真菌次生代谢物胶质毒素通过重塑土壤微生物群增强土壤中的酶活性

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-09-14 DOI:10.1016/j.rhisph.2024.100960
Anastasia V. Teslya, Elena V. Gurina, Darya V. Poshvina, Artyom A. Stepanov, Aleksandr V. Iashnikov, Alexey S. Vasilchenko
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引用次数: 0

摘要

胶质毒素(GT)是由各种丝状真菌(包括用于生物植物保护的真菌(毛霉菌))产生的一种含硫表二硫代氧哌嗪。GT 对多种真菌和细菌具有明显的抗菌作用,因此很有希望成为农业系统中控制植物病原体的一种药剂。在本研究中,我们旨在调查引入 GT 后土壤微生物组的微生物特性。施用 GT 的剂量为 10、25、50、100 和 500 μM kg-1 土壤。培养 1、7、14、30、60 和 90 天后进行土壤取样。结果发现,GT 能明显刺激土壤微生物的呼吸活动,并在整个实验过程中保持这种活性。相反,微生物生物量的碳在 GT 的影响下会减少,只有在添加了 10 和 25 μM GT 的微生态系统中,微生物生物量的碳才会在实验结束时得到恢复。对细菌和真菌生物量的单独估计表明,细菌群落的生物量在处理后第 14 天增加,而真菌生物量在处理后第 30 天增加。在 GT 的影响下,参与碳循环(CB、βG、βX)、氮循环(NAG、LAP)和磷循环(AP)的土壤酶的活性显著增加。ITS 和 16S rDNA 标记的高通量扩增子测序显示,土壤真菌群落比细菌群落更容易受到 GT 的影响。这反映在α-多样性指数的变化和一些微生物属丰度的变化规律上。因此,一方面,所获得的数据有助于深入了解 GT 对土壤微生物群落的生物影响。另一方面,也为进一步研究土壤和根圈微生物产生的抗生素的生态作用指明了方向。
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Fungal secondary metabolite gliotoxin enhances enzymatic activity in soils by reshaping their microbiome

Gliotoxin (GT) is a sulfur-containing epidithiodioxopiperazine produced by various filamentous fungi, including those used in biological plant protection (Trichoderma virens). The pronounced antimicrobial effect of GT on a variety of fungi and bacteria makes it a promising agent for controlling phytopathogens in agricultural systems. In this study, we aim to investigate the microbiological properties of the soil microbiome after the introduction of GT. GT was applied at doses of 10, 25, 50, 100 and 500 μM kg−1 soil. Soil sampling was carried out after 1, 7, 14, 30, 60 and 90 days of incubation. It was found that GT significantly stimulated the respiratory activity of soil microorganisms and maintained this activity throughout the experiment. Carbon of microbial biomass, on the contrary, decreases under the influence of GT and is restored at the end of the experiment only in microcosms with 10 and 25 μM GT. Separate estimates of bacterial and fungal biomass showed that the bacterial community increased in biomass on day 14, while fungal biomass increased on day 30 after the treatment. Under the influence of GT, the activity of soil enzymes involved in the carbon (CB, βG, βX), nitrogen (NAG, LAP) and phosphate (AP) cycles significantly increased. High-throughput amplicon sequencing of the ITS and 16S rDNA markers revealed that the soil fungal community is more susceptible to GT than the bacterial community. This was reflected in changes in alpha-diversity indices and in the pattern of changes in the abundance of some microbial genera. Thus, on the one hand, the data obtained provides insight into the biological effects of GT on the soil microbial community. On the other hand, it sets the direction for further research into the ecological role of antibiotics produced by soil and rhizosphere microorganisms.

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4.30%
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567
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