Teratocytes (TCs) are the cells derived from the embryonic serosal membrane of some parasitic hymenopteran insects. As a parasitic factor, TCs are multifunctional in host regulation by inducing nutritional, immune, and developmental alterations. However, little is understood about their genetic constituents. This study reveals a comprehensive view of the genes expressed by TCs through a transcriptome analysis based on RNAseq technology. More than 6.29 Gb sequences were used to assemble 34,686 contigs (>200 bp) and annotated into different functional categories. The TC transcriptome profile was clearly distinct from those of hemocytes and the fat body. The TC transcriptome contained components of insulin signaling and biosynthesis of juvenile hormone and 20-hydroxyecdysone. TCs also expressed various groups of digestive enzymes, supporting its nutritional role for the growing parasitoid larvae in parasitism. Furthermore, this transcriptome analysis annotated two kinds of immunosuppressive serine protease inhibitors (serpins) and Rho GTPase-activating proteins (RhoGAPs). To determine the biological functions of these factors, we devised ex vivo RNA interference (RNAi) by conducting knockdown of gene expression in in vitro cultured TCs followed by injection of the treated TCs to test insects. Ex vivo RNAi revealed that some serpins and RhoGAPs expressed in TCs inhibited host cellular immunity. This study reports a transcriptome of the unique TC animal cell, and its immunosuppressive genetic factors using ex vivo RNAi technology.

An endoparasitoid wasp, Cotesia plutellae, parasitizes young larvae of the diamondback moth, Plutella xylostella, with its parasitic factors of polydnavirus, venom, ovarian proteins, and teratocytes (TC). TCs are originated from embryonic serosal membrane at hatch of C. plutellae eggs. TCs, after released in hemocoel of parasitized larvae, increased their average cell size from 20.6 μm to 77 μm during whole developmental period of the parasitoid larvae, but did not increase their cell number by maintaining about 150 cells per larvae. TCs of C. plutellae, are considered to be involved to extend the host larval development period and to arrest larval-pupal metamorphosis, were cultured in an insect cell culture medium for 21 days. Like TCs in parasitized larvae, in vitro cultured TCs showed increase in cell size, but did not show increase of cell number. Microinjection of in vitro cultured TCs significantly inhibited larva-to-pupa metamorphosis of nonparasitized P. xylostella, in which pupated host also showed extended larval period. Larvae injected with TCs exhibited alteration in expression of ecdysone receptor (EcR) and insulin receptor (InR) as well as in parasitized larvae. Teratocyte-secretory factors in culture medium showed this antimetamorphic effect on P. xylostella, while heat treated TC culture medium lost the effect. However, a successful parasitization of C. plutellae required both TCs and polydnavirus to alter host physiology.

Teratocytes are originated from embryonic serosal membrane of some endoparasitoid wasps. Cotesia plutellae eggs release teratocytes in parasitoid host hemocoel at hatch in about 150 cells per egg. Teratocytes of C. plutellae were cultured in an insect culture medium for at least 14 days. Teratocytes cultured in vitro showed no increase in cell numbers but increased in cell size. Similarly,teratocytes in parasitized larvae did not increase cell numbers, but increased their cell size. Microinjection of invitro cultured teratocytes in to third instar larvae of nonparasitized Plutella xylostella showed a dose-dependently inhibitory effect on development and larval-pupal metamorphosis. In addition, teratocytes prolonged the immature developmental period and reduced the pupation rate, in which young aged host larvae were more sensitive to teratocytes treatment than old larvae. These results suggest that teratocytes play a crucial role in successful parasitization of C.plutellae by altering host developmental program.