Conserved queen pheromones in bumblebees: a reply to Amsalem et al.

In a recent study, Amsalem, Orlova & Grozinger (2015) performed experiments with Bombus impatiens bumblebees to test the hypothesis that saturated cuticular hydrocarbons are evolutionarily conserved signals used to regulate reproductive division of labor in many Hymenopteran social insects. They concluded that the cuticular hydrocarbon pentacosane (C25), previously identified as a queen pheromone in a congeneric bumblebee, does not affect worker reproduction in B. impatiens. Here we discuss some shortcomings of Amsalem et al.’s study that make its conclusions unreliable. In particular, several confounding effects may have affected the results of both experimental manipulations in the study. Additionally, the study’s low sample sizes (mean n per treatment = 13.6, range: 4–23) give it low power, not 96–99% power as claimed, such that its conclusions may be false negatives. Inappropriate statistical tests were also used, and our reanalysis found that C25 substantially reduced and delayed worker egg laying in B. impatiens. We review the evidence that cuticular hydrocarbons act as queen pheromones, and offer some recommendations for future queen pheromone experiments

Buffered fitness components: Antagonism between malnutrition and an insecticide in bumble bees.

Global insect biodiversity declines due to reduced fitness are linked to interactions between environmental stressors. In social insects, inclusive fitness depends on successful mating of reproductives, i.e. males and queens, and efficient collaborative brood care by workers. Therefore, interactive effects between malnutrition and environmental pollution on sperm and feeding glands (hypopharyngeal glands (HPGs)) would provide mechanisms for population declines, unless buffered against due to their fitness relevance. However, while negative effects for bumble bee colony fitness are known, the effects of malnutrition and insecticide exposure singly and in combination on individuals are poorly understood. Here we show, in a fully-crossed laboratory experiment, that malnutrition and insecticide exposure result in neutral or antagonistic interactions for spermatozoa and HPGs of bumble bees, Bombus terrestris, suggesting strong selection to buffer key colony fitness components. No significant effects were observed for mortality and consumption, but significant negative effects were revealed for spermatozoa traits and HPGs. The combined effects on these parameters were not higher than the individual stressor effects, which indicates an antagonistic interaction between both. Despite the clear potential for additive effects, due to the individual stressors impairing muscle quality and neurological control, simultaneous malnutrition and insecticide exposure surprisingly did not reveal an increased impact compared to individual stressors, probably due to key fitness traits being resilient. Our data support that stressor interactions require empirical tests on a case-by-case basis and need to be regarded in context to understand underlying mechanisms and so adequately mitigate the ongoing decline of the entomofauna

Dual Effect of Wasp Queen Pheromone in Regulating Insect Sociality

SummaryEusocial insects exhibit a remarkable reproductive division of labor between queens and largely sterile workers [1, 2]. Recently, it was shown that queens of diverse groups of social insects employ specific, evolutionarily conserved cuticular hydrocarbons to signal their presence and inhibit worker reproduction [3]. Workers also recognize and discriminate between eggs laid by the queen and those laid by workers, with the latter being destroyed by workers in a process known as “policing” [4, 5]. Worker policing represents a classic example of a conflict-reducing mechanism, in which the reproductive monopoly of the queen is maintained through the selective destruction of worker-laid eggs [5, 6]. However, the exact signals used in worker policing have thus far remained elusive [5, 7]. Here, we show that in the common wasp, Vespula vulgaris, the pheromone that signals egg maternity and enables the workers to selectively destroy worker-laid eggs is in fact the same as one of the sterility-inducing queen signals that we identified earlier [3]. These results imply that queen pheromones regulate insect sociality in two distinct and complementary ways, i.e., by signaling the queen’s presence and inhibiting worker reproduction, and by facilitating the recognition and policing of worker-laid eggs

Emerging threats and opportunities to managed bee species in European agricultural systems: a horizon scan

Managed bee species provide essential pollination services that contribute to food security worldwide. However, managed bees face a diverse array of threats and anticipating these, and potential opportunities to reduce risks, is essential for the sustainable management of pollination services. We conducted a horizon scanning exercise with 20 experts from across Europe to identify emerging threats and opportunities for managed bees in European agricultural systems. An initial 63 issues were identified, and this was shortlisted to 21 issues through the Horizon Scanning process. These ranged from local landscape-level management to geopolitical issues on a continental and global scale across seven broad themes - Pesticides & pollutants, Technology, Management practices, Predators & parasites, Environmental stressors, Crop modification, and Political & trade influences. While we conducted this Horizon Scan within a European context, the opportunities and threats identified will likely be relevant to other regions. A renewed research and policy focus, especially on the highest-ranking issues, is required to maximise the value of these opportunities and mitigate threats to maintain sustainable and healthy managed bee pollinators within agricultural systems

