Direct PCR‐based method for detecting Bursaphelenchus xylophilus,the pine wood nematode in wood tissue of Pinus massoniana

Pine wilt disease (PWD), caused by the pine wood nematode (PWN) Bursaphelenchus xylophilus, leads to serious losses to pine forestry around the world. Pinus massoniana, which is vulnerable to be attacked by the PWN, is the dominant species used in pine forestry in China. The objective of this study is to develop a direct PCR‐based method for detecting B. xylophilus in the wood of P. massoniana without a separate nematode extraction step. A simple procedure was first developed for isolating B. xylophilus DNA in 5 mg pine wood tissue samples harbouring PWN for detection by PCR amplification. A B. xylophilus‐specific amplicon of 403 bp (DQ855275) was generated by PCR from the infested wood tissue. The entire procedure can be completed within 5 h with one pair of primers. This assay can serve as a rapid, cheap and environmentally friendly method to detect B. xylophilus in samples of P. massoniana.     

Pine wilt disease: detection of the pinewood nematode (Bursaphelenchus xylophilus) as a tool for a pine breeding programme

The pinewood nematode (PWN), Bursaphelenchus xylophilus, is a serious quarantine pest first detected in Portugal and Europe in 1999. It is the causal agent of pine wilt disease (PWD). A resistance breeding programme has been initiated to contribute to control the evolution of the disease. Five hundred and four adult maritime pine, Pinus pinaster, trees were phenotypically selected as candidate trees for this programme from an area affected by PWD. To identify tolerance to the nematode, the selected trees were monitored monthly. Over the course of 1 year, 57 candidate trees died and were tested for the presence/absence of the PWN. As accuracy of detection is of major importance, an ITS‐PCR‐based method applied directly to wood from adult maritime pine trees was tested and compared with a standard morphological identification method. The results showed that the use of PCR to detect the pathogen provided more rapid and accurate results in comparison with the standard morphological identification. Thus, this method is suitable to be used in the survey of the breeding population for resistance/tolerance to PWD.     

Development of two reverse transcription‐PCR methods to detect living pinewood nematode,Bursaphelenchus xylophilus,in wood

Pinewood nematode, Bursaphelenchus xylophilus, is an inhabitant of native pine species of North America, where its presence in trees is non‐pathogenic. By contrast, the introduction of this nematode to forests overseas has devastated some pine stands and is recognized as a pest of phytosanitary concern by some countries' National Plant Protection Organizations. The ability to detect B. xylophilus in internationally traded wood products is crucial to reduce the spread of this organism. Current molecular techniques for the detection of B. xylophilus rely on the presence of genomic DNA and thus will detect both living and dead nematodes without differentiation. The detection of dead nematodes could lead to unnecessary trade disruption. Therefore, accurate techniques for the detection of and differentiation between live and dead B. xylophilus are critical. We have developed an endpoint RT‐PCR assay and a SYBR Green 1 real‐time RT‐PCR assay, both of which selectively identify living pinewood nematode by detecting the presence of Hsp70 mRNA as a viability marker. Both of these assays may help overcome or resolve disputes involving the detection of pinewood nematode at the port of entry and can also be used to evaluate the efficiency of wood treatment procedures.     

First record of Ektaphelenchoides pini associated with Ips sexdentatus on Pinus nigra laricio in Italy

In February 2015, an unexpected windstorm downed five hectares of a European black pine Pinus nigra subsp. laricio forest formation located close to Vallombrosa, Florence (Central Italy). In the following spring, an extensive survey was conducted in the area. Felled trees, stumps and all the suitable plant material were screened for the presence of the pinewood nematode (PWN), Bursaphelenchus xylophilus, by sampling wood and bark. Bark beetles were then collected from the gallery systems on the inner side of bark samples and observed in the laboratory. The following bark beetles were morphologically identified: Ips sexdentatus, Orthotomicus erosus, O. laricis and Pityogenes bidentatusa. The dissection of Ips sexdentatus allowed the extraction of numerous nematodes that were morphologically and molecularly identified as Ektaphelenchoides pini. Conversely, only few nematode specimens were isolated from either pine bark or wood. These individuals could be only molecularly identified and belonged to an undescribed nematode taxon. Even though no PWN was recorded in the investigated sites, our survey allowed the detection of a new association between E. pini and I. sexdentatus on P. nigra.     

