Jabborova Dilfuza, Kadirova Dilbar, Jabbarov Zafarjon, Thakker Janki N, Rathod Khushbu, Jabborov Muzafar, Madan Ayush, Jahan Mohammad Shah, Rahimi Mehdi, Husaini Amjad M
Institute of Genetics and Plant Experimental Biology, Uzbekistan Academy of Sciences, 111208, Kibray, Uzbekistan.
Faculty of Biology, National University of Uzbekistan, 100174, Tashkent, Uzbekistan.
Antonie Van Leeuwenhoek. 2025 Sep 2;118(10):148. doi: 10.1007/s10482-025-02161-1.
Plant growth-promoting rhizobacteria (PGPR) are known to enhance the productivity, development, yield, and soil health of both medicinal and vegetable crops. The present investigation evaluated the influence of PGPR on the growth attributes and physiological parameters of ginger, alongside soil quality, under field conditions. Field trials were carried out over three consecutive years (2020 to 2022), with ginger being planted each March. The experiment included six treatments: five PGPR strains-Bacillus subtilis IGPEB 1, Bacillus pumilus IGPEB 2, Bacillus altitudinis IGPEB 8, Pseudomonas koreensis IGPEB 17, and Bacillus endophyticus IGPEB 33-applied individually, along with an uninoculated control. These treatments were arranged in a randomized block design with five replications. Among the strains, B. endophyticus IGPEB 33 notably improved ginger's morphological traits, including shoot length, leaf number, leaf length, leaf width, and overall yield, compared to the control. This strain also significantly boosted the content of chlorophyll (a and b), total chlorophyll, and carotenoids in ginger leaves. Furthermore, B. endophyticus IGPEB 33 enhanced soil nitrogen content as well as catalase and urease enzymatic activity. Notably, urease activity was also increased with the inoculation of B. subtilis IGPEB 1, B. pumilus IGPEB 2, and P. koreensis IGPEB 17. A significant positive correlation was observed between phosphorus levels and physiological parameters such as relative water content, photosynthetic pigments, and soil enzymes. Overall, this study highlights the effectiveness of PGPR in improving ginger growth and productivity through favorable modulation of plant physiology and soil biochemical properties, offering a promising approach for sustainable crop management. The positive correlations observed between PGPR inoculation, physiological traits, and yield performance suggest that these bacterial strains actively contribute to nutrient uptake, water retention, and stress tolerance mechanisms in ginger. Furthermore, their use promotes a sustainable and environmentally friendly alternative to chemical fertilizers, aligning with global efforts to reduce agricultural dependency on synthetic inputs. Given their effectiveness and potential scalability, these PGPR strains are strong candidates for development into commercial biofertilizer formulations.
植物促生根际细菌(PGPR)已知可提高药用作物和蔬菜作物的生产力、促进其生长发育、增加产量并改善土壤健康状况。本研究评估了在田间条件下,PGPR对生姜生长特性、生理参数以及土壤质量的影响。连续三年(2020年至2022年)进行了田间试验,每年3月种植生姜。试验包括六种处理:单独施用五种PGPR菌株——枯草芽孢杆菌IGPEB 1、短小芽孢杆菌IGPEB 2、高地芽孢杆菌IGPEB 8、韩国假单胞菌IGPEB 17和内生芽孢杆菌IGPEB 33,以及一个未接种的对照。这些处理采用随机区组设计,重复五次。在这些菌株中,与对照相比,内生芽孢杆菌IGPEB 33显著改善了生姜的形态特征,包括茎长、叶片数量、叶长、叶宽和总产量。该菌株还显著提高了生姜叶片中叶绿素(a和b)、总叶绿素和类胡萝卜素的含量。此外,内生芽孢杆菌IGPEB 33提高了土壤氮含量以及过氧化氢酶和脲酶的活性。值得注意的是,接种枯草芽孢杆菌IGPEB 1、短小芽孢杆菌IGPEB 2和韩国假单胞菌IGPEB 17也提高了脲酶活性。观察到磷水平与相对含水量、光合色素和土壤酶等生理参数之间存在显著正相关。总体而言,本研究强调了PGPR通过有利地调节植物生理和土壤生化特性来改善生姜生长和生产力的有效性,为可持续作物管理提供了一种有前景的方法。PGPR接种、生理特性和产量表现之间的正相关表明,这些细菌菌株积极促进生姜的养分吸收、保水和抗逆机制。此外,它们的使用促进了一种可持续且环保的替代化肥的方法,符合全球减少农业对合成投入物依赖的努力。鉴于其有效性和潜在的可扩展性,这些PGPR菌株是开发成商业生物肥料配方的有力候选者。
