通过纳米碳溶胶操纵根相关微生物群以改善植物生长。

IF 10.6 1区 生物学 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Journal of Nanobiotechnology Pub Date : 2024-11-09 DOI:10.1186/s12951-024-02971-x
Lingtong Cheng, Jiemeng Tao, Peng Lu, Taibo Liang, Xutao Li, Dong Chang, Huan Su, Wei He, Zechao Qu, He Li, Wenjun Mu, Wei Zhang, Nan Liu, Jianfeng Zhang, Peijian Cao, Jingjing Jin
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引用次数: 0

摘要

背景:有人提出用纳米材料调节微生物组来改善植物生长,减少对外部投入的依赖。纳米碳溶胶(CNS)因其提高植物生产力的潜力而备受关注。然而,纳米碳溶胶与根瘤微生物之间的作用机理在很大程度上仍然难以捉摸:结果:在此,我们试图系统地探讨纳米碳溶胶(浓度分别为 600 毫克/升和 1200 毫克/升)对烟草生长、土壤物理特性和根相关微生物群的影响。CNS 对土壤理化性质和植物生长的影响显著,且呈剂量依赖性,600 毫克/升 CNS 可使生物量积累增加 28.82%。对比 CNS 处理过的植物和对照植物,发现微生物群组成存在显著差异,包括 1148 种不同的 ASV(923 种细菌和 225 种真菌)、微生物群相互作用以及根相关微生物群的代谢功能。真菌和细菌群落对 CNS 处理有不同的反应模式,具有阶段性和剂量依赖性效应,处理 10 天后,在 1200 毫克/升浓度下观察到的微生物群落结构变化最为显著。与对照植物相比,CNS 处理植物的微生物网络具有更多的节点和边缘、更高的连通性和更多的中枢微生物。与对照组相比,CNS 显著提高了各种细菌生物标志物(如鞘氨单胞菌和伯克霍尔德氏菌)和真菌生物标志物(包括青霉、嗜菌菌和担子菌)的丰度,而这些生物标志物都是潜在的对植物有益的生物。根据元基因组数据进行的功能预测表明,在 CNS 处理下,与养分循环相关的途径大大丰富。此外,从土壤和根部样本中分离出了 391 种可培养细菌和 44 种可培养真菌。其中,6 种细菌和 2 种真菌在 CNS 处理后富集,被证实具有促进植物生长的作用,2 种真菌(Cladosporium spp.在某种程度上,中枢神经系统对微生物组的驱动和塑造有助于其对植物生长和发育的影响:我们的研究结果揭示了根相关微生物群在介导中枢神经系统与植物之间相互作用中的关键作用,从而为利用中枢神经系统促进植物生长提供了有价值的见解和策略。
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Manipulation in root-associated microbiome via carbon nanosol for plant growth improvements.

Background: Modulating the microbiome with nanomaterials has been proposed to improve plant growth, and reduce reliance on external inputs. Carbon Nanosol (CNS) was attracted for its potential to improve plant productivity. However, the mechanism between CNS and rhizosphere microorganisms remained largely elusive.

Results: Here, we tried to systematically explore the effects of CNS (600 and 1200 mg/L by concentration) on tobacco growth, soil physical properties, and root-associated microbiome. The influence of CNS on soil physicochemical properties and plant growth was significant and dose-dependent, leading to a 28.82% increase in biomass accumulation by 600 mg/L CNS. Comparison between the CNS-treated and control plants revealed significant differences in microbiome composition, including 1148 distinct ASVs (923 bacteria and 225 fungi), microbiome interactions, and metabolic function of root-associated microbiomes. Fungal and bacterial communities had different response patterns for CNS treatment, with phased and dose-dependent effects, with the most significant changes in microbial community structure observed at 1200 mg/L after 10 days of treatment. Microbial networks of CNS-treated plants had more nodes and edges, higher connectivity, and more hub microorganisms than those of control plants. Compared with control, CNS significantly elevated abundances of various bacterial biomarkers (such as Sphingomonas and Burkholderia) and fungi biomarkers (including Penicillium, Myceliophthora, and Talaromyces), which were potential plant-beneficial organisms. Functional prediction based on metagenomic data demonstrated pathways related to nutrient cycling being greatly enriched under CNS treatment. Furthermore, 391 culturable bacteria and 44 culturable fungi were isolated from soil and root samples. Among them, six bacteria and two fungi strains enriched upon CNS treatment were validated to have plant growth promotion effect, and two fungi (Cladosporium spp. and Talaromyces spp.) played their roles by mediating volatile organic compounds (VOCs). To some extent, the driving and shaping of the microbiome by CNS contributed to its impact on plant growth and development.

Conclusion: Our results revealed the key role of root-associated microbiota in mediating the interaction between CNS and plants, thus providing valuable insights and strategies for harnessing CNS to enhance plant growth.

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来源期刊
Journal of Nanobiotechnology
Journal of Nanobiotechnology BIOTECHNOLOGY & APPLIED MICROBIOLOGY-NANOSCIENCE & NANOTECHNOLOGY
CiteScore
13.90
自引率
4.90%
发文量
493
审稿时长
16 weeks
期刊介绍: Journal of Nanobiotechnology is an open access peer-reviewed journal communicating scientific and technological advances in the fields of medicine and biology, with an emphasis in their interface with nanoscale sciences. The journal provides biomedical scientists and the international biotechnology business community with the latest developments in the growing field of Nanobiotechnology.
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