Cytoplasmic incompatibility in the semivoltine longicorn beetle Acalolepta fraudatrix (Coleoptera: Cerambycidae) double infected with Wolbachia.

Wolbachia are obligatory endosymbiotic α-proteobacteria found in many arthropods. They are maternally inherited, and can induce reproductive alterations in the hosts. Despite considerable recent progress in studies on the associations between Wolbachia and various taxonomic groups of insects, none of the researches have revealed the effects of Wolbachia on longicorn beetles as the host insect. Acalolepta fraudatrix is a forest longicorn beetle that is distributed in East Asia. In this study, the relationship between Wolbachia and A. fraudatrix was investigated. Out of two populations of A. fraudatrix screened for Wolbachia using the genes ftsZ, wsp, and 16S rRNA, only one of the populations showed detection of all three genes indicating the presence of Wolbachia. Electron microscopy and fluorescent in situ hybridization also confirmed that the A. fraudatrix population was infected with Wolbachia. Sequencing the wsp genes derived from single insects revealed that two strains of Wolbachia coexisted in the insects based on the detection of two different sequences of the wsp gene. We designated these strains as wFra1 and wFra2. The bacterial titers of wFra1 were nearly 2-fold and 3-fold higher than wFra2 in the testes and ovaries, respectively. The two strains of Wolbachia in the insects were completely eliminated by rearing the insects on artificial diets containing 1% concentration of tetracycline for 1 generation. Reciprocal crosses between Wolbachia-infected and Wolbachia-uninfected A. fraudatrix demonstrated that only eggs produced by the crosses between Wolbachia-infected males and Wolbachia-uninfected females did not hatch, indicating that Wolbachia infecting A. fraudatrix causes cytoplasmic incompatibility in the host insect. This is the first report showing the effect of Wolbachia on reproductive function in a longicorn beetle, A. fraudatrix.

Potential vector switching in the evolution of Bursaphelenchus xylophilus group nematodes (Nematoda: Aphelenchoididae).

To show the importance of vector switching of nematodes in the evolution of the Bursaphelenchus xylophilus group, we tested a hypothesis that "Bursaphelenchus doui (or its ancestor) was transferred by Acalolepta fraudatrix, Acalolepta sejuncta, and/or Monochamus subfasciatus (or their ancestral species) from broad-leaved trees to conifers, switched vectors from these cerambycid beetles to Monochamus beetles in conifers, and then evolved into the common ancestor of Bursaphelenchus mucronatus and B. xylophilus." We used a simple nematode-loading method to beetles and produced 20 binary combinations of five B. xylophilus group species and four cerambycid beetle species in the tribe Lamiini. The affinity of the nematodes for the beetles was examined based on phoretic stage formation of the nematodes. Phoretic stages of B. doui appeared in all beetle species examined, namely Acalolepta luxuriosa, Psacothea hilaris, A. fraudatrix, and Monochamus alternatus, although the affinity of the nematode for M. alternatus was weak. This finding indicates that B. doui could switch vectors to conifer-using Monochamus beetles after transfer by A. fraudatrix from broad-leaved trees to conifers. We conclude that vector switching of nematodes could have potentially happened during the evolutionary history of the B. xylophilus group.

Artificial induction of third-stage dispersal juveniles of Bursaphelenchus xylophilus using newly established inbred lines.

The pine wood nematode, Bursaphelenchus xylophilus, is the causal agent of pine wilt disease. This nematode has two developmental forms in its life cycle; i.e., the propagative and dispersal forms. The former is the form that builds up its population inside the host pine. The latter is specialized for transport by the vector. This form is separated into two dispersal stages (third and fourth); the third-stage dispersal juvenile (JIII) is specialized for survival under unfavorable conditions, whereas the fourth-stage juvenile (JIV), which is induced by a chemical signal from the carrier Monochamus beetle, is transported to new host pines and invades them. Because of its importance in the disease cycle, molecular and chemical aspects of the JIV have been investigated, while the mechanism of JIII induction has not been sufficiently investigated. In an effort to clarify the JIII induction process, we established inbred lines of B. xylophilus and compared their biological features. We found that the total number of nematodes (propagation proportion) was negatively correlated with the JIII emergence proportion, likely because nematode development was arrested at JIII; i.e., they could not develop to adults via the reproductive stage. In addition, JIII induction seemed to be regulated by a small number of genes because the JIII induction proportion varied among inbred lines despite the high homozygosity of the parental line. We also demonstrated that JIII can be artificially induced by the nematode's secreted substances. This is the first report of artificial induction of JIII in B. xylophilus. The dauer (dispersal) juvenile of the model organism Caenorhabditis elegans corresponds functionally to JIII of B. xylophilus, and this stage is known to be induced by a chemical signal referred to as daumone, derived from the nematodes' secretion. The artificial induction of JIII suggests the presence of daumone-like material in B. xylophilus.

