Singh Shailendra, Singh Udai B, Trivdi Mala, Malviya Deepti, Sahu Pramod K, Roy Manish, Sharma Pawan K, Singh Harsh V, Manna M C, Saxena Anil K
Plant-Microbe Interaction and Rhizosphere Biology Lab, ICAR-National Bureau of Agriculturally Important Microorganisms, Kushmaur, India.
Amity Institute of Biotechnology, Amity University Uttar Pradesh, Lucknow, India.
Front Microbiol. 2021 Feb 12;11:568325. doi: 10.3389/fmicb.2020.568325. eCollection 2020.
Salt stress hampers plant growth and development. It is now becoming one of the most important threats to agricultural productivity. Rhizosphere microorganisms play key roles in modulating cellular responses and enable plant tolerant to salt stress, but the detailed mechanisms of how this occurs need in-depth investigation. The present study elucidated that the microbe-mediated restructuring of the cellular responses leads to ecological fitness and adaptiveness to the maize ( L.) grown in saline-sodic soil. In the present study, effects of seed biopriming with MF-01, MF-15, and MF-08 singly and in consortium on different growth parameters were recorded. Soil biochemical and enzymatic analyses were performed. The activity and gene expression of High-Affinity K Transporter (), Sodium/Hydrogen exchanger 1 (), and antioxidant enzymes (, , , , , and ) were studied. The expression of genes related to lateral root development (, , and ) and root architecture were also carried out. Seeds bioprimed with consortium of all three strains have been shown to confer increased seed germination (23.34-26.31%) and vigor indices (vigor index I: 38.71-53.68% and vigor index II: 74.11-82.43%) as compared to untreated control plant grown in saline-sodic soil at 30 days of sowing. Results indicated that plants treated with consortium of three strains induced early production of adventitious roots (tips: 4889.29, forks: 7951.57, and crossings: 2296.45) in maize compared to plants primed with single strains and untreated control (tips: 2019.25, forks: 3021.45, and crossings: 388.36), which was further confirmed by assessing the transcript level of (7.20 folds), (4.50 folds), and (12.00 folds) genes using the qPCR approach. The uptake and translocation of Na, K, and Ca significantly varied in the plants treated with bioagents alone or in consortium. qRT-PCR analysis also revealed that the and expression levels varied significantly in the maize root upon inoculation and showed a 6- to 11-fold increase in the plants bioprimed with all the three strains in combination. Further, the activity and gene expression levels of antioxidant enzymes were significantly higher in the leaves of maize subjected seed biopriming with bioagents individually or in combination (3.50- to 12.00-fold). Our research indicated that and expression could effectively enhance salt tolerance by maintaining an optimal Na/K balance and increasing the antioxidant activity that keeps reactive oxygen species at a low accumulation level. Interestingly, up-regulation of , , , , and and genes encoding antioxidants regulates the cellular responses that could effectively enhance the adaptiveness and ultimately leads to better plant growth and grain production in the maize crop grown in saline-sodic soil.
盐胁迫阻碍植物生长发育。目前,它正成为对农业生产力最重要的威胁之一。根际微生物在调节细胞反应中起关键作用,并使植物能够耐受盐胁迫,但其发生的详细机制需要深入研究。本研究阐明,微生物介导的细胞反应重组导致了在盐碱土壤中生长的玉米(L.)的生态适应性。在本研究中,记录了单独和联合使用MF - 01、MF - 15和MF - 08进行种子生物引发对不同生长参数的影响。进行了土壤生化和酶分析。研究了高亲和性钾转运蛋白()、钠/氢交换蛋白1()和抗氧化酶(、、、、和)的活性及基因表达。还进行了与侧根发育(、和)及根系结构相关基因的表达研究。与在盐碱土壤中播种30天时未处理的对照植株相比,用所有三种菌株联合进行生物引发的种子已显示出种子发芽率提高(23.34 - 26.31%)和活力指数增加(活力指数I:38.71 - 53.68%,活力指数II:74.11 - 82.43%)。结果表明,与用单一菌株引发和未处理的对照植株相比,用三种菌株联合处理的玉米植株诱导了不定根的早期产生(根尖:4889.29,分支:7951.57,交叉点:2296.45)(根尖:2019.25,分支:3021.45,交叉点:388.36),使用qPCR方法评估(7.20倍)、(4.50倍)和(12.00倍)基因的转录水平进一步证实了这一点。单独或联合使用生物制剂处理的植株中,钠、钾和钙的吸收及转运存在显著差异。qRT - PCR分析还显示,接种后玉米根中的和表达水平有显著变化,在用所有三种菌株联合进行生物引发的植株中增加了6至11倍。此外,单独或联合使用生物制剂对种子进行生物引发后,玉米叶片中抗氧化酶的活性和基因表达水平显著更高(3.50至12.00倍)。我们的研究表明,和表达可以通过维持最佳的钠/钾平衡并增加抗氧化活性,使活性氧积累水平保持在较低水平,从而有效提高耐盐性。有趣的是,上调以及编码抗氧化剂的基因调节细胞反应,这可以有效增强适应性,并最终使在盐碱土壤中生长的玉米作物实现更好的植株生长和籽粒产量。
