K. Mycorrhizal fungi modulate phytochemical production and antioxidant activity of Cichorium intybus L. (Asteraceae) under metal toxicity. Chemosphere 2014, 112, 217–224. [Google Scholar] [CrossRef]
  128. Devi, M.C.; Reddy, M. Phenolic acid metabolism of groundnut (Arachis hypogaea L.) plants inoculated with VAM fungus and Rhizobium. Plant Growth Regul. 2002, 37, 151–156. [Google Scholar] [CrossRef]
  129. Eftekhari, M.; Alizadeh, M.; Ebrahimi, P. Evaluation of the total phenolics and quercetin content of foliage in mycorrhizal grape (Vitis vinifera L.) varieties and effect of postharvest drying on quercetin yield. Ind. Crop. Prod. 2012, 38, 160–165. [Google Scholar] [CrossRef]
  130. Rojas-Andrade, R.; Cerda-García-Rojas, C.M.; Frías-Hernández, J.; Dendooven, L.; Olalde-Portugal, V.; Ramos-Valdivia, A. Changes in the concentration of trigonelline in a semi-arid leguminous plant (Prosopis laevigata) induced by an arbuscular mycorrhizal fungus during the presymbiotic phase. Mycorrhiza 2003, 13, 49–52. [Google Scholar] [CrossRef] [PubMed]
  131. Yao, M.K.; Charles, M.T.; Boulanger, R.; Tweddell, R.J.; Désilets, H. Effect of mycorrhization on the accumulation of rishitin and solavetivone in potato plantlets challenged with Rhizoctonia solani. Mycorrhiza 2003, 13, 333–336. [Google Scholar] [CrossRef]
  132. Caser, M.; Victorino, Í.M.M.; Demasi, S.; Berruti, A.; Donno, D.; Lumini, E.; Bianciotto, V.; Scariot, V. Saffron Cultivation in Marginal Alpine Environments: How AMF Inoculation Modulates Yield and Bioactive Compounds. Agronomy 2018, 9, 12. [Google Scholar] [CrossRef] [Green Version]
  133. Toussaint, J.-P.; Smith, F.A.; Smith, S.E. Arbuscular mycorrhizal fungi can induce the production of phytochemicals in sweet basil irrespective of phosphorus nutrition. Mycorrhiza 2007, 17, 291–297. [Google Scholar] [CrossRef]
  134. Adolfsson, L.; Nziengui, H.; De Abreu, I.N.; Šimura, J.; Beebo, A.; Herdean, A.; Aboalizadeh, J.; Široká, J.; Moritz, T.; Novák, O.; et al. Enhanced Secondary- and Hormone Metabolism in Leaves of Arbuscular Mycorrhizal Medicago truncatula. Plant Physiol. 2017, 175, 392–411. [Google Scholar] [CrossRef] [Green Version]
  135. Li, C.; Swofford, C.A.; Sinskey, A.J. Modular engineering for microbial production of carotenoids. Metab. Eng. Commun. 2020, 10, e00118. [Google Scholar] [CrossRef]
  136. Shumskaya, M.; Wurtzel, E.T. The carotenoid biosynthetic pathway: Thinking in all dimensions. Plant Sci. 2013, 208, 58–63. [Google Scholar] [CrossRef] [Green Version]
  137. Al-Babili, S.; Bouwmeester, H.J. Strigolactones, a Novel Carotenoid-Derived Plant Hormone. Annu. Rev. Plant Boil. 2015, 66, 161–186. [Google Scholar] [CrossRef]
  138. Mayzlish-Gati, E.; De-Cuyper, C.; Goormachtig, S.; Beeckman, T.; Vuylsteke, M.; Brewer, P.B.; Beveridge, C.A.; Yermiyahu, U.; Kaplan, Y.; Enzer, Y.; et al. Strigolactones Are Involved in Root Response to Low Phosphate Conditions in Arabidopsis. Plant Physiol. 2012, 160, 1329–1341. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  139. Fiorilli, V.; Wang, J.Y.; Bonfante, P.; Lanfranco, L.; Al-Babili, S. Apocarotenoids: Old and New Mediators of the Arbuscular Mycorrhizal Symbiosis. Front. Plant Sci. 2019, 10, 10. [Google Scholar] [CrossRef] [PubMed]
