Next Article in Journal
Evaluation of qPCR for the Selective Detection of Enteric Adenovirus Followed by Sequence-Based Genetic Characterization of F Strains Circulating in Brazil
Previous Article in Journal / Special Issue
Obtaining Novel Vitamin B12 Production Strains Acetobacter malorum HFD 3141 and Acetobacter orientalis HFD 3031 from Home-Fermented Sourdough
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Applied Microbiology
Volume 4
Issue 3
10.3390/applmicrobiol4030068
applmicrobiol-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Review

Beneficial Plant–Microbe Interactions and Stress Tolerance in Maize

by
Saroj Burlakoti
,
Ananta R. Devkota
,
Shital Poudyal
and
Amita Kaundal
*
Department of Plants, Soils, and Climate, College of Agriculture and Applied Science, Utah State University, Logan, UT 84332, USA
*
Author to whom correspondence should be addressed.
Appl. Microbiol. 2024, 4(3), 1000-1015; https://doi.org/10.3390/applmicrobiol4030068
Submission received: 4 June 2024 / Revised: 18 June 2024 / Accepted: 20 June 2024 / Published: 25 June 2024
(This article belongs to the Special Issue Current Trends in the Applications of Probiotics and Other Beneficial Microbes)
Browse Figure
Review Reports Versions Notes

Abstract

:
Beneficial microbes are crucial for improving crop adaptation and growth under various stresses. They enhance nutrient uptake, improve plant immune responses, and help plants tolerate stresses like drought, salinity, and heat. The yield potential of any crop is significantly influenced by its associated microbiomes and their potential to improve growth under different stressful environments. Therefore, it is crucial and exciting to understand the mechanisms of plant–microbe interactions. Maize (Zea mays L.) is one of the primary staple foods worldwide, in addition to wheat and rice. Maize is also an industrial crop globally, contributing 83% of its production for use in feed, starch, and biofuel industries. Maize requires significant nitrogen fertilization to achieve optimal growth and yield. Maize plants are highly susceptible to heat, salinity, and drought stresses and require innovative methods to mitigate the harmful effects of environmental stresses and reduce the use of chemical fertilizers. This review summarizes our current understanding of the beneficial interactions between maize plants and specific microbes. These beneficial microbes improve plant resilience to stress and increase productivity. For example, they regulate electron transport, downregulate catalase, and upregulate antioxidants. We also review the roles of plant growth-promoting rhizobacteria (PGPR) in enhancing stress tolerance in maize. Additionally, we explore the application of these microbes in maize production and identify major knowledge gaps that need to be addressed to utilize the potential of beneficial microbes fully.

1. Introduction

Maize (Zea mays L.), alongside wheat and rice, stands as one of the primary staple foods worldwide, boasting a global production of 1147.7 million metric tons in 2020 [1]. Maize has risen to prominence as an industrial crop on a global scale, with 83% of its production allocated for use in feed, starch, and biofuel industries. Among the 125 developing countries, approximately 75 consider maize a staple crop, contributing to 70% of the world’s maize production originating from these nations [2]. Maize is a nitrogen-hungry crop requiring a significant amount of nitrogen fertilization to achieve optimal growth and yield, particularly during its vegetative and early reproductive stages, which are more sensitive to nitrogen requirements. Inadequate nitrogen supply during these phases limits plant development, reduces photosynthetic efficiency, and ultimately, decreases grain yield [3,4]. Moreover, maize crops are extremely susceptible to heat, salinity, and drought stresses. Global maize yield is projected to decline by 20–40% under a 2 °C warming scenario and by 40–60% under a 4 °C warming scenario [5]. The variability in global maize production between 1980 and 2013 can be attributed to heat stress and drought [5]. Salinity stress further exacerbates challenges by decreasing the germination rate in maize. It causes osmotic stress, inhibiting water uptake by seeds delaying germination [6]. In salinity stress, the accumulation of Na+ competes with K+, leading to inhibition of protein synthesis [7]. This stress causes ionic toxicity, reactive oxygen species (ROS) generation, and osmotic stress [8]. In addition to abiotic stresses, between 6% and 19% of maize production worldwide is lost annually because of damage caused by insects and other herbivores. The primary pests of maize are Leaf aphids (Rhopalosiphum maidis), thrips (Frankliniella williamsi) [9], fall armyworm (Spodoptera frugiperda), black cutworms (Agrotis ípsilon), cotton bollworm (Helicoverpa armígera), corn earworm (Helicoverpa zea) [10], stalk borer (Elasmopalpus lignosellus), and armyworm (Spodoptera spp.).
Plant microbiomes are microorganisms that live in and around plants, forming a complex microbial ecosystem, and can play a significant role in plant growth and development. These microbiomes include bacteria, fungi, nematodes, archaea, and viruses that inhabit different parts of plants. These parts include the rhizosphere (soil surrounding roots), phyllosphere (above-ground parts like leaves and stems), endosphere (internal tissue), and spermosphere (seed surfaces) [11,12]. Beneficial plant–microbial interactions significantly affect plant growth and development and mitigate environmental stresses [13,14]. Plants are intimately associated with microbes during their growth and survival; they play a significant role in plant nutrient availability and uptake and plant stress tolerance [15]. Studies reported the presence of plant growth-promoting rhizobacteria from the native plant Ceanothus velutinus, which contains several rhizobacteria possessing plant growth-promoting traits such as the production of IAA, siderophore, protease, catalase, ability to fix nitrogen, and phosphate solubilization [16]. Moreover, inoculating native soil from Ceanothus velutinus with a propagation mix enhanced cutting propagation, and IAA-producing isolates from the rhizosphere promoted Arabidopsis growth [17]. Thus, exploring how plant microbiomes can improve maize yield and help it withstand different biotic and abiotic stresses is crucial. This review focuses on the beneficial plant–microbe interactions in maize to enhance yield and mitigate environmental stresses. The goal is to identify new strategies with high implementation potential to strengthen the agricultural economy and address the demand for practices that mitigate the effects of drought and other stress factors in maize production. Emphasizing the relationship between maize and its microbiome offers a promising research area for increasing productivity and yield.

2. Abiotic Stresses and Their Impact on Crop Productivity

To meet the high consumptive demand of maize, they are often grown in arid locations where maize may experience drought-related stress. The maize life cycle has various distinct growth stages, including seedling emergence and development, vegetative growth, flowering and pollination, grain filling, and maturation. Drought and high temperatures can negatively impact maize crops throughout these growth stages, with the most significant effects during the vegetative and grain-filling stages and when plants reach the eighth leaf stage [18]. In regions where water is scarce during the growing season, maize production may decline by up to 15% [19]. In China’s key maize-producing areas, approximately 60% of crops face water and heat stress, leading to a 30% reduction in annual yield [20]. Similarly, different studies have shown that a temperature increase of 6 °C above 35 °C for 3 days during the silking period reduced yield by 13% in the USA [21]; a temperature of 33 to 36 °C during the pre- and post-flowering stage reduced yield by 10–45% in Argentina [22]; and each degree above 30 °C in the reproductive stage decreased yield by 1–1.7% in Africa [23]. However, the most alarming prospect is the future. With ongoing climate change and global shifting weather patterns, water and heat stresses are projected to diminish the global maize supply by 15–20% annually [18]. Elevated temperatures exceeding 35 °C can impede maize crop’s reproductive and vegetative growth from seed germination to grain filling, the final stage [24]. Concurrently, when maize faces water and heat stresses during its reproductive phases, it becomes even more vulnerable [25]. The impact of drought stress on maize includes reduced leaf area, low water-use efficiency, lesser nutrient uptake, decreased photosynthetic efficiency, reduced biomass accumulation, and lower productivity. Studies have shown that water stress during vegetative growth can diminish the growth rate, decrease root system development, prolong the vegetative phase, and affect CO2 distribution. A brief period of water scarcity can lead to a 28–32% reduction in dry weight during vegetative growth and 66–93% during tasseling/ear formation [26]. Extended drought stress before flowering can decrease leaf size and internodal distance, delaying silk emergence and tasseling and resulting in a 15–25% overall yield decrease [27]. Additionally, even a few days of drought stress during pollination/fertilization can lead to abnormal embryo formation and fewer kernels per plant. Drought stress before and after pollination is associated with a significant decline in kernel set [27]. The primary photosynthetic activity of maize plants occurs in their five- or six-ear leaves, mainly contributing to plant biomass. However, drought stress can diminish the photosynthetic rate by reducing ear leaf size and slowing crop growth [28].
Higher temperatures at reproductive stages, such as tasseling, pollination, and grain filling, can lower maize grain quality. A study by Izaurralde et al. [29] suggests that increasing the mean seasonal temperature by 1 °C can reduce maize economic yield by 3–13%. The study by Hussain et al. [20] on two maize hybrids, Xida 319 and Xida 889, subjected to heat stress observed reduced plant height, lowered biomass accumulation, and decreased yield. Increased heat stress reduces the efficiency of light utilization in maize plants, thus leading to chlorophyll degradation. Additionally, increased temperature during the anthesis stage of maize cultivation results in reduced growth [30]. Similarly, exposure of maize to heat stress during the 12-leaf stage reduces pollen production, germination rate, zeatin content, salicylic acid content, and tassel size [31].
Salt stress is among several abiotic stresses affecting maize growth and yield. Increased salt concentration reduces plant height and biomass because of high osmotic stress and ion toxicity [32]. This reduction in growth is followed by decreased stomatal conductance and photosynthetic pigments, disturbance to cytosolic enzyme activity, and impairment of carbon fixation enzymes [33,34]. In a study by Kaya et al. [35], applying a salt concentration of 100 mM NaCl during the reproductive phase of maize reduced kernel weight and yield by 8% and 25%, respectively. Similarly, a study by Katerji et al. [36] showed an 11.3% reduction in maize grain yield in clay soil subjected to salinity stress. An increase in salt concentration interferes with the maize plant’s ability to absorb nitrate ions because of the antagonistic action between chloride and nitrate ions [37]. The effect of abiotic stress is described in Figure 1B.

