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Review

Significance of Arbuscular Mycorrhizal Fungi in Mitigating Abiotic Environmental Stress in Medicinal and Aromatic Plants: A Review

by
Abir Israel
,
Julien Langrand
,
Joël Fontaine
and
Anissa Lounès-Hadj Sahraoui
*
Unité de Chimie Environnementale et Interactions sur le Vivant (UCEIV-UR 4492), Université Littoral Côte d’Opale, SFR Condorcet FR CNRS 3417, CS 80699, F-62228 Calais, France
*
Author to whom correspondence should be addressed.
Foods 2022, 11(17), 2591; https://doi.org/10.3390/foods11172591
Submission received: 25 May 2022 / Revised: 22 July 2022 / Accepted: 24 August 2022 / Published: 26 August 2022
(This article belongs to the Section Plant Foods)
Browse Figure
Review Reports Versions Notes

Abstract

:
Medicinal and aromatic plants (MAPs) have been used worldwide for thousands of years and play a critical role in traditional medicines, cosmetics, and food industries. In recent years, the cultivation of MAPs has become of great interest worldwide due to the increased demand for natural products, in particular essential oils (EOs). Climate change has exacerbated the effects of abiotic stresses on the growth, productivity, and quality of MAPs. Hence, there is a need for eco-friendly agricultural strategies to enhance plant growth and productivity. Among the adaptive strategies used by MAPs to cope with the adverse effects of abiotic stresses including water stress, salinity, pollution, etc., their association with beneficial microorganisms such as arbuscular mycorrhizal fungi (AMF) can improve MAPs’ tolerance to these stresses. The current review (1) summarizes the effect of major abiotic stresses on MAPs’ growth and yield, and the composition of EOs distilled from MAP species; (2) reports the mechanisms through which AMF root colonization can trigger the response of MAPs to abiotic stresses at morphological, physiological, and molecular levels; (3) discusses the contribution and synergistic effects of AMF and other amendments (e.g., plant growth-promoting bacteria, organic or inorganic amendments) on MAPs’ growth and yield, and the composition of distilled EOs in stressed environments. In conclusion, several perspectives are suggested to promote future investigations.

1. Introduction

Medicinal and aromatic plants (MAPs) are a diverse group of plant species that have received a great deal of interest due to their herbal medicine, pharmaceutical, cosmetic, and nutritional applications [1,2,3]. While medicinal plants include herbs used for therapeutic or pharmacological purposes, aromatic plants are rich in aromatic compounds and provide products that are widely used as spices or flavoring agents, and in cosmetics, or medicine [4,5]. These plant species are mainly cultivated for their various parts (roots, stems, leaves, flowers, seeds, buds, rhizomes, wood, bark, etc.) containing a wide range of secondary metabolites, including essential oils (EOs), which exert antimicrobial, antioxidant, and anti-inflammatory effects [6,7,8]. The cultivation of MAPs is looked upon not only as a source of effective health care products but also of income and livelihood security [9]. The World Health Organization estimates that 80% of the world’s population depends on medicinal herbs for primary healthcare and wellness [10,11]. The use of MAPs has increased widely over the past three decades, and partly because of their low side effects, their demand has expanded not only in local but also international markets [12,13,14].
With increasing global warming, the intensity of droughts and heatwaves will increase, as along with other abiotic stress conditions such as salinity and flooding [15,16]. These various environmental stresses can severely affect the growth, development, and productivity of MAPs [17]. Indeed, MAPs are not tolerant of the impacts of climate change [18]. It has been reported that various abiotic stresses influence the yields and the chemical composition of EOs and lead to variations in their quality [19,20,21]. The chemotype of EOs extracted from cumin (Cuminum cyminum L.) seeds changed under water stress, resulting in a change in the EO’s odor [22]. Furthermore, a reduction was observed in the relative concentration of 1,3,8-p-menthatriene in the EO extracted from plain-leaved parsley, Petroselinum crispum, exposed to water stress [20]. This decrease could be detrimental to oil quality.
Due to the significance of MAPs for humans and the detrimental impacts of abiotic stress on MAP’s growth and productivity, to improve plant growth and productivity there is a need to identify adequate approaches to enhance plant tolerance to abiotic stress. Amongst eco-friendly agricultural practices, the addition of microbial and/or organic or inorganic amendments could be sustainable mitigation strategies to fight against the detrimental effects of abiotic stress [23,24,25,26,27,28].
Plants rely greatly on root-associated microorganisms, particularly bacteria and fungi, to improve plant performance under abiotic stress [29,30]. Arbuscular mycorrhizal fungi (AMF) of the phylum Glomeromycota are known to establish a symbiotic relationship with the roots of over 80% of terrestrial plant species [31], including MAPs [32,33,34]. Such symbiosis helps plants to obtain from the soil more water, and mineral nutrients including phosphorus, nitrogen, and oligo-elements. In return, the AMF takes photo-assimilates (i.e., carbohydrates) from the host plant [31,35,36]. It has been established through many studies that the inoculation of MAPs by AMF renders them more tolerant to abiotic stress conditions including water stress, salinity, and pollution [32,33,37,38], through the involvement of several mechanisms at morphological, physiological, and molecular levels [38,39,40,41,42,43,44,45].
The synergistic effect of microbial (i.e., AMF, plant growth-promoting bacteria (PGPR)) and organic or inorganic (i.e., compost, biochar, manures, NPK, silicate, and clay) soil amendments is beneficial for plant tolerance, by enhancing physicochemical properties and total organic matter content, as well as by increasing nutrient availability and the water-holding capacity of the soil [46,47,48]. Under abiotic stress such as water stress, salinity, or pollution, with the presence of microbial or organic or inorganic soil amendments, the improvement of plant growth and secondary metabolite production has been reported for various MAPs such as pennyroyal (Mentha pulegium), sage (Salvia officinalis), sweet basil (Ocimum basilicum), rosemary (Rosmarinus officinalis), and cumin (Cuminum cyminum) [49,50,51,52]
The present review aims first to analyze the data of several studies reporting the impacts of various abiotic stresses (water stress, salt stress, low and high temperatures, light, and pollution) on MAPs’ growth, and on the yield and composition of distilled EOs. Secondly, it deciphers the AMF-mediated mechanisms to improve MAPs’ tolerance at morphological, physiological, and molecular levels. Finally, the role of PGPR with organic and inorganic amendments in alleviating abiotic stress is discussed. In conclusion, several perspectives to promote future investigations are suggested.

2. Impact of Abiotic Stresses on MAPs

2.1. Water Stress

Water stress is among the most important abiotic factors that severely affect MAPs’ growth, and it can adversely affect yield and EO composition [20]. Various studies have established that water stress causes a reduction in the vegetative growth of MAPs (Table 1). For instance, in lavender species such as Lavandula angustifolia [19] and Lavandula stoechas [53], water stress reduced plant height, leaf area, and number of leaves per plant. In addition, Alishah et al. [54] showed that water stress decreased the plant height, stem diameter, number, and area of leaves for sweet basil (Ocimum basilicum). The restriction in shoot growth was most likely due to carbohydrate reallocation in favor of root growth, or to a decrease in photosynthesis efficiency [55]. The water stress effect can be extended to the reproductive stage by decreasing seed yield.
Numerous studies have reported that water stress has a negative effect on the number of umbels and umbellets during the reproductive stage in various Apiaceae species, such as cumin (Cuminum cyminum L.) [22], sesame (Sesamum indicum L.) [64], caraway (Carum carvi L.) [56], and coriander (Coriandrum sativum) [57]. Concomitant with this, reductions in seed yield were observed.
Several studies have shown that water stress modifies EOs yield and composition by increasing or decreasing constituent levels depending on plant species and stress duration. Water stress has been found to have a positive effect on the yield of EOs distilled from MAPs including Iranian native savory (Satureja hortensis) [63], Mexican oregano (Lippia berlandieri Schauer) [65], basil (Ocimum sp.), and caraway (Carum carvi L.) [56] (Table 1). It has been reported that the EOs of Greek sage (Salvia fruticose) doubled under moderate water stress and increased by 83% under severe water stress, compared with normal conditions [19]. In another sage species, Salvia officinalis, Bettaieb et al. [62] reported an increase in EO yield when plants were cultivated under water stress. The effects of water deficit on the EOs of three parsley (Petroselinum crispum) cultivars, designated as plain-leafed, curly-leafed, and turnip-rooted, were studied by Petropoulos et al. [20]. They showed an enhancement in the EO yield for plain-leafed and curly-leafed parsley but not for turnip-rooted parsley. There is evidence that the presence of a high density of oil glands due to limited leaf area might explain such a rise in EO content [66]. Conversely, a decrease in EO yield was reported in a number of MAPs, including rosemary (Rosmarinus officinalis L.) [53,60], anise (Pimpinella anisum L.) [21], lavender (Lavandula latifolia) [19], and clary sage (Salvia sclarea) [61].
From the aforementioned studies, it is clear that water stress also influences the EO composition. Water stress was found to induce changes in the composition of EOs distilled from cumin (Cuminum cyminum L.) [22]. Furthermore, water stress modified the chemotype of the EO from γ-terpinene/phenyl-1,2 ethanediol in control seeds to γ-terpinene/cuminaldehyde in stressed seeds, possibly changing the EO’s odor [22]. However, the EO chemotype of caraway (Carum carvi L.) did not change under water stress, but the content of limonene and carvone increased in the oil extracted from caraway seeds [56]. Water stress decreased certain compositions within the EO extracted from plain-leafed parsley, particularly 1,3,8-p-menthatriene [20]. As a result, this decrease could be detrimental to oil quality [67], although an increase in myristicin, which is another essential aromatic constituent, was observed [20]. Under water stress, a decrease in total monoterpenes and an increase in oxygenated monoterpenes were observed in lavender (Lavandula angustifolia) and Greek sage (Salvia fruticose) [19]. This variation in EO yield and composition might be due to enzyme activity and metabolism enhancements [22,68,69].

2.2. Salt Stress

Salt stress, generally resulting from poor quality irrigated water, is considered a major environmental factor limiting plant growth and productivity [70]. There are several common features between salt and water stress, as in both cases, the primary effect is a lower water potential in the soil around the roots [71].
Many researchers have studied the effect of soil and water salinity on the growth of MAPs, as well as on the yields and composition of their distilled EOs. A decrease in shoot and root dry weight, as well as seed yield in response to salinity, was reported in sweet fennel (Foeniculum vulgare) [72] and ajwain (Trachyspermum ammi L.) [73]. Many other plant growth parameters including plant height, root length, number of leaves per plant, branches per plant, and flowers per plant decreased in a number of MAPs under salt stress (Table 2).
From a wide array of experiments, it has been demonstrated that EO yield and composition can vary with plant species, cultivation conditions, and salt concentrations in the soil. An increase in EO yield was observed for English marigold (Calendula officinalis) [78], thyme (Thymus vulgaris) [88], and sweet basil (Ocimum basilicum L.) [90]. The increase in EO yield was attributed to a higher oil gland density [66]. In contrast, other studies have revealed that high salinization of soil and water had a negative effect on oil yield for several MAPs including sage (Saliva officinalis) [84], chamomile (Matricaria chamomile) [77], mint (Mentha sp.) [80], and marjoram (Origanum majorana) [82] (Table 2). In sage (Saliva officinalis) leaves and fruits, the EO yield increased under moderate salt stress (50 and 75 mM), but when the NaCl concentration was increased to 100 mM, the oil yield decreased [83,84]. The application of salt stress induced marked changes in the major EO compounds of sage (Saliva officinalis) fruits [84], in particular viridiflorol, which acts as an antifungal potential, and manool, which is a precursor for aromatic products and has an ambergris odor [91]. In control plants and at a low concentration of NaCl (25 mM), viridiflool was the main compound in EOs, whereas at a high salt concentration (100 mM) manool was the dominating compound. These variations might be due to the induction of enzyme activities involved in the biosynthesis of the latter compounds [84]. In coriander (Coriandrum sativum L.) leaves, the EO yield was increased at 25 and 50 mM NaCl concentrations while it decreased at a high NaCl concentration (75 mM) [74]. On the other hand, in coriander fruits and roots, the EO yield increased with increasing NaCl concentration (0, 25, and 50 mM) [75,76]. The compositions of EOs from coriander leaves and roots were affected differently by salt treatment. Coriander fruit contains linalool and camphor as major constituents, and their amounts increased along with the NaCl concentrations.

2.3. Low and High Temperatures

Temperature is one of the most important abiotic factors limiting plant growth and productivity [92]. Heat stress (high temperature) and cold stress (low temperature) can cause a series of changes at physiological, biochemical, and molecular levels [93]. Heat stress induces leaf senescence, cell membrane damage, degradation of chlorophyll content, and denaturation of various proteins [94]. Several studies are available on the effect of temperature stress on MAPs’ growth [95,96] as well as on EOs’ quantity and quality [97,98]. The effect of high temperature on sweet basil (Ocimum basilicum) was studied by Al-Huqail et al. [95]. The authors observed inhibition in plant growth under all high temperature treatments (35, 45, and 55 °C) compared with the control treatment (25 °C), which might be due to the effects of high temperature on plant metabolism [95]. Similarly, plant growth parameters (flower yield and plant height) for chamomile (Matricaria chamomilla) decreased at high temperatures (15, 20, and 25 °C) while these parameters increased at a low temperature (12 °C) [97]. In contrast, the fresh and dry weight of fennel (Foeniculum vulgare) were reduced under cold stress (2 °C) [96]. Another study has shown that increased temperature can cause early onset of senescence in American ginseng (Panax quinquefolius) and, subsequently, decreased photosynthetic rate. Furthermore, a decline in total biomass was observed [99]. The decrease in plant growth parameters might be because stomata become closed or partially closed under temperature stress, which causes a reduction in the CO2 availability, and consequently the efficiency of photosynthesis decreases [97,100]. In addition, the reduction in leaf area and stomatal conductance affects the plant’s capacity to intercept light and capture CO2 and, consequently, its ability to produce biomass [97,101].
Temperature stress can also affect the production of secondary metabolites including EOs [93,97]. For example, at low temperatures the EO yield of chamomile (Matricaria chamomilla) increased, while it decreased at a high temperature [97]. In another study, the EO yield of chamomile (Matricaria chamomilla) increased at 10 and 20 °C and decreased under cold stress (5 °C) [102]. Some studies also showed that EO composition can be affected by low temperature. For example, Nguyen et al. [98] indicated an increase in some compounds such as eugenol, methyl eugenol, and β-caryophyllen in the EO of holy basil (Ocimum tenuiflorum), cultivated at low temperatures. Similarly, Rastogi et al. [103] reported that eugenol and methyl eugenol content in holy basil (Ocimum tenuiflorum) EOs decreased under cold stress.

2.4. Light

As well as being the primary source of energy for photosynthesis, light also acts as a signal and can regulate plant development [104,105]. Different parameters such as light quality (wavelengths), quantity (fluence rate), and duration strongly influence plant growth and development, as well as plant productivity [106,107,108]. Although light provides energy for photosynthesis and regulates plant development, it may also function as a stress factor [108]. Many experiments have been conducted to assess how light quality, quantity, and duration affect the growth and EO yield of MAPs. For instance, the fresh weight of mint (Mentha spp.) was highest under combined red and blue LED light (70/30%) compared to normal growing conditions [109]. Likewise, the combination of red and blue LED light increased the fresh and dry weights of the shoots and the leaf numbers of lemon balm (Melissa officinalis) compared with red light alone, blue light alone, or white light [110]. Another study showed that the leaf and shoot numbers of coriander (Coriandrum sativum), as well as its fresh and dry mass, increased under different ratios of red: blue compared with red light alone [111]. In contrast, the total fresh lateral-shoot weight of sweet basil (Ocimum basilicum) was highest under blue light compared with other lights (red, green, blue-green, or white light) [112]. The combination of blue and white light increased the leaf area of peppermint (Mentha piperia) [113]. These studies demonstrate that combined red and blue light is more effective than monochromatic red light for plant growth, and their conclusions explain that the red light wavelength (650–665 nm) matches the absorption peak of chlorophyll a/b found in the chloroplast [114], while blue light has a complementary effect [115]. Furthermore, blue light has been shown to affect the opening of stomata [116], allowing more CO2 entrance for photosynthesis, which is reflected by an increase in dry matter [117]. The effect of increasing light intensity (approximately 4, 7, 11, or 20 mol m−2 d−1) on the growth of African basil (Ocimum gratissimum) was conducted by Fernandes et al. [118]. Results from that experiment indicated that the number of leaves, leaf area, and plant height increased up to 10 mol m−2 d−1, but decreased after this value. In the presence of green LED light, the fresh weight and leaf area of sweet basil (Ocimum basilicum L.) were higher than under other tested lights [112].
Ultraviolet (UV) light is stressful for plants, causing dwarfing and loss in photosynthesis, but appropriately using UV light can increase plant yield in some species [119]. Supplementary UV-B light for two hours each day for seven days had a greater effect on plant height, leaf area, fresh weight, and dry weight of sweet basil than one hour supplemental UV-B light [120]. In peppermint (Mentha piperita), combining white and UV-A or UV-B light increased the leaf area and leaf area index. In contrast, Johnson et al. [121] reported that the leaf area of sweet basil (Ocimum basilicum) was reduced by UV-B light. Another study reported that the combination of UV-B and white light affected neither the number of leaves nor the leaf area of Japanese mint (Menthe arvensis) [122].
It has been established that red, blue, and UV light can improve EO yield in various MAPs compared to white light. For instance, the effect of various LED lights (red, blue, red + blue (70% + 30%), or white) on some species of mint (Mentha piperita, Mentha spicata, and Mentha longifolia) was investigated by Sabzalian et al. [109]. The results showed that the EO content of all mint species was higher under red or combined red and blue light than under white light. In sweet basil (Ocimum basilicum L.), the EO content under blue light was 1.2–4.4 times higher than in plants cultivated under white light, and was lowest under red light, in experiments conducted at 50 μmol. m−2·s−1 PPFD for 70 days [112]. Changes in the EO composition of basil depended on light treatments. The second and third major compounds, respectively, were myrcene and linalool under blue light, and α-pinene and β-pinene under green and red light; under white light, these produced an intermediate response [112]. Even though UV light has a generally negative effect on plant growth, it might improve EO yield in some MAPs. For instance, Karousou et al. [123] studied the effect of supplementary UV-B radiation on the EO yield of two distinct chemotypes of spearmint (Mentha spicata) growing under field conditions. A significant increase in EO production was observed in chemotype II, while in chemotype I, the increase was insignificant. An increase in EO yield in Japanese mint (Mentha arvensis) was observed under UV-B or combined UV-A and UV-B light with white light [122]. Under the same conditions, increases in l-menthol and limonene concentrations were observed. Similarly, the combination of UV-A or UV-B with white light increased the EO yield in peppermint (Mentha piperita) [113,124]. There is limited information on the enhancement of EOs in MAPs under light [109]. However, the accumulation of EOs in MAPs may be due to the effects of light on the metabolic pathways of MAPs leading to an increase in EO yield [109,112]. Therefore, further investigations are needed to study the mechanisms that affect EO accumulation in MAPs under light, including UV light.