  140. Strack, D.; Fester, T. Isoprenoid metabolism and plastid reorganization in arbuscular mycorrhizal roots. New Phytol. 2006, 172, 22–34. [Google Scholar] [CrossRef] [PubMed]
  141. Fester, T.; Wray, V.; Nimtz, M.; Strack, D. Is stimulation of carotenoid biosynthesis in arbuscular mycorrhizal roots a general phenomenon? Phytochemistry 2005, 66, 1781–1786. [Google Scholar] [CrossRef]
  142. Fontana, A.; Reichelt, M.; Hempel, S.; Gershenzon, J.; Unsicker, S.B. The Effects of Arbuscular Mycorrhizal Fungi on Direct and Indirect Defense Metabolites of Plantago lanceolata L. J. Chem. Ecol. 2009, 35, 833–843. [Google Scholar] [CrossRef] [Green Version]
  143. Deng, Y.; Lu, S. Biosynthesis and Regulation of Phenylpropanoids in Plants. Crit. Rev. Plant Sci. 2017, 36, 257–290. [Google Scholar] [CrossRef]
  144. A Dixon, R.; Achnine, L.; Kota, P.; Liu, C.-J.; Reddy, M.S.S.; Wang, L. The phenylpropanoid pathway and plant defence-a genomics perspective. Mol. Plant Pathol. 2002, 3, 371–390. [Google Scholar] [CrossRef]
  145. Mierziak, J.; Kostyn, K.; Kulma, A. Flavonoids as Important Molecules of Plant Interactions with the Environment. Molecules 2014, 19, 16240–16265. [Google Scholar] [CrossRef]
  146. Scervino, J.M.; Ponce, M.A.; Erra-Bassells, R.; Vierheilig, H.; Ocampo, J.A.; Godeas, A. Flavonoids exhibit fungal species and genus specific effects on the presymbiotic growth of Gigaspora and Glomus. Mycol. Res. 2005, 109, 789–794. [Google Scholar] [CrossRef] [Green Version]
  147. Catford, J.G.; Staehelin, C.; LaRose, G.; Piché, Y.; Vierheilig, H. Systemically suppressed isoflavonoids and their stimulating effects on nodulation and mycorrhization in alfalfa split-root systems. Plant Soil 2006, 285, 257–266. [Google Scholar] [CrossRef]
  148. Harrison, M.J. Isoflavonoid Accumulation and Expression of Defense Gene Transcripts During the Establishment of Vesicular-Arbuscular Mycorrhizal Associations in Roots of Medicago truncatula. Mol. Plant-Microbe Interact. 1993, 6, 643. [Google Scholar] [CrossRef]
  149. Mandal, S.M.; Chakraborty, D.; Dey, S. Phenolic acids act as signaling molecules in plant-microbe symbioses. Plant Signal Behav. 2010, 5, 359–368. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  150. Ghasemzadeh, A. Flavonoids and phenolic acids: Role and biochemical activity in plants and human. J. Med. Plants Res. 2011, 5, 6697–6703. [Google Scholar] [CrossRef]
  151. López-Ráez, J.A.; Flors, V.; García, J.M.; Pozo, M.J. AM symbiosis alters phenolic acid content in tomato roots. Plant Signal. Behav. 2010, 5, 1138–1140. [Google Scholar] [CrossRef] [Green Version]
  152. Jaiti, F.; Meddich, A.; El Hadrami, I. Effectiveness of arbuscular mycorrhizal fungi in the protection of date palm (Phoenix dactylifera L.) against bayoud disease. Physiol. Mol. Plant Pathol. 2007, 71, 166–173. [Google Scholar] [CrossRef]
  153. Krishnaiah, D.; Sarbatly, R.; Nithyanandam, R. A review of the antioxidant potential of medicinal plant species. Food Bioprod. Process. 2011, 89, 217–233. [Google Scholar] [CrossRef]
  154. Da Silva, F.S.B.; Maia, L.C. Mycorrhization and phosphorus may be an alternative for increasing the production of metabolites in Myracrodruon urundeuva. Theor. Exp. Plant Physiol. 2018, 30, 297–302. [Google Scholar] [CrossRef]