3. Mechanism of Abiotic Stress Tolerance in Maize

Plants developed various mechanisms to cope with various abiotic stresses, which are described below for three major abiotic stresses in maize.

3.1. Drought Stress

To cope with drought stress, maize plants have evolved various mechanisms broadly categorized into escape, avoidance, and tolerance strategies [38]. Drought escape refers to shortening a crop’s life cycle to avoid drought stress, which is particularly crucial during reproductive growth stages. Traits like days to sowing, flowering, and maturity are genetically heritable, allowing for phenological adjustments in response to water availability [38]. Developing early-maturing cultivars aids in evading terminal drought stress [39]. However, this strategy may reduce yields, as crop duration directly correlates with yield [40]. Through selection, crops adjust their growth period based on available moisture, completing their life cycle before drought onset. Maize plants try to complete the reproductive stage before drought becomes more prevalent. Maize, being highly susceptible to drought, benefits significantly from this escape mechanism [41].
Drought avoidance in maize is assessed by measuring tissue water status, typically indicated by turgor water potential under drought stress conditions. Avoidance involves maintaining plant water status by reducing transpiration rates or increasing water uptake [42]. Various physiological and morphological traits are essential selection criteria for drought avoidance in maize, including leaf rolling, leaf firing, canopy temperature, stomatal closure, leaf attributes, and root traits [43]. Stomata regulate transpiration and gaseous exchange, governing photosynthesis and respiration. Plants reduce water loss by closing their stomata, preserving water status, and enhancing drought avoidance [40]. Drought tolerance for the combination of heat and drought stresses involves maintaining growth and development through cellular and biochemical adaptations. Along with sustaining average physical growth, drought tolerance is also associated with yield stability under water-stressed conditions, a complex process in which crops have developed various natural mechanisms to adapt and tolerate drought stress [44]. These adaptations include accumulating compatible osmolytes like proline, glycine betaine, soluble sugars, and various inorganic ions (K+, Na+, Ca2+, Mg2+, Cl, and NO3) to support plant water status via osmotic adjustment [44,45].
Additionally, the enzymatic and non-enzymatic antioxidant systems, including superoxide dismutase (SOD), catalase (CAT), peroxidase (POD), and ascorbate peroxidase (APX), are activated to mitigate oxidative damage. Growth regulators like abscisic acid (ABA) also play a role [20,28]. Moreover, transcription factors (TFs) are activated to regulate gene expression sensitive to drought and high temperatures, while stress proteins like heat shock proteins (HSPs), late embryogenesis abundant (LEA) proteins, and aquaporins assist in water movement under stress [41].
Similarly, antioxidants are molecules that protect plants by scavenging reactive oxygen species, thus preventing oxidative damage. They form a defense shield against oxidative stress. Antioxidants can be enzymatic or non-enzymatic. Enzymatic antioxidants include catalase (CAT), superoxide dismutase (SOD), glutathione reductase (GR), ascorbate peroxidase (APX), peroxidase, and polyphenol oxidase. Non-enzymatic antioxidants include α-tocopherol, ascorbic acid, β-carotene, glutathione, and cysteine [46]. These components are essential in neutralizing reactive oxygen species and preserving plant health under oxidative stress conditions. Plant hormones, also known as plant growth regulators or phytohormones, play vital roles in governing the growth and development of plants, acting as signaling molecules that trigger cellular differentiation and function locally or are transported to distant targets.
In response to drought stress, plants undergo various adaptations, including maintaining endogenous hormonal balance [47]. Different plant growth regulators confer drought tolerance, including auxins, cytokinins, abscisic acid (ABA), gibberellins, salicylic acid, brassinosteroids, methyl jasmonate, polyamines, ethylene, and zeatin. These hormones interact to regulate plant responses, specific growth stages, tissues, and environmental conditions. For instance, auxins are involved in drought stress responses, with interactions observed between ethylene, cytokinins, and auxins affecting their biosynthesis [48,49]. The concentration of indole acetic acid (IAA) decreases in maize leaves under drought stress, while the accumulation of ABA increases, influencing hormonal balance. IAA accumulation increases under moderate stress (13.4%) and decreases under severe drought stress (63.2%) in maize [28]. Salicylic acid helps maintain photosynthesis by retaining a higher chlorophyll content under drought stress, contributing to drought tolerance [50]. ABA and ethylene regulate stomatal conductance, grain number, grain-filling rate, and plant apex growth antagonistically, with cytokinin enhancing growth and development. ABA plays a crucial role as a stress hormone, modulating growth, development, and stress responses through a signaling pathway involving various components highly responsive to ABA. Average water availability does not induce ABA accumulation, and extremely severe drought reduces ABA accumulation because of the cessation of ABA precursors [51]. The antioxidant defense system detoxifies ROS and maintains redox homeostasis [52]. Overall plant hormonal balance is critical for various growth and development processes, with interactions among hormones playing a crucial role in plant adaptation to drought stress.

3.2. Salinity Stress

An imbalance in the cellular ion exchange process causes salinity stress in the plant. Because of this ionic imbalance, Na+ influx and K+ efflux through various ion transporters in the cell membrane [53]. The excess concentration of Na+ increases oxidative stress by enhancing ROS (reactive oxygen species) production [54]. Consequently, cellular membranes become disrupted, leading to a breakdown in cell homeostasis. During salinity stress, genes and transcription factors regulating ion transports are activated, which helps to alleviate ion toxicity in cells. These include plasma membrane protein (PMP), high sodium affinity transporter (HKT), the salt overly sensitive (SOS) pathway, and Na+/H+ exchangers (NHXs) [55]. ZmCIPK24a and ZmCBL4 plus ZmCBL8 act as SOS2 and SOS3 in maize [56]. During salinity stress, SOS3 senses changes in the cytoplasmic Ca2+ level, which activates SOS2. The SOS2-SOS3 complex phosphorylates ZmSOS1, activating SOS1 and increasing root-to-soil Na+ efflux, enhancing salt tolerance [57]. One study identified QTL for K+ content (qKC3), which encodes ZmHKT2, a K+ transporter localized in the xylem parenchyma [58]. ZmHKT2 reduces shoot K+ content by retrieving K+ from xylem vessels. Mutants lacking ZmHKT2 have higher shoot K+ content and salt tolerance [59]. Decreasing the activity of ZmHKT2 is a viable strategy for developing salt-tolerant maize varieties.

3.3. Heat Stress

Osmotic adjustment is a mechanism that helps maize plants cope with high temperatures. This involves creating a water gradient to enhance water influx, thereby maintaining turgor by reducing osmotic potential. This adjustment aids in preserving tissue water status by minimizing the detrimental effects of drought through the accumulation of solutes in cellular cytoplasm and vacuoles. By sustaining turgor potential and supporting physiological processes, osmotic adjustment protects against drought-induced damage [60]. Relative water content is a crucial indicator for estimating drought tolerance in plants with closed stomata and reduced CO2 accumulation resulting from decreased relative water content under drought stress [42]. The sustainable regulation of the photosynthetic rate and turgor potential ensures the translocation of photosynthetic assimilates to developing kernels [61]. Osmoprotectants, including nitrogenous compounds like proline, polyols, polyamines, and glycine betaine, as well as hydroxy compounds like polyhydric alcohols, sucrose, and oligosaccharides, play crucial roles in osmotic adjustment [62]. These compounds protect cellular proteins and membranes against dehydration effects and help maintain cellular integrity [63]. Glycine betaine, for instance, acts as an important osmoprotectant, safeguarding plants against various stresses such as drought, salinity, cold, and heat by protecting the photosynthetic apparatus and stabilizing cellular proteins [64]. Proline, another osmoprotectant, helps maintain water status, protect cellular membranes, and prevent protein denaturation under osmotic stress [64,65]. Soluble sugars, accumulated in response to drought stress, serve multiple roles in plant metabolism and protection, including acting as substrates for biosynthesis processes and protecting cellular organelles through vitrification [66]. Polyols, such as sorbitol, glycerol, and mannitol, form hydration spheres around macromolecules, safeguarding them from dehydration [67]. These mechanisms collectively contribute to plants’ ability to tolerate drought stress and maintain essential physiological processes.

