Three acetylcholinesterases (ACEs) were identified from the pinewood nematode, Bursaphelenchus xylophilus, and named BxACE-1, BxACE-2, and BxACE-3. Sequence comparison with known ACEs in conjunction with three-dimensional structure analysis suggested that all BxACEs share typical characteristics of ACE but show some differences in the peripheral anionic site. BgACE-3 was most predominantly transcribed, followed by ACE-1 and ACE-2. Immunohistochemistry using anti-BxACEs antibodies revealed that BxACE-1 is most widely distributed whereas BxACE-2 exhibits more localized distribution in neuronal tissues. BxACE-3 was detected from entire body together with some limited tissues, and determined to be soluble. Kinetic analysis of in vitro expressed BxACEs revealed that BxACE-1 has the highest substrate specificity whereas BxACE-2 has the highest catalytic efficiency with BxACE-3 having the lowest catalytic efficiency. Interestingly, presence of BxACE-3 in the pool of BxACEs significantly reduced the inhibition of BxACE-1 and BxACE-2 by inhibitors. Knockout of BxACE-3 by RNAi significantly increased the toxicity of nematicides, supporting the protective role of BxACE-3 against these toxicants. Taken together, BxACE-1 appears to be the major ACE with the function of postsynaptic transmission whereas BxACE-3 has been evolved to acquire the function of chemical defense. BxACE-2 appears to play a role in post-synaptic transmission in specialized neurons.

Injection of nematicides such as emamectin benzonate and milbemectin is the most common practice to control the pinewood nematode, Bursaphelenchus xylophilus, in Korea. These macrocyclolactone nematicides, however, are expensive, limiting their practicability despite of high efficacy. In an attempt to screen affordable alternative organophosphate (OP) and carbamate (CB) nematicides, we identified and characterized three acetylcholinesterases (ACE, EC 3.1.1.7) from B. xylophilus and functionally expressed them using baculovirus system. In inhibition assay using 11 OPs and 3 CBs, all the three ACEs were highly inhibited by paraoxon, DDVP, chlorpyrifos-oxon and mevinphos of OPs and carbofuran and carbaryl of CBs but not inhibited well by the others. Interestingly, inhibition assay revealed that BxACE-3 is less sensitive to all insecticides tested than other two ACEs. In additional bioassay, chlorpyrifos, DDVP and parathion showed a high LC50 but all CBs tested did a very low mortality. The inhibition kinetic data and bioassay data obtained in this study should provide essential information for the development of OP-based nematicidal agents against B. xylophilus. Availability of expressed ACE will also facilitate the development of in vitro screening system to develop potential OP nematicides.

To determine differential gene expression profiles in the salivary gland of a water stick-insect, Ranatra chinensis Mayrt, a subtractive cDNA library was constructed by suppression subtractive hybridization. The salivary gland was determined among three salivary gland-like tissues by investigating transcription levels of five trypsin genes isolated from R. chinensis. The major transcripts encoding trypsins (64.4% of the total ESTs) were eliminated from the library and then remaining salivary gland-specific genes were searched. A total of 643 expressed sequence tags (ESTs) were clustered and assembled into 148 contigs (49 multiple sequences and 99 singletons), among which 35 contigs had matched BLASTx hits (E ≤ 1.00E-4). Salivary apyrase occupied 5.6% (36 ESTs) of the library. Apyrase is known to be released by female mosquitoes or blood-sucking assassin bugs to prevent blood clots during blood sucking. Therefore, apyrase in the salivary of R. chinensis might allow R. chinensis to facilitate feeding. Several contigs encoding acid phosphatase, hyaluronidase, prophenoloxidase, and dipeptidylpeptidase IV, commonly found in venoms of Hymenoptera, were also identified from the salivary gland-specific library. Discovery of salivary glandspecific genes should promote further studies on biologically active components in the saliva of R. chinensis.

The differences in the immune response between body lice, Pediculus humanus humanus, and head lice, Pediculus humanus capitis, were regarded as primary factors determining their differential vector competence. To find any differences in genetic components in immune system between body and head lice, whole genome sequences of head lice were determined by both SBS [sequencing by synthesis, Illumina Genome Analyzer (Illumina-GA)] and pyrosequencing (Roche GS FLX), and compared with the reference genome sequences of body lice. The short DNA reads from Illumina-GA (an average mapping depth of 50-fold) were aligned first to the body louse reference genome, to which Roche GS FLX DNA reads (an average depth of 2.5-fold) were subsequently assembled to make up gaps between mapped consensus. Total consensus showed a size of 114 Mb and a coverage of 96% of the published body louse genome sequences. From this head louse genome sequences, a total of 12,651 genes were predicted and used for comparing with the 10,775 genes previously reported from the body louse genome. The homolog analysis identified 873 head louse-specific genes and 422 body lice-specific genes. Comparison of immune response genes between both louse species showed head lice have more number of immune-related genes than body lice. Head lice were determined to possess all of the 107 immune-related genes reported in the previous study (Kim et al., 2011), suggesting that there is no difference in genetic make-up in terms of the 107 immune-related genes between body and head lice.

