Salinity Stress in Maize: Effects of Stress and Recent Developments of Tolerance for Improvement

Sabagh, Ayman El; Çığ, Fatih; Seydoşoğlu, Seyithan; Battaglia, Martín Leonardo; Javed, Talha; Iqbal, Muhammad Aamir; Mubeen, Muhammad; Ali, M. N.; Ali, Mazhar; Bengisu, Gülşah; Konuşkan, Ömer; Barutçular, Celaleddin; Erman, Murat; Açıkbaş, Semih; Hossain, Akbar; Islam, Mohammad Sohidul; Wasaya, Allah; Ratnasekera, Disna; Arif, Muhammad; Ahmad, Zahoor; Awad, Mahrous

doi:10.5772/intechopen.98745

Cited by 20 publications

(14 citation statements)

References 113 publications

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“…It has been reported that soil salinity is one of the significant threats to maize production worldwide [31]. In general, maize shows decreased germination rate, stunted growth, reduced photosynthesis and less productivity under salinity stress [32,33]. However, maize production needs to be doubled, even under salinity stress, by 2050 to meet the ever-increasing demand of maize as a fundamental foodstuff [34].…”

Section: Introductionmentioning

confidence: 99%

Characterization of Maize Hybrids (Zea mays L.) for Detecting Salt Tolerance Based on Morpho-Physiological Characteristics, Ion Accumulation and Genetic Variability at Early Vegetative Stage

Huqe

Haque

Sagar

et al. 2021

Plants

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Increasing soil salinity due to global warming severely restricts crop growth and yield. To select and recommend salt-tolerant cultivars, extensive genotypic screening and examination of plants’ morpho-physiological responses to salt stress are required. In this study, 18 prescreened maize hybrid cultivars were examined at the early growth stage under a hydroponic system using multivariate analysis to demonstrate the genotypic and phenotypic variations of the selected cultivars under salt stress. The seedlings of all maize cultivars were evaluated with two salt levels: control (without NaCl) and salt stress (12 dS m−1 simulated with NaCl) for 28 d. A total of 18 morpho-physiological and ion accumulation traits were dissected using multivariate analysis, and salt tolerance index (STI) values of the examined traits were evaluated for grouping of cultivars into salt-tolerant and -sensitive groups. Salt stress significantly declined all measured traits except root–shoot ratio (RSR), while the cultivars responded differently. The cultivars were grouped into three clusters and the cultivars in Cluster-1 such as Prabhat, UniGreen NK41, Bisco 51, UniGreen UB100, Bharati 981 and Star Beej 7Star exhibited salt tolerance to a greater extent, accounting for higher STI in comparison to other cultivars grouped in Cluster-2 and Cluster-3. The high heritability (h2bs, >60%) and genetic advance (GAM, >20%) were recorded in 13 measured traits, indicating considerable genetic variations present in these traits. Therefore, using multivariate analysis based on the measured traits, six hybrid maize cultivars were selected as salt-tolerant and some traits such as Total Fresh Weight (TFW), Total Dry Weight (TDW), Total Na+, Total K+ contents and K+–Na+ Ratio could be effectively used for the selection criteria evaluating salt-tolerant maize genotypes at the early seedling stage.

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Section: Introductionmentioning

confidence: 99%

Characterization of Maize Hybrids (Zea mays L.) for Detecting Salt Tolerance Based on Morpho-Physiological Characteristics, Ion Accumulation and Genetic Variability at Early Vegetative Stage

Huqe

Haque

Sagar

et al. 2021

Plants

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“…It has been reported that the use of Bch affects the absorption of nutrients and water and causes an increase in RWC and a decrease in ion leakage under salinity stress conditions . Also, the combination of Bch and AMF improves growth and water absorption by inducing the expression of speci c genes and balancing plant hormones [52][53][54][55][56][57][58][59][60].…”