  155. Wu, Q.; Zou, Y.-N.; Xia, R.X. Effects of water stress and arbuscular mycorrhizal fungi on reactive oxygen metabolism and antioxidant production by citrus (Citrus tangerine) roots. Eur. J. Soil Boil. 2006, 42, 166–172. [Google Scholar] [CrossRef]
  156. Avio, L.; Maggini, R.; Ujvári, G.; Incrocci, L.; Giovannetti, M.; Turrini, A. Phenolics content and antioxidant activity in the leaves of two artichoke cultivars are differentially affected by six mycorrhizal symbionts. Sci. Hortic. 2020, 264, 109153. [Google Scholar] [CrossRef]
  157. Da Silva, F.A.; Maia, L.C.; Silva, F.S.B. Arbuscular mycorrhizal fungi as biotechnology alternative to increase concentrate of secondary metabolites in Zea mays L. Braz. J. Bot. 2018, 42, 189–193. [Google Scholar] [CrossRef]
  158. Eid, K.E.; Abbas, M.H.; Mekawi, E.M.; Elnagar, M.M.; Abdelhafez, A.A.; Amin, B.H.; Mohamed, I.; Ali, M.M. Arbuscular mycorrhiza and environmentally biochemicals enhance the nutritional status of Helianthus tuberosus and induce its resistance against Sclerotium rolfsii. Ecotoxicol. Environ. Saf. 2019, 186, 109783. [Google Scholar] [CrossRef] [PubMed]
  159. Huang, D.; Ma, M.; Wang, Q.; Zhang, M.; Jing, G.; Li, C.; Ma, F. Arbuscular mycorrhizal fungi enhanced drought resistance in apple by regulating genes in the MAPK pathway. Plant Physiol. Biochem. 2020, 149, 245–255. [Google Scholar] [CrossRef] [PubMed]
  160. Ahammed, G.J.; Mao, Q.; Yan, Y.; Wu, M.; Wang, Y.; Ren, J.; Guo, P.; Liu, A.; Chen, S. Role of Melatonin in Arbuscular Mycorrhizal Fungi-Induced Resistance to Fusarium Wilt in Cucumber. Phytopathology 2020, 110, 999–1009. [Google Scholar] [CrossRef] [PubMed]
  161. Xie, M.-M.; Zhang, Y.-C.; Liu, L.-P.; Zou, Y.-N.; Wu, Q.; Kuca, K. Mycorrhiza Regulates Signal Substance Levels and Pathogen Defense Gene Expression to Resist Citrus Canker. Not. Bot. Horti Agrobot. Cluj-Napoca 2019, 47, 1161–1167. [Google Scholar] [CrossRef] [Green Version]
  162. Li, Y.; Duan, T.; Nan, Z. Arbuscular mycorrhizal fungus alleviates alfalfa leaf spots caused by Phoma medicaginis revealed by RNA-seq analysis. J. Appl. Microbiol. 2019, 14387. [Google Scholar] [CrossRef]
  163. Song, Y.; Wang, M.; Zeng, R.; Groten, K.; Baldwin, I.T. Priming and filtering of antiherbivore defences among Nicotiana attenuata plants connected by mycorrhizal networks. Plant Cell Environ. 2019, 42, 2945–2961. [Google Scholar] [CrossRef]
  164. Sendek, A.; Karakoç, C.; Wagg, C.; Domínguez-Begines, J.; Couto, G.M.D.; Van Der Heijden, M.G.A.; Naz, A.A.; Lochner, A.; Chatzinotas, A.; Klotz, S.; et al. Drought modulates interactions between arbuscular mycorrhizal fungal diversity and barley genotype diversity. Sci. Rep. 2019, 9, 9650. [Google Scholar] [CrossRef] [Green Version]
  165. Gbongue, L.-R.; Lalaymia, I.; Zeze, A.; Delvaux, B.; Declerck, S. Increased Silicon Acquisition in Bananas Colonized by Rhizophagus irregularis MUCL 41833 Reduces the Incidence of Pseudocercospora fijiensis. Front. Plant Sci. 2019, 9, 1977. [Google Scholar] [CrossRef] [Green Version]
