Relationship between soil properties and incidence of pine wilt disease at stand level

This study was conducted to evaluate and compare soil properties between pine stands either damaged or undamaged by pine wilt disease in Jinju and Sacheon Cities, which are areas in Korea severely affected by the disease. Soil physical and chemical properties were generally similar between damaged and undamaged pine stands. There was no significant difference in soil factors related to soil nutrient fertility between damaged and undamaged pine stands, although the incidence of pine wilt disease was affected by soil clay content, which was significantly (P < 0.05) higher in the damaged (24.8%) than in the undamaged (20.1%) pine stands. However, this relationship should be treated with caution because small scale topographical variation may simply reflect the incidence of pine wilt disease. The results suggest that incidence of pine wilt disease was not influenced by soil nutrient properties at a small stand scale.     

东亚地区夏季干旱、强台风事件与松树枯萎病的关系

松树枯萎病的发生和流行给东亚的日本、中国和韩国带来了不小的损失,引起许多国家的重视. 本文应用实地观测和气象数据分析等方法,研究了东亚地区松树枯萎病的发生和流行特点,以及与灾害气象事件之间的关系.结果表明: 在日本、中国和韩国,持续的夏季干旱少雨和强台风等极端气象事件能够诱发松树枯萎.在极端干热的环境中,松树常出现能量代谢失调, 以至于受胁迫的松树整株枯萎;而在低温多雨的年份,松树枯萎少,甚至没有发生枯死现象.在松材线虫及其媒介昆虫侵染之前,松树的活力业已下降.松树枯萎病似乎应该局限在台风频发和持续干热的地区.在自然环境优越、少有台风和干热事件出现且没有不当扩大松树栽培范围的地区,松树枯萎病大面积发生的可能性不大.     

Response of soil microbial communities to changes in a forest ecosystem brought about by pine wilt disease

Japan has suffered a lot from forestry losses due to pine wilt disease caused by pinewood nematode infestations. Studies were conducted regarding its causative agent and the effects of natural vegetation succession after pine wilt disease, but its effects on microorganisms were not given equal attention. This study determined the effects of pine wilt disease on light conditions, soil microbial biomass, litter decomposition, microbial abundance and the physical and chemical properties of the soil. Results showed that in a forest currently affected by pine wilt disease, there was higher light penetration, greater microbial biomass carbon, and a faster rate of litter decomposition. Microbial abundance was shown to be reduced in pine wilt affected areas. There were close correlations between the biological and physicochemical properties of the soil, but the reason for the decrease in microbial abundance is not yet well understood, and thus requires further study.     

松材线虫病发生点格局及影响因素

松材线虫病在中国大陆造成了巨大的生态与经济价值损失,南方地区尤为严重,分析松材线虫病空间分布、量化环境因素对其发生的影响对于松材线虫病的防控整治具有重要意义。本研究以江西省赣州市南康区松材线虫病为研究对象,采用核平滑密度、Ripley’s K函数、点过程模拟等空间点格局分析方法,探讨了区域松材线虫病发生的空间格局及其对环境变量的响应。结果表明: 研究区松材线虫病的发生不是随机分布,而是存在显著的空间聚集区。地形因子、植被因子和人类活动因子是影响松材线虫病空间异质性分布的主要因素。空间点格局分析表明,海拔、坡度、距最近道路距离、道路密度、距最近居民点距离、郁闭度和植被类型对松材线虫病的发生具有重要影响。在森林病害管理中,除了加强因人类活动引起病害传播源的管控外,还应该考虑地形、植被类型等特征进行松材线虫病害的综合预警监测。     

Development of secondary pine forests after pine wilt disease in western Japan

Abstract. The development of secondary Pinus densiflora (Japanese red pine) forests after pine wilt disease was studied through phytosociological analysis, estimation of forest structure before disease and size-structure, tree ring and stem analyses. Following the end of the disease, the growth of previously suppressed small oak trees was accelerated. This is quite different from the development of forests following fire, which starts with the establishment of pine seedlings. Pine wilt disease shifted the dominance of secondary forests from Pinus densiflora to Quercus serrata oak forest. In pine forests, disturbance by fire is important for forest maintenance. In contrast, disturbance by pine wilt disease leads to an acceleration of succession from pine forest to oak forest.     

