do A Kehrig Helena, Seixas Tércia G, Palermo Elisabete A, Baêta Aida P, Castelo-Branco Christina W, Malm Olaf, Moreira Isabel
Instituto de Biofísica Carlos Chagas Filho, Universidade Federal do Rio de Janeiro, 21941-902, Rio de Janeiro, Brazil.
Environ Sci Pollut Res Int. 2009 Jan;16(1):10-24. doi: 10.1007/s11356-008-0038-8. Epub 2008 Aug 27.
BACKGROUND, AIM, AND SCOPE: Selenium (Se) has been shown to reduce mercury (Hg) bioavailability and trophic transfer in aquatic ecosystems. The study of methylmercury (MeHg) and Se bioaccumulation by plankton is therefore of great significance in order to obtain a better understanding of the estuarine processes concerning Hg and Se accumulation and biomagnification throughout the food web. In the western South Atlantic, few studies have documented trace element and MeHg in fish tissues. No previous study about trace elements and MeHg in plankton has been conducted concerning tropical marine food webs. Se, Hg, and MeHg were determined in two size classes of plankton, microplankton (70-290 microm) and mesoplankton (>or=290 microm), and also in muscle tissues and livers of four fish species of different trophic levels (Mugil liza, a planktivorous fish; Bagre spp., an omnivorous fish; Micropogonias furnieri, a benthic carnivorous fish; and Centropomus undecimalis, a pelagic carnivorous fish) from a polluted estuary in the Brazilian Southeast coast, Guanabara Bay. Biological and ecological factors such as body length, feeding habits, and trophic transfer were considered in order to outline the relationships between these two elements. The differences in trace element levels among the different trophic levels were investigated.
Fish were collected from July 2004 to August 2005 at Guanabara Bay. Plankton was collected from six locations within the bay in August 2005. Total mercury (THg) was determined by cold vapor atomic absorption spectrometry (CV-AAS) with sodium borohydride as a reducing agent. MeHg analysis was conducted by digesting samples with an alcoholic potassium hydroxide solution followed by dithizone-toluene extraction. MeHg was then identified and quantified in the toluene layer by gas chromatography with an electron capture detector (GC-ECD). Se was determined by AAS using graphite tube with Pin platform and Zeeman background correction.
Total mercury, MeHg, and Se increased with plankton size class. THg and Se values were below 2.0 and 4.8 microg g(-1) dry wt in microplankton and mesoplankton, respectively. A large excess of molar concentrations of Se in relation to THg was observed in both plankton size class and both fish tissues. Plankton presented the lowest concentrations of this element. In fish, the liver showed the highest THg and Se concentrations. THg and Se in muscle were higher in Centropomus undecimalis (3.4 and 25.5 nmol g(-1)) than in Micropogonias furnieri (2.9 and 15.3 nmol g(-1)), Bagre spp (1.3 and 3.4 nmol g(-1)) and Mugil liza (0.3 and 5.1 nmol g(-1)), respectively. The trophic transfer of THg and Se was observed between trophic levels from prey (considering microplankton and mesoplankton) to top predator (fish). The top predators in this ecosystem, Centropomus undecimalis and Micropogonias furnieri, presented similar MeHg concentrations in muscles and liver. Microplankton presented lower ratios of methylmercury to total mercury concentration (MeHg/THg) (34%) than those found in mesoplankton (69%) and in the muscle of planktivorous fish, Mugil liza (56%). The other fish species presented similar MeHg/THg in muscle tissue (of around 100%). M. liza showed lower MeHg/THg in the liver than C. undecimalis (35%), M. furnieri (31%) and Bagre spp. (22%). Significant positive linear relationships were observed between the molar concentrations of THg and Se in the muscle tissue of M. furnieri and M. liza. These fish species also showed significant inverse linear relationships between hepatic MeHg and Se, suggesting a strong antagonistic effect of Se on MeHg assimilation and accumulation.
Differences found among the concentrations THg, MeHg, and Se in microplankton, mesozooplankton, and fishes were probably related to the preferred prey and bioavailability of these elements in the marine environment. The increasing concentration of MeHg and Se at successively higher trophic levels of the food web of Guanabara Bay corresponds to a transfer between trophic levels from the lower trophic level to the top-level predator, suggesting that MeHg and Se were biomagnified throughout the food web. Hg and Se were positively correlated with the fish standard length, suggesting that larger and older fish bioaccumulated more of these trace elements. THg, MeHg, and Se were a function of the plankton size.
