Effect of neurotoxic compounds on ephyrae of Aurelia aurita jellyfish

Costa, Elisa; Gambardella, Chiara; Piazza, Veronica; Greco, Giuliano; Lavorano, Silvia; Beltrandi, Martina; Bongiovanni, Elisabetta; Gnone, G.; Faimali, Marco; Garaventa, Francesca

doi:10.1007/s10750-015-2284-3

Cited by 27 publications

(23 citation statements)

References 60 publications

(74 reference statements)

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“…Acute and chronic effects of chlorpyrifos on various amphibians as well as aquatic vertebrates and invertebrates have been well reviewed by Corbin et al (2009). Ephyra stage of the Scyphozoan jellyfish Aurelia aurita was recently reported susceptible to dose dependent effect of chlorpyrifos (Costa et al 2015). All these together indicate apprehension about the potential hazards of chlorpyrifos to aquatic life.…”

Section: Toxicity On Aquatic Systemmentioning

confidence: 97%

Chlorpyrifos: pollution and remediation

2015

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The widespread use of pesticides in modern agriculture is of increasing concern due to environmental contamination and subsequent biodiversity loss. Chlorpyrifos is a toxic organophosphate pesticide. Repeated applications of chlorpyrifos modify the soil microbial community structure and pose potential health risks to the other nontargets. Chlorpyrifos has been reported as the second most commonly detected pesticide in food and water. Extensive use of chlorpyrifos in agriculture and persistence in the environment have raised public concern and demand for safe technologies to overcome the pollution and toxicity problems. Here, we review pollution and toxicity issues associated with chlorpyrifos use and discuss strategies to solve pesticide contamination. Chlorpyrifos, previously shown to be resistant to enhanced degradation, has now been proved to undergo enhanced microbe-mediated decay. Here, special emphasis is given to degradation methods such as ozonation, Fenton treatment, photodegradation, and advanced oxidation processes along with microbial degradation. Finally, we focus on degradation process at enzyme and molecular levels which will enable us to elucidate the exact degradative pathway involved in biodegradation.

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Section: Toxicity On Aquatic Systemmentioning

confidence: 97%

Chlorpyrifos: pollution and remediation

2015

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“…Such an effect, in which sublethal exposures to stress cause an improved capacity to withstand higher doses or result in higher growth or reproduction at subsequent time intervals (a phenomenon known as hormesis; Forbes ; Gems & Partridge ), is known to occur in cnidarians (Stebbing ; Lucas & Horton ; Costa et al. ) and in hydra in particular (Stebbing & Pomroy ; Schaible et al. ; de Jong et al.…”

mentioning

confidence: 99%

“…(4) Does a previous exposure to low-level UV radiation influence subsequent responses? Such an effect, in which sublethal exposures to stress cause an improved capacity to withstand higher doses or result in higher growth or reproduction at subsequent time intervals (a phenomenon known as hormesis ;Forbes 2000;Gems & Partridge 2008), is known to occur in cnidarians (Stebbing 1981;Lucas & Horton 2014;Costa et al 2015) and in hydra in particular (Stebbing & Pomroy 1978;Schaible et al 2011;de Jong et al 2016; but see T€ ok€ olyi et al 2014). (5) Is there variation between individuals in hormetic response, and does it depend on age, size, or reproductive investment (budding rate) of polyps?…”

mentioning

confidence: 99%

Life history traits and previous exposure predict resistance to UV irradiation in the freshwater cnidarian Hydra oligactis

Tökölyi

Kozma

Sebestyén

et al. 2017

Invertebrate Biology

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Abiotic stress is an important source of mortality for cnidarians and is likely to be a major factor shaping their life histories. In freshwater hydra, the ability to withstand exogenous sources of stress varies between species and populations, but little is known about the factors responsible for this variation. Here, we investigated resistance to UV irradiation in Hydra oligactis, a common temperate freshwater cnidarian. We collected polyps from 12 populations and propagated these asexually under standard conditions in the laboratory to obtain 69 laboratory clonal lines with a total of 324 polyps of different age. We measured the size of polyps and recorded their budding rate. In addition, a subset of animals was exposed to hormetic treatment, where experimental animals received a short, sublethal irradiation 2 d before testing their resistance to a higher dose. We investigated how life history traits (age, size, and budding rate), hormetic treatment, and the interaction between life history traits and hormetic treatment relate to the ability of hydra polyps to tolerate high doses of UV irradiation. In multivariate models controlling for the effect of other variables, stress tolerance was positively related to age (lower tolerance in freshly detached buds compared to adult hydra) and size (higher tolerance in polyps with a large body column). Budding rate was negatively associated with stress tolerance. Hormetic treatment increased resistance to UV irradiation, but we found no evidence for an interaction between hormetic response and any of the life history traits, suggesting that the ability to upregulate physiological defense mechanisms after exposure to mild stress does not depend on the life history background of the individuals.

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“…For example, Faimali et al (2014) investigated the influence of different culturing and methodological parameters (temperature, photoperiod, ephyrae density and age) on considered end-points and standardized a protocol for organisms' maintenance and testing; then, ephyrae were exposed to two well-known reference toxic compounds (Cadmium Nitrate and Sodium Dodecyl Sulphate). Successively, Costa et al (2015) described another toxicity bioassay where Aurelia aurita ephyrae were used as model organism to test noxious effects of tow neurotoxic compounds, namely eserine (ES) and chlorpyrifos (CPF). In the case of toxicology bioassay on polyps, even less data are reported in literature, mostly addressing accumulation of contaminants, such as heavy metals (e.g.…”

Section: Discussionmentioning

confidence: 99%