Abstract
Honeybees use a variety of defence mechanisms to reduce disease infection and spread throughout the colony. Many of these defences rely on the collective action of multiple individuals to prevent, reduce or eradicate pathogens—often referred to as ‘social immunity’. Glucose oxidase (GOX) and some antimicrobial peptides (e.g. defensin-1 or Def1) are secreted by the hypopharyngeal gland of adult bees on larval food for their antiseptic properties. Because workers secrete these compounds to protect larvae, they have been used as ‘biomarkers’ for social immunity. The aim of this study was to investigate if GOX and Def1 are induced after pathogen exposure to determine whether its production by workers is the result of a collective effort to protect the brood and colony in response to a pathogen challenge. Specifically, we quantified GOX and Def1 in honeybee adults before and after colony-level bacterial infection by American foulbrood ((AFB), Paenibacillus larvae). Overall, our results indicate that levels of GOX and Def1 are not induced in response to pathogenic infections. We therefore conclude that GOX and Def1 are highly constitutive and co-opted as mechanisms of social immunity, and these factors should be considered when investigating immunity at the individual and colony level in social insects.
Highlights
Social species rely on individual and group mechanisms to reduce the increased risk of disease transmission that results from living in large colonies [1,2]
We investigate whether Glucose oxidase (GOX) activity and Def1 expression are activated in nurse bees after a colony-level challenge with the causative agent of the bacterial brood disease American foulbrood ((AFB), Paenibacillus larvae)
For gene expression of GOX, there was no significant interaction between time and treatment (F2,116 = 1.385, p = 0.255) and no effect of AFB treatment (F1,4 = 0.007, p = 0.936)
Summary
Social species rely on individual and group mechanisms to reduce the increased risk of disease transmission that results from living in large colonies [1,2]. The honeybee (Apis mellifera) is a model organism to study the role of physiological and behavioural mechanisms on social immunity [4,5]. These defence mechanisms can result from individual or group defences and range on a spectrum from highly constitutive (regularly expressed as a first line of defence) to highly inducible (upregulated in response to exposure) (figure 1; [6]). In terms of individual physiological immunity, the phenoloxidase cascade is often described as a model for constitutive innate immunity [10,11], while antimicrobial peptides are highlighted as highly inducible, even though they show some constitutive expression [4]
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