Oxygen flux as an indicator of physiological stress in aquatic organisms: a real-time biomonitoring system of water quality

The detection of harmful chemicals and biological agents in real time is a critical need for protecting water quality. We studied the real-time effects of five environmental contaminants with differing modes of action (atrazine, pentachlorophenol, cadmium chloride, malathion, and potassium cyanide) on respiratory oxygen consumption in 2-day post-fertilization fathead minnow (Pimephales promelas) eggs. Our objective was to assess the sensitivity of fathead minnow eggs using the self-referencing micro-optrode technique to detect instantaneous changes in oxygen consumption after brief exposures to low concentrations of contaminants. Oxygen consumption data indicated that the technique is indeed sensitive enough to reliably detect physiological alterations induced by all contaminants. After 2 h of exposure, we identified significant increases in oxygen consumption upon exposure to pentachlorophenol (100 and 1000 μg/L), cadmium chloride (0.0002 and 0.002 μg/L), and atrazine (150 μg/L). In contrast, we observed a significant decrease in oxygen flux after exposures to potassium cyanide (5.2, 22, and 44 μg/L) and atrazine (1500 μg/L). No effects were detected after exposures to malathion (200 and 340 μg/L). We have also tested the sensitivity of Daphnia magna embryos as another animal model for real-time environmental biomonitoring. Our results are so far encouraging and support further development of this technology as a physiologically coupled biomonitoring tool for the detection of environmental toxicants.

[1]  A. Heath,et al.  Cardiac, ventilatory and metabolic responses of two ecologically dissimilar species of fish to waterborne cyanide , 2005, Fish Physiology and Biochemistry.

[2]  K. Stolze,et al.  Effect of xenobiotics on the respiratory activity of rat heart mitochondria and the concomitant formation of superoxide radicals , 1994 .

[3]  Dick de Zwart,et al.  The valve movement response of mussels: a tool in biological monitoring , 1989, Hydrobiologia.

[4]  W H van der Schalie,et al.  Long-Term Operation of an Automated Fish Biomonitoring System for Continuous Effluent Acute Toxicity Surveillance , 2001, Bulletin of environmental contamination and toxicology.

[5]  Raoul Kopelman,et al.  Noninvasive approaches to measuring respiratory patterns using a PtTFPP based phase-lifetime self-referencing oxygen optrode , 2006, SPIE Optics East.

[6]  S. Duke,et al.  Overview of herbicide mechanisms of action. , 1990, Environmental health perspectives.

[7]  G. Leduc Cyanides in water: toxicological significance , 1984 .

[8]  D Marshall Porterfield,et al.  Oxygen flux as an indicator of physiological stress in fathead minnow (Pimephales promelas) embryos: a real-time biomonitoring system of water quality. , 2008, Environmental science & technology.

[9]  E. C. Weinbach The effect of pentachlorophenol on oxidative phosphorylation. , 1954, The Journal of biological chemistry.

[10]  Gerald J. Niemi,et al.  Use of respiratory‐cardiovascular responses of rainbow trout (Salmo gairdneri) in identifying acute toxicity syndromes in fish: Part 2. malathion, carbaryl, acrolein and benzaldehyde , 1987 .

[11]  Dawson,et al.  Sublethal physiological stress induced by cadmium and mercury in the winter flounder, Pseudopleuronectes americanus , 1975 .

[12]  K. V. Rao,et al.  Effect of malathion exposure on some physical parameters of whole body and on tissue cations of teleost,Tilapia mossambica(Peters) , 1981, Journal of Biosciences.

[13]  A. Boudou,et al.  Comparative Effects of Direct Cadmium Contamination on Gene Expression in Gills, Liver, Skeletal Muscles and Brain of the Zebrafish (Danio rerio) , 2006, Biometals.

[14]  Ingo Klimant,et al.  Fiber‐optic oxygen microsensors, a new tool in aquatic biology , 1995 .

[15]  W. Waller,et al.  Biochemical Responses of Bluegill Sunfish (Lepomis macrochirus, Rafinesque) to Atrazine Induced Oxidative Stress , 2002, Bulletin of environmental contamination and toxicology.

[16]  S. Leonard,et al.  Cadmium inhibits the electron transfer chain and induces reactive oxygen species. , 2004, Free radical biology & medicine.

[17]  Jieun Park,et al.  A novel continuous toxicity test system using a luminously modified freshwater bacterium. , 2004, Biosensors & bioelectronics.

[18]  L. Xiang,et al.  Cytotoxic effects and apoptosis induction of atrazine in a grass carp (Ctenopharyngodon idellus) cell line , 2006, Environmental toxicology.

[19]  L. Fuiman,et al.  Ecological performance of red drum (Sciaenops ocellatus) larvae exposed to environmental levels of the insecticide malathion , 2006, Environmental toxicology and chemistry.

[20]  A. Gül,et al.  Investigation of acute toxicity and the effect of cadmium chloride (CdCl2 . H2O) metal salt on behavior of the guppy (Poecilia reticulata). , 2004, Chemosphere.

[21]  W. H. van der Schalie,et al.  Response characteristics of an aquatic biomonitor used for rapid toxicity detection , 2004, Journal of applied toxicology : JAT.

[22]  J. Cairns Biological monitoring part I—Early warning systems , 1980 .