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通过接种解锌根际细菌对小麦作物进行生物施肥和生物强化的调控

Modulation in Biofertilization and Biofortification of Wheat Crop by Inoculation of Zinc-Solubilizing Rhizobacteria.

作者信息

Yadav Ramesh Chandra, Sharma Sushil K, Varma Ajit, Rajawat Mahendra Vikram Singh, Khan Mohammad Shavez, Sharma Pawan K, Malviya Deepti, Singh Udai B, Rai Jai P, Saxena Anil K

机构信息

Amity Institute of Microbial Technology, Amity University, Noida, India.

Plant-Microbe Interaction and Rhizosphere Biology Lab, ICAR-National Bureau of Agriculturally Important Microorganisms, Kushmaur, India.

出版信息

Front Plant Sci. 2022 Feb 25;13:777771. doi: 10.3389/fpls.2022.777771. eCollection 2022.

DOI:10.3389/fpls.2022.777771
PMID:35283872
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8914200/
Abstract

Zinc is an important micronutrient needed for the optimum growth and development of plants. Contrary to chemical zinc fertilizers, the use of zinc-solubilizing bacteria is an environmentally friendly option for zinc enrichment in edible parts of crops. This study was conducted with the objective of selecting potential zinc-solubilizing rhizobacteria from the rhizosphere of chickpea grown in soils of eastern Uttar Pradesh and further assessing their impact on the magnitude of zinc assimilation in wheat crops. Among 15 isolates, CRS-9, CRS-17, CRS-30, and CRS-38 produced net soluble zinc in broth to the tune of 6.1, 5.9, 5.63, and 5.6 μg ml, respectively, in zinc phosphate with the corresponding pH of 4.48, 5.31, 5.2, and 4.76. However, the bacterial strains CRS-17, CRS-30, CRS-38, and CRS-9 showed maximum zinc phosphate solubilization efficiency of 427.79, 317.39, 253.57, and 237.04%, respectively. The four bacterial isolates were identified as CRS-9, CRS-17, CRS-30, and CRS-38 on the basis of morphological and biochemical studies and 16S rRNA gene sequencing. Bacterial inoculants significantly colonized the roots of wheat plants and formed a biofilm in the root matrix. These strains significantly increased seed germination (%) and vigor indices in wheat grown under glasshouse conditions. After 30 days of sowing of wheat under microcosm conditions, eight zinc transporter () genes were expressed maximally in roots, with concomitant accumulation of higher zinc content in the bacterially treated plant compared to the absolute control. Out of the four strains tested, two bacteria, CRS-38 and CRS-30, improved seed germination (%), vigor indices (2-2.5 folds), plant biomass, grain yield (2.39 g plant), and biofortificated grains (54.25 μg gZn) of wheat. To the best of our knowledge, this may be the first report on the presence of zinc solubilization trait in CRS-9, CRS-17, and CRS-30.

摘要

锌是植物最佳生长和发育所需的重要微量营养素。与化学锌肥不同,使用解锌细菌是一种在作物可食用部分富集锌的环保选择。本研究旨在从印度北方邦东部土壤中种植的鹰嘴豆根际筛选潜在的解锌根际细菌,并进一步评估它们对小麦作物锌同化量的影响。在15个分离株中,CRS - 9、CRS - 17、CRS - 30和CRS - 38在磷酸锌肉汤中分别产生了6.1、5.9、5.63和5.6 μg/ml的净可溶性锌,相应的pH值分别为4.48、5.31、5.2和4.76。然而,细菌菌株CRS - 17、CRS - 30、CRS - 38和CRS - 9的磷酸锌溶解效率最高,分别为427.79%、317.39%、253.57%和237.04%。根据形态学、生化研究和16S rRNA基因测序,这四种细菌分离株被鉴定为CRS - 9、CRS - 17、CRS - 30和CRS - 38。细菌接种剂显著定殖在小麦植株的根部,并在根基质中形成生物膜。这些菌株显著提高了温室条件下种植的小麦的种子发芽率(%)和活力指数。在微观条件下播种小麦30天后,8个锌转运蛋白()基因在根部表达量最高,与绝对对照相比,经细菌处理的植株中锌含量同时更高。在测试的四种菌株中,两种细菌CRS - 38和CRS - 30提高了小麦的种子发芽率(%)、活力指数(2 - 2.5倍)、植株生物量、籽粒产量(2.39 g/株)和生物强化籽粒(54.25 μg/g Zn)。据我们所知,这可能是关于CRS - 9、CRS - 17和CRS - 30存在解锌特性的首次报道。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2f0e/8914200/34849b826f89/fpls-13-777771-g009.jpg
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