Bacterial community associated to the pine wilt disease insect vectors Monochamus galloprovincialis and Monochamus alternatus.

Monochamus beetles are the dispersing vectors of the nematode Bursaphelenchus xylophilus, the causative agent of pine wilt disease (PWD). PWD inflicts significant damages in Eurasian pine forests. Symbiotic microorganisms have a large influence in insect survival. The aim of this study was to characterize the bacterial community associated to PWD vectors in Europe and East Asia using a culture-independent approach. Twenty-three Monochamus galloprovincialis were collected in Portugal (two different locations); twelve Monochamus alternatus were collected in Japan. DNA was extracted from the insects' tracheas for 16S rDNA analysis through denaturing gradient gel electrophoresis and barcoded pyrosequencing. Enterobacteriales, Pseudomonadales, Vibrionales and Oceanospirilales were present in all samples. Enterobacteriaceae was represented by 52.2% of the total number of reads. Twenty-three OTUs were present in all locations. Significant differences existed between the microbiomes of the two insect species while for M. galloprovincialis there were no significant differences between samples from different Portuguese locations. This study presents a detailed description of the bacterial community colonizing the Monochamus insects' tracheas. Several of the identified bacterial groups were described previously in association with pine trees and B. xylophilus, and their previously described functions suggest that they may play a relevant role in PWD.

Hydrogen Production from a Methanol-Water Solution Catalyzed by an Anionic Iridium Complex Bearing a Functional Bipyridonate Ligand under Weakly Basic Conditions.

An efficient catalytic system for the production of hydrogen from a methanol-water solution has been developed using a new anionic iridium complex bearing a functional bipyridonate ligand as a catalyst. This system can be operated under mild conditions [weakly basic solution (0.046 mol L(-1) NaOH) below 100 °C] without the use of an additional organic solvent. Long-term continuous hydrogen production from a methanol-water solution catalyzed by the anionic iridium complex was also achieved.

An entomoparasitic adult form in Bursaphelenchus doui (Nematoda: Tylenchomorpha) associated with Acalolepta fraudatrix.

The nematode family Aphelenchoididae (Rhabditida: Tylenchomorpha) includes species with various feeding habitats. Bursaphelenchus, a member of the family, has for a long time been considered as a home for plant parasitic or mycophagous species (or both). However, recent intensive biological studies on the family revealed that the genus contains several insect parasitic species. Dauer juveniles of Bursaphelenchus doui were isolated from Acalolepta fraudatrix during a field study of longhorn beetle-Bursaphelenchus nematode associations. Two different insect-associated forms, an "entomoparasitic adult form" and a regular dauer juvenile, were isolated from a single individual beetle in a subsequent laboratory investigation of the B. doui-A. fraudatrix relationship. Thus these 2 distinct, insect-associated forms were confirmed to occur simultaneously. The entomoparasitic form is morphologically similar to that of Bursaphelenchus luxuriosae, with a dome-shaped head and vacuole-like spots assumed to be an internal structure of sensory organ, a stylet, a metacorpus (median bulb), and a moderately-developed and seemingly fully functional reproductive system. It is distinguishable from B. luxuriosae based on male spicule morphology and female tail morphology. A degenerate ingestive-digestive system distinguishes the entomoparasitic form from the propagative form and, unlike dauer juveniles, it has a moderately-developed reproductive system. The presence of this characteristic parasitic adult form is known only in these 2 Bursaphelenchus species. However, these 2 species did not form a clear monophyletic clade within the Bursaphelenchus xylophilus group and, thus, this characteristic parasitic form may occur independently in each species.

A rapid and precise diagnostic method for detecting the Pinewood nematode Bursaphelenchus xylophilus by loop-mediated isothermal amplification.

