53 Root, A.I. and Root, E.R. (1908). ABC and XYZ of Bee Culture: A Cyclopedia of Everything Pertaining to the Care of the Honey‐bee; Bees, Hives, Honey, Implements, Honey‐plants, etc. Facts Gleaned from the Experience of Thousands of Bee‐keepers, and Afterward Verified in Our Apiary. Medina, OH: AI Root Company.
54 Rosenkranz, P., Fries, I., Boecking, O., and Stürmer, M. (1997). Damaged Varroa mites in the debris of honey bee (Apis mellifera L.) colonies with and without hatching brood. Apidologie 28 (6): 427–437. https://doi.org/10.1051/apido:19970609.
55 Rosenkranz, P., Aumeier, P., and Ziegelmann, B. (2010). Biology and control of Varroa destructor. Journal of Invertebrate Pathology 103: S96–S119.
56 Salmela, H., Amdam, G.V., and Freitak, D. (2015). Transfer of immunity from mother to offspring is mediated via egg‐yolk protein vitellogenin. PLoS Pathogens 11 (7): e1005015. https://doi.org/10.1371/journal.ppat.1005015.
57 Seeley, T.D. (1977). Measurement of nest cavity volume by the honey bee (Apis mellifera). Behavioral Ecology and Sociobiology 2: 201–227.
58 Seeley, T.D. (2002). The effect of drone comb on a honey bee colony's production of honey. Apidologie 33: 75–86.
59 Seeley, T.D. (2017a). Darwinian beekeeping: an evolutionary approach to apiculture. American Bee Journal 157: 277–282.
60 Seeley, T.D. (2017b). Life‐history traits of wild honey bee colonies living in forests around Ithaca, NY, USA. Apidologie https://doi.org/10.1007/s13592‐017‐0519‐1.
61 Seeley, T.D. (2019a). The Lives of Bees: The Untold Story of the Honey Bee in the Wild. Princeton, NJ: Princeton University Press.
62 Seeley, T.D. (2019b). The history of honey bees in North America. In: Phylogenetics of Bees (eds. R. Ilyasov and H.W. Kwon), 222–232. Boca Raton, FL: CRC Press.
63 Seeley, T.D. and Morse, R.A. (1976). The nest of the honey bee (Apis mellifera L.). Insectes Sociaux 23 (4): 495–512.
64 Seeley, T.D. and Smith, M. (2015). Crowding honey bee colonies in apiaries can increase their vulnerability to the deadly ectoparasite Varroa destructor. Apidologie 46: 716–727.
65 Seeley, T.D. and Tarpy, D.R. (2007). Queen promiscuity lowers disease within honeybee colonies. Proceedings of the Royal Society of London Series B 274: 67–72.
66 Seeley, T.D., Tarpy, D.R., Griffin, S.R. et al. (2015). A survivor population of wild colonies of European honeybees in the northeastern United States: investigating its genetic structure. Apidologie 46: 654–666.
67 Sherman, P.W., Seeley, T.D., and Reeve, H.K. (1998). Parasites, pathogens, and polyandry in honey bees. The American Naturalist 151 (4): 392–396.
68 Simone, M., Evans, J.D., and Spivak, M. (2009). Resin collection and social immunity in honey bees. Evolution 63 (11): 3106–3022.
69 Spivak, M. and Downey, D.L. (1998). Field assays for hygienic behavior in honey bees (Hymenoptera: Apidae). Apiculture and Social Insects 91 (1): 64–70.
70 Tarpy, D.R. and Seeley, T.D. (2006). Lower disease infections in honeybee (Apis mellifera) colonies headed by polyandrous vs monandrous queens. Naturwissenschaften 93: 195–199.
71 vanEngelsdorp, D., Evans, J.D., Saegerman, C. et al. (2009). Colony collapse disorder: a descriptive study. PLoS One 4 (8): e6481. https://doi.org/10.1371/journal.pone.0006481.
72 Winston, M.L. (1980). Swarming, afterswarming, and reproductive rate of unmanaged honey bee colonies (Apis mellifera). Insectes Sociaux 27 (4): 391–398.
73 Zheng, H., Steele, M.I., Leonard, S.P. et al. (2018). Honey bees as models for gut microbiota research. Lab Animal 47: 317–325.
2 The Superorganism and Herd Health for the Honey Bee
Robin W. Radcliffe
Department of Clinical Sciences, College of Veterinary Medicine, Cornell University, Ithaca, NY, USA
* Illustrations by Anna Connington
Introduction
The honey bee colony is a magnificent product of evolution. Collective decision‐making of thousands of individual bees, each with roles that change as they age, work seamlessly together to create a highly integrated system (the colony) that functions as a single organism (the superorganism). In this chapter we will explore the marvelous world of the honey bee with a focus on how the organization and structure of the colony allows honey bee societies to function as a single coordinated living entity. The superorganism must build new comb, make replacement bees, collect food, water, and hive materials all while protecting their home from pests and pathogens, and survive to reproduce by casting a swarm and sending off drones. Deviations in any one of these collective pathways can lead to disorders, disease, or colony failure.
We will follow the honey bee as it allocates tasks in sophisticated communication networks that help prevent the spread of pathogens, make and use organic compounds to fight disease, collect plant resins to make propolis, and manipulate the hive environment to prevent and even treat infections in the colony. In an extraordinary example of social behavior, we will also learn how honey bees can treat themselves and prevent disease by working as their own “doctors”! These novel methods of disease control and mitigation are just now becoming well understood. The marvels of resin and pollen collection and the myriad bioactive elements in these compounds, collected from nature itself, offers wonderful insights into the ways that honey bees protect themselves from harm. The health benefits of propolis to human health have been known since the days of the ancient Greeks, Romans, and Egyptians; the word itself comes from the Greek “pro” to defend and “opolis” the city, or in this case the beehive or wild nest. Here we will explore the value of propolis to the bees themselves, a topic deserving of more in‐depth research. Honey bees can also control fundamental environmental conditions that are protective against disease, including the remarkable ability to regulate the “body temperature” of the superorganism. Used against large invaders such as a bumble bee that attempts to enter the colony, honey bees use heat to “bake” the invader in a ball of heater bees, while small invaders such as some bacteria and fungi that infect the brood are killed by small elevations in temperature (enough to kill the pathogen, but not the developing brood). Scientists call the latter a “social fever”, and it is another example of how the colony can ward off infections through cooperative action.
Finally, the health and fitness of honey bees as a superorganism can be examined and evaluated in much the same way as a herd of livestock – herd health for honey bees offers a big picture “lens” through which serial monitoring of population level determinants of health are made. An understanding of how honey bees coordinate important hive processes (including collection of pollen, nectar and tree resins, coordination of bee caste populations, maintenance of biosecurity, and ensuring a healthy living environment) combined with the collection of relevant data will provide one of the most important tools for the bee doctor to help decipher health at the level of the colony working in concert with the beekeeper.
Part 1: The Superorganism and Swarm Intelligence
At the peak of summer activity, an estimated 30 000–50 000 bees live in close proximity within the confines of the typical beehive, or a bee tree if a wild colony. The value of social living must exceed the disadvantages of being closely packed together since parasites and pathogens can exploit the high density of individuals and their