2.5. Pollution

Soil pollution is becoming a major environmental problem, due to rapid urbanization and industrialization [125]. Trace elements (TEs) are the major pollutants found in polluted soils. Soil pollution by TEs may occur naturally (i.e., erosion, geochemical background, volcanic eruption, etc.), but it mainly originates from anthropogenic activities (i.e., industrial and agricultural activities, traffic, mining, etc.) [126]. The most commonly found TEs in contaminated soil include arsenic (As), chromium (Cr), cadmium (Cd), lead (Pb), copper (Cu), zinc (Zn), nickel (Ni), and mercury (Hg) [127]. TEs cause significant risks to human health and the environment due to their non-biodegradability, bioaccumulation, and extreme toxicity [128,129]. Concerns have been raised about the accumulation of TEs in the soil, and their ability to penetrate and become incorporated into plants. These accumulated TEs adversely affect plant growth and productivity, as well as possibly contaminating the human food chain [129]. TEs can adversely affect MAPs’ development [130,131,132] as well as the quantity and composition of their secondary metabolites such as EOs [130,133].
Several studies have indicated that the response of MAPs to TEs is highly variable. This is probably due to the different experimental conditions (plant species, concentration, duration of treatment, composition of growth medium, culture conditions, etc.). The effect of TEs on plant growth has been observed in various Lamiaceae species. For instance, the uptake of As by the Ocimum spp. (Ocimum tenuiflorum, O. basilicum, and O. gratissimum) significantly decreased plant growth (plant height and dry weight) [134]. However, Cd, Pb, and Cu did not affect the growth of sweet basil (Ocimum. basilicum) [135]. Moreover, another study has shown that Cd, Pb, and Zn reduced root and shoot dry biomass by 15 and 10%, respectively, in garden sage (Salvia officinalis) [130]. Likewise, Raveau et al. [136] showed that the plant height and dry weight of clary sage (Salvia officinalis) were decreased by polluted soil (Pb, Zn, and Cd) compared with unpolluted soil. Similarly, a decrease in the dry biomass of shoot and root in chamomile (Matricaria recutita) was observed when grown in soil contaminated with Cd and Pb [137]. Despite being members of the same genus, menthol mint (Mentha arvensis), peppermint (M. piperita), and bergamot mint (M. citrata) responded differently to soil contaminated by Cr and Pb. M. arvensis’s shoot and root yields were not significantly affected by the application of Cr and Pb in the growth medium, whereas the shoot and root yields of M. citrata decreased, and those of M. piperita increased [131]. In addition, Sá et al. [138] reported that the application of Pb in soil did not affect the growth of garden mint (Mentha crispa). Another study reported that the application of Ni up to 30 ppm increased the shoot yield of Tagetes minuta. However, a further increase in the level of Ni decreased the shoot yield of that species [132]. Plant height and the number of branches per plant increased at low concentrations of Ni, while these parameters decreased with increasing Ni concentrations [132].
It has been hypothesized that the reduction in plant growth on TE-polluted soils is due to poor nutrient uptake because TEs compete with other plant nutrients [139]. Arsenate (AsV) accumulates in plants via the phosphate transporter (PHT) as an analog of phosphate (Pi), resulting in an inhibition of phosphorus (P) uptake [140,141,142]. Cd can reduce the uptake and translocation of essential nutrients including calcium (Ca), Cu, iron (Fe), Zn, and manganese (Mn) [143]. Cd is a divalent cation and may compete with plant nutrients for the same transporters [144]. Cd uptake by plants is mediated through cation transport systems, which are generally involved in the uptake of essential nutrients such as zinc–iron permease (ZIP) (ZRT–IRT-like proteins), natural resistant associated macrophage protein (NRAMP) transporters, or Ca channels and transporters [145]. In leaves, Cd penetrates via the Ca channel, disrupting the plant–water relationship [145], causing stomatal closure and leading to inhibition of photosynthetic activity, which subsequently reduces plant growth [143]. Furthermore, excessive Pb concentrations in soil inhibit plants’ uptake of minerals including Ca, Fe, Mg, Mn, P, and Zn, resulting in reduced plant growth [146].
The effects of TEs on the EO yields of many MAPs have been studied, including basil spp. (Ocimum spp.), mint spp. (Mentha spp.), lemon balm (Melissa officinalis), and sage (Salvia officinalis) [131,136,147,148]. Previous studies carried out on Ocimum species reported an increase in EO yield with the application of As [134,149]. Similarly, an increase in EO yield following Cd and Pb treatments was observed in sweet basil (Ocimum basilicum L.) [148]. Furthermore, differences in EO yield appeared between plant species within the same genus. The application of Cr and Pb in the medium growth, for example, decreased EO yields in menthol mint (Mentha. arvensis) and bergamot mint (M. citrata) while increasing the EO yield in peppermint (M. piperita) [131]. In contrast, the EO yield of M. arvensis was not affected by the application of Pb and Cd in soil [150], while in another mint species, garden mint (Mentha crispa), the EO yield increased when the concentration of Pb increased [138]. Moreover, the application of Pb in the soil decreased the EO yield of lemon balm (Melissa officinalis) [147]. In contrast, an increase in the EO yield of sage (Salvia officinalis) was observed in the presence of Cd, Pb, and Zn [130,136]. Differences in EOs’ chemical compositions were also observed. For example, menthol content in M. arvensis and M. piperita was not affected in response to Cr and Pb treatments, but minor constituents such as α-pinene and β-pinene were reduced in M. arvensis [131]. The reason for the changes in the EO yield of plants after the application of TEs is not known, but it might be attributable to the effect of TEs on enzymatic activity and carbon metabolism [68].
Phytoremediation is a green approach that relies on plants, including MAPs, to clean pollutants from contaminated soil [133]. It has been demonstrated through many studies that MAPs can be used in the phytoremediation of TE-polluted soils. For instance, vetiver (Vetiveria zizanioides) and rose (Pelargonium roseum) can act as phytoextractants for Pb. A study conducted by Chen et al. [151] showed that the formation of Pb-EDTA complexes (i.e., a chelating agent) in vetiver increased the accumulation of Pb in the roots and its translocation from roots to shoots. In addition, rose geranium (Pelargonium roseum) possesses a hyperaccumulator phenotype due to the accumulation of a high concentration of Pb in shoots relative to roots (8644 and 5550 mg Pb kg−1 DW, respectively) [152]. Other MAPs, including basil (Ocimum spp.), lavender (Lavandula angustifolia L.), sage (Saliva sclarea), and rosemary (Rosmarinus officinalis L.), act as multi-hyperaccumulators or excluders of multiple TEs including Cd, Zn, and Ni [52,153,154,155,156,157]. On the other hand, several MAPs have been shown to act as phytostabilizers for TEs. For example, palmarosa (Cymbopogon martini) can accumulate TEs (Cr, Ni, Pb, and Cd) with less translocation of TEs from roots to its aerial parts [158]. Furthermore, rosemary (Rosmarinus officinalis L.), clary sage (Saliva officinalis), and vetiver (Vetiveria zizanioides) can be useful for the phytostabilization of TEs such as Cu, As, Cd, Zn, and Pb [136,159,160].
In plants, the uptake and translocation of TEs occur through specific transporters such as ZIP (ZRT–IRT-like proteins), cation diffusion facilitators, heavy metal transport ATPases, metal transporter proteins, natural resistant associated macrophage proteins, and ATP-binding cassette transporters, which are localized at the plasma membrane and on the vacuole membrane of cells. These transporters facilitate TE uptake into plants and participate in their sequestration into vacuoles or cell walls [127,161,162]. In fact, plants have an antioxidant defense system which is triggered as a consequence of the increased level of reactive oxygen species (ROS). Glutathione (GSH) shows a high affinity for toxic metals, and plays an important role in metal sequestration and tolerance in plants [163,164,165].

3. Arbuscular Mycorrhizal Fungi Help MAPs to Cope with Abiotic Stress

It is evident from the studies cited above that water stress, salinity, temperature, light, and pollution are among the major abiotic stresses that can affect plant growth and consequently reduce biomass production and EO yield in some MAP species. In addition, abiotic stresses induced changes in the composition of distilled EOs. Since plants cannot move, they have evolved numerous strategies to cope with abiotic stress, among which AMF are known to promote plant growth and to confer better tolerance to abiotic stresses in host plants [31], including MAPs [32,33]. The following sections of the current review focus on the mechanisms used by AMF to alleviate the deleterious effects of abiotic stress in MAPs (Figure 1).

3.1. AMF Improves MAPs Growth and EOs Yield

Many studies have shown that AMF inoculation improves plant growth and biomass in addition to EO yield under abiotic stresses; see Table 3. Under conditions of water stress, Indian coral tree (Erythrina variegate) inoculated with Funneliformis mosseae presented a significant increase in plant growth parameters (shoot and root length, stem diameter, and leaf area) compared to non-inoculated plants [166]. The increase in dry biomass was explained by an improvement in water uptake by AMF extraradical hyphae [166]. Furthermore, sesbania (Sesbania sesban) colonized by different AMF species (F. mosseae, Rhizophagus irregularis, and Claroideoglomus etunicatum) showed an increase in fresh weight and lengths of shoot and root compared to non-inoculated plants [43]. The enhancement of MAPs’ growth by AMF could be attributed to AMF improving nutrient acquisition, especially P nutrition [167].
The accumulation of EOs in MAPs is generally attributed to glandular trichomes, which are specialized external secretory structures that secrete secondary metabolites including EOs [168,169]. Hence, there is a strong correlation between the density of glandular trichomes and EO yield. Interestingly, several studies revealed an enhancement in EO yield in many MAPs colonized with AMF, and these improvements were attributed to increases in the number of glandular trichomes in mycorrhizal plants [170,171,172]. It has been shown that the inoculation of oregano (Origanum vulgare L.) with Glomus viscosum increased the glandular density on the upper leaf epidermis [170]. Furthermore, sweet basil (Ocimum basilicum L.) inoculated with a mixture of AMF species, viz., F. mosseae, Gigaspora margarita, and Gigaspora rosea, showed an increase in EO yield [171]. This increase was associated with an abundance of glandular trichomes on the basal and central leaf zones [171]. Moreover, it has been reported that the inoculation of rose geranium (Pelargonium graveolens) with F. mosseae and R. irregularis increased the EO yield under conditions of water stress [37,173]. Similarly, basil (Ocimum gratissimum L.) plants inoculated with R. irregularis showed an increase in plant height and EO yield when experiencing water stress [44]. Likewise, sweet basil (Ocimum basilicum L.) inoculated with R. irregularis showed an increase in plant biomass and EO yield with a high level of metals in the soil [174]. The AMF can protect plants against TE toxicity by binding the metals in their hyphae, which limits the translocation of TEs from roots to shoots [174,175]. In addition, AMF hyphae produce glomalin, a glycoprotein that plays a role in the immobilization of TEs by generating protein–metal complexes, resulting in a reduction of TE content in the soil [176].
However, in addition to the advantages described above, some studies have reported that AMF can promote the content of active compounds in MAPs. Such benefits may be related to changes in the gene expressions involved in the biosynthesis of these compounds [177]. For example, Lazzara et al. [178] showed that Hypericum perforatum inoculated with a mixture of nine different AMF species increased the concentration of bioactive secondary metabolites such as hypericin and pseudohypericin in flowers, compared with non-inoculated plants under conditions of low P availability [178]. This enhancement could be attributed to the involvement of methyl jasmonate or salicylic acid in the mycorrhizal symbiosis, which can positively affect hypericin content [178,179].
Table
Table 3. Effect of mycorrhizal inoculation on MAPs growth and EOs yield under abiotic stress.
Table 3. Effect of mycorrhizal inoculation on MAPs growth and EOs yield under abiotic stress.
Stress TypePlant SpeciesAMF SpeciesGrowthEO YieldReference
Water stressEphedra foliataClaroideoglomus etunicatum,
Funneliformis mosseae,
Rhizophagus irregularis		+n.d.[33]
Erythrina variegataFunneliformis mosseae+n.d.[166]
Foeniculum vulgareFunneliformis mosseae,
Rhizophagus irregularis		+n.d.[180]
Glycyrrhiza uralensisRhizophagus irregularis+n.d.[40]
Lavandula spicaFunneliformis mosseae,
Rhizophagus intraradices		+n.d.[32]
Matricaria chamomillaFunneliformis mosseae+n.d.[38]
Ocimum gratissimumRhizophagus irregularis++[44]
Pelargonium graveolensFunneliformis mosseae,
Rhizophagus irregularis		++[37,173]
Ricinus communisFunneliformis mosseae,
Rhizophagus intraradices		+n.d.[181]
Tagetes erectaGlomus constrictum+n.d.[182]
SalinityAcacia niloticaGlomus fasciculatum+n.d.[183]
Chrysanthemum morifoliumDiversispora versiformis Funneliformis mosseae+n.d.[184]
Ephedra aphyllaClaroideoglomus etunicatum,
Funneliformis mosseae, Rhizophagus irregularis		+n.d.[185]
Ricinus communisFunneliformis mosseae,
Rhizophagus intraradices		+n.d.[181]
Sesbania sesbanClaroideoglomus etunicatum,
Funneliformis mosseae,
Rhizophagus irregularis		+n.d.[43]
Valeriana officinalisFunneliformis mosseae,
Rhizophagus irregularis		+n.d.[41]
High temperatureCyclamen persicumGlomus fasciculatum+n.d.[186]
Trace elementsOcimum basilicumRhizophagus intraradices++[174]
Trigonella foenum-graecumAcaulospora laevis,
Gigaspora nigra
Glomus monosporum,
Glomus clarum		++[187]
‘+’ indicates increasing responses; ‘–’ indicates decreasing responses; ‘=’ indicates no response; ‘n.d.’ indicates not determined.
Similarly, an enhancement in the concentration of artemisinin was observed in leaves of Artemisia annua inoculated with R. intraradices, and such an increase was attributed to the induced expression of the artemisinin biosynthesis genes including amorpha-4; 11-diene synthase, cytochrome P450, double bond reductase 2, and aldehyde dehydrogenase 1 [188]. Recently, Li et al. [189] reported that the inoculation of Paris polyphylla var. yunnanensis with mixtures of AMF species induced increased content of polyphyllin, which was associated with the expression of PpSE. A study caried out by Duc et al. [190] showed that a mixture of AMF species (F. mosseae, Septoglomus deserticola, and Acaulospora lacunose) promoted the accumulation of polyphenol content in Eclipta prostrata under salt stress [190]. This change in the polyphenol profile could be explained by the changes in the expression of genes involved in the polyphenol biosynthesis pathway [190]. Moreover, the AMF R. irregularis promoted glycyrrhizin and liquiritin in Glycyrrhiza uralensis plants experiencing water stress, and this enhancement was associated with an increase in the expression of glycyrrhizin biosynthesis genes (squalene synthase, β-amyrin synthase), P450 monooxygenase, and cytochrome P450 monooxygenase 72A154) [40].

3.2. AMF Improves Mineral Nutrient Uptake

It has been shown that AMF can boost the uptake of relatively immobile mineral nutrients in soils, including P, Zn, and Cu. The extraradical hyphae of AMF can extend beyond the depletion zone of the rhizosphere to absorb and transfer nutrient elements to the host plant [167]. Several studies have shown the impact of AMF inoculation on nutrient uptake in MAPs. For instance, two AMF species (F. mosseae and R. irregularis) significantly increased the leaf P concentration in fennel (Foeniculum vulgare Mill.) plants under different levels of water stress [180]. Under conditions of water stress, colonization of the roots by two AMF, R. intraradices and F. mosseae, alone or in combination, resulted in a significant increase in the concentrations of N, P, Fe, and Zn in rose geranium (Pelargonium graveolens L.) compared with non-inoculated plants [173]. It has been observed that water stress reduces P absorption, but this reduction rate was lower in mycorrhizal marigolds (Tagetes erecta) than in non-mycorrhizal plants [182]. Many studies have further shown that AMF inoculation enhanced the mineral nutrition of MAPs cultivated under abiotic stress. For example, it was shown that chamomile plants inoculated with F. mosseae demonstrated an increase in the shoot and root P and K concentrations under osmotic stress [38]. Similarly, enhancement of P, K, and Mg levels was reported in valerian (Valeriana officinalis L.) inoculated with F. mosseae and R. irregularis under salt stress [41]. In addition, hangbaiju (Chrysanthemum morifolium) inoculated with F. mosseae or Diversispora versiformis showed an increase in root concentration of N under salt stress [185]. Autochthonous F. mosseae (i.e., a drought-tolerant AMF strain) was found to be better than allochthonous F. mosseae (i.e., a drought-sensitive AMF strain) in terms of drought tolerance, with higher contents of N and K established in lavender (Lavandula spica) [32].
The main mechanism behind the higher nutrient concentration of mycorrhizal plants, especially in terms of P nutrients, is the increase in surface area for P uptake. The uptake of phosphate (Pi) from soil and AMF is mediated by the PHT1 gene family [191]. AMF induced Pi transporter genes during plant–AMF symbiosis [192]. AMF up-regulated the expression of phosphate transporter (PT) genes (LePT4 and LePT5) in tomato plants to enhance plant tolerance under conditions of water stress [193]. Furthermore, AMF induced the expression of ammonium transporter protein and potassium (K+) transporter genes under conditions of water stress, which is crucial for N and K uptake by host plants in arid regions [194]. The secretion of acid phosphates by extraradical hyphae has also been proposed [195].

3.3. AMF Improves Plant Water Status

It has been demonstrated that AMF can significantly improve plants’ water uptake to alleviate abiotic stresses such as water stress, salinity, and light stress [196,197]. This increase in water uptake could be attributed to an increase in the hydraulic conductivity of the roots, which results from a change in root morphology [198,199]. The formation of external hyphae by AMF can also improve access to larger areas in soil, resulting in increased uptake and transport of water from soil to roots [200,201]. Mycorrhizal plants have improved access to soil water compared with non-mycorrhizal plants because the extraradical hyphae involved in water transport have a diameter of 2–5 µm, allowing them to easily penetrate small soil pores that are not accessible to root hairs [200,202]. It is noteworthy that there has been no research using MAPs to confirm water uptake by extraradical hyphae under abiotic stress.
Due to negative water potential, meaning low water availability in the soil, plants can be faced with the problem of acquiring a sufficient amount of water [203], a process that necessitates the involvement of aquaporins [204,205,206]. Aquaporins, also called water channel proteins, belong to the family of membrane channel proteins that facilitate the transport of water following an osmotic gradient [205,206,207]. Numerous studies on various plant species have indicated that AMF can modify the expression of genes’ coding for plant aquaporins under different environmental stresses [203,208,209]. Under salt stress conditions, common bean (Phaseolus vulgaris) roots inoculated with R. irregularis showed an up-regulation of three plasma membrane intrinsic protein (PIP) genes, PvPIP1;1, PvPIP1;3, and PvPIP2;1, compared with non-inoculated plants [208]. Under conditions of water deficit, soybean (Glycine max) and lettuce (Lactuca sativa) plants inoculated with F. mosseae and R. irregularis showed rapid decreases in the expression of certain PIP genes in comparison with non-inoculated plants [210]. A study carried out on liquorice (Glycyrrhiza uralensis), which is an important medicinal plant, found that inoculating plants with R. irregularis increased the expression of aquaporin genes when compared with non-inoculated plants, implying that AMF has a direct role in improving plant water status during water stress [40]. These studies clearly showed that the expression of aquaporin genes in host plants may respond differently according to leels of AMF colonization and stress imposed. Taken together, the up-regulation of aquaporin genes might be linked to an increase in the water transport capacity of plants [211], especially under abiotic stresses [208,209,210]. Further studies are required to analyze the expression of plant aquaporins in mycorrhizal MAPs exposed to different abiotic stresses, and to investigate the roles of aquaporins in facilitating plants’ water uptake.
Some studies have reported that mycorrhizal MAPs such as liquorice (Glycyrrhiza uralensis) [40], pangola-grass Digitaria eriantha [39], and Polygonum cuspidatum [212] showed an increase in stomatal conductance, thereby increasing their photosynthetic rate. Indeed, it has been well demonstrated that water stress prompts stomatal closure, causing a reduction in CO2 availability, which reduces photosynthesis in plants [100]. In this way, AMF could enhance photosynthesis by improving the plant’s water status, because the increase of stomatal conductance could result in an increase in gas exchange [213].
Under water stress, rose geranium (Pelargonium graveolens L.) inoculated with AMF species (R. irregularis or F. mosseae) showed higher water use efficiency (WUE) than non-inoculated plants [173]. Similarly, R. irregularis had a positive effect on WUE in liquorice (Glycyrrhiza uralensis) subjected to water stress [40]. The mechanisms behind the enhancement of WUE can be attributed to higher water uptake by extraradical hyphae [196,214], an increase of stomatal conductance and transpiration rate [196,215], and adjustment of osmotic potential [216].

