Salt-Tolerant PGPR Confer Salt Tolerance to Maize Through Enhanced Soil Biological Health, Enzymatic Activities, Nutrient Uptake and Antioxidant Defense

Shabaan, Muhammad; Asghar, Hafiz Naeem; Zahir, Zahir Ahmad; Zhang, Xiu; Sardar, Muhammad Fahad; Li, Hongna

doi:10.3389/fmicb.2022.901865

ORIGINAL RESEARCH article

Front. Microbiol., 13 May 2022

Sec. Terrestrial Microbiology

Volume 13 - 2022 | https://doi.org/10.3389/fmicb.2022.901865

Salt-Tolerant PGPR Confer Salt Tolerance to Maize Through Enhanced Soil Biological Health, Enzymatic Activities, Nutrient Uptake and Antioxidant Defense

$\r\nMuhammad Shabaan&#x;$ Muhammad Shabaan^1†

Hafiz Naeem Asghar¹

Zahir Ahmad Zahir¹

Xiu Zhang²

Muhammad Fahad Sardar^3*†

Hongna Li^3*†

¹Institute of Soil and Environmental Sciences, University of Agriculture, Faisalabad, Pakistan
²Ningxia Key Laboratory for the Development and Application of Microbial Resources in Extreme Environments, North Minzu University, Yinchuan, China
³Agricultural Clean Watershed Research Group, Institute of Environment and Sustainable Development in Agriculture, Chinese Academy of Agricultural Sciences, Beijing, China

Salt-tolerant plant growth-promoting rhizobacteria (PGPR) can improve soil enzyme activities, which are indicators of the biological health of the soil, and can overcome the nutritional imbalance in plants. A pot trial was executed to evaluate the effect of inoculation of different salt-tolerant PGPR strains in improving soil enzyme activities. Three different salinity levels (original, 5, and 10 dS m^–1) were used and maize seeds were coated with the freshly prepared inocula of ten different PGPR strains. Among different strains, inoculation of SUA-14 (Acinetobacter johnsonii) caused a maximum increment in urease (1.58-fold), acid (1.38-fold), and alkaline phosphatase (3.04-fold) and dehydrogenase (72%) activities as compared to their respective uninoculated control. Acid phosphatase activities were found to be positively correlated with P contents in maize straw (r = 0.96) and grains (r = 0.94). Similarly, a positive correlation was found between alkaline phosphatase activities and P contents in straw (r = 0.77) and grains (r = 0.75). In addition, urease activities also exhibited positive correlation with N contents in maize straw (r = 0.92) and grains (r = 0.91). Moreover, inoculation of Acinetobacter johnsonii caused a significant decline in catalase (39%), superoxide dismutase (26%) activities, and malondialdehyde contents (27%). The PGPR inoculation improved the soil’s biological health and increased the uptake of essential nutrients and conferred salinity tolerance in maize. We conclude that the inoculation of salt-tolerant PGPR improves soil enzyme activities and soil biological health, overcomes nutritional imbalance, and thereby improves nutrient acquisition by the plant under salt stress.

Introduction

Climate change has aggravated the harshness of environmental stressors and has badly affected agricultural crop productivity. At the same time, it is inevitable to increase agricultural production to meet the global food demand of a growing population, which is expected to reach 9 billion by 2050 (Rout, 2020). Excessive concentration of soluble salts in soil as well as water are responsible for lesser agricultural production and thereby, convert fertile lands to marginal lands leading to their abandonment (Ilangumaran and Smith, 2017). Soil salinization is considered one of the major constraints that not only limit agricultural output but also compromise soil fertility (Machado and Serralheiro, 2017). High salt concentrations usually occur in those regions that are characterized by high surface evaporation, low precipitation, and high temperature (Arora et al., 2018). In addition to that, continuous application of agrochemicals (fertilizers and pesticides) and various amendments with elevated salt concentrations, as well as the use of low-quality irrigation water are propagating salt accumulation to other cultivated areas (Enebe and Babalola, 2018). Toxic concentrations of soluble salts, predominantly NaCl, are present in the salt-affected areas, which induce osmotic stress, imbalance in nutrient uptake, and alterations in the plant metabolic system, thereby reducing plant growth (Deinlein et al., 2014). Moreover, excessive NaCl interferes with the soil microbial communities and their activities (Rath and Rousk, 2015) concomitant with detrimental impacts on organic matter degradation and nutrient cycling (Yan et al., 2015).

