松树抗松材线虫病机制研究进展

松材线虫病(pine wilt disease,PWD)是一种重大的森林病害,对我国乃至世界生态环境和森林资源造成了严重破坏和威胁。由于该病发生发展的复杂性,病原的致病机理一直不清楚。面对松材线虫的侵染,寄主松树势必要启动防御机制予以抵抗。现对寄主松树受松材线虫侵染后组织病理学、生理生化及分子病理学的变化进行综述,并对今后从寄主角度研究松材线虫病提出思考和展望,这将有助于进一步了解松树与松材线虫的互作过程,并揭示寄主从防御到最后死亡的内在原因,从而找到防治松材线虫病的有效策略。     

季也蒙假丝酵母对松材线虫病的抑制作用

松材线虫病是重要的森林病害,该病与松材线虫携带的病原菌和松树的内生病原菌密切相关。在室内条件下,初步研究了从人工培养的松材线虫上分离到的菌株C对松材线虫病的抑制作用。在健康的水培马尾松枝上分别接种松材线虫接种液、菌株C接种液、松材线虫与菌株C的混合接种液。处理后松枝的相对重量与相对蒸腾强度均为:接种菌株C的松枝>混合接种的松枝>接种线虫的松枝。处理后15d时,接种线虫的松枝与混合接种的松枝的相对重量有显著性差异(p<0.05)。接种线虫松枝的存活期显著短于其它处理松枝的存活期(p<0.05)。接种菌株C的针叶褐变株数少于接种线虫的松枝,两者有显著性差异(p<0.05)。从接种线虫和混合接种的所有松枝中都分离到松材线虫,且分离出的线虫量没有显著性差异。将8个月生的断根马尾松苗插入菌株C的查彼培养液的滤液中培养,6d后松苗的平均感病指数和感病株率均显著少于对照(p<0.05)。这表明,菌株C对松材线虫病有抑制作用,菌株C培养液中产生的某些代谢物质有利于松苗的抗病和存活。菌株C可能抑制了松树上的内生病原菌和松材线虫携带的病原微生物,或提高了松树的生长力和抗逆能力。经电子显微镜观察并参照AP I 20 C AUX鉴定系统鉴定,菌株C为季也蒙假丝酵母C and id a gu ilierm ond ii。     

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     

松材线虫与伴生微生物的生态关系

松材线虫是重要的外来有害生物,造成松树大量死亡,带来严重的经济损失和生态破坏.松材线虫与伴生微生物存在密切的生态关系.本文综述了松材线虫伴生微生物的种类及其在松材线虫繁殖和致病过程中的重要生态作用,从微生态系统角度对松材线虫病进行探讨.伴生真菌能为松材线虫提供食物,维持松材线虫次生侵染循环,提高分散型第三龄幼虫在种群中的比例,利于松材线虫侵染扩散;伴生细菌能够提高松材线虫致病性,促进其繁殖,并菌有助于松材线虫降解松萜类物质,从而提高松材线虫的适应性.     

松材线虫和拟松材线虫体内细菌的透射电镜观察及分离鉴定

【目的】松材线虫是松树萎蔫病的病原,拟松材线虫在形态等方面与松材线虫极其相似。关于两种线虫与细菌的研究多集中于体表伴生细菌。本文要揭示松材线虫和拟松材线虫体内是否存在细菌。【方法】对松材线虫和拟松材线虫进行透射电镜观察;并采用1%升汞和抗菌素混合液对两种线虫虫体进行体表消毒后研磨,制备悬浮液涂布NA平板;通过生理生化测定和16S rDNA序列分析鉴定细菌种类。【结果】松材线虫和拟松材线虫透射电镜照片显示在两种线虫肠道内均发现细菌;体表无菌的松材线虫和拟松材线虫共分离到3株体内细菌;这3株细菌分别属于寡养单胞菌属(Stenotrophomonas)和爱文氏菌属(Ewingella)。【结论】松材线虫和拟松材线虫体内均存在细菌;这些细菌对这两种线虫可能具有一定的生理生态作用。本文是松材线虫和拟松材线虫体内存在细菌的首次报导。     