3.4. AMF Modifies Endogenous Hormones

Abscisic acid (ABA) is a phytohormone that regulates plant development, including seed dormancy, inhibition of seed germination, growth regulation, and stomatal closure [217,218,219]. Its role in stress tolerance has received significant attention [220]. Indeed, ABA is considered a stress hormone due to its fundamental role in the responses of plants to abiotic stresses [221]. Under abiotic stress conditions, ABA levels increase, maintaining plant water status, regulating stomatal closure, and inducing changes in the expression of stress-inducible genes [217,221,222,223,224].
Several studies have documented that ABA levels were higher in mycorrhizal MAPs having experienced water stress [33,225]. For example, Ephedra foliate inoculated with Claroideoglomus etunicatum, R. irregularis, and F. mosseae showed an increase in ABA concentration under conditions of water stress compared with control plants [33]. Under dehydration, the leaves of mycorrhizal chile ancho pepper (Capsicum annuum) plantlets had higher ABA concentrations than non-mycorrhizal plantlets [225]. Thus, in stressed–inoculated plants, the modulation of ABA levels in guard cells induces the closure of the stomata in order to prevent water loss [226]. In contrast, AMF can also reduce the ABA levels in MAPs under conditions of water and salt stress [40,43]. For example, sesbania (Sesbania sesban) colonized by F. mosseae, R. irregularis, and Claroideoglomus etunicatum exhibited lower ABA levels than non-mycorrhizal plants under salt stress [43]. In addition, lower ABA concentrations were observed in the roots of liquorice (Glycyrrhiza uralensis) inoculated with R. irregularis compared with non-mycorrhizal plants under drought stress [40]. It has been reported that AMF could improve plants’ drought tolerance by decreasing root ABA concentration, which in turn up-regulated the expression of plasma membrane intrinsic proteins (PIPs) and antioxidant SOD genes [227]. Based on the above studies, it seems that the regulation of ABA levels depends on the AMF and the host plant species.

3.5. AMF Mediates Osmotic Adjustments

Osmotic adjustment is another important mechanism that allows plants to tolerate abiotic stresses including water stress, salinity, and osmotic stress. Osmotic adjustment allows the plant to maintain its turgor pressure and physiological activity by accumulating organic osmolytes including proline, soluble sugars, glycine betaine, and polyamines, as well as inorganic osmolytes such as K+, Ca2+, and Mg2+ [228,229]. Several studies have shown that AMF inoculation enhanced the stress tolerance of MAPs by increasing osmolyte accumulation [38,41,180]. Accumulation of soluble sugars in mycorrhizal plants leads to an adjustment of osmotic potential, constituting an important defense mechanism against abiotic stress [230]. Studies conducted on valerian (Valeriana officinalis L.) colonized with R. irregularis and F. mosseae indicated a higher accumulation of total soluble sugars in shoots and roots under salinity stress compared with non-mycorrhizal plants [41]. Compared with non-mycorrhizal plants, German chamomile (Matricaria chamomilla L.) plants inoculated with F. mosseae presented significantly higher levels of soluble sugars under osmotic stress [38]. An increase in soluble sugars was also reported in fennel (Foeniculum vulgare Mill.) plants inoculated with F. mosseae and R. irregularis during water stress [180]. Inoculation of Ephedra foliate with a mixture of AMF species, viz., Claroideoglomus etunicatum, R. irregularis, and F. mosseae, prompted a higher accumulation of glucose than in non-inoculated plants [33]. Recently, a study by Sun et al. [231] reported an increase in sucrose content in the roots of Polygonum cuspidatum inoculated with F. mosseae.
Sugar accumulation in mycorrhizal plants is due to an increase in photosynthesis activity and also due to the hydrolysis of starch [232]. Furthermore, an increase in the expression of sugar transporter encoding genes may also lead to sugar accumulation in mycorrhizal plants [213,233]. It has been reported that, during AMF symbiosis, the carbon allocation from source leaves to the roots increases, and that this process requires an increase in the expression of genes encoding for sugar transporters [234]. In the roots of tomato (Solanum lycopersicon) plants colonized by F. mosseae, a higher accumulation of sucrose and fructose content was observed. These results suggest that sucrose synthesized in source organs is loaded into the phloem. Therefore, the expression of the three genes encoding the sucrose transporters SUT1, SUT2, and SUT4 was increased [213]. However, as far as we know, the role of sugar transporter genes in the osmotic adjustment of mycorrhizal MAPs under abiotic stresses has not been reported, and further investigations are needed to elucidate this subject.
Proline is one of the most important osmolytes, and its high accumulation in response to abiotic stresses maintains the cell’s osmotic balance. Several studies reported an accumulation of proline in MAPs inoculated with AMF under abiotic stresses, such as chamomile (Matricaria chamomilla) [38], castor bean (Ricinus communis) [181], basil (Ocimum gratissimum L.) [44], Ephedra alata [184], Ephedra foliate [33], and valerian (Valeriana officinalis L.) [41]. However, some plants do not show this increase in osmolytes. For instance, the Indian coral tree (Erythrina variegata L.) inoculated with F. mosseae showed tolerance to water deficit by accumulating chlorophyll and carotenoids but not proline or soluble sugars [166].

3.6. AMF Stimulates Plants’ Antioxidant Defense Systems

Exposure of plants to abiotic stresses induces an accumulation of ROS including hydroxyl radicals (·OH), hydrogen peroxide (H2O2), singlet oxygen (O1), and superoxide anion radical (O2). An excess accumulation of ROS might be harmful to plants as a result of oxidative damage to proteins, lipids, and nucleic acids [235,236]. Malondialdehyde (MDA) is the end product of lipid peroxidation and is widely used as a marker of oxidative lipid damage [237,238]. The detoxification of excess cellular ROS requires an antioxidant machinery composed of enzymatic and non-enzymatic antioxidants. The enzymatic antioxidants comprise superoxide dismutase (SOD), peroxidases (POD), catalase (CAT), ascorbate peroxidase (APX), glutathione peroxidase (GPX), and glutathione reductase (GR), while the non-enzymatic system includes reduced GSH, ascorbic acid (AA), phenols, tocopherols, and carotenoids [235,236,239]. Several studies have shown that AMF colonization reduces oxidative damage by enhancing the antioxidant system in plants (including MAPs) under conditions of water stress, salinity, and heat stress. For instance, rose geranium (Pelargonium graveolens L.) inoculated with F. mosseae or R. irregularis presented lower accumulations of H2O2 and MDA in their leaves. These findings suggested that mycorrhizal plants had higher antioxidant enzyme activity (CAT, APX, GPX, and SOD) than non-mycorrhizal plants [37]. AMF-treated Ephedra foliate plants showed an increase in enzymatic (CAT, APX, GPX, SOD, and GR) and non-enzymatic antioxidants (GSH and AA), allowing them to maintain ROS levels that better prevent cell damage under conditions of water stress compared with non-mycorrhizal plants [240]. The activation by AMF of antioxidant activities enhanced tolerance to water stress. Autochthonous R. irregularis conferred greater drought tolerance to lavender (Lavandula spica) plants than allochthonous F. mosseae did, because higher antioxidant concentrations and greater development of intraradical and extraradical mycelium and arbuscular formation were produced in lavender inoculated with R. irregularis [32]. Sesbania (Sesbania sesban L.) [43] and Ephedra aphylla [184] colonized with a mixture of AMF species, viz., Claroideoglomus etunicatum, R. irregularis, and F. mosseae, showed an increase of different enzymatic antioxidants under salt stress. An enhancement in non-enzymatic antioxidants was also observed in sesbania (Sesbania sesban L.) [43]. A low level of MDA was observed in AMF-treated Ephedra aphylla plants compared with control plants [184]. Roots of cyclamen (Cyclamen persicum Mill.) plants colonized by Glomus fasciculatum subjected to heat stress presented an increase in the production of SOD and APX, as well as non-enzymatic antioxidants (AA), compared with non-mycorrhizal stressed plants [186].
AMF can also stimulate the production of non-enzymatic antioxidants other than GSH and AA, such as carotenoids, phenolic, and flavonoid compounds [37,182,184,241]. For example, rose geranium (Pelargonium graveolens) plants colonized by different Glomus species had higher phenol and flavonoid contents than non-colonized planted subjected to water stress [37]. Furthermore, Ephedra aphyla inoculated with a mixture of AMF, viz., Claroideoglomus etunicatum, R. irregularis, and F. mosseae, showed an increase in phenolic compounds under salt stress [241]. In addition, an enhancement in carotenoid content was documented in marigold (Tagetes erecta) plants colonized with Glomus constrictum [182]. These studies suggest that mycorrhizal MAPs can withstand abiotic stresses by maintaining ROS homeostasis through the accumulation of enzymatic and non-enzymatic antioxidants. Overall, the improvement in antioxidant defense systems caused by AMF could be attributed to the fact that AMF can accumulate ROS and also that AMF possesses SOD genes [242,243].

4. Synergistic Effects of AMF and Other Amendments on MAPs

4.1. Microbial Amendments

PGPR are soil bacteria living around or on the root surface, and in addition to AMF can also be used to improve MAPs’ growth under stress conditions. Indeed, PGPR are directly or indirectly involved in promoting plant growth and development via secretion into the rhizosphere soil of various regulatory chemicals (phytohormones, aminocyclopropane-1-carboxylic acid deaminase, and volatile growth stimulants) [244,245]. They also perform important biological functions, protecting plants against many pests or helping them to mitigate abiotic stresses such as drought, salt, or pollution [246,247].
Many studies have reported the beneficial effects of PGPR on the growth and yield of MAPs under drought stress. For example, Asghari et al. [248] showed that PGPR conferred drought tolerance and stimulated the biosynthesis of secondary metabolites in pennyroyal (Mentha pulegium L.) under water shortage conditions. The authors demonstrated high ABA, salicylic acid (SA), soluble sugars, phenolics, flavonoids, and oxygenated monoterpene contents, as well as radical scavenging activity in PGPR-inoculated plants under severe drought stress. The contribution of PGPR has also been shown to promote seed germination and root elongation of sage (Salvia officinalis L.) as well as growth of Hyoscyamus niger under water deficit conditions [51]. The improvement in seed germination rate could be due to an increase in gibberellin (GA) synthesis, which triggers the activity of α-amylase enzymes that promote early germination by improving starch assimilation [51,249]. This mechanism has been reported in hopbush (Dodonaea viscosa L.) under saline stress [250]. Likewise, plant growth promotion by PGPR involves the production of plant growth regulators such as indole acetic acid, GA, cytokinins, and ethylene [251,252,253,254]. In addition, through the production of biofilms, PGPR improve the availability of water for the plant, helping to manage abiotic stresses. Several works have reported modifications of MAPs’ metabolisms and increases in EO production using PGPR inoculants [255]. Indeed, PGPR are known to improve plant biomass and trichome production and to stimulate terpene biosynthesis, which improves EO production [49,51,256]. For example, increases of cis-thujone in sage (Salvia officinalis L.), α-terpineol in sweet basil (Ocimum basilicum) and marjoram (Origanum majorana L.), trans-sabinene in marjoram (O. majorana L.) and hybrid marjoram (Origanum x majoricum), and EO yield in fennel (Foeniculum vulgare Mill.) and geranium (Pelargonium graveolens) have variously been observed [49,51,257,258].
Further studies have demonstrated the beneficial and synergistic effects of dual PGPR and AMF inoculation on MAPs under metal, water, and salt-stressed conditions [259,260,261,262,263]. It has been demonstrated under conditions of water stress that the combined inoculation of myrtle (Myrtus communis L.) with AMF (R. irregularis) and PGPR (Pseudomonas fluorescens, P. putida) species improved hydromineral supply and EO production as well as enhancing plants’ oxidative defense [262]. Furthermore, it was reported that combined inoculation of PGPR and AMF improved plant growth, metabolite content, and root length under drought stress in various MAPs [264,265]. Similarly, co-inoculation with plant-growth-promoting fungi (like Trichoderma spp. and AMF) and PGPR has been reported to increase the production of secondary metabolites and hairy roots of Chinese salvia (Salvia miltiorrhiza) under conditions of drought or salinity stress [261].

4.2. Organic Amendments

Organic amendments including biochar, composts, manures, and mulch are known to limit biotic and abiotic stresses on plants by influencing the physico-chemical properties, nutrient availability, retention capacity, or microbial activity of the soil [48]. In addition, organic amendments are rich in humic acids, which decrease the availability of metals through adsorption and the formation of stable organometallic complexes [266], which could contribute to reducing TE stress for MAPs. If well-chosen, all these organic amendments could (depending on the MAP species and soil type) significantly improve soil fertility and nutrient cycling, nitrogen fixation, organic matter amount, plant growth, and consequently plant establishment under conditions of water and temperature stress [267,268]. The decomposition of organic amendments has also been reported to provide useful weed control for MAPs, and as a solution to avoid water runoff while maintaining soil moisture [269]. Thus, compost application increased the biomass and EO yields of black cumin (Nigella sativa L.), cumin (Cuminum cyminum), and sweet basil (Ocimum basilicum L.) under drought stress conditions, and of Chenopodium album L. in TE-polluted soil. These improvements in plant biomass could be due to an increase in NPK availability, the physical, chemical, and biological properties of soils, and increased soil cation exchange capacity and water retention, resulting in better plant growth [270,271]. The addition of biochar allows the immobilization of TEs such as Pb and Cd through various mechanisms including surface complexation, surface precipitation, electrostatic attraction, physical adsorption, and ion exchange, improving soil quality by increasing water retention and nutrient mineralization, and reducing soil bulk density [272]. Biochar-based amendments can improve plant biomass, stimulate production of pharmaceutically active compounds, including phenolic and flavonoids, consequently increasing antioxidant activities, and could reduce the risk of metal accumulation in the plant [272]. Indeed, biochar has been shown to improve the quality of bioactive compounds and the biomass yield of various MAPs, including kalmegh (Andrographis paniculata) cultivated under conditions of water stress, and brahmi (Bacopa monnieri L.), kalmegh, and ashwagandha (Withania somnifera L.) cultivated on TE-polluted soil [272,273].
Synergistic effects of combined organic amendment and AMF have been reported in many studies [274,275,276,277]. For example, the combination of AMF inoculation with organic amendment improved the biomass and active principle yields of lemon balm (Melissa officinalis L.) [274]. Similarly, Kaleji et al. [275] reported that the co-application of AMF and compost enhanced the growth and EO content of water mint (Mentha aquatica) [275].

4.3. Mineral Amendments

Mineral fertilizers such as NPK, silicate, or clay are known to affect soil porosity, pore distribution, water retention, and water availability in the soil [52,278,279]. Under conditions of water stress, the EO and biomass yields of sage (Salvia officinalis L.) have been reported to be significantly higher when fertilized with a conventional NPK mineral fertilizer [280]. Indeed, by changing soil pH, silicates reduced the phytoavailability of TEs, which are precipitated or chelated on soil aggregates [52]. Furthermore, silicate has been reported to be useful against various stresses, e.g., salinity, temperature, and flooding [281]. Generally, stress tolerance mechanisms can be attributed to physiological improvements in plants, activation of antioxidant systems, elicitation of secondary metabolites including ABA implicated in the osmotic stress response, or enzymatic activity (SOD, GPX, and CAT) [281]. For example, under stress conditions, silicate has been known to improve plant enzymatic activities such as SOD, CAT, GPX, and APX, as well as those of non-enzymatic antioxidants such as glutathione and proline, or plant transporters [281]. Likewise, clay amendment was reported to promote root elongation and drought tolerance in Pakchoi (Brassica chinesis L.) and hybrid sage varieties (Salvia officinalis × S. pomifera, S. officinalis × S. tomentosa, S. officinalis × S. ringens and S. fruticosa × S. ringens) under conditions of water stress [278,282], and silicate fertilizers reduced Cd transfer and accumulation in basil (Ocimum basilicum) shoots under metal stress [52].
Very few studies have demonstrated the synergistic effects of AMF inoculation and mineral amendments on MAPs under stress conditions. Indeed, AMF are often presented as an alternative to the application of chemical fertilizer in the production of MAPs. Recently, it has been shown that the application of a mixture of mycorrhizal species (R. intraradices, F. mosseae, Glomus hoi) and phosphorus fertilizer could improve the EO yield and physiological characteristics of peppermint (Mentha piperita) cultivated under different water stress conditions [283]. On the other hand, several studies have reported beneficial effects after the co-application of mineral and organic fertilizers [284,285]. For example, synergistic effects on fruit quality improvement have been described in the case of co-application of mineral and organic amendments under water deficit in pomegranate [286].

4.4. Biostimulants

Biostimulants are categorized as biological amendments and contain a wide range of molecules which may include chitosan, amino acids, humic substances, or plant extracts [46]. Their functional richness and potential interest in relation to MAPs grown under abiotic stress conditions have been highlighted in numerous studies [46,287,288,289,290]. It was shown that moderate water stress combined with SA application (300 ppm) increased EO yield [291] in lemon verbena (Lippia citriodora L.). The foliar application of SA and chitosan increased the EO content of thymbra (Thymbra spicata L.) and, particularly, the amount of thymol produced under reduced irrigation conditions [289]. Likewise, palm pollen grain extracts increased EO yield and the level of osmoprotectants (proline, amino acids, and soluble sugars) in basil (Ocimum basilicum L.) cultivated under drought conditions [290]. It has also been reported that the use of microalgae extracts caused a change in the composition of basil (Ocimum basilicum L.) and parsley (Petroselinum crispum L.) EOs, and increased the content of certain compounds [292]. Foliar spray of pluramin (a powdery compound of amino acids) was reported to reduce water stress damage in lemon balm (Melissa officinalis L.) [293].
To the best of our knowledge, no data have been reported on the synergistic effects of biostimulants and AMF inoculation on MAPs. On the other hand, some studies have demonstrated the beneficial and synergistic effects of combinations of various biostimulants, including those with organic amendments, on MAPs’ biomass production or EO yield [289,294]. For example, it was reported that co-application of biostimulants (such as Azotobacter chroococcum and Azospirillum lipoferum) and vermicompost improved the fresh and dry weights of coriander (Coriandrum sativum L.) [294].

5. Conclusions and Future Perspectives

With the increasing demand for natural products originating from MAPs, the cultivation of these plant species has become of great interest throughout the world. Unfortunately, MAPs face various environmental stresses due to anthropic activities, intensified by climate change, which have triggered harmful effects on their growth as well as the productivity and quality of their EOs. Therefore, much effort has gone into developing eco-friendly strategies that can tackle the problems related to ongoing climate change and improve plant tolerance. Hence, the actual challenge is to increase plant growth and biomass production while maintaining or improving the quality and yield of herbal materials such as EOs.
Microbial and organic or inorganic amendments can confer greater tolerance against abiotic stress in MAPs. AMF not only enhanced water and nutrient acquisition but also rapidly triggered the MAPs’ morphological, physiological, and molecular responses, which increased their ability to overcome the adverse effects of abiotic stress (Figure 1). It has been shown in the current review that AMF can improve plant growth as well as the quantity and quality of EOs. Many studies have demonstrated the synergetic effect of AMF with other soil amendments to improve MAPs’ growth and, consequently, EO yield and quality under abiotic stress. However, insights into the mechanisms behind the interaction of microbial soil amendments and MAPs under abiotic stress are very complex, and there remains a need for further investigation. Based on the data outlined in the current review, there is a need in the future for fundamental and applied investigations into different aspects:
  • Most of the previously cited studies were conducted in the laboratory or under greenhouse conditions (i.e., pot experiments). However, further field experiments are required as many factors, including climate and microbial rhizosphere biodiversity, may influence the results compared with those obtained in controlled conditions.
  • In studies where different strains were tested, the extent of AMF response on plant growth and root colonization varied with AMF species and also with the type and level of stress. Therefore, choosing the appropriate host plant and AMF species is important for using plant–AMF symbionts successfully. In future research, it will be important to screen indigenous and stress-tolerant AMF isolates to improve the effectiveness of arbuscular mycorrhizal symbiosis.
  • More research should focus on the use of AMF in combination with PGPR or with organic or inorganic amendments to obtain more advantages in enhancing MAP growth and productivity. In addition, there is a considerable lack of data underlying the molecular mechanisms involved in the synergistic effects observed, and more generally in the modification of secondary metabolite pathway biosynthesis.
  • Finally, various advanced techniques (proteomics, genomics, and metabolomics) could provide new insight into the mechanisms exerted by arbuscular mycorrhizal symbiosis, which confer stronger productivity and enhanced resistance to MAPs under abiotic stresses.

Author Contributions

Conceptualization, methodology, and validation, A.I., J.L., A.L.-H.S. and J.F; writing—original draft preparation, A.I. and J.L.; Writing—review and editing, A.I., J.L., J.F. and A.L.-H.S.; Supervision, A.L.-H.S. and J.F.; Project administration, A.L.-H.S.; Funding acquisition, A.L.-H.S. and J.F. All authors have read and agreed to the published version of the manuscript.