  166. Berdeni, D.; Cotton, T.E.A.; Daniell, T.J.; Bidartondo, M.I.; Cameron, D.D.; Evans, K.L. The Effects of Arbuscular Mycorrhizal Fungal Colonisation on Nutrient Status, Growth, Productivity, and Canker Resistance of Apple (Malus pumila). Front. Microbiol. 2018, 9, 9. [Google Scholar] [CrossRef]
  167. Bernaola, L.; Cosme, M.; Schneider, R.W.; Stout, M. Belowground Inoculation With Arbuscular Mycorrhizal Fungi Increases Local and Systemic Susceptibility of Rice Plants to Different Pest Organisms. Front. Plant Sci. 2018, 9, 1461. [Google Scholar] [CrossRef]
  168. Omomowo, I.O.; Fadiji, A.E.; Omomowo, O.I. Assessment of bio-efficacy of Glomus versiforme and Trichoderma harzianum in inhibiting powdery mildew disease and enhancing the growth of cowpea. Ann. Agric. Sci. 2018, 63, 9–17. [Google Scholar] [CrossRef]
  169. Zhang, R.-Q.; Zhu, H.; Zhao, H.-Q.; Yao, Q. Arbuscular mycorrhizal fungal inoculation increases phenolic synthesis in clover roots via hydrogen peroxide, salicylic acid and nitric oxide signaling pathways. J. Plant Physiol. 2013, 170, 74–79. [Google Scholar] [CrossRef] [PubMed]
  170. Aseel, D.G.; Rashad, Y.; Hammad, S.M. Arbuscular Mycorrhizal Fungi Trigger Transcriptional Expression of Flavonoid and Chlorogenic Acid Biosynthetic Pathways Genes in Tomato against Tomato Mosaic Virus. Sci. Rep. 2019, 9, 9692. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  171. Jia, T.; Wang, J.; Chang, W.; Fan, X.; Sui, X.; Song, F. Proteomics Analysis of E. angustifolia Seedlings Inoculated with Arbuscular Mycorrhizal Fungi under Salt Stress. Int. J. Mol. Sci. 2019, 20, 788. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  172. Miller, R.E.; Gleadow, R.; Cavagnaro, T.R. Age versus stage: Does ontogeny modify the effect of phosphorus and arbuscular mycorrhizas on above- and below-ground defence in forage sorghum? Plant Cell Environ. 2013, 37, 929–942. [Google Scholar] [CrossRef] [PubMed]
  173. Zhang, F.; Zou, Y.-N.; Wu, Q.; Kuča, K. Arbuscular mycorrhizas modulate root polyamine metabolism to enhance drought tolerance of trifoliate orange. Environ. Exp. Bot. 2020, 171, 103926. [Google Scholar] [CrossRef]
  174. Ghanbarzadeh, Z.; Mohsenzadeh, S.; Rowshan, V.; Moradshahi, A. Evaluation of the growth, essential oil composition and antioxidant activity of Dracocephalum moldavica under water deficit stress and symbiosis with Claroideoglomus etunicatum and Micrococcus yunnanensis. Sci. Hortic. 2019, 256, 108652. [Google Scholar] [CrossRef]
  175. Garcia-Garrido, J.M.; Ocampo, J.A. Regulation of the plant defence response in arbuscular mycorrhizal symbiosis. J. Exp. Bot. 2002, 53, 1377–1386. [Google Scholar] [CrossRef]
  176. Fernández, I.; Merlos, M.; López-Ráez, J.A.; Martínez-Medina, A.; Ferrol, N.; Azcón-Aguilar, C.; Bonfante, P.; Flors, V.; Pozo, M.J. Defense Related Phytohormones Regulation in Arbuscular Mycorrhizal Symbioses Depends on the Partner Genotypes. J. Chem. Ecol. 2014, 40, 791–803. [Google Scholar] [CrossRef]
  177. Medina, M.H. Root colonization by arbuscular mycorrhizal fungi is affected by the salicylic acid content of the plant. Plant Sci. 2003, 164, 993–998. [Google Scholar] [CrossRef]
