Transient expression of a viral histone H4 inhibits expression of cellular and humoral immune-associated genes in Tribolium castaneum

A viral histone H4 is encoded in a polydnavirus called Cotesia plutellae bracovirus (CpBV), which is symbiotic to an endoparasitoid wasp, C. plutellae. Compared to general histone H4s, the viral H4 possesses an extra N-terminal tail containing 38 amino acid residues, which has been presumed to control host gene expression in an epigenetic mode. To analyze the epigenetic control activity of CpBV-H4 on expression of immune-associated genes, it was transiently expressed in larvae of Tribolium castaneum that had been annotated in the immune genes from a full genome sequence. Subsequent alteration of gene expression pattern was compared with that of its mutant form deleting N-terminal tail (truncated CpBV-H4). In response to bacterial challenge, T. castaneum induces expression of 13 antimicrobial peptide (AMP) genes. When CpBV-H4 was expressed, the larvae failed to express 12 inducible AMP genes. By contrast, when truncated CpBV-H4 was transiently expressed, all AMP genes were expressed. Hemocyte nodule formation was significantly impaired by expression of CpBV-H4, in which expressions of tyrosine hydroxylase and dihydroxyphenylalanine decarboxylase were suppressed. However, expression of truncated CpBV-H4 did not give any significant adverse effect on the cellular immunity. The immunosuppression of CpBV-H4 was further supported by its activity of enhancing bacterial pathogenicity of an entomopathogenic bacterium, Xenorhabdus nematophila, against larvae transiently expressing CpBV-H4. These results suggest that CpBV-H4 suppresses both humoral and cellular immune responses of T. castaneum by altering a normal epigenetic control of immune-associated gene expression.     

IkB genes encoded in Cotesia plutellae bracovirus suppress an antiviral response and enhance baculovirus pathogenicity against the diamondback moth, Plutella xylostella

An endoparasitoid wasp, Cotesia plutellae, parasitizes larvae of the diamondback moth, Plutella xylostella, with its symbiotic polydnavirus, C. plutellae bracovirus (CpBV). This study analyzed the role of Inhibitor-kB (IkB)-like genes encoded in CpBV in suppressing host antiviral response. Identified eight CpBV-IkBs are scattered on different viral genome segments and showed high homologies with other bracoviral IkBs in their amino acid sequences. Compared to an insect ortholog (e.g., Cactus of Drosophila melanogaster), they possessed a shorter ankyrin repeat domain without any regulatory domains. The eight CpBV-IkBs are, however, different in their promoter components and expression patterns in the parasitized host. To test their inhibitory activity on host antiviral response, a midgut response of P. xylostella against baculovirus infection was used as a model reaction. When the larvae were orally fed the virus, they exhibited melanotic responses of midgut epithelium, which increased with baculovirus dose and incubation time. Parasitized larvae exhibited a significant reduction in the midgut melanotic response, compared to nonparasitized larvae. Micro-injection of each of the four CpBV genome segments containing CpBV-IkBs into the hemocoel of nonparasitized larvae showed the gene expressions of the encoded IkBs and suppressed the midgut melanotic response in response to the baculovirus treatment. When nonparasitized larvae were orally administered with a recombinant baculovirus containing CpBV-IkB, they showed a significant reduction in midgut melanotic response and an enhanced susceptibility to the baculovirus infectivity.     

An Evidence for Host Translation Inhibitory Factor Encoded in a Polydnavirus,Cotesia glomerata Bracovirus,Genome and Its Expression in Parasitized Cabbage White Butterfly,Pieris rapae

Polydnavirus is a DNA virus symbiotic to some endoparasitic wasps and plays a critical role in accomplishing successful parasitic life cycle of host wasps. Host translation inhibitory factor (HTIF) has been found in some polydnaviral genomes and performs parasitic functions leading to host immunosuppression and redirecting host nutrient usage to wasp development. The cabbage white butterfly, Pieris rapae, parasitized by a gregarious endoparasitoid, Cotesia glomerata, undergoes several physiological alterations including immune malfunctioning and failure of pupal metamorphosis. C. glomerata possesses its own symbiotic polydnavirus, C. glomerata bracovirus (CgBV). Its genome consisted of at least 12 segments in unequal amounts. Parasitized P. rapae hemolymph contained HTIF-like protein, which was determined through an immunoblotting assay using HTIF antibody of C. plutellae bracovirus (CpBV). RT-PCR using HTIF primers of CpBV produced an HTIF-like gene in P. rapae larvae parasitized by C. glomerata. Also, this HTIF-like gene was encoded in CgBV genome and its partial sequence of CgBV showed highly homology (98.5%) to amino acid sequence of an HTIF of CpBV, called CpBV15a. These results suggest that a common HTIF-like moiety may be shared among Cotesia-associated bracovirus.     

