Sibling Cannibalism in Group-Living Larvae of the Solitary Wasp, Isodontia harmandi (Hymenoptera: Sphecidae): Effects of Prey Availability and Size Discrepancy.

Sibling cannibalism has rarely been documented in the resource-based context of sibling rivalry. The solitary wasp Isodontia harmandi (Pérez) (Hymenoptera: Sphecidae) has an exceptional style of nursery 'communal brood cells', in which multiple larvae gregariously develop while relying on maternal prey provisioning. In this species there are several distinct features; e.g., cannibalism-driven brood reduction, single-sex broods, and mass provisioning. Rearing of the wasp larvae in artificial nest chambers provides the novel opportunity to study larval interactions under controlled conditions. To determine the factors that influence the occurrence of cannibalism and its timing, we conducted a rearing experiment using sib and non-sib pairs under two prey-availability treatments, and recorded the occurrence of cannibalism and the processes of larval growth and prey consumption over a 96-hr period. Cannibalism occurred more frequently in the low-prey treatment than in the high-prey treatment, and in female pairs than in male pairs. Cannibalism tended to occur earlier when the amount of prey remaining decreased rapidly. However, cannibalism did not occur only when all prey had been completely consumed, implying that it was not triggered directly by prey exhaustion. Cannibals were always larger than their victims, whose growth rates had often slowed before they were eaten. These results strongly imply that wasp larvae commit sibling cannibalism in the context of resource-based sibling rivalry, ensuring the double benefit of nutritional gains and reduced resource competition. We also investigated the possibility that wasp larvae monitor the size difference and/or body condition of brood-mates as an indicator of prey availability.

Brood reduction caused by sibling cannibalism in Isodontia harmandi (Hymenoptera: Sphecidae), a solitary wasp species building communal brood cells.

Sibling rivalry or brood reduction prevailing within bird nests is effectively avoided in solitary aculeate nests because the larvae of wasps and bees usually develop in each brood cell. However, a solitary wasp species, Isodontia harmandi, allows us to study brood reduction in a communal brood cell, where up to a dozen larvae develop in a group relying on prey provisioned by a female wasp. To demonstrate brood reduction in this species, we collected nests at various developmental brood stages from fields for five years (2010-2015). There was a significant decrease in the brood size between the nests sampled at the egg or hatchling stages and those at later stages when analyzing only data excluding nests that were parasitized, attacked by predators, or containing deteriorated prey. In whole brood-rearing experiments, we also confirmed that brood reduction occurred in 30 of 39 nests during larval stages and in 23 nests after cocoon stage. Larval survival was affected positively by total prey weight and negatively by brood size, though cocoon survival was not affected. A third-quarter (76%) of larval death was identified as sibling cannibalism through observation by time-lapse recording on multi-larvae rearing experiments. Therefore, we conclude that brood reduction routinely occurs as a result of sibling cannibalism in I. harmandi. Additionally, as we could not detect any positive effects of clutch size on the amount of provision, female wasps might overproduce offspring due to the unpredictability of available prey resources. Differences in brood size and reduction among sex categories were undetected, except for parental provisions. Thus, sibling cannibalism may efficiently regulate brood size in communal brood cells under prey shortage.