From cryptic herbivore to predator: stable isotopes reveal consistent variability in trophic levels in an ant population.

Populations may collectively exhibit a broad diet because individuals have large diet breadths and/or because subpopulations of specialists co-occur. In social insect populations, the diet of the genetic individual, the colony, may similarly arise because workers are diet generalists or castes of specialists. We used elemental and isotopic methods to explore how the invasive red imported fire ant, Solenopsis invicta, achieves its status as a trophic generalist. In one 0.5-ha old field, 31 S. invicta colonies ranged from 1°-consumer to 2°-predator (δ15 N's 0.35-7.38‰), a range comparable to that shown in sampled ant communities. Moreover, a colony's trophic rank was stable despite δ15 N fluctuating 2.98‰ over the year. Colonies that fed at higher trophic levels were not larger, but consumed more C3 -based resources. Individual worker mass, however, did increase with δ15 N (r2  = 0.29, P < 0.001). The ninefold variation in worker mass within a colony generated trophic variance approximately 15% of the population of colonies. Combined, we show how intraspecific trait variation contributes to the trophic breadth of S. invicta, and suggest mechanisms that further explain how their trophic signature varies across space, but remains stable over time.