Rapid detection of silkworm microsporidia by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry.

Microsporidia cause the disease pébrine in silkworm and are known to be detrimental to sericulture and beekeeping. The microsporidian species Nosema bombycis was rapidly identified in silkworm (Bombyx mori) using matrix-assisted laser desorption/ionization time-of-flight mass spectrometry. Four types of microsporidian spores purified from infected silkworm could be distinguished based on the differences in their mass fingerprints. Microsporidia growing in a silkworm larva were also identified based on their mass spectra after rapid separation using filtration and centrifugation for 30 min.

Application of RT-PCR and MALDI-TOF MS for the detection of RNA luteovirus.

There is a need for rapid and less expensive methods to identify RNA viruses, including luteoviruses, for practical use in agriculture and quarantine. The mass spectrometric cleaved amplified polymorphic sequence (MS-CAPS) method, which detects enzymatically cleaved amplicons by matrix-assisted laser desorption/ionization mass spectrometry, was herein used together with a short RT-PCR to detect luteovirus in only 90 min. In addition, the matrixes 2',4',6'-trihydroxyacetophene and 3-hydroxypicolinic acid were compared for their effectiveness in the analysis of short single-stranded biotinylated DNA obtained by a MS-CAPS reaction.

Complete genome sequences of two iflaviruses from the brown planthopper, Nilaparvata lugens.

The complete genome sequences of two new iflaviruses (genus Iflavirus, family Iflaviridae) were determined. These viral sequences were first identified in RNA-seq contig sequences of Nilaparvata lugens in two distinct colonies: Izumo and Kagoshima. The accuracy of the contig sequences of the two viruses was verified by restriction enzyme digestion of RT-PCR products from viruliferous insects. RT-PCR of RNA extracted from honeydews after viruliferous insect feeding detected the expected viral products, which suggested that viruses were excreted into the honeydews by the insects. Since we previously designated a similar iflavirus as "Nilaparvata lugens honeydew virus 1", the two new viruses have been tentatively named "Nilaparvata lugens honeydew virus 2" and "Nilaparvata lugens honeydew virus 3". The identity of the putative amino acid sequences of the capsid proteins of these viruses met the criterion for iflavirus species demarcation. Therefore, these two viruses are suggested to be members of distinct species in the genus Iflavirus.

The genome sequence of pepper vein yellows virus (family Luteoviridae, genus Polerovirus).

The complete genome of pepper vein yellows virus (PeVYV) was sequenced using random amplification of RNA samples isolated from vector insects (Aphis gossypii) that had been given access to PeVYV-infected plants. The PeVYV genome consisted of 6244 nucleotides and had a genomic organization characteristic of members of the genus Polerovirus. PeVYV had highest amino acid sequence identities in ORF0 to ORF3 (75.9 - 91.9%) with tobacco vein distorting polerovirus, with which it was only 25.1% identical in ORF5. These sequence comparisons and previously studied biological properties indicate that PeVYV is a distinctly different virus and belongs to a new species of the genus Polerovirus.

The N-terminal region of an entomopoxvirus fusolin is essential for the enhancement of peroral infection, whereas the C-terminal region is eliminated in digestive juice.

The spindles of Anomala cuprea entomopoxvirus (AncuEPV), which are composed of glycoprotein fusolin, are known to enhance the peroral infectivity of AncuEPV itself and of nucleopolyhedroviruses. This has been demonstrated to involve the disruption of intestinal peritrophic membrane (PM), composed of chitin matrix, glycosaminoglycans, and proteins. To identify essential and nonessential regions for this enhancement activity, AncuEPV fusolin and its deletion mutants were expressed in Sf21 cells using a baculovirus system, and their enhancement abilities were analyzed. The recombinant fusolin enhanced the peroral infectivity of Bombyx mori nucleopolyhedrovirus up to 320-fold and facilitated the infection of host insect with AncuEPV. Deletion mutagenesis revealed that the N-terminal region (amino acids 1 to 253), a possible chitin-binding domain, is essential for the enhancement of infection, whereas the C-terminal region is entirely dispensable. The glycosylation-defective mutants N191Q, whose Asn(191) is replaced with Gln, and DeltaSIG, whose signal peptide is deleted, showed considerably reduced and abolished enhancing activities, respectively, indicating that the carbohydrate chain is important in the enhancing activity. Interestingly, the C-terminal dispensable region was digested by a serine protease(s) in insect digestive juice. Moreover, both the N-terminal conserved region and the carbohydrate chain were necessary not only for chitin binding but also for stability in digestive juice. A triple amino acid replacement mutant, IHE (Ile-His-Glu(161) to Ala-Ala-Ala), was stable in digestive juice and had chitin-binding ability but did not retain its enhancing activity. These results suggest that the enhancement of infectivity involves more than the tolerance to digestive juice and chitin-binding ability.