Succession of secondary forests affected by pine wilt disease in western Japan followed on vegetation maps

Abstract. Succession, changes in the distribution pattern of forest vegetation, and Pinus forest survival following pine wilt disease were clarified based on phytosociological analysis and vegetation maps. Survival of Pinus forests was restricted to the early successional stages, which were located on ridges and the upper part of slopes. Subsequent to pine wilt disease, the succession progressed from early to late substages of Pinus forest, mixed deciduous and evergreen Quercus, to evergreen Quercus forest. Succession occurs in abandoned pine forests which apparently are in a bad state and are vulnerable to attacks by pine wilt disease.     

松树萎蔫的成因与控制策略

已报道的松树萎蔫枯死类型有多种,它们之间存在内在的联系,其发生及严重与否涉及多种生态因子,是立地环境、感病松树、媒介昆虫、病原线虫、病原微生物综合作用的结果,基于生态学的可持续有害生物管理应是防治松树萎蔫的有效途径。     

化学通讯在松材线虫侵染和扩散中的作用

松材线虫为外来入侵种 ,由其引起的松材线虫病正在我国迅速扩散蔓延 ,造成我国部分地区松林资源的毁灭性破坏。松材线虫病的发生和流行与媒介天牛、寄主植物、共生真菌和细菌密切相关 ,松材线虫 -墨天牛 -松树 -共生微生物之间存在着广泛的化学联系 ,它们通过化学互作 ,调控松材线虫的行为 ,影响松材线虫的侵染和扩散     

Regeneration of different plant functional types in a Masson pine forest following pine wilt disease

Pine wilt disease is a severe threat to the native pine forests in East Asia. Understanding the natural regeneration of the forests disturbed by pine wilt disease is thus critical for the conservation of biodiversity in this realm. We studied the dynamics of composition and structure within different plant functional types (PFTs) in Masson pine forests affected by pine wilt disease (PWD). Based on plant traits, all species were assigned to four PFTs: evergreen woody species (PFT1), deciduous woody species (PFT2), herbs (PFT3), and ferns (PFT4). We analyzed the changes in these PFTs during the initial disturbance period and during post-disturbance regeneration. The species richness, abundance and basal area, as well as life-stage structure of the PFTs changed differently after pine wilt disease. The direction of plant community regeneration depended on the differential response of the PFTs. PFT1, which has a higher tolerance to disturbances, became dominant during the post-disturbance regeneration, and a young evergreen-broad-leaved forest developed quickly after PWD. Results also indicated that the impacts of PWD were dampened by the feedbacks between PFTs and the microclimate, in which PFT4 played an important ecological role. In conclusion, we propose management at the functional type level instead of at the population level as a promising approach in ecological restoration and biodiversity conservation.     

松萎蔫病发生区和未发生区油松根部真菌群落研究

植物根部真菌群落结构和多样性与植物的抗病性和病害的危害程度相互影响。为揭示松萎蔫病与松树根部真菌群落的相互作用,该研究对陕西省商洛市柞水县松萎蔫病发生区和未发生区油松的根尖活性、根部外生菌根真菌(ECMF)和深色有隔内生真菌(DSE)的侵染率进行分析,并通过油松根部可培养真菌的分离和鉴定,分析了两地油松根部真菌的群落结构及多样性。结果显示:(1)松萎蔫病未发生区油松根部的活性根尖比、菌根根尖比和ECMF的侵染率均显著高于发生区,而DSE的侵染率和微菌核密度却低于松萎蔫病发生区,ECMF的侵染率在两个样区油松根部都显著高于DSE。(2)从两个样区油松根部共分离到131个菌株,根据形态和分子学特征最终鉴定为23种真菌,其中DSE占绝对优势,且Phialocephala fortinii和Cryptosporiopsis ericae为油松根部分离真菌的优势种。(3)两个样区真菌的群落组成存在明显差异,共有真菌仅5种。(4)松萎蔫病未发生区真菌群落的丰富度(17)和多样性(2.012 0)、以及ECMF的相对丰度(8%)都高于松萎蔫病发生区(分别为11、1.197 9和1.6%),而DSE的相对丰度(70%)却明显低于发生区(82.7%)。研究表明,松萎蔫病的发生影响了油松根部的活性、菌根的形成、ECMF和DSE的侵染,以及根部真菌的群落组成和多样性。该文首次报道了DSE与松萎蔫病的关系,但分离真菌对油松松萎蔫病抗性的影响有待进一步研究。     

