Worker bees, wasps and ants are often considered neuter. But in many species they are females with ovaries, who although unable to mate, can lay unfertilized eggs which turn into males if reared. For some species, such as bumble bees, this is the source of many of the males in the species. But in others, like the honeybee, workers “police” each other — killing eggs laid by workers or confronting egg-laying workers.
In 1964 the English biologist William Hamilton put forward his “relatedness hypothesis”, a major landmark in kin selection theory. His hypothesis was that worker bees, wasps and ants do not reproduce because most workers are half sisters. Instead the workers favor the queen’s male progeny, since she has mated with multiple males, ensuring variation in the species. According to this theory, a species where the mother queen mates with multiple males would have more worker policing. This theory is widespread and in animal behavior textbooks.
However, Hamilton’s relatedness hypothesis was challenged in 2004 by researchers from the University of Lausanne, Switzerland. They compared 50 species and found no evidence that multiple mating by the queen correlated with reduced rearing of workers’ sons or greater worker reproductive policing. Were the textbooks wrong”
A new study appearing in the current issue of The American Naturalist strongly supports Hamilton’s original theory. Tom Wenseleers and Francis Ratnieks (University of Sheffield) compared 90 species and found that workers’ sons are reared 100 times less in species with a queen mated to multiple males. They also found worker policing by the queen, with the queen eating working-laid eggs, in all species with multiple-mated queens, but in only 20 percent with single-mated queens.
“It seems that the textbooks do not need rewriting,” write the authors. “Kin selection theory is important when studying relatedness in social behavior. Social insects, with their great variation in kinship, have been a key test bed of the theory, and the theory has revolutionized our understanding of insect societies.”