On a global scale, approximately 45 mha of farmland is estimated to be affected by salinity at an observed rate of 0.2–0.5 mha per year (CGIAR, 2016). To date, more than 20% of the agricultural land has been affected by elevated NaCl concentrations. If these conditions prevail at the same pace, agricultural land may lose 50% of its arability till 2050 (Din et al., 2019). Enormous salt concentrations in soil can result in hyperosmotic and hyperionic stresses that lead to a decline in plant growth, lessen nutrient uptake levels, and even result in plant death (Hidri et al., 2019).

Pakistan is an agriculture-based country that is estimated to have nearly 80% arid to semiarid areas. Soil salinization is one of the major limiting factors in Pakistan’s agriculture, and this problem has been further aggravated by the high evapotranspiration rate that prevails in the country with 8% humidity and 12% subhumid climatic conditions (Lal, 2018). Evapotranspiration rate is usually very high in June, i.e., 7.6 mm, and thereby, exceeding the precipitation rate (Hayat et al., 2020). In Pakistan, approximately 33% (6.8 mha) area of cultivation has been severely affected by salinity stress (Aslam et al., 2017). It not only disturbs the physicochemical properties of soil but also negatively affects the biological properties of soil.

Maize (Zea mays L.) ranks as the third most important cereal crop in Pakistan and it contributes to the value addition of agriculture and gross domestic product (GDP) by 2.1 and 0.4%, respectively (Abbas et al., 2017). Many studies have emphasized that global maize production must be doubled to meet the growing demands of living beings in the developing world (Meng et al., 2016). Maize is slightly sensitive to salinity stress, and at higher salinity levels, its production is severely affected, and salinity stress has become one of the major limiting factors regarding maize production (Farooq et al., 2015; Soothar et al., 2021). To achieve better maize growth and production, a suitable alternative must be sought to ensure sustained maize production even under excessive salt concentrations.

Different approaches are being used to manage salt-affected soils, such as the use of tube wells for irrigation, application of different chemicals such as gypsum, acids, and different organic amendments development of salt-tolerant cultivars, and inoculation of plant growth-promoting rhizobacteria (PGPR) strains to seeds. However, the use of physicochemical approaches is limited on account of their high cost and impracticability. The PGPR activities may alter the physiology of the plant’s root growth and support plants coping with salt stress (Azcón et al., 2013). Moreover, PGPR produces 1-aminocyclopropane-1-carboxylic acid (ACC) deaminase, which degrades ACC, a precursor of ethylene, which is very critical regarding salt tolerance in plants (Sarkar et al., 2019). PGPR can allocate its resources toward the production of different enzymes (dehydrogenases, phosphatases, and urease, etc.) that degrade organic matter followed by the mineralization of essential soil nutrients (Bezemer et al., 2010; Eisenhauer et al., 2010). These enzymes are believed to be linked to soil health and plant growth (Hidri et al., 2019; Sardar et al., 2021). These enzymes are responsible for increasing the availability of essential nutrients and, in this way, ensure nutrient availability for plant uptake. Overall, these soil enzymes may impose significant impacts on soil biology, growth, and nutrient uptake by plants and their management may be applied to stressed environments. Various studies have reported the role of microbes in association with plants in conferring salinity tolerance in plants (Hidri et al., 2016; Vimal et al., 2017; Vimal and Singh, 2019).

On this basis, this study was planned with the following objectives: (i) to compare the potential of salt-tolerant PGPR in improving soil enzyme activities under salt stress and (ii) to evaluate the possible role of soil enzymes in alleviating the nutritional imbalance in maize and improving its growth. We hypothesized that salt-tolerant rhizobacterial strains that possessed the potential to not only exhibit plant growth-promoting traits but also improve soil enzyme activities under varying levels of salt stress may improve the soil health and its ability to regulate the supply of essential nutrients for plant uptake.

Materials and Methods

Rhizobacteria were previously isolated from maize that was grown in the salt-affected areas and evaluated for salt tolerance, plant growth-promoting traits, and extracellular enzyme production (Shabaan et al., 2021). Based on the results, ten strains were selected and were further investigated in a pot trial to test their efficacy in conferring salt tolerance to maize. Improvement in the soil enzyme activities after inoculation and a resultant increase in the plant uptake of essential nutrients were also correlated with plant growth and yield parameters. PGPR attributes of the rhizobacterial isolates are given in Table 1.

TABLE 1

Table 1. Results of plant growth-promoting traits of rhizobacterial strains used in pot trial.

Details of different procedures during the experimental trial are given below.