Section: Ion Leakage and Rwcmentioning

confidence: 99%

Improvement of Nutrient Content, Physiological Traits and Grain Yield of Maize Varieties Grown in Saline Soil by Combining Biochar, Mycorrhizal Fungi and Silicon Foliar Application

Kachouei,

Madandoust,

Dejam

et al. 2024

Silicon

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In the studies that have been conducted on resources that increase tolerance to salt stress, their individual use has often been considered. There is little evidence of their synergistic effects, especially for plants grown in saline soil conditions. In this research, a factorial experiment was conducted in the randomized complete block design in 2020 and 2021. The rst factor was 3 maize varieties including 704, 604 and 370 and the second factor was resources ameliorating the adverse effcts of salinity including control, single, dual and combined use of biochar (Bch), arbuscular mycorrhizal fungus (AMF) and silicon foliar application (SiFA). The results showed that leaves sodium concentration in the combined treatment of Bch + AMF + SiFA decreased by 13% compared to the control. In 704 the concentration of potassium and nitrogen in the combination of Bch + AMF + SiFA respectively showed an increase of 25 and 22% compared to the control. Also, dual consumption of ameliorating resources caused an increase in leaf iron, zinc, copper and manganese. Combined use of ameliorating resources decreased ion leakage and increased the relative water content and the photosynthetic pigments. In 604 and 370, the grain yield was respectively increased by 10 and 18% in the combination of Bch + AMF + SiFA compared to the control. Considering the positive effect of ameliorating resources in improving seed yield and seed oil percentage, the combination of biochar + mycorrhiza + silicon can be recommended under salt stress.

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“…Salinity decreases the growth and grain yield of Z. mays while there is no application of mitigating strategies. The most critical phases for plant development are germination and seedling growth, and maize is more sensitive to salinity at these stages [5,6].…”

Section: Introductionmentioning

confidence: 99%

Salinity stress mitigation on Zea mays L. seedling by halotolerant bacteria

Saryanah

Sulastri

Himawati

et al. 2023

IOP Conf. Ser.: Earth Environ. Sci.

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Halotolerant bacteria are reported as a potential biostimulant to mitigate saline stress on various crops. The mechanism of halotolerant bacteria in elevating plant growth under saline stress is associated with their plant growth-promoting (PGP) traits. This study evaluated the activity of single-strain halotolerant phosphate-solubilizing bacteria and its consortia with halotolerant bacteria that were able to fix nitrogen and produce ACC deaminase in alleviating salinity stress on Zea mays seedlings under in vitro conditions. One single strain and five consortia of bacterial isolates were tested for seedling growth assay under four salinity levels (0, 60, 80, and 100 mM). In vitro assay showed that halotolerant bacteria B1 (Vibrio alginolycticus) and all consortia significantly increased root number at 60 mM salinity level. Consortium B3 (V. alginolyticus+Salinicola zeshunii) was also able to improve the fresh weight of seedlings significantly (by 63.3%). Moreover, inoculation of consortium B3 affected more proline and soluble sugar accumulation in Z. mays seedlings when compared to uninoculated seedlings. We conclude that the application of a consortium of halotolerant bacteria V. alginolyticus+S. zeshunii was potentially used in improving Z. mays growth in slightly and moderately saline areas.

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Salinity Stress in Maize: Effects of Stress and Recent Developments of Tolerance for Improvement

Cited by 20 publications

References 113 publications

Characterization of Maize Hybrids (Zea mays L.) for Detecting Salt Tolerance Based on Morpho-Physiological Characteristics, Ion Accumulation and Genetic Variability at Early Vegetative Stage

Characterization of Maize Hybrids (Zea mays L.) for Detecting Salt Tolerance Based on Morpho-Physiological Characteristics, Ion Accumulation and Genetic Variability at Early Vegetative Stage

Improvement of Nutrient Content, Physiological Traits and Grain Yield of Maize Varieties Grown in Saline Soil by Combining Biochar, Mycorrhizal Fungi and Silicon Foliar Application

Salinity stress mitigation on Zea mays L. seedling by halotolerant bacteria

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