Use of neutral red to assess survival of juvenile freshwater mussels (Bivalvia: Unionidae) in bioassays

P. Jacobson, J. Farris, R. Neves, D. Cherry
{"title":"Use of neutral red to assess survival of juvenile freshwater mussels (Bivalvia: Unionidae) in bioassays","authors":"P. Jacobson, J. Farris, R. Neves, D. Cherry","doi":"10.2307/3226786","DOIUrl":null,"url":null,"abstract":"The effectiveness of vital staining for assessing lethal and sublethal responses of juvenile mussels was examined. Neutral red was used to quantify survival of juvenile Villosa iris and Anodonta grandis after exposures to aqueous copper in 24-hour static bioassays. Live juveniles readily incorporated the stain, but dead individuals did not. Variation in stain intensity was associated with behavioral responses, permitting diagnosis of alive, dead, and sublethal responses of juvenile V. iris. The amber coloration of juvenile A. grandis prevented detection of variations in stain intensity, thus allowing only livingversus-dead determinations to be made. Responding to precipitous declines in populations of freshwater mussels (Unionidae), several workers recently conducted laboratory tests to measure sensitivity of juvenile stages to various pollutants (Johnson et al., 1990; Keller & Zam, 1991; Lasee, 1991). Both Johnson et al. (1990) and Keller & Zam (1991) determined post-exposure mortality from observations of internal anatomy, but did not detail any sublethal effects of the exposures. By contrast, Lasee (1991) assessed both post-exposure mortality and sublethal responses by individual inspection of the juvenile mussels. Juveniles were recorded as alive (active and moving), stressed (no foot movement but cilia beating), or dead (no foot or cilia movement). Toxicity tests depend on an accurate assessment of post-exposure condition and are complicated by the small size (<1 mm) of juvenile mussels. Healthy juveniles are typically active, extruding the foot and gaping (opening) their valves. If immobile or ungaped, their condition is not as apparent. Because juveniles of many species possess transparent valves, with visible internal structure, the reduction or absence of movement by the foot or cilia may be used to assess responses. This requires close, individual inspections, and the effort is time-intensive. A more rapid and equally precise means of assessing postexposure condition of juvenile mussels thus was desirable. Vital staining has been used successfully to distinguish living from dead We thank Mr. Lou Rifici and Ms. Lisa Wolcott for assistance in the laboratory with rearing juvenile mussels and vital staining procedures. This research was supported by a grant from the American Electric Power Company through the American Electric Power Service Corporation, Columbus, Ohio 43216, U.S.A. 2 Address: Department of Biological Sciences, Arkansas State University, State University, Arkansas 72467, U.S.A. 3 Address: U.S. Fish and Wildlife Service, Virginia Cooperative Fish and Wildlife Research Unit, Department of Fisheries and Wildlife Sciences, Virginia Polytechnic Institute and State University, Blacksburg, Virginia 24061, U.S.A. TRANS. AM. MICROSC. SOC., 112(1): 78-80. 