Venom allergen-like protein 2 (Vap2) was characterized from the pinewood nematode, Bursaphelenchus xylophilus, which is a destructive pathogen in several countries including Japan, China and Korea. Among three vaps of B. xylophilus (Bx-vap)reported in GenBank, Bx-vap2 showed the highest transcript level in both pine-grown propagative stage (PGPS) and media-grown propagative stage (MGPS). Bx-vap2 also was revealed that its transcript level over 10-fold increased in PGPS. In addition, western blot using BxVap2-polyclonal antibody showed that expression level of BxVap2 was significantly increased in PGPS. In immunohistochemistry, moreover, strong signals were detected around putative subventral gland in PGPS, whereas weak signals were observed in MGPS. These experimental results suppose pathogenic function of BxVap2 and migration assay using Bx-vap2 knock-down worms by RNA interference supports this postulation.

Bursaphelenchus xylophilus is known to be a major pathogen of the pine wilt disease (PWD). The pathogenecity of PWD is considered to be related to cell wall-degrading enzymes such as endoglucanases, expansins and pectate lyases (PELs). Two PELs, Bx-PEL1 and Bx-PEL2 are known to be expressed in B. xylophilus and regarded as a putative pathogenic factor. Recently, we developed stage-specific expressed tag library of B. xylophilus and identified a novel Bx-PEL3. We cloned Bx-PEL3 gene with RT-PCR, which showed high similarity to previously reported Bx-PELs. Phylogenetic analysis revealed that PEL3 was much closer to Bx-PELs than any other PELs. PEL3 has a conserved intron site as found in other Bx-PELs in the genomic DNA. Quantitative real-time PCR analysis revealed that Bx-PEL1 and Bx-PEL2 were more predominant in B. xylophilus than the Bx-PEL3. Recombinant Bx-PEL3 showed the activity for polgalacturonic acid and its physical conditions such as PH and Ca2+concentration for optimized activity were 9.0 and 0.5 mM, respectively. The localization of PEL3 transcript is the anterior body of B. xylophilus, near the esophageal gland. Taken together, these results suggest that a novel PEL3 gene is biochemically functional and can play a role as a putative pathogenic factor like other PELs.

Insects or insect remains found in beer are one of major issues in consumer claim. Accurate estimation of inflow time isa critical factor for the settlement of such claims related with beer-contaminating insects but no reliable methods have been developed. In an attempt to establish a molecular marker-based diagnostic method, the degradation rates of 18S rRNA genes in the insectssoaked in 500 ml beer were investigated by quantitative real-time PCR (qPCR) over one month period at room temperature. Among the six insect species tested, the house fly (Musca domestica) and honey bee (Apis mellifera) revealed high correlations (r2=0.974-0.990) between the degradation of 18S rRNA gene and inflow time. In these insects, statistically significant distinction was possible between the samples stored in beer less than 14 days and more than 14 days. Other insects, including the fruit fly, common house mosquito, German cockroach and Indian meal moth, displayed poor correlations, which appeared attributed to the inefficient genomic DNA extraction likely due to small sample size or disintegration of body parts during storage in beer. With proper improvement in DNA extraction, this 18S rRNA-based diagnostic method would be applicable for estimating the inflow time of beer-contaminating insects.

The cotton aphid, Aphis gossypii (Glover), is one of the most serious pest in seed potato and various vegetable cultivation. The imidacloprid resistant strain (IR) was over 200 fold more resistant to imidacloprid compared to the susceptible strain (S) as judged by the LC50 values and IR showed cross resistant to acetamiprid, thiamethoxam, thiacloprid, clothianidin. By using the suppression subtractive hybridization method, a imidacloprid resistant associated cDNA library was constructed in adult cotton aphid. In total 115 differentially expressed cDNA clones were obtained. Any point mutation detected in nicotinic acetylcholine receptor alpha 1~5 and beta 1 subunits in the IR. Based on IEF, the IR general esterase isozyme banding patterns were identical with that of S.

The pinewood nematode (PWN, Bursaphelenchus xylophilus) is known to be a major pathogen of the pine wilt disease (PWD). However molecular pathology of B. xylophilus is not completely understood, the pathogenecity of PWD is related to cell wall-degrading enzymes such as endoglucanases, expansins and pectate lyases (PELs). Recently, we developed stage-specific expressed tag library of B. xylophilus and identified a novel PEL, Bx-PEL3. We cloned Bx-PEL3 gene with RT-PCR, which showed high similarity to previously reported Bx-PELs. Phylogenetic analysis revealed that PEL3 was much closer to PELs of B. xylophilus than any other PELs. PEL3 has a conserved intron site as found in Bx-PEL2 in the genomic DNA analysis. Quantitative real-time PCR analysis revealed that Bx-PEL1 and Bx-PEL2 were more predominantly expressed than the Bx-PEL3 in B. xylophilus. The difference of expression level among Bx-PELs according to growth condition suggests that each Bx-PEL plays different biochemical role in the pathogenesis of the PWD.