Aseptic Bursaphelenchus xylophilus does not reduce the mortality of young pine tree

To assess the role of bacteria in pine wilt disease (PWD), aseptic M form (with a mucronated tail) and R form (with a round tail) of Bursaphelenchus xylophilus and B. mucronatus were obtained and compared, in terms of reproduction and pathogenicity, with non‐aseptic nematode. In addition, bacteria isolated from non‐aseptic nematodes and pine trees inoculated with non‐aseptic nematodes were identified. The results indicated that the bacteria associated with nematodes significantly lowered the reproduction of R form of B. xylophilus and B. mucronatus. Both the non‐aseptic and aseptic R forms of B. xylophilus induced death in all infected 7‐ to 8‐year‐old pine trees, while the non‐aseptic and aseptic M forms of B. xylophilus and B. mucronatus caused almost no plant mortality. High numbers of the non‐aseptic and aseptic R forms of B. xylophilus were distributed throughout the inoculated trees, while B. mucronatus and M form of B. xylophilus nematodes were lower in number and their distribution in stems limited within the inoculation site. Bacteria isolated from non‐aseptic nematodes were not recovered from the pine trees inoculated with these same kinds of nematodes. Two species of bacteria were both isolated from non‐aseptic B. mucronatus and from R form of B. xylophilus. Microbacterium trichotecenolyticum was common to both the control and inoculated pine trees. These results suggest that R form of B. xylophilus is the causal agent of PWD and that bacteria cannot increase the virulence of B. xylophilus and B. mucronatus.     

Insect vectors of the pinewood nematode: a review of the biology and ecology of Monochamus species

Pine wilt disease (PWD), caused by the pinewood nematode (PWN), Bursaphelenchus xylophilus (Steiner and Buhrer) Nickle 1970 , is a serious threat to susceptible pine forests of the world. The PWN is primarily vectored by Monochamus species (Coleoptera: Cerambycidae). The first occurrence of PWD was reported from Japan in the early 1900s. Following this report, Japanese scientists documented the community of bark‐ and phloem‐inhabiting insects associated with the nematodes in dying trees to determine possible vectors of the nematode. Monochamus alternatus was reported to be the most effective vector in Japan. The primary vector in North America is Monochamus carolinensis, and in Europe, it is Monochamus galloprovincialis. Further studies have been expanded through the nematode‐invaded countries of Korea, Taiwan, China and Portugal. There is an interspecific association between the PWN and its insect vectors, and it is an obligatory component of the disease cycle. It is crucial to understand this relationship as well as the population ecology of the beetle to aid in monitoring and control of this worldwide threat to pine forests. Studies to date indicate a remarkable similarity among beetle species around the globe for a variety of life‐history traits, including lifespan, adult emergence numbers, flight capability, nematode transmission rates and attraction to pine volatiles. Wherever pines are found, there is a beetle species capable of transmitting the nematode. Although flight performance and range is generally poor for this group of beetle vectors, the cryptic nature of the species and the lack of interest in the beetles by countries in the absence of the nematode have led to the disease establishing a foothold in a variety of countries such as Portugal. In this paper, studies conducted in different countries on Monochamus vector species of the PWN are compared and discussed.     

Long‐term survival and non‐vector spread of the pinewood nematode,Bursaphelenchus xylophilus,via wood chips

The pinewood nematode, Bursaphelenchus xylophilus, is the causal agent of pine wilt disease and is transmitted to new host trees by beetles of the genus Monochamus. The increasing interest in imported wood chips from North America for paper production and energy purposes and the corresponding phytosanitary risk of non‐vector transmission of B. xylophilus has been discussed since 1984, the year of the first interception of B. xylophilus in wood chips in the European Union. The long‐term survival of B. xylophilus in wood chips and its non‐vector spread from infested wood chips to non‐infested trees were studied. Pinus sylvestris logs were inoculated with a suspension of B. xylophilus to produce infested wood chips. During the long‐term storage test, B. xylophilus in P. sylvestris wood chips were examined. Four variants, including sealed and openly stored wood chips at both 15°C and 25°C, were studied. For the test of non‐vector spread, B. xylophilus ‐infested wood chips were placed on three‐ to four‐year‐old P. sylvestris saplings under different conditions. Bursaphelenchus xylophilus survived for more than 1 year at both temperatures in the sealed wood chips, which was significantly longer than for the openly stored variant at 25°C. Temperature, tree condition and wood chip location all influenced non‐vector spread through wood chips. Of the 480 trees that were in contact with infested wood chips and showed clear symptoms of pine wilt disease, B. xylophilus were extracted from 42 pines at 25°C and one pine at 15°C. The highest B. xylophilus infestation rates resulting in clear pine wilt disease symptoms (75%) were found in infested wood chips directly attached to stem‐wounded trees at 25°C. However, more variants exhibited B. xylophilus infestation at this temperature; trees with stem or root injuries plus direct contact with infested wood chips to the wounded part were primarily affected. Moreover, non‐vector spread was also detected in stem‐ and root‐injured pines without any direct contact with infested wood chips. Our results confirmed that B. xylophilus can survive for long periods in wood chips and can be transmitted from infested wood chips to damaged trees, but the likelihood of such PWN establishment should be low compared to spread through vectors. These findings must be considered in the pest risk analysis of B. xylophilus, and studies using outdoor trials should be carried out to complete this pest risk analysis.     

