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    Characterization of tissue specific cholinesterases in native fishes, Rasbora daniconius and Dawkinsia singhala: their sensitivity to the heavy metal, copper
    (Research Symposium on Pure and Applied Sciences, 2018 Faculty of Science, University of Kelaniya, Sri Lanka, 2018) Premarathna, K.I.R.; Pathiratne, A.
    Aquatic pollutants could pose health hazards to humans and wildlife. Cholinesterases (ChEs) have been recognized as biomarkers of exposure to a range of aquatic pollutants including organophosphate and carbamate pesticides and heavy metals. This study examined tissue specific characteristics of ChE activities in the brain, muscle and gills of two native freshwater fish species Rasbora daniconius (Sinhala; Dandiya) and Dawkinsia singhala (Sinhala; Dankola pethiya) in Sri Lanka with the aim of using ChEs of these fishes as potential biomarkers for biomonitoring aquatic pollution. The main objectives were to characterize the biochemical properties of ChEs in brain, muscle and gill tissues of R . daniconius and D . singhala, using two specific substrates and three selective inhibitors and to measure in vitro sensitivity of the ChE activities to exposure to heavy metal, Copper. Cholinesterase activity measurements with two substrates (acetyl thiocholine iodide (ATCI) and butyryl thiocholine iodide (BTCI)) showed the presence of two different cholinesterases in both fishes namely Acetyl cholinesterase and Butyryl cholinesterase. With the estimated kinetic parameters of the enzymes (Km, Vmax and Vmax/Km) for both substrates, highest catalytic efficiency was obtained for brain tissues with the two substrates for both fish species. Of the two substrates tested, the catalytic efficiencies were generally higher when ATCI was used as the substrate in crude enzyme extracts (Vmax/Km for brain ChE: 3.95 for R . daniconius; 2.04 for D . singhala). Using enzyme inhibition pattern in response to three selective inhibitors (Eserine, BW254C51 and Iso-OMPA), it was found that the brain and muscle tissues of both fishes contained mainly Acetylcholinesterase enzyme whereas the gill tissues are the sources of both Acetylcholinesterase and Butyryl cholinesterase enzymes. The results of the present study clearly proved that ChE activities of both species have a concentration depended inhibition pattern in response to in vitro exposure of Cu2+ at least in the tested concentration range (0.05-2 mM). ChEs in the gill tissues in both fish species are more sensitive to the Cu2+ than the ChEs in brain and muscle tissues. Overall results indicate that cholinesterase enzymes of R . daniconius and D . singhala may be used as biomarkers for neurotoxic contaminants such as the heavy metal, copper. Crude extracts of the ChE enzymes in brain, muscle and gill tissues of the two fish species can be used in routine procedures for screening anticholinesterase contaminations in water resources.
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    Toxicity of malathion to nile tilapia, Oreochromis niloticus and modulation by other environmental contaminants
    (Aquatic Toxicology, 1998) Pathiratne, A.; George, S.G.
    Deliberate or accidental contamination of ponds by widely utilised organophophorous (OP) insecticides such as malathion is a potential problem for aquaculture in tropical countries. The aim of the study was to investigate potential synergistic or protective effects of common environmental pollutants on malathion toxicity in the Nile tilapia (Oreochromis niloticus) and by correlation of acute toxicity (LC50) studies with biochemical parameters, identify potential enzyme systems involved in malathion toxicity. Tilapia were very sensitive to malathion (96h LC50 2ppm) and in vitro data indicated that malaoxon, formed by oxidation of malathion, was the effective toxicant. Exposure of fish to an environmentally relevant dose of the insecticide synergist and CYP inhibitor, piperonyl butoxide (PBO) markedly reduced both the sublethal and the acute toxicity of malathion by 2-fold. Correlation of toxicity data with inducer effects and biochemical analyses failed to provide any evidence for CYP1-, CYP2B- or CYP3A-mediated malathion activation or detoxication in this species, thus the effect of PBO could not be attributed to inhibition of these enzymes. Whilst interspecies comparisons implicate hepatic θ class GST and non-specific carboxylesterase in malathion detoxication there was no evidence for alterations in malathion toxicity to tilapia by inducers of these enzymes. Treatment of fish with concentrations of a prototypical polyaromatic hydrocarbon, or cadmium, exceeding those producing effects in field situations, did not alter malathion toxicity indicating a lack of interaction of other common classes of environmental pollutants with OP toxicity