Agricultural Pesticides and Ectoparasites: Potential Combined Effects on the Physiology of a Declining Aerial Insectivore

Overview

Journal Conserv Physiol

Date 2021 May 7

PMID 33959290

Citations 1

Authors

Audrey Sigouin

Marc Belisle

Dany Garant

Fanie Pelletier

Affiliations

Soon will be listed here.

Abstract

Agricultural pesticides usage has been increasing globally. These compounds have been developed to disrupt pest species physiology, but because their specificity is limited, they can also have adverse effects on non-target organisms. Recent studies have shown that the damaging toxicological effects of pesticides can be amplified in stressful environments. However, few studies have documented these effects in natural settings where organisms are simultaneously exposed to pesticides and to other environmental stressors such as parasites. In this study, we assessed both pesticide and ectoparasite effects on the physiology of a free-ranging bird. We measured physiological markers including haematocrit, bacteria-killing ability (BKA) and leucocyte counts, as well as exposure to haematophagous larvae, in tree swallow nestlings (), a declining aerial insectivore, in southern Québec, Canada, for over 3 years. We found that combined exposure to pesticides and larvae was negatively related to haematocrit, suggesting possible synergistic effects. However, we found no such relationships with BKA and leucocyte counts, highlighting the complexity of physiological responses to multiple stressors in natural settings. Populations of several aerial insectivores are declining, and although sublethal pesticide effects on physiology are suspected, our results suggest that exposure to other factors, such as parasitism, should also be considered to fully assess these effects, especially because pesticides are increasingly present in the environment.

Citing Articles

Sublethal pesticide exposure influences behaviour, but not condition in a widespread Australian lizard.

Contador-Kelsall I, Maute K, Story P, Hose G, French K Conserv Physiol. 2022; 10(1):coac024.

PMID: 35492410 PMC: 9040277. DOI: 10.1093/conphys/coac024.

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