Funding

The authors wish to thank the “Université du Littoral Côte d’Opale” and the “Région des Hauts de France” for providing the financial support for Julien Langrand’s Ph.D thesis and Abir Israel’s ATER post. This work was carried out within the framework of the DEPHYTOP project funded by ADEME, CPER ALIBIOTECH and BiHautsEcodeFrance projects, which are funded by the European Union, the French State, and the French Region of Hauts-de-France, as well as the TRIPLET project, financed by A2U.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Hassan, B. Medicinal Plants (Importance and Uses). Pharm. Anal. Acta 2012, 3, 2153–2435. [Google Scholar] [CrossRef]
  2. Chouhan, S.; Sharma, K.; Guleria, S. Antimicrobial Activity of Some Essential Oils—Present Status and Future Perspectives. Medicines 2017, 4, 58. [Google Scholar] [CrossRef]
  3. Raveau, R.; Fontaine, J.; Lounès – Hadj Sahraoui, A. Essential Oils as Potential Alternative Biocontrol Products against Plant Pathogens and Weeds: A Review. Foods 2020, 9, 365. [Google Scholar] [CrossRef]
  4. Sofowora, A.; Ogunbodede, E.; Onayade, A. The Role and Place of Medicinal Plants in the Strategies for Disease Prevention. Afr. J. Tradit. Complement. Altern. Med. 2013, 10, 210–229. [Google Scholar] [CrossRef]
  5. Samarth, R.M.; Samarth, M.; Matsumoto, Y. Medicinally Important Aromatic Plants with Radioprotective Activity. Future Sci. OA 2017, 3, FSO247. [Google Scholar] [CrossRef] [PubMed]
  6. Dhifi, W.; Bellili, S.; Jazi, S.; Bahloul, N.; Mnif, W. Essential Oils’ Chemical Characterization and Investigation of Some Biological Activities: A Critical Review. Medicines 2016, 3, 25. [Google Scholar] [CrossRef] [PubMed]
  7. Li, Y.; Kong, D.; Fu, Y.; Sussman, M.R.; Wu, H. The Effect of Developmental and Environmental Factors on Secondary Metabolites in Medicinal Plants. Plant Physiol. Biochem. 2020, 148, 80–89. [Google Scholar] [CrossRef]
  8. Mugao, L.G.; Gichimu, B.M.; Muturi, P.W.; Mukono, S.T. Characterization of the Volatile Components of Essential Oils of Selected Plants in Kenya. Biochem. Res. Int. 2020, 2020, e8861798. [Google Scholar] [CrossRef]
  9. Sujatha, S.; Bhat, R.; Kannan, C.; Balasimha, D. Impact of Intercropping of Medicinal and Aromatic Plants with Organic Farming Approach on Resource Use Efficiency in Arecanut (Areca catechu L.) Plantation in India. Ind. Crops Prod. 2011, 33, 78–83. [Google Scholar] [CrossRef]
  10. Ekor, M. The Growing Use of Herbal Medicines: Issues Relating to Adverse Reactions and Challenges in Monitoring Safety. Front. Pharmacol. 2014, 4, 177. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  11. Karunamoorthi, K.; Jegajeevanram, K.; Vijayalakshmi, J.; Mengistie, E. Traditional Medicinal Plants: A Source of Phytotherapeutic Modality in Resource-Constrained Health Care Settings. J. Evid. Based Complement. Altern. Med. 2013, 18, 67–74. [Google Scholar] [CrossRef]
  12. Hamilton, A.C. Medicinal Plants, Conservation and Livelihoods. Biodivers. Conserv. 2004, 13, 1477–1517. [Google Scholar] [CrossRef]
  13. He, J.; Yang, B.; Dong, M.; Wang, Y. Crossing the Roof of the World: Trade in Medicinal Plants from Nepal to China. J. Ethnopharmacol. 2018, 224, 100–110. [Google Scholar] [CrossRef] [PubMed]
  14. Lange, D. International Trade in Medicinal and Aromatic Plants: Actors, Volumes and Commodities. Frontis 2006, 17, 155–170. [Google Scholar]
  15. Crockett, J.L.; Westerling, A.L. Greater Temperature and Precipitation Extremes Intensify Western U.S. Droughts, Wildfire Severity, and Sierra Nevada Tree Mortality. J. Clim. 2018, 31, 341–354. [Google Scholar] [CrossRef]
  16. Zandalinas, S.I.; Fritschi, F.B.; Mittler, R. Global Warming, Climate Change, and Environmental Pollution: Recipe for a Multifactorial Stress Combination Disaster. Trends Plant Sci. 2021, 26, 588–599. [Google Scholar] [CrossRef]
  17. Mahajan, M.; Kuiry, R.; Pal, P. Understanding the Consequence of Environmental Stress for Accumulation of Secondary Metabolites in Medicinal and Aromatic Plants. J. Appl. Res. Med. Aromat. Plants 2020, 18, 100255. [Google Scholar] [CrossRef]
  18. Das, M.; Jain, V.; Malhotra, S. Impact of Climate Change on Medicinal and Aromatic Plants: Review. Indian J. Agric. Sci. 2016, 86, 1375–1382. [Google Scholar]
  19. Chrysargyris, A.; Laoutari, S.; Litskas, V.D.; Stavrinides, M.C.; Tzortzakis, N. Effects of Water Stress on Lavender and Sage Biomass Production, Essential Oil Composition and Biocidal Properties against Tetranychus Urticae (Koch). Sci. Hortic. 2016, 213, 96–103. [Google Scholar] [CrossRef]
  20. Petropoulos, S.A.; Daferera, D.; Polissiou, M.G.; Passam, H.C. The Effect of Water Deficit Stress on the Growth, Yield and Composition of Essential Oils of Parsley. Sci. Hortic. 2008, 115, 393–397. [Google Scholar] [CrossRef]
  21. Zehtab-Salmasi, S.; Javanshir, A.; Omidbaigi, R.; Alyari, H.; Ghassemi-Golezani, K. Effects of Water Supply and Sowing Date on Performance and Essential Oil Production of Anise (Pimpinella anisum L.). Acta Agron. Hung. 2001, 49, 75–81. [Google Scholar] [CrossRef]
  22. Bettaieb Rebey, I.; Jabri-Karoui, I.; Hamrouni-Sellami, I.; Bourgou, S.; Limam, F.; Marzouk, B. Effect of Drought on the Biochemical Composition and Antioxidant Activities of Cumin (Cuminum cyminum L.) Seeds. Ind. Crops Prod. 2012, 36, 238–245. [Google Scholar] [CrossRef]
  23. Begum, N.; Qin, C.; Ahanger, M.A.; Raza, S.; Khan, M.I.; Ashraf, M.; Ahmed, N.; Zhang, L. Role of Arbuscular Mycorrhizal Fungi in Plant Growth Regulation: Implications in Abiotic Stress Tolerance. Front. Plant Sci. 2019, 10, 1068. [Google Scholar] [CrossRef]
  24. Benaffari, W.; Boutasknit, A.; Anli, M.; Ait-El-Mokhtar, M.; Ait-Rahou, Y.; Ben-Laouane, R.; Ben Ahmed, H.; Mitsui, T.; Baslam, M.; Meddich, A. The Native Arbuscular Mycorrhizal Fungi and Vermicompost-Based Organic Amendments Enhance Soil Fertility, Growth Performance, and the Drought Stress Tolerance of Quinoa. Plants 2022, 11, 393. [Google Scholar] [CrossRef]
  25. Diagne, N.; Ngom, M.; Djighaly, P.I.; Fall, D.; Hocher, V.; Svistoonoff, S. Roles of Arbuscular Mycorrhizal Fungi on Plant Growth and Performance: Importance in Biotic and Abiotic Stressed Regulation. Diversity 2020, 12, 370. [Google Scholar] [CrossRef]
  26. Porcel, R.; Aroca, R.; Ruiz-Lozano, J.M. Salinity Stress Alleviation Using Arbuscular Mycorrhizal Fungi. A Review. Agron. Sustain. Dev. 2012, 32, 181–200. [Google Scholar] [CrossRef]
  27. Shah, A.; Nazari, M.; Antar, M.; Msimbira, L.A.; Naamala, J.; Lyu, D.; Rabileh, M.; Zajonc, J.; Smith, D.L. PGPR in Agriculture: A Sustainable Approach to Increasing Climate Change Resilience. Front. Sustain. Food Syst. 2021, 5, 667546. [Google Scholar] [CrossRef]
  28. Sun, R.-T.; Zhang, Z.-Z.; Zhou, N.; Srivastava, A.K.; Kuča, K.; Abd-Allah, E.F.; Hashem, A.; Wu, Q.-S. A Review of the Interaction of Medicinal Plants and Arbuscular Mycorrhizal Fungi in the Rhizosphere. Not. Bot. Horti Agrobot. Cluj-Napoca 2021, 49, 12454. [Google Scholar] [CrossRef]
  29. Brown, M.E. Seed and Root Bacterization. Annu. Rev. Phytopathol. 1974, 12, 181–197. [Google Scholar] [CrossRef]
  30. Saia, S.; Amato, G.; Frenda, A.S.; Giambalvo, D.; Ruisi, P. Influence of Arbuscular Mycorrhizae on Biomass Production and Nitrogen Fixation of Berseem Clover Plants Subjected to Water Stress. PLoS ONE 2014, 9, e90738. [Google Scholar] [CrossRef]
  31. Smith, S.E.; Read, D.J. Mycorrhizal Symbiosis, 3rd ed.; Academic Press: Amsterdam, The Netherland; Boston, MA, USA, 2008; ISBN 978-0-12-370526-6. [Google Scholar]
  32. Marulanda, A.; Porcel, R.; Barea, J.M.; Azcón, R. Drought Tolerance and Antioxidant Activities in Lavender Plants Colonized by Native Drought-Tolerant or Drought-Sensitive Glomus Species. Microb. Ecol. 2007, 54, 543–552. [Google Scholar] [CrossRef] [PubMed]
  33. Al-Arjani, A.-B.F.; Hashem, A.; Abd_Allah, E.F. Arbuscular Mycorrhizal Fungi Modulates Dynamics Tolerance Expression to Mitigate Drought Stress in Ephedra Foliata Boiss. Saudi J. Biol. Sci. 2020, 27, 380–394. [Google Scholar] [CrossRef] [PubMed]
  34. Zhang, M.; Shi, Z.; Zhang, S.; Gao, J. A Database on Mycorrhizal Traits of Chinese Medicinal Plants. Front. Plant Sci. 2022, 13, 840343. [Google Scholar] [CrossRef] [PubMed]
  35. Latef, A.A.H.A.; Hashem, A.; Rasool, S.; Abd_Allah, E.F.; Alqarawi, A.A.; Egamberdieva, D.; Jan, S.; Anjum, N.A.; Ahmad, P. Arbuscular Mycorrhizal Symbiosis and Abiotic Stress in Plants: A Review. J. Plant Biol. 2016, 59, 407–426. [Google Scholar] [CrossRef]
  36. Parniske, M. Arbuscular Mycorrhiza: The Mother of Plant Root Endosymbioses. Nat. Rev. Microbiol. 2008, 6, 763–775. [Google Scholar] [CrossRef]
  37. Amiri, R.; Nikbakht, A.; Etemadi, N. Alleviation of Drought Stress on Rose Geranium [Pelargonium graveolens (L.) Herit.] in Terms of Antioxidant Activity and Secondary Metabolites by Mycorrhizal Inoculation. Sci. Hortic. 2015, 197, 373–380. [Google Scholar] [CrossRef]
  38. Ebrahimi, F.; Salehi, A.; Movahedi Dehnavi, M.; Mirshekari, A.; Hamidian, M.; Hazrati, S. Biochemical Response and Nutrient Uptake of Two Arbuscular Mycorrhiza-Inoculated Chamomile Varieties under Different Osmotic Stresses. Bot. Stud. 2021, 62, 22. [Google Scholar] [CrossRef]
  39. Pedranzani, H.; Rodríguez-Rivera, M.; Gutiérrez, M.; Porcel, R.; Hause, B.; Ruiz-Lozano, J.M. Arbuscular Mycorrhizal Symbiosis Regulates Physiology and Performance of Digitaria eriantha Plants Subjected to Abiotic Stresses by Modulating Antioxidant and Jasmonate Levels. Mycorrhiza 2016, 26, 141–152. [Google Scholar] [CrossRef]
  40. Xie, W.; Hao, Z.; Zhou, X.; Jiang, X.; Xu, L.; Wu, S.; Zhao, A.; Zhang, X.; Chen, B. Arbuscular Mycorrhiza Facilitates the Accumulation of Glycyrrhizin and Liquiritin in Glycyrrhiza uralensis under Drought Stress. Mycorrhiza 2018, 28, 285–300. [Google Scholar] [CrossRef]
  41. Amanifar, S.; Toghranegar, Z. The Efficiency of Arbuscular Mycorrhiza for Improving Tolerance of Valeriana officinalis L. and Enhancing Valerenic Acid Accumulation under Salinity Stress. Ind. Crops Prod. 2020, 147, 112234. [Google Scholar] [CrossRef]
  42. Bitterlich, M.; Rouphael, Y.; Graefe, J.; Franken, P. Arbuscular Mycorrhizas: A Promising Component of Plant Production Systems Provided Favorable Conditions for Their Growth. Front. Plant Sci. 2018, 9, 1329. [Google Scholar] [CrossRef] [PubMed]
  43. Abd_Allah, E.F.; Hashem, A.; Alqarawi, A.A.; Bahkali, A.H.; Alwhibi, M.S. Enhancing Growth Performance and Systemic Acquired Resistance of Medicinal Plant Sesbania sesban (L.) Merr Using Arbuscular Mycorrhizal Fungi under Salt Stress. Saudi J. Biol. Sci. 2015, 22, 274–283. [Google Scholar] [CrossRef] [PubMed]
  44. Hazzoumi, Z.; Moustakime, Y.; Hassan Elharchli, E.; Joutei, K.A. Effect of Arbuscular Mycorrhizal Fungi (AMF) and Water Stress on Growth, Phenolic Compounds, Glandular Hairs, and Yield of Essential Oil in Basil (Ocimum gratissimum L). Chem. Biol. Technol. Agric. 2015, 2, 10. [Google Scholar] [CrossRef]
  45. Cheng, S.; Zou, Y.-N.; Kuča, K.; Hashem, A.; Abd_Allah, E.F.; Wu, Q.-S. Elucidating the Mechanisms Underlying Enhanced Drought Tolerance in Plants Mediated by Arbuscular Mycorrhizal Fungi. Front. Microbiol. 2021, 12, 809473. [Google Scholar] [CrossRef]
  46. Abbott, L.K.; Macdonald, L.M.; Wong, M.T.F.; Webb, M.J.; Jenkins, S.N.; Farrell, M. Potential Roles of Biological Amendments for Profitable Grain Production—A Review. Agric. Ecosyst. Environ. 2018, 256, 34–50. [Google Scholar] [CrossRef]
  47. Bamdad, H.; Papari, S.; Lazarovits, G.; Berruti, F. Soil Amendments for Sustainable Agriculture: Microbial-organic Fertilizers. Soil Use Manag. 2021, 38, 94–120. [Google Scholar] [CrossRef]
  48. Ullah, N.; Ditta, A.; Imtiaz, M.; Li, X.; Jan, A.U.; Mehmood, S.; Rizwan, M.S.; Rizwan, M. Appraisal for Organic Amendments and Plant Growth-promoting Rhizobacteria to Enhance Crop Productivity under Drought Stress: A Review. J. Agron. Crop Sci. 2021, 207, 783–802. [Google Scholar] [CrossRef]
  49. Banchio, E.; Xie, X.; Zhang, H.; Paré, P.W. Soil Bacteria Elevate Essential Oil Accumulation and Emissions in Sweet Basil. J. Agric. Food Chem. 2009, 57, 653–657. [Google Scholar] [CrossRef]
  50. Dehghani Bidgoli, R.; Azarnezhad, N.; Akhbari, M.; Ghorbani, M. Salinity Stress and PGPR Effects on Essential Oil Changes in Rosmarinus officinalis L. Agric. Food Secur. 2019, 8, 2. [Google Scholar] [CrossRef]
  51. Ghorbanpour, M.; Hatami, M.; Kariman, K.; Khavazi, K. Enhanced Efficiency of Medicinal and Aromatic Plants by PGPRs. In Plant-Growth-Promoting Rhizobacteria (PGPR) and Medicinal Plants; Egamberdieva, D., Shrivastava, S., Varma, A., Eds.; Soil Biology; Springer International Publishing: Cham, Switzerland, 2015; Volume 42, pp. 43–70. ISBN 978-3-319-13400-0. [Google Scholar]
  52. Putwattana, N.; Kruatrachue, M.; Pokethitiyook, P.; Chaiyarat, R. Immobilization of Cadmium in Soil by Cow Manure and Silicate Fertilizer, and Reduced Accumulation of Cadmium in Sweet Basil (Ocimum basilicum). ScienceAsia 2010, 36, 349–354. [Google Scholar] [CrossRef]
  53. Nogués, S.; Baker, N.R. Effects of Drought on Photosynthesis in Mediterranean Plants Grown under Enhanced UV-B Radiation. J. Exp. Bot. 2000, 51, 1309–1317. [Google Scholar] [CrossRef] [PubMed]
  54. Moeini Alishah, H.; Heidari, R.; Hassani, A.; Dizaji Asadi, A. Effect of Water Stress on Some Morphological and Biochemical Characteristics of Purple Basil ( Ocimum basilicum ). J. Biol. Sci. 2006, 6, 763–767. [Google Scholar] [CrossRef] [Green Version]
  55. Jones, H.; Tardieu, F. Modelling Water Relations of Horticultural Crops: A Review. Sci. Hortic. 1998, 74, 21–46. [Google Scholar] [CrossRef]
  56. Laribi, B.; Bettaieb, I.; Kouki, K.; Sahli, A.; Mougou, A.; Marzouk, B. Water Deficit Effects on Caraway (Carum carvi L.) Growth, Essential Oil and Fatty Acid Composition. Ind. Crops Prod. 2009, 30, 372–379. [Google Scholar] [CrossRef]
  57. Thakur, P.; Thakur, A. Effect of Water Stress on Growth, Physiological and Biochemical Characteristics of Coriander. Indian J. Ecol. 2017, 44, 731–735. [Google Scholar]
  58. Khorasaninejad, S.; Mousavi, A.; Soltanloo, H.; Hemmati, K.; Khalighi, A. The Effect of Drought Stress on Growth Parameters, Essential Oil Yield and Constituent of Peppermint (Mentha piperita L.). J. Med. Plants Res. 2011, 5, 5360–5365. [Google Scholar] [CrossRef]
  59. Khalid, K. Influence of Water Stress on Growth, Essential Oil, and Chemical Composition of Herbs (Ocimum Sp.). Int. Agrophysics 2006, 20, 289–296. [Google Scholar]
  60. Hassan, F.A.S.; Bazaid, S.; Ali, E.F. Effect of Deficit Irrigation on Growth, Yield and Volatile Oil Contenton Rosmarinus officinalis L. Plant. J. Med. Plants Study 2013, 1, 12–21. [Google Scholar]
  61. García-Caparrós, P.; Romero, M.J.; Llanderal, A.; Cermeño, P.; Lao, M.T.; Segura, M.L. Effects of Drought Stress on Biomass, Essential Oil Content, Nutritional Parameters, and Costs of Production in Six Lamiaceae Species. Water 2019, 11, 573. [Google Scholar] [CrossRef]
  62. Bettaieb, I.; Zakhama, N.; Wannes, W.A.; Kchouk, M.E.; Marzouk, B. Water Deficit Effects on Salvia officinalis Fatty Acids and Essential Oils Composition. Sci. Hortic. 2009, 120, 271–275. [Google Scholar] [CrossRef]
  63. Baher, Z.F.; Mirza, M.; Ghorbanli, M.; Bagher Rezaii, M. The Influence of Water Stress on Plant Height, Herbal and Essential Oil Yield and Composition in Satureja hortensis L. Flavour Fragr. J. 2002, 17, 275–277. [Google Scholar] [CrossRef]
