水生系统中的金属生物利用率--超越络合与竞争

Claude Fortin
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引用次数: 0

摘要

溶液中的金属生物利用率主要由两个因素驱动:络合和竞争。第一个因素是络合作用,它通过降低游离金属离子的活性来降低金属的整体反应活性,游离金属离子是涉及溶解配体或表面功能基团(非生物或生物)的金属反应的共同点。天然有机物在自然生态系统中无处不在,对于几种金属来说,天然有机物是最重要的金属络合配体。第二个因素是竞争,它有助于减少参与金属从大量溶液到细胞内介质的膜传输的生物配体的可用性。在淡水系统中,质子和硬度阳离子浓度是潜在调节金属生物利用率的主要参数。上述情况反映了目前公认的模式。本文指出了两个知识空白点:i) 除金属络合外,天然有机物的作用可能会导致金属生物利用率的增加;ii) 除竞争外,多种金属的作用可能会触发生物反馈机制,进而改变生物配体的结合特性。需要开展更多的研究工作,以了解这些被忽视的潜在影响的程度,并提高金属生物利用率的可预测性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Metal bioavailability in aquatic systems— beyond complexation and competition
Metal bioavailability in solution is mostly driven by two factors: complexation and competition. The first factor, complexation, contributes to decrease the overall reactivity of the metal by reducing the activity of the free metal ion, which is known as the common denominator of metal reactions involving either dissolved ligands or surface functional groups (abiotic or biotic). Ubiquitous in natural ecosystems, natural organic matter is, for several metals, the most important metal complexing ligand. The second factor, competition, contributes to decrease the availability of biotic ligands involved in the membrane transport of metals from the bulk solution to the intracellular medium. In freshwater systems, proton and hardness cation concentrations are the main parameters potentially modulating metal bioavailability. The above reflects the current accepted paradigm. In this paper, two knowledge gaps are identified: i) the role of natural organic matter other than metal complexation that may lead to an increase in metal bioavailability; and ii) the effects of multiple metals other than competition that may trigger biological feedback mechanisms which may, in turn, alter biotic ligand binding properties. More research efforts are needed to decipher the extent of these overlooked potential effects and to improve the predictability of metal bioavailability.
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