植物根际益生细菌代表性菌株贝莱斯芽孢杆菌FZB42对松材线虫的抑杀性

【目的】由松材线虫导致的松树萎蔫病是松树的毁灭性病害,也是我国最主要的林业病害之一。本研究测评了在农业上广泛使用的、我国微生物肥料行业主要菌种资源之一——贝莱斯芽孢杆菌,对松材线虫的潜在抑杀性能。【方法】选用贝莱斯芽孢杆菌的代表性菌株FZB42为材料,测定对不同条件下的菌液上清、不同菌株的菌液上清、细菌素plantazolicin的提取物以及菌体直接接触等方式,对松材线虫死亡率/存活率的影响,并构建FZB42生物膜合成缺损菌株,测定比较其对松材线虫存活率的影响。【结果】相比于Landy培养基,使用LB培养基得到的菌液上清,对松材线虫具有明显抑杀性,培养48h的菌液上清比培养24h的菌液上清抑杀性更强,同时,菌液上清的抑杀效能随浓度升高及处理时间增长而有所增加。其中,使用培养48h后收集的LB菌液上清处理48h,松材线虫死亡率可高达约50%。之前报道对秀丽隐杆线虫有杀线虫活性的细菌素plantazolicin,经不同突变株上清以及plantazolicin提取物测试,被证实对松材线虫无抑制作用。直接接触实验表明,尽管FZB42的生物膜形成作用会刺激松材线虫提高抗胁迫能力,但整体而言,菌体接触对松材线虫亦有明显抑杀效果。【结论】本研究通过严格细致的测试证明,贝莱斯芽孢杆菌FZB42对松材线虫具有抑杀性,该抑杀作用的分子基础和作用机理有待深入挖掘,但其与plantazolicin无关。作为安全性好、研究开发程度高的一类生防菌株,贝莱斯芽孢杆菌在防治松材线虫病方面的潜在价值值得关注。     

松材线虫生防细菌的筛选、鉴定及其毒性因子的初步研究

从河南南阳不同农田的植物根部采取土壤样本,共分离获得了198株细菌。通过毒性测试和平板生测从中筛选出松材线虫生防细菌6株,其中NS-3菌株对松材线虫的杀灭活性最高。结合该菌株的形态学、生理学特征及16S rDNA序列分析等结果将该菌株归为芽孢杆菌属,命名为Bacillus sp.strain NS-3。将该细菌液体培养的上清液和上清蛋白粗提物分别处理松材线虫48h后线虫的死亡率分别达到50%和100%;线虫死亡后虫体消解。然而,细菌的上清蛋白粗提物经煮沸变性后,基本丧失了对松材线虫的侵染活性,结果显示细菌Bacillus sp.strain NS-3的杀线虫活性物质主要要存在于细菌培养上清液中,并且为热不稳定性物质。     

杀松材线虫海洋放线菌HT-8的鉴定及培养条件的研究（英文）

松树萎蔫病(Pine wilt disease,PWD)是由松材线虫(Bursaphelenchus xylophilus)引起的一种毁灭性疾病,该病对世界上许多国家和地区的针叶林资源造成严重破坏。为了寻找具有高杀松材线虫活性的海洋放线菌,对分离自海洋环境中的放线菌菌株进行杀线虫活性测定。选用稀释涂布平板法对采自青岛近海海域的样品进行放线菌分离,采用浸渍法测定菌株的杀松材线虫活性,并对所筛选出的高杀线虫活性菌株的形态学、培养特征和16S rD NA序列进行测定,运用单因素试验测定菌株产生杀线虫活性物质的最适培养条件。结果显示,从采集的样品中共分离到28株放线菌,经杀线虫活性筛选得到1株具有高杀线虫活性的放线菌HT-8。该菌株分离自海沙,其培养上清液处理松材线虫30 h时,线虫的校正死亡率高达88.30%。根据形态学、培养特征和16S rD NA序列测定及其系统发育分析结果,将菌株HT-8鉴定为Streptomyces termitum。单因素试验结果表明,该菌株产生杀线虫活性物质的最适培养条件为接种体菌龄48 h,接种量6%,培养基海水浓度100%,初始pH 7.5,培养温度25℃,培养时间7 d。该研究为海洋微生物资源的开发及其杀松材线虫天然活性物质的利用提供理论依据。     

Fast R-CNN深度学习和无人机遥感相结合在松材线虫病监测中的初步应用研究

松材线虫病因其破坏性强、传播速度快和防治难度大等特点,严重威胁着我国的松林资源.及时发现、定位和清理病死松树是控制松材线虫病蔓延的有效手段.本研究利用小型无人机获得松材线虫病疫点的可见光和多光谱的航摄影像.根据松树针叶颜色变化,将松材线虫Bursaphelenchus xylophilus侵染的松树分为病树和枯死树两种类型.将无人机遥感正摄影像图切割成瓦片图,根据不同植被指数的特征差异,筛选出含病树和枯死树的瓦片图.训练Fast R-CNN深度学习框架形成最终模型,通过模型运算获得病枯死松树的分布地图及坐标点位置.研究结果显示Fast R-CNN深度学习和无人机遥感相结合能有效识别出病树和枯死树,正确率分别达到90％和82％,漏检率分别为23％和34％,可为大面积监测松材线虫病的发生现状和流行动态、评估防控效果和灾害损失提供技术支撑.     