Inoculum Preparation

For the preparation of fresh inoculum of each of the selected rhizobacterial strains, Lauria Bertini (LB) broth media was used with the following recipe (10 g l^–1) NaCl: 10, tryptone: 10, and yeast extract: 5. A pure single colony of each selected strain was inoculated to LB broth and was incubated at 28 ± 2°C for 48 h to prepare bacterial culture. Bacterial cells were harvested by centrifugation at 4,000 g and 4°C for 15 min. The pellet obtained was resuspended in the sterilized distilled water. The optical density of the bacterial culture was maintained at 10⁷–10⁸ colony-forming unit (CFU) ml^–1 by using a UV-visible spectrophotometer (Mortensen et al., 2021).

Seed Inoculation

Spring maize cultivar (31P41) was purchased from an authorized seed company and the inocula of rhizobacterial strain were carefully coated on the seeds. Before inoculation, seeds were washed with distilled water followed by their treatment with 2% sodium hypochlorite solution for 1–2 min. Then, after washing, the seeds were dipped in 95% ethanol for 30 s. Peat-based slurry and sugar solution (10%) were used for the seed inoculation (inoculum to peat ratio: 1:1), whereas for control treatments, seeds were coated with sterilized broth.

Pot Trial

The experiment was designed to explore the effect of rhizobacterial inoculation on soil enzyme activities and antioxidants production. Calculated quantities of NaCl were added to the soil to develop electrical conductivity (EC) levels of 5 and 10 dS m^–1, 2 weeks before the trial to ensure homogeneous mixing of salt in the soil. Experimental units were arranged according to a completely randomized design (CRD) under the factorial arrangement. Six seeds of maize were sown in each pot and three seedlings per pot were maintained after germination. Moreover, before pot filling, each pot was lined with polythene sheets to avoid leaching losses. A total of 10 kg of uniformly mixed and air-dried soil was filled in each pot having EC 1.58 dS m^–1, pH 7.7, organic matter (OM) 0.61%, saturation percentage 36.98%, available phosphorus 6.9 mg kg^–1, extractable potassium 165.7 mg kg^–1, and cation exchange capacity (CEC) 1.49 C molc kg^–1. The experiment was performed for a period of 110 days, and upon harvesting, growth and yield parameters were measured by following suitable protocols.

Parameters Studied

Chlorophyll Contents and Relative Water Contents

The soil plant analysis development (SPAD) value was measured by using a chlorophyll meter (SPAD-502) at 10:00 a.m., whereas chlorophyll a, chlorophyll b, and carotenoid contents were measured by following the method of Armon (1949). Acetone extract (80% v/v) was used for determining the chlorophyll and carotenoids contents through spectrophotometer at 663, 645, and 480 nm wavelengths for chlorophyll a, chlorophyll b, and carotenoids, respectively, and were expressed as mg g^–1 fresh weight.

Chl “a” = [12.7 (OD 663) – 2.69 (OD 645) × $\frac{Volume of sample}{1000}$ × Weight of fresh tissue]

Chl “b” = [22.9 (OD 645) – 4.68 (OD 663) × $\frac{Volume of sample}{1000}$ × Weight of fresh tissue]

Carotenoids = $\frac{Acar}{Em}$ × 100,

where

Em = 2,500 and A^car = OD 480 + 0.114 (OD 663) – 0.638 (OD 645)

For the determination of relative water contents, the method of Barrs and Weatherley (1962) was followed;

\begin{matrix} Relative water contents (RWCs) = \\ \frac{Fresh weight - Dry weight}{Fully turgid weight - Dry weight} \times 100 \end{matrix} (1)

To get a turgid weight of the leaves, they were placed in distilled water for 18 h in the dark at room temperature. Leaves were blotted carefully with tissue paper for the determination of turgid weight, while dry weight was obtained after drying the leaves in an oven grain fresh weight (g) at 70°C for 72 h.

Growth and Yield Parameters

Upon harvesting, data regarding maize growth parameters and yield parameters were measured.

Nutrient Analysis in Plant

Determination of N, P, K, and Na contents in plant matter and grains after grinding and digestion is as follows.

Digestion

Plant samples were digested by following the method of Wolf (1982) where ground plant samples (0.5 g) were used. Completion of the digestion process was indicated by the appearance of colorless liquid in the flask. Later, the material was diluted with distilled water followed by its filtration into a 50-ml volumetric flask, and distilled water was used again to fill the flask up to the mark. The digested material was stored for N, P, and K analysis.

Nitrogen, Phosphorus, and Potassium Determination

For the determination of N, P, K, and Na contents in different plant parts, Kjeldahl ammonia distillation apparatus, spectrophotometer (ANA-720W, Tokyo Photoelectric Company Limited, Japan), and Flame photometer (Jenway PFP-7) were used.

