Effects of parasitization by Cotesia congregata on the brain-prothoracic gland axis of its host, Manduca sexta.

The ability of prothoracic glands (PTGs) from parasitized and unparasitized Manduca sexta 5th-instars to respond to ecdysiotropic extracts prepared from day-5 5th instar brains was compared. An in vitro bioassay revealed that PTGs from parasitized animals were much less responsive to brain PTTH than glands from unparasitized larvae. However, when incubated in Grace's medium in the absence of brain extract, glands from day-3 and -4 hosts remained active for a much longer period of time than did those dissected from their unparasitized counterparts. Rather than exhibiting reduced (basal) levels of synthesis after the 3rd hour of incubation, glands from these parasitized larvae continued to synthesize/release ecdysteroid into the medium at relatively high rates. The timing of this enhanced secretory activity is coincident with the ecdysteroid peak that occurs just prior to and during wasp emergence. Following parasite emergence, gland activity decreased, and by the third day after emergence, was reduced to low levels. Results suggest that the requirement for PTTH to stimulate ecdysteroid production has been bypassed, i.e. that the parasite has uncoupled the normal mechanisms that permit brain regulation of PTG activity. The ability of brains from parasitized M. sexta to stimulate PTGs from unparasitized day-2 5th instars was also examined. Dose-response analyses performed for the first 7 days of the 5th instar showed that on a per brain basis ecdysiotropic activity in brains from parasitized and unparasitized animals was similar. However, when differences in brain size were considered, ecdysiotropic activity appeared to be more concentrated in brains from day-7 parasitized larvae than in brains from similarly aged unparasitized larvae. Analysis of the size distribution of the ecdysiotropic activity in brains from parasitized larvae revealed a unique form that was larger than the 29kDa standard. This suggests that parasitization may inhibit neuropeptide processing, particularly during the final stages preceding emergence of the wasps from the host. Thus, both an inhibition of prothoracicotropic hormone processing and the inability to respond to this neurohormone may contribute to the developmental arrest characteristic of parasitized 5th instars.