Arbuscular Mycorrhizal Fungi Enhance Biomass Growth, Mineral Content, and Antioxidant Activity in Tomato Plants under Drought Stress

Arbuscular mycorrhizal fungi (AMF) are symbiotically associated with crops. Tey increase biomass production, nutritional elements, and antioxidant activities in food and vegetable crops grown in soil under stress conditions. Te present study focused on the efects of AMF ( Acaulospora morrowiae , Paraglomus occultum , Funneliformis mosseae , Rhizophagus clarus , and Rhizo-phagus intraradices ) on biomass growth and yield, contents of chlorophyll and carotenoids, activities of catalase (CAT) and ascorbate peroxidase (APX), and contents of hydrogen peroxide (H 2 O 2 ), malondialdehyde (MDA), and minerals (Na, K, Ca, Mg, and Fe) in Unnayan, LT896, and Minto super tomato ( Solanum lycopersicum L.) varieties grown in soil under drought stress ( < 10% moisture). Te results showed that root length and shoot mass in plants treated with R. clarus and P. occultum were signifcantly higher than those of the control (non-AMF) in Minto super tomato. Compared to the control, the shoot’s dry weight and yield were enhanced by 28% and 20% with AMF-treated tomatoes. Te CAT activity in P. occultum -treated plants was statistically higher than that of the control in Unnayan tomatoes. H 2 O 2 content was detected higher in the control than R. clarus - treated LT896 tomatoes. In plants treated with A. morrowiae and R. clarus , APX activity was signifcantly higher than that of the control in the Unnayan tomatoes. CATand APX activity increased by 42% and 66% in AMF-treated leaves of tomatoes compared to non-AMF. Treatment with AMF reduced the content of MDA and H 2 O 2 (ROS) in the leaves of tomato plants by 50% and 2% compared to the control, respectively. Potassium (K), calcium (Ca), magnesium (Mg), and iron (Fe) of tomato fruits increased by 2%, 13%, 24%, and 37% with AMF treatment compared to the control. Tese results suggested that biomass growth, yield, photosynthetic pigments, antioxidant enzyme activity, and mineral contents could be enhanced by AMF in food crops grown under drought stress. It is concluded that AMF might be used for the development of AMF-enriched biofertilizers that will improve the nutritional quality of food crops grown under stress conditions.