中国科学院动物研究所松材线虫快速取样技术在湖北试验取得成功

中国科学院动物研究所有关专家与湖北省联合开展的一项技术试验取得成功，最快只需2h就能检测出有“松树癌症”之称的松材线虫病。松材线虫病是世界上最具危险性的森林病害之一，松树感染此虫害后40d即可死亡。按照传统的方法，必须经过取样、锯末、浸泡分离等程序，需要一两天时间才能得出检测结果。采用松材线虫快速取样技术，     

Effects of Bacteria Associated with Pine Wood Nematode (Bursaphelenchus xylophilus) on Development and Egg Production of the Nematode

We tested the effects of four bacterial strains carried on the surface of the pine wood nematode (PWN), Bursaphelenchus xylophilus, on egg hatch, development rate and egg production. Strains GcM5‐1A (Pseudomonas fluorescens) and ZpB1‐2A (P. putida), were strong phytotoxin producers, while strains JnB1B (Pantoea sp.) and AcB1C (Peptostreptococcus asaccharalyticus) did not produce phytotoxins. None of the strains had any effect on egg hatch. GcM5‐1A and ZpB1‐2A promoted egg production, developmental rate, body length and diameter growth in both male and female PWN, whereas JnB1B and AcB1C had no such effects on the nematode. Indeed, the latter two strains completely inhibited egg production of the nematode. The results suggest that GcM5‐1A and ZpB1‐2A may provide PWN with food and/or essential nutrients for development and egg production. These results provide further evidence for our previous finding of a mutualistic symbiosis between the PWN and certain strains of bacteria carried by this nematode ( Zhao et al., 2003, 2005 ).     

Post-inoculation Population Dynamics of Bursaphelenchus xylophilus and Associated Bacteria in Pine Wilt Disease on Pinus thunbergii

Population dynamics of the pine wood nematode Bursaphelenchus xylophilus (PWN) and its accompanying bacteria in non-inoculated twigs along with the process of the disease was observed in Japanese black pine, Pinus thunbergii inoculated with PWN. In the non-inoculated twigs, bacteria could be detected when only a few pine needles became yellow. Once most needles had turned yellow or brown, the nematode began to appear and the bacterial populations increased. At the late stages of the disease when the inoculated pine was dying and the needles were totally wilted, the populations of both nematode and bacteria started to increase rapidly. Only a few bacterial species were found at the early stages. As the disease process advanced, the bacterial populations increased rapidly in both population size and variety of the species. However, Pseudomonas fluorescens , P. sp., Pantoea sp. and Sphimgomenas pancimobilis, remained dominant.     

Diversity of bacteria associated with Bursaphelenchus xylophilus and other nematodes isolated from Pinus pinaster trees with pine wilt disease

The pinewood nematode (PWN), Bursaphelenchus xylophilus, has been thought to be the only causal agent of pine wilt disease (PWD), however, since bacteria have been suggested to play a role in PWD, it is important to know the diversity of the microbial community associated to it. This study aimed to assess the microbial community associated with B. xylophilus and with other nematodes isolated from pine trees, Pinus pinaster, with PWD from three different affected forest areas in Portugal. One hundred and twenty three bacteria strains were isolated from PWN and other nematodes collected from 14 P. pinaster. The bacteria strains were identified by comparative analysis of the 16S rRNA gene partial sequence. All except one gram-positive strain (Actinobacteria) belonged to the gram-negative Beta and Gammaproteobacteria. Most isolates belonged to the genus Pseudomonas, Burkholderia and to the family Enterobacteriaceae. Species isolated in higher percentage were Pseudomonas lutea, Yersinia intermedia and Burkholderia tuberum. The major bacterial population associated to the nematodes differed according to the forest area and none of the isolated bacterial species was found in all different forest areas. For each of the sampled areas, 60 to 100% of the isolates produced siderophores and at least 40% produced lipases. The ability to produce siderophores and lipases by most isolates enables these bacteria to have a role in plant physiological response. This research showed a high diversity of the microbial community associated with B. xylophilus and other nematodes isolated from P. pinaster with PWD.     

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.     

Specific and Functional Diversity of Endophytic Bacteria from Pine Wood Nematode Bursaphelenchus Xylophilus with Different Virulence

