Characterization of hitchhiker, a transposon insertion frequently associated with baculovirus FP mutants derived upon passage in the TN-368 cell line

Assessing the Impact of a Viral Infection on the Expression of Transposable Elements in the Cabbage Looper Moth (Trichoplusia ni)

Most studies of stress-induced transposable element (TE) expression have so far focused on abiotic sources of stress. Here, we analyzed the impact of an infection by the AcMNPV baculovirus on TE expression in a cell line (Tnms42) and midgut tissues of the cabbage looper moth (Trichoplusia ni). We find that a large fraction of TE families (576/636 in Tnms42 cells and 503/612 in midgut) is lowly expressed or not expressed at all [≤ 4 transcripts per million (TPM)] in the uninfected condition (median TPM of 0.37 in Tnms42 and 0.46 in midgut cells). In the infected condition, a total of 62 and 187 TE families were differentially expressed (DE) in midgut and Tnms42 cells, respectively, with more up- (46) than downregulated (16) TE families in the former and as many up- (91) as downregulated (96) TE families in the latter. Expression log2 fold changes of DE TE families varied from -4.95 to 9.11 in Tnms42 cells and from -4.28 to 7.66 in midgut. Large variations in expression profiles of DE TEs were observed depending on the type of cells and on time after infection. Overall, the impact of AcMNPV on TE expression in T. ni is moderate but potentially sufficient to affect TE activity and genome architecture. Interestingly, one host-derived TE integrated into AcMNPV genomes is highly expressed in infected Tnms42 cells. This result shows that virus-borne TEs can be expressed, further suggesting that they may be able to transpose and that viruses may act as vectors of horizontal transfer of TEs in insects.

Expression- and genomic-level changes during passage of four baculoviruses derived from bacmids in permissive insect cell lines

The baculovirus-based bacmid expression vector system has been widely used for protein production in basic research and biotechnological laboratories. Since the first construction of the Autographa californica multiple nucleopolyhedrovirus bacmid (AcBacmid), three more bacmids have been created from Bombyx mori nucleopolyhedrovirus (BmBacmid), Spodoptera exigua nucleopolyhedrovirus (SeBacmid) and Helicoverpa armigera nucleopolyhedrovirus (HaBacmid). Each of these bacmid-derived viruses replicates efficiently in a range of specific and permissive cell types. Here, we investigated the relative stability of each virus derived from the bacmid during passage in permissive cell lines through assessment of their expression level and genome structure changes. Using two different reporters, the expression levels of the viruses from the AcBacmid-Sf9, AcBacmid-Tn5, BmBacmid-BmN and SeBacmid-SeE1 bacmid-cell systems were significantly reduced after five passages of the viruses, whereas the reductions were not detected in the AcBacmid-Sf21 and HaBacmid-HzAM1 systems. Pulse field gel electrophoresis (PFGE) and restriction fragment length polymorphism (RFLP) analysis of viral DNA isolated from passaged viruses from the AcBacmid-Sf21 and HaBacmid-HzAM1 systems showed no major genomic changes. In contrast, the genomes from passaged viruses in the AcBacmid-Tn5 and AcBacmid-Sf9 systems displayed reduced genome size and various mutations at individual loci, including genotypes missing one at least or more viral RNA polymerase subunits and fp25k. These genotypic changes were correlated with reduced protein expression. RFLP analysis of viral DNA from passaged viruses in the BmBacmid-BmN and SeBacmid-SeE1 systems exhibited changes in genome size, including excision of particular EcoRI fragments containing the mini-F replicon. Collectively, our data suggest that the viruses from the AcBacmid-Sf21 and HaBacmid-HzAM1 bacmid-cell systems are better for large-scale protein expression in continuous culture. Further study is needed to investigate the mechanism(s) behind the protein expression reduction in these bacmid-derived virus/cell systems.