Introduction
Arbuscular mycorrhizal fungi are benefcial microbes forming a symbiotic relationship with food crops [1].AMF could increase the nutrient and water uptake capacity through a hyphal network in the roots of the host plant [2,3].In contrast, plants serve as carbohydrates and organic nutrient sources for the AMF [4,5].Te prominent role of AMF in boosting the uptake of various nutrients, especially phosphate, is already well recorded [3,6].Tis natural symbiosis is highly efective in increasing nutrients within the plant organs [7].Te concentration of nutrients in the colonization of AMF with host plants can be increased by double compared to its non-mycorrhizal counterparts [8].
For instance, the concentration of nitrogen is increased in AMF-colonized leguminous species Melilotus alba [9].
AMF increase soil organic carbon and microbial activity through the interaction with the rhizosphere, which fnally enhances the nutrient availability in soils.AMF also boost the photosynthetic contents and its following efect on biomass growth of plants [10].Consequently, these ubiquitous fungi have various constructive efects on plant biomass growth, soil quality, and defense mechanisms against stresses [11,12].Tere are abundant records of AMF aiding in the vigorous vegetative growth of diferent plants.AMF increase plants' biomass of leaves, roots, and shoots [13,14].A majority of food crops such as onion, leeks, garlic, carrot, lettuce, cucumber, lentils, rice, mung beans, peas, tomato, and pepper form symbiotic associations with AMF [15,16].Recently, we showed that crop productivity increased signifcantly in AMF-colonized mung bean crops through the formation of photosynthetic products [12].In addition to this, an excellent positive correlation between AMF colonization and biomass production in carrots and parsley was reported by Regvar et al. [17], suggesting that mycorrhizae can enhance biomass growth in food crops [18,19].
Around 180 million tons of fresh tomato fruits are produced worldwide from 5 million ha of land [20].Tomatoes can be consumed as both fresh salad and processed food.Daily consumption of tomato products may provide a superb combination of healthy substances such as minerals, vitamins, favonoids, and antioxidant compounds like lycopene, beta-carotene, and lutein [21,22].Among the antioxidant compounds, lycopene and carotenoids contribute to reddening and enhancing the nutritional quality of tomato fruits [22].Lycopene works as a scavenger of toxic substances such as reactive oxygen species (ROS) in food crops grown under stress conditions [23].Consequently, antioxidants also work as potential inhibitors of diferent diseases like cancer, heart diseases, and macular degeneration [24].Te important incidence of AMF on P uptake was confrmed with generally double the concentration in mycorrhizal olive plants as compared to non-mycorrhizal controls, irrespective of genotype and inoculation.An evidence of higher crop yield and water use efciency by AMFcolonized tomato genotypes has been reported [25], where elevated levels of N and P concentration, higher photosynthetic rate, and fnally increased amount of fruit yield in AM tomato genotype are found.For example, AMF-inoculated tomato plants in arsenic-contaminated soil have been shown to increase nutrient uptake and biomass production, resulting in higher growth parameters [25].Inoculation of AMF increased P and K concentration in tomato plants under abiotic stress [26].
Photosynthesis reduces due to the dropping of CO 2 in crops grown under drought stress [37].Reactive oxygen species (ROS) is one of the major indicators of drought stress [38].However, ROS reduces through diferent mechanisms in food crops grown under drought stress [38].Te key mechanism to mitigate the adverse impacts of drought stress is increasing antioxidant activities [39].
Tomato is highly sensitive to drought stress.Te biomass production and photosynthetic pigments reduce in tomato plants under drought stress.Moreover, drought also reduces the enzymatic APX, CAT, DHAR (dehydroascorbate reductase), GST (glutathione S-transferase), GR (glutathione reductase), MDHAR (monodehydroascorbate reductase), POD (peroxidase), and SOD (superoxide dismutase) and non-enzymatic antioxidant AsA (ascorbate), DHA (dehydroascorbic acid), GSH (glutathione), and GSSG (oxidized glutathione) activities and increases oxidative damage, H 2 O 2 (hydrogen peroxide), MDA (malondialdehyde), and O 2 •− (superoxide ion) [40].Arbuscular mycorrhizal fungi (AMF) are considered one of the most disseminated fungi throughout the world [41].Te symbiotic association between the host plant and AMF substantially improved the resistance to drought stress [42].Drought stress is regulated in plants by AMF through diverse metabolic pathways [43].AMF increase water uptake in the host plant, progress water use efciency and gas change ability [43], alter the morphology of roots [44], adjust hormone levels [45], and decrease the generation of ROS [39] and thus decline the impacts of drought stress.Additionally, AMF also generate glomalin-related soil protein (GRSP), which works as a cement that encourages the creation of water-stable aggregates by extraradical hyphae, thus enhancing the water-holding capacity [46].Additionally, under drought stress, AMF regulate antioxidant activities, osmolytes, and photosynthetic pigments [47].
Te Unnayan, LT896, and Minto super tomatoes are hybrid day-length sensitive varieties.Te yield is comparatively higher than other varieties.Te infuence of AMF species (Acaulospora morrowiae, Paraglomus occultum, Funneliformis mosseae, Rhizophagus clarus, and Rhizophagus intraradices) on biomass growth, photosynthetic pigments, and antioxidant activity in Unnayan, LT896, and Minto super tomato varieties remains unknown under drought stress.Terefore, we studied the efects of AMF on biomass growth, yield, chlorophyll and carotenoids, catalase (CAT), hydrogen peroxide (H 2 O 2 ), malondialdehyde (MDA), ascorbate peroxidase (APX), and minerals (Na, K, Ca, Mg, and Fe) in tomato varieties grown in soil under drought stress.It is hypothesized that AMF will increase biomass growth, antioxidant activity, and nutritional quality in tomatoes and other food crops grown in soil under drought stress.

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Journal of Food Quality

Materials and Methods
2.1.Soil Sampling.Te soil sample was taken from a farmer's land in Gazipur of Bangladesh.Te geographical position of Gazipur District is between 23 °53′ and 24 °20′ north latitude and between 90 °09′ and 90 °42′ east longitude.Te collected soil was silty loam.Te experiment was conducted in the net house during winter (November to February) of the Department of Environmental Science at Bangabandhu Sheikh Mujibur Rahman Agricultural University (BSMRAU).Te absence of mycorrhizal spores was confrmed in the soil using a stereomicroscope by following the wet sieving and decanting method [48].Te average temperature was 22 °C during the experiment.