4. Biotic Stress and Crop Production

Although abiotic stress is the major obstacle in attaining potential yield for maize production worldwide, biotic stress also threatens maize cultivation, often leading to substantial yield losses [68]. Diseases, insects, and pests are the primary factors responsible for these losses, with pathogens such as fungi, bacteria, and viruses eliciting syndromes like ear/stalk/kernel rot, rough dwarf/wilt disease, and northern leaf blight/maize mosaic [69], which are the major diseases that reduce maize yield. The simultaneous occurrence of abiotic and biotic stresses exacerbates the situation, resulting in a remarkable reduction in global maize production. Studies indicate that over 50% reduction in yield occurs in major crops, including maize because of abiotic stresses alone. In comparison, approximately 10% of maize productivity is lost annually to biotic stresses worldwide [70], and 22.5% of the global maize loss is due to diseases and pests. The European corn borer alone caused up to USD 2 billion in losses per year in the USA, while a 50% yield reduction by northern leaf blight occurred in northern regions of China [71]. Similarly, Colletotrichum graminicola, which causes anthracnose in maize, is a major threat responsible for the annual loss of up to USD 1 billion while maize weevil (Sitophilus zeamais) damages over 30% of grain during on-farm storage [70]. The production of highly carcinogenic aflatoxins by Aspergillus flavus alone has led to a staggering loss of USD 686.6 million in maize cultivation in the U.S. These statistics are not merely statistics, but a stark reminder of the economic havoc wreaked by biotic stress. Other climate-dependent pathogens, such as Fusarium spp. and Ustilago maydis, further compound the issue [72,73]. Among multiple strategies to deal with biotic stress caused by such pathogens, the use of polyamines (PAs) has emerged as an effective strategy in reducing biotic stress caused by various pathogens in maize. PAs play a crucial role in the production of H2O2, acting as both a defensive tool and a signaling molecule in response to biotic stress [73]. For example, spermine (Spm), a form of PA, functions as a signaling molecule in pathogen defense and plays a critical role in resistance against viral infections [74]. In the case of Ustilago maydis, a dimorphic host-specific fungus, it induces “huitlacoche” or common smut in maize plants. The accumulation of H2O2 derived from polyamine oxidase plays a significant role in tumor formation caused by U. maydis in maize plants. The maize polyamine oxidases (zMPAOs) transcription factor was found to be downregulated in tumors. The symptoms of the disease were observed to reduce upon application of 1,8-diamino octane (1,8-DO), a potent polyamine oxidase inhibitor [73]. The effect of abiotic stress is described in Figure 1B.

5. Beneficial Plant–Microbe Interactions in Maize

5.1. Arbuscular Mycorrhizal Symbiosis

Maize forms symbiotic associations with Arbuscular mycorrhizal (AM) fungi. This partnership, established via the mycorrhizal and root pathway, allows plants to uptake nutrients from the soil efficiently. In this symbiosis, fungi and plants engage in a mutual exchange where fungi provide mineral nutrients while plants supply carbon (C). Maize roots, in addition to beneficial relationships with microbes such as mycorrhizal fungi, play a crucial role in the uptake of nutrients like phosphorus (P) and nitrogen (N). Maize root residues, a significant byproduct of this symbiosis, provide N for other plants in crop rotation, thereby improving agricultural productivity [75,76]. This exchange occurs via arbuscules inside root cortex cells, where AM fungi acquire 4–20% of the total photosynthetic carbon fixed by the plant through symbiotic relationships. AM fungal hyphae then utilize this carbon to generate specialized exudates, which attract and establish a hyphosphere microbiome. This microbiome plays a crucial role in compensating for fungi’s incapacity to utilize organic nutrients directly. By secreting enzymes and fostering the mineralization of organic nutrient sources, the hyphosphere microbiome significantly increases nitrogen and phosphorus availability. This collaborative functionality within the holobiont substantially enhances nutrient accessibility for all interacting organisms, including plants, AM fungi, and hyphosphere bacteria (Figure 1C,D).
In maize, the colonization of maize roots by AM fungi begins early in the plant development phase, which peaks at the vegetative growth stages. Maize roots produce strigolactones (5-deoxy-strigol and Sorghumol), which are essential for establishing AM symbiosis [77,78]. These compounds act as chemoattractants and guide fungal hyphae toward the root system [79]. Upon contact with strigolactones, AM fungi initiate signaling cascades that activate genes such as SYM and RAM1 involved in colonization. Like other plants such as carrots, maize roots form pre-penetration apparatuses (PPAs) at the root surface to facilitate penetration of fungal hyphae into root tissue. Upon penetration, fungal hyphae initiate a series of molecular events, such as the production of chitin and lipochitooligosaccharides for recognition and signaling between plants and fungi [80]. Signal transduction also leads to the activation of transcription factors and arbuscule formation. Fungal-derived proteins, such as Small Secreted Effector Proteins (SSEPs), are transported into the plant cell and are believed to play roles in arbuscule formation and function [81]. Nutrient exchange between fungi and maize plants occurs within the arbuscules. In addition to arbuscules, vesicles are formed within root cells, which act as storage structures for lipids, glycogen, and other metabolites.
Once the symbiosis between AM fungi and maize plants is established, AM fungi can increase the root volume, increasing the surface area for water absorption. D-myo-inositol-3-phosphate synthase (IPS) and the 14-3-3-like protein GF14 (14-3GF) are pivotal in facilitating signal communication between maize and AMF during drought stress. Co-expression of these two genes has been shown to enhance maize drought tolerance significantly [82]. Similarly, AM fungi infection upregulates the expression level of NPF4.5 homologs, indicating higher nitrate uptake during symbiosis [82]. The ammonium transporter ZmAMT3;1 expressed in cortical cells of maize during AM fungi infection absorbs 68–70% of the transported nitrogen AM fungi to maize plants [83].

5.2. Nitrogen-Fixing Symbiosis with Rhizobia

Rhizobia, a widely distributed Gram-negative bacteria in soil, can enhance maize cultivation. Despite being primarily associated with legumes, these beneficial bacteria can promote growth and yield in maize through various mechanisms. While their efficiency with maize is generally lower than with legumes, the potential for improvement is promising [84].
The inoculation of the Azospirillum strain in maize roots was found to increase GA3 levels, thereby boosting root growth [85]. Similarly, the strains of Rhizobium (such as R. etli bv. Phaseoli and R. leguminosarum bv. trifolii) and Sinorhizobium sp. have shown promising results in enhancing growth, increasing plant height, and improving grain yield in maize [86]. Numerous studies have reported on the nitrogen-fixing ability of Herbaspirillum seopedicae and Azospirillum spp. in maize. A study on two maize genotypes, Morgan 318 and Dekalb 4D-70, demonstrated a significant increase in grain yield and higher N accumulation with the inoculation of a mixture of Azospirillum spp. strains, a result comparable to the application of 100 Kg N ha [87]. Another study unveiled the identification of a nitrogen-fixing association with the native variety of maize grown in nitrogen-depleted soils in Mexico. The microoxic environment for better nitrogen fixation is created by the mucilage tube surrounding the roots, which had a high abundance of proteobacteria [88]. These symbiotic relationships are crucial in enhancing plant growth, higher nutrient acquisition, and crop yield, offering a hopeful outlook for the future of maize cultivation.

5.3. Agricultural Application of Stress-Tolerant Microbes

The use of stress-tolerant microbes shows a significant increase in the yield of maize plants. Maize plants inoculated with Piriformospora indica, an endophytic fungus grown under drought stress conditions, had increased leaf area, SPAD value, higher root fresh and dry weight, and upregulated antioxidants including catalase and superoxide dismutase. Upregulating drought-related genes DREB2A, CBL1, ANAC072, and RD29A increased resistance to drought stress [89]. Bacillus spp. PM31 also improved maize growth under salinity stress [90]. Microbes can be applied to enhance plant yield and improve soil health. Stress-tolerant microbes can replace 20–40% of chemical fertilizers while alleviating drought stress impact. Integrating stress-tolerant bacteria with other beneficial microbes, such as AM fungi, can increase stress tolerance in maize and other plants, offering more significant agricultural benefits. These microbes can be integrated into agronomic practices through various application strategies that contribute to sustainable agriculture, as listed in Table 1.

