Back on April 30th, I found an adjoining pair of potter wasp nests (likely belonging to Eumenes sp.) while on a collecting trip to Zaleski State Forest with the Ohio State University's undergraduate entomology club. At the recommendation of one of my fellow students, I saved the stout clay pots in hopes that something more interesting than the offspring of their creator would emerge.
hope paid off just one day shy of a month later, when two distinctly
non-eumenine wasps emerged, one from each pot: both larvae had been
parasitized (females of the Eumenini lay a single egg in each jar;
Hermes et al., 2015). Much to my pleasure, the parasitoids I had unwittingly collected were Lycogaster pullata, a member of the small, seldom-encountered family Trigonalidae.
genera of trigonalids are present in North America. They tend to be
moderately sized, chunky wasps with unreduced wing venation and >16
flagellomeres, distinguished from other apocritans of this description
by finger-like ventral projections at their tarsomeres' apices and
reduced ovipositors in females (Goulet & Huber, 1993).
Distinctive enough to warrant their own superfamily, trigonalids have
most recently been classified within the infraorder Evaniomorpha (Heraty
et al., 2011).
reduced ovipositor is a consequence of the wasps' distinctive biology,
the convolutions of which are at least partially responsible for their
rarity: rather than lay eggs directly upon or within their desired
hosts, trigonalid females oviposit large quantities of minute eggs in
foliage, where they are ingested by herbivorous sawfly and lepidopteran
larvae. This strategy is not unique, but trigonalids add a bizarre
wrinkle in that they are for the most part obligate hyperparasitoids,
attacking ichneumonid or tachinid larvae that are themselves parasitoids
of the insect that originally ingested the eggs (Murphy et al., 2009).
L. pullata has been reported both as a hyperparasitoid, and as facultatively employing a different stratagem—the one employed by the particular specimen I collected (Smith, 1996). Namely, it (and other trigonalids) may parasitize the
larvae of vespid wasps (including eumenines) that provision their nests
with caterpillars, infesting these hosts through inadvertent larval ingestion
of minute trigonalid larvae. Evidently, one should thoroughly chew one's
Goulet, H and Huber, J. T. (1993). Hymenoptera of the World: an Identification Guide to Families. Ottawa: Agriculture Canada.
J.; Ronquist, F.; Carpenter, J. M.; Hawks, D.; Schulmeister, S.;
Dowling, A. P.; Murray, D.; Munro, J.; Wheeler, W. C.; Schiff, N.; and
Sharkey, M. (2011). Evolution of the hymenopteran megaradiation. Molecular Phylogenetics & Evolution, 60, 73-88.
Hermes, M. G.; Araujo, G. and Antonini, Y. (2015). On the nesting biology of eumenine wasps yet again: Minixi brasilianum (de Saussure) is a builder and a renter… at the same time! (Hymenoptera, Vespidae, Eumeninae). Revista Brasileira de Entomologia, 59(2), 121-142. Retrieved 5/30/16 from http://www.sciencedirect.com/science/article/pii/S0085562615000424
Murphy, S. M.; Lill, J. T.; and Smith, D. R. (2009). A
scattershot approach to host location: uncovering the unique life
history of the trigonalid hyperparasitoid Orthogonalys pulchella
(Cresson). American Entomologist, 55, 82-87. Retrieved 5/29/16 from https://www.researchgate.net/publication/221959174_A_scattershot_approach_to_host_location_uncovering_the_unique_life_history_of_the_trigonalid_hyperparasitoid_Orthogonalys_pulchella_Cresson
Smith, D. R. (1996). Trigonalyidae (Hymenoptera) in the eastern United States: seasonal flight activity, distributions, hosts. Proceedings of the Entomological Society of Washington, 98(1), 109-118.