Within-tree distribution and attractant sampling of propagative pinewood nematode, Bursaphelenchus xylophilus: An early diagnosis approach

Early detection is of primary importance to enable rapid actions to prevent the spread and introduction of invasive species. The pinewood nematode (PWN), Bursaphelenchus xylophilus, a serious invasive and destructive species, is listed as a quarantine pest in the legislation of more than 40 countries. However, Baermann funnel extractions of wood from discs cut from trees at breast-height often do not detect the presence of PWN in infested trees. A serious consequence of such false negatives is the loss of the best window for implementation of eradication or quarantine measures to prevent establishment of incipient PWN infestations. Here we document the within-tree horizontal and vertical distribution of PWN in infested stands in China, using a newly developed kairomonal trapping technique. Our results provide a simple, effective, rapid and non-destructive sampling method that takes into account the changes of PWN within-tree distribution in relation to pine wilt disease (PWD) symptom development. When 60–80% of the foliage has become pale green, PWN is recovered from larger diameter branches. As disease symptoms progress, PWN moves into and down the trunk. As the needles turn yellow, PWN was recovered from the trunk at 1–2 m above the ground. The correlation between the within-tree distribution of PWN and the expression of symptoms indicated a strong association between the distribution of PWN and physiological and pathological changes that develop in attacked pines through the interaction between PWN and tree. This systematic sampling technique takes into account the within-tree distribution of the nematode and should greatly enhance early detection of PWN in field surveys, monitoring and phytosanitary inspections.     

An inoculation experiment of Japanese <Emphasis Type="Italic">Bursaphelenchus</Emphasis> nematodes on Japanese black and red pine, <Emphasis Type="Italic">Pinus thunbergii</Emphasis> and <Emphasis Type="Italic">P. densiflora</Emphasis>

The pinewood nematode (PWN) Bursaphelenchus xylophilus is an invasive pathogen that was introduced from North America to Asian countries and Portugal and is devastating native pine forests. Some native European and Asian Bursaphelenchus nematodes also have weak to moderate pathogenicity to native pine species. To evaluate the potential risk of native Bursaphelenchus species, we inoculated ten Japanese Bursaphelenchus species into native pine species (the dominant forest species) in Japan, and evaluated their pathogenicity using mortality and tracheal tissue damage as indices. Inoculation was conducted on August 3, 2007, and the symptoms were observed every 2 weeks until February 1, 2008. None of the inoculated trees, excluding the pathogenic PWN inoculated control, showed external disease symptoms; however, four species [a less pathogenic PWN isolate, B. luxuriosae, Bursaphelenchus sp. NK215 (undescribed), and NK224 (undescribed)] caused tracheal tissue damage in inoculated seedlings and showed weak pathogenicity. Therefore, we conclude that there are some potentially pathogenic native species of nematodes distributed in Japan. Interestingly, two of these weakly pathogenic species, B. luxuriosae and NK215, are not associated with Pinaceae trees, suggesting that nematode pathogenicity may be a pre-adaptive character. More experimental studies under different conditions are necessary to accurately evaluate the potential risk of these pathogens.     

Genetic diversity of pine‐parasitic nematodes Bursaphelenchus xylophilus and Bursaphelenchus mucronatus in China

The internal transcribed spacer (ITS) regions of rDNA have been routinely employed for identification and phylogenetic analysis of many nematode species. In this study, the intra‐ and interspecies ITS genetic diversity of Bursaphelenchus xylophilus and Bursaphelenchus mucronatus was evaluated. Ninety‐one isolates of the two nematode species collected from 14 Chinese provinces, Japan and Korea were used for ITS‐PCR and sequencing. An unweighted pair group cluster analysis dendrogram clustered them as two B. mucronatus and one B. xylophilus independent clades. Principal component analysis showed the phylogenetic relationship of the two nematode species more clearly; B. mucronatus isolates were separated into more than four groups, whereas B. xylophilus isolates still clustered into a group. The results of the Mantel test indicated the correlation of genetic distance matrices and geographic distance matrices was significant for both nematode species. The genetic differentiation coefficient (G_st) and gene flow (N_m) of B. mucronatus were 0.341 and 1.091, respectively, suggesting the importance of landscape heterogeneity and considerable obstacles for genetic exchange among B. mucronatus isolates in China. However, G_st and N_m of B. xylophilus were 0.188 and 2.151, respectively, very different compared to B. mucronatus. This could be owing to the short‐term introduction of B. xylophilus into China and a rapid spread through anthropogenic pathways. Our work adds to the understanding of the genetic diversity and genetic relationship of the two pine‐parasitic nematode species, and will aid in controlling them in the future.     