5.4. Microbe-Mediated Induced Systemic Resistance (ISR) in Maize

Systemic Acquired Resistance (SAR) and Induced Systemic Resistance (ISR) are different mechanisms by which plants can develop systemic resistance against pathogens and diseases. SAR is a plant defense mechanism that protects plants against a broad spectrum of pathogens following an initial infection. SAR is induced by recognizing pathogen-associated molecular patterns (PAMPs) or effector molecules released by a pathogen [91]. ISR is a plant defense mechanism in which exposure to certain beneficial microorganisms, pathogens, or chemical compounds primes the plant’s immune system to enhance its resistance against subsequent pathogen attacks. Unlike SAR, which is induced by direct pathogen infection, ISR is triggered by beneficial microbes or certain chemical compounds in the plant environment [92].
ISR is a complex process that involves the activation of various defense responses within the plant, including the production of antimicrobial compounds, reinforcement of cell walls, and activation of defense-related genes. ISR is triggered by non-pathogenic rhizobacteria, which colonizes the rhizosphere. The microbes prime the plant’s innate immune system, enhancing its defense response against subsequent pathogen and insect attacks [93]. Specific microorganisms, such as beneficial rhizobacteria, B. velezensis SQR9, and the fungus Trichoderma harzianum, play crucial roles in inducing ISR in maize against pathogens. B. velezensis SQR9 colonizes maize roots and activates defense signaling pathways. This colonization leads to the enrichment of phenylpropanoid biosynthesis, amino acid metabolism, and plant–pathogen interaction pathways in maize roots. The calcium signaling pathway is pivotal in SQR9-induced ISR, as inhibiting calcium signaling weakens the induced resistance [58]. Similarly, T. harzianum triggers ISR in maize against Curvularia leaf spot by releasing cellulases and cellobiose from roots. Cellobiose released from T. harzianum-colonized roots prompts the expression of defense-related genes (Opr7, Pr4, Aoc1, Erf1) in maize, thereby enhancing ISR against the pathogen [94]. ISR in maize involves jasmonic acid and ethylene signaling pathways mediated by the NPR1 protein.
Table 1. Plant growth-promoting rhizobacteria (PGPR) that enhance stress tolerance in maize.
Table 1. Plant growth-promoting rhizobacteria (PGPR) that enhance stress tolerance in maize.
Host Associated Microbial StrainsEffect/Mechanism of Stress ToleranceReferences
Microbial-mediated beneficial drought stress tolerance
Rhizobium R. etli bv. Phaseoli, R. leguminosarum bv. Trifolii,
Sinorhizobium sp. 		Enhanced growth, increased plant height,
improved grain yield 		[86]
Herbaspirillum seopedicae
Azospirillum sp. 		Increased grain yield
Higher N accumulation 		[87]
Piriformospora indicaIncreased leaf area and SPAD value
Increased root fresh and dry weight
Decreased Malondialdehyde (MDA) accumulation
Upregulation of antioxidants and drought-related genes 		[89]
Pseudomonas putidaForm viable biofilms around roots
Increased soil holding capacity
Improved soil structure 		[95]
Pseudomonas aeruginosa
Alcaligenes faecalis
Proteus peneri		Increased soil moisture content
Enhanced plant growth traits such as leaf area, shoot length, and root length
Downregulation of catalase, ascorbate peroxidase, and glutathione peroxidase 		[96]
Klebsiella variicola
Pseudomonas fluorescens
Raoultella planticola		Increased levels of betaine, glycine, and choline
Improved plant growth 		[97]
Burkholderia sp.
Mitsuaria sp.		Increased proline and phytohormone accumulation
Higher antioxidant activity
Decreased MDA content 		[98]
Megathyrsus maximusIncreased proline accumulation
Decreased in MDA content
Reduced glutathione reductase activity 		[99]
Azospirillum brasilense
Pseudomonas putida
Sphingomonas		Symcoms containing these microbes had increased shoot dry weight, root dry weight, and plant height [100]
Azospirillum lipoferumIncreased proline and soluble sugar and amino acid accumulation
Enhanced shoot and root weight, root length 		[101,102]
Bacillus sp.Increased proline accumulation
Reduction in electrolyte leakage
Decreased activity of antioxidants 		[103]
Burkholderia phytofirmans Strain PsJN
Enterobacter sp. FD17		Increased root and shoot biomass
Higher chlorophyll content
Increased leaf area and photosynthetic rate 		[104]
Rhizophagus irregularisIncreased hydraulic conductivity and the water permeability coefficient
Increased phosphorylation of plasma membrane intrinsic proteins (PIPs)
Increased photosynthetic activity 		[105]
B pumilusIncreased relative water content and osmotic potential
Higher photosynthetic activity
Increased ABA production		[106]
Azospirillum brasilense SP-7
Herbaspirillum seropedicae Z-152		Decreased expression of ZmVP14 [107]
Microbial-mediated beneficial saline stress tolerance
Bacillus sp. PM31 Improved maize growth under salinity stress [90]
Co-inoculation of Rhizophagus intraradices
Massilia sp. RK4		Increased nutrient uptake
Increased AMF root colonization
Decreased leaf proline levels 		[108]
Rhizobium sp.
Pseudomonas sp.		Enhanced proline production
Decreasd electrolyte leakage
Reduced osmotic potential
Selective K ion uptake 		[109]
Pseudomonas fluorescens,
P. syringae, P. chlororaphis Enterobacter aerogenes		ACC-deaminase for increasing plant height, biomass, and cob yield
Higher grain mass and straw yield
Increased P and K uptake
Higher K+/Na+ ratio 		[110]
Glomus mosseaeEnhanced soluble sugar accumulation
Increased total organic acids, acetic acid, malic acid, oxalic acid, fumaric acid, and citric acid accumulation
Increased upregulation of the osmoregulation process 		[111]
B. amyloliquefaciens SQR9Increased chlorophyll content
Enhanced soluble sugar content
Decreased level of Na+
Upregulation of RBCS, RBCL, H+-PPase, HKT1, NHX1, NHX2, and NHX3 		[112]
Kocuria rhizophila Y1Increased photosynthetic capacity and relative water content
Increased antioxidant levels
Decreased level of Na+ 		[113]
Azotobacter chroococcumIncreased K+/Na+ ratio
Higher chlorophyll content
Increased proline concentration		[95]
Microbial-mediated beneficial heat stress tolerance
Bacillus sp. AH-08, AH-67, AH-16
Pseudomonas sp. SH-29		Upregulation of heat shock proteins (HSPs)
Increased total chlorophyll, catalase, and peroxidase
Enhanced plant height, leaf area, and root and shoot fresh and dry weight
Decreased concentration of MDA 		[114]
Rhizophagus intraradices
Funneliformis mosseae
F. geosporum		Increased quantum efficiency of PSII
Higher photosynthetic rate
Increased plant height, leaf width, and cob number 		[115]
Glomus etunicatumIncreased water content and leaf water potential
Increased photosynthetic activity
Higher stomatal conductance 		[116]
Glomus sp.Regulation of electron transport through PSII
Increased plant height and leaf width 		[117]

6. Challenges and Future Perspectives

The significant influence of abiotic and biotic stresses on the growth and development of maize plants cannot be overstated. Salt stress disrupts water uptake and nutrient acquisition, while drought stress hinders photosynthetic activity, decreasing maize yield. Despite their heat tolerance, prolonged exposure to temperatures exceeding 35 °C is detrimental to crop growth and development, and exceeding 40 °C during the flowering and grain-filling season will reduce grain productivity.
Despite the known benefits of plant–microbe interactions such as arbuscular mycorrhizal (AM) fungi and rhizobia, as well as bacterial and fungal endophytes, there is still much to learn about the diversity of beneficial microbes present in maize rhizosphere and their specific functions. Understanding which microbes are most helpful under different growing conditions and soil types is crucial for optimizing microbial inoculants. The interactions between introduced beneficial microbes and native soil microbiota are complex and poorly understood. Competition, cooperation, and antagonistic interactions among microbes can influence their effectiveness in promoting plant growth. To address the current challenges facing society and scientists, future work should focus on assessing the long-term durability of the effects caused by microorganisms. This includes evaluating the stability of these effects over multiple growing seasons and varying environmental conditions. Importantly, selecting the most effective microbial strains for specific conditions, such as drought, salinity, heat stress, or nutrient deficiency, is a key aspect. Educating farmers about the use and efficiency of biofertilizers is another important challenge.
More research is needed to assess the long-term effects of microbial inoculation on soil health, microbial community dynamics, and crop productivity. We are responsible for developing sustainable management practices that integrate microbial interactions into existing agricultural systems.

7. Conclusions

The positive interactions between maize plants and beneficial microbes offer a promising solution for enhancing plant growth and nutrient absorption under challenging environmental conditions. These interactions not only have the potential to bolster the environmental resiliency of maize production but can also promote sustainability. Beneficial microbes contribute by producing growth-promoting hormones, facilitating phosphorus availability, and enhancing photosynthesis and grain yield. They also bolster plant resilience to stresses like drought, salinity, and heat and can induce systemic resistance. Leveraging these microbes for stress defense has the potential to significantly boost crop yield and productivity, providing economic advantages to farmers while potentially reducing reliance on chemical inputs, thus benefiting the environment.

Author Contributions

A.K. and S.B. conceived the concept. S.B. wrote the original draft. A.K., A.R.D. and S.P. edited and reviewed this article. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding. This work is the product of the final assignment in a graduate-level course in Plant–Microbe Interactions.

Conflicts of Interest

The authors declare no conflicts of interest.