Three acetylcholinesterases (AChEs) were identified from the pinewood nematode, Bursaphelenchus xylophilus. Sequence comparison with known AChEs in conjunction with three-dimensional structure analysis suggested that all BxAChEs share typical characteristics of AChE at the major catalytic structures. BgAChE3 was most predominantly transcribed and then followed by AChE1 and AChE2. Immunohistochemistry using anti-BxAChEs antibodies revealed that BxAChE1 is most widely distributed whereas BxAChE2 exhibits more localized distribution in neuronal tissues. BxAChE3 was detected from entire body together with some limited tissues, including mouth parts and alimentary lining, and determined to be the only soluble AChE, suggesting its localization in hemolymph or/and extracellular space. Kinetic analysis of in vitro expressed BxAChEs revealed that BxAChE1 has the highest substrate specificity whereas BxAChE2 has the highest catalytic efficiency with BxAChE3 having the lowest catalytic efficiency. Interestingly, presence of BxAChE3 in the pool of BxAChEs significantly reduced the inhibition of BxAChE1 and BxAChE2 by inhibitors. Knockout of BxAChE3 by RNAi significantly increased the toxicity of nematicides, suggesting the protective role of BxAChE3 against these toxicants. Based on several features, including tissue distribution, expression level, substrate kinetics and inhibition property, it appeared that BxAChE1 is the major AChE with the function of postsynaptic transmission whereas BxAChE3 has been evolved to acquire the function of chemical defense, perhaps intrinsically against secondary toxic compounds from host pine trees, such as α-pinene and limonene. BxAChE2 appears to play a role in post-synaptic transmission in specialized neurons but its detailed physiological function still remains to be elucidated.

There are increasing interests in developing methods specifically detecting pathogenic Bursaphelenchus xylophilus. In order to develop a detecting method for B .xylophilus, at first we generated monoclonal antibodies (MAbs) specific to B. xylophilus, discriminating from other pine tree resident nematodes. Among 2304 hybridoma fusions screened. We finally selected a MAb clone, 9F10 and used for further study. To identify the antigenic target of MAb-9F10, we employed several biochemical methods such as SDS-PAGE, 2 dimensional electrophoresis, anion exchange chromatography, and immunoprecipitation to separate and isolate an antigenic target. Proteins from above methods were analyzed via nano-LC-ESI-Q-IT-MS. Peptides of GaLECtin were always detected from several proteomic analyses, suggesting that GaLECtin is the antigenic target of MAb-9F10.

Three acetylcholinesterase (ace) genes were identified from Bursaphelenchus xylophilus and named as Bxace1, Bxace2 and Bxace3. Open reading fragments of Bxace1, Bxace2 and Bxace3 were composed of 622, 625 and 588 amino acids, respectively. Sequencing comparison with Torpedo ace gene identified cholinebinding site, catalytic triad functional site, three internal disulfide bonds and aromatic residues for the catalytic gorge. Transcriptional profiling by quantitative real-time PCR revealed that Bxace3 is more actively transcribed than Bxace1 (2-3 times) and Bxace2 (9-18 times) in both propagative and dispersal stages. The three ace genes were functionally expressed using baculovirus system. Kinetic analysis using three choline substrates demonstrated that BxAce2 has higher maximum velocity than BxAce1 (ca. 2 times) and BxAce3 (ca. 100 times) whereas BxAce3 shows lower Michaelis constant than BxAce1 (12.8 times) and BxAce2 (13.6 times). In inhibition assay using five organophosphates (OPs) and three carbamates (CBs), all the three BxAces were highly inhibited by paraoxon, DDVP and chlorpyrifos-oxon but not inhibited well by fenamiphos and fosthiazate. Interestingly, inhibition assay revealed that BxAce3 is less sensitive to all insecticides tested than other two BxAces. The inhibition kinetic data obtained in this study should provide essential information for the development of OP- and CB-based nematicidal agents againt B. xylophilus.

The pinewood nematode, Bursaphelenchus xylophilus (Steinner & Buhrer) Nickle, has two different life stages according to several environmental factors: dispersal stage and propagative stages. The dispersal stage is closely related to the migration to other host pines, whereas the propagative stage is coupled to the direct cause of pine wilt. To establish expressed sequence tag (EST) database of two life cycles of B. xylophilus, subtractive EST libraries were constructed using suppressed subtractive hybridization (SSH). From 3,072 and 3,840 sequences of dispersal- and propagative-specific stage cDNA libraries, 1,927 and 2,604 clusters were generated, respectively, which were annotated by BLASTx and Gene ontology (GO). A total of 1,112 (57.7%) and 1,215 (46.7%) clusters from the dispersal- and propagative-specific stage cDNA libraries respectively had the matched BLASTx hits (E≤10-2), among which 913 (47.4%) and 960 (36.9%) were classified into three categories in Gene ontology. From GO database, some respective stage-specific genes were searched and estimated the relative transcripts level according to stages using the quantitative real-time PCR.