Antioxidant Production

Enzyme Extract

Enzyme extraction was carried out by the homogenization of maize leaves in phosphate buffer (7.0) in prechilled pestle and mortar by following the method used by Pandey et al. (2003). The extract was centrifuged in a cooled centrifuge at 9,000 g for 20 min. The supernatant was analyzed for catalase (CAT), superoxide dismutase (SOD) activities, and malondialdehyde (MDA) contents by following suitable protocols.

Catalase [mM Hydrogen Peroxide Mint^–1 g^–1 Fresh Weight]

Catalase (CAT) activities in enzyme extract were determined by following the method of Hugo and Lester (1984), where decomposition of hydrogen peroxide (H₂O₂) was observed spectrophotometrically at 240 nm. Then, 3 ml of reaction mixture comprised 2 ml of enzyme extract and 10 mM H₂O₂.

Superoxide Dismutase (Nmol Mint^–1 mg^–1 Protein)

Total SOD activity in the crude enzyme extract was assayed by using the modified nitroblue tetrazolium (NBT) substrate method. The reaction mixture (2 ml) comprised of phosphate buffer (50 mM; pH 7.8) having ethylenediaminetetraacetic acid (EDTA) (2 mM), L-methionine (9.9 mM), NBT (55 μM), and 0.025% Triton X-100, and the reaction was started by the illumination of the sample under a fluorescent lamp and terminated by covering the test tubes with aluminum foil. SOD activity was measured by calculations given by Beauchamp and Fridovich (1971).

Lipid Peroxidation (Malondialdehyde Contents)

Levels of lipid peroxidation in maize leaves were determined by Sheng and Zhu (2019) and comprised of homogenization of leaves in the presence of 10% trichloroacetic acid (TCA) followed by their homogenization at 9,000 g for 20 min. A reaction mixture consisting of aliquot (2 ml), 0.6% thiobarbituric acid (2 ml) in 10% TCA was heated for 15 min at 100°C followed by its quick cooling in an ice bath. The mixture was centrifuged at 9,000 g for 20 min and absorbance of the resultant supernatant was measured at 532 and 450 nm. MDA contents were expressed as nmol mint^–1 mg^–1 protein.

Proline Determination (μMole G^–1 Fresh Weight)

Proline determination in the samples was done according to the method of Bates et al. (1973) where a 0.5-g plant sample was homogenized in sulfosalicylic acid followed by its filtration. The filtrate was mixed with acid ninhydrin (2 ml) and glacial acetic acid (2 ml) and the reaction terminated in an ice bath. Toluene was used for the extraction of the reaction mixture. The absorbance of the reaction mixture was determined at 520 nm. Proline concentration was determined using a standard curve.

Soil Enzyme Activities

For the measurement of soil enzyme activities, rhizosphere soil that was closely attached to plant roots was taken in the laboratory and stored in a refrigerator at -4°C in polythene bags.

Soil Urease Activity

Soil urease activity was determined by following the method of Tabatabai (1972) and was based on the determination of ammonium released during the steam distillation of soil suspension with 0.2 g MgO with boric acid (H₃BO₃) as a receiver solution when the soil was incubated with tris(hydroxymethyl)aminomethane (THAM) buffer, urea solution (analytical grade), and toluene at 37°C for 2 h. It was expressed as μg NH₄⁺ released per gram of soil per 2 h.

Soil Phosphatase Activity

Activities of acid and alkaline phosphatase in the soil samples were determined by following the method used by Tabatabai and Bremner (1969) and were based on the colorimetric estimation of p-nitrophenol released by the incubation of soil with p-nitrophenyl phosphate solution and toluene. Two different types of modified universal buffer (pH 6.5 for acidic) and (pH 11 for alkaline) phosphatase were prepared. The intensity of the yellow color was spectrophotometrically observed at 410 nm.

Soil Dehydrogenase Activity

Soil dehydrogenase activities were measured based on the colorimetric determination of 1,3,5-triphenylformazan (TPF) formed on account of microbially mediated reduction of 2,3,5-triphenyltetrazolium chloride (TTC), which was devised by Lenhard (1956). The intensity of reddish color developed by the reduction of TPF was measured at 485 nm with methanol as a blank. Based on the values of absorbance of standard TPF solution in methanol, a calibration curve was drawn to quantify the dehydrogenase activity and was expressed as μg TPF formed per h per g dry weight of soil.