"Conflict and conflict resolution in insect societies"

In insect societies, intracolonial conflict frequently arises because of conflicting genetic interests of non-clonal individuals. This conflict may be avoided by increasing genetic relatedness among colony members. This may be achieved through asexual or clonal reproduction by which conflicting genetic interests are silenced. An additional mechanism to resolve conflict over male production is policing, a mechanism whereby queens or workers aggress reproductive workers and/or cannibalize worker-laid eggs. To this end, workers need accurate cues that inform them on the presence of a fecund queen, because in queenless colonies, workers will cease policing and start reproducing. Queen caste-specific cuticular hydrocarbons can prevent worker ovary activation in different species belonging to groups of social insects that evolved eusociality idependently, i.e. the common wasp (Vespula vulgaris), a bumblebee (Bombus terrestris), and a Desert ant (Cataglyphis iberica). Interestingly, in all three species all identified queen pheromones are non-volatile linear and methyl-branched alkanes. In addition, comparative analysis and ancestral state reconstruction suggests that these queen pheromones evolved from conserved signals in solitary ancestors. Hence, hydrocarbons appear to have played a key role in the evolution of reproductive division of labour in social insects. This hypothesis is further strengthened by the finding that a methyl-branched alkane is used as a queen egg-marking pheromone in the common wasp. Together, these results demonstrate that saturated hydrocarbons present on the queen s cuticle and eggs can fulfil the important role of queen pheromones. Intercolonial conflict arises when unrelated individuals infiltrate colonies to benefit nutritionally or reproductively from the host s resources. In the case of brood parasitism, individuals forgo brood care and have their brood reared by their host. A special case of brood parasitism, queen reproductive parasitism, occurs in the stingless bee Melipona scutellaris. In this species, queen parasitism is common, with 1/3 of all take-overs being undertaken by alien queens. Furthermore, alien queens actively seek out queenless colonies, and employ a specific strategy to enter their target colonies. Lone queens enter colonies in the evening when guarding efficiency is significantly reduced, and thus maximize their chances on a successful take-over.Interspecific conflict occurs between members of different species. Parasites of social insect species might employ chemical mimicry to infiltrate colonies and avoid attack. A parasitic beetle, Metoecus paradoxus, uses different chemical strategies to enter colonies of his social insect host, the common wasp. The beetles do not acquire their host-specific cuticular hydrocarbon profile through contact with the host nest material, but appear to recycle hydrocarbons from their wasp host larvae. Furthermore, the beetle has significantly lower proportions of long-chain methyl-branched hydrocarbons on its cuticle when compared to his host. This type of compounds has been suggested to play a key role in nestmate recognition, and it might therefore indicate that chemical transparancy is used as a strategy to avoid detection. In addition, beetles overproduce common wasp queen pheromones, suggesting that queen mimicry is an important chemical strategy that the beetle uses to avoid attack by the workers in its host colony.status: publishe

Unusual modes of reproduction in social insects: Shedding light on the evolutionary paradox of sex

The study of alternative genetic systems and mixed modes of reproduction, whereby sexual and asexual reproduction is combined within the same lifecycle, is of fundamental importance as they may shed light on classical evolutionary issues, such as the paradox of sex. Recently, several such cases were discovered in social insects. A closer examination of these systems has revealed many amazing facts, including the mixed use of asexual and sexual reproduction for the production of new queens and workers, males that can clone themselves and the routine use of incest without deleterious genetic consequences. In addition, in several species, remarkable cases of asexually reproducing socially parasitic worker lineages have been discovered. The study of these unusual systems promises to provide insight into many basic evolutionary questions, including the maintenance of sex, the expression of sexual conflict and kin conflict and the evolution of cheating in asexual lineages.status: publishe

Worker dominance and reproduction in the bumblebee Bombus terrestris: when does it pay to bare one's mandibles?

In bumblebees, dominance behaviour contributes to the regulation of the reproductive division of labour between queens and workers. Towards the end of the colony cycle, at the onset of the competition phase, reproductive workers will establish a dominance hierarchy and challenge the reproductive monopoly of the queen by laying unfertilized, male-destined eggs. However, it has been suggested that the dominance and reproductive hierarchies in bumblebee workers are not completely aligned. By performing manipulative experiments and observing both aggressive behaviour and ovarian activation in Bombus terrestris workers, we aimed to elucidate how these two hierarchies interact and are modulated by the presence of the queen and other reproductive workers. We found that the reintroduction of a queen in a queenless colony not only caused worker ovary regression, but also decreased aggressive interactions between workers, thereby restoring the harmony in the colony. Furthermore, transplanting dominant reproductive workers from queenless colonies into queenright colonies induced the resident workers to activate their ovaries and aggressively compete over reproduction, thereby implying that positive feedback drives the onset of the competition phase. However, we did not see this result when subordinate reproductive workers from queenless colonies were added to queenright colonies, suggesting that ovary activation is mainly initiated in reaction to displays of dominance. Additionally, we observed that workers were attacked irrespective of their reproductive state, questioning the importance of signals that advertise either fertility or sterility in bumblebees. Finally, larger workers were significantly more aggressive and significantly more likely to be attacked, even though smaller workers were equally likely to have activated ovaries. This suggests that large workers resort to aggression to increase their chances of successfully reproducing due to their inherent fighting advantage, whereas small cheater workers could possibly reproduce by staying under the radar to evade nestmate aggression.status: publishe