1993. ? Copyright, 1993, by the American Microscopical Society, Inc. This content downloaded from 157.55.39.220 on Fri, 02 Sep 2016 04:36:20 UTC All use subject to http://about.jstor.org/terms VOL. 112, NO. 1, JANUARY 1993 invertebrates. Dressel et al. (1972) used vital staining to sort copepods, and Crippen & Perrier (1974) used neutral red to determine mortality among marine plankters. Platter-Rieger & Frank (1987) successfully used neutral red to assess post-exposure effects of tributyltin on mussel larvae (Mytilus edulis). They defined three levels of staining: darkly stained (healthy), lightly stained (stressed and inactive), or not stained (dead). They found increasing percentages of lightly stained larvae in treatments with higher toxicant concentrations and assumed that staining intensity was related to the level of stress. The purpose of our investigation was to evaluate the effectiveness of vital staining with neutral red in determining post-exposure survival of juvenile freshwater mussels. Copper was chosen as the toxicant because it is a known molluscicide, highly toxic to invertebrates, and a common pollutant in riverine systems (U.S.E.P.A., 1985; Van Hassel & Gaulke, 1986). MATERIALS AND METHODS Juveniles of Villosa iris (I. Lea, 1829) and Anodonta grandis Say, 1829 were obtained following metamorphosis of glochidia encysted upon largemouth bass, Micropterus salmoides (Lacepede, 1802). We conducted 24-h, static exposures at eight concentrations ranging from approximately 0 to 200 tg Cu/L. Absolute metal concentration was determined by inductively coupled, argon-plasmaemission spectroscopy. We used two replicates of each toxicant concentration for V. iris and three for A. grandis, with 10 juveniles per replicate. Test containers were held in an incubator at 20?C; after exposure, juvenile response was determined by visual inspection and vital staining. Prior to vital staining, we examined juveniles at 12-50 x magnification with a stereomicroscope. Three classes of response were established: (1) gaped and alive, (2) gaped and dead, or (3) ungaped. Dead juveniles were characterized by their rigid, immobile foot and the absence of beating cilia. We stained juveniles after the initial inspection by the technique of Crippen & Perrier (1974) using a 1-h exposure to a 1:100,000 concentration of neutral red in water. Stained juveniles were stored overnight in a refrigerator at approximately 4?C prior to examination. The degree of staining was assessed using a stereomicroscope at 12-20 x magnification. We defined three levels of staining: (1) brightly stained, (2) lightly or partially stained, and (3) unstained. 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引用次数: 11

Abstract

The effectiveness of vital staining for assessing lethal and sublethal responses of juvenile mussels was examined. Neutral red was used to quantify survival of juvenile Villosa iris and Anodonta grandis after exposures to aqueous copper in 24-hour static bioassays. Live juveniles readily incorporated the stain, but dead individuals did not. Variation in stain intensity was associated with behavioral responses, permitting diagnosis of alive, dead, and sublethal responses of juvenile V. iris. The amber coloration of juvenile A. grandis prevented detection of variations in stain intensity, thus allowing only livingversus-dead determinations to be made. Responding to precipitous declines in populations of freshwater mussels (Unionidae), several workers recently conducted laboratory tests to measure sensitivity