The genome sequence and transmission of an iflavirus from the brown planthopper, Nilaparvata lugens.

A previously unknown iflavirus has been identified in a laboratory colony of the brown planthopper, Nilaparvata lugens. The iflavirus-like sequence was first identified in contig sequences obtained from transcriptome sequencing (RNA-seq) of the brown planthopper. The complete viral genome was resequenced using the Sanger method. The positive-strand RNA genome was 10,937 nucleotides excluding the 3' poly(A) tail, and contained a single large open reading frame encoding coat proteins in the 5' region and replicases in the 3' region. Conserved motifs for coat proteins, helicase, cysteine protease, and RNA-dependent RNA polymerase were identified in the deduced amino sequence, and the estimated molecular mass of the large polyprotein was 358.6kDa. RT-PCR detection of the viral genome indicated that viral shedding occurred through the honeydews of insects in the infected colony. To test transmission, the collected honeydews were used to feed insects in a non-viruliferous colony. After 7 days, the expected RT-PCR fragment was detected in the insects, indicating that the virus can be transmitted horizontally. This is the first iflavirus identified in planthoppers; thus, we propose the name of the virus as Nilaparvata lugens honeydew virus-1.

[The toxicity of starfishes, Astropecten genus, inhabiting the coast of Toyama Bay].

Toxicity study was conducted using an official method (mouse assay) on 77 individual starfishes of the Astropecten genus collected in 5 sites inside Toyama Bay during the period from July 2002 to January 2003. Three kinds of starfishes were toxic, i.e., Astropecten polyacanthus, A. scoparius, and A. latespinosus meissner. Of A. polyacanthus. Those collected in the winter and spring were highly toxic, and there were regional differences in toxicity. The toxicity of A. latespinosus meissner, which inhibits only Himi, was less than that of A. polyacanthus. The toxicity of A. scoparius was weak. Toxic components were extracted and analyzed by LC/MS. Tetrodotoxin and related substances were confirmed to be present in all 3 kinds of starfishes.

Spindles of an entomopoxvirus facilitate its infection of the host insect by disrupting the peritrophic membrane.

The mode of action by which entomopoxvirus (EPV) spindles, proteinaceous crystalline bodies produced by EPVs, enhance EPV infection has not been clarified. We fed Anomala cuprea EPV (AcEPV) spindles to host insects; subsequent scanning electron microscopy revealed the disruption of the peritrophic membranes (PMs) of these insects. The PM is reportedly a barrier against the infection of some insects by viruses. Quantitative PCR of AcEPV DNA in the ectoperitrophic area revealed that PM disruption facilitated the passage of EPVs through the PM toward the initial infection site, the midgut epithelium. These results indicate that EPV spindles enhance infection by EPVs by disrupting the PM in the host insects. Fusolin is almost exclusively the constituent protein of the spindles and is the enhancing factor of the infectivity of nucleopolyhedroviruses (NPVs) and possibly that of EPVs. Spheroid is another type of proteinaceous crystalline structure produced by EPVs. Pseudaletia separata EPV (PsEPV) spheroids reportedly contain considerable amounts of fusolin and enhance NPV infection. We assessed the ability of AcEPV spheroids to enhance EPV infectivity and their effect on the PM and carried out immunological experiments; these experiments showed that AcEPV spheroids contain little or no fusolin and are biologically inactive, in contrasts to the situation in PsEPV.