Identification and genetic analysis of the pinewood nematode Bursaphelenchus xylophilus from Pinus yunnanensis

In China, pinewood nematode (PWN), Bursaphelenchus xylophilus, was first discovered from Pinus thunbergii in 1982. Thus far, 14 species in the genus Pinus have been reported to be infected by PWN under natural conditions. Pinus yunnanensis, a pine species native to south‐western China, is considered a pioneer tree for barren hill afforestation in areas undergoing rocky desertification. In this study, we detected PWN in dead P. yunnanensis trees in Anlong County, Guizhou Province, China, using both morphological and molecular methods. To our knowledge, this is the first report of PWN from P. yunnanensis in China. To investigate the possible origin of this new outbreak, mitochondrial cytochrome oxidase gene subunit I and cellulase gene sequences were used to evaluate genetic relationships among worldwide PWN isolates. Phylogenetic tree and haplotype networks revealed that the Anlong isolate (BxChQAL008) sequence was identical to those of seven Chinese isolates collected from Sichuan, Chongqing, Zhejiang, Anhui and Shandong (372–1500 km from Anlong County), but different from the isolate BxChQZY030 collected from the same province (330 km from Anlong County). It is suggested, therefore, that more than one introduction of PWN into Guizhou Province has taken place. The Anlong isolate was likely introduced from neighbouring or more distant provinces rather than from outside China. Moreover, the absence of a correlation between geographic and genetic distance was observed using Mantel test analysis, providing evidence that human‐induced dispersal plays a fundamental role in the spread of the PWN in this region.     

Suppression of ectomycorrhizal development in young Pinus thunbergii trees inoculated with Bursaphelenchus xylophilus

In order to study the changes in ectomycorrhizal development during symptom expression of pine wilt disease, root window observations were conducted concurrent with measurements of leaf water potential as well as photosynthetic and transpiration rates of 5‐year‐old Pinus thunbergii trees that were inoculated with the pinewood nematode (PWN) Bursaphelenchus xylophilus. Infected trees were compared with girdled and uninfected control trees. Ectomycorrhizas developed constantly during the experimental period in control trees but did not develop in the girdled trees. Ectomycorrhizal development ceased within 2 weeks in those trees that finally died after PWN infection. In the trees that survived PWN infection, ectomycorrhizal development ceased within 1–4 weeks of inoculation but was resumed thereafter within 3–6 weeks. Ectomycorrhizal development ceased prior to a decrease in both photosynthetic rate and leaf water potential in the inoculated trees.     

Pathogenicity testing of four Bursaphelenchus species on conifer seedlings under greenhouse conditions

The pinewood nematode, Bursaphelenchus xylophilus (Steiner and Buhrer, J. Agric Res. 48, 1934, 949), Nickle (J. Nematol. 2, 1970, 375), is the causative agent of the pine wilt disease and causes serious damage to pine forests around the world. During a survey for the pinewood nematode, four other Bursaphelenchus species (Bursaphelenchus mucronatus, B. sexdentati, B. anamurius and B. vallesianus) were isolated from wilted pine trees in Turkey. To understand the effects of these Bursaphelenchus species on wilting of pine trees, a study was conducted under greenhouse conditions. Two‐year‐old seedlings of three pine species (Pinus nigra, P. brutia and P. pinea) and one cedar species (Cedrus libani) were used. Fifteen seedlings of each species were inoculated with nematodes and 10 seedlings of each species served as controls. The inoculum densities used for each seedling contained approximately 1000 (±100) nematodes of all life stages in 0.25 ml of distilled water. The first wilting symptoms were observed in the fifth week in all pine species but not in the cedar seedlings. All seeding mortality occurred between the 5th and 13th weeks of the study; no mortality was observed outside of this period. The most pathogenic nematode species was B. mucronatus, closely followed by the other species. The most susceptible seedling species was P. nigra, and C. libani was the most resistant species.     

