Foreign DNA acquisition by invertebrate genomes.

Recent studies have highlighted that the accidental acquisition of DNA from other species by invertebrate genomes is much more common than originally thought. The transferred DNAs are of bacterial or eukaryote origin and in both cases the receiver species may end up utilising the transferred genes for its own benefit. Frequent contact with prokaryotic DNA from symbiotic endocellular bacteria may predispose invertebrates to incorporate this genetic material into their genomes. Increasing evidence also points to viruses as major players in transferring genes and mobile elements between the species they infect. Unexpectedly a gene flux between Hymenoptera and Lepidoptera mediated by endogenous viruses of parasitic wasps has been recently unravelled, suggesting we are probably just seeing the tip of the iceberg concerning horizontal gene transfers in invertebrates. In the context of insect for feed and food, if the new technology of insect genome editing (such as Crisper/Cas9) were used to modify the genome of reared insects it is important to take into account the risk that an introduced gene can be transferred. More generally, although insects are traditionally consumed in Asia and Africa, knowledge on insect viruses is still limited rendering it difficult to predict the impact they might have in the context of insect rearing at an industrial scale.

Transfer of a chromosomal Maverick to endogenous bracovirus in a parasitoid wasp.

Bracoviruses are used by parasitoid wasps to allow development of their progeny within the body of lepidopteran hosts. In parasitoid wasps, the bracovirus exists as a provirus, integrated in a wasp chromosome. Viral replication occurs in wasp ovaries and leads to formation of particles containing dsDNA circles (segments) that are injected into the host body during wasp oviposition. We identified a large DNA transposon Maverick in a parasitoid wasp bracovirus. Closely related elements are present in parasitoid wasp genomes indicating that the element in CcBV corresponds to the insertion of an endogenous wasp Maverick in CcBV provirus. The presence of the Maverick in a bracovirus genome suggests the possibility of transposon transfers from parasitoids to lepidoptera via bracoviruses.

The few virus-like genes of Cotesia congregata bracovirus.

The origin of the symbiotic association between parasitoid wasps and bracoviruses is still unknown. From phylogenetic analyses, bracovirus-associated wasp species constitute a monophyletic group, the microgastroid complex. Thus all wasp-bracovirus associations could have originated from the integration of an ancestral virus in the genome of the ancestor of the microgastroids. In an effort to identify a set of virus genes that would give clues on the nature of the ancestral virus, we have recently performed the complete sequencing of the genome of CcBV, the bracovirus of the wasp Cotesia congregata. We describe here the putative proteins encoded by CcBV genome having significant similarities with sequences from known viruses and mobile elements. The analysis of CcBV gene content does not lend support to the hypothesis that bracoviruses originated from a baculovirus. Moreover, no consistent homology was found between CcBV genes and any set of genes constituting the core genome of a known free-living virus. We discuss the significance of the scarce homology found between proteins from CcBV and other viruses or mobile elements.