Recruitment-dance signals draw larger audiences when honey bee colonies have multiple patrilines

Girard, Madeline B.; Mattila, Heather R.; Seeley, Thomas D.

doi:10.1007/s00040-010-0118-x

Cited by 12 publications

(5 citation statements)

References 51 publications

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“…Tracking an entire colony over a long time would allow one to investigate the stability of task allocation. Prior research has shown that during each life stage, an individual spends most of its time in a specific nest region 31 , 54 , interacting with nestmates, but with whom they interact may depend on more than location alone (e.g., previous interactions, or the genetic diversity within the colony 55 , 56 ). Social interactions permit an exchange of information and can have long-term effects on an individual’s behavior 57 .…”

Section: Introductionmentioning

confidence: 99%

Social networks predict the life and death of honey bees

et al. 2021

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In complex societies, individuals’ roles are reflected by interactions with other conspecifics. Honey bees (Apis mellifera) generally change tasks as they age, but developmental trajectories of individuals can vary drastically due to physiological and environmental factors. We introduce a succinct descriptor of an individual’s social network that can be obtained without interfering with the colony. This ‘network age’ accurately predicts task allocation, survival, activity patterns, and future behavior. We analyze developmental trajectories of multiple cohorts of individuals in a natural setting and identify distinct developmental pathways and critical life changes. Our findings suggest a high stability in task allocation on an individual level. We show that our method is versatile and can extract different properties from social networks, opening up a broad range of future studies. Our approach highlights the relationship of social interactions and individual traits, and provides a scalable technique for understanding how complex social systems function.

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Section: Introductionmentioning

confidence: 99%

Social networks predict the life and death of honey bees

et al. 2021

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“…Tracking an entire colony over a long time would allow one to investigate the stability of task allocation. Prior research has shown that during each life stage, an individual spends most of its time in a specific nest region (Johnson 2010; Seeley 1982), interacting with nestmates, but with whom they interact may depend on more than location alone (Farina 2000; Girard et al 2011). Social interactions permit an exchange of information and can have long-term effects on an individual’s behavior (Cholé et al 2019).…”

Section: Introductionmentioning

confidence: 99%

Social networks predict the life and death of honey bees

Wild

Dormagen

Zachariae

et al. 2020

Preprint

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In many social systems, an individual's role is reflected by its interactions with other members of the group (Gordon 2010, Pinter-Wollmann et al. 2014, Krause 2015, Farine & Whitehead 2015. In honey bee colonies ( Apis mellifera ), workers generally perform different tasks as they age, yet there is high behavioral variation in same-aged bees (Seeley 1982, Robinson 1992, Huang and Robinson 1996, Johnson 2010. It is unknown how social interactions within the colony relate to an individual's tasks throughout her life. We propose a new method to extract a single number from each individual's interaction patterns in multimodal social networks that captures her current role in the colony. This "network age" is better than biological age at predicting task allocation (+99%), survival (+157%), and activity patterns (+44-108%) and even predicts task allocation up to one week (around a sixth of her typical lifespan) into the future. Network age identifies distinct developmental paths and task changes throughout a bee's life: We show that individuals change tasks gradually and exhibit high task repeatability, and that same aged bees form stable behavioral subgroups in which they predominantly interact with one another. While we derived interaction networks by automatically tracking a fully tagged colony, we show that tracking only 5% of the bees is sufficient to extract a meaningful representation of the individuals' interaction patterns, demonstrating the feasibility of our method for detecting complex social structures with reduced experimental effort. Since network age more accurately predicts task allocation than biological age, it could be used in experimental manipulations to quantify shifts in the timing of task transitions as a response. We extend our method to extract interaction patterns relevant to other attributes of the individuals, such as their mortality, opening up a broad range of possible applications. Our approach is a scalable instrument to study individual behavior through the lens of social interactions over time in honey bees and other complex social systems.

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“…In general, if a colony is genotypically diverse, then foragers of all stripes (including those who rely on waggle dances to learn about the profitability of a food source) tend to visit a food source in greater numbers and often at faster rates (this study; Mattila and Seeley 2010), producing upon return to their colonies more chemical signals that spur forager reactivation (Gilley et al 2012;Carr-Markell et al 2013) and more waggle dances (this study; Mattila et al 2008;Seeley 2010, 2011). Moreover, the dances produced in genotypically diverse colonies are better attended by dance followers (Girard et al 2011) and result in a greater number of recruits arriving at the food source (this study). These interactions, which are powered by the interplay between the responsiveness of genetic specialists to foraging-related stimuli (Table I) and the allocation of foragers to high-quality food sources through intensified use of recruitment signals (Seeley and Visscher 1988), fuel a honey bee colony's competitive ability to discover, exploit, and mass recruit to patchy and ephemeral food sources.…”

Section: Discussionmentioning

confidence: 69%

Extreme polyandry improves a honey bee colony’s ability to track dynamic foraging opportunities via greater activity of inspecting bees

Mattila

Seeley

2013

Apidologie

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International audienceWe explored the worker-level interactions that enhance the organization of foraging in honey bee colonies with extremely polyandrous queens by determining whether a colony’s patriline number affects the activity of its inspectors (foragers who visit a previously utilized food source to see if it is profitable again). We monitored the use of sucrose feeders by foragers in free-flying colonies that had either multiple patrilines or a single patriline as the feeders were sequentially stocked, emptied, and then restocked. Multiple-patriline colonies tended to have more inspectors than single-patriline colonies, their inspectors inspected their feeder at higher rates when it was empty, and then foraged at higher rates and performed more waggle runs when it was restocked, which quadrupled feeder recruitment. The patriline profile for a colony’s inspectors consistently differed from that of its general population. We show clear ergonomic benefits of extreme polyandry for honey bee queens and their colonies

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Recruitment-dance signals draw larger audiences when honey bee colonies have multiple patrilines

Cited by 12 publications

References 51 publications

Social networks predict the life and death of honey bees

Social networks predict the life and death of honey bees

Social networks predict the life and death of honey bees

Extreme polyandry improves a honey bee colony’s ability to track dynamic foraging opportunities via greater activity of inspecting bees

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