Chemical Analysis.
Te collected soil samples were brought into the laboratory for chemical analysis before fertilization [49].Soil samples were dried with sunlight.Ten, the samples were crushed and sieved with 250 μ size sieve and kept in Ziploc bags with proper tagging.Te percentages of total nitrogen (0.086%), phosphorus (9.6 mg•kg −1 ), exchangeable potassium (0.28 meq −100g ), and pH (7.34) were detected by the Kjeldahl method [50], by the Olsen method [51], by the ammonium acetate extraction method [50], and by the glass electrode pH meter [50] in soils, respectively (Table 1).

Tomato Seedlings, Pots, and
Fertilizers.Seeds of tomato (Solanum lycopersicum L.) varieties (Unnayan, LT896, and Minto super) were collected from the research and development wing of Lal Teer Institute in Bangladesh.Tese varieties were selected based on their growing season and height.Tese tomatoes are grown in winter (November to February) in Bangladesh.Tey need 18 to 22 °C temperature.Seeds of three tomato varieties were spread into the soil in a concrete structured seedbed separately for the growing of seedlings during November 2020.Tree tomato seedlings of each variety were transferred into the soil in each pot at week 3. Urea, triple superphosphate (TSP), and muriate of potash (MOP) were applied as nutrients.Plastic-made pots and pesticides were purchased from a local shop in Bangladesh.Te sizes of the pots were 25/25 cm.Te volume of the pot with soil was 8 kg.Urea (550 kg•ha −1 ), triple superphosphate (TSP) (250 kg•ha −1 ), and muriate of potash (MOP) (250 kg•ha −1 ) were applied according to the BARC recommendations to the soil in each pot.

Mycorrhizal Fungi. Arbuscular mycorrhizal fungi (AMF) species (CL149: Acaulospora morrowiae, CL699:
Paraglomus occultum, CA201: Funneliformis mosseae, BR143A: Rhizophagus clarus, and WV116: Rhizophagus intraradices) was cultured with Sorghum separately in a concrete structured seedbed for multiplication as a source of AMF in the Department of Environmental Science at BSMRAU.AMF species were collected from the International Collection of Vesicular Arbuscular Mycorrhizal Fungi (INVAM).AMF species were collected separately from the inoculated plants of Sorghum.Hyphae, vesicles, and spores were included in the AMF inoculum (Figure 1).Mycorrhizal spores in the soil and vesicle, hyphae, and arbuscules in the root samples were observed before using as treatment in pot soils by following the wet sieving and decanting method [48].Te spores in the watch glass were observed under a stereomicroscope (Figure 1).Te number of spores was expressed as the total number of spores in 100 g of soil.Each sample was observed around 100 intersections of roots under the compound microscope (Zeiss Primo Star, Carl Zeiss Ltd., Germany).Mycorrhizal colonization was recorded based on the presence of hyphae, vesicles, or arbuscule in a root segment (Figure 1).Te colonization of AMF in roots was calculated using the following formula: % root colonization � total number of positive segments/total number of segments studied × 100 [52].In Sorghum, the average percentages of root colonization and spores in 100 g soil of AMF species were 40 and 50, respectively, before using as treatment.In tomatoes, the average percentages of root colonization and spores of AMF species were 45 and 60, respectively, after using them as treatments (Figure 1).

Treatments. Tree tomato varieties (Unnayan, LT896, and Minto super) and six treatments comprised of T
intraradices, and T 6 � control (non-AMF).Five replications of each treatment were used, and the total number of pots was 90 in this experiment.Soil moisture was less than 10%.A soil moisture meter was used for maintaining expected moisture content in soil samples.Fifty gram AMF soil kg −1 pot soil was used in this experiment (5% of total biomass).
2.6.Biomass Growth.Average shoot length, number of leaves, length of leaves, the width of leaves, and branches of leaves were noted using a measuring tape (cm) during week 9 of each treated tomato plant.Te root and shoot's average dry and fresh weight were measured separately using an electrical balance after harvesting each treated tomato plant at week 18.Te yield was recorded during the collection of each tomato variety grown in pot soil (Figures 2 and 3).

