利用标准技术优化常见淡水蓝藻毒素 ATX-a、CYN 和 MC-LR 的分离和浓度,优化蓝藻生长。

IF 2.6 4区 医学 Q2 PHARMACOLOGY & PHARMACY
Saravana Kumar Selvaraj , Bartosz Lelito , Michal Adamski , Ariel Kaminski
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引用次数: 0

摘要

一些最常见的淡水毒素包括锐毒素-a(ATX-a)、圆筒孢藻毒素(CYN)和微囊藻毒素-LR(MC-LR)。本文旨在比较提取和浓缩这些蓝藻毒素的不同方法,并检查选定物理因素对 Dolichospermum flos-aquae、Microcystis aeruginosa 和 Raphidiopsis raciborskii 生物量积累的影响。不同蓝藻培养条件对蓝藻毒素合成量的影响表明,与对照组相比,培养基中所有测试毒素的平均浓度随时间的推移没有显著变化。混合培养可增加细胞内 ATX-a 的含量。通气也会对细胞内 MC-LR 的浓度产生积极影响。为了优化毒素的固相萃取(SPE)过程,使用了 C18 相或活性炭。一般来说,使用 C18 相的毒素回收率较高。ATX-a 的最佳结果是使用含 0.1% 三氟乙酸(TFA)的甲醇进行洗脱,回收率达到 94%。MC-LR 的最佳回收率为 59%,CYN 为 22%。研究评估了从蓝藻中释放蓝藻毒素的各种方法,结果表明:使用 MilliQ 水和微波处理 10-15 秒,ATX-a 的浓度最高(0.60 μg/mg d.w)。至于 MC-LR,甲醇处理和 100°C 沸腾 15 分钟的提取量最高(6.73 μg/mg d.w)。使用 MilliQ 水和其他冷冻/解冻方法提取 CYN 的效果最好(1.54 μg/mg d.w)。总之,改变蓝藻培养的最佳参数仅会对蓝藻生物量积累和毒素合成的增加产生轻微影响。就 ATX 而言,关键是在 SPE 过程中使用反式脂肪酸添加剂。目前还没有一种方法被认为是分离各种细胞内蓝藻毒素的理想方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Optimization of isolation and concentration of the common freshwater cyanobacterial toxins ATX-a, CYN and MC-LR using standard techniques, optimization of cyanobacteria growth

Optimization of isolation and concentration of the common freshwater cyanobacterial toxins ATX-a, CYN and MC-LR using standard techniques, optimization of cyanobacteria growth
Some of the most commonly identified freshwater toxins are anatoxin-a (ATX-a), cylindrospermopsin (CYN), and microcystin-LR (MC-LR). The aim of this paper was to compare different methods of extracting and concentrating these cyanotoxins and check the impact of selected physical factors on the accumulation of biomass of Dolichospermum flos-aquae, Microcystis aeruginosa, and Raphidiopsis raciborskii. The effect of different cyanobacteria cultivation conditions on the amount of cyanotoxins synthesized showed no significant changes over time in the average concentration of all tested toxins in the medium compared to the control. Mixing cultures increases the intracellular content of ATX-a. Aerating also positively affects the concentration of MC-LR intracellularly. In order to optimize the solid phase extraction (SPE) process of toxins, the C18 phase or activated carbon was used. In general, higher toxin recoveries were achieved when using the C18 phase. The best result was achieved for ATX-a, 94% recovery with elution using methanol with 0.1% trifluoroacetic acid (TFA). For MC-LR, the best recovery was 59%, and for CYN 22%. The study evaluated the various methods to release cyanotoxins from cyanobacteria showed that: the highest ATX-a concentration (0.60 μg/mg d.w) was obtained using MilliQ water and microwave treatment for 10–15 s. For MC-LR, the highest extracted amount (6.73 μg/mg d.w) resulted from methanol treatment and boiling at 100 °C for 15 min. CYN extraction was the most effective by using MilliQ water and alternative freezing/thawing (1.54 μg/mg d.w). In conclusion, changing the optimal parameters of cyanobacterial cultivation, only slightly affects the increase in biomass accumulation and synthesis of cyanobacterial toxins. In the case of ATX, the key is the use of the TFA additive in the SPE process. No single method has been identified as the ideal approach for isolating various intracellular cyanotoxins.
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来源期刊
Toxicon
Toxicon 医学-毒理学
CiteScore
4.80
自引率
10.70%
发文量
358
审稿时长
68 days
期刊介绍: Toxicon has an open access mirror Toxicon: X, sharing the same aims and scope, editorial team, submission system and rigorous peer review. An introductory offer Toxicon: X - full waiver of the Open Access fee. Toxicon''s "aims and scope" are to publish: -articles containing the results of original research on problems related to toxins derived from animals, plants and microorganisms -papers on novel findings related to the chemical, pharmacological, toxicological, and immunological properties of natural toxins -molecular biological studies of toxins and other genes from poisonous and venomous organisms that advance understanding of the role or function of toxins -clinical observations on poisoning and envenoming where a new therapeutic principle has been proposed or a decidedly superior clinical result has been obtained. -material on the use of toxins as tools in studying biological processes and material on subjects related to venom and antivenom problems. -articles on the translational application of toxins, for example as drugs and insecticides -epidemiological studies on envenoming or poisoning, so long as they highlight a previously unrecognised medical problem or provide insight into the prevention or medical treatment of envenoming or poisoning. Retrospective surveys of hospital records, especially those lacking species identification, will not be considered for publication. Properly designed prospective community-based surveys are strongly encouraged. -articles describing well-known activities of venoms, such as antibacterial, anticancer, and analgesic activities of arachnid venoms, without any attempt to define the mechanism of action or purify the active component, will not be considered for publication in Toxicon. -review articles on problems related to toxinology. To encourage the exchange of ideas, sections of the journal may be devoted to Short Communications, Letters to the Editor and activities of the affiliated societies.
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