In order to identify the specific antigens for pine wood nematode (PWN), we confirmed that one of the genes commonly found in the transcriptome, proteome and secretory proteins of PWN belonged to the Aldose Reductase (AR) family protein. 36.5 kDa PWN-AR1 was expressed and purified using Baculovirus Expression System. Total 1,546 hybridoma fusion library was generated and screened for specificity to PWN-AR1 by Enzyme Linked Immunosorbent assay (ELISA). Nine clones showed strong immunoreactivity to PWN-AR1 were limited-diluted. Total 864 limited-diluted clones were further screened using PWN-AR1 by ELISA and 34 monoclonal antibody (Mab) clones were selected. 34 Mab clones were further screened using PWN extracts and a standard PWN-infected pine tree extract by ELISA. Finally nine clones were selected and their immunoreactivities to 4 different nematodes were examined by ELISA. Seven clones pecifically recognized PWN while two clones recognized 4 nematodes. Our data suggested that PWN-AR1 is a PWN secretory enzyme while PWN is invading pine trees, Thus, PWN-AR1-Mabs could be used to develop diagnosis tools for PWN and its infected pine trees. (This work was supported by National Institute of Forest Science)

소나무재선충(Pine wood nematode, PWN)은 아시아와 유럽의 소나무류들에 침입하여 고사시키는 심각해 병원성 선충이다. 가장 완벽한 방제 방법은 감염목을 소각/분쇄의 방법으로 PWN 감염목을 제거하는 것이다. 현재 PWN의 다른 종과 차이를 가지는 유전자서열을 이용한 진단 방법이 다양하게 개발되어져서 실험실에서의 종 판명은 가능한 실정이다. 하지만, 대부분의 분자진단방법은 소나무 목편에서부터의 시료 추출, 그리고 분자진단 시약과 혼합하고, PCR을 이용하여 증폭을 진행 한 후, 결과를 확인하는 과정이 필요하다. 그러므로, 분자진단법을 현장에 적용하기 위해서는 향 후 많은 노력이 필요하다. 이에 반하여 항원/항체 반응을 이용한 진단 방법의 경우는 항원 추출 후, 일정량을 신속진단키트에 떨어 뜨려서 반응을 확인하는 과정을 거치므로, 전문적인 지식이나 기술이 필요하지 않다. 하지만, PWN과 PWN 감염목에 특이적인 항원이 밝혀지지 않은 상황이다. 최근에 우리는 PWN단백질 중에서 분비되는 Aspartic peptidase 1 (ASP1)을 항원으로 선정을 하고, 전장단백질을 Baculovirus Expression System으로 발현을 하였다. PWN-ASP1을 항원으로 단클론항체를 분비하는 세포 주를 확립하였다. 이러한 단클론항체는 향후, PWN의 소나무 침입에 관한 연구와 신속진단키트의 개발에 활용될 수 있을 것이다. (본 연구는 국립산림과학원의 연구비 지원으로 진행되었음)

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.

The pinewood nematode (PWN, Bursaphelenchus xylophilus) is known as a virulent factor of the pine wilt disease, transmitted to pinewoods by the pine sawyer beetle, Monochamus alternatus. It is very hard to discriminate B. xylophilus from B. mucronatus because these Bursaphelenchus species are genetically and biochemically very close. Therefore, it has been necessary to detect PWN-infected trees for the prevention of pine wilt disease transmission in a short time. We developed polyclonal antibodies against B. xylophilus in BalbC mice and primarily screened with ELISA. Positive clones releasing polyclonal antisera revealed B. xylophilus-specific immuno-reactivity, which were at least two times higher than that of B. mucronatus. Two clones, D9-F10 and 1F3, were finally selected and exhibited specific immuno-reactivity for B. xylophilus, not for B. mucronatus in Western blot analysis. D9-F10 clone was reactive with a 43-kDa whereas 1F3 clone with two proteins, 40- and 45-kDa. Their isotypes against mouse Ig family were identical, kappa-light chain. These results suggest that these monoclonal antibodies can be useful for the development of diagnostic kit for the pine wilt disease.

The pine sawyer beetle, Monochamus alternatus, transmits the pinewood nematode (PWN, Bursaphelenchus xylophilus), causing the pine wilt disease (PWD), which gives rise to enormously economic as well as forest damage. However, PWN has been identified as a pathogen of PWD, it is very difficult to discriminate B. xylophilus from B. mucronatus in a short time, which are genetically and morphologically very similar. Therefore, it has been necessary to detect and eliminate PWN-infected trees in the forest area for the prevention of PWD transmission. Up to date, there is no report on biomarkers such as DNA and protein for the diagnosis of B. xylophilus. In this study, we produced a B. xylophilus monoclonal antiserum (D9-F10) from BalbC mice and screened its specificity with various proteins extracts. Western blot analysis revealed that the D9-F10 is only reactive with B. xylophilus protein extract among other tested protein extracts, indicating that the D9-F10 is specific for a B. xylophilus protein. Furthermore, two-dimensional electrophoresis showed the D9-F10 detects a very highly acidic protein, pI≒3.5. These results suggest that the D9-F10 monoclonal antibody is useful for the development of a diagnostic kit for the pine wilt disease.

The pinewood nematode (PWN, Bursaphelenchus xylophilus) causes the pine wilt disease, transmitted to pinewoods by the pine sawyer beetle, Monochamus alternatus. It is very difficult to discriminate B. xylophilus from B. mucronatus. Therefore, it has been necessary to detect PWN-infected trees for the prevention of pine wilt disease transmission in a short time. The development of biomarkers such as DNA and protein is important for diagnosis of B. xylophilus. However, there have been no reports regarding biomarker identifications of B. xylophilus. In this study, polyclonal antisera were raised against whole proteins of B. xylophilus in BalbC mice and were primarily screened with ELISA. Twenty five among over 500 cell lines releasing polyclonal antisera revealed B. xylophilus-specific immuno-reactivity, which was at least three times higher than that of B. mucronatus. Three cell lines among them were secreting monoclonal antibody through further screening. These cell lines only detect about a 33-kDa protein in B. xylophilus in the western blot. These results suggest that these monoclonal antibodies will be useful for the development of diagnostic kit for the pine wilt disease.