Sylvaine Renault

Commensal and mutualistic relationships of reoviruses with their parasitoid wasp hosts

Abstract During evolution, certain endoparasitoid wasps have developed mechanisms to suppress the defence systems of their hosts. For this purpose, these species, all of which belong to the families Ichneumonidae and Braconidae, inject various kinds of virus-like particles. The most studied of these particles are classified as polydnaviruses (family Polydnaviridae) which are symbiotic viruses. Over the past decade, it has also been shown that several wasp species harbour reoviruses (family Reoviridae), and that two of these suppress host defence, allowing the development of the parasitoid eggs. In this paper, we summarize the key features of these viruses and their relationships with their wasp hosts. Five reoviruses are known that appear to be non-pathogenic for the wasps. Three of these, McRVLP, HeRV, OpRVLP, use their wasp hosts as vectors, and do not appear to be involved in host defence suppression. The fourth, DpRV-1, is a commensal reovirus detected in most field populations of the wasp, Diadromus pulchellus. This reovirus is always found associated with an ascovirus, DpAV-4a, which is indispensable for host immune suppression. Although DpRV-1 has not been shown to directly increase D. pulchellus parasitic success, it may contribute to this success by retarding DpAV-4a replication in the wasp. The fifth reovirus, DpRV-2, occurs in a specific population of D. pulchellus in which DpRV-1 and DpAV-4 are absent. This virus has a mutualistic relationship with its wasp host, as its injection by females during oviposition is essential for host immunosuppression. Interestingly, these viruses belong to several different reovirus genera.

Symbiotic Virus at the Evolutionary Intersection of Three Types of Large DNA Viruses; Iridoviruses, Ascoviruses, and Ichnoviruses

Background The ascovirus, DpAV4a (family Ascoviridae), is a symbiotic virus that markedly increases the fitness of its vector, the parasitic ichneumonid wasp, Diadromus puchellus, by increasing survival of wasp eggs and larvae in their lepidopteran host, Acrolepiopsis assectella. Previous phylogenetic studies have indicated that DpAV4a is related to the pathogenic ascoviruses, such as the Spodoptera frugiperda ascovirus 1a (SfAV1a) and the lepidopteran iridovirus (family Iridoviridae), Chilo iridescent virus (CIV), and is also likely related to the ancestral source of certain ichnoviruses (family Polydnaviridae). Methodology/Principal Findings To clarify the evolutionary relationships of these large double-stranded DNA viruses, we sequenced the genome of DpAV4a and undertook phylogenetic analyses of the above viruses and others, including iridoviruses pathogenic to vertebrates. The DpAV4a genome consisted of 119,343 bp and contained at least 119 open reading frames (ORFs), the analysis of which confirmed the relatedness of this virus to iridoviruses and other ascoviruses. Conclusions Analyses of core DpAV4a genes confirmed that ascoviruses and iridoviruses are evolutionary related. Nevertheless, our results suggested that the symbiotic DpAV4a had a separate origin in the iridoviruses from the pathogenic ascoviruses, and that these two types shared parallel evolutionary paths, which converged with respect to virion structure (icosahedral to bacilliform), genome configuration (linear to circular), and cytopathology (plasmalemma blebbing to virion-containing vesicles). Our analyses also revealed that DpAV4a shared more core genes with CIV than with other ascoviruses and iridoviruses, providing additional evidence that DpAV4a represents a separate lineage. Given the differences in the biology of the various iridoviruses and ascoviruses studied, these results provide an interesting model for how viruses of different families evolved from one another.

Effects of the Diadromus pulchellus ascovirus, DpAV-4, on the hemocytic encapsulation response and capsule melanization of the leek-moth pupa, Acrolepiopsis assectella

DpAV-4 is a symbiotic ascovirus found in natural populations of the solitary endoparasitoid wasp Diadromus pulchellus. The female wasp injects this virus into the pupae of the leek-moth Acrolepiopsis assectella during oviposition. The ascovirus replicates in the pupal tissues and the consequent lysis of the cells occurs synchronously with egg hatching and the development of the wasp larva. We show here that encapsulation and capsule melanization were activated when minute nylon monofilaments were implanted into the hemocoel of non parasitized leek-moth pupae and that encapsulation and melanization were inhibited in pupae parasitized by D. pulchellus. When the pupae were infected by DpAV-4, melanization of the nylon monofilaments was abolished, but a capsule was still always formed. These results indicate that DpAV-4 is a free virus able to alter the defence system of the parasitized host so as to improve the development of the parasitoid wasp, D. pulchellus.