Impact of Lateral Transfers on the Genomes of Lepidoptera

Transfer of DNA sequences between species regardless of their evolutionary distance is very common in bacteria, but evidence that horizontal gene transfer (HGT) also occurs in multicellular organisms has been accumulating in the past few years. The actual extent of this phenomenon is underestimated due to frequent sequence filtering of "alien" DNA before genome assembly. However, recent studies based on genome sequencing have revealed, and experimentally verified, the presence of foreign DNA sequences in the genetic material of several species of Lepidoptera. Large DNA viruses, such as baculoviruses and the symbiotic viruses of parasitic wasps (bracoviruses), have the potential to mediate these transfers in Lepidoptera. In particular, using ultra-deep sequencing, newly integrated transposons have been identified within baculovirus genomes. Bacterial genes have also been acquired by genomes of Lepidoptera, as in other insects and nematodes. In addition, insertions of bracovirus sequences were present in the genomes of certain moth and butterfly lineages, that were likely corresponding to rearrangements of ancient integrations. The viral genes present in these sequences, sometimes of hymenopteran origin, have been co-opted by lepidopteran species to confer some protection against pathogens.

Removal of transposon target sites from the Autographa californica multiple nucleopolyhedrovirus fp25k gene delays, but does not prevent, accumulation of the few polyhedra phenotype

Low-cost, large-scale production of the baculovirus Autographa californica multiple nucleopolyhedrovirus (AcMNPV) using continuous insect cell culture is seriously hindered by the accumulation of AcMNPV mutants. Specifically, few-polyhedra (FP) mutants, with a reduced yield of occluded virus (polyhedra) and decreased infectivity, usually accumulate upon passaging in cell culture. FP mutations result from transposon insertions in the baculovirus fp25k gene, leading to significantly reduced levels of FP25K protein synthesis. This study evaluated the effects of removing the transposon insertion sites from the wild-type baculovirus fp25k gene; the mutated virus was denoted Ac-FPm. Specifically, this study involved a detailed comparison of wild-type (WT) AcMNPV and Ac-FPm with regard to the proportion of cells having polyhedra, number of polyhedra per cell, the fraction of empty polyhedra, number of occlusion-derived viruses per polyhedron, number of nucleocapsids in the nuclei, FP25K protein synthesis and genetic analysis of the fp25k gene. Removal of TTAA transposon insertion sites from the fp25k gene stabilized FP25K protein synthesis and delayed the appearance of the FP phenotype from passage 5 to passage 10. Electron micrographs revealed that more virus particles were found inside the nuclei of cells infected with Ac-FPm than in the nuclei of cells infected with WT AcMNPV (at passage 10). Abnormalities, however, were observed in envelopment of nucleocapsids and virus particle occlusion within Ac-FPm polyhedra. Thus, the FP phenotype appeared in spite of continued FP25K protein synthesis, suggesting that mechanisms other than fp25k gene disruption can lead to the FP phenotype.

Role of the silkworm argonaute2 homolog gene in double-strand break repair of extrachromosomal DNA

The argonaute protein family provides central components for RNA interference (RNAi) and related phenomena in a wide variety of organisms. Here, we isolated, from a Bombyx mori cell, a cDNA clone named BmAGO2, which is homologous to Drosophila ARGONAUTE2, the gene encoding a repressive factor for the recombination repair of extrachromosomal double-strand breaks (DSBs). RNAi-mediated silencing of the BmAGO2 sequence markedly increased homologous recombination (HR) repair of DSBs in episomal DNA, but had no effect on that in chromosomes. Moreover, we found that RNAi for BmAGO2 enhanced the integration of linearized DNA into a silkworm chromosome via HR. These results suggested that BmAgo2 protein plays an indispensable role in the repression of extrachromosomal DSB repair.