Collection of Leaves and Fruits for the Analysis of Photosynthetic
Pigments, Antioxidants, and Minerals.Tomato leaves were taken after inoculation with AMF on week 9 for biochemical analysis.Tomato fruits were collected on week 18 for the analysis of minerals.All treated samples were kept in Ziploc bags with proper labeling for chemical analysis.Ten, samples with iceboxes containing liquid nitrogen were carried into the laboratory.

Chlorophyll and Carotenoids.
Te chlorophyll content of tomato leaves was detected following the method described by Arnon [53].Chlorophyll contents were calculated using the following formula:

Malondialdehyde (MDA).
Te malondialdehyde content of tomato leaves was determined by the method of Heath and Packer [54].Te absorbance of the colored supernatant was taken at 532 nm.Te MDA content was estimated using an extinction coefcient (Є) of 155 mM•cm −1 .
Te following formula was used for the calculation of

Catalase (CAT). Catalase (CAT) activity in tomato leaves
was estimated by the method of Aebi [55].Te activity was calculated by using an extinction coefcient of 6.93 × 10 −3 mM•cm −1 .Te activity of CAT was determined by the following formula: mM min − 1 mg − 1 P   � unit activity units min − 1 g − 1 FW   protein mg g −1   .
2.12.Hydrogen Peroxide (H 2 O 2 ).According to Loreto and Velikova [57], hydrogen peroxide (H 2 O 2 ) content was determined in tomato leaves.Tomato leaves of 0.5 g were homogenized in 3 mL of 1% (w/v) trichloroacetic acid (TCA).Te homogenate was centrifuged at 10,000 rpm and 4 °C for 10 min.Subsequently, 0.75 mL of the supernatant was added to 0.75 mL of 10 mM K-phosphate bufer (pH 7.0), and 1.5 mL of 1 M KI.H 2 O 2 concentration of the supernatant was evaluated by comparing its absorbance at 390 nm to a standard calibration curve.Te concentration of H 2 O 2 was calculated from a standard curve plotted in the range from 100 to 1000 μ mol•mL −1 .H 2 O 2 concentration was expressed as μ mol•g −1 FW.

Digestion and Detection of Minerals.
Tomato fruits were digested individually using a hot plate [58].For the fruit samples, 0.2 g fresh samples was placed into a clean beaker and 8 mL concentrated HNO 3 was mixed with it.Te beaker was put into the hot plate for 2 hours at 90 °C temperature on the following day.Usually, heating stopped when a white dense fume of HNO 3 was released into the air.Ten, the samples were cooled and diluted to 25 ml with deionized water and fltered through Whatman No. 42 flter paper.Lastly, samples were kept in polyethylene bottles.All glassware was washed with 2% HNO 3 followed by rinsing with deionized water and drying.Minerals in tomato fruits such as Ca, Fe, K, Mg, and Na were analyzed by fow injection hydride generation atomic absorption spectrophotometry (FI-HG-AAS, Perkin Elmer A Analyst 400, USA) [59].
2.14.Quality Control.Quality assurance such as reagent quality, cleaning, accuracy, precision, instrumentation, and reliability, blank analysis, replication, internal standard, and certifed reference materials were followed properly according to the proposed guidelines of the National Association of Testing Authorities [60].Along with their guidelines, several QC parameters are highlighted in Table 1.Photosynthetic pigments, antioxidant activities, and mineral contents of tomatoes were detected using three technical replicates for each sample in the Laboratory of Environmental Science at BSMRAU.

Statistical Analysis.
Te completely randomized design (CRD) was followed in this experiment.Analysis of variance (ANOVA) and efects of treatment on biomass, photosynthetic pigments, antioxidants, and minerals of tomatoes were analyzed using Minitab software.Te separation of means considering the two factors was performed by the Tukey HSD test.All data were normally distributed.