Influence of FCGRT gene polymorphisms on pharmacokinetics of therapeutic antibodies

The neonatal Fc receptor (FcRn) encoded by FCGRT is known to be involved in the pharmacokinetics (PK) of therapeutic monoclonal antibodies (mAbs). Variability in the expression of FCGRT gene and consequently in the FcRn protein level could explain differences in PK observed between patients treated with mAbs. We studied whether the previously described variable number tandem repeat (VNTR) or copy number variation (CNV) of FCGRT are associated with individual variations of PK parameters of cetuximab. VNTR and CNV were assessed on genomic DNA of 198 healthy individuals and of 94 patients treated with the therapeutic mAb. VNTR and CNV were analyzed by allele-specific PCR and duplex real-time PCR with Taqman® technology, respectively. The relationship between FCGRT polymorphisms (VNTR and CNV) and PK parameters of patients treated with cetuximab was studied. VNTR3 homozygote patients had a lower cetuximab distribution clearance than VNTR2/VNTR3 and VNTR3/VNTR4 patients (p = 0.021). We observed no affects of VNTR genotype on elimination clearance. One healthy person (0.5%) and 1 patient (1.1%) had 3 copies of FCGRT. The PK parameters of this patient did not differ from those of patients with 2 copies. The FCGRT promoter VNTR may influence mAbs’ distribution in the body. CNV of FCGRT cannot be used as a relevant pharmacogenetic marker because of its low frequency.

Free serosal cells originating from the embryo of the wasp Diadromus pulchellus in the pupal body of parasitized leek-moth, Acrolepiosis assectella. Are these cells teratocyte-like?

In braconid species, teratocytes are derived from a serosal cell membrane which envelops the developing parasitoid embryo. On hatching, this membrane dissociates into individual cells, the teratocytes, which then circulate in the haemolymph of the host. We describe herein such a membrane, surrounding the embryo in eggs of the ichneumonid parasitoid wasp, Diadromus pulchellus. This membrane consisted of a single sheet of tightly packed cells with large 12+/-1.4 &mgr;m nuclei. These cells were released after hatching in vitro and cells of the same size were detected in vivo, in the vicinity of the D. pulchellus embryo. The number of nuclei detected suggests that the serosal membrane consists of about 450+/-150 cells. These cells did not grow after hatching of the parasitoid egg in the parasitized host, Acrolepiosis assectella, during the development of the parasitoid wasp larva. Southern blot experiments, using D. pulchellus satellite DNA or the ribosomal genes as probes, showed that free-living floating cells of wasp origin were present in the body of the parasitized host. This is the first time that free-floating teratocyte-like cells have been described in species of the Ichneumonidae.

Transposase-transposase interactions in MOS1 complexes: a biochemical approach.

Transposases are proteins that have assumed the mobility of class II transposable elements. In order to map the interfaces involved in transposase-transposase interactions, we have taken advantage of 12 transposase mutants that impair mariner transposase-transposase interactions taking place during transposition. Our data indicate that transposase-transposase interactions regulating Mos1 transposition are sophisticated and result from (i) active MOS1 dimerization through the first HTH of the N-terminal domain, which leads to inverted terminal repeat (ITR) binding; (ii) inactive dimerization carried by part of the C-terminal domain, which prevents ITR binding; and (iii) oligomerization. Inactive dimers are nonpermissive in organizing complexes that produce ITR binding, but the interfaces (or interactions) supplied in this state could play a role in the various rearrangements needed during transposition. Oligomerization is probably not due to a specific MOS1 domain, but rather the result of nonspecific interactions resulting from incorrect folding of the protein. Our data also suggest that the MOS1 catalytic domain is a main actor in the overall organization of MOS1, thus playing a role in MOS1 oligomerization. Finally, we propose that MOS1 behaves as predicted by the pre-equilibrium existing model, whereby proteins are found to exist simultaneously in populations with diverse conformations, monomers and active and inactive dimers for MOS1. We were able to identify several MOS1 mutants that modify this pre-existing equilibrium. According to their properties, some of these mutants will be useful tools to break down the remaining gaps in our understanding of mariner transposition.

