AI Article Synopsis
- - Two strains of symbiotic bacteria, SOB-1 and SOB-2, were isolated from the algae Scenedesmus obliquus and tested for their ability to degrade the herbicide acetochlor (ACT) under stress conditions, revealing significant degradation capabilities (up to 226.9% increase for SOB-1) compared to non-bacterial algae.
- - Higher concentrations of ACT led to increased metabolic stress and cellular damage in the algae, while also decreasing important antimicrobial substances, allowing the bacteria to exploit the algae more effectively.
- - The study indicated a shift in the relationship between the algae and bacteria from mutualism to exploitation as ACT concentrations increased, suggesting potential risks for algal-bacterial systems under ecotoxic
Article Abstract
In this study, two strains of symbiotic bacteria (SOB-1 and SOB-2) were isolated from Scenedesmus obliquus, and various algal-bacterial mutualistic systems were established under acetochlor (ACT) stress conditions. Following exposure to varying ACT concentrations from 2.0 to 25.0 μg/L, the capacity for co-cultured bacteria to degrade ACT was enhanced in 7 days by up to 226.9% (SOB-1) and 193.0% (SOB-2), compared with axenic algae, although bacteria exposed to higher ACT concentrations exacerbated algal metabolic stress, oxidative states, apoptosis and cellular lysis. ACT reduced carbohydrates in the phycosphere by up to 31.5%; compensatory nutrient plunder and structural damage by bacteria were the potential exploitation pathways determined based on the inhibition of bacterial infection using a glucanase inhibitor. The ACT-induced reduction in algal antimicrobial substances, including fatty acids and phenolics (by up to 58.1% and 56.6%, respectively), also facilitated bacterial exploitation of algae. ACT-dependent interspecific interaction coefficients between algae and bacteria generated from long-term symbiosis cultures implied that bacteria moved from mutualism (0 and 2.0 μg/L ACT) to exploitation (7.9 and 25.0 μg/L ACT). The population dynamic model under incremental ACT-concentration scenarios inferred that theoretical systematic extinction may occur in algal-bacterial systems earlier than in axenic algae. These outcomes provide interspecific insights into the distortion of algal-bacterial reciprocity due to the ecotoxicological effects of ACT.
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| http://dx.doi.org/10.1016/j.jhazmat.2023.132848 | DOI Listing |
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