Cross-activity of honeybee queen mandibular pheromone in bumblebees provides evidence for sensory exploitation

The evolutionary origin of queen pheromones (QPs), which regulate reproductive division of labor in insect societies, has been explained by two evolutionary scenarios: the sender-precursor hypothesis and the sensory exploitation hypothesis. These scenarios differ in terms of whether the signaling system was built on preadaptations on the part of either the sender queens or the receiver workers. While some social insect QPs—such as cuticular hydrocarbons—were likely derived from ancestral fertility cues and evolved according to the former theory, the honeybee’s queen mandibular pheromone (QMP) has been suggested to act directly on preexisting gene-regulatory networks linked with reproduction. This is evidenced by the fact that QMP has been shown to also inhibit ovary activation in fruit flies, thereby implying exploitation of conserved physiological pathways. To verify whether QMP has similar effects on more closely related eusocial species, we here tested for QMP cross-activity in the bumblebee Bombus terrestris. Interestingly, we found that the non-native QMP blend significantly inhibited egg laying in both worker and queen bumblebees and caused accompanying shifts in ovary activation. The native bumblebee QP pentacosane, by contrast, only inhibited the reproduction of the workers. Overall, these findings support the hypothesis that honeybee QMP likely evolved via a route of sensory exploitation. We argue that such exploitation could allow social insect queens to produce compounds that manipulate the workers to remain sterile, but that a major hurdle would be that the queens themselves would have to be immune to such compounds.status: publishe

Seasonal changes in parasite load and a cellular immune response in a colour polymorphic lizard

Permanent colour polymorphisms may be maintained by complex interactions between physiological traits (e.g. immunity) and environmental pressures. In this study we investigate morph specific variation in parasite load and cellular immune response (induced by a Phytohaemagglutinin, PHA injection) in a colour polymorphic population of the Dalmatian wall lizard (Podarcis melisellensis), where adult males have bright white, yellow or orange throats and ventral sides. Orange males have larger heads and can bite harder than the others. To examine seasonal effects, analyses were performed at an early and late stage in the reproductive season (May and September). Infection with mites and ticks did not differ among morphs, but was more severe at the end of the reproductive season. Fewer orange individuals were infected with haemogregarines at the end of the season, but white males were always more infected (higher number of haemogregarines in their blood) than other morphs. White and yellow males showed an increased PHA response towards the end of the season, but PHA response decreased in the orange morph. Finally, across all morphs, a relationship was found between ectoparasite load and PHA response. Our study provides indications of alternative life-history strategies among colour morphs and evidence for an up-regulation of the immune function at the end of the reproductive season.status: publishe

Short-term lab assessments and microcolonies are insufficient for the risk assessment of insecticides for bees

Risk assessment studies addressing effects of agrochemicals on bumblebees frequently use microcolonies. These are queenless colonies consisting of workers only in which typically one worker will lay unfertilized male-destined eggs. In the first tier of risk assessment for bees, short-term laboratory experiments (e.g. microcolonies) are used, the results of which will determine whether higher tier (semi-)field experiments are needed. To evaluate the suitability of microcolonies for risk assessment, a direct comparison between different assessment methods for the neonicotinoid pesticides acetamiprid and thiacloprid was made: microcolonies and queenright colonies under short-term laboratory conditions, queenright colonies under long-term laboratory conditions, and queenright colonies under field conditions. Here, we demonstrate that results from microcolonies contradict results from queenright colonies. While thiacloprid negatively impacted gyne production in queenright colonies, it had a positive effect on microcolony size. By contrast, thiacloprid had no significant effect on fitness parameters of queenright colonies under short-term laboratory conditions when mostly workers are produced. These results thus highlight both the need for long term assessments, allowing evaluation of gyne production, and the risk of reaching erroneous conclusions when using microcolonies. The negative effect of thiacloprid on colony fitness was confirmed under field conditions, where thiacloprid affected the production of reproductives, colony weight gain, worker weight, and foraging behaviour. For acetamiprid, a negative trend on colony fitness could only be shown in a field setup. Therefore, field-realistic setups, which allow colonies to forage freely, are most appropriate to assess sublethal effects of pesticides affecting behaviour and learning