Microbial Identification

Bacterial strains were identified using 16S rRNA sequencing. Identification was done by comparing the partial sequences of the isolated strains with those existing in the GenBank database. Universal primer sets, forward primer 27F 5’ (AGA GTT TGA TCM TGG CTC AG) 3’ and reverse primer 1492R 5’ (TAC GGY TAC CTT GTT ACG ACT T) 3’, were used for this purpose.

Statistical Analysis

The data of each parameter were separately analyzed, and all the statistical analyses were performed using software IBM SPSS v19.0. The experiment consisted of thirty-three treatments, each with three replications. Means, SEs, and residues were calculated using Microsoft Excel software (version 2019, United States). Tukey’s honestly significant difference (HSD) test was used as a post hoc test to conduct pairwise comparisons between different treatments at p ≤ 0.05. Moreover, the Pearson correlation between soil enzyme activities and different growth-related parameters was performed in RStudio, and a correlogram was constructed using the built-in “cor” function and the publicly available package “corrplot,” as per R-project instructions (RStudio Team, 2019).

Results

Salinity stress has a damaging effect on soil enzyme activities as well as growth, yield, and physiological attributes of maize, and these effects were more pronounced at higher salinity levels. However, rhizobacterial inoculation caused a considerable improvement in all the measured plant traits at all the salinity levels. Different rhizobacterial strains responded differently toward applied salinity stress and regulated plant growth as compared to the uninoculated contaminated control.

Growth and Yield Attributes

Results indicated that salinity stress decreased the overall growth and yield attributes, where the highest salinity stress (10 dS m^–1) exhibited more adverse impacts as compared to the lower levels as well as control as it decreased the shoot length (1.2-fold), shoot fresh biomass (26%), root length (9%), root fresh weight (11%), root/shoot ratio (5%), 100-grain weight (36%), and cob length (35%) in the absence of inoculation and comparison with the control treatment (Figure 1). However, among all the inoculated rhizobacterial strains, maximum increment in the shoot length (31%) was found by the inoculation of SUA-14, whereas inoculation of SHM-13 caused a significant promotion in the shoot fresh biomass (66%), root length (20%), and root fresh weight (94%) in comparison with their respective uninoculated control at 10 dS m^–1 salinity level. Similarly, results regarding yield parameters (Figure 2) exhibited that, at the highest salinity level (10 dS m^–1), maximum increment in the cob length (41%) and cob weight (32%) was observed with SHM-13 inoculation, followed by SUA-14, which increased cob length and cob weight by 38 and 30%, respectively. Similarly, a maximum increment in the 100-grain weight was found due to inoculation with SHM-7 (45%).

FIGURE 1

Figure 1. Effect of rhizobacterial inoculation on growth parameters, i.e., (A) shoot length (cm), (B) shoot fresh weight (g), (C) root length (cm), and (D) root fresh weight (g) of maize under salt-stressed pot conditions. Bars sharing similar letters are statistically non-significant at p ≤0.05.

FIGURE 2

Figure 2. Effect of rhizobacterial inoculation on yield parameters, i.e., (A) 100-grain weight (g), (B) Cob length (cm), (C) Cob weight (g), and (D) root/shoot ratio of maize under salt-stressed pot conditions. Bars sharing the same letters are statistically non-significant at p≤0.05.

Physiological Attributes

Results regarding the physiological attributes (relative water contents, chl “a” and “b,” and carotenoids contents) (Figure 3) revealed that, in the absence of bacterial inoculation, maximum adverse impacts were observed at a higher salinity level of 10 dS m^–1 as it decreased the SPAD (23%), chl “a” (28%), chl “b” (24%), and carotenoid (52%) contents as compared to the control treatment. However, a maximum increment in the relative water contents (52%) was found with inoculation of SUA-14 followed by SHM-5 (50%) as compared to their respective uninoculated control. Similarly, the maximum increase in the chlorophyll “a” (35%) and chlorophyll “b” (33%) contents was found due to inoculation with SHM-7. Moreover, SHM-7 caused a significant uplift in the carotenoid (88%) contents followed by SUA-14 (85%).

FIGURE 3

Figure 3. Effect of rhizobacterial inoculation on the physiological attributes, i.e., (A) Relative water contents (%), (B) Chlorophyll “a”. Effect of rhizobacterial inoculation on relative water contents (RWCs) (%), (C) Chlorophyll “b” (mg g^–1 fresh weight), and (D) carotenoid (mg g^–1 fresh weight) contents of maize under salt-stressed pot conditions. Bars sharing the same letters are statistically non-significant at p≤0.05.