Transient expression of specific Cotesia plutellae bracoviral segments induces prolonged larval development of the diamondback moth, Plutella xylostella

A polydnavirus, Cotesia plutellae bracovirus (CpBV), possesses a segmented and dispersed genome that is located on chromosome(s) of its symbiotic endoparasitic wasp, C. plutellae. When the host wasp parasitizes larvae of the diamondback moth, Plutella xylostella, at least 27 viral genome segments are delivered to the parasitized host along with the wasp egg. The parasitized P. xylostella exhibits significant immunosuppression and a prolonged larval development. Parasitized larvae take about 2 days longer than nonparasitized larvae to develop until the wandering stage of the final larval instar, and die after egress of the full grown wasp larvae. Developmental analysis using juvenile hormone and ecdysteroid analogs suggests that altering endocrine signals could induce the retardation of larval developmental rate in P. xylostella. In this study we used a transient expression technique to micro-inject individual CpBV genome segments, and tested their ability to induce delayed larval development of P. xylostella. We demonstrated that a CpBV segment was able to express its own encoded genes when it was injected into nonparasitized larvae, in which the expression patterns of the segment genes were similar to those in the larvae parasitized by C. plutellae. Twenty three CpBV genome segments were individually cloned and injected into the second instar larvae of P. xylostella and their effects assessed by measuring the time taken for host development to the cocooning stage. Three CpBV genome segments markedly interfered with the host larval development. When the putative genes of these segments were analyzed, it was found that they did not share any common genes. Among these segments able to delay host development, segment S27 was predicted to encode seven protein tyrosine phosphatases (CpBV-PTPs), some of which were mutated by insertional inactivation with transposons, while other encoded gene expressions were unaffected. The mutant segments were unable to induce prolonged larval development of P. xylostella. These results suggest that CpBV can induce prolonged larval development of P. xylostella, and that at least some CpBV-PTPs may contribute to the parasitic role probably by altering titers of developmental hormones.     

Transient expression of a polydnaviral gene, CpBV15beta, induces immune and developmental alterations of the diamondback moth, Plutella xylostella

The diamondback moth, Plutella xylostella, parasitized by its endoparasitoid wasp, Cotesia plutellae, undergoes various physiological alterations which include immunosuppression and an extended larval development. Its symbiotic virus, C. plutellae bracovirus (CpBV), is essential for their successful parasitization with more than 136 putative genes encoded in the viral genome. CpBV15β, a CpBV gene, has been known to play significant role in altering host physiological processes including hemocyte-spreading behavior through inhibition of protein synthesis under in vitro conditions. In the current study, we investigated its specific involvement in physiological processes of the host by transient expression and RNA interference techniques. The open reading frame of CpBV15β was cloned into a eukaryotic expression vector and this recombinant CpBV15β was transfected into nonparasitized 3rd instar P. xylostella by microinjection. CpBV15β was expressed as early as 24 h and was consistent up to 72 h. Due to the expression of this gene, plasma protein levels were significantly reduced and the ability of the hemocytes to adhere and spread on extracellular matrix was inhibited, wherein CpBV15β was detectable in the cytoplasm of hemocytes based on an indirect immunofluorescence assay. To confirm the role of CpBV15β, its double stranded RNA could efficiently recover the hemocyte-spreading behavior and synthesis of plasma proteins suppressed by the transient expression of CpBV15β. In addition, the larvae transfected with CpBV15β significantly suffered poor adult development probably due to lack of storage proteins. Thus these results demonstrate the role of CpBV15β in altering the host physiological processes involving cellular immune response and metamorphic development, which are usually induced by wasp parasitization.     

