Investigating the mechanisms of Ni uptake and sub-lethal toxicity in the Atlantic killifish Fundulus heteroclitus in relation to salinity

Investigating the mechanisms of Ni uptake and sub-lethal toxicity in the Atlantic killifish Fundulus heteroclitus in relation to salinity

The Atlantic killifish (Fundulus heteroclitus) is a resilient estuarine species that may be subjected to anthropogenic contamination of its natural habitat, by toxicants such as nickel (Ni). We investigated Ni accumulation and potential modes of Ni toxicity, in killifish, as a function of environmen...

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Veröffentlicht in:Environmental pollution (1987) 2016-04, Vol.211, p.370-381
Hauptverfasser: Blewett, Tamzin A., Ransberry, Victoria E., McClelland, Grant B., Wood, Chris M.
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Sprache:eng
Schlagworte:
Animals
Catalase
Contamination
Exposure
Fish
Fresh Water
Freshwater
Fundulidae - physiology
Fundulus heteroclitus
Gills - metabolism
Invertebrate
Marine
Metal
Nickel
Nickel - metabolism
Nickel - toxicity
Osmoregulation
Oxidative Stress
Salinity
Seawater
Stresses
Toxicity
Uptakes
Water Pollutants, Chemical - metabolism
Water Pollutants, Chemical - toxicity
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creator Blewett, Tamzin A.
Ransberry, Victoria E.
McClelland, Grant B.
Wood, Chris M.
description The Atlantic killifish (Fundulus heteroclitus) is a resilient estuarine species that may be subjected to anthropogenic contamination of its natural habitat, by toxicants such as nickel (Ni). We investigated Ni accumulation and potential modes of Ni toxicity, in killifish, as a function of environmental salinity. Killifish were acclimated to 4 different salinities [0 freshwater (FW), 10, 30 and 100% seawater (SW)] and exposed to 5 mg/L of Ni for 96 h. Tissue Ni accumulation, whole body ions, critical swim speed and oxidative stress parameters were examined. SW was protective against Ni accumulation in the gills and kidney. Addition of Mg and Ca to FW protected against gill Ni accumulation, suggesting competition with Ni for uptake. Concentration-dependent Ni accumulation in the gill exhibited saturable relationships in both FW- and SW-acclimated fish. However SW fish displayed a lower Bmax (i.e. lower number of Ni binding sites) and a lower Km (i.e. higher affinity for Ni binding). No effect of Ni exposure was observed on critical swim speed (Ucrit) or maximum rate of oxygen consumption (MO2max). Markers of oxidative stress showed either no effect (e.g. protein carbonyl formation), or variable effects that appeared to depend more on salinity than on Ni exposure. These data indicate that the killifish is very tolerant to Ni toxicity, a characteristic that may facilitate the use of this species as a site-specific biomonitor of contaminated estuaries. •SW was protective against Ni accumulation in the gills and kidney only.•Mg and Ca in FW protected against Ni accumulation, suggesting competition with Ni.•No effect of Ni exposure was observed on critical swim speed or oxygen consumption. Marine vertebrates do not have the same response to Ni toxicity as freshwater vertebrates and as such. Euryhaline killifish may be very useful as site-specific biomonitors.
doi_str_mv 10.1016/j.envpol.2016.01.002
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Markers of oxidative stress showed either no effect (e.g. protein carbonyl formation), or variable effects that appeared to depend more on salinity than on Ni exposure. These data indicate that the killifish is very tolerant to Ni toxicity, a characteristic that may facilitate the use of this species as a site-specific biomonitor of contaminated estuaries. •SW was protective against Ni accumulation in the gills and kidney only.•Mg and Ca in FW protected against Ni accumulation, suggesting competition with Ni.•No effect of Ni exposure was observed on critical swim speed or oxygen consumption. Marine vertebrates do not have the same response to Ni toxicity as freshwater vertebrates and as such. 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Markers of oxidative stress showed either no effect (e.g. protein carbonyl formation), or variable effects that appeared to depend more on salinity than on Ni exposure. These data indicate that the killifish is very tolerant to Ni toxicity, a characteristic that may facilitate the use of this species as a site-specific biomonitor of contaminated estuaries. •SW was protective against Ni accumulation in the gills and kidney only.•Mg and Ca in FW protected against Ni accumulation, suggesting competition with Ni.•No effect of Ni exposure was observed on critical swim speed or oxygen consumption. Marine vertebrates do not have the same response to Ni toxicity as freshwater vertebrates and as such. 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We investigated Ni accumulation and potential modes of Ni toxicity, in killifish, as a function of environmental salinity. Killifish were acclimated to 4 different salinities [0 freshwater (FW), 10, 30 and 100% seawater (SW)] and exposed to 5 mg/L of Ni for 96 h. Tissue Ni accumulation, whole body ions, critical swim speed and oxidative stress parameters were examined. SW was protective against Ni accumulation in the gills and kidney. Addition of Mg and Ca to FW protected against gill Ni accumulation, suggesting competition with Ni for uptake. Concentration-dependent Ni accumulation in the gill exhibited saturable relationships in both FW- and SW-acclimated fish. However SW fish displayed a lower Bmax (i.e. lower number of Ni binding sites) and a lower Km (i.e. higher affinity for Ni binding). No effect of Ni exposure was observed on critical swim speed (Ucrit) or maximum rate of oxygen consumption (MO2max). Markers of oxidative stress showed either no effect (e.g. protein carbonyl formation), or variable effects that appeared to depend more on salinity than on Ni exposure. These data indicate that the killifish is very tolerant to Ni toxicity, a characteristic that may facilitate the use of this species as a site-specific biomonitor of contaminated estuaries. •SW was protective against Ni accumulation in the gills and kidney only.•Mg and Ca in FW protected against Ni accumulation, suggesting competition with Ni.•No effect of Ni exposure was observed on critical swim speed or oxygen consumption. Marine vertebrates do not have the same response to Ni toxicity as freshwater vertebrates and as such. Euryhaline killifish may be very useful as site-specific biomonitors.</abstract><cop>England</cop><pub>Elsevier Ltd</pub><pmid>26796747</pmid><doi>10.1016/j.envpol.2016.01.002</doi><tpages>12</tpages></addata></record>
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identifier ISSN: 0269-7491
ispartof Environmental pollution (1987), 2016-04, Vol.211, p.370-381
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source MEDLINE; Access via ScienceDirect (Elsevier)
subjects Animals
Catalase
Contamination
Exposure
Fish
Fresh Water
Freshwater
Fundulidae - physiology
Fundulus heteroclitus
Gills - metabolism
Invertebrate
Marine
Metal
Nickel
Nickel - metabolism
Nickel - toxicity
Osmoregulation
Oxidative Stress
Salinity
Seawater
Stresses
Toxicity
Uptakes
Water Pollutants, Chemical - metabolism
Water Pollutants, Chemical - toxicity
title Investigating the mechanisms of Ni uptake and sub-lethal toxicity in the Atlantic killifish Fundulus heteroclitus in relation to salinity
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