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2014 年至 2022 年加利西亚沿海软体动物中的 Yessotoxins:变异性、生物转化和对碱性水解的抗性。

Yessotoxins in Mollusks of the Galician Coast from 2014 to 2022: Variability, Biotransformation, and Resistance to Alkaline Hydrolysis.

机构信息

Centro de Investigacións Mariñas (CIMA), Xunta de Galicia, 36611 Pontevedra, Spain.

Instituto Tecnolóxico para o Control do Medio Mariño de Galicia (Intecmar), 36611 Pontevedra, Spain.

出版信息

Toxins (Basel). 2023 Nov 16;15(11):661. doi: 10.3390/toxins15110661.

DOI:10.3390/toxins15110661
PMID:37999524
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10674579/
Abstract

The presence of yessotoxins (YTXs) was analyzed in 10,757 samples of Galician bivalves from 2014 to 2022. Only YTX and 45-OH YTX were found. YTX was detected in 31% of the samples, while 45-OH YTX was found in 11.6% of them. Among the samples containing YTX, 45-OH YTX was detected in 37.3% of cases. The maximum recorded levels were 1.4 and 0.16 mg of YTX-equivalentsg, for YTX and 45-OH YTX, respectively, which are well below the regulatory limit of the European Union. The YTX and 45-OH YTX toxicities in the raw extracts and extracts subjected to alkaline hydrolysis were strongly and linearly related. Due to the lack of homo-YTX in Galician samples, the effect of alkaline hydrolysis on homo-YTX and 45OH-Homo-YTX was only checked in 23 additional samples, observing no negative effect but a high correlation between raw and hydrolyzed extracts. Hydrolyzed samples can be used instead of raw ones to carry out YTXs determinations in monitoring systems, which may increase the efficiency of those systems where okadaic acid episodes are very frequent and therefore a higher number of hydrolyzed samples are routinely analyzed. The presence of YTX in the studied bivalves varied with the species, with mussels and cockles having the highest percentages of YTX-detected samples. The presence of 45-OH YTX was clearly related to YTX and was detected only in mussels and cockles. Wild populations of mussels contained proportionally more 45-OH YTX than those that were raft-cultured. Spatially, toxin toxicities varied across the sampling area, with higher levels in raft-cultured mussels except those of Ría de Arousa. Ría de Ares (ARE) was the most affected geographical area, although in other northern locations, lower toxin levels were detected. Seasonally, YTX and 45-OH YTX toxicities showed similar patterns, with higher levels in late summer and autumn but lower toxicities of the 45-OH toxin in August. The relationship between the two toxins also varied seasonally, in general with a minimum proportion of 45-OH YTX in July-August but with different maximum levels for raft-cultured and wild mussel populations. Interannually, the average toxicities of YTX decreased from 2014 to 2017 and newly increased from 2018 to 2021, but decreased slightly in 2022. The relationship between 45-OH YTX and YTX also varied over the years, but neither a clear trend nor a similar trend for wild and raft mussels was observed.

摘要

从 2014 年到 2022 年,对加利西亚贝类的 10757 个样本进行了 yessotoxins(YTXs)的分析。仅发现 YTX 和 45-OH YTX。31%的样本中检测到 YTX,而其中 11.6%的样本中发现了 45-OH YTX。在含有 YTX 的样本中,有 37.3%的样本检测到 45-OH YTX。记录的最高水平分别为 1.4 和 0.16 毫克 YTX 当量/克,分别为 YTX 和 45-OH YTX,远低于欧盟的监管限值。在原始提取物和经碱性水解的提取物中,YTX 和 45-OH YTX 的毒性具有强烈的线性关系。由于加利西亚样品中没有 homo-YTX,因此仅在另外 23 个样品中检查了碱性水解对 homo-YTX 和 45OH-Homo-YTX 的影响,没有观察到负面影响,但原始提取物和水解提取物之间存在高度相关性。水解样品可用于替代原始样品,在监测系统中进行 YTXs 测定,这可能会提高那些经常发生 okadaic 酸事件的系统的效率,因此通常会分析更多的水解样品。在所研究的双壳类动物中,YTX 的存在因物种而异,贻贝和鸟蛤的 YTX 检出率最高。45-OH YTX 的存在与 YTX 明显相关,仅在贻贝和鸟蛤中检出。野生贻贝体内的 45-OH YTX 比例高于筏式养殖贻贝。从空间上看,整个采样区域的毒素毒性各不相同,除了 Ría de Arousa 外,筏式养殖贻贝的毒素水平较高。Ares 湾(ARE)是受影响最严重的地理区域,尽管在其他北部地区,毒素水平较低。季节上,YTX 和 45-OH YTX 的毒性表现出相似的模式,夏末和秋季的水平较高,但 8 月 45-OH 毒素的毒性较低。两种毒素之间的关系也随季节而变化,一般来说,7 月至 8 月 45-OH YTX 的比例最低,但筏式养殖和野生贻贝种群的最高水平不同。从年际上看,2014 年至 2017 年 YTX 的平均毒性下降,2018 年至 2021 年新增加,但 2022 年略有下降。45-OH YTX 和 YTX 之间的关系也逐年变化,但无论是野生和筏式贻贝,都没有观察到明显的趋势或类似的趋势。

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