References

  1. Chávez-Arias, C.C.; Ligarreto-Moreno, G.A.; Ramírez-Godoy, A.; Restrepo-Díaz, H. Maize Responses Challenged by Drought, Elevated Daytime Temperature and Arthropod Herbivory Stresses: A Physiological, Biochemical and Molecular View. Front. Plant Sci. 2021, 12, 702841. [Google Scholar] [CrossRef] [PubMed]
  2. Nyirenda, H.; Mwangomba, W.; Nyirenda, E.M. Delving into Possible Missing Links for Attainment of Food Security in Central Malawi: Farmers’ Perceptions and Long Term Dynamics in Maize (Zea mays L.) Production. Heliyon 2021, 7, e07130. [Google Scholar] [CrossRef] [PubMed]
  3. Asibi, A.E.; Chai, Q.; A. Coulter, J. Mechanisms of Nitrogen Use in Maize. Agronomy 2019, 9, 775. [Google Scholar] [CrossRef]
  4. Gheith, E.M.S.; El-Badry, O.Z.; Lamlom, S.F.; Ali, H.M.; Siddiqui, M.H.; Ghareeb, R.Y.; El-Sheikh, M.H.; Jebril, J.; Abdelsalam, N.R.; Kandil, E.E. Maize (Zea mays L.) Productivity and Nitrogen Use Efficiency in Response to Nitrogen Application Levels and Time. Front. Plant Sci. 2022, 13, 941343. [Google Scholar] [CrossRef]
  5. Maitah, M.; Malec, K.; Maitah, K. Influence of Precipitation and Temperature on Maize Production in the Czech Republic from 2002 to 2019. Sci. Rep. 2021, 11, 10467. [Google Scholar] [CrossRef]
  6. AbdElgawad, H.; Zinta, G.; Hegab, M.M.; Pandey, R.; Asard, H.; Abuelsoud, W. High Salinity Induces Different Oxidative Stress and Antioxidant Responses in Maize Seedlings Organs. Front. Plant Sci. 2016, 7, 276. [Google Scholar] [CrossRef]
  7. Schachtman, D.; Liu, W. Molecular Pieces to the Puzzle of the Interaction between Potassium and Sodium Uptake in Plants. Trends Plant Sci. 1999, 4, 281–287. [Google Scholar] [CrossRef]
  8. Chawla, S.; Jain, S.; Jain, V. Salinity Induced Oxidative Stress and Antioxidant System in Salt-Tolerant and Salt-Sensitive Cultivars of Rice (Oryza sativa L.). J. Plant Biochem. Biotechnol. 2011, 22, 27–34. [Google Scholar] [CrossRef]
  9. Corona, A.O. Insect Pests of Maize: A Guide for Field Identification; CIMMYT: Mexico City, Mexico, 1987. [Google Scholar]
  10. Widstrom, N.W. The Role of Insects and Other Plant Pests in Aflatoxin Contamination of Corn, Cotton, and Peanuts—A Review. J. Environ. Qual. 1979, 8, 5–11. [Google Scholar] [CrossRef]
  11. Shelake, R.M.; Pramanik, D.; Kim, J.-Y. Exploration of Plant-Microbe Interactions for Sustainable Agriculture in CRISPR Era. Microorganisms 2019, 7, 269. [Google Scholar] [CrossRef]
  12. Rochefort, A.; Simonin, M.; Marais, C.; Guillerm-Erckelboudt, A.-Y.; Barret, M.; Sarniguet, A. Transmission of Seed and Soil Microbiota to Seedling. mSystems 2021, 6, e0044621. [Google Scholar] [CrossRef] [PubMed]
  13. Harman, G.; Khadka, R.; Doni, F.; Uphoff, N. Benefits to Plant Health and Productivity from Enhancing Plant Microbial Symbionts. Front. Plant Sci. 2021, 11, 610065. [Google Scholar] [CrossRef] [PubMed]
  14. Vocciante, M.; Grifoni, M.; Fusini, D.; Petruzzelli, G.; Franchi, E. The Role of Plant Growth-Promoting Rhizobacteria (PGPR) in Mitigating Plant’s Environmental Stresses. Appl. Sci. 2022, 12, 1231. [Google Scholar] [CrossRef]
  15. Zilber-Rosenberg, I.; Rosenberg, E. Role of Microorganisms in the Evolution of Animals and Plants: The Hologenome Theory of Evolution. FEMS Microbiol. Rev. 2008, 32, 723–735. [Google Scholar] [CrossRef] [PubMed]
  16. Ganesh, J.; Singh, V.; Hewitt, K.; Kaundal, A. Exploration of the Rhizosphere Microbiome of Native Plant Ceanothus velutinus—An Excellent Resource of Plant Growth-Promoting Bacteria. Front. Plant Sci. 2022, 13, 979069. [Google Scholar] [CrossRef] [PubMed]
  17. Ganesh, J.; Hewitt, K.; Devkota, A.R.; Wilson, T.; Kaundal, A. IAA-Producing Plant Growth Promoting Rhizobacteria from Ceanothus velutinus Enhance Cutting Propagation Efficiency and Arabidopsis Biomass. Front. Plant Sci. 2024, 15, 1374877. [Google Scholar] [CrossRef] [PubMed]
  18. Kim, K.-H.; Lee, B.-M. Effects of Climate Change and Drought Tolerance on Maize Growth. Plants 2023, 12, 3548. [Google Scholar] [CrossRef]
  19. Ziyomo, C.; Bernardo, R. Drought Tolerance in Maize: Indirect Selection through Secondary Traits versus Genomewide Selection. Crop Sci. 2013, 53, 1269–1275. [Google Scholar] [CrossRef]
  20. Hussain, H.A.; Men, S.; Hussain, S.; Chen, Y.; Ali, S.; Zhang, S.; Zhang, K.; Li, Y.; Xu, Q.; Liao, C.; et al. Interactive Effects of Drought and Heat Stresses on Morpho-Physiological Attributes, Yield, Nutrient Uptake and Oxidative Status in Maize Hybrids. Sci. Rep. 2019, 9, 3890. [Google Scholar] [CrossRef] [PubMed]
  21. Siebers, M.H.; Slattery, R.A.; Yendrek, C.R.; Locke, A.M.; Drag, D.; Ainsworth, E.A.; Bernacchi, C.J.; Ort, D.R. Simulated Heat Waves during Maize Reproductive Stages Alter Reproductive Growth but Have No Lasting Effect When Applied during Vegetative Stages. Agric. Ecosyst. Environ. 2017, 240, 162–170. [Google Scholar] [CrossRef]
  22. Neiff, N.; Trachsel, S.; Valentinuz, O.R.; Balbi, C.N.; Andrade, F.H. High Temperatures around Flowering in Maize: Effects on Photosynthesis and Grain Yield in Three Genotypes. Crop Sci. 2016, 56, 2702–2712. [Google Scholar] [CrossRef]
  23. Lobell, D.B.; Bänziger, M.; Magorokosho, C.; Vivek, B. Nonlinear Heat Effects on African Maize as Evidenced by Historical Yield Trials. Nat. Clim. Chang. 2011, 1, 42–45. [Google Scholar] [CrossRef]
  24. Hatfield, J. Increased Temperatures Have Dramatic Effects on Growth and Grain Yield of Three Maize Hybrids. Agric. Environ. Lett. 2016, 1, 150006. [Google Scholar] [CrossRef]
  25. Boehlein, S.K.; Liu, P.; Webster, A.; Ribeiro, C.; Suzuki, M.; Wu, S.; Guan, J.-C.; Stewart, J.D.; Tracy, W.F.; Settles, A.M.; et al. Effects of Long-Term Exposure to Elevated Temperature on Zea mays Endosperm Development during Grain Fill. Plant J. 2019, 99, 23–40. [Google Scholar] [CrossRef] [PubMed]
  26. Cakir, R. Effect of Water Stress at Different Development Stages on Vegetative and Reproductive Growth of Corn. Field Crops Res. 2004, 89, 1–16. [Google Scholar] [CrossRef]
  27. Hütsch, B.W.; Faust, F.; Jung, S.; Schubert, S. Drought Stress during Maize Flowering May Cause Kernel Abortion by Inhibition of Plasma Membrane H+-ATPase Activity. J. Plant Nutr. Soil Sci. 2024, 187, 321–332. [Google Scholar] [CrossRef]
  28. Aslam, M.; Maqbool, M.A.; Cengiz, R. Drought Stress in Maize (Zea mays L.): Effects, Resistance Mechanism, Global Achievements and Biological Strategies for Improvement; Springer: Berlin/Heidelberg, Germany, 2015; ISBN 978-3-319-25442-5. [Google Scholar]
  29. Izaurralde, R.C.; Thomson, A.M.; Morgan, J.A.; Fay, P.A.; Polley, H.W.; Hatfield, J.L. Climate Impacts on Agriculture: Implications for Forage and Rangeland Production. Agron. J. 2011, 103, 371–381. [Google Scholar] [CrossRef]
  30. Gabaldón-Leal, C.; Webber, H.; Otegui, M.E.; Slafer, G.A.; Ordóñez, R.A.; Gaiser, T.; Lorite, I.J.; Ruiz-Ramos, M.; Ewert, F. Modelling the Impact of Heat Stress on Maize Yield Formation. Field Crops Res. 2016, 198, 226–237. [Google Scholar] [CrossRef]
  31. Sun, J.; Wang, H.; Ren, H.; Zhao, B.; Zhang, J.; Ren, B.; Liu, P. Maize (Zea mays L.) Responses to Heat Stress: Mechanisms That Disrupt the Development and Hormone Balance of Tassels and Pollen. J. Agron. Crop Sci. 2023, 209, 502–516. [Google Scholar] [CrossRef]
  32. Singh, V.; Krause, M.; Sandhu, D.; Sekhon, R.S.; Kaundal, A. Salinity Stress Tolerance Prediction for Biomass-Related Traits in Maize (Zea mays L.) Using Genome-Wide Markers. Plant Genome 2023, 16, e20385. [Google Scholar] [CrossRef]