Using an evapo-transpiration model (ETpN) to predict the risk and expression of symptoms of pine wilt disease (PWD) across Europe

The pine wood nematode (PWN) Bursaphelenchus xylophilus is the causal agent of pine wilt disease (PWD), a xylem restricting disease of pine trees. PWN, a native of North America where it very rarely kills native pine trees, has spread internationally killing host trees in China, Japan, Korea, Taiwan and Portugal, with isolated incursions into Spain. Based on the locations where tree mortality has been recorded, it appears that pine trees growing in hot, dry conditions are more susceptible to pine wilt disease. This paper describes the ETpN model, an evapo-transpiration model (previously developed by Forest Research), which has been modified to incorporate the presence of PWN inside a tree and which predicts the regions of Europe that are likely to succumb to PWD. ETpN acts independently of the vector beetle (Monochamus spp.), predicting the likelihood of PWD on the assumption that a tree in a particular region has already been infested by the pine wood nematode. Different regions across Europe are included to investigate and demonstrate how different climates affect PWD incidence significantly. Simplified, “lite” and latency models have been developed to allow a non-specialist user to determine respectively the risk of PWD at a particular location and the likelihood of delays (latency) in expression of wilt symptoms.     

History of Pine Wilt Disease in Japan

Pine wilt disease induced by the pinewood nematode, Bursaphelenchus xylophilus, is a great threat to pine forests in Japan. The first occurrence of the disease was reported in Nagasaki, Kyushu. During the 1930s the disease occurrence was extended in 12 prefectures, and in the 1940s the disease was found in 34 prefectures. The annual loss of pine trees increased from 30,000 m³ to 1.2 million m³ during these two decades. The enormous increase in timber loss in the 1970s resulted in 2.4 million m³ of annual loss in 1979. The affected area expanded into 45 prefectures of 47 prefectures in Japan. In cool areas the disease differs in epidemiology from that in heavily infested areas in the warm regions. A national project for controlling pine wilt disease lays special emphasis on the healthy pine forests predominating throughout cool areas in northern Japan.     

Bursaphelenchus xylophilus: opportunities in comparative genomics and molecular host-parasite interactions

Most Bursaphelenchus species are fungal feeding nematodes that colonize dead or dying trees. However, Bursaphelenchus xylophilus, the pine wood nematode, is also a pathogen of trees and is the causal agent of pine wilt disease. B. xylophilus is native to North America and here it causes little damage to trees. Where it is introduced to new regions it causes huge damage. The most severely affected areas are found in the Far East but more recently B. xylophilus has been introduced into Portugal and the potential for damage here is also high. As incidence and severity of pine wilt disease are linked to temperature we suggest that climate change is likely to exacerbate the problems caused by B. xylophilus and, in addition, will extend (northwards in Europe) the range in which pine wilt disease can occur. Here we review what is currently known about the interactions of B. xylophilus with its hosts, including recent developments in our understanding of the molecular biology of pathogenicity in the nematode. We also examine the potential developments that could be made by more widespread use of genomics tools to understand interactions between B. xylophilus, bacterial pathogens that have been implicated in disease and host trees.     

Pathogenic cellulase assay of pine wilt disease and immunological localization

The pine wilt disease caused by Bursaphelenchus xylophilus (BX), also known as the pine wood nematode (PWN), is the most devastating disease of pine trees. In this work, a high molecular weight B. xylophilus cellulase antigen (BXCa) was purified from total homogenates of nematodes. BXCa was found to be able to hydrolyze carboxymethyl cellulose (CMC) efficiently (155.65 U/mg) and to have an approximate molecular mass of 58.9 kDa. We harvested anti-BXCa antibodies and performed immunocytochemical assays, which revealed the localization of cellulase pools in the esophageal gland cells of the PWN. It was also discovered that cellulase was secreted from the stylet and was used to hydrolyze cellulose to facilitate the PWN entering host cells. These results are consistent with other plant parasitical nematodes. Interestingly, strong fluorescence signals from cellulase staining were observed in tracheid cells in naturally infected pine wood, in addition to ray cells and the resin canal zone. These results strongly suggest that the cellulase released by the PWN is one of the pathogenic substances of pine wilt disease and is responsible for the development of the early symptoms of the disease.     