  178. Pozo, M.J.; López-Ráez, J.A.; Azcón-Aguilar, C.; García-Garrido, J.M. Phytohormones as integrators of environmental signals in the regulation of mycorrhizal symbioses. New Phytol. 2015, 205, 1431–1436. [Google Scholar] [CrossRef] [PubMed]
  179. Johnson, C.H.; Gonzalez, F.J. Challenges and opportunities of metabolomics. J. Cell. Physiol. 2012, 227, 2975–2981. [Google Scholar] [CrossRef] [PubMed]
  180. Pan, Z.; Raftery, D. Comparing and combining NMR spectroscopy and mass spectrometry in metabolomics. Anal. Bioanal. Chem. 2006, 387, 525–527. [Google Scholar] [CrossRef] [PubMed]
  181. Lankadurai, B.P.; Nagato, E.G.; Simpson, A. Environmental metabolomics: An emerging approach to study organism responses to environmental stressors. Environ. Rev. 2013, 21, 180–205. [Google Scholar] [CrossRef]
  182. Allwood, J.W.; Goodacre, R. An introduction to liquid chromatography-mass spectrometry instrumentation applied in plant metabolomic analyses. Phytochem. Anal. 2010, 21, 33–47. [Google Scholar] [CrossRef]
  183. Hagel, J.M.; Facchini, P.J. Plant metabolomics: Analytical platforms and integration with functional genomics. Phytochem. Rev. 2007, 7, 479–497. [Google Scholar] [CrossRef]
  184. Dunn, W.B.; Erban, A.; Weber, R.J.M.; Creek, D.J.; Brown, M.; Breitling, R.; Hankemeier, T.; Goodacre, R.; Neumann, S.; Kopka, J.; et al. Mass appeal: Metabolite identification in mass spectrometry-focused untargeted metabolomics. Metabolomics 2012, 9, 44–66. [Google Scholar] [CrossRef] [Green Version]
  185. Miozzi, L.; Vaira, A.M.; Catoni, M.; Fiorilli, V.; Accotto, G.P.; Lanfranco, L. Arbuscular mycorrhizal symbiosis: Plant friend or foe in the fight against viruses? Front. Microbiol. 2019, 10, 1238. [Google Scholar] [CrossRef]
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Figure 1. Schematic representation of the potential pathways through which arbuscular mycorrhizal fungi (AMF) reprograms the plant metabolome. Plant–AMF symbiosis reprograms the primary and secondary metabolites in plants. Reprogramming of secondary metabolites autoregulates the AMF colonization in the plant by modulating the production of signaling compounds. Interaction of plants with AMF primes plant defense via changes in the secondary metabolic pathways, which increase plant tolerance to biotic and abiotic stresses. Key: LCOs—lipochitooligosaccharides; SPs—secreted proteins; SA—salicylic acid, JA—jasmonic acid.
Figure 1. Schematic representation of the potential pathways through which arbuscular mycorrhizal fungi (AMF) reprograms the plant metabolome. Plant–AMF symbiosis reprograms the primary and secondary metabolites in plants. Reprogramming of secondary metabolites autoregulates the AMF colonization in the plant by modulating the production of signaling compounds. Interaction of plants with AMF primes plant defense via changes in the secondary metabolic pathways, which increase plant tolerance to biotic and abiotic stresses. Key: LCOs—lipochitooligosaccharides; SPs—secreted proteins; SA—salicylic acid, JA—jasmonic acid.
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Figure 2. Different mass analyzers with their resolution and type of metabolomics analysis. Quad—quadrupole; TOF—time of flight; Q-TOF—quadrupole-time of flight, FTICR–MS—Fourier transform ion cyclotron resonance mass spectrometry.
