Abstract
The presence of antimicrobial secondary metabolites in nectar suggests that pollinators, which are threatened globally by emergent disease, may benefit from the consumption of nectars rich in these metabolites. We tested whether nicotine, a nectar secondary metabolite common in Solanaceae and Tilia species, is used by parasitized bumblebees as a source of self-medication , using a series of toxicological, microbiological and behavioural experiments. Caged bees infected with Crithidia bombihad a slight preference for sucrose solution laced with the alkaloid and behavioural tests showed that the parasite infection induced an increased consumption of nicotine during foraging activity, though nicotine had an appetite-reducing effect overall. When ingested, nicotine delayed the progression of a gut infection in bumblebees by a few days, but dietary nicotine did not clear the infection, and after 10 days the parasite load approached that of control bees. Moreover, when pathogens were exposed to the alkaloid prior to host ingestion, the protozoan's viability was not directly affected, suggesting that anti-parasite effects were relatively weak. Nicotine consumption in a single dose did not impose any cost even in starved bees but the alkaloid had detrimental effects on healthy bees if consistently consumed for weeks. These toxic effects disappeared in infected bees, suggesting that detoxification costs might have been counterbalanced by the advantages in slowing the progression of the infection. Nicotine consumption did not affect bee lifespan but the reduction in the parasite load may have other likely unexplored subtle benefits both for individual bees and their colony. Potential evidence for self-medication is discussed. The contention that secondary metabolites in nectar may be under selection from pollinators, or used by plants to enhance their own reproductive success, remains to be confirmed.
Highlights
Parasites can have a dramatic impact on their hosts, and provide a powerful selective force for host defence mechanisms
In the “Continuous Exposure” test, a diet laced with nicotine reduced the intensity of C. bombi infections in bee workers (Dataset 1)
Here we demonstrate that parasitized bumblebees modify their diet preference and foraging behaviour, delaying the development of an infection
Summary
Parasites can have a dramatic impact on their hosts, and provide a powerful selective force for host defence mechanisms. Molecular mechanisms (e.g. the innate and adaptive immune system) are traditionally considered the major anti-parasite defences in the animal kingdom. Behavioural immunity is an important modality of defence against diseases (de Roode & Lefèvre, 2012), and medication behaviour is a key immune mechanism in some animals (Clayton & Wolfe, 1993; de Roode et al, 2013). Medication behaviour has been defined as the selective use of anti-pathogenic substances by infected individuals (Lozano, 1998; Singer et al, 2009), with a measurable benefit to host fitness and negative effects on the pathogen (Abbott, 2014; Clayton & Wolfe, 1993; Singer et al, 2009). As an additional criterion to support the notion that the substance is only of value as medication, it has been proposed that healthy individuals must suffer a cost when consuming it (Abbott, 2014)
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