  64. Kim, K.S.; Park, S.H.; Jenks, M.A. Changes in Leaf Cuticular Waxes of Sesame (Sesamum indicum L.) Plants Exposed to Water Deficit. J. Plant Physiol. 2007, 164, 1134–1143. [Google Scholar] [CrossRef] [PubMed]
  65. Dunford, N.T.; Vazquez, R.S. Effect of Water Stress on Plant Growth and Thymol and Carvacrol Concentrations in Mexican oregano Grown under Controlled Conditions. J. Appl. Hortic. 2005, 7, 20–22. [Google Scholar] [CrossRef]
  66. Simon, J.E.; Reiss-Bubenheim, D.; Joly, R.J.; Charles, D.J. Water Stress-Induced Alterations in Essential Oil Content and Composition of Sweet Basil. J. Essent. Oil Res. 1992, 4, 71–75. [Google Scholar] [CrossRef]
  67. Simon, J.E.; Quinn, J. Characterization of Essential Oil of Parsley. J. Agric. Food Chem. 1988, 36, 467–472. [Google Scholar] [CrossRef]
  68. Hendawy, S.; Khalid, K. Response of Sage (Salvia officinalis L.) Plants to Zinc Application Under Different Salinity Levels. J. Appl. Sci. Res. 2005, 1, 147–155. [Google Scholar]
  69. Nacif de Abreu, I.; Mazzafera, P. Effect of Water and Temperature Stress on the Content of Active Constituents of Hypericum Brasiliense Choisy. Plant Physiol. Biochem. 2005, 43, 241–248. [Google Scholar] [CrossRef]
  70. Wang, W.; Vinocur, B.; Altman, A. Plant Responses to Drought, Salinity and Extreme Temperatures: Towards Genetic Engineering for Stress Tolerance. Planta 2003, 218, 1–14. [Google Scholar] [CrossRef]
  71. Lemoine, R.; Camera, S.L.; Atanassova, R.; Dédaldéchamp, F.; Allario, T.; Pourtau, N.; Bonnemain, J.-L.; Laloi, M.; Coutos-Thévenot, P.; Maurousset, L.; et al. Source-to-Sink Transport of Sugar and Regulation by Environmental Factors. Front. Plant Sci. 2013, 4, 272. [Google Scholar] [CrossRef]
  72. Ashraf, M.; Akhtar, N. Influence of Salt Stress on Growth, Ion Accumulation and Seed Oil Content in Sweet Fennel. Biol. Plant. 2004, 48, 461–464. [Google Scholar] [CrossRef]
  73. Ashraf, M.; Orooj, A. Salt Stress Effects on Growth, Ion Accumulation and Seed Oil Concentration in an Arid Zone Traditional Medicinal Plant Ajwain (Trachyspermum ammi [L.] Sprague). J. Arid Environ. 2006, 2, 209–220. [Google Scholar] [CrossRef]
  74. Neffati, M.; Marzouk, B. Changes in Essential Oil and Fatty Acid Composition in Coriander (Coriandrum sativum L.) Leaves under Saline Conditions. Ind. Crops Prod. 2008, 28, 137–142. [Google Scholar] [CrossRef]
  75. Neffati, M.; Sriti, J.; Hamdaoui, G.; Kchouk, M.E.; Marzouk, B. Salinity Impact on Fruit Yield, Essential Oil Composition and Antioxidant Activities of Coriandrum sativum Fruit Extracts. Food Chem. 2011, 124, 221–225. [Google Scholar] [CrossRef]
  76. Neffati, M.; Marzouk, B. Roots Volatiles and Fatty Acids of Coriander (Coriandrum sativum L.) Grown in Saline Medium. Acta Physiol. Plant. 2009, 31, 455–461. [Google Scholar] [CrossRef]
  77. Razmjoo, K.; Heydarizadeh, P.; Sabzalian, M. Effect of Salinity and Drought Stresses on Growth Parameters and Essential Oil Content of Matricaria chamomila. Int. J. Agri. Biol. 2008, 10, 1560–8530. [Google Scholar]
  78. Khalid, K.A.; Teixeira da Silva, J.A. Yield, Essential Oil and Pigment Content of Calendula officinalis L. Flower Heads Cultivated under Salt Stress Conditions. Sci. Hortic. 2010, 126, 297–305. [Google Scholar] [CrossRef]
  79. Ozturk, A.; Ünlükara, A.; Ipek, A.; Gürbüz, B. Effects of Salt Stress and Water Deficit on Plant Growth and Essential Oil Content of Lemon Balm (Melissa officinalis L.). Pak. J. Bot. 2004, 36, 787–792. [Google Scholar]
  80. Aziz, E.E.; Al-Amier, H.; Craker, L.E. Influence of Salt Stress on Growth and Essential Oil Production in Peppermint, Pennyroyal, and Apple Mint. J. Herbs Spices Med. Plants 2008, 14, 77–87. [Google Scholar] [CrossRef]
  81. Tabatabaei, S.J.; Nazari deljou, M. Javad Influence of Nutrient Concentrations and NaCl Salinity on the Growth, Photosynthesis and Essential Oil Content of Peppermint and Lemon Verbena. Turk. J. Agric. For. 2007, 31, 245–253. [Google Scholar]
  82. Baatour, O.; Kaddour, R.; Aidi Wannes, W.; Lachaâl, M.; Marzouk, B. Salt Effects on the Growth, Mineral Nutrition, Essential Oil Yield and Composition of Marjoram (Origanum majorana). Acta Physiol. Plant. 2009, 32, 45. [Google Scholar] [CrossRef]
  83. Ben Taarit, M.; Msaada, K.; Hosni, K.; Marzouk, B. Changes in Fatty Acid and Essential Oil Composition of Sage (Salvia officinalis L.) Leaves under NaCl Stress. Food Chem. 2010, 119, 951–956. [Google Scholar] [CrossRef]
  84. Ben Taarit, M.; Msaada, K.; Hosni, K.; Hammami, M.; Kchouk, M.E.; Marzouk, B. Plant Growth, Essential Oil Yield and Composition of Sage (Salvia officinalis L.) Fruits Cultivated under Salt Stress Conditions. Ind. Crops Prod. 2009, 30, 333–337. [Google Scholar] [CrossRef]
  85. Najafi, F.; Khavari-Nejad, R.; Ali, M. The Effects of Salt Stress on Certain Physiological Parameters in Summer Savory (Satureja hortensis L.) Plants. J. Stress Physiol. Biochem. 2010, 6, 13–21. [Google Scholar]
  86. Emami Bistgani, Z.; Ataollah Siadat, S.; Bakhshandeh, A.; Ghasemi Pirbalouti, A.; Hashemi, M.; Maggi, F.; Reza Morshedloo, M. Application of Combined Fertilizers Improves Biomass, Essential Oil Yield, Aroma Profile, and Antioxidant Properties of Thymus daenensis Celak. Ind. Crops Prod. 2018, 121, 434–440. [Google Scholar] [CrossRef]
  87. Belaqziz, R.; Abderrahmane, R.; Abbad, A. Salt Stress Effects on Germination, Growth and Essential Oil Content of an Endemic Thyme Species in Morocco (Thymus maroccanus Ball.). J. Appl. Sci. Res. 2009, 5, 858–863. [Google Scholar]
  88. Ezz, A.; Aziz, E.; Hendawy, S.; Omer, E. Response of Thymus vulgaris L. to Salt Stress and Alar (B ) in Newly Reclaimed Soil. J. Appl. Sci. Res. 2009, 5, 2165–2170. [Google Scholar]
  89. Khadhri, A.; Neffati, M.; Smiti, S.; Nogueira, J.M.F.; Araujo, M.E.M. Influence of Salt Stress on Essential Oil Yield and Composition of Lemon Grass (Cymbopogon schoenanthus L. Spreng. Ssp. Laniger (Hook) Maire et Weil). Nat. Prod. Res. 2011, 25, 108–117. [Google Scholar] [CrossRef]
  90. Elhindi, K.M.; Al-Suhaibani, N.A.; El-Din, A.F.S.; Yakout, S.M.; Al-Amri, S.M. Effect of Foliar-Applied Iron and Zinc on Growth Rate and Essential Oil in Sweet Basil (Ocimum basilicum L.) under Saline Conditions. Prog. Nutr. 2016, 18, 288–298. [Google Scholar]
  91. Kordali, S.; Cakir, A.; Mavi, A.; Kilic, H.; Yildirim, A. Screening of Chemical Composition and Antifungal and Antioxidant Activities of the Essential Oils from Three Turkish Artemisia Species. J. Agric. Food Chem. 2005, 53, 1408–1416. [Google Scholar] [CrossRef] [PubMed]
  92. Allakhverdiev, S.I.; Kreslavski, V.D.; Klimov, V.V.; Los, D.A.; Carpentier, R.; Mohanty, P. Heat Stress: An Overview of Molecular Responses in Photosynthesis. Photosynth. Res. 2008, 98, 541. [Google Scholar] [CrossRef]
  93. Wahid, A.; Gelani, S.; Ashraf, M.; Foolad, M.R. Heat Tolerance in Plants: An Overview. Environ. Exp. Bot. 2007, 61, 199–223. [Google Scholar] [CrossRef]
  94. Bita, C.; Gerats, T. Plant Tolerance to High Temperature in a Changing Environment: Scientific Fundamentals and Production of Heat Stress-Tolerant Crops. Front. Plant Sci. 2013, 4, 273. [Google Scholar] [CrossRef] [PubMed]
  95. Al-Huqail, A.; El-Dakak, R.M.; Sanad, M.N.; Badr, R.H.; Ibrahim, M.M.; Soliman, D.; Khan, F. Effects of Climate Temperature and Water Stress on Plant Growth and Accumulation of Antioxidant Compounds in Sweet Basil (Ocimum basilicum L.) Leafy Vegetable. Scientifica 2020, 2020, 3808909. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  96. Nourimand, M.; Mohsenzadeh, S.; Teixeira da Silva, J. Physiological Responses of Fennel Seedling to Four Environmental Stresses. Iran. J. Sci. Technol. Trans. Sci. 2012, 36, 37–46. [Google Scholar] [CrossRef]
  97. Ebrahimi, A.; Moaveni, P.; Dashtbozorg, A.T.; Farahani, H. Effects of Temperature and Varieties on Essential Oil Content and Quantity Features of Chamomile. J. Agric. Ext. Rural. Dev. 2011, 3, 19–22. [Google Scholar]
  98. Nguyen, C.T.T.; Nguyen, N.H.; Choi, W.S.; Lee, J.H.; Cheong, J.-J. Biosynthesis of Essential Oil Compounds in Ocimum tenuiflorum Is Induced by Abiotic Stresses. Plant Biosyst. Int. J. Deal. Asp. Plant Biol. 2020, 156, 353–357. [Google Scholar] [CrossRef]
  99. Jochum, G.M.; Mudge, K.W.; Thomas, R.B. Elevated Temperatures Increase Leaf Senescence and Root Secondary Metabolite Concentrations in the Understory Herb Panax quinquefolius (Araliaceae). Am. J. Bot. 2007, 94, 819–826. [Google Scholar] [CrossRef]
  100. Lawlor, D.W.; Cornic, G. Photosynthetic Carbon Assimilation and Associated Metabolism in Relation to Water Deficits in Higher Plants. Plant Cell Environ. 2002, 25, 275–294. [Google Scholar] [CrossRef]
  101. Tardieu, F.; Granier, C.; Muller, B. Water Deficit and Growth. Co-Ordinating Processes without an Orchestrator? Curr. Opin. Plant Biol. 2011, 14, 283–289. [Google Scholar] [CrossRef]
  102. Bagheri, R.; Dehdari, M.; Salehi, A. Effect of Cold Stress at Flowering Stage on Some Important Characters of Five German Chamomile (Matricaria chamomilla L.) Genotypes in a Pot Experiment. J. Appl. Res. Med. Aromat. Plants 2020, 16, 100228. [Google Scholar] [CrossRef]
  103. Rastogi, S.; Shah, S.; Kumar, R.; Vashisth, D.; Akhtar, M.Q.; Kumar, A.; Dwivedi, U.N.; Shasany, A.K. Ocimum Metabolomics in Response to Abiotic Stresses: Cold, Flood, Drought and Salinity. PLoS ONE 2019, 14, e0210903. [Google Scholar] [CrossRef] [PubMed]
  104. Franklin, K.A.; Larner, V.S.; Whitelam, G.C. The Signal Transducing Photoreceptors of Plants. Int. J. Dev. Biol. 2004, 49, 653–664. [Google Scholar] [CrossRef] [PubMed]
  105. Eckstein, A.; Zięba, P.; Gabryś, H. Sugar and Light Effects on the Condition of the Photosynthetic Apparatus of Arabidopsis thaliana Cultured in Vitro. J. Plant Growth Regul. 2012, 31, 90–101. [Google Scholar] [CrossRef]
  106. Chen, M.; Chory, J.; Fankhauser, C. Light Signal Transduction in Higher Plants. Annu. Rev. Genet. 2004, 38, 87–117. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  107. Casal, J.J.; Yanovsky, M.J. Regulation of Gene Expression by Light. Int. J. Dev. Biol. 2005, 49, 501–511. [Google Scholar] [CrossRef] [PubMed]
  108. Bayat, L.; Arab, M.; Aliniaeifard, S.; Seif, M.; Lastochkina, O.; Li, T. Effects of Growth under Different Light Spectra on the Subsequent High Light Tolerance in Rose Plants. AoB Plants 2018, 10, ply052. [Google Scholar] [CrossRef]
  109. Sabzalian, M.R.; Heydarizadeh, P.; Zahedi, M.; Boroomand, A.; Agharokh, M.; Sahba, M.R.; Schoefs, B. High Performance of Vegetables, Flowers, and Medicinal Plants in a Red-Blue LED Incubator for Indoor Plant Production. Agron. Sustain. Dev. 2014, 34, 879–886. [Google Scholar] [CrossRef]
  110. Ahmadi, T.; Shabani, L.; Sabzalian, M.R. LED Light Sources Improved the Essential Oil Components and Antioxidant Activity of Two Genotypes of Lemon Balm (Melissa officinalis L.). Bot. Stud. 2021, 62, 9. [Google Scholar] [CrossRef]
  111. Naznin, M.T.; Lefsrud, M.; Gravel, V.; Hao, X. Different Ratios of Red and Blue LED Light Effects on Coriander Productivity and Antioxidant Properties. Acta Hortic. 2016. [Google Scholar] [CrossRef]
  112. Amaki, W.; Yamazaki, N.; Ichimura, M.; Watanabe, H. Effects of Light Quality on the Growth and Essential Oil Content in Sweet Basil. Acta Hortic. 2011, 907, 91–94. [Google Scholar] [CrossRef]
  113. Maffei, M.; Scannerini, S. Photomorphogenic and Chemical Responses to Blue Light in Mentha Piperita. J. Essent. Oil Res. 1999, 11, 730–738. [Google Scholar] [CrossRef]
  114. Schoefs, B. Chlorophyll and Carotenoid Analysis in Food Products. Properties of the Pigments and Methods of Analysis. Trends Food Sci. Technol. 2002, 13, 361–371. [Google Scholar] [CrossRef]
  115. Darko, E.; Heydarizadeh, P.; Schoefs, B.; Sabzalian, M.R. Photosynthesis under Artificial Light: The Shift in Primary and Secondary Metabolism. Philos. Trans. R. Soc. Lond. B. Biol. Sci. 2014, 369, 20130243. [Google Scholar] [CrossRef] [PubMed]
  116. Schwartz, A.; Zeiger, E. Metabolic Energy for Stomatal Opening. Roles of Photophosphorylation and Oxidative Phosphorylation. Planta 1984, 161, 129–136. [Google Scholar] [CrossRef] [PubMed]
  117. Goins, G.D.; Yorio, N.C.; Sanwo-Lewandowski, M.M.; Brown, C.S. Life Cycle Experiments with Arabidopsis Grown under Red Light-Emitting Diodes (LEDS). Life Support Biosph. Sci. 1998, 5, 143–149. [Google Scholar]
  118. Fernandes, V.F.; de Almeida, L.B.; Feijó, E.V.R.d.S.; Silva, D.d.C.; de Oliveira, R.A.; Mielke, M.S.; Costa, L.C.d.B. Light Intensity on Growth, Leaf Micromorphology and Essential Oil Production of Ocimum gratissimum. Rev. Bras. Farmacogn. 2013, 23, 419–424. [Google Scholar] [CrossRef]
  119. Dou, H.; Niu, G.; Gu, M.; Masabni, J.G. Effects of Light Quality on Growth and Phytonutrient Accumulation of Herbs under Controlled Environments. Horticulturae 2017, 3, 36. [Google Scholar] [CrossRef]
  120. Sakalauskaitė, J.; Viskelis, P.; Duchovskis, P.; Dambrauskienė, E.; Sakalauskienė, S.; Samuoliene, G.; Brazaitytė, A. Supplementary UV-B Irradiation Effects on Basil (Ocimum basilicum L.) Growth and Phytochemical Properties. J. Food Agric. Environ. 2012, 10, 342–346. [Google Scholar]
  121. Johnson, C.B.; Kirby, J.; Naxakis, G.; Pearson, S. Substantial UV-B-Mediated Induction of Essential Oils in Sweet Basil (Ocimum basilicum L.). Phytochemistry 1999, 51, 507–510. [Google Scholar] [CrossRef]
  122. Hikosaka, S.; Ito, K.; Goto, E. Effects of Ultraviolet Light on Growth, Essential Oil Concentration, and Total Antioxidant Capacity of Japanese Mint. Environ. Control Biol. 2010, 48, 185–190. [Google Scholar] [CrossRef]
  123. Karousou, R.; Grammatikopoulos, G.; Lanaras, T.; Manetas, Y.; Kokkini, S. Effects of Enhanced UV-B Radiation on Mentha Spicata Essential Oils. Phytochemistry 1998, 49, 2273–2277. [Google Scholar] [CrossRef]
  124. Maffei, M.; Scannerini, S. UV-B Effect on Photomorphogenesis and Essential Oil Composition in Peppermint (Mentha piperita L.). J. Essent. Oil Res. 2000, 12, 523–529. [Google Scholar] [CrossRef]
  125. Pandey, J.; Verma, R.K.; Singh, S. Suitability of Aromatic Plants for Phytoremediation of Heavy Metal Contaminated Areas: A Review. Int. J. Phytoremediat. 2019, 21, 405–418. [Google Scholar] [CrossRef] [PubMed]
  126. Sarma, H.; Deka, S.; Deka, H.; Saikia, R.R. Accumulation of Heavy Metals in Selected Medicinal Plants. Rev. Environ. Contam. Toxicol. 2011, 214, 63–86. [Google Scholar] [CrossRef]
  127. Yan, A.; Wang, Y.; Tan, S.N.; Mohd Yusof, M.L.; Ghosh, S.; Chen, Z. Phytoremediation: A Promising Approach for Revegetation of Heavy Metal-Polluted Land. Front. Plant Sci. 2020, 11, 359. [Google Scholar] [CrossRef]
  128. Gong, Y.; Zhao, D.; Wang, Q. An Overview of Field-Scale Studies on Remediation of Soil Contaminated with Heavy Metals and Metalloids: Technical Progress over the Last Decade. Water Res. 2018, 147, 440–460. [Google Scholar] [CrossRef]
  129. Lin, Y.; Xiao, W.; Ye, Y.; Wu, C.; Hu, Y.; Shi, H. Adaptation of Soil Fungi to Heavy Metal Contamination in Paddy Fields—a Case Study in Eastern China. Environ. Sci. Pollut. Res. 2020, 27, 27819–27830. [Google Scholar] [CrossRef]
  130. Stancheva, I.; Geneva, M.; Hristozkova, M.; Boychinova, M.; Markovska, Y. Essential Oil Variation of Salvia officinalis (L.), Grown on Heavy Metals Polluted Soil. Biotechnol. Biotechnol. Equip. 2009, 23, 373–376. [Google Scholar] [CrossRef]
