Copper Exposure Affects Anti-Predatory Behaviour and Acetylcholinesterase Levels in ICulex pipiens/I

Copper Exposure Affects Anti-Predatory Behaviour and Acetylcholinesterase Levels in ICulex pipiens/I

Interaction between natural and anthropogenic stressors, such as contaminants and predators, could jointly account for potential ecological risk to organisms. This study quantified the combined effect of copper and/or predation cues (non- consumptive predation) on the anti-predatory behaviour of Cul...

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Bibliographic Details
Published in:Insects (Basel, Switzerland) Vol. 13; no. 12
Main Authors: Amer, Nermeen R, Lawler, Sharon P, Zohdy, Nawal M, Younes, Aly, ElSayed, Wael M, Wos, Guillaume, Abdelrazek, Samah, Omer, Hind, Connon, Richard E
Format: Journal Article
Language:English
Published: MDPI AG 01-12-2022
Subjects:
Alarm reaction
Behavior
Biological research
Biology, Experimental
Chemical properties
Copper
Environmental aspects
Mosquitoes
Physiological aspects
United States
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Summary:Interaction between natural and anthropogenic stressors, such as contaminants and predators, could jointly account for potential ecological risk to organisms. This study quantified the combined effect of copper and/or predation cues (non- consumptive predation) on the anti-predatory behaviour of Culex pipiens larvae (swimming distance and speed). As well, we tested the ability of mosquito larvae to escape predation by dragonfly larvae. We also measured the long-term effect of copper on an enzyme important to the nervous system, acetylcholine esterase (AChE) for two successive generations. Copper reduced the movement and velocity of Cx. pipiens larvae, even at levels regarded as environmentally safe. Interestingly, copper showed some stronger effects in the second generation than the first one. Copper acted as an AChE inhibitor at 500 µg L[sup.−1] . There was no significant effect of copper on the ability of larvae to escape from the direct predation of dragonflies in the laboratory, where most were consumed rapidly. However, the behavioural and neurological changes documented could result in Cx. pipiens larvae being more vulnerable to predation in natural habitats. Copper likely bioaccumulated and was passed on in eggs, and/or had other maternal or gene expression effects, resulting in harmful effects on offspring. Copper is an essential metal that occurs chronically in the environment and affects the development and physiology of aquatic insects. In excess amounts, it can impair their nervous system and behaviour. We tested the anti-predatory behaviour of Cx. pipiens larvae after seven days exposure with several concentrations of copper up to 500 mg L[sup.−1] . We measured responses to non- consumptive (predation cues) and consumptive predation (dragonfly larvae) across two generations. We also tested the accumulated effect of copper on AChE enzyme activity. We exposed half of treated and control larvae to predation cues (water with predator odour and crushed conspecifics) and the other half to water without predation cues. We evaluated total distance moved and velocity. Copper reduced the distance moved and velocity, with stronger effects in the second generation. Copper had no significant effect on larvae eaten by dragonflies. Copper inhibited the AChE enzyme across both generations at 500 µg L[sup.−1] . Copper can affect the nervous system directly by inhibiting AChE activity, and possibly also by impairing the olfaction sensors of the larvae, resulting in larval inability to detect predation cues.
ISSN:2075-4450
2075-4450
DOI:10.3390/insects13121151