Using the nematophagous fungus Esteya vermicola to control the disastrous pine wilt disease

The present study evaluated the protective effects of the nematophagous fungus Esteya vermicola on the large pine trees of Mt. Wora, Jinju, South Korea for six years. When pine trees were treated with E. vermicola 110 days before artificial normal pinewood nematode (PWN) infection, 30–50% of the trees survived for six years. When pine trees were treated with E. vermicola one week after artificial normal PWN infection, 40% of the trees were saved. In contrast, all of the control trees were killed by pine wilt disease in the first year. Although it has been more than six years since the beginning of this experiment, the existence of E. vermicola inside the treated pine trees was successfully detected using a PCR method with two pairs of specific primers for E. vermicola. These results suggest that E. vermicola possesses great potential as a biocontrol agent to combat the disastrous pine wilt disease. This is the first report of using nematophagous fungi to control pine wilt disease in the field for a duration of over five years.     

Pathogenic Cellulase Assay of Pine Wilt Disease and Immunological Localization

The pine wilt disease caused by Bursaphelenchus xylophilus (BX), also known as the pine wood nematode (PWN), is the most devastating disease of pine trees. In this work, a high molecular weight B. xylophilus cellulase antigen (BXCa) was purified from total homogenates of nematodes. BXCa was found to be able to hydrolyze carboxymethyl cellulose (CMC) efficiently (155.65 U/mg) and to have an approximate molecular mass of 58.9 kDa. We harvested anti-BXCa antibodies and performed immunocytochemical assays, which revealed the localization of cellulase pools in the esophageal gland cells of the PWN. It was also discovered that cellulase was secreted from the stylet and was used to hydrolyze cellulose to facilitate the PWN entering host cells. These results are consistent with other plant parasitical nematodes. Interestingly, strong fluorescence signals from cellulase staining were observed in tracheid cells in naturally infected pine wood, in addition to ray cells and the resin canal zone. These results strongly suggest that the cellulase released by the PWN is one of the pathogenic substances of pine wilt disease and is responsible for the development of the early symptoms of the disease.     

Pathogenicity of aseptic Bursaphelenchus xylophilus

Pine wilt is a disease of pine (Pinus spp.) caused by the pine wood nematode (PWN), Bursaphelenchus xylophilus. However, the pathogenic mechanism of pine wilt disease (PWD) remains unclear. Although the PWN was thought to be the only pathogenic agent associated with this disease, a potential role for bacterial symbionts in the disease process was recently proposed. Studies have indicated that aseptic PWNs do not cause PWD in aseptic pine trees, while PWNs associated with bacteria cause wilting symptoms. To investigate the pathogenicity of the PWN and its associated bacteria, 3-month-old microcuttings derived from certain clones of Pinus densiflora Siebold & Zucc. produced in vitro were inoculated under aseptic conditions with aseptic PWNs, non-aseptic PWNs and bacteria isolated from the nematodes. Six-month-old aseptic P. densiflora microcuttings and 7-month-old P. massoniana seedlings were also inoculated under aseptic conditions with aseptic PWNs and non-aseptic PWNs. The results showed that the aseptic microcuttings and seedlings inoculated with aseptic PWNs or non-aseptic PWNs wilted, while those inoculated with bacterial isolates did not wilt. Nematodes were recovered from wilted microcuttings and seedlings inoculated with aseptic PWNs and non-aseptic PWNs, and the asepsis of nematodes recovered from aseptic PWN-inoculated microcuttings and seedlings was reconfirmed by culturing them in NB liquid medium at 30°C for more than 7 days. Taken together, the results indicate that the asepsis of PWN did not cause the loss of pathogenicity.     