The mariner Transposons Belonging to the irritans Subfamily Were Maintained in Chordate Genomes by Vertical Transmission

Mariner-like elements (MLEs) belong to the Tc1-mariner superfamily of DNA transposons, which is very widespread in animal genomes. We report here the first complete description of a MLE, Xtmar1, within the genome of a poikilotherm vertebrate, the amphibian Xenopus tropicalis. A close relative, XlMLE, is also characterized within the genome of a sibling species, Xenopus laevis. The phylogenetic analysis of the relationships between MLE transposases reveals that Xtmar1 is closely related to Hsmar2 and Bytmar1 and that together they form a second distinct lineage of the irritans subfamily. All members of this lineage are also characterized by the 36- to 43-bp size of their imperfectly conserved inverted terminal repeats and by the -8-bp motif located at their outer extremity. Since XlMLE, Xlmar1, and Hsmar2 are present in species located at both extremities of the vertebrate evolutionary tree, we looked for MLE relatives belonging to the same subfamily in the available sequencing projects using the amino acid consensus sequence of the Hsmar2 transposase as an in silico probe. We found that irritans MLEs are present in chordate genomes including most craniates. This therefore suggests that these elements have been present within chordate genomes for 750 Myr and that the main way they have been maintained in these species has been via vertical transmission. The very small number of stochastic losses observed in the data available suggests that their inactivation during evolution has been very slow.

Replication, integration, and packaging of plasmid DNA following cotransfection with baculovirus viral DNA

Infection-dependent replication assays have been used to identify numerous putative origins of baculovirus replication. However, plasmid DNA, when cotransfected into insect cells with Autographa californica multinucleocapsid nucleopolyhedrovirus (AcMNPV) DNA, replicates independently of any viral sequence in cis (11). Cotransfection of transfer plasmids and baculovirus DNA is a common procedure used in generating recombinant viruses and in measuring the level of gene expression in transient-expression assays. We have examined the fate of a series of vector plasmids in cotransfection experiments. The data reveal that these plasmids replicate following cotransfection and the replication of plasmid DNA is not due to acquisition of viral putative origin sequences. The conformation of plasmid DNA replicating in the cotransfected cells was analyzed and found to exist as high-molecular-weight concatemers. Ten to 25% of the replicated plasmid DNA was integrated into multiple locations on the viral genome and was present in progeny virions following serial passage. Sequence analysis of plasmid-viral DNA junction sites revealed no homologous or conserved sequences in the proximity of the integration sites, suggesting that nonhomologous recombination was involved during the integration process. These data suggest that while a rolling-circle mechanism could be used for baculovirus DNA replication, recombination may also be involved in this process. Plasmid integration may generate large deletions of the viral genome, suggesting that the process of DNA replication in baculovirus may be prone to generation of defective genomes.

Phenotypic and genetic analysis of Lymantria dispar nucleopolyhedrovirus few polyhedra mutants: mutations in the 25K FP gene may be caused by DNA replication errors

We previously demonstrated that polyhedron formation (PF) mutants arise at a high frequency during serial passage of the Lymantria dispar nucleopolyhedrovirus (LdMNPV) in the L. dispar 652Y cell line (J. M. Slavicek, N. Hayes-Plazolles, and M. E. Kelly, Biol. Control 5:251-261, 1995). Most of these PF mutants exhibited the traits of few polyhedra (FP) mutants; however, no large DNA insertions or deletions that correlated with the appearance of the FP phenotype were found. In this study, we have characterized several of the PF mutants at the phenotypic and genetic levels. Genetic techniques were used to group the mutations in the LdMNPV PF mutants to the same or closely linked genes. Wild-type viruses were recovered after coinfection of L. dispar 652Y cells with certain combinations of PF mutants. These viruses were analyzed by restriction endonuclease analysis and found to be chimeras of the original PF mutants used in the coinfections. Marker rescue experiments localized the mutations in one group of PF isolates to the region containing the LdMNPV 25K FP gene. The mutations in these PF mutants were identified. Four of five of the LdMNPV FP mutants contain small insertions or deletions within the 25K FP gene. The fifth LdMNPV FP mutant analyzed contained a large deletion that truncated the C terminus of the 25K FP gene product. All of the deletions occurred within the same potential hairpin loop structure, which had the lowest free energy value (most stable hairpin) of the five potential hairpin loop structures present in the 25K FP gene. One of the insertion mutants contained an extra base within a repetitive sequence. These types of mutations are likely caused by errors that occur during DNA replication. The relationship between the types of mutations found within the LdMNPV 25K FP gene and DNA replication-based mutagenesis is discussed.