Caique Menezes de Abreu, Guilherme Henrique Fernandes Carneiro, Márcia Regina da Costa, Gabriela Madureira Barroso, Tayna Sousa Duque, Joice Mariana Santos Silva, José Barbosa Dos Santos
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引用次数: 0
Abstract
Phytoremediation using Avena sativa offers a sustainable strategy for mitigating sulfentrazone contamination while integrating bioenergy production. This study proposes an analysis of the bioenergy potential and the microbial metagenomic profile associated with Avena sativa in the presence and absence of sulfentrazone, aiming at the synergistic bioprospecting of microbial communities capable of biodegradation and remediation of contaminated environments. Using a randomized block design, we evaluated the bioenergy potential and rhizospheric microbial dynamics of A. sativa in soils with and without sulfentrazone (600 g ha-1). Herbicide residues were quantified via UHPLC-MS/MS, and metagenomic profiles were obtained through 16S rRNA gene and ITS region sequencing to assess shifts in rhizospheric microbiota. Microbial diversity was analyzed using the Shannon and Gini-Simpson Indices, complemented by Principal Component Analysis (PCA). Bioenergy yields (biogas and ethanol) were estimated based on plant biomass. Over 80 days, the cultivation of A. sativa promoted a 19.7% dissipation of sulfentrazone, associated with rhizospheric enrichment of plant growth-promoting taxa (Bradyrhizobium, Rhodococcus, and Trichoderma), which increased by 68% compared to uncontaminated soils. Contaminated soils exhibited reduced microbial diversity (Gini-Simpson Index = 0.7), with a predominance of Actinobacteria and Ascomycota, suggesting adaptive specialization. Despite herbicide-induced stress (39.3% reduction in plant height and 60% reduction in grain yield), the biomass demonstrated considerable bioenergy potential: 340.6 m3 ha-1 of biogas and 284.4 L ha-1 of ethanol. The findings highlight the dual role of A. sativa in soil rehabilitation and renewable energy systems, supported by plant-microbe synergies. Scalability challenges and regulatory gaps in ecotoxicological assessments were identified, reinforcing the need to optimize microbial consortia and implement region-specific management strategies. These results support the integration of phytoremediation into circular bioeconomy models, balancing ecological recovery with agricultural productivity. Future research should focus on microbial genetic pathways, field-scale validation, and the development of regulatory frameworks to advance this green technology in global soil remediation efforts.
利用苜蓿进行植物修复提供了一种可持续的策略来减轻磺胺酮污染,同时整合生物能源生产。本研究提出了在存在和不存在磺胺曲酮的情况下,与玉米玉米相关的生物能源潜力和微生物宏基因组图谱的分析,旨在协同生物勘探能够生物降解和修复污染环境的微生物群落。采用随机区组设计,研究了在添加和不添加磺胺菊酮(600 g ha-1)的土壤中,sativa的生物能源潜力和根际微生物动态。通过UHPLC-MS/MS对除草剂残留进行定量分析,并通过16S rRNA基因和ITS区域测序获得宏基因组图谱,以评估根际微生物群的变化。微生物多样性分析采用Shannon指数和Gini-Simpson指数,并辅以主成分分析(PCA)。生物能源产量(沼气和乙醇)是基于植物生物量估算的。经过80天的培养,苜蓿的磺胺酮的消散率达到19.7%,与根际植物生长促进类群(慢根瘤菌、红球菌和木霉)的富集有关,比未污染的土壤增加了68%。污染土壤的微生物多样性降低(Gini-Simpson指数= 0.7),放线菌和子囊菌群占优势,表明土壤的适应性特化。尽管受到除草剂胁迫(株高降低39.3%,籽粒产量降低60%),但生物量显示出相当大的生物能源潜力:340.6 m3 ha-1沼气和284.4 L ha-1乙醇。这些发现强调了sativa在土壤修复和可再生能源系统中的双重作用,并得到了植物-微生物协同作用的支持。生态毒理学评估的可扩展性挑战和监管缺口被确定,加强了优化微生物群落和实施区域特定管理策略的必要性。这些结果支持将植物修复纳入循环生物经济模型,平衡生态恢复与农业生产力。未来的研究应该集中在微生物遗传途径、田间规模验证和监管框架的发展上,以推进这种绿色技术在全球土壤修复中的应用。
期刊介绍:
The Journal of Xenobiotics publishes original studies concerning the beneficial (pharmacology) and detrimental effects (toxicology) of xenobiotics in all organisms. A xenobiotic (“stranger to life”) is defined as a chemical that is not usually found at significant concentrations or expected to reside for long periods in organisms. In addition to man-made chemicals, natural products could also be of interest if they have potent biological properties, special medicinal properties or that a given organism is at risk of exposure in the environment. Topics dealing with abiotic- and biotic-based transformations in various media (xenobiochemistry) and environmental toxicology are also of interest. Areas of interests include the identification of key physical and chemical properties of molecules that predict biological effects and persistence in the environment; the molecular mode of action of xenobiotics; biochemical and physiological interactions leading to change in organism health; pathophysiological interactions of natural and synthetic chemicals; development of biochemical indicators including new “-omics” approaches to identify biomarkers of exposure or effects for xenobiotics.
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