Pine wilt disease (PWD) caused by the pine wood nematode (PWN), Bursaphelenchus xylophilus, is one of the most devastating diseases of Pinus spp. The PWN was therefore listed as one of the most dangerous forest pests in China meriting quarantine. Virulence of the PWN is closely linked with the spread of PWD. However, main factors responsible for the virulence of PWNs are still unclear. Recently epiphytic bacteria carried by PWNs have drawn much attention. But little is known about the relationship between endophytic bacteria and virulence of B. xylophilus. In this research, virulence of ten strains of B. xylophilus from different geographical areas in six provinces of China and four pine species were tested with 2-year-old seedlings of Pinus thunbergii. Endophytic bacteria were isolated from PWNs with different virulence to investigate the relationship between the bacteria and PWN virulence. Meanwhile, the carbon metabolism of endophytic bacteria from highly and low virulent B. xylophilus was analyzed using Biolog plates (ECO). The results indicated that ten strains of PWNs showed a wide range of virulence. Simultaneously, endophytic bacteria were isolated from 90% of the B. xylophilus strains. The dominant endophytic bacteria in the nematodes were identified as species of Stenotrophomonas, Achromobacter, Ewingella, Leifsonia, Rhizobium, and Pseudomonas using molecular and biochemical methods. Moreover, S. maltophilia, and A. xylosoxidans subsp. xylosoxidans were the predominant strains. Most of the strains (80%) from P. massoniana contained either S. maltophilia, A. xylosoxidans, or both species. There was a difference between the abilities of the endophytic bacteria to utilize carbon sources. Endophytic bacteria from highly virulent B. xylophilus had a relatively high utilization rate of carbohydrate and carboxylic acids, while bacteria from low virulent B. xylophilus made better use of amino acids. In conclusion, endophytic bacteria widely exist in B. xylophilus from different pines and areas; and B. xylophilus strains with different virulence possessed various endophytic bacteria and diverse carbon metabolism which suggested that the endophytic bacteria species and carbon metabolism might be related with the B. xylophilus virulence.     

Chloroform mineralization by toluene-oxidizing bacteria.

Seven toluene-oxidizing bacterial strains (Pseudomonas mendocina KR1, Burkholderia cepacia G4, Pseudomonas putida F1, Pseudomonas pickettii PKO1, and Pseudomonas sp. strains ENVPC5, ENVBF1, and ENV113) were tested for their ability to degrade chloroform (CF). The greatest rate of CF oxidation was achieved with strain ENVBF1 (1.9 nmol/min/mg of cell protein). CF also was oxidized by P. mendocina KR1 (0.48 nmol/min/mg of cell protein), strain ENVPC5 (0.49 nmol/min/mg of cell protein), and Escherichia coli DH510B(pRS202), which contained cloned toluene 4-monooxygenase genes from P. mendocina KR1 (0.16 nmol/min/mg of cell protein). Degradation of [14C]CF and ion analysis of culture extracts revealed that CF was mineralized to CO2 (approximately 30 to 57% of the total products), soluble metabolites (approximately 15%), a total carbon fraction irreversibly bound to particulate cellular constituents (approximately 30%), and chloride ions (approximately 75% of the expected yield). CF oxidation by each strain was inhibited in the presence of trichloroethylene, and acetylene significantly inhibited trichloroethylene oxidation by P. mendocina KR1. Differences in the abilities of the CF-oxidizing strains to degrade other halogenated compounds were also identified. CF was not degraded by B. cepacia G4, P. putida F1, P. pickettii PKO1, Pseudomonas sp. strain ENV113, or P. mendocina KRMT, which contains a tmo mutation.     

松材线虫(Bursaphelenchus xylophilus)入侵对马尾松(Pinus massoniana)林分生长的影响及相关生长模型

松材线虫（Bursaphelenchus xylophilus）是一种松树上发生严重的有害生物,它不仅改变了生态系统的结构和功能,而且改变了系统内生物的原有特性和地理分布。松材线虫及其引起的松树萎蔫病已对中国马尾松林（Pinus massoniana）的树木成长产生了巨大影响。基于此,使用＂每木调查法＂和＂样方法＂,对松材线虫入侵后的马尾松林内松树的各项生长指标因子进行了调查分析,其结果表明：自松材线虫1996年入侵所调查地区的松林后,对于受害松树不管是伐倒木（被伐倒）还是倒木（自然倒地）,其对周围马尾松胸径生长的影响是显著的,而对树高生长的影响不显著。最后建立了一系列的灰色和灰色-马尔可夫链数学模型,其预测结果精度高,可用于今后受害和未受害区马尾松林分因子的生长预测。     

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.     

Two Cyclic Dipeptides from Pseudomonas fluorescens GcM5-1A Carried by the Pine Wood Nematode and Their Toxicities to Japanese Black Pine Suspension Cells and Seedlings in vitro

Pseudomonas fluorescens GcM5-1A, isolated from the pine wood nematode (PWN), Bursaphelenchus xylophilus, was cultured in Luria Broth medium (LB). The clarified culture was extracted with ethyl acetate, and two dipeptides were purified from the extract. The chemical structures of 1 and 2 were identified as cyclo(-Pro-Val-)and cyclo(-Pro-Tyr-), respectively, by MS, ¹H NMR, ¹³C NMR,¹H-¹H COSY, 1H -¹³C COSY spectra. Bioassay results showed that the two compounds were toxic to both suspension cells and seedlings of Pinus thunbergii, which may offer some clues to research the mechanism of pine wilt disease caused by PWN.