Figure 2. Different mass analyzers with their resolution and type of metabolomics analysis. Quad—quadrupole; TOF—time of flight; Q-TOF—quadrupole-time of flight, FTICR–MS—Fourier transform ion cyclotron resonance mass spectrometry.
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Table
Table 2. Summary of secondary metabolites modulated by AMF.
Table 2. Summary of secondary metabolites modulated by AMF.
Secondary MetabolitesPlant PartsAMF SpeciesPlant SpeciesEnvironmental ConditionIncrease/DecreaseReference
Carotenoid pathway
BlumenolsRootsRhizophagus irregularisSenecio jacobea (Ragwort plant)-Increase[118]
BlumenolsShootRhizophagus irregularisNicotiana attenuate-Increase[59]
CarotenoidsLeavesGlomus intraradices and G. mossaeLettuce-Increase[120]
Cyclohexenone conjugatesRootsGlomus intraradicesHordeum vulgare-Increase[121]
Cyclohexenone derivatives with blumeninRootsGlomus intraradicesHordeum vulgare and Triticum aestivum-Increase[122]
Cyclohexenone derivatives RootsGlomus intraradices, Glomus mossae and Gigaspora roseaHordeum vulgare, Triticum aestivum and Zea mays-Increase[123]
RootsGlomus intraradicesTobacco and Tomato plants-Increase[87]
RootsGlomus intraradicesAllium porrum-Increase[124]
RootsGlomus intraradicesMedicago truncatula-Increase[70]
Mono-, di-, and branched triglycosides of blumenolRootsGlomus intraradicesOrnithogalum umbellatum-Increase[125]
MycorradicinRootsGlomus intraradicesOrnithogalum umbellatum-Increase[125]
Sesquiterpenoid cyclohexenone derivativesRootsGlomus intraradices61 members of poaceae-Increase[126]
Phenylpropanoid pathway
Bound phenolicsRootsGlomus intraradicesMedicago truncatula-No change[70]
CaffeoylshikimateLeavesRhizophagus irregularisSalix purpurea-Increase[89]
Coniferyl alcoholRootsRhizophagus irregularis+ Funneliformis mossaeSolanum lycopersicum-Increase[64]
CoumarateLeavesRhizophagus irregularisSalix purpurea-Increase[89]
Coumaryl acetateLeavesRhizophagus irregularisSalix purpurea-Increase[89]
Coumaryl alcoholRootsRhizophagus irregularis+ Funneliformis mossaeSolanum lycopersicum-Increase[64]
Daidzein (Isoflavonoid)RootsGlomus intraradicesMedicago truncatula-Increase[70]
EpicatechinLeavesRhizophagus irregularisSalix purpurea-Decrease[89]
Ferulic acidRootsRhizophagus irregularis+ Funneliformis mossaeSolanum lycopersicum-Increase[64]
FlavonoidsLeavesFunneliformis mossaeCucumis sativa (Cucumber)Chilling stressIncrease[119]
FlavonoidsLeavesGigaspora albida+ Acaulospora longulaAnadenanthera colubrinaIncreasing P concentrationIncrease[69]
HydroxycinnamatesShootsRhizophagus irregularisCichorium intybusMetal toxicityIncreases without stress, no difference under stress[127]
Hydroxycinnamic acid amidesRootsGlomus intraradicesHordeum vulgare-Increase[128]
Hydroxycinnamic acid amidesRootsGlomus intraradicesHordeum vulgare and Triticum aestivum-Increase[122]
Lignans:
Secoisolariciresinol
Yatein		RootRhizophagus irregularis(Ri), Funneliformis mossae(Fm) and Claroideoglomu etunicatum(Ce)Solanum lycopersicumSalt stressIncrease[86]
LigninLeavesFunneliformis mossaeCucumis sativa (Cucumber)Chilling stressIncrease[119]
Luteolin-7-O-glucosideLeavesRhizophagus irregularisSalix purpurea-Increase[89]
Malonylononin (Isoflavonoid)RootsGlomus intraradicesMedicago truncatula-Increase[70]
MonolignansRootsRhizophagus irregularis+ Funneliformis mossaeSolanum lycopersicum-Increase[64]