Immunosuppression induced by expression of a viral RNase enhances susceptibility of Plutella xylostella to microbial pesticides

Abstract Polydnaviruses are a group of insect DNA viruses and are characterized in their segmented genome that is located in the chromosome(s) of host wasps. A polydnavirus, Cotesia plutellae bracovirus (CpBV), encodes a viral ribonuclease (RNase) T2 in a specific segment #3 (CpBV‐S3). This study tested its effect on gene expression associated with host immune responses in the diamondback moth, Plutella xylostella. Micro‐injection of CpBV‐S3 into nonparasitized larvae induced expression of its two encoded genes, CpBV‐ORF301 (=CpBV‐RNase T2) and CpBV‐ORF302. In response to a bacterial challenge, four antimicrobial peptide genes (hemolin, gloverin, cecropin and lysozyme) and six phenoloxidase (PO)–associated genes (proPO‐activating proteinase, PO, serine proteinase homolog and serpins 1–3) were up‐regulated in their expressions. However, the transient expression of CpBV‐S3 suppressed the expressions of cecropin, PO and serpin 1. Double‐stranded RNA specific to the viral RNase T2 could specifically knockdown the viral gene expression and restored the three gene expressions suppressed in the larvae injected with CpBV‐S3. The inhibitory activity of the viral RNase T2 on the target genes was further proven by the suppression of PO activation in response to bacterial challenge in the larvae injected with CpBV‐S3. This immunosuppression by the expression of the viral RNase T2 resulted in significant increase of pathogen susceptibility of P. xylostella against Bacillus thuringiensis or baculovirus infection.     

Baculoviral p94 homologs encoded in Cotesia plutellae bracovirus suppress both immunity and development of the diamondback moth,Plutellae xylostella

Polydnaviruses (PDVs) are a group of insect DNA viruses, which exhibit a mutual symbiotic relationship with their specific host wasps. Moreover, most encapsidated genes identified so far in PDVs share homologies with insect‐originated genes, but not with virus‐originated genes. In the meantime, PDVs associated with 2 wasp genera Cotesia and Glytapanteles encode some genes presumably originated from other viruses. Cotesia plutellae bracovirus (CpBV) encodes 4 genes homologous to baculoviral p94: CpBV‐E94k1, CpBV‐E94k2, CpBV‐E94k3, and CpBV‐E94k4. This study was conducted to predict the origin of CpBV‐E94ks by comparing their sequences with those of baculoviral orthologs and to determine the physiological functions by their transient expressions in nonparasitized larvae and subsequent specific RNA interference. Our phylogenetic analysis indicated that CpBV‐E94ks were clustered with other E94ks originated from different PDVs and shared high similarity with betabaculoviral p94s. These 4 CpBV genes were expressed during most developmental stages of the larvae of Plutella xylostella parasitized by C. plutellae. Expression of these 4 E94ks was mainly detected in hemocytes and fat body. Subsequent functional analysis by in vivo transient expression showed that all 4 viral genes significantly inhibited both host immune and developmental processes. These results suggest that CpBV‐E94ks share an origin with betabaculoviral p94s and play parasitic roles in suppressing host immune and developmental processes.     

The histone H4 acetyltransferase MOF uses a C2HC zinc finger for substrate recognition

Site-specific acetylation of histone H4 by MOF is central to establishing the hyperactive male X chromosome in Drosophila. MOF belongs to the MYST family of histone acetyltransferases (HATs) characterized by an unusual C₂HC-type zinc finger close to their HAT domains. The function of these rare zinc fingers is unknown. We found that this domain is essential for HAT activity, in addition to the established catalytic domain. MOF uses its zinc finger to contact the globular part of the nucleosome as well as the histone H4 N-terminal tail substrate. Point mutations that leave the zinc-finger structure intact nevertheless abolish its interaction with the nucleosome. Our data document a novel role of the C₂HC-type finger in nucleosome binding and HAT activity.     

Cotesia plutellae Bracovirus Genome and Its Function in Altering Insect Physiology