Biomass Growth.
Te efects of arbuscular mycorrhizal fungi (AMF) treatment on root length, dry weight, fresh weight of root and shoot, and yield were found statistically diferent (p ≤ 0.001, p ≤ 0.05) in Unnayan, LT896, and Minto super tomatoes under drought stress.Te interaction efect of treatment and variety on root length, shoot's dry and fresh weight, and yield was signifcantly diferent (Supplementary Table (available here)).Te number of leaves, length of leaves, leaf width, branches, fresh and dry weight of roots, shoot length, and yield were found statistically similar to controls in A. morrowiae, P. occultum, F. mosseae, R. clarus, and R. intraradices-treated tomato plants (Figure 3).In R. intraradices-treated Minto super tomato, root length was signifcantly higher than that of the control (Figures 2 and 3).In Paraglomus occultum-treated Minto super tomato, shoot dry and fresh weight was signifcantly higher than that of other varieties.Te dry weight of the shoot was enhanced by 28% with AMF treatment compared to the control.Te yield of tomatoes increased by 20% with AMF treatment than that of non-AMF plants under drought stress (Figure 3).

Photosynthetic Pigments and Antioxidants.
Te efects of AMF treatment and the interaction results of treatment and varieties on chlorophyll and carotenoids were statistically similar in Unnayan, LT896, and Minto super tomato varieties.Efects of treatment and interaction results of treatment and varieties on catalase (CAT), hydrogen peroxide (H 2 O 2 ), malondialdehyde (MDA), and ascorbate peroxidase (APX) were noted signifcantly diferent (p ≤ 0.05) in tomatoes grown in soil under drought stress (Supplementary Table ).In A. morrowiae, P. occultum, F. mosseae, R. clarus, and R. intraradices treatments, chlorophyll a, chlorophyll b, total chlorophyll, and carotenoid were found statistically similar to controls in tomato varieties (Table 2).In P. occultum-treated plants, CAT activity in the Unnayan tomato was found statistically higher than that of the control.CAT activity in AMF-treated plants was found statistically similar to the control in LT896 and Minto super tomatoes (Table 2).Hydrogen peroxide (H 2 O 2 ) was detected lower in R. clarus-treated LT896 tomatoes than in controls.However, H 2 O 2 was recorded as statistically similar to the control in AMF-treated Unnayan and Minto super varieties (Table 2).In A. morrowiae and R. clarus-treated plants, APX activity was found signifcantly higher than that of control in Unnayan tomato.AMF treatment had no signifcant efect on APX activity in LT896 and Minto super tomato varieties.Similarly, MDA content in AMF-treated plants was statistically similar to the control (Table 2).CAT and APX activity was increased by 42% and 66% in AMF-treated Unnayan, LT896, and Minto super tomato varieties as compared with non-AMF/control under drought stress.In contrast, AMF Journal of Food Quality  2).Tese fndings suggest that AMF enhanced photosynthetic pigment and antioxidant activities in tomato leaves compared with the control (Figure 4).

Minerals.
Te efects of AMF treatment and the interaction result of treatment and varieties on sodium (Na), potassium (K), calcium (Ca), magnesium (Mg), and iron (Fe) in tomato fruits were statistically diferent in Unnayan, LT896, and Minto super tomato varieties grown in soil under drought stress.In AMF-treated tomato varieties, mineral contents increased signifcantly (Supplementary Table ).In P. occultum and R. intraradices-treated plants, Na was found statistically diferent from that of the control in Unnayan tomato (Table 2).Na content in AMF treatment was found statistically diferent in LT896 tomato compared with the control.In A. morrowiae, P. occultum, and F. mosseae-treated plants, Na was found statistically higher than that of the control in Minto super tomato (Table 2).Potassium (K) was found statistically higher in F. mosseae-treated Unnayan tomato than that of control.In contrast, in F. mosseae, R. clarus, and R. intraradices-treated plants, K was found statistically similar to the control in LT896 and Minto super tomato (Table 2).
In F. mosseae and R. intraradices-treated plants, Ca was found statistically higher than that of the control in the Unnayan tomato (Table 2).In F. mosseae, R. clarus, and R. intraradices treatments, Ca was found signifcantly higher than that of the control in LT896 tomato.Similarly, in R. intraradices treatment, Ca was found statistically higher than that of the control in Minto super tomato (Table 2).In R. clarus treatment, Mg was found signifcantly higher than that of control in Unnayan and LT896 tomatoes.Moreover, in R. clarus treatment, Fe was detected as signifcantly higher than that of the control in the Unnayan tomato (Table 2).In A. morrowiae, P. occultum, and R. clarus treatments, Fe was found statistically higher than that of the control in the LT896 tomato.On the other hand, in A. morrowiae, F. mosseae, and R. intraradices treatments, Fe was recorded as higher than that of the control in Minto super tomato (Table 2).K, Ca, Mg, and Fe of tomato fruits increased by 2%, 13%, 24%, and 37% with AMF treatments (Table 2).Tese results reveal that AMF enhanced mineral contents in tomato fruits compared with the control under drought stress (Figure 4).