Pathogenicity and repulsion for toxin‐producing bacteria of dominant bacteria on the surface of American pine wood nematodes

Bacteria were isolated from the surface of two samples of American pine wood nematodes to identify methods of controlling pine wilt disease. The dominant bacterial strains were identified, and their toxicity and pathogenicity, in addition to their competitiveness with other pathogenic bacteria, were measured to ascertain how bacteria on the surface of American pine wood nematodes might be used to prevent and control pine wilt disease. The bacterial isolates show that the dominant bacteria carried by the two samples of pine wood nematodes are US4, US5, Smal‐007 and Rrad‐006. Based on routine staining, morphological observation and 16S rDNA sequence analysis, the four strains were identified as Delftia lacustris, Pseudomonas putida, Stenotrophomonas maltophilia and Rhizobium nepotum. The incubation of four dominant bacterial strains and Chinese dominant bacterial strains on the surface of aseptic nematodes and in nutrient broth showed that Smal‐007 and Rrad‐006 have strong competitiveness on the surface of pine wood nematodes. Using a bacterial culture medium to measure the propensity of pine seedlings to wilt, all the American dominant bacterial strains were shown to be less toxic than the Chinese dominant strains. If pine seedlings are inoculated with both bacterial and aseptic pine wood nematodes, American dominant bacterial strains present less pathogenicity than the Chinese dominant bacterial strains. In particular, Smal‐007 and Rrad‐006 show the lowest pathogenicity. If pine seedlings are inoculated with both bacterial and wild pine wood nematodes, American dominant bacterial strains significantly reduce the pathogenicity of wild pine wood nematodes isolated from Zhejiang Province, China. The effects of Smal‐007 and Rrad‐006 are confirmed as the most prominent. The American dominant strains Smal‐007 and Rrad‐006 satisfy two main requirements: excellent repulsion performance and low pathogenicity. Therefore, they can be used as candidate strains for biocontrol bacteria.     

Relationship of Bursaphelenchus xylophilus Population Density to Mortality of Pinus sylvestris

Seven-month-old Scots pine seedlings were inoculated with water or culture filtrate (controls), with 10,000, or 20,000 (experiment 1), and with 2,500 (experiment 2) Bursaphelenchus xylophilus B.C. isolate nematodes and maintained under defined experimental conditions. Controls did not develop pine wilt disease over a 2-month period. In experiment 1, less than 50% of the inoculum was recovered from the nematode-inoculated seedlings in the first 48 hours, after which the nematode population of both treatments increased exponentially resulting in pine death and approximately equal populations at 216 hours after inoculation. In the second experiment, plant mortality, which was always preceded by 2-3 days of chlorosis and associated stem vascular necrosis, first occurred 14 days after inoculation. The nematode population increased until about day 40 after inoculation and declined thereafter. Nematodes extracted from the roots 2 weeks after inoculation accounted for ca.15% of the total number of nematodes per pine. The study indicates that the rate of nematode reproduction is a factor in pine wilt disease. However, the lack of a linear correlation between the number of nematodes and the timing of pine mortality suggests that the timing of pine death may also depend on the location of nematode damage to the host tissue.     

Influence of Temperature on Development of Pine Wilt in Scots Pine

The effect of temperature on pine wilt development in Scots pine (Pinus sylvestris) was examined in three experiments. Container-grown pines (4-6 years old) inoculated with 1,500 Bursaphelenchus xylophilus were incubated at constant temperatures in growth chamber for 8 weeks, then at a temperature range of 15-30 C in a greenhouse for 10-12 weeks. Nematode infection was greater, tree mortality was higher, and disease incubation was shorter at 32 and 30 C than at 25, 23, 18, and 11 C. Foliar symptoms developed more rapidly and uniformly at higher temperatures. Ninety-five percent of tree deaths at 32 and 30 C and 88% at 25 and 23 C occurred within the 8-week exposure to constant temperatures. Mortality at 18, 16, and 11 C occurred only after transfer to the greenhouse. Results indicate that pine wilt incidence is directly related and disease incubation period is inversely related to temperature and that high-temperature stress predisposes Scots pine to lethal infection by B. xylophilus.