of juvenile stages to various pollutants (Johnson et al., 1990; Keller & Zam, 1991; Lasee, 1991). Both Johnson et al. (1990) and Keller & Zam (1991) determined post-exposure mortality from observations of internal anatomy, but did not detail any sublethal effects of the exposures. By contrast, Lasee (1991) assessed both post-exposure mortality and sublethal responses by individual inspection of the juvenile mussels. Juveniles were recorded as alive (active and moving), stressed (no foot movement but cilia beating), or dead (no foot or cilia movement). Toxicity tests depend on an accurate assessment of post-exposure condition and are complicated by the small size (<1 mm) of juvenile mussels. Healthy juveniles are typically active, extruding the foot and gaping (opening) their valves. If immobile or ungaped, their condition is not as apparent. Because juveniles of many species possess transparent valves, with visible internal structure, the reduction or absence of movement by the foot or cilia may be used to assess responses. This requires close, individual inspections, and the effort is time-intensive. A more rapid and equally precise means of assessing postexposure condition of juvenile mussels thus was desirable. Vital staining has been used successfully to distinguish living from dead We thank Mr. Lou Rifici and Ms. Lisa Wolcott for assistance in the laboratory with rearing juvenile mussels and vital staining procedures. This research was supported by a grant from the American Electric Power Company through the American Electric Power Service Corporation, Columbus, Ohio 43216, U.S.A. 2 Address: Department of Biological Sciences, Arkansas State University, State University, Arkansas 72467, U.S.A. 3 Address: U.S. Fish and Wildlife Service, Virginia Cooperative Fish and Wildlife Research Unit, Department of Fisheries and Wildlife Sciences, Virginia Polytechnic Institute and State University, Blacksburg, Virginia 24061, U.S.A. TRANS. AM. MICROSC. SOC., 112(1): 78-80. 1993. ? Copyright, 1993, by the American Microscopical Society, Inc. This content downloaded from 157.55.39.220 on Fri, 02 Sep 2016 04:36:20 UTC All use subject to http://about.jstor.org/terms VOL. 112, NO. 1, JANUARY 1993 invertebrates. Dressel et al. (1972) used vital staining to sort copepods, and Crippen & Perrier (1974) used neutral red to determine mortality among marine plankters. Platter-Rieger & Frank (1987) successfully used neutral red to assess post-exposure effects of tributyltin on mussel larvae (Mytilus edulis). They defined three levels of staining: darkly stained (healthy), lightly stained (stressed and inactive), or not stained (dead). They found increasing percentages of lightly stained larvae in treatments with higher toxicant concentrations and assumed that staining intensity was related to the level of stress. The purpose of our investigation was to evaluate the effectiveness of vital staining with neutral red in determining post-exposure survival of juvenile freshwater mussels. Copper was chosen as the toxicant because it is a known molluscicide, highly toxic to invertebrates, and a common pollutant in riverine systems (U.S.E.P.A., 1985; Van Hassel & Gaulke, 1986). MATERIALS AND METHODS Juveniles of Villosa iris (I. Lea, 1829) and Anodonta grandis Say, 1829 were obtained following metamorphosis of glochidia encysted upon largemouth