Localized within‐ and between‐tree variation in nematode distribution during latent state of pine wilt disease makes the disease status cryptic

The pinewood nematode (PWN), Bursaphelenchus xylophilus, is the causal agent of pine wilt disease, an epidemic disease that has severely damaged pine forests in East Asia. The disease has spread to northern areas in Asia and parts of Europe. To prevent disease spread as the forefront of damage prevention, a better understanding of infection status is highly important. Not all infected trees show disease symptoms, and such asymptomatic PWN‐carrying trees are likely to be overlooked and can become a pathogen reservoir. To elucidate PWN infection status in asymptomatic trees, we performed PWN inspection of branches and trunks in 21 test trees in two different conditions: trees that had experienced PWN inoculation and those with suspected PWN infection that had experienced transient foliage discoloration. We detected PWNs in eight test trees (38%) and in 13 (1.5%) of a total of 843 samples. The difference in these percentages suggests that nematode inhabitation was highly localized within the trees, possibly owing to the restricted migration of PWNs. Our data demonstrated that trees that were once weakened but recovered their vigour can persist, as the asymptomatic carriers, in the forest. The implications for disease control are also discussed.     

A loop‐mediated isothermal amplification‐based method for detecting Bursaphelenchus xylophilus from Monochamus alternatus

The introduction of the pine wood nematode (PWN), Bursaphelenchus xylophilus, to new areas has impacted on the international economy. Therefore, accurate and reliable detection methods for PWN are essential for the control and management of this pest. A rapid and economic method for detecting PWN may be developed focusing on the PWN vector (Monochamus alternatus). This work standardized a loop‐mediated isothermal amplification (LAMP) method using newly designed primer sequences based on the syg‐2 gene, which encodes the synaptogenesis protein syg‐2. Loop‐mediated isothermal amplification was conducted at 63°C for 60 min using six sets of primers. The result was confirmed by visual observation. A positive reaction was confirmed by SYBR Green I fluorescence dye under light thermal cycling. The lower limit of DNA detection was 51.4 pg/μl in both LAMP and 51.4 ng/μl in PCR. Therefore, the LAMP was 1,000 times more sensitive in DNA detection than PCR. The LAMP is a relatively new, highly accurate and rapid molecular technique that can rapidly detect infectious agents in the field without requiring sophisticated instruments, giving a visually readable result. The method greatly improves detection, without requiring professional knowledge and expensive, sophisticated equipment. Therefore, this system is suitable for quarantine and field detection.     

First detection of Bursaphelenchus mucronatus (Nematoda: Aphelenchoididae) on Monochamus sutor (Coleoptera: Cerambycidae) in Romania

As a result of the detection of the pinewood nematode Bursaphelenchus xylophilus in Portugal, and its subsequent spread to Spain, intense surveys were conducted to screen for the presence of Bursaphelenchus species in Romania. Herein, we report recent surveys of insects potentially vectoring Bursaphelenchus species collected using trap trees or pheromone‐baited traps placed in the forest. Trap felled spruce trees (Picea abies) and pheromone‐baited traps were installed in six different counties in Romania (Bra?ov, Sibiu, Suceava, Hunedoara, Timi? and Dâmbovi?a). Ten different species of insects distributed among Curculionidae and Cerambycidae were obtained. Nematodes were extracted from insects and observed to validate the presence of Bursaphelenchus specimens. One female identified as Monochamus sutor was the only specimen carrying nematodes in the genus Bursaphelenchus. Nematodes were identified as B. mucronatus based on morphological and molecular features. This is the first detection and report of natural spread of B. mucronatus in Romania. The absence of B. xylophilus was confirmed in the areas of Romania surveyed in this work.     

Spatiotemporal analysis of pine wilt disease: Relationship between pinewood nematode distribution and defence response in Pinus thunbergii seedlings

Pine wilt disease is of major concern as it has destroyed pine forests in East Asia and Europe. Several studies have suggested that invasion by the pinewood nematode (PWN) Bursaphelenchus xylophilus, which causes this disease, evokes an excessive defence response in pine trees, resulting in tree death. However, few studies have quantitatively evaluated the correlation between PWN distribution and tree defence responses. Therefore, the present study aimed to quantify the number of PWNs and expression levels of putative pathogenesis‐related (PR) genes in different positions of Japanese black pine (Pinus thunbergii) seedlings over time. To quantify the number of PWNs in the seedlings, we used TaqMan quantitative real‐time PCR (qPCR) assay. During the early phase of infection, most PWNs were distributed around the inoculated sites, with only a small number being detected at distant sites, but the expression levels of PR genes were highly upregulated throughout the seedlings. Both the number of PWNs and expression levels of PR genes then increased drastically throughout the seedlings, all of which exhibited external symptoms. Thus, it appears that the rapid migration of PWNs induces a defence response throughout the seedling; however, this may not be effective in controlling these parasites, thereby ultimately leading to plant death.