  33. Farooq, M.; Hussain, M.; Wakeel, A.; Siddique, K.H.M. Salt Stress in Maize: Effects, Resistance Mechanisms, and Management. A Review. Agron. Sustain. Dev. 2015, 35, 461–481. [Google Scholar] [CrossRef]
  34. Gong, X.; Chao, L.; Zhou, M.; Hong, M.; Luo, L.; Wang, L.; Ying, W.; Jingwei, C.; Songjie, G.; Fashui, H. Oxidative Damages of Maize Seedlings Caused by Exposure to a Combination of Potassium Deficiency and Salt Stress. Plant Soil 2011, 340, 443–452. [Google Scholar] [CrossRef]
  35. Kaya, C.; Ashraf, M.; Dikilitas, M.; Tuna, A.L. Alleviation of Salt Stress-Induced Adverse Effects on Maize Plants by Exogenous Application of Indoleacetic Acid (IAA) and Inorganic Nutrients—A Field Trial. Aust. J. Crop Sci. 2013, 7, 249–254. [Google Scholar]
  36. Katerji, N.; van Hoorn, J.W.; Hamdy, A.; Karam, F.; Mastrorilli, M. Effect of Salinity on Water Stress, Growth, and Yield of Maize and Sunflower. Agric. Water Manag. 1996, 30, 237–249. [Google Scholar] [CrossRef]
  37. Shahzad, M.; Witzel, K.; Zörb, C.; Mühling, K.H. Growth-Related Changes in Subcellular Ion Patterns in Maize Leaves (Zea mays L.) under Salt Stress. J. Agron. Crop Sci. 2012, 198, 46–56. [Google Scholar] [CrossRef]
  38. Arshad, M.; Ranamukhaarachchi, S.L.; Ahmad, S.; Nawaz, R.; Qayyum, M.M.N.; Razaq, A.; Faiz, F. Variability and Correlation of Selected Soil Attributes and Maize Yield Influenced by Tillage Systems in Mountainous Agroecosystem. J. Soil Water Conserv. 2022, 77, 466–481. [Google Scholar] [CrossRef]
  39. Kumar, J.; Abbo, S. Genetics of Flowering Time in Chickpea and Its Bearing on Productivity in Semiarid Environments. Adv. Agron. 2001, 72, 107–138. [Google Scholar] [CrossRef]
  40. Turner, N.; Wright, G.; Siddique, K. Adaptation of Grain Legumes (Pulses) to Water-Limited Environments. Adv. Agron. 2001, 71, 193–231. [Google Scholar] [CrossRef]
  41. Khan, S.; Anwar, S.; Ashraf, M.Y.; Khaliq, B.; Sun, M.; Hussain, S.; Gao, Z.; Noor, H.; Alam, S. Mechanisms and Adaptation Strategies to Improve Heat Tolerance in Rice. A Review. Plants 2019, 8, 508. [Google Scholar] [CrossRef]
  42. Seleiman, M.F.; Al-Suhaibani, N.; Ali, N.; Akmal, M.; Alotaibi, M.; Refay, Y.; Dindaroglu, T.; Abdul-Wajid, H.H.; Battaglia, M.L. Drought Stress Impacts on Plants and Different Approaches to Alleviate Its Adverse Effects. Plants 2021, 10, 259. [Google Scholar] [CrossRef]
  43. Zhang, F.; Wang, P.; Zou, Y.-N.; Wu, Q.-S.; Kuča, K. Effects of Mycorrhizal Fungi on Root-Hair Growth and Hormone Levels of Taproot and Lateral Roots in Trifoliate Orange under Drought Stress. Arch. Agron. Soil Sci. 2019, 65, 1316–1330. [Google Scholar] [CrossRef]
  44. Blum, A. Osmotic Adjustment Is a Prime Drought Stress Adaptive Engine in Support of Plant Production. Plant Cell Environ. 2017, 40, 4–10. [Google Scholar] [CrossRef]
  45. Lamaoui, M.; Jemo, M.; Datla, R.; Bekkaoui, F. Heat and Drought Stresses in Crops and Approaches for Their Mitigation. Front. Chem. 2018, 6, 26. [Google Scholar] [CrossRef]
  46. Rajput, V.D.; Harish; Singh, R.K.; Verma, K.K.; Sharma, L.; Quiroz-Figueroa, F.R.; Meena, M.; Gour, V.S.; Minkina, T.; Sushkova, S.; et al. Recent Developments in Enzymatic Antioxidant Defence Mechanism in Plants with Special Reference to Abiotic Stress. Biology 2021, 10, 267. [Google Scholar] [CrossRef]
  47. Wang, C.; Yang, A.; Yin, H.; Zhang, J. Influence of Water Stress on Endogenous Hormone Contents and Cell Damage of Maize Seedlings. J. Integr. Plant Biol. 2008, 50, 427–434. [Google Scholar] [CrossRef]
  48. Jones, B.; Gunnerås, S.A.; Petersson, S.V.; Tarkowski, P.; Graham, N.; May, S.; Dolezal, K.; Sandberg, G.; Ljung, K. Cytokinin Regulation of Auxin Synthesis in Arabidopsis Involves a Homeostatic Feedback Loop Regulated via Auxin and Cytokinin Signal Transduction. Plant Cell 2010, 22, 2956–2969. [Google Scholar] [CrossRef]
  49. Weiss, D.; Ori, N. Mechanisms of Cross Talk between Gibberellin and Other Hormones. Plant Physiol. 2007, 144, 1240–1246. [Google Scholar] [CrossRef]
  50. Rao, S.R.; Qayyum, A.; Razzaq, A.; Ahmad, M.; Mahmood, I.; Sher, A. Role of Foliar Application of Salicylic Acid and L-Tryptophan in Drought Tolerance of Maize. J. Anim. Plant Sci. 2012, 22, 768–772. [Google Scholar]
  51. Shen, Y.-Y.; Wang, X.-F.; Wu, F.-Q.; Du, S.-Y.; Cao, Z.; Shang, Y.; Wang, X.-L.; Peng, C.-C.; Yu, X.-C.; Zhu, S.-Y.; et al. The Mg-Chelatase H Subunit Is an Abscisic Acid Receptor. Nature 2006, 443, 823–826. [Google Scholar] [CrossRef]
  52. Hasanuzzaman, M.; Bhuyan, M.H.M.B.; Zulfiqar, F.; Raza, A.; Mohsin, S.M.; Mahmud, J.A.; Fujita, M.; Fotopoulos, V. Reactive Oxygen Species and Antioxidant Defense in Plants under Abiotic Stress: Revisiting the Crucial Role of a Universal Defense Regulator. Antioxidants 2020, 9, 681. [Google Scholar] [CrossRef]
  53. Sandhu, D.; Kaundal, A. Dynamics of Salt Tolerance: Molecular Perspectives. In Biotechnologies of Crop Improvement, Volume 3: Genomic Approaches; Gosal, S.S., Wani, S.H., Eds.; Springer International Publishing: Cham, Switzerland, 2018; pp. 25–40. ISBN 978-3-319-94746-4. [Google Scholar]
  54. Amin, I.; Rasool, S.; Mir, M.A.; Wani, W.; Masoodi, K.Z.; Ahmad, P. Ion Homeostasis for Salinity Tolerance in Plants: A Molecular Approach. Physiol. Plant 2021, 171, 578–594. [Google Scholar] [CrossRef] [PubMed]
  55. Basu, S.; Kumar, A.; Benazir, I.; Kumar, G. Reassessing the Role of Ion Homeostasis for Improving Salinity Tolerance in Crop Plants. Physiol. Plant. 2021, 171, 502–519. [Google Scholar] [CrossRef] [PubMed]
  56. Zhou, X.; Li, J.; Wang, Y.; Liang, X.; Zhang, M.; Lu, M.; Guo, Y.; Qin, F.; Jiang, C. The Classical SOS Pathway Confers Natural Variation of Salt Tolerance in Maize. New Phytol. 2022, 236, 479–494. [Google Scholar] [CrossRef] [PubMed]
  57. Yang, Y.; Guo, Y. Elucidating the Molecular Mechanisms Mediating Plant Salt-Stress Responses. New Phytol. 2018, 217, 523–539. [Google Scholar] [CrossRef] [PubMed]
  58. Cao, Y.; Wang, Y.; Gui, C.; Nguvo, K.J.; Ma, L.; Wang, Q.; Shen, Q.; Zhang, R.; Gao, X. Beneficial Rhizobacterium Triggers Induced Systemic Resistance of Maize to Gibberella Stalk Rot via Calcium Signaling. Mol. Plant Microbe Interact. 2023, 36, 516–528. [Google Scholar] [CrossRef] [PubMed]
  59. Yao, X.; Horie, T.; Xue, S.; Leung, H.-Y.; Katsuhara, M.; Brodsky, D.E.; Wu, Y.; Schroeder, J.I. Differential Sodium and Potassium Transport Selectivities of the Rice OsHKT2;1 and OsHKT2;2 Transporters in Plant Cells. Plant Physiol. 2009, 152, 341–355. [Google Scholar] [CrossRef] [PubMed]
  60. 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; 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 978-3-319-28899-4. [Google Scholar]
  61. Subbarao, G.V.; Nam, N.H.; Chauhan, Y.S.; Johansen, C. Osmotic Adjustment, Water Relations and Carbohydrate Remobilization in Pigeonpea under Water Deficits. J. Plant Physiol. 2000, 157, 651–659. [Google Scholar] [CrossRef]
  62. Ghosh, U.K.; Islam, M.N.; Siddiqui, M.N.; Khan, M.A.R. Understanding the Roles of Osmolytes for Acclimatizing Plants to Changing Environment: A Review of Potential Mechanism. Plant Signal. Behav. 2021, 16, 1913306. [Google Scholar] [CrossRef] [PubMed]
  63. Yancey, P.H. Compatible and Counteracting Solutes: Protecting Cells from the Dead Sea to the Deep Sea. Sci. Prog. 2004, 87, 1–24. [Google Scholar] [CrossRef]
  64. Ashraf, M.; Foolad, M.R. Roles of Glycine Betaine and Proline in Improving Plant Abiotic Stress Resistance. Environ. Exp. Bot. 2007, 59, 206–216. [Google Scholar] [CrossRef]
  65. Yoshiba, Y.; Kiyosue, T.; Nakashima, K.; Yamaguchi-Shinozaki, K.; Shinozaki, K. Regulation of Levels of Proline as an Osmolyte in Plants under Water Stress. Plant Cell Physiol. 1997, 38, 1095–1102. [Google Scholar] [CrossRef]