Gustatory sensilla sensitive to protein kairomones trigger host acceptance by an endoparasitoid.

Proteins isolated from the host cocoon of Acrolepiopsis assectella (Lepidoptera: Yponomeutoidea) act as kairomones for host acceptance by the endoparasitoid wasp Diadromus pulchellus Wesmael (Hymenoptera: Ichneumonidae). In this study, morphological, ultrastructural and electrophysiological studies were carried out in order to identify the contact chemoreceptive sensilla on the parasitoid antennae that perceive the protein kairomones. Three types of sensillum on the antennae of the females were found to have a chemosensory function. The receptor cell(s) of one sensillar type were shown to give a positive electrophysiological response to protein kairomones. This sensillar type is apically multiporous and female specific. Consequently, this sensillum could be the one implicated in the perception of the protein kairomone that triggers the host–acceptance behaviour of D. pulchellus females.

Target Capture during Mos1 Transposition

Background: The target capture is a critical step for the selection of integration site. Results: Mos1 transposon excision occurred before target capture. The TA dinucleotide present in the target and bent targets are important for this step. Conclusion: Target capture mechanism and distribution of mariner elements are linked. Significance: New insights for modeling Mos1 target capture complex and better understanding of mariner transposition cycle. DNA transposition contributes to genomic plasticity. Target capture is a key step in the transposition process, because it contributes to the selection of new insertion sites. Nothing or little is known about how eukaryotic mariner DNA transposons trigger this step. In the case of Mos1, biochemistry and crystallography have deciphered several inverted terminal repeat-transposase complexes that are intermediates during transposition. However, the target capture complex is still unknown. Here, we show that the preintegration complex (i.e., the excised transposon) is the only complex able to capture a target DNA. Mos1 transposase does not support target commitment, which has been proposed to explain Mos1 random genomic integrations within host genomes. We demonstrate that the TA dinucleotide used as the target is crucial both to target recognition and in the chemistry of the strand transfer reaction. Bent DNA molecules are better targets for the capture when the target DNA is nicked two nucleotides apart from the TA. They improve strand transfer when the target DNA contains a mismatch near the TA dinucleotide.

In vitro recombination and inverted terminal repeat binding activities of the Mcmar1 transposase.

The Mcmar1 mariner element (MLE) presents some intriguing features with two large, perfectly conserved, 355 bp inverted terminal repeats (ITRs) containing two 28 bp direct repeats (DRs). The presence of a complete ORF in Mcmar1 makes it possible to explore the transposition of this unusual MLE. Mcmar1 transposase (MCMAR1) was purified, and in vitro transposition assays showed that it is able to promote ITR-dependent DNA cleavages and recombination events, which correspond to plasmid fusions and transpositions with imprecise ends. Further analyses indicated that MCMAR1 is able to interact with the 355 bp ITR through two DRs: the EDR (external DR) is a high-affinity binding site for MCMAR1, whereas the IDR (internal DR) is a low-affinity binding site. The main complex detected within the EDR contained a transposase dimer and only one DNA molecule. We hypothesize that the inability of MCMAR1 to promote precise in vitro transposition events could be due to mutations in its ORF sequence or to the specific features of transposase binding to the ITR. Indeed, the ITR region spanning from EDR to IDR resembles a MITE and could be bent by specific host factors. This suggests that the assembly of the transposition complex is more complex than that of those involved in the mobility of the Mos1 and Himar1 mariner elements.

RNA Viruses in Parasitoid Wasps

Publisher Summary This chapter describes the different RNA viruses that have been detected at least once in parasitoid wasps. It could be wondered whether the other families of parasitoids are really absent, or if this is due to the fact that inadequate techniques were used to detect viruses. In fact, several different methods have been used: TEM of the venom glands of females, extraction of nucleic acids, followed by DNAse digestion to eliminate the polydnavirus or ascovirus genome, RT-PCR with primers specific of RdRp or data mining in an EST library. To resolve this problem of detecting RNA viruses, a systematic search for viruses in parasitoids should be carried out using a combination of these different methods. Only a few hymenopteran species are known to be infected by RNA viruses, although thousands of species are known to carry polydnaviruses or VLPs. This could suggest that the presence of polydnaviruses or VLPs may block infections with other viruses.