Discussion
Te symbiotic relationship of arbuscular mycorrhizal fungi (AMF) with host plants is persistent for a prolonged period ensuring nutrient uptake into the host plant.Tus, AMF enhance biomass growth as well as enable the plant to resist environmental stresses.In this study, fve species of AMF (A. morrowiae, P. occultum, F. mosseae, R. clarus, and R. intraradices) were used to treat three popular tomato varieties under drought stress.AMF are well known for their ability to increase biomass growth by colonizing the majority of food crops [61].Here, we found that AMF increased shoot length, dry weight of root and shoots, leaves, and yield of tomato varieties (Figures 3 and 4).Te mechanism of biomass growth is directly connected with the extended hyphal network of AMF in the root zone.Te hyphal networks in non-AMF plants are much thinner than the roots of host plants [62,63].Tus, nutrients are readily available for the host plants when colonized with AMF [5,[64][65][66].AMF can also increase water use efciency and improve the quality of fruits [63].A similar growth efect of AMF is also found in many food crops such as S. lycopersicum L. [64], Sorghum bicolor (L.) [65], Withania somnifera (L.) [66], Cucurbita maxima [67], Piper longum L. [68], Phaseolus vulgaris L., Pisum sativum, Lens culinaris, and Vigna radiata [16,19,27].Arbuscular mycorrhizal fungi (AMF) can prompt the buildup of carotenoids, phenolics, and anthocyanins in the leaves of diferent food crops.In most cases, AMF increased the contents of carotenoids, chlorophylls, and tocopherols in green and red leaf lettuce.Tese molecules are also important to enhance the minerals in edible vegetables [69].For instance, chlorophyll contents are enhanced by 31-35% in AMF-treated pea crops [12].Similarly, chlorophyll contents were higher compared to control in mung beans grown in AMF soils [14,70].In this study, both chlorophyll and carotenoids were found higher in AMF-treated tomato varieties under drought stress (Table 2 and Figure 4).
AMF enhance antioxidant enzyme activity in food crops.Literature showed that SOD, CAT, and APX increased in AMF (R. irregularis)-treated Elaeagnus angustifolia L. plants [71].In peas, soil amendment with AMF increased CAT and POD activity by 24 to 46%.AMF also signifcantly improved the proline content in plants [42].Similarly, CAT activity was found higher than that of the control in P. occultumtreated Unnayan tomatoes.In A. morrowiae and R. clarustreated plants, APX activity was also found higher than that in the control (Table 2).Tus, soil amendment with AMF signifcantly improved antioxidant enzyme activity in food crops [12].
AMF produce glomalin, which is also known as glomalin-related soil protein (GRSP), which works as a glue that promotes the formation of water-stable aggregates by physical entanglement of extraradical hyphae, thus improving the water-holding capacity of the soil and stabilizing the structure of the soil [46].Additionally, AMF regulate antioxidant activities, osmolyte accumulation, and gene expression and maintain plant water status and photosynthetic performance under drought stress [47].As a result, AMF reduce drought stress in food crops through the stimulation of metabolites [72].In this aspect, increased metabolites decrease the osmotic potential in the AMFinoculated plants that improve the photosynthetic pigments [12].AMF plants also alter drought-induced oxidative stress by scavenging ROS through antioxidant activities [73].However, the activity of SOD, CAT, APX, and glutathione reductase (GR) increases through AMF inoculation in crops grown under drought stress [74].Te SOD is the principal defender for the reduction of oxidative stress.Several researchers also reported that AMF enhance APX, CAT, SOD, and GR activities, which verifed to improve biomass growth in food crops grown under drought stress [73].
In this study, the increased antioxidant potential in AMF-treated tomato plants reduces ROS.For example, H 2 O 2 content was detected higher in control than AMF (R. clarus)-treated LT896 tomato variety under stress.However, MDA was also found higher in the control than in the AMF-treated tomatoes under drought stress in this experiment (Table 2).An excessive amount of ROS such as hydroxyl radicals (_OH), superoxide radicals (O 2 -), singlet oxygen ( 1 O 2 ), and hydrogen peroxide (H 2 O 2 ) creates oxidative stress and damages membrane lipids, proteins, and nucleic acids and even causes the death of cells [75,76].In this situation, antioxidants enable the removal of ROS [77][78][79].Consequently, oxidative stress is reduced due to the minimization of ROS accumulation in plants under stress conditions [80,81].
AMF increase mineral contents in tomato fruits [82,83].In this experiment, Na, Ca, Mg, K, and Fe contents under A. morrowiae, P. occultum, R. clarus, R. intraradices, and F. mosseae treatments were found higher than those of the control (Table 2 and Figure 4).Te fungal structure of AMFlike arbuscules can assist in the exchange of inorganic minerals and compounds [84,85].Consequently, an association of AMF with host plants increases the nutritional value of fruits [82,86,87].Although the efect of AMF on the edible portions of plants is less clear, AMF can increase micronutrients and macronutrients in plants.For instance, AMF (Rhizophagus irregularis and Funneliformis mosseae) improve the quality of fruits, particularly minerals, vitamins, and favor compounds (sugars, titratable acids, and volatile compounds) in fruits [88].It was found that AMF inoculation increased the nutritional quality of tomato fruits.Likewise, antioxidant capacity, carotenoids, and volatile compounds were signifcantly higher in AMF plants compared with non-AMF under stress conditions.AMF might be used in other food crops grown in stress condition that will enhance nutritional quality and antioxidant activities [89].Taken together, these results show that AMF represent a promising resource for improving both sustainable food production and human nutritional needs for future demand throughout the world.

