Key Laboratory of Plant Secondary Metabolism and Regulation of Zhejiang Province, College of Life Sciences and Medicine, Zhejiang Sci-Tech University, Hangzhou 310018, China.
Key Laboratory of Plant Secondary Metabolism and Regulation of Zhejiang Province, College of Life Sciences and Medicine, Zhejiang Sci-Tech University, Hangzhou 310018, China.
Ecotoxicol Environ Saf. 2024 Mar 1;272:116012. doi: 10.1016/j.ecoenv.2024.116012. Epub 2024 Jan 30.
Heavy metal pollution of agricultural soils, especially from cadmium (Cd) contaminationcaused serious problems in both food security and economy. Sorghum bicolor (L.) showed a great potential in phytoremediation of Cd contamination due to its fast growth, high yield and easy harvesting. However, the growth of S. bicolor plants tends to be inhibited under Cd exposure, which limited its application for Cd remediation. Plant growth-promoting rhizobacteria may enhance the Cd resistance of S. bicolor and thus improve its Cd removal efficiency. In this study, three Cd-resistant bacteria were screened based on Cd and acid tolerance and identified as Bacillus velezensis QZG6, Enterobacter cloacae QZS3 and Bacillus cereus QZS8, by 16S rRNA sequencing. Inoculation of hydroponic plants with strains QZG6, QZS3 or QZS8 significantly promoted the biomass of sorghum plants by 31.52%, 50.20% and 26.93%, respectively, compared with those of uninoculated plants under Cd exposure. The activity of SOD, POD and MDA content in Cd-stressed S. bicolor plants were reduced of 65.74%, 31.52%, and 80.91%, respectively, when inoculated with the strains QZS3. For pot experiment, strains QZG6, QZS3 and QZS8 significantly promoted the biomass of sorghum plants by 47.30%, 19.27% and 58.47%, compared with those of uninoculated plants under Cd exposure. The activity of SOD, POD and MDA content in Cd-stressed S. bicolor plants were reduced of 67.20%, 22.40%, and 40.65%, respectively, when inoculated with the strains QZS3. All these three strains significantly increased the Cd removal efficiency of the plants by 42.16% (QZG6), 18.76% (QZS3) and 21.06% (QZS8). To investigate the bacterial characteristics associated with growth promotion of S. bicolor plants, the ability on nitrogen fixation, phosphorus solubilization, siderophores production, and phytohormones production were determined. All the strains were able to fix nitrogen. Phosphorus release was observed for strains QZG6 (inorganic or organic phosphorus) and QZS3 (inorganic phosphorus). Both QZG6 and QZS8 were able to produce siderophores, while only QZG6 was positive for ACC deaminase. All the strains produced IAA, SA and GA. These results indicated that the three strains promoted the plant growth under Cd stress, probably through Cd detoxification by siderophores, as well as through growth regulation by N/P nutrient supply and phytohormone. The present study showed a great potential of the three Cd-resistant strains combined with S. bicolor plants in the remediation of Cd-polluted soils, which may provide a new insight into combining the advantages of microbes and plants to improve the remediation of Cd-contaminated soils.
重金属污染的农业土壤,尤其是镉(Cd)污染,在食品安全和经济方面造成了严重问题。由于其生长迅速、产量高且易于收获,高粱(Sorghum bicolor(L.))在镉污染的植物修复中具有很大的潜力。然而,在镉暴露下,高粱植物的生长往往受到抑制,这限制了其在 Cd 修复中的应用。植物促生根际细菌可以增强高粱对 Cd 的抗性,从而提高其 Cd 去除效率。在这项研究中,基于 Cd 和耐酸能力,筛选了 3 株 Cd 抗性细菌,并通过 16S rRNA 测序鉴定为解淀粉芽孢杆菌(Bacillus velezensis)QZG6、阴沟肠杆菌(Enterobacter cloacae)QZS3 和蜡样芽孢杆菌(Bacillus cereus)QZS8。在水培植物中接种菌株 QZG6、QZS3 或 QZS8 可分别显著促进 Cd 胁迫下高粱植株的生物量,与未接种植物相比,生物量分别增加了 31.52%、50.20%和 26.93%。与未接种植物相比,菌株 QZS3 接种后 Cd 胁迫下高粱植株 SOD、POD 和 MDA 含量分别降低了 65.74%、31.52%和 80.91%。在盆栽试验中,与未接种植物相比,菌株 QZG6、QZS3 和 QZS8 接种后 Cd 胁迫下高粱植株的生物量分别显著增加了 47.30%、19.27%和 58.47%。与未接种植物相比,菌株 QZS3 接种后 Cd 胁迫下高粱植株 SOD、POD 和 MDA 含量分别降低了 67.20%、22.40%和 40.65%。这 3 株菌均能显著提高植物的 Cd 去除效率,分别提高 42.16%(QZG6)、18.76%(QZS3)和 21.06%(QZS8)。为了研究与高粱植物生长促进相关的细菌特性,测定了菌株的固氮能力、溶磷能力、产铁载体能力和产植物激素能力。所有菌株均具有固氮能力。QZG6(无机或有机磷)和 QZS3 可释放磷。QZG6 和 QZS8 均能产生铁载体,但只有 QZG6 为 ACC 脱氨酶阳性。所有菌株均产生 IAA、SA 和 GA。这些结果表明,这 3 株菌可能通过铁载体的 Cd 解毒以及 N/P 养分供应和植物激素的生长调节,在 Cd 胁迫下促进了植物的生长。本研究表明,3 株 Cd 抗性菌株与高粱植物结合在 Cd 污染土壤修复中具有很大的潜力,这可能为结合微生物和植物的优势来改善 Cd 污染土壤的修复提供新的思路。
