Shao Xia, Yang Chunmei, Chen Yuxuan, Liu Chang, Liu Chunjuan, Shi Xiaolong, Zhou Yufei
College of Agronomy, Shenyang Agricultural University, Shenyang, China.
Front Microbiol. 2025 May 1;16:1589415. doi: 10.3389/fmicb.2025.1589415. eCollection 2025.
Soil salinization is a substantial impediment to agricultural production, and investigating sustainable mitigation measures is essential for addressing food security. We conducted a two-year pot experiment to investigate the shaping mechanism of sorghum rhizosphere microbial community in sorghum-peanut intercropping system under salt stress. The experiment comprised four treatments: sole-cropped sorghum under normal soil conditions (NSS), intercropped sorghum under normal soil conditions (NIS), sole-cropped sorghum under salt-stress conditions (SSS), and intercropped sorghum under salt-stress conditions (SIS). The sorghum rhizosphere soil metabolites were examined using GC-MS, and the rhizosphere microbial community was characterized through metabolome sequencing. We identified 123 metabolites across treatments, with significant differences between normal and salt-stress soil conditions. The major metabolite classes included carbohydrates, alcohols, and acids. Key carbohydrates, including fructose and sucrose, were significantly reduced in the SIS than in SSS, NSS, and NIS treatments. Metabolic pathway analyses revealed that these differences were primarily associated with "Fructose and mannose metabolism," "Starch and sucrose metabolism" and "ABC transporter." Metabolome analyses revealed significant differences in microbial community structure across diverse soil conditions and cropping patterns. At phylum level, Proteobacteria, Gemmatimonadetes, and Verrucomicrobia predominated, with their relative abundance experiencing substantial changes under salt stress. SIS facilitated the enrichment of specific genera (), which were associated with soil health and stress tolerance. Additionally, the responses of rare microbial taxa to salt stress and intercropping varied, with specific rare microbial taxa () exhibiting relative abundance under salt stress. Correlation analysis of metabolites and microbial taxa revealed that certain carbohydrates were significantly positively correlated with specific microbial phyla (Cyanobacteria and Nitrospirae) while demonstrating a significant negative correlation with Planctomycetota and Bacteroidota. These correlations indicate that sorghum intercropped with peanuts can promote the enrichment of microbial taxa under salt stress, thereby enhancing soil metabolic functions and stress tolerance by optimizing the rhizosphere microbial community. This study reveals the mechanism through which sorghum-peanut intercropping under salt stress influences the composition of sorghum's rhizosphere microbial community by modulating soil sugar metabolism pathways. This finding provides a new perspective on sustainable agricultural practices in saline soils and emphasizes the pivotal role of plant-metabolite-microbe interactions in abiotic stress mitigation.
土壤盐渍化是农业生产的重大障碍,研究可持续的缓解措施对于解决粮食安全问题至关重要。我们进行了一项为期两年的盆栽试验,以研究盐胁迫下高粱-花生间作系统中高粱根际微生物群落的形成机制。该试验包括四个处理:正常土壤条件下单作高粱(NSS)、正常土壤条件下间作高粱(NIS)、盐胁迫条件下单作高粱(SSS)和盐胁迫条件下间作高粱(SIS)。使用气相色谱-质谱联用仪(GC-MS)检测高粱根际土壤代谢产物,并通过代谢组测序对根际微生物群落进行表征。我们在各处理中鉴定出123种代谢产物,正常土壤条件和盐胁迫土壤条件之间存在显著差异。主要代谢产物类别包括碳水化合物、醇类和酸类。关键碳水化合物,包括果糖和蔗糖,在SIS处理中的含量显著低于SSS、NSS和NIS处理。代谢途径分析表明,这些差异主要与“果糖和甘露糖代谢”、“淀粉和蔗糖代谢”以及“ABC转运蛋白”有关。代谢组分析揭示了不同土壤条件和种植模式下微生物群落结构的显著差异。在门水平上,变形菌门、芽单胞菌门和疣微菌门占主导地位,它们的相对丰度在盐胁迫下发生了显著变化。SIS促进了特定属()的富集,这些属与土壤健康和胁迫耐受性相关。此外,稀有微生物类群对盐胁迫和间作的反应各不相同,特定的稀有微生物类群()在盐胁迫下表现出相对丰度。代谢产物与微生物类群的相关性分析表明,某些碳水化合物与特定微生物门(蓝细菌门和硝化螺旋菌门)显著正相关,而与浮霉菌门和拟杆菌门显著负相关。这些相关性表明,高粱与花生间作可以促进盐胁迫下微生物类群的富集,从而通过优化根际微生物群落增强土壤代谢功能和胁迫耐受性。本研究揭示了盐胁迫下高粱-花生间作通过调节土壤糖代谢途径影响高粱根际微生物群落组成的机制。这一发现为盐渍土可持续农业实践提供了新的视角,并强调了植物-代谢产物-微生物相互作用在缓解非生物胁迫中的关键作用。