  66. Rosa, M.; Prado, C.; Podazza, G.; Interdonato, R.; González, J.A.; Hilal, M.; Prado, F.E. Soluble Sugars—Metabolism, Sensing and Abiotic Stress. Plant Signal. Behav. 2009, 4, 388–393. [Google Scholar] [CrossRef]
  67. Liu, F.-F.; Ji, L.; Zhang, L.; Dong, X.-Y.; Sun, Y. Molecular Basis for Polyol-Induced Protein Stability Revealed by Molecular Dynamics Simulations. J. Chem. Phys. 2010, 132, 225103. [Google Scholar] [CrossRef]
  68. Njeru, F.; Wambua, A.; Muge, E.; Haesaert, G.; Gettemans, J.; Misinzo, G. Major Biotic Stresses Affecting Maize Production in Kenya and Their Implications for Food Security. PeerJ 2023, 11, e15685. [Google Scholar] [CrossRef]
  69. Lodha, T.D.; Hembram, P.; Nitile Tep, J.B. Proteomics: A Successful Approach to Understand the Molecular Mechanism of Plant-Pathogen Interaction. Am. J. Plant Sci. 2013, 2013, 32899. [Google Scholar] [CrossRef]
  70. Gong, F.; Yang, L.; Tai, F.; Hu, X.; Wang, W. “Omics” of Maize Stress Response for Sustainable Food Production: Opportunities and Challenges. Omics J. Integr. Biol. 2014, 18, 714–732. [Google Scholar] [CrossRef]
  71. Basu, S.K.; Dutta, M.; Goyal, A.; Bhowmik, P.K.; Kumar, J.; Nandy, S.; Scagliusi, S.M.; Prasad, R. Is Genetically Modified Crop the Answer for the next Green Revolution? GM Crops 2010, 1, 68–79. [Google Scholar] [CrossRef]
  72. Hung, H.-Y.; Shannon, L.M.; Tian, F.; Bradbury, P.J.; Chen, C.; Flint-Garcia, S.A.; McMullen, M.D.; Ware, D.; Buckler, E.S.; Doebley, J.F.; et al. ZmCCT and the Genetic Basis of Day-Length Adaptation Underlying the Postdomestication Spread of Maize. Proc. Natl. Acad. Sci. USA 2012, 109, E1913–E1921. [Google Scholar] [CrossRef]
  73. Jasso-Robles, F.I.; Jiménez-Bremont, J.F.; Becerra-Flora, A.; Juárez-Montiel, M.; Gonzalez, M.E.; Pieckenstain, F.L.; García De La Cruz, R.F.; Rodríguez-Kessler, M. Inhibition of Polyamine Oxidase Activity Affects Tumor Development during the Maize-Ustilago maydis Interaction. Plant Physiol. Biochem. 2016, 102, 115–124. [Google Scholar] [CrossRef]
  74. Takahashi, Y.; Berberich, T.; Miyazaki, A.; Seo, S.; Ohashi, Y.; Kusano, T. Spermine Signalling in Tobacco: Activation of Mitogen-Activated Protein Kinases by Spermine Is Mediated through Mitochondrial Dysfunction. Plant J. 2003, 36, 820–829. [Google Scholar] [CrossRef] [PubMed]
  75. Herridge, D.F.; Peoples, M.B.; Boddey, R.M. Global Inputs of Biological Nitrogen Fixation in Agricultural Systems. Plant Soil 2008, 311, 1–18. [Google Scholar] [CrossRef]
  76. Peoples, M.B.; Brockwell, J.; Herridge, D.F.; Rochester, I.J.; Alves, B.J.R.; Urquiaga, S.; Boddey, R.M.; Dakora, F.D.; Bhattarai, S.; Maskey, S.L.; et al. The Contributions of Nitrogen-Fixing Crop Legumes to the Productivity of Agricultural Systems. Symbiosis 2009, 48, 1–17. [Google Scholar] [CrossRef]
  77. Akiyama, K.; Hayashi, H. Strigolactones: Chemical Signals for Fungal Symbionts and Parasitic Weeds in Plant Roots. Ann. Bot. 2006, 97, 925–931. [Google Scholar] [CrossRef]
  78. Lucido, A.; Andrade, F.; Basallo, O.; Eleiwa, A.; Marin-Sanguino, A.; Vilaprinyo, E.; Sorribas, A.; Alves, R. Modeling the Effects of Strigolactone Levels on Maize Root System Architecture. Front. Plant Sci. 2024, 14, 1329556. [Google Scholar] [CrossRef]
  79. Guan, J.C.; Koch, K.E.; Suzuki, M.; Wu, S.; Latshaw, S.; Petruff, T.; Goulet, C.; Klee, H.J.; McCarty, D.R. Diverse Roles of Strigolactone Signaling in Maize Architecture and the Uncoupling of a Branching-Specific Subnetwork. Plant Physiol. 2012, 160, 1303–1317. [Google Scholar] [CrossRef]
  80. Genre, A.; Chabaud, M.; Timmers, T.; Bonfante, P.; Barker, D.G. Arbuscular Mycorrhizal Fungi Elicit a Novel Intracellular Apparatus in Medicago Truncatula Root Epidermal Cells before Infection. Plant Cell 2005, 17, 3489–3499. [Google Scholar] [CrossRef]
  81. Mortier, E.; Mounier, A.; Kreplak, J.; Martin-Laurent, F.; Recorbet, G.; Lamotte, O. Evidence That a Common Arbuscular Mycorrhizal Network Alleviates Phosphate Shortage in Interconnected Walnut Sapling and Maize Plants. Front. Plant Sci. 2023, 14, 1206047. [Google Scholar] [CrossRef]
  82. Wang, Q.; Liu, M.; Wang, Z.; Li, J.; Liu, K.; Huang, D. The Role of Arbuscular Mycorrhizal Symbiosis in Plant Abiotic Stress. Front. Microbiol. 2024, 14, 1323881. [Google Scholar] [CrossRef]
  83. Hui, J.; An, X.; Li, Z.; Neuhäuser, B.; Ludewig, U.; Wu, X.; Schulze, W.; Chen, F.; Feng, G.; Lambers, H.; et al. The Mycorrhiza-Specific Ammonium Transporter ZmAMT3;1 Mediates Mycorrhiza-Dependent Nitrogen Uptake in Maize Roots. Plant Cell 2022, 34, 4066–4087. [Google Scholar] [CrossRef]
  84. Cheng, Z.; Meng, L.; Yin, T.; Li, Y.; Zhang, Y.; Li, S. Changes in Soil Rhizobia Diversity and Their Effects on the Symbiotic Efficiency of Soybean Intercropped with Maize. Agronomy 2023, 13, 997. [Google Scholar] [CrossRef]
  85. Lucas, T.M.R.; Carlos, H.C.; Fabio, L.C.M.; Gustavo, V.M. Azospirillum spp. Potential for Maize Growth and Yield. Afr. J. Biotechnol. 2018, 17, 574–585. [Google Scholar] [CrossRef]
  86. Hayat, R.; Ahmed, I.; Sheirdil, R.A. An Overview of Plant Growth Promoting Rhizobacteria (PGPR) for Sustainable Agriculture. In Crop Production for Agricultural Improvement; Ashraf, M., Öztürk, M., Ahmad, M.S.A., Aksoy, A., Eds.; Springer: Dordrecht, The Netherlands, 2012; pp. 557–579. ISBN 978-94-007-4115-7. [Google Scholar]
  87. Garcia de Salamone, I.E.; Döbereiner, J.; Urquiaga, S.; Boddey, R.M. Biological Nitrogen Fixation in Azospirillum Strain-Maize Genotype Associations as Evaluated by the 15N Isotope Dilution Technique. Biol. Fertil. Soils 1996, 23, 249–256. [Google Scholar] [CrossRef]
  88. Deynze, A.V.; Zamora, P.; Delaux, P.-M.; Heitmann, C.; Jayaraman, D.; Rajasekar, S.; Graham, D.; Maeda, J.; Gibson, D.; Schwartz, K.D.; et al. Nitrogen Fixation in a Landrace of Maize Is Supported by a Mucilage-Associated Diazotrophic Microbiota. PLoS Biol. 2018, 16, e2006352. [Google Scholar] [CrossRef]
  89. Xu, L.; Wang, A.; Wang, J.; Wei, Q.; Zhang, W. Piriformospora indica Confers Drought Tolerance on Zea mays L. through Enhancement of Antioxidant Activity and Expression of Drought-Related Genes. Crop J. 2017, 5, 251–258. [Google Scholar] [CrossRef]
  90. Ali, B.; Hafeez, A.; Afridi, M.S.; Javed, M.A.; Sumaira; Suleman, F.; Nadeem, M.; Ali, S.; Alwahibi, M.S.; Elshikh, M.S.; et al. Bacterial-Mediated Salinity Stress Tolerance in Maize (Zea mays L.): A Fortunate Way toward Sustainable Agriculture. ACS Omega 2023, 8, 20471–20487. [Google Scholar] [CrossRef] [PubMed]
  91. Ryals, J.; Neuenschwander, U.; Willits, M.; Molina, A.; Steiner, H.; Hunt, M. Systemic Acquired Resistance. Plant Cell 1996, 8, 1809–1819. [Google Scholar] [CrossRef] [PubMed]
  92. Yu, Y.; Gui, Y.; Li, Z.; Jiang, C.; Guo, J.; Niu, D. Induced Systemic Resistance for Improving Plant Immunity by Beneficial Microbes. Plants 2022, 11, 386. [Google Scholar] [CrossRef]
  93. Bakker, P.A.H.M.; Doornbos, R.F.; Zamioudis, C.; Berendsen, R.L.; Pieterse, C.M.J. Induced Systemic Resistance and the Rhizosphere Microbiome. Plant Pathol. J. 2013, 29, 136–143. [Google Scholar] [CrossRef]
  94. Saravanakumar, K.; Fan, L.; Fu, K.; Yu, C.; Wang, M.; Xia, H.; Sun, J.; Li, Y.; Chen, J. Cellulase from Trichoderma harzianum Interacts with Roots and Triggers Induced Systemic Resistance to Foliar Disease in Maize. Sci. Rep. 2016, 6, 35543. [Google Scholar] [CrossRef]
