Larger ant colonies drive the evolution of worker castes – division of labour is key to life’s complexity

Just like human societies, ant societies have a division of labour. Within a colony, some individuals feed the young while others are soldiers who protect the colony from intruders. New research across 794 ant species reveals that group size determines whether or not division of labour evolves.
Ants of different sizes
Image caption: Camponotus ants in the south of Finland. Workers of this species vary a lot in size and have a distinct soldier caste. Such morphological differences between castes only evolved in species with large colonies. Image: Philip Downing.

Remarkably, in some ant species, individuals have become morphologically specialized to carry out their different tasks, despite being siblings. . Darwin called the existence of such workers castes his ‘special difficulty’ because it was hard to explain how they evolved.

“We know that larger ant colonies have more worker castes”, says Postdoctoral Researcher Philip Downing from the University of Oulu, one of the international study’s authors. “The difficulty is working out how this association came to be. Which came first? Did large colonies evolve first, followed by castes, or did castes evolve first, which allowed colonies to get larger? To solve this problem, we had to compare modern-day ants with their ancestors.”

Since the ant ancestors no longer exist, researchers used statistical approaches to infer what their colony sizes and caste numbers would have been, based on their living descendants. “We found that larger colony sizes evolved before workers castes did, supporting what’s known as the size-complexity hypothesis”, explains Downing who was involved in coding the statistical analyses.

Lead author Louis Bell-Roberts from the University of Oxford says: “The size–complexity hypothesis is a leading explanation for the evolution of complex life on earth. In line with this, our research shows that larger colony sizes favoured the evolution of increased division of labour, resulting in more worker castes and greater variation in worker size.” The results may also offer insights about the evolution of multicellular organisms such as animals and plants. Read more on the University of Oxford news.

“Now that we know larger colony size favours more worker castes, the next step is to study what favours larger colony sizes in ants. Colony size in ants varies from seven to 14,8 million. Can ecological factors, such as the number of predators, the climate, or even the number of parasites of an ant species explain this?” Downing asks. He plans to conduct large-scale statistical comparisons across many ant species to find out.

The new research article was published on 26.8.2024: Bell-Roberts, L., Turner, J.F.R., Werner, G.D.A. et al. Larger colony sizes favoured the evolution of more worker castes in ants. Nature Ecology & Evolution (2024). Read the article.

Read also

Downing, P.A. 2024. Michener’s Group Size Paradox in Cooperatively Breeding Birds. Journal of Evolutionary Biology, 37: 353-359. Read the article.

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Last updated: 29.8.2024