ABSTRACT Bursaphelenchus xylophilus is the causal agent of pine wilt disease, which is a major forest disease in Japan, Korea, China, Taiwan, and Portugal. A diagnostic method which is rapid, precise, and simple could greatly help the proper management of this disease. Here, we present a novel detection method using loop-mediated isothermal amplification (LAMP) targeting the internal transcribed spacer region of ribosomal DNA of the nematode. Specificity of the primers and LAMP was confirmed using DNA from various nematode species related to B. xylophilus. Our experimental results suggest that LAMP can detect B. xylophilus faster and with higher sensitivity than the traditional diagnostic method. Moreover, because it does not require expensive equipment or specialized techniques, this LAMP-based diagnostic method has the potential to be used under field conditions.

Longicorn beetle that vectors pinewood nematode carries many Wolbachia genes on an autosome.

Monochamus alternatus is the longicorn beetle notorious as a vector of the pinewood nematode that causes the pine wilt disease. When two populations of M. alternatus were subjected to diagnostic polymerase chain reaction (PCR) detection of four Wolbachia genes, only the ftsZ gene was detected from one of the populations. The Wolbachia ftsZ gene persisted even after larvae were fed with a tetracycline-containing diet for six weeks. The inheritance of the ftsZ gene was not maternal but biparental, exhibiting a typical Mendelian pattern. The ftsZ gene titres in homozygotic ftsZ(+) insects were nearly twice as high as those in heterozygotic ftsZ(+) insects. Exhaustive PCR surveys revealed that 31 and 30 of 214 Wolbachia genes examined were detected from the two insect populations, respectively. Many of these Wolbachia genes contained stop codon(s) and/or frame shift(s). Fluorescent in situ hybridization confirmed the location of the Wolbachia genes on an autosome. On the basis of these results, we conclude that a large Wolbachia genomic region has been transferred to and located on an autosome of M. alternatus. The discovery of massive gene transfer from Wolbachia to M. alternatus would provide further insights into the evolution and fate of laterally transferred endosymbiont genes in multicellular host organisms.

The first report of a putative "entomoparasitic adult form" in Bursaphelenchus.

A putative "entomoparasitic adult form" of Bursaphelenchus luxuriosae was found in the tracheal system and body cavity of its cerambycid vector beetle, Acalolepta luxuriosa. Morphologically, this form is intermediate between the usual mycophagous adult and the phoretic dauer juvenile, i.e., it shares the primary and secondary reproductive features with the mycophagous phase but shares a degenerate digestive tract with JIV dauer juveniles. In addition, the "parasitic form" has specialized characters relative to the mycophagous phase analogous to dicyclic Hexatylina, e.g., vacuole-like dots (assumed to be sensory organs) at the anterior end, a very long vulval flap, conical female tail, and elongated male spicules. The presence of insect-parasitic juveniles has been reported in several Bursaphelenchus species, but this is the first confirmed report of a putative "entomoparasitic adult form" in the genus. Thus, the "parasitic adult form" of B. luxuriosae is hypothesized to be an autapomorphic character of this species in the genus. The physiological impact of the parasitism on the host beetle is assumed to be weak because no clear symptoms were observed in the infested beetles. Also, no nematode eggs or propagative juveniles were observed in the beetle host, suggesting that more research is needed to confirm the nature of the association (parasitic vs. endophoretic).

Haradamyces foliicola anam. gen. et sp. nov., a cause of zonate leaf blight disease in Cornus florida in Japan.

A fungus causing zonate leaf blight diseases in various evergreen and deciduous woody plant species in Japan was characterized by a discoid multicellular propagule arising from a hyaline sclerotium-like structure in the leaf tissue and dark-coloured microconidia produced enteroblastically from the terminal cells on the surface of the discoid propagules. Myrioconium-like microconidiophores also producing microconidia were occasionally produced in culture. No teleomorphic characteristics were observed on the fungus. Molecular analysis based on the partial nu-rDNA sequence data revealed that the fungus was phylogenetically related to the Sclerotiniaceae, Leotiomycetes, and Ascomycota. Because the morphology and sequence data of this fungus does not coincide with those of any known anamorphic fungi, Haradamyces foliicola is proposed here as a new anamorphic genus and species for this fungus.

First report of parthenogenesis in the genus Bursaphelenchus Fuchs, 1937: a description of Bursaphelenchus okinawaensis sp. nov. isolated from Monochamus maruokai (Coleoptera: Cerambycidae).