Polydnavirus is a group of animal DNA virus mutually associated with some ichneumonoid wasp. Its relatively large size of genome has been considered as a major source of the parasitoid function to manipulate developmental and immunological processes of target parasitized insects. Cotesia plutellae bracovirus (CpBV) is a polydnavirus derived from C. plutellae, which parasitizes the diamondback moth, Plutella xylostella. Parasitized P. xylostella exhibits altered physiological symptoms in development and immune reactions. Though several other parasitic factors such as ovarian proteins, venom, and teratocytes are identified, CpBV has been more focused on elucidating various host physiological alterations occurring due to the parasitism, which has driven the CpBV genome project. CpBV attains a typical bracovirus structure by its single unit membrane envelope, in which multiple nucleocapsids are enclosed. Its genome DNAs are segmented and located on the genome of C. plutellae. Its replication begins at adult tissue development during pupal stage. An apparent genome size is 471 kb estimated from 27 segments separated on 5% agarose gel. A current work on the genome has been completely sequenced 24 genomic segments and analyzed their genomic structure. The aggregated genome size is 351, 299 bp long and exhibits an average GC content of approximately 34.6%. Average coding density is about 32.3% and 125 putative open reading frames are predicted. Though more than half (52.5%) of predicted genes are annotated as hypothetical, the annotated CpBV genes share amino acid sequence homologies with those of other bracoviral genomes. The annotated genes are classified into the known bracoviral families, in which a family of protein tyrosine phosphatase is the largest including 36 ORFs, suggesting a significant role during parasitization. In addition, 8 and 7 ORFs encode Iκβ-like and EP1-like, respectively. Some predicted genes are known only in Cotesia-associated bracoviral genomes. Finally, two homologous genes, CpBV15α/β, are unique in CpBV genome, which are not matched to any other known polydnaviral genes. Their homology with malarian circumsporozoite toxin and eukaryotic translation inhibition factors suggests their function in host translation inhibitory factor. This review discusses CpBV genes on their putative physiological functions based on the molecular interactions between the host-parasite.     

Anti-cancer drug KP1019 modulates epigenetics and induces DNA damage response in Saccharomyces cerevisiae

KP1019 comprises a class of ruthenium compounds having promising anticancer activity. Here, we investigated the molecular targets of KP1019 using Saccharomyces cerevisiae as a model organism. Our results revealed that in the absence of the N-terminal tail of histone H3, the growth inhibitory effect of KP1019 was markedly enhanced. Furthermore, H3K56A or rtt109Δ mutants exhibit hypersensitivity for KP1019. Moreover, KP1019 evicts histones from the mononucleosome and interacts specifically with histone H3. We have also shown that KP1019 treatment causes induction of Ribonucleotide Reductase (RNR) genes and degradation of Sml1p. Our results also suggest that DNA damage induced by KP1019 is primarily repaired through double-strand break repair (DSBR). In summary, KP1019 targets histone proteins, with important consequences for DNA damage responses and epigenetics.     

RNA-dependent chromatin localization of KDM4D lysine demethylase promotes H3K9me3 demethylation

The JmjC-containing lysine demethylase, KDM4D, demethylates di-and tri-methylation of histone H3 on lysine 9 (H3K9me3). How KDM4D is recruited to chromatin and recognizes its histone substrates remains unknown. Here, we show that KDM4D binds RNA independently of its demethylase activity. We mapped two non-canonical RNA binding domains: the first is within the N-terminal spanning amino acids 115 to 236, and the second is within the C-terminal spanning amino acids 348 to 523 of KDM4D. We also demonstrate that RNA interactions with KDM4D N-terminal region are critical for its association with chromatin and subsequently for demethylating H3K9me3 in cells. This study implicates, for the first time, RNA molecules in regulating the levels of H3K9 methylation by affecting KDM4D association with chromatin.     

Parasitism of Cotesia spp. Enhances Susceptibility of Plutella xylostella to Other Pathogens

Two endoparasitoids, Cotesia plutellae and C. glomerata, parasitize the diamondback moth, Plutella xylostella, and induce significant host immunosuppression. This study analyzed the susceptibility changes of the parasitized P. xylostella against other pathogens using an entomopathogenic bacterium, Xenorhabdus nematophila (Xn), and a viral pathogen, Autographa californica nucleopolyhedrosis virus (AcNPV). The P. xylostella parasitized by either C. plutellae or C. glomerata exhibited higher susceptibilities to both microbial pathogens than the nonpara-sitized. To determine the parasitism factors inducing the enhanced susceptibility, three polydnaviral genes so far successfully cloned were selected from C. plutellae bracovirus (CpBV). CpBV-lectin and CpBV15 α/β were inserted into AcNPV under a CpBV promote and analyzed in their pathogenicities against P. xylostella larvae. Two AcNPVs recombined with CpBV15α/β were more potent than the control AcNPV recombined with an enhanced green fluorescent protein gene or the AcNPV recombined with CpBV-lectin. These results suggest that the wasp parasitization enhances other pathogen susceptibilities by inducing host immunosuppression, in which the symbiotic polydnavirus can play significant role in the enhanced susceptibility.