bass, Micropterus salmoides (Lacepede, 1802). We conducted 24-h, static exposures at eight concentrations ranging from approximately 0 to 200 tg Cu/L. Absolute metal concentration was determined by inductively coupled, argon-plasmaemission spectroscopy. We used two replicates of each toxicant concentration for V. iris and three for A. grandis, with 10 juveniles per replicate. Test containers were held in an incubator at 20?C; after exposure, juvenile response was determined by visual inspection and vital staining. Prior to vital staining, we examined juveniles at 12-50 x magnification with a stereomicroscope. Three classes of response were established: (1) gaped and alive, (2) gaped and dead, or (3) ungaped. Dead juveniles were characterized by their rigid, immobile foot and the absence of beating cilia. We stained juveniles after the initial inspection by the technique of Crippen & Perrier (1974) using a 1-h exposure to a 1:100,000 concentration of neutral red in water. Stained juveniles were stored overnight in a refrigerator at approximately 4?C prior to examination. The degree of staining was assessed using a stereomicroscope at 12-20 x magnification. We defined three levels of staining: (1) brightly stained, (2) lightly or partially stained, and (3) unstained. Classes 2 and 3 were combined to yield a total number affected both by visual inspection and vital
在生物测定中使用中性红评价淡水贻贝幼鱼的存活率
研究了生命染色法对贻贝幼鱼致死性和亚致死性反应的评价效果。在24小时静态生物测定中,中性红色用于定量暴露于水铜后的幼鱼虹膜和大菱鲆的存活率。活的幼鱼很容易吸收这种污渍,而死的幼鱼则不然。染色强度的变化与行为反应有关,可以诊断幼年虹膜弧菌的活、死和亚致死反应。幼鼠的琥珀色阻止了染色强度变化的检测,因此只允许进行活与死的测定。为了应对淡水贻贝(Unionidae)数量的急剧下降,一些工作人员最近进行了实验室测试,以测量幼年期对各种污染物的敏感性(Johnson等人,1990年;Keller & Zam, 1991;Lasee, 1991)。Johnson et .(1990)和Keller & Zam(1991)都通过观察内部解剖学确定了暴露后的死亡率,但没有详细说明暴露的任何亚致死效应。相比之下,Lasee(1991)通过单独检查幼年贻贝来评估接触后死亡率和亚致死反应。幼崽被记录为活着(活跃和移动),应激(没有脚运动但纤毛跳动)或死亡(没有脚或纤毛运动)。毒性测试依赖于对暴露后条件的准确评估,并且由于幼年贻贝的体积小(<1毫米)而变得复杂。健康的幼鱼通常是活跃的,挤压足部并打开它们的阀门。如果不能动或没有开口,它们的情况就不那么明显了。由于许多物种的幼体具有透明的阀门,具有可见的内部结构,因此足或纤毛的减少或不运动可用于评估反应。这需要密切的、个别的检查,而且需要大量的时间。因此,需要一种更快速和同样精确的方法来评估幼年贻贝的暴露后状况。生命染色法已经成功地用于区分生者和死者我们感谢卢·里菲奇先生和丽莎·沃尔科特女士在实验室里帮助培养贻贝幼体和生命染色程序。本研究由美国电力公司通过美国电力服务公司(Columbus, Ohio 43216, usa)资助。2地址:阿肯色州立大学生物科学系,阿肯色州立大学,阿肯色州72467,usa。美国鱼类和野生动物管理局,弗吉尼亚渔业和野生动物合作研究单位,弗吉尼亚理工学院和州立大学渔业和野生动物科学系,布莱克斯堡,弗吉尼亚州24061,美国点。MICROSC。SOC。生物医学工程学报,12(1):78-80。1993. ? 版权所有,1993年,美国显微学会,Inc。此内容下载于157.55.39.220星期五,2016年9月2日04:36:20 UTC所有使用须遵守http://about.jstor.org/terms卷112,NO。1993年1月1日无脊椎动物。Dressel等人(1972)使用生命染色法对桡足类进行分类,Crippen & Perrier(1974)使用中性红色来确定海洋浮游生物的死亡率。Platter-Rieger & Frank(1987)成功地使用中性红色评估了三丁基锡对贻贝幼虫(Mytilus edulis)的暴露后影响。他们定义了三种染色水平:深色染色(健康),轻度染色(压力和不活跃),或未染色(死亡)。他们发现,在毒物浓度较高的环境中,轻度染色的幼虫比例增加,并假设染色强度与压力水平有关。本研究的目的是评价中性红活体染色法测定淡水贻贝幼鱼暴露后存活率的有效性。铜之所以被选为有毒物质,是因为它是一种已知的杀软体动物剂,对无脊椎动物有剧毒,也是河流系统中的一种常见污染物(美国环保局,1985;Van Hassel & Gaulke, 1986)。材料与方法对大嘴鲈鱼,Micropterus salmoides (Lacepede, 1802)上的舌虫进行蜕变后,获得大嘴鲈鱼(Villosa iris, 1829)和大嘴鲈鱼(Anodonta grandis Say, 1829)幼鱼。我们在大约0至200 tg Cu/L的8种浓度下进行了24小时的静态暴露。用电感耦合氩等离子体发射光谱法测定金属绝对浓度。我们对鸢尾花和大花田鼠分别使用2个和3个不同浓度的毒理学重复,每个重复10只幼体。测试容器放在20℃的培养箱中;暴露后,通过目视检查和活体染色来确定幼鱼的反应。在活体染色之前,我们用体视显微镜在12-50倍放大镜下检查幼鱼。建立了三类反应:(1)张开和活着,(2)张开和死亡,或(3)没有张开。 死去的幼龙的特点是脚僵硬,不能动,没有跳动的纤毛。在初步检查后,我们使用Crippen & Perrier(1974)的技术对幼鱼进行染色,将其暴露在1:10万浓度的水中1小时。染色的幼鱼在大约4?C考查前。使用12-20倍放大的体视显微镜评估染色程度。我们定义了三个级别的染色:(1)明亮染色,(2)轻度或部分染色,(3)未染色。将第2类和第3类结合起来,得到受目视检查和重要因素影响的总数
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