An evolutionarily interesting nematode, Bursaphelenchus okinawaensis sp. nov., is described and illustrated. The new species has several characteristic morphological traits, i.e., four lateral lines in both sexes, lack of a vulval flap in females, and a triangular spicule shape and stout P4 caudal papillae in males, and characteristic biological traits, including phoretic association with Monochamus maruokai, a species of longhorn beetle, parthenogenetic reproduction, and a high frequency of dauer production. Bursaphelenchus okinawaensis sp. nov. shares several important traits with various phylogenetic groups within the genus. The new species shares its spicule shape with B. hellenicus and B. hofmanni. It shares four lateral lines, P4 caudal papillar structure (size and position), and female vulval shape with the 'hunti' group, although it was molecularly inferred to be phylogenetically closer to the 'xylophilus' group and B. africanus. The autapomorphic traits of B. okinawaensis sp. nov. are parthenogenetic reproduction and high frequency of dauer production. All other nominal Bursaphelenchus nematodes have bisexual reproduction and tightly synchronized dauer production. The unique morphological and biological traits of B. okinawaensis sp. nov. suggest genetic flexibility within the genus. The importance of the morphology and arrangement of the caudal papillae is discussed relative to the phylogeny of the genus.

Expressed sequence tag (EST) analysis of the pine wood nematode Bursaphelenchus xylophilus and B. mucronatus.

Most Bursaphelenchus species feed on fungi that colonise dead or dying trees. However, Bursaphelenchus xylophilus is unique in that in addition to feeding on fungi it has the capacity to be a parasite of live pine trees. We present an analysis of over 13,000 expressed sequence tags (ESTs) from B. xylophilus and, by way of contrast, over 3000 ESTs from a closely related species that does not parasitise plants as readily; B. mucronatus. Four libraries from B. xylophilus, from a variety of life stages including fungal feeding nematodes, nematodes extracted from plants and dauer-like stage nematodes, and one library from B. mucronatus were constructed and used to generate ESTs. Contig analysis showed that the 13,327 B. xylophilus ESTs could be grouped into 2110 contigs and 4377 singletons giving a total of 6487 identified genes. Similarly the 3193 B. mucronatus ESTs yielded a total of 2219 identified genes from 425 contigs and 1794 singletons. A variety of proteins potentially important in the parasitic process of B. xylophilus and B. mucronatus, including plant and fungal cell wall degrading enzymes and a novel gene potentially encoding a expansin-like protein that may disrupt non-covalent bonds in the plant cell wall were identified in the libraries. Additionally several gene candidates potentially involved in dauer entry or maintenance were also identified in the EST dataset. The EST sequences from this study will provide a solid base for future research on the biology, pathogenicity and evolutionary history of this nematode group.

Cloning and characterization of pectate lyases expressed in the esophageal gland of the pine wood nematode Bursaphelenchus xylophilus.

Two pectate lyase genes (Bx-pel-1 and Bx-pel-2) were cloned from the pine wood nematode, Bursaphelenchus xylophilus. The deduced amino acid sequences of these pectate lyases are most similar to polysaccharide lyase family 3 proteins. Recombinant BxPEL1 showed highest activity on polygalacturonic acid and lower activity on more highly methylated pectin. Recombinant BxPEL1 demonstrated full dependency on Ca2+ for activity and optimal activity at 55 degrees C and pH 8 to 10 like other pectate lyases of polysaccharide lyase family 3. The protein sequences have predicted signal peptides at their N-termini and the genes are expressed solely in the esophageal gland cells of the nematode, indicating that the pectate lyases could be secreted into plant tissues to help feeding and migration in the tree. This study suggests that pectate lyases are widely distributed in plant-parasitic nematodes and play an important role in plant-nematode interactions.

A family of glycosyl hydrolase family 45 cellulases from the pine wood nematode Bursaphelenchus xylophilus.

We have characterized a family of GHF45 cellulases from the pine wood nematode Bursaphelenchus xylophilus. The absence of such genes from other nematodes and their similarity to fungal genes suggests that they may have been acquired by horizontal gene transfer (HGT) from fungi. The cell wall degrading enzymes of other plant parasitic nematodes may have been acquired by HGT from bacteria. B. xylophilus is not directly related to other plant parasites and our data therefore suggest that horizontal transfer of cell wall degrading enzymes has played a key role in evolution of plant parasitism by nematodes on more than one occasion.