  131. Prasad, A.; Singh, A.K.; Chand, S.; Chanotiya, C.S.; Patra, D.D. Effect of Chromium and Lead on Yield, Chemical Composition of Essential Oil, and Accumulation of Heavy Metals of Mint Species. Commun. Soil Sci. Plant Anal. 2010, 41, 2170–2186. [Google Scholar] [CrossRef]
  132. Chand, S.; Kumari, R.; Patra, D.D. Effect of Nickel and Vermicompost on Growth, Yield, Accumulation of Heavy Metals and Essential Oil Quality of Tagetes minuta. J. Essent. Oil Bear. Plants 2015, 18, 767–774. [Google Scholar] [CrossRef]
  133. Zheljazkov, V.D.; Jeliazkova, E.A.; Kovacheva, N.; Dzhurmanski, A. Metal Uptake by Medicinal Plant Species Grown in Soils Contaminated by a Smelter. Environ. Exp. Bot. 2008, 64, 207–216. [Google Scholar] [CrossRef]
  134. Siddiqui, F.; Krishna, S.; Tandon, P.; Srivastava, S. Arsenic Accumulation in Ocimum Spp. and Its Effect on Growth and Oil Constituents. Acta Physiol. Plant. 2012, 35, 1071–1079. [Google Scholar] [CrossRef]
  135. Zheljazkov, V.D.; Craker, L.E.; Xing, B. Effects of Cd, Pb, and Cu on Growth and Essential Oil Contents in Dill, Peppermint, and Basil. Environ. Exp. Bot. 2006, 58, 9–16. [Google Scholar] [CrossRef]
  136. Raveau, R.; Fontaine, J.; Bert, V.; Perlein, A.; Tisserant, B.; Ferrant, P.; Lounès - Hadj Sahraoui, A. In Situ Cultivation of Aromatic Plant Species for the Phytomanagement of an Aged-Trace Element Polluted Soil: Plant Biomass Improvement Options and Techno-Economic Assessment of the Essential Oil Production Channel. Sci. Total Environ. 2021, 789, 147944. [Google Scholar] [CrossRef]
  137. Stancheva, I.; Geneva, M.; Boychinova, M.; Mitova, I.; Markovska, Y. Physiological Response of Foliar Fertilized Matricaria recutita L. Grown on Industrially Polluted Soil. J. Plant Nutr. 2014, 37, 1952–1964. [Google Scholar] [CrossRef]
  138. Sá, R.A.; Sá, R.A.; Alberton, O.; Gazim, Z.C.; Laverde, A., Jr.; Caetano, J.; Amorin, A.C.; Dragunski, D.C. Phytoaccumulation and Effect of Lead on Yield and Chemical Composition of Mentha crispa Essential Oil. Desalination Water Treat. 2015, 53, 3007–3017. [Google Scholar] [CrossRef]
  139. Ali, B.; Song, W.J.; Hu, W.Z.; Luo, X.N.; Gill, R.A.; Wang, J.; Zhou, W.J. Hydrogen Sulfide Alleviates Lead-Induced Photosynthetic and Ultrastructural Changes in Oilseed Rape. Ecotoxicol. Environ. Saf. 2014, 102, 25–33. [Google Scholar] [CrossRef]
  140. Zhang, J.; Duan, G.-L. Genotypic Difference in Arsenic and Cadmium Accumulation by Rice Seedlings Grown in Hydroponics. J. Plant Nutr. 2008, 31, 2168–2182. [Google Scholar] [CrossRef]
  141. Dwivedi, S.; Tripathi, R.D.; Srivastava, S.; Singh, R.; Kumar, A.; Tripathi, P.; Dave, R.; Rai, U.N.; Chakrabarty, D.; Trivedi, P.K.; et al. Arsenic Affects Mineral Nutrients in Grains of Various Indian Rice (Oryza sativa L.) Genotypes Grown on Arsenic-Contaminated Soils of West Bengal. Protoplasma 2010, 245, 113–124. [Google Scholar] [CrossRef]
  142. Finnegan, P.; Chen, W. Arsenic Toxicity: The Effects on Plant Metabolism. Front. Physiol. 2012, 3, 182. [Google Scholar] [CrossRef]
  143. Haider, F.U.; Liqun, C.; Coulter, J.A.; Cheema, S.A.; Wu, J.; Zhang, R.; Wenjun, M.; Farooq, M. Cadmium Toxicity in Plants: Impacts and Remediation Strategies. Ecotoxicol. Environ. Saf. 2021, 211, 111887. [Google Scholar] [CrossRef] [PubMed]
  144. Llamas, A.; Ullrich, C.I.; Sanz, A. Cd2+ Effects on Transmembrane Electrical Potential Difference, Respiration and Membrane Permeability of Rice (Oryza sativa L) Roots. Plant Soil 2000, 219, 21–28. [Google Scholar] [CrossRef]
  145. Perfus-Barbeoch, L.; Leonhardt, N.; Vavasseur, A.; Forestier, C. Heavy Metal Toxicity: Cadmium Permeates through Calcium Channels and Disturbs the Plant Water Status. Plant J. 2002, 32, 539–548. [Google Scholar] [CrossRef] [PubMed]
  146. Dong, D.; Zhao, X.; Hua, X.; Liu, J.; Gao, M. Investigation of the Potential Mobility of Pb, Cd and Cr(VI) from Moderately Contaminated Farmland Soil to Groundwater in Northeast, China. J. Hazard. Mater. 2009, 162, 1261–1268. [Google Scholar] [CrossRef]
  147. Kılıc, S.; Kılıc, M. Effects of Cadmium-Induced Stress on Essential Oil Production, Morphology and Physiology of Lemon Balm (Melissa officinalis L., Lamiaceae). Appl. Ecol. Environ. Res. 2017, 15, 1653–1669. [Google Scholar] [CrossRef]
  148. Fattahi, B.; Arzani, K.; Souri, M.K.; Barzegar, M. Effects of Cadmium and Lead on Seed Germination, Morphological Traits, and Essential Oil Composition of Sweet Basil (Ocimum basilicum L.). Ind. Crops Prod. 2019, 138, 111584. [Google Scholar] [CrossRef]
  149. Biswas, S. Effect of Arsenic on Trichome Ultrastructure, Essential Oil Yield and Quality of Ocimum basilicum L. Med. Plant Res. 2015, 5, 6. [Google Scholar] [CrossRef]
  150. Jezler, C.N.; Mangabeira, P.A.O.; Almeida, A.-A.F.d.; Jesus, R.M.d.; Oliveira, R.A.; de Silva, D.d.C.; Costa, L.C.d.B. Pb and Cd on Growth, Leaf Ultrastructure and Essential Oil Yield Mint (Mentha arvensis L.). Ciênc. Rural 2015, 45, 392–398. [Google Scholar] [CrossRef]
  151. Chen, Y.; Shen, Z.G.; Li, X.-D. The Use of Vetiver Grass (Vetiveria zizanioides) in the Phytoremediation of Soils Contaminated with Heavy Metals. Appl. Geochem. 2004, 19, 1553–1565. [Google Scholar] [CrossRef]
  152. Shahid, M.; Arshad, M.; Kaemmerer, M.; Pinelli, E.; Probst, A.; Baque, D.; Pradere, P.; Dumat, C. Long-Term Field Metal Extraction by Pelargonium: Phytoextraction Efficiency in Relation to Plant Maturity. Int. J. Phytoremediat. 2012, 14, 493–505. [Google Scholar] [CrossRef]
  153. Akoumianaki-Ioannidou, A.; Papadimitriou, K.; Barouchas, P.; Moustakas, N. The Effects of Cd and Zn Interactions on the Concentration of Cd and Zn in Sweet Bush Basil (Ocimum basilicum L.) and Peppermint (Mentha piperita L.). Fresenius Environ. Bull. 2015, 24, 77–83. [Google Scholar]
  154. Angelova, V.R.; Grekov, D.F.; Kisyov, V.K.; Ivanov, K.I. Potential of Lavender (Lavandula vera L.) for Phytoremediation of Soils Contaminated with Heavy Metals. Int. J. Agric. Biosyst. Eng. 2015, 9, 522–529. [Google Scholar] [CrossRef]
  155. Angelova, V.R.; Ivanova, R.V.; Todorov, G.M.; Ivanov, K.I. Potential of Salvia Sclarea L. for Phytoremediation of Soils Contaminated with Heavy Metals. Int. J. Agric. Biosyst. Eng. 2016, 10, 780–790. [Google Scholar]
  156. Divrikli, U.; Horzum, N.; Soylak, M.; Elci, L. Trace Heavy Metal Contents of Some Spices and Herbal Plants from Western Anatolia-Turkey. Int. J. Food Sci. Technol. 2006, 41, 712–716. [Google Scholar] [CrossRef]
  157. Perlein, A.; Zdanevitch, I.; Gaucher, R.; Robinson, B.; Papin, A.; Lounès-Hadj Sahraoui, A.; Bert, V. Phytomanagement of a Metal(Loid)-Contaminated Agricultural Site Using Aromatic and Medicinal Plants to Produce Essential Oils: Analysis of the Metal(Loid) Fate in the Value Chain. Environ. Sci. Pollut. Res. Int. 2021, 28, 62155–62173. [Google Scholar] [CrossRef]
  158. Pandey, J.; Chand, S.; Pandey, S.; Rajkumari; Patra, D.D. Palmarosa [Cymbopogon martinii (Roxb.) Wats.] as a Putative Crop for Phytoremediation, in Tannery Sludge Polluted Soil. Ecotoxicol. Environ. Saf. 2015, 122, 296–302. [Google Scholar] [CrossRef]
  159. Affholder, M.-C.; Prudent, P.; Masotti, V.; Coulomb, B.; Rabier, J.; Nguyen-The, B.; Laffont-Schwob, I. Transfer of Metals and Metalloids from Soil to Shoots in Wild Rosemary (Rosmarinus officinalis L.) Growing on a Former Lead Smelter Site: Human Exposure Risk. Sci. Total Environ. 2013, 454–455, 219–229. [Google Scholar] [CrossRef]
  160. Madejón, P.; Burgos, P.; Cabrera, F.; Madejón, E. Phytostabilization of Amended Soils Polluted with Trace Elements Using the Mediterranean Shrub: Rosmarinus officinalis. Int. J. Phytoremediat. 2009, 11, 542–557. [Google Scholar] [CrossRef] [Green Version]
  161. Singh, S.; Parihar, P.; Singh, R.; Singh, V.P.; Prasad, S.M. Heavy Metal Tolerance in Plants: Role of Transcriptomics, Proteomics, Metabolomics, and Ionomics. Front. Plant Sci. 2016, 6, 1143. [Google Scholar] [CrossRef]
  162. Rizvi, A.; Zaidi, A.; Ameen, F.; Ahmed, B.; AlKahtani, M.D.F.; Khan, M.S. Heavy Metal Induced Stress on Wheat: Phytotoxicity and Microbiological Management. RSC Adv. 2020, 10, 38379–38403. [Google Scholar] [CrossRef]
  163. Freeman, J.L.; Persans, M.W.; Nieman, K.; Albrecht, C.; Peer, W.; Pickering, I.J.; Salt, D.E. Increased Glutathione Biosynthesis Plays a Role in Nickel Tolerance in Thlaspi Nickel Hyperaccumulators [W]. Plant Cell 2004, 16, 2176–2191. [Google Scholar] [CrossRef] [PubMed]
  164. Mithöfer, A.; Schulze, B.; Boland, W. Biotic and Heavy Metal Stress Response in Plants: Evidence for Common Signals. FEBS Lett. 2004, 566, 1–5. [Google Scholar] [CrossRef]
  165. Yadav, S.K. Heavy Metals Toxicity in Plants: An Overview on the Role of Glutathione and Phytochelatins in Heavy Metal Stress Tolerance of Plants. South Afr. J. Bot. 2010, 76, 167–179. [Google Scholar] [CrossRef]
  166. Manoharan, P.; Vellasamy, S.; Balasubramanian, N.; Gomathinayagam, S.; Sharma, M.; Muthuchelian, K. Influence of AM Fungi on the Growth and Physiological Status of Erythrina variegata Linn. Grown under Different Water Stress Conditions. Eur. J. Soil Biol. 2010, 46, 151–156. [Google Scholar] [CrossRef]
  167. Smith, S.E.; Smith, F.A. Roles of Arbuscular Mycorrhizas in Plant Nutrition and Growth: New Paradigms from Cellular to Ecosystem Scales. Annu. Rev. Plant Biol. 2011, 62, 227–250. [Google Scholar] [CrossRef]
  168. Jia, P.; Liu, H.; Gao, T.; Xin, H. Glandular Trichomes and Essential Oil of Thymus quinquecostatus. Sci. World J. 2013, 2013, e387952. [Google Scholar] [CrossRef]
  169. Rehman, R.; Hanif, M.A.; Mushtaq, Z.; Mochona, B.; Qi, X. Biosynthetic Factories of Essential Oils: The Aromatic Plants. Nat. Prod. Chem. Res. 2016, 4, 1000227. [Google Scholar] [CrossRef]
  170. Morone-Fortunato, I.; Avato, P. Plant Development and Synthesis of Essential Oils in Micropropagated and Mycorrhiza Inoculated Plants of Origanum vulgare L. Ssp. Hirtum (Link) Ietswaart. Plant Cell Tissue Organ Cult. 2008, 93, 139. [Google Scholar] [CrossRef]
  171. Copetta, A.; Lingua, G.; Berta, G. Effects of Three AM Fungi on Growth, Distribution of Glandular Hairs, and Essential Oil Production in Ocimum basilicum L. Var. Genovese. Mycorrhiza 2006, 16, 485–494. [Google Scholar] [CrossRef]
  172. Kapoor, R.; Chaudhary, V.; Bhatnagar, A.K. Effects of Arbuscular Mycorrhiza and Phosphorus Application on Artemisinin Concentration in Artemisia annua L. Mycorrhiza 2007, 17, 581–587. [Google Scholar] [CrossRef]
  173. Amiri, R.; Nikbakht, A.; Etemadi, N.; Sabzalian, M.R. Nutritional Status, Essential Oil Changes and Water-Use Efficiency of Rose geranium in Response to Arbuscular Mycorrhizal Fungi and Water Deficiency Stress. Symbiosis 2017, 73, 15–25. [Google Scholar] [CrossRef]
  174. Prasad, A.; Kumar, S.; Khaliq, A.; Pandey, A. Heavy Metals and Arbuscular Mycorrhizal (AM) Fungi Can Alter the Yield and Chemical Composition of Volatile Oil of Sweet Basil (Ocimum basilicum L.). Biol. Fertil. Soils 2011, 47, 853–861. [Google Scholar] [CrossRef]
  175. Mozafar, A.; Ruh, R.; Klingel, P.; Gamper, H.; Egli, S.; Frossard, E. Effect of Heavy Metal Contaminated Shooting Range Soils on Mycorrhizal Colonization of Roots and Metal Uptake by Leek. Environ. Monit. Assess. 2002, 79, 177–191. [Google Scholar] [CrossRef]
  176. Dhalaria, R.; Kumar, D.; Kumar, H.; Nepovimova, E.; Kuča, K.; Torequl Islam, M.; Verma, R. Arbuscular Mycorrhizal Fungi as Potential Agents in Ameliorating Heavy Metal Stress in Plants. Agronomy 2020, 10, 815. [Google Scholar] [CrossRef]
  177. Tavarini, S.; Passera, B.; Martini, A.; Avio, L.; Sbrana, C.; Giovannetti, M.; Angelini, L.G. Plant Growth, Steviol Glycosides and Nutrient Uptake as Affected by Arbuscular Mycorrhizal Fungi and Phosphorous Fertilization in Stevia Rebaudiana Bert. Ind. Crops Prod. 2018, 111, 899–907. [Google Scholar] [CrossRef]
  178. Lazzara, S.; Militello, M.; Carrubba, A.; Napoli, E.; Saia, S. Arbuscular Mycorrhizal Fungi Altered the Hypericin, Pseudohypericin, and Hyperforin Content in Flowers of Hypericum Perforatum Grown under Contrasting P Availability in a Highly Organic Substrate. Mycorrhiza 2017, 27, 345–354. [Google Scholar] [CrossRef]
  179. Pozo, M.J.; Van Loon, L.C.; Pieterse, C.M.J. Jasmonates—Signals in Plant-Microbe Interactions. J. Plant Growth Regul. 2004, 23, 211–222. [Google Scholar] [CrossRef]
  180. Gheisari Zardak, S.; Movahhedi Dehnavi, M.; Salehi, A.; Gholamhoseini, M. Responses of Field Grown Fennel (Foeniculum vulgare Mill.) to Different Mycorrhiza Species under Varying Intensities of Drought Stress. J. Appl. Res. Med. Aromat. Plants 2017, 5, 16–25. [Google Scholar] [CrossRef]
  181. Zhang, T.; Hu, Y.; Zhang, K.; Tian, C.; Guo, J. Arbuscular Mycorrhizal Fungi Improve Plant Growth of Ricinus communis by Altering Photosynthetic Properties and Increasing Pigments under Drought and Salt Stress. Ind. Crops Prod. 2018, 117, 13–19. [Google Scholar] [CrossRef]
  182. Asrar, A.-W.A.; Elhindi, K.M. Alleviation of Drought Stress of Marigold (Tagetes erecta) Plants by Using Arbuscular Mycorrhizal Fungi. Saudi J. Biol. Sci. 2011, 18, 93–98. [Google Scholar] [CrossRef]
  183. Giri, B.; Kapoor, R.; Mukerji, K.G. Improved Tolerance of Acacia Nilotica to Salt Stress by Arbuscular Mycorrhiza, Glomus Fasciculatum May Be Partly Related to Elevated K/Na Ratios in Root and Shoot Tissues. Microb. Ecol. 2007, 54, 753–760. [Google Scholar] [CrossRef] [PubMed]
  184. Alqarawi, A.A.; Abd Allah, E.F.; Hashem, A. Alleviation of Salt-Induced Adverse Impact via Mycorrhizal Fungi in Ephedra Aphylla Forssk. J. Plant Interact. 2014, 9, 802–810. [Google Scholar] [CrossRef]
  185. Wang, Y.; Wang, M.; Li, Y.; Wu, A.; Huang, J. Effects of Arbuscular Mycorrhizal Fungi on Growth and Nitrogen Uptake of Chrysanthemum morifolium under Salt Stress. PLoS ONE 2018, 13, e0196408. [Google Scholar] [CrossRef]
  186. Maya, M.A.; Matsubara, Y. Influence of Arbuscular Mycorrhiza on the Growth and Antioxidative Activity in Cyclamen under Heat Stress. Mycorrhiza 2013, 23, 381–390. [Google Scholar] [CrossRef] [PubMed]
  187. Abdelhameed, R.E.; Metwally, R.A. Alleviation of Cadmium Stress by Arbuscular Mycorrhizal Symbiosis. Int. J. Phytoremediation 2019, 21, 663–671. [Google Scholar] [CrossRef]
  188. Mandal, S.; Upadhyay, S.; Wajid, S.; Ram, M.; Jain, D.C.; Singh, V.P.; Abdin, M.Z.; Kapoor, R. Arbuscular Mycorrhiza Increase Artemisinin Accumulation in Artemisia Annua by Higher Expression of Key Biosynthesis Genes via Enhanced Jasmonic Acid Levels. Mycorrhiza 2015, 25, 345–357. [Google Scholar] [CrossRef]
  189. Li, H.; Xu, L.; Li, Z.; Zhao, S.; Guo, D.; Rui, L.; Zhou, N. Mycorrhizas Affect Polyphyllin Accumulation of Paris Polyphylla var. Yunnanensis through Promoting PpSE Expression. Phyton 2021, 90, 1535–1547. [Google Scholar] [CrossRef]
  190. Duc, N.H.; Vo, A.T.; Haddidi, I.; Daood, H.; Posta, K. Arbuscular Mycorrhizal Fungi Improve Tolerance of the Medicinal Plant Eclipta prostrata (L.) and Induce Major Changes in Polyphenol Profiles Under Salt Stresses. Front. Plant Sci. 2021, 11, 612299. [Google Scholar] [CrossRef]
  191. Liu, F.; Xu, Y.; Han, G.; Wang, W.; Li, X.; Cheng, B. Identification and Functional Characterization of a Maize Phosphate Transporter Induced by Mycorrhiza Formation. Plant Cell Physiol. 2018, 59, 1683–1694. [Google Scholar] [CrossRef]
  192. Delaux, P.-M.; Séjalon-Delmas, N.; Bécard, G.; Ané, J.-M. Evolution of the Plant–Microbe Symbiotic ‘Toolkit. ’ Trends Plant Sci. 2013, 18, 298–304. [Google Scholar] [CrossRef]