There is a need to assess the role of selenium in mercury accumulation in tropical ecosystems. Without further studies of the speciation of selenium in livers of fishes from this region, the precise role of this element, if any, cannot be verified in positively affecting mercury accumulation. Further studies of this element in the study of marine species should include liver samples containing relatively high concentrations of mercury. A basin-wide survey of selenium in fishes is also recommended.
背景、目的和范围:硒(Se)已被证明可降低水生生态系统中汞(Hg)的生物有效性和营养转移。因此,研究浮游生物对甲基汞(MeHg)和硒的生物累积,对于更好地理解河口地区汞和硒在整个食物网中的累积及生物放大过程具有重要意义。在南大西洋西部,很少有研究记录鱼类组织中的微量元素和甲基汞。此前尚未有关于热带海洋食物网中浮游生物微量元素和甲基汞的研究。对巴西东南海岸瓜纳巴拉湾一个受污染河口的两种浮游生物大小类群(微型浮游生物(70 - 290微米)和中型浮游生物(≥290微米))以及四种不同营养级鱼类(食浮游生物的丽脂鲤;杂食性的袋须鲶属鱼类;底栖肉食性的福氏美塘鳢;中上层肉食性的十一带石斑鱼)的肌肉组织和肝脏中的硒、汞和甲基汞进行了测定。考虑了体长、摄食习惯和营养转移等生物学和生态学因素,以勾勒这两种元素之间的关系。研究了不同营养级之间微量元素水平的差异。
2004年7月至2005年8月在瓜纳巴拉湾采集鱼类。2005年8月在该湾内六个地点采集浮游生物。采用硼氢化钠作为还原剂,通过冷原子吸收光谱法(CV - AAS)测定总汞(THg)。用氢氧化钾乙醇溶液消化样品,然后用双硫腙 - 甲苯萃取进行甲基汞分析。然后通过带有电子捕获检测器(GC - ECD)的气相色谱法在甲苯层中鉴定和定量甲基汞。使用带Pin平台的石墨管和塞曼背景校正的原子吸收光谱法测定硒。
总汞、甲基汞和硒随浮游生物大小类群增加。微型浮游生物和中型浮游生物中总汞和硒的值分别低于2.0和4.8微克/克干重。在浮游生物大小类群和两种鱼类组织中均观察到硒的摩尔浓度相对于总汞有大量过剩。浮游生物中该元素的浓度最低。在鱼类中,肝脏中总汞和硒的浓度最高。中上层肉食性的十一带石斑鱼肌肉中的总汞和硒(3.4和25.5纳摩尔/克)高于底栖肉食性的福氏美塘鳢(2.9和15.3纳摩尔/克)、袋须鲶属鱼类(1.3和3.4纳摩尔/克)以及食浮游生物的丽脂鲤(0.3和5.1纳摩尔/克)。观察到总汞和硒在从猎物(考虑微型浮游生物和中型浮游生物)到顶级捕食者(鱼类)的营养级之间的营养转移。该生态系统中的顶级捕食者,十一带石斑鱼和福氏美塘鳢,肌肉和肝脏中的甲基汞浓度相似。微型浮游生物中甲基汞与总汞浓度的比值(MeHg/THg)(34%)低于中型浮游生物(69%)和食浮游生物的丽脂鲤肌肉中的比值(56%)。其他鱼类在肌肉组织中的MeHg/THg相似(约100%)。丽脂鲤肝脏中的MeHg/THg低于十一带石斑鱼(35%)、福氏美塘鳢(31%)和袋须鲶属鱼类(22%)。在福氏美塘鳢和丽脂鲤的肌肉组织中,总汞和硒的摩尔浓度之间观察到显著的正线性关系。这些鱼类还显示肝脏中甲基汞与硒之间存在显著的负线性关系,表明硒对甲基汞的同化和累积有强烈的拮抗作用。
微型浮游生物、中型浮游动物和鱼类中总汞、甲基汞和硒浓度的差异可能与这些元素在海洋环境中的首选猎物和生物有效性有关。瓜纳巴拉湾食物网中营养级依次升高时甲基汞和硒浓度的增加对应于从低营养级到顶级捕食者的营养级转移,表明甲基汞和硒在整个食物网中发生了生物放大。汞和硒与鱼类标准长度呈正相关,表明体型更大、年龄更大的鱼生物累积更多这些微量元素。总汞、甲基汞和硒是浮游生物大小的函数。
有必要评估硒在热带生态系统汞累积中的作用。如果没有对该地区鱼类肝脏中硒的形态进行进一步研究,就无法验证该元素在积极影响汞累积方面的确切作用(如果有的话)。在海洋物种研究中对该元素的进一步研究应包括含有相对高浓度汞的肝脏样本。还建议对鱼类中的硒进行全流域调查。