Ononin (Isoflavonoid)RootsGlomus intraradicesMedicago truncatula-Increase[70]
Phenolic acidsRoots+ shootsGlomus mossaeGroundnut-Increase[128]
Phenolic compounds:
Cinnamic acid
p-coumaric acid
caffeic acid
ferulic acid		LeavesFunneliformis mossaeCucumis sativa (Cucumber)Chilling stressIncrease[119]
PhenolsLeavesGigaspora albida+ Acaulospora longulaAnadenanthera colubrinaIncreasing P concentrationIncrease[69]
PinostrobinLeavesRhizophagus irregularisSalix purpurea-Increase[89]
Quercetin (flavonoid)Stems and leavesMixture of Glomus fasciculatum, G. mossae, and G. intraradicesVitis vinifera-Increase[129]
RutinLeavesRhizophagus irregularisSalix purpurea-Increase[89]
Scopoletin and its glucoside scopolinRootsGlomus intraradicesTobacco and Tomato plants-Decrease[87]
ScopolinLeavesRhizophagus irregularisSalix purpurea-Decrease[89]
TanninsLeavesGigaspora albida+ Acaulospora longulaAnadenanthera colubrinaIncreasing P concentrationIncrease[69]
Alkaloids
Benzylisoquinoline alkaloidsRootsRhizophagus irregularis+ Funneliformis mossaeSolanum lycopersicum-Increase[64]
Pyrrolizidine alkaloidsRootsRhizophagus irregularisSenecio jacobea (Ragwort plant)-Increase[118]
Trigonelline (pyridine alkaloid)RootsGigaspora roseaProsopis laevigata-Increase[130]
Phytoalexins
RishitinRootsGlomus etunicatumPotato plantletsRhizoctonia solani pathogenIncrease[131]
SolavetivoneRootsGlomus etunicatumPotato plantletsRhizoctonia solani pathogenIncrease[131]
Antioxidants
Bioactive compounds:
Picrocrocin
Crocin II
Quercitrin		saffronRhizophagus intraradicesCrocus sativus (saffron)-Increase[132]
Caffeic acidsShootGlomus caledonium and Glomus mossaeSweet basil-Increase[133]
Caffeic acidsShootGlomus intraradicesSweet basil-Same as non-mycorrhizal[133]
Rosmarinic acidShootGlomus caledonium and Glomus mossaeSweet basil-Increase[133]
Rosmarinic acidShootGlomus intraradicesSweet basil-Same as non-mycorrhizal[133]
Plant defense and hormones
Abscisic acidLeafRhizophagus irregularisMedicago truncatula-Increase[134]
CatalpolLeafRhizophagus irregularis** Monocot and dicots-Increased in Plantago lanceolate, slightly decreased in Veronica chamaedrys[76]
GlucosinolatesRootFunneliformis mossaeTriticum aestivum and Triticum durumWater stressMostly decreased[92]
Jasmonic acid
Methyl jasmonate		RootRhizophagus irregularis(Ri), Funneliformis mossae(Fm) and Claroideoglomu etunicatum(Ce)Solanum lycopersicumSalt stressIncrease[86]
** Monocot and dicots: Plantago lanceolata, Plantago major, Veronica chamaedrys, Medicago truncatula (Dicots) and Poa annua (Monocot).

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Kaur, S.; Suseela, V. Unraveling Arbuscular Mycorrhiza-Induced Changes in Plant Primary and Secondary Metabolome. Metabolites 2020, 10, 335. https://doi.org/10.3390/metabo10080335

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Kaur S, Suseela V. Unraveling Arbuscular Mycorrhiza-Induced Changes in Plant Primary and Secondary Metabolome. Metabolites. 2020; 10(8):335. https://doi.org/10.3390/metabo10080335

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Kaur, Sukhmanpreet, and Vidya Suseela. 2020. "Unraveling Arbuscular Mycorrhiza-Induced Changes in Plant Primary and Secondary Metabolome" Metabolites 10, no. 8: 335. https://doi.org/10.3390/metabo10080335

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