  193. Volpe, V.; Chitarra, W.; Cascone, P.; Volpe, M.G.; Bartolini, P.; Moneti, G.; Pieraccini, G.; Di Serio, C.; Maserti, B.; Guerrieri, E.; et al. The Association With Two Different Arbuscular Mycorrhizal Fungi Differently Affects Water Stress Tolerance in Tomato. Front. Plant Sci. 2018, 9, 1480. [Google Scholar] [CrossRef] [PubMed]
  194. Balestrini, R.; Rosso, L.C.; Veronico, P.; Melillo, M.T.; De Luca, F.; Fanelli, E.; Colagiero, M.; di Fossalunga, A.S.; Ciancio, A.; Pentimone, I. Transcriptomic Responses to Water Deficit and Nematode Infection in Mycorrhizal Tomato Roots. Front. Microbiol. 2019, 10, 1807. [Google Scholar] [CrossRef] [PubMed]
  195. Sato, T.; Ezawa, T.; Cheng, W.; Tawaraya, K. Release of Acid Phosphatase from Extraradical Hyphae of Arbuscular Mycorrhizal Fungus Rhizophagus Clarus. Soil Sci. Plant Nutr. 2015, 61, 269–274. [Google Scholar] [CrossRef]
  196. Augé, R. Arbuscular Mycorrhizae and Soil/Plant Water Relations. Can. J. Soil Sci. 2004, 84, 373–381. [Google Scholar] [CrossRef]
  197. Bowles, T.M.; Jackson, L.E.; Cavagnaro, T.R. Mycorrhizal Fungi Enhance Plant Nutrient Acquisition and Modulate Nitrogen Loss with Variable Water Regimes. Glob. Change Biol. 2018, 24, e171–e182. [Google Scholar] [CrossRef]
  198. Augé, R.M.; Stodola, A.J.W.; Tims, J.E.; Saxton, A.M. Moisture Retention Properties of a Mycorrhizal Soil. Plant Soil 2001, 230, 87–97. [Google Scholar] [CrossRef]
  199. Augé, R.M.; Toler, H.D.; Sams, C.E.; Nasim, G. Hydraulic Conductance and Water Potential Gradients in Squash Leaves Showing Mycorrhiza-Induced Increases in Stomatal Conductance. Mycorrhiza 2008, 18, 115–121. [Google Scholar] [CrossRef]
  200. Neumann, E.; Schmid, B.; Römheld, V.; George, E. Extraradical Development and Contribution to Plant Performance of an Arbuscular Mycorrhizal Symbiosis Exposed to Complete or Partial Rootzone Drying. Mycorrhiza 2009, 20, 13–23. [Google Scholar] [CrossRef]
  201. Bowles, T.M.; Barrios-Masias, F.H.; Carlisle, E.A.; Cavagnaro, T.R.; Jackson, L.E. Effects of Arbuscular Mycorrhizae on Tomato Yield, Nutrient Uptake, Water Relations, and Soil Carbon Dynamics under Deficit Irrigation in Field Conditions. Sci. Total Environ. 2016, 566–567, 1223–1234. [Google Scholar] [CrossRef]
  202. Marulanda, A.; Azcón, R.; Ruiz-Lozano, J.M. Contribution of Six Arbuscular Mycorrhizal Fungal Isolates to Water Uptake by Lactuca Sativa Plants under Drought Stress. Physiol. Plant. 2003, 119, 526–533. [Google Scholar] [CrossRef]
  203. Ouziad, F.; Wilde, P.; Schmelzer, E.; Hildebrandt, U.; Bothe, H. Analysis of Expression of Aquaporins and Na+/H+ Transporters in Tomato Colonized by Arbuscular Mycorrhizal Fungi and Affected by Salt Stress. Environ. Exp. Bot. 2006, 57, 177–186. [Google Scholar] [CrossRef]
  204. Luu, D.-T.; Maurel, C. Aquaporins in a Challenging Environment: Molecular Gears for Adjusting Plant Water Status. Plant Cell Environ. 2005, 28, 85–96. [Google Scholar] [CrossRef]
  205. Maurel, C.; Verdoucq, L.; Luu, D.-T.; Santoni, V. Plant Aquaporins: Membrane Channels with Multiple Integrated Functions. Annu. Rev. Plant Biol. 2008, 59, 595–624. [Google Scholar] [CrossRef] [PubMed]
  206. Maurel, C.; Boursiac, Y.; Luu, D.-T.; Santoni, V.; Shahzad, Z.; Verdoucq, L. Aquaporins in Plants. Physiol. Rev. 2015, 95, 1321–1358. [Google Scholar] [CrossRef]
  207. Li, G.; Santoni, V.; Maurel, C. Plant Aquaporins: Roles in Plant Physiology. Biochim. Biophys. Acta BBA Gen. Subj. 2014, 1840, 1574–1582. [Google Scholar] [CrossRef]
  208. Aroca, R.; Porcel, R.; Ruiz-Lozano, J.M. How Does Arbuscular Mycorrhizal Symbiosis Regulate Root Hydraulic Properties and Plasma Membrane Aquaporins in Phaseolus vulgaris under Drought, Cold or Salinity Stresses? New Phytol. 2007, 173, 808–816. [Google Scholar] [CrossRef]
  209. Jahromi, F.; Aroca, R.; Porcel, R.; Ruiz-Lozano, J.M. Influence of Salinity on the In Vitro Development of Glomus intraradices and on the In Vivo Physiological and Molecular Responses of Mycorrhizal Lettuce Plants. Microb. Ecol. 2007, 55, 45. [Google Scholar] [CrossRef]
  210. Porcel, R.; Aroca, R.; Azcón, R.; Ruiz-Lozano, J.M. PIP Aquaporin Gene Expression in Arbuscular Mycorrhizal Glycine max and Lactuca sativa Plants in Relation to Drought Stress Tolerance. Plant Mol. Biol. 2006, 60, 389–404. [Google Scholar] [CrossRef]
  211. Xu, H.; Cooke, J.E.K.; Kemppainen, M.; Pardo, A.G.; Zwiazek, J.J. Hydraulic Conductivity and Aquaporin Transcription in Roots of Trembling Aspen (Populus tremuloides) Seedlings Colonized by Laccaria bicolor. Mycorrhiza 2016, 26, 441–451. [Google Scholar] [CrossRef]
  212. Sun, R.-T.; Zhang, Z.-Z.; Feng, X.-C.; Zhou, N.; Feng, H.-D.; Liu, Y.-M.; Harsonowati, W.; Hashem, A.; Abd_Allah, E.F.; Wu, Q.-S. Endophytic Fungi Accelerate Leaf Physiological Activity and Resveratrol Accumulation in Polygonum cuspidatum by Up-Regulating Expression of Associated Genes. Agronomy 2022, 12, 1220. [Google Scholar] [CrossRef]
  213. Boldt-Burisch, K.; Pörs, Y.; Haupt, B.; Bitterlich, M.; Kühn, C.; Grimm, B.; Franken, P. Photochemical Processes, Carbon Assimilation and RNA Accumulation of Sucrose Transporter Genes in Tomato Arbuscular Mycorrhiza. J. Plant Physiol. 2011, 168, 1256–1263. [Google Scholar] [CrossRef] [PubMed]
  214. Rouphael, Y.; Franken, P.; Schneider, C.; Schwarz, D.; Giovannetti, M.; Agnolucci, M.; Pascale, S.D.; Bonini, P.; Colla, G. Arbuscular Mycorrhizal Fungi Act as Biostimulants in Horticultural Crops. Sci. Hortic. 2015, 196, 91–108. [Google Scholar] [CrossRef]
  215. Augé, R. Water Relation, Drought and VA Mycorrhizal Symbiosis. Mycorrhiza. Mycorrhiza 2001, 11, 3–42. [Google Scholar] [CrossRef]
  216. Wu, Q.-S.; Xia, R.-X. Arbuscular Mycorrhizal Fungi Influence Growth, Osmotic Adjustment and Photosynthesis of Citrus under Well-Watered and Water Stress Conditions. J. Plant Physiol. 2006, 163, 417–425. [Google Scholar] [CrossRef]
  217. Wani, S.H.; Kumar, V.; Shriram, V.; Sah, S.K. Phytohormones and Their Metabolic Engineering for Abiotic Stress Tolerance in Crop Plants. Crop J. 2016, 4, 162–176. [Google Scholar] [CrossRef]
  218. Vishal, B.; Kumar, P.P. Regulation of Seed Germination and Abiotic Stresses by Gibberellins and Abscisic Acid. Front. Plant Sci. 2018, 9, 838. [Google Scholar] [CrossRef]
  219. Chen, K.; Li, G.-J.; Bressan, R.A.; Song, C.-P.; Zhu, J.-K.; Zhao, Y. Abscisic Acid Dynamics, Signaling, and Functions in Plants. J. Integr. Plant Biol. 2020, 62, 25–54. [Google Scholar] [CrossRef]
  220. Bharath, P.; Gahir, S.; Raghavendra, A.S. Abscisic Acid-Induced Stomatal Closure: An Important Component of Plant Defense Against Abiotic and Biotic Stress. Front. Plant Sci. 2021, 12, 615114. [Google Scholar] [CrossRef]
  221. Tuteja, N. Abscisic Acid and Abiotic Stress Signaling. Plant Signal. Behav. 2007, 2, 135–138. [Google Scholar] [CrossRef]
  222. Kagaya, Y.; Hobo, T.; Murata, M.; Ban, A.; Hattori, T. Abscisic Acid-Induced Transcription Is Mediated by Phosphorylation of an Abscisic Acid Response Element Binding Factor, TRAB1. Plant Cell 2002, 14, 3177–3189. [Google Scholar] [CrossRef]
  223. Yamaguchi-Shinozaki, K.; Shinozaki, K. Transcriptional Regulatory Networks in Cellular Responses and Tolerance to Dehydration and Cold Stresses. Annu. Rev. Plant Biol. 2006, 57, 781–803. [Google Scholar] [CrossRef]
  224. Yamaguchi-Shinozaki, K.; Shinozaki, K. Organization of Cis-Acting Regulatory Elements in Osmotic- and Cold-Stress-Responsive Promoters. Trends Plant Sci. 2005, 10, 88–94. [Google Scholar] [CrossRef] [PubMed]
  225. Estrada-Luna, A.A.; Davies, F.T. Arbuscular Mycorrhizal Fungi Influence Water Relations, Gas Exchange, Abscisic Acid and Growth of Micropropagated Chile Ancho Pepper (Capsicum annuum) Plantlets during Acclimatization and Post-Acclimatization. J. Plant Physiol. 2003, 160, 1073–1083. [Google Scholar] [CrossRef] [PubMed]
  226. Mohanta, T.K.; Bashir, T.; Hashem, A.; Abd Allah, E.F. Systems Biology Approach in Plant Abiotic Stresses. Plant Physiol. Biochem. PPB 2017, 121, 58–73. [Google Scholar] [CrossRef] [PubMed]
  227. Li, T.; Sun, Y.; Ruan, Y.; Xu, L.; Hu, Y.; Hao, Z.; Zhang, X.; Li, H.; Wang, Y.; Yang, L.; et al. Potential Role of D-Myo-Inositol-3-Phosphate Synthase and 14-3-3 Genes in the Crosstalk between Zea Mays and Rhizophagus Intraradices under Drought Stress. Mycorrhiza 2016, 26, 879–893. [Google Scholar] [CrossRef]
  228. Zivcak, M.; Brestic, M.; Sytar, O. Osmotic Adjustment and Plant Adaptation to Drought Stress. In Drought Stress Tolerance in Plants, Vol 1: Physiology and Biochemistry, 1st ed.; Hossain, M.A., Wani, S.H., Bhattacharjee, S., Burritt, D.J., Tran, L.-S.P., Eds.; Springer International Publishing: Cham, Switzerland, 2016; pp. 105–143. ISBN 978-3-319-28897-0. [Google Scholar]
  229. Turner, N.C. Turgor Maintenance by Osmotic Adjustment: 40 Years of Progress. J. Exp. Bot. 2018, 69, 3223–3233. [Google Scholar] [CrossRef]
  230. Bakr, J.; Pék, Z.; Helyes, L.; Posta, K. Mycorrhizal Inoculation Alleviates Water Deficit Impact on Field-Grown Processing Tomato. Pol. J. Environ. Stud. 2018, 27, 1949–1958. [Google Scholar] [CrossRef]
  231. Sun, R.-T.; Feng, X.-C.; Zhang, Z.-Z.; Zhou, N.; Feng, H.-D.; Liu, Y.-M.; Hashem, A.; Al-Arjani, A.-B.F.; Abd_Allah, E.F.; Wu, Q.-S. Root Endophytic Fungi Regulate Changes in Sugar and Medicinal Compositions of Polygonum cuspidatum. Front. Plant Sci. 2022, 13, 818909. [Google Scholar] [CrossRef]
  232. Evelin, H.; Kapoor, R.; Giri, B. Arbuscular Mycorrhizal Fungi in Alleviation of Salt Stress: A Review. Ann. Bot. 2009, 104, 1263–1280. [Google Scholar] [CrossRef]
  233. García-Rodríguez, S.; Pozo, M.J.; Azcón-Aguilar, C.; Ferrol, N. Expression of a Tomato Sugar Transporter Is Increased in Leaves of Mycorrhizal or Phytophthora Parasitica-Infected Plants. Mycorrhiza 2005, 15, 489–496. [Google Scholar] [CrossRef]
  234. Salmeron-Santiago, I.A.; Martínez-Trujillo, M.; Valdez-Alarcón, J.J.; Pedraza-Santos, M.E.; Santoyo, G.; Pozo, M.J.; Chávez-Bárcenas, A.T. An Updated Review on the Modulation of Carbon Partitioning and Allocation in Arbuscular Mycorrhizal Plants. Microorganisms 2021, 10, 75. [Google Scholar] [CrossRef] [PubMed]
  235. Apel, K.; Hirt, H. Reactive Oxygen Species: Metabolism, Oxidative Stress, and Signal Transduction. Annu. Rev. Plant Biol. 2004, 55, 373–399. [Google Scholar] [CrossRef] [PubMed]
  236. Das, K.; Roychoudhury, A. Reactive Oxygen Species (ROS) and Response of Antioxidants as ROS-Scavengers during Environmental Stress in Plants. Front. Environ. Sci. 2014, 2, 53. [Google Scholar] [CrossRef]
  237. Meloni, D.A.; Oliva, M.A.; Martinez, C.A.; Cambraia, J. Photosynthesis and Activity of Superoxide Dismutase, Peroxidase and Glutathione Reductase in Cotton under Salt Stress. Environ. Exp. Bot. 2003, 49, 69–76. [Google Scholar] [CrossRef]
  238. Kong, W.; Liu, F.; Zhang, C.; Zhang, J.; Feng, H. Non-Destructive Determination of Malondialdehyde (MDA) Distribution in Oilseed Rape Leaves by Laboratory Scale NIR Hyperspectral Imaging. Sci. Rep. 2016, 6, 35393. [Google Scholar] [CrossRef] [PubMed]
  239. Rhoads, D.M.; Umbach, A.L.; Subbaiah, C.C.; Siedow, J.N. Mitochondrial Reactive Oxygen Species. Contribution to Oxidative Stress and Interorganellar Signaling. Plant Physiol. 2006, 141, 357–366. [Google Scholar] [CrossRef]
  240. Hashem, A.; Abd_Allah, E.F.; Alqarawi, A.A.; Aldubise, A.; Egamberdieva, D. Arbuscular Mycorrhizal Fungi Enhances Salinity Tolerance of Panicum turgidum Forssk by Altering Photosynthetic and Antioxidant Pathways. J. Plant Interact. 2015, 10, 230–242. [Google Scholar] [CrossRef]
  241. Alqarawi, A.; Hashem, A.; Abd_Allah, E.; Alshahrani, T.; Huqail, A. Effect of Salinity on Moisture Content, Pigment System, and Lipid Composition in Ephedra Alata Decne. Acta Biol. Hung. 2014, 65, 61–71. [Google Scholar] [CrossRef]
  242. Fester, T.; Hause, G. Accumulation of Reactive Oxygen Species in Arbuscular Mycorrhizal Roots. Mycorrhiza 2005, 15, 373–379. [Google Scholar] [CrossRef]
  243. Corradi, N.; Ruffner, B.; Croll, D.; Colard, A.; Horák, A.; Sanders, I.R. High-Level Molecular Diversity of Copper-Zinc Superoxide Dismutase Genes among and within Species of Arbuscular Mycorrhizal Fungi. Appl. Environ. Microbiol. 2009, 75, 1970–1978. [Google Scholar] [CrossRef]
  244. Woźniak, M.; Gałązka, A.; Tyśkiewicz, R.; Jaroszuk-ściseł, J. Endophytic Bacteria Potentially Promote Plant Growth by Synthesizing Different Metabolites and Their Phenotypic/Physiological Profiles in the Biolog Gen Iii MicroplateTM Test. Int. J. Mol. Sci. 2019, 20, 5283. [Google Scholar] [CrossRef] [PubMed]
  245. Xiong, Y.W.; Li, X.W.; Wang, T.T.; Gong, Y.; Zhang, C.M.; Xing, K.; Qin, S. Root Exudates-Driven Rhizosphere Recruitment of the Plant Growth-Promoting Rhizobacterium bacillus Flexus KLBMP 4941 and Its Growth-Promoting Effect on the Coastal Halophyte Limonium Sinense under Salt Stress. Ecotoxicol. Environ. Saf. 2020, 194, 110374. [Google Scholar] [CrossRef] [PubMed]
  246. Novo, L.A.B.; Castro, P.M.L.; Alvarenga, P.; da Silva, E.F. Plant Growth-Promoting Rhizobacteria-Assisted Phytoremediation of Mine Soils; Elsevier Inc.: Amsterdam, The Netherlands, 2018; ISBN 9780128129876. [Google Scholar]
  247. Pathania, P.; Rajta, A.; Singh, P.C.; Bhatia, R. Role of Plant Growth-Promoting Bacteria in Sustainable Agriculture. Biocatal. Agric. Biotechnol. 2020, 30, 101842. [Google Scholar] [CrossRef]
  248. Asghari, B.; Khademian, R.; Sedaghati, B. Plant Growth Promoting Rhizobacteria (PGPR) Confer Drought Resistance and Stimulate Biosynthesis of Secondary Metabolites in Pennyroyal (Mentha pulegium L.) under Water Shortage Condition. Sci. Hortic. 2020, 263, 109132. [Google Scholar] [CrossRef]
  249. Jochum, M.D.; McWilliams, K.L.; Borrego, E.J.; Kolomiets, M.V.; Niu, G.; Pierson, E.A.; Jo, Y.-K. Bioprospecting Plant Growth-Promoting Rhizobacteria That Mitigate Drought Stress in Grasses. Front. Microbiol. 2019, 10, 2106. [Google Scholar] [CrossRef]
  250. Yousefi, S.; Kartoolinejad, D.; Bahmani, M.; Naghdi, R. Effect of Azospirillum Lipoferum and Azotobacter Chroococcum on Germination and Early Growth of Hopbush Shrub (Dodonaea viscosa L.) under Salinity Stress. J. Sustain. For. 2017, 36, 107–120. [Google Scholar] [CrossRef]
  251. Saleem, M.; Arshad, M.; Hussain, S.; Bhatti, A.S. Perspective of Plant Growth Promoting Rhizobacteria (PGPR) Containing ACC Deaminase in Stress Agriculture. J. Ind. Microbiol. Biotechnol. 2007, 34, 635–648. [Google Scholar] [CrossRef]
  252. Mishra, M.; Kumar, U.; Mishra, P.K.; Prakash, V. Efficiency of Plant Growth Promoting Rhizobacteria for the Enhancement of Cicer arietinum L. Growth and Germination under Salinity. Adv. Biol. Res. 2010, 4, 92–96. [Google Scholar]
  253. Narula, N.; Deubel, A.; Gans, W.; Behl, R.K.; Merbach, W. Paranodules and Colonization of Wheat Roots by Phytohormone Producing Bacteria in Soil. Plant Soil Environ. 2006, 52, 119–129. [Google Scholar] [CrossRef] [Green Version]
  254. Ortíz-Castro, R.; Valencia-Cantero, E.; López-Bucio, J. Plant Growth Promotion by Bacillus megaterium Involves Cytokinin Signaling. Plant Signal. Behav. 2008, 3, 263–265. [Google Scholar] [CrossRef]
  255. Chiappero, J.; Cappellari, L.d.R.; Palermo, T.B.; Giordano, W.; Khan, N.; Banchio, E. Antioxidant Status of Medicinal and Aromatic Plants under the Influence of Growth-Promoting Rhizobacteria and Osmotic Stress. Ind. Crops Prod. 2021, 167, 113541. [Google Scholar] [CrossRef]
