Response of laboratory ecosystems to environmental stress: Effect of phenol

J. Pratt, N. Bowers, B. R. Niederlehner, J. Cairns
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引用次数: 4

Abstract

Ecologically realistic laboratory and field simulated ecosystems (microcosms and mesocosms) are playing increasing roles in fate and effect testing of chemicals and mixtures. Controlled ecosystems allow evaluation of toxicant effects on collective and emergent ecosystem properties. Information is needed to evaluate the validity of test system responses, interpretability of results, and cost effectiveness of simulated ecosystem tests. We developed replicate microcosms using periphyton on polyurethane artificial substrates. Source communities were obtained from two ecosystems—a reservoir in Kentucky and a softwater pond in Virginia—and tested for effects of continuous inputs of phenol (up to 30 mg/L) over 21 days. System responses measured included several biomass estimators, net oxygen production, and protozoan species richness. Communities were generally insensitive to phenol input. Primary production in microcosms from both ecosystems was inhibited at phenol concentrations >10 mg/L and chlorophyll a concentrations were also depressed. Other biomass estimators (protein, hexosamine) were not affected or were stimulated at lower (⩽10 mg/L) phenol concentrations. Protozoan species numbers were not affected. Functional shifts in the communities preceded adverse structural effects. Effect levels were similar for both communities, although the more complex community with greater biomass (Kentucky) showed more significant responses than the simpler community (Virginia). Systems showed resistance to phenol levels that were actually toxic in standard single-species tests, suggesting that ecosystems may differ in magnitude and rate of response to some nonpersistent toxicants.
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实验室生态系统对环境压力的响应:苯酚的影响
生态现实的实验室和现场模拟生态系统(微观和中生态)在化学品和混合物的命运和效果测试中发挥着越来越大的作用。受控制的生态系统允许评估对集体和新兴生态系统特性的毒性影响。评估测试系统响应的有效性、结果的可解释性和模拟生态系统测试的成本效益需要信息。我们利用外生植物在聚氨酯人造基质上开发了复制微观世界。研究人员从两个生态系统——肯塔基州的一个水库和弗吉尼亚州的一个软池塘——中获得了源群落,并对21天内连续输入苯酚(高达30毫克/升)的效果进行了测试。测量的系统响应包括几个生物量估计值、净氧产量和原生动物物种丰富度。群落一般对苯酚输入不敏感。当苯酚浓度>10 mg/L时,两个生态系统微生物的初级产量均受到抑制,叶绿素a浓度也受到抑制。其他生物量估算物(蛋白质、己糖胺)在较低(≤10 mg/L)苯酚浓度下不受影响或受到刺激。原生动物的种类数量没有受到影响。群落的功能转变先于不利的结构影响。两种群落的效应水平相似,但生物量更大的复杂群落(肯塔基州)比生物量更简单的群落(弗吉尼亚州)表现出更显著的响应。在标准的单物种测试中,系统显示出对实际上有毒的苯酚水平的抵抗力,这表明生态系统对一些非持久性有毒物质的反应程度和速度可能不同。
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