Conclusions
AMF increased biomass growth, yield, and nutritional quality in tomato cultivars (Unnayan, LT896, and Minto super) grown in soil under drought stress.Te shoot's dry weight and yield were enhanced by 28% and 20% on AMF-treated tomatoes, respectively, compared to the control under drought stress.AMF also increased the catalase (CAT) and ascorbate peroxidase (APX) activity as well as reduced MDA and hydrogen peroxide (H 2 O 2 ) content.CAT and APX activity increased by 42% and 66% in AMF-treated tomatoes compared to non-AMF.In contrast, AMF treatment decreased MDA and H 2 O 2 (ROS) in tomatoes by 50% and 2% compared to the control, respectively.K, Ca, Mg, and Fe of tomato fruits increased by 2%, 13%, 24%, and 37% with AMF treatments.Although AMF enhanced the yield and yieldcontributing attributes of tomato varieties in pot trials, further feld studies are suggested in multiple sites to verify these results.Tese results suggested that biomass growth, yield, photosynthetic pigments, antioxidant enzyme activity, and mineral contents could be enhanced by AMF in food crops grown under drought stress.It is concluded that AMF might be used for the development of AMF-enriched biofertilizers that will reduce fertilizer demand and improve the nutritional quality of food crops grown under stress conditions.

Figure 2 :
Figure 2: Mycorrhizal and non-mycorrhizal treated roots of tomato plants under drought stress.

Figure 3 :
Figure 3: Efect of AMF on (a) number of leaves, (b) length of leaves, (c) leaf width, (d) number of branches, (e) root length, (f ) shoot length, (g) dry weight of root, (h) fresh weight of root, (i) dry weight of shoot, (j) fresh weight of shoot, and (k) yield of Unnayan, LT896, and Minto super tomatoes (mean ± SEM) grown in soil under drought condition.Means denoted by diferent letters indicate a diference at 0.05% level of signifcance.Tree varieties, 5 replications, and 5 treatments with one control were used in this experiment.

Figure 4 :
Figure 4: Arbuscular mycorrhizal fungi increase biomass growth and antioxidant activity and reduce climate change-induced drought stress in tomato plants.

Table 1 :
Quality control (QC) for the determination of chemical properties, photosynthetic pigments, antioxidants, and minerals.

Table 2 :
Efect of AMF on photosynthetic pigments, antioxidant activity, and mineral content in tomatoes grown in soil under drought stress (3 varieties, 5 replications, and 5 treatments with one control).
8Journal of Food Quality treatment decreased MDA and H 2 O 2 (ROS) in tomatoes by 50% and 2% compared to the control, respectively (Table