  95. Rojas-Tapias, D.; Moreno-Galván, A.; Pardo-Díaz, S.; Obando, M.; Rivera, D.; Bonilla, R. Effect of Inoculation with Plant Growth-Promoting Bacteria (PGPB) on Amelioration of Saline Stress in Maize (Zea mays). Appl. Soil Ecol. 2012, 61, 264–272. [Google Scholar] [CrossRef]
  96. Naseem, H.; Bano, A. Role of Plant Growth-Promoting Rhizobacteria and Their Exopolysaccharide in Drought Tolerance of Maize. J. Plant Interact. 2014, 9, 689–701. [Google Scholar] [CrossRef]
  97. Gou, W.; Tian, L.; Ruan, Z.; Zheng, P.; Chen, F.; Zhang, L.; Cui, Z.; Zheng, P.; Li, Z.; Gao, M.; et al. Accumulation of Choline and Glycinebetaine and Drought Stress Tolerance Induced in Maize (Zea mays) by Three Plant Growth Promoting Rhizobacteria (PGPR) Strains. Pak. J. Bot. 2015, 47, 581–586. [Google Scholar]
  98. Huang, X.-F.; Zhou, D.; Lapsansky, E.; Reardon, K.; Guo, J.; Andales, M.; Vivanco, J.; Manter, D. Mitsuaria sp. and Burkholderia sp. from Arabidopsis Rhizosphere Enhance Drought Tolerance in Arabidopsis thaliana and Maize (Zea mays L.). Plant Soil 2017, 419, 523–539. [Google Scholar] [CrossRef]
  99. Moreno-Galván, A.; Cortés-Patiño, S.; Romero-Perdomo, F.; Uribe-Vélez, D.; Bashan, Y.; Bonilla, R. Proline Accumulation and Glutathione Reductase Activity Induced by Drought-Tolerant Rhizobacteria as Potential Mechanisms to Alleviate Drought Stress in Guinea Grass. Appl. Soil Ecol. 2020, 147, 103367. [Google Scholar] [CrossRef]
  100. Molina-Romero, D.; Baez, A.; Quintero-Hernández, V.; Castañeda-Lucio, M.; Fuentes-Ramírez, L.E.; Bustillos-Cristales, M.d.R.; Rodríguez-Andrade, O.; Morales-García, Y.E.; Munive, A.; Muñoz-Rojas, J. Compatible Bacterial Mixture, Tolerant to Desiccation, Improves Maize Plant Growth. PLoS ONE 2017, 12, e0187913. [Google Scholar] [CrossRef]
  101. Bano, Q.; Ilyas, N.; Bano, A.; Zafar, N.; Akram, A.; Hassan, F.U. Effect of Azospirillum Innoculation on Maize (Zea mays L.) Under Drought Stress. Pak. J. Bot. 2013, 45, 13–20. [Google Scholar]
  102. Cohen, A.; Travaglia, C.; Bottini, R.; Piccoli, P. Participation of Abscisic Acid and Gibberellins Produced by Endophytic Azospirillum in the Alleviation of Drought Effects in Maize. Botany 2009, 87, 455–462. [Google Scholar] [CrossRef]
  103. Vardharajula, S.; Shaik, Z.A.; Grover, M.; Reddy, G.; Venkateswarlu, B. Drought-Tolerant Plant Growth Promoting Bacillus spp.: Effect on Growth, Osmolytes, and Antioxidant Status of Maize under Drought Stress. J. Plant Interact. 2011, 6, 1–14. [Google Scholar] [CrossRef]
  104. Naveed, M.; Mitter, B.; Reichenauer, T.G.; Wieczorek, K.; Sessitsch, A. Increased Drought Stress Resilience of Maize through Endophytic Colonization by Burkholderia phytofirmans PsJN and Enterobacter sp. FD17. Environ. Exp. Bot. 2014, 97, 30–39. [Google Scholar] [CrossRef]
  105. Quiroga, G.; Erice, G.; Ding, L.; Chaumont, F.; Aroca, R.; Ruiz-Lozano, J.M. The Arbuscular Mycorrhizal Symbiosis Regulates Aquaporins Activity and Improves Root Cell Water Permeability in Maize Plants Subjected to Water Stress. Plant Cell Environ. 2019, 42, 2274–2290. [Google Scholar] [CrossRef]
  106. Yasmin, H.; Nosheen, A.; Naz, R.; Bano, A.; Keyani, R. L-Tryptophan-Assisted PGPR-Mediated Induction of Drought Tolerance in Maize (Zea mays L.). J. Plant Interact. 2017, 12, 567–578. [Google Scholar] [CrossRef]
  107. Curá, J.A.; Franz, D.R.; Filosofía, J.E.; Balestrasse, K.B.; Burgueño, L.E. Inoculation with Azospirillum sp. and Herbaspirillum sp. Bacteria Increases the Tolerance of Maize to Drought Stress. Microorganisms 2017, 5, 41. [Google Scholar] [CrossRef]
  108. Krishnamoorthy, R.; Kim, K.; Subramanian, P.; Senthilkumar, M.; Anandham, R.; Sa, T. Arbuscular Mycorrhizal Fungi and Associated Bacteria Isolated from Salt-Affected Soil Enhances the Tolerance of Maize to Salinity in Coastal Reclamation Soil. Agric. Ecosyst. Environ. 2016, 231, 233–239. [Google Scholar] [CrossRef]
  109. Bano, A.; Fatima, M. Salt Tolerance in Zea mays (L). Following Inoculation with Rhizobium and Pseudomonas. Biol. Fertil. Soils 2009, 45, 405–413. [Google Scholar] [CrossRef]
  110. Nadeem, S.M.; Zahir, Z.A.; Naveed, M.; Arshad, M. Rhizobacteria Containing ACC-Deaminase Confer Salt Tolerance in Maize Grown on Salt-Affected Fields. Can. J. Microbiol. 2009, 55, 1302–1309. [Google Scholar] [CrossRef]
  111. Sheng, M.; Tang, M.; Zhang, F.; Huang, Y. Influence of Arbuscular Mycorrhiza on Organic Solutes in Maize Leaves under Salt Stress. Mycorrhiza 2011, 21, 423–430. [Google Scholar] [CrossRef]
  112. Chen, L.; Liu, Y.; Wu, G.; Kimani, V.; Shen, Q.; Zhang, N.; Zhang, R. Induced Maize Salt Tolerance by Rhizosphere Inoculation of Bacillus amyloliquefaciens SQR9. Physiol. Plant. 2016, 158, 34–44. [Google Scholar] [CrossRef]
  113. Li, X.; Sun, P.; Zhang, Y.; Jin, C.; Guan, C. A Novel PGPR Strain Kocuria rhizophila Y1 Enhances Salt Stress Tolerance in Maize by Regulating Phytohormone Levels, Nutrient Acquisition, Redox Potential, Ion Homeostasis, Photosynthetic Capacity and Stress-Responsive Genes Expression. Environ. Exp. Bot. 2020, 174, 104023. [Google Scholar] [CrossRef]
  114. Ahmad, M.; Imtiaz, M.; Nawaz, M.S.; Mubeen, F.; Sarwar, Y.; Hayat, M.; Asif, M.; Naqvi, R.Z.; Ahmad, M.; Imran, A. Thermotolerant PGPR Consortium B3P Modulates Physio-Biochemical and Molecular Machinery for Enhanced Heat Tolerance in Maize during Early Vegetative Growth. Ann. Microbiol. 2023, 73, 34. [Google Scholar] [CrossRef]
  115. Mathur, S.; Agnihotri, R.; Sharma, M.P.; Reddy, V.R.; Jajoo, A. Effect of High-Temperature Stress on Plant Physiological Traits and Mycorrhizal Symbiosis in Maize Plants. J. Fungi 2021, 7, 867. [Google Scholar] [CrossRef]
  116. Zhu, X.; Song, F.-B.; Xu, H.-W. Arbuscular Mycorrhizae Improves Low Temperature Stress in Maize via Alterations in Host Water Status and Photosynthesis. Plant Soil 2010, 331, 129–137. [Google Scholar] [CrossRef]
  117. Mathur, S.; Jajoo, A. Arbuscular Mycorrhizal Fungi Protects Maize Plants from High Temperature Stress by Regulating Photosystem II Heterogeneity. Ind. Crops Prod. 2020, 143, 111934. [Google Scholar] [CrossRef]
Applmicrobiol 04 00068 g001
Figure 1. An overview of maize plants showing (A) a healthy maize plant, (B) a maize plant affected by abiotic and biotic stresses, (C) mechanisms of abiotic stress tolerance including osmotic adjustment, antioxidant activity, and stomatal regulation, and (D) mechanisms of biotic stress tolerance such as activation of pathogenesis-related proteins and structural barriers.
Figure 1. An overview of maize plants showing (A) a healthy maize plant, (B) a maize plant affected by abiotic and biotic stresses, (C) mechanisms of abiotic stress tolerance including osmotic adjustment, antioxidant activity, and stomatal regulation, and (D) mechanisms of biotic stress tolerance such as activation of pathogenesis-related proteins and structural barriers.
Applmicrobiol 04 00068 g001
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Burlakoti, S.; Devkota, A.R.; Poudyal, S.; Kaundal, A. Beneficial Plant–Microbe Interactions and Stress Tolerance in Maize. Appl. Microbiol. 2024, 4, 1000-1015. https://doi.org/10.3390/applmicrobiol4030068

AMA Style

Burlakoti S, Devkota AR, Poudyal S, Kaundal A. Beneficial Plant–Microbe Interactions and Stress Tolerance in Maize. Applied Microbiology. 2024; 4(3):1000-1015. https://doi.org/10.3390/applmicrobiol4030068

Chicago/Turabian Style

Burlakoti, Saroj, Ananta R. Devkota, Shital Poudyal, and Amita Kaundal. 2024. "Beneficial Plant–Microbe Interactions and Stress Tolerance in Maize" Applied Microbiology 4, no. 3: 1000-1015. https://doi.org/10.3390/applmicrobiol4030068

Article Metrics

Back to TopTop