  256. Bidgoli, R.D. Providing a Strategy to Confronting the Salinity Stress by Using the PGPR in a Desert Species (Calligonum comosum L‘Her) in Greenhouse Conditions. Desert Ecosyst. Eng. J. 2019, 2, 13–22. [Google Scholar] [CrossRef]
  257. Alipour, A.; Rahimi, M.M.; Hosseini, S.M.A.; Bahrani, A. Mycorrhizal Fungi and Growth-Promoting Bacteria Improves Fennel Essential Oil Yield under Water Stress. Ind. Crops Prod. 2021, 170, 113792. [Google Scholar] [CrossRef]
  258. Banchio, E.; Bogino, P.C.; Santoro, M.; Torres, L.; Zygadlo, J.; Giordano, W. Systemic Induction of Monoterpene Biosynthesis in Origanum × Majoricum by Soil Bacteria. J. Agric. Food Chem. 2010, 58, 650–654. [Google Scholar] [CrossRef] [PubMed]
  259. Diagne, N.; Ndour, M.; Djighaly, P.I.; Ngom, D.; Ngom, M.C.N.; Ndong, G.; Svistoonoff, S.; Cherif-Silini, H. Effect of Plant Growth Promoting Rhizobacteria (PGPR) and Arbuscular Mycorrhizal Fungi (AMF) on Salt Stress Tolerance of Casuarina obesa (Miq.). Front. Sustain. Food Syst. 2020, 4, 601004. [Google Scholar] [CrossRef]
  260. Moreira, H.; Pereira, S.I.A.; Vega, A.; Castro, P.M.L.; Marques, A.P.G.C. Synergistic Effects of Arbuscular Mycorrhizal Fungi and Plant Growth-Promoting Bacteria Benefit Maize Growth under Increasing Soil Salinity. J. Environ. Manage. 2020, 257, 109982. [Google Scholar] [CrossRef]
  261. Şirin, E.; Ertürk, Y.; Kazankaya, A. Effects of PGPR, AMF and Trichoderma Applications on Adaptation Abilities to Different Biotic and Abiotic Conditions in Medicinal and Aromatic Plants. Turk. J. Agric. Food Sci. Technol. 2022, 10, 166–173. [Google Scholar] [CrossRef]
  262. Azizi, S.; Tabari Kouchaksaraei, M.; Hadian, J.; Fallah Nosrat Abad, A.R.; Modarres Sanavi, S.A.M.; Ammer, C.; Bader, M.K.F. Dual Inoculations of Arbuscular Mycorrhizal Fungi and Plant Growth-Promoting Rhizobacteria Boost Drought Resistance and Essential Oil Yield of Common Myrtle. For. Ecol. Manag. 2021, 497, 119478. [Google Scholar] [CrossRef]
  263. Mishra, V.; Gupta, A.; Kaur, P.; Singh, S.; Singh, N.; Gehlot, P.; Singh, J. Synergistic Effects of Arbuscular Mycorrhizal Fungi and Plant Growth Promoting Rhizobacteria in Bioremediation of Iron Contaminated Soils. Int. J. Phytoremediat. 2016, 18, 697–703. [Google Scholar] [CrossRef]
  264. Jaleel, C.A.; Manivannan, P.; Sankar, B.; Kishorekumar, A.; Gopi, R.; Somasundaram, R.; Panneerselvam, R. Pseudomonas Fluorescens Enhances Biomass Yield and Ajmalicine Production in Catharanthus roseus under Water Deficit Stress. Colloids Surf. B Biointerfaces 2007, 60, 7–11. [Google Scholar] [CrossRef]
  265. Swamy, M.K.; Akhtar, M.S.; Sinniah, U.R. Response of PGPR and AM Fungi Toward Growth and Secondary Metabolite Production in Medicinal and Aromatic Plants. In Plant, Soil and Microbes: Volume 2: Mechanisms and Molecular Interactions; Hakeem, K.R., Akhtar, M.S., Eds.; Springer International Publishing: Cham, Switzerland, 2016; pp. 145–168. ISBN 978-3-319-29573-2. [Google Scholar]
  266. Touceda-González, M.; Álvarez-López, V.; Prieto-Fernández; Rodríguez-Garrido, B.; Trasar-Cepeda, C.; Mench, M.; Puschenreiter, M.; Quintela-Sabarís, C.; Macías-García, F.; Kidd, P.S. Aided Phytostabilisation Reduces Metal Toxicity, Improves Soil Fertility and Enhances Microbial Activity in Cu-Rich Mine Tailings. J. Environ. Manage. 2017, 186, 301–313. [Google Scholar] [CrossRef] [PubMed]
  267. Dishani, P.T.N.; De Silva, C.S. Effect of Simulated Temperature and Water Stress on Growth, Physiological and Yield Parameters of Tomato [Lycopersicon esculentum Var: Thilina] Grown with Mulch. OUSL J. 2016, 11, 37–51. [Google Scholar] [CrossRef]
  268. Fracchiolla, M.; Renna, M.; D’Imperio, M.; Lasorella, C.; Santamaria, P.; Cazzato, E. Living Mulch and Organic Fertilization to Improve Weed Management, Yield and Quality of Broccoli Raab in Organic Farming. Plants 2020, 9, 177. [Google Scholar] [CrossRef]
  269. Matković, A.; Božić, D.; Filipović, V.; Radanović, D.; Vrbničanin, S.; Marković, T.; Ana, M.; Dragana, B.; Vladimir, F.; Dragoja, R.; et al. Mulching as a Physical Weed Control Method Applicable in Medicinal Plants Cultivations. Lek. Sirovine 2016, 35, 37–51. [Google Scholar] [CrossRef]
  270. Forouzandeh, M.; Fanoudi, M.; Arazmjou, E.; Tabiei, H. Effect of Drought Stress and Types of Fertilizers on the Quantity and Quality of Medicinal Plant Basil ( Ocimum basilicum L.). Indian J. Innov. Dev 2012, 1, 696–699. [Google Scholar]
  271. Alves, P.A.C.; Gross, E.; Costa, L.C.d.B.; Silva, V.C.; Corrêa, F.M.; Oliveira, R.A. Biomass and Essential Oil Production from Menthe Is Influenced by Compost and Lime. J. Med. Plants Res. 2014, 8, 468–474. [Google Scholar] [CrossRef]
  272. Nigam, N.; Khare, P.; Ahsan, M.; Yadav, V.; Shanker, K.; Singh, R.P.; Pandey, V.; Das, P.; Anupama, A.; Yadav, R.; et al. Biochar Amendment Reduced the Risk Associated with Metal Uptake and Improved Metabolite Content in Medicinal Herbs. Physiol. Plant. 2021, 173, 321–339. [Google Scholar] [CrossRef]
  273. Saha, A.; Basak, B.B.; Gajbhiye, N.A.; Kalariya, K.A.; Manivel, P. Sustainable Fertilization through Co-Application of Biochar and Chemical Fertilizers Improves Yield, Quality of Andrographis Paniculata and Soil Health. Ind. Crops Prod. 2019, 140, 111607. [Google Scholar] [CrossRef]
  274. de Assis, R.M.A.; Carneiro, J.J.; Medeiros, A.P.R.; de Carvalho, A.A.; da Cunha Honorato, A.; Carneiro, M.A.C.; Bertolucci, S.K.V.; Pinto, J.E.B.P. Arbuscular Mycorrhizal Fungi and Organic Manure Enhance Growth and Accumulation of Citral, Total Phenols, and Flavonoids in Melissa officinalis L. Ind. Crops Prod. 2020, 158, 112981. [Google Scholar] [CrossRef]
  275. Koozehgar Kaleji, M.; Ardakani, M.R.; Khodabandeh, N.; Alavi Fazel, M. Effects of Mycorrhizal Symbiosis along with Vermicompost and Tea Compost on Quantity and Quality Yield of Mentha aquatic L. J. Crop Ecophysiol. 2018, 12, 461–476. [Google Scholar]
  276. Tanu; Prakash, A.; Adholeya, A. Effect of Different Organic Manures/Composts on the Herbage and Essential Oil Yield of Cymbopogon Winterianus and Their Influence on the Native AM Population in a Marginal Alfisol. Bioresour. Technol. 2004, 92, 311–319. [Google Scholar] [CrossRef]
  277. Lermen, C.; Cruz, M.; Silva de Souza, J.; Marchi, B.; Alberton, O. Growth of Lippia alba (Mill.) N. E. Brown Inoculated with Arbuscular Mycorrhizal Fungi with Different Levels of Humic Substances and Phosphorus in the Soil. J. Appl. Res. Med. Aromat. Plants 2017, 7, 48–53. [Google Scholar] [CrossRef]
  278. Papafotiou, M.; Martini, A.N.; Papanikolaou, E.; Stylias, E.G.; Kalantzis, A. Hybrids Development between Greek Salvia Species and Their Drought Resistance Evaluation along with Salvia fruticosa, under Attapulgite-Amended Substrate. Agronomy 2021, 11, 2401. [Google Scholar] [CrossRef]
  279. Yang, T.; Xing, X.; Gao, Y.; Ma, X. An Environmentally Friendly Soil Amendment for Enhancing Soil Water Availability in Drought-Prone Soils. Agronomy 2022, 12, 133. [Google Scholar] [CrossRef]
  280. Soltanbeigi, A.; Yıldız, M.; Dıraman, H.; Terzi, H.; Sakartepe, E.; Yıldız, E. Growth Responses and Essential Oil Profile of Salvia officinalis L. Influenced by Water Deficit and Various Nutrient Sources in the Greenhouse. Saudi J. Biol. Sci. 2021, 28, 7327–7335. [Google Scholar] [CrossRef] [PubMed]
  281. Liu, B.; Soundararajan, P.; Manivannan, A. Mechanisms of Silicon-Mediated Amelioration Of. Plants 2019, 8, 307. [Google Scholar] [CrossRef]
  282. Xu, C.; Qi, J.; Yang, W.; Chen, Y.; Yang, C.; He, Y.; Wang, J.; Lin, A. Immobilization of Heavy Metals in Vegetable-Growing Soils Using Nano Zero-Valent Iron Modified Attapulgite Clay. Sci. Total Environ. 2019, 686, 476–483. [Google Scholar] [CrossRef]
  283. Fard, S.E.; Yarnia, M.; Farahvash, F.; Behrouzyar, E.K.; Rashidi, V. Arbuscular Mycorrhizas and Phosphorus Fertilizer Affect Photosynthetic Capacity and Antioxidant Enzyme Activity in Peppermint Under Different Water Conditions. Acta Agrobot. 2020, 73, 13. [Google Scholar]
  284. Mierzwa-Hersztek, M.; Gondek, K.; Klimkowicz-Pawlas, A.; Kopeć, M. Effect of Coapplication of Poultry Litter Biochar and Mineral Fertilisers on Soil Quality and Crop Yield. Zemdirbyste 2018, 105, 203–210. [Google Scholar] [CrossRef]
  285. Hussain, M.M.; Bibi, I.; Niazi, N.K.; Shahid, M.; Iqbal, J.; Shakoor, M.B.; Ahmad, A.; Shah, N.S.; Bhattacharya, P.; Mao, K.; et al. Arsenic Biogeochemical Cycling in Paddy Soil-Rice System: Interaction with Various Factors, Amendments and Mineral Nutrients. Sci. Total Environ. 2021, 773, 145040. [Google Scholar] [CrossRef]
  286. Almutairi, K.F.; Abdel-Sattar, M.; Mahdy, A.M.; El-Mahrouky, M.A. Co-Application of Mineral and Organic Fertilizers under Deficit Irrigation Improves the Fruit Quality of the Wonderful Pomegranate. PeerJ 2021, 9, e11328. [Google Scholar] [CrossRef] [PubMed]
  287. Ainalidou, A.; Bouzoukla, F.; Menkissoglu-Spiroudi, U.; Vokou, D.; Karamanoli, K. Impacts of Decaying Aromatic Plants on the Soil Microbial Community and on Tomato Seedling Growth and Metabolism: Suppression or Stimulation? Plants 2021, 10, 1848. [Google Scholar] [CrossRef] [PubMed]
  288. Ait Elallem, K.; Sobeh, M.; Boularbah, A.; Yasri, A. Chemically Degraded Soil Rehabilitation Process Using Medicinal and Aromatic Plants: Review. Environ. Sci. Pollut. Res. 2021, 28, 73–93. [Google Scholar] [CrossRef] [PubMed]
  289. Momeni, M.; Pirbalouti, A.G.; Mousavi, A.; Badi, H.N. Effect of Foliar Applications of Salicylic Acid and Chitosan on the Essential Oil of Thymbra spicata L. under Different Soil Moisture Conditions. J. Essent. Oil Bear. Plants 2020, 23, 1142–1153. [Google Scholar] [CrossRef]
  290. Taha, R.S.; Alharby, H.F.; Bamagoos, A.A.; Medani, R.A.; Rady, M.M. Elevating Tolerance of Drought Stress in Ocimum Basilicum Using Pollen Grains Extract; a Natural Biostimulant by Regulation of Plant Performance and Antioxidant Defense System. South Afr. J. Bot. 2020, 128, 42–53. [Google Scholar] [CrossRef]
  291. Dianat, M.; Saharkhiz, M.J.; Tavassolian, I. Salicylic Acid Mitigates Drought Stress in Lippia citriodora L.: Effects on Biochemical Traits and Essential Oil Yield. Biocatal. Agric. Biotechnol. 2016, 8, 286–293. [Google Scholar] [CrossRef]
  292. Paulert, R.; Ascrizzi, R.; Malatesta, S.; Berni, P.; Noseda, M.D.; Mazetto de Carvalho, M.; Marchioni, I.; Pistelli, L.; Rabello Duarte, M.E.; Mariotti, L.; et al. Ulva Intestinalis Extract Acts as Biostimulant and Modulates Metabolites and Hormone Balance in Basil (Ocimum basilicum L.) and Parsley (Petroselinum crispum L.). Plants 2021, 10, 1391. [Google Scholar] [CrossRef] [PubMed]
  293. Mohammadi, H.; Saeedi, S.; Hazrati, S.; Brestic, M. Physiological and Phytochemical Responses of Lemon Balm (Melissa officinalis L.) to Pluramin Application and Inoculation with Pseudomonas Fluorescens PF-135 under Water-Deficit Stress. Russ. J. Plant Physiol. 2021, 68, 909–922. [Google Scholar] [CrossRef]
  294. Shirkhodaei, M.; Taghi Darzi, M.; Haj Seyed Hadi, M. Influence of Vermicompost and Biostimulant on The Growth and Biomass of Coriander (Coriandrum sativum L.). Int. J. Adv. Biol. Biomed. Res. 2014, 2, 706–714. [Google Scholar]
Foods 11 02591 g001 550
Figure 1. Mechanisms used by arbuscular mycorrhizal fungi (AMF) to improve stress tolerance and enhance the growth of medicinal and aromatic plants. AMF triggers the response of plants at morphological, physiological, and molecular levels to cope with the detrimental effects of abiotic stress. Arbuscular mycorrhizal symbiosis improves water and nutrient acquisition, enhances plant growth and abiotic stress tolerance. “+” indicates a positive effect. EOs, essential oils; SOD, superoxide dismutase; POD, peroxidase; APX, ascorbate peroxidase; H2O2, hydrogen peroxide; MDA, malondialdehyde; P, phosphorus.
Figure 1. Mechanisms used by arbuscular mycorrhizal fungi (AMF) to improve stress tolerance and enhance the growth of medicinal and aromatic plants. AMF triggers the response of plants at morphological, physiological, and molecular levels to cope with the detrimental effects of abiotic stress. Arbuscular mycorrhizal symbiosis improves water and nutrient acquisition, enhances plant growth and abiotic stress tolerance. “+” indicates a positive effect. EOs, essential oils; SOD, superoxide dismutase; POD, peroxidase; APX, ascorbate peroxidase; H2O2, hydrogen peroxide; MDA, malondialdehyde; P, phosphorus.
Foods 11 02591 g001
Table
Table 1. Summary of water stress effects on growth and essential oil (EO) yield in various medicinal and aromatic plants (MAPs).
Table 1. Summary of water stress effects on growth and essential oil (EO) yield in various medicinal and aromatic plants (MAPs).
FamilyPlant SpeciesGrowthEOsReference
YieldPlant Part Used for EOs Distillation
ApiaceaeCarum carvi+Seeds[56]
Coriandrum sativumn.d.n.d.[57]
Cuminum cyminumSeeds[22]
Petroselinum crispum+Roots; Leaves[20]
Pimpinella anisumSeeds[21]
LamiaceaeLavandula angustifolia=Leaves[19]
Lavandula stoechasn.d.n.d.[53]
Mentha piperitaAerial parts[58]
Ocimum basilicum+Aerial parts[59]
Ocimum americanum
Ocimum basilicumn.d.n.d.[54]
Rosmarinus officinalisLeaves[60]
Salvia sclareaArial parts[61]
Saliva officinalis+Arial parts[62]
Salvia fruticosa+Leaves[19]
Sureja hortensis+Aerial parts[63]
‘+’ indicates increasing responses; ‘–’ indicates decreasing responses; ‘=’ indicates no response; ‘n.d.’ indicates not determined.
Table
Table 2. Summary of salt stress effects on growth and EO yield in various MAPs.
Table 2. Summary of salt stress effects on growth and EO yield in various MAPs.
FamilyPlant SpeciesGrowthEOReference
YieldPlant Part Used for EO Distillation
ApiaceaeCoriandrum sativumn.d.Leaves[74]
Coriandrum sativum+Fruits[75]
Coriandrum sativum+Roots[76]
Foeniculum vulgare+Seeds[72]
Trachyspermum ammi=Seeds[73]
AsteraceaeMatricaria chamomilaFlowers[77]
LamiaceaeCalendula officinalis+Flowers[78]
Melissa officinalisAerial parts[79]
Mentha x piperitaAerial parts[80]
Menhta piperitan.d.Aerial parts[81]
Mentha suaveolensAerial parts[80]
Ocimum basilicum+Aerial parts[81]
Origanum majoranaShoots[82]
Saliva officinalisLeaves; Fruits[83,84]
Satureja hortensis=Aerial parts[85]
Thymus daenensisn.d.n.d.[86]
Thymus maroccanus=Aerial parts[87]
Thymus vulgarisn.d.n.d.[86]
Thymus vulgaris+Aerial parts[88]
PoaceaeCymbopogon
schoenanthus		+Aerial parts[89]
‘+’ indicates increasing responses; ‘–’ indicates decreasing responses; ‘=’ indicates no response; ‘n.d.’ indicates not determined.
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Israel, A.; Langrand, J.; Fontaine, J.; Lounès-Hadj Sahraoui, A. Significance of Arbuscular Mycorrhizal Fungi in Mitigating Abiotic Environmental Stress in Medicinal and Aromatic Plants: A Review. Foods 2022, 11, 2591. https://doi.org/10.3390/foods11172591

AMA Style

Israel A, Langrand J, Fontaine J, Lounès-Hadj Sahraoui A. Significance of Arbuscular Mycorrhizal Fungi in Mitigating Abiotic Environmental Stress in Medicinal and Aromatic Plants: A Review. Foods. 2022; 11(17):2591. https://doi.org/10.3390/foods11172591

Chicago/Turabian Style

Israel, Abir, Julien Langrand, Joël Fontaine, and Anissa Lounès-Hadj Sahraoui. 2022. "Significance of Arbuscular Mycorrhizal Fungi in Mitigating Abiotic Environmental Stress in Medicinal and Aromatic Plants: A Review" Foods 11, no. 17: 2591. https://doi.org/10.3390/foods11172591

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