Kumar Nitish, Kaur Bhupinder, Sharma Deepika, Korpole Suresh, Shukla Shardulya, Bhardwaj Pushpender, Patel Manoj Kumar, Acharya Somen, Khatri Madhu, Saxena Shweta
Defence Institute of High Altitude Research (DIHAR), Defence Research and Development Organization (DRDO), Ministry of Defence, Govt. of India, C/o 56 APO, Leh-Ladakh, 194101, India.
University Institute of Engineering and Technology (UIET), Panjab University, Chandigarh, 160014, India.
Sci Rep. 2025 Apr 22;15(1):13839. doi: 10.1038/s41598-025-98242-2.
High-altitude environments present unique abiotic stresses, yet their impact on the growth, nutritional quality, and rhizospheric interactions of E. sativa remains underexplored. Here, we investigate the altitudinal variations in growth dynamics, nutritional composition, and rhizospheric free-living N-fixing bacteria (NFBs) of E. sativa (Arugula) grown at higher (3,524 m, Leh-Ladakh) and lower (321 m, Chandigarh) altitudes. Results revealed significant physiological adaptations to high-altitude conditions, with increased concentrations of magnesium (748.84 ± 4.06 mg/100 g), iron (189.83 ± 2.16 mg/100 g), and manganese (8.48 ± 0.27 mg/100 g), while potassium (3,400.83 ± 3.82 mg/100 g), sodium (175.83 ± 1.44 mg/100 g), and copper (1.69 ± 0.01 mg/100 g) were higher at lower-altitude. Zinc content remained unchanged. Notably, dietary nitrate was higher (155.67 ± 22.12 mg/100 g) at high-altitudes. Rhizospheric NFBs were isolated and functionally characterized for N-fixation efficacy along with various plant growth-promoting (PGP) attributes; viz., production of ammonia, siderophores, HCN, IAA and phosphate solubilization. Field inoculation with selected strains significantly enhanced nitrogen content and plant growth. Soil chemical analysis further revealed significant differences between the altitudes. A total of twenty-seven NFBs belonging to Actinobacteria (77%), Proteobacteria (11%), Firmicutes(8%), and Bacteroidetes(4%) were isolated, with Streptomyces being the predominant genus, exhibiting distinct species at different altitudes. Remarkably, high-altitude strains showed significantly higher N-fixing efficiencies (88.15 ± 17.41 µgN mL) than lower-altitude (65.7 ± 14.36 µgN mL) along with superior PGP traits. Overall, these findings suggest that E. sativa, enriched in key nutrients at high-altitudes, could be a valuable functional food crop, addressing the dietary needs of high-altitude populations. Furthermore, the rhizospheric NFBs identified in this study may be potentially beneficial for the development of novel bio-fertilizers, promoting eco-friendly agricultural practices through improved N-fixation. Further field trials are recommended to validate their potential for sustainable crop production.
高海拔环境呈现出独特的非生物胁迫,但它们对紫花南芥的生长、营养品质和根际相互作用的影响仍未得到充分研究。在这里,我们调查了在高海拔(3524米,列城-拉达克)和低海拔(321米,昌迪加尔)生长的紫花南芥(芝麻菜)在生长动态、营养成分和根际自生固氮细菌(NFBs)方面的海拔变化。结果显示,紫花南芥对高海拔条件有显著的生理适应性,镁(748.84±4.06毫克/100克)、铁(189.83±2.16毫克/100克)和锰(8.48±0.27毫克/100克)的浓度增加,而钾(3400.83±3.82毫克/100克)、钠(175.83±1.44毫克/100克)和铜(1.69±0.01毫克/100克)在低海拔地区含量更高。锌含量保持不变。值得注意的是,高海拔地区的膳食硝酸盐含量较高(155.67±22.12毫克/100克)。对根际NFBs进行了分离,并对其固氮效率以及各种植物促生(PGP)特性进行了功能表征;即氨、铁载体、HCN、IAA 的产生和磷的溶解。用选定菌株进行田间接种显著提高了氮含量和植物生长。土壤化学分析进一步揭示了不同海拔之间的显著差异。共分离出27株属于放线菌(77%)、变形菌(11%)、厚壁菌(8%)和拟杆菌(4%)的NFBs,其中链霉菌是优势属,在不同海拔表现出不同的物种。值得注意的是,高海拔菌株的固氮效率(88.15±17.41微克氮/毫升)明显高于低海拔菌株(65.7±14.36微克氮/毫升),并且具有更优异的PGP特性。总体而言,这些发现表明,在高海拔地区富含关键营养素的紫花南芥可能是一种有价值的功能性粮食作物,可满足高海拔人群的饮食需求。此外,本研究中鉴定的根际NFBs可能对新型生物肥料的开发具有潜在益处,通过改善固氮促进生态友好型农业实践。